Bipolar Disorder
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Bipolar Disorder
Bipolar Disorder: Clinical and Neurobiological Foundations Edited by Lakshmi N. Yatham and Mario Maj © 2010 John Wiley & Sons, Ltd. ISBN: 978-0-470-72198-8
Bipolar Disorder: Clinical and Neurobiological Foundations Editors Lakshmi N. Yatham Department of Psychiatry, The University of British Columbia, Vancouver, Canada
Mario Maj Department of Psychiatry, University of Naples SUN, Naples, Italy
This edition first published 2010, Ó 2010 by John Wiley & Sons, Ltd Wiley-Blackwell is an imprint of John Wiley & Sons, formed by the merger of Wiley’s global Scientific, Technical and Medical business with Blackwell Publishing. Registered office: John Wiley & Sons Ltd, The Atrium, Southern Gate, Chichester, West Sussex, PO19 8SQ, UK Other Editorial Offices: 9600 Garsington Road, Oxford, OX4 2DQ, UK 111 River Street, Hoboken, NJ 07030-5774, USA For details of our global editorial offices, for customer services and for information about how to apply for permission to reuse the copyright material in this book please see our website at www.wiley.com/wiley-blackwell The right of the author to be identified as the author of this work has been asserted in accordance with the Copyright, Designs and Patents Act 1988. All rights reserved. No part of this publication may be reproduced, stored in a retrieval system, or transmitted, in any form or by any means, electronic, mechanical, photocopying, recording or otherwise, except as permitted by the UK Copyright, Designs and Patents Act 1988, without the prior permission of the publisher. Wiley also publishes its books in a variety of electronic formats. Some content that appears in print may not be available in electronic books. Designations used by companies to distinguish their products are often claimed as trademarks. All brand names and product names used in this book are trade names, service marks, trademarks or registered trademarks of their respective owners. The publisher is not associated with any product or vendor mentioned in this book. This publication is designed to provide accurate and authoritative information in regard to the subject matter covered. It is sold on the understanding that the publisher is not engaged in rendering professional services. If professional advice or other expert assistance is required, the services of a competent professional should be sought. The contents of this work are intended to further general scientific research, understanding, and discussion only and are not intended and should not be relied upon as recommending or promoting a specific method, diagnosis, or treatment by physicians for any particular patient. The publisher and the author make no representations or warranties with respect to the accuracy or completeness of the contents of this work and specifically disclaim all warranties, including without limitation any implied warranties of fitness for a particular purpose. In view of ongoing research, equipment modifications, changes in governmental regulations, and the constant flow of information relating to the use of medicines, equipment, and devices, the reader is urged to review and evaluate the information provided in the package insert or instructions for each medicine, equipment, or device for, among other things, any changes in the instructions or indication of usage and for added warnings and precautions. Readers should consult with a specialist where appropriate. The fact that an organization or Web site is referred to in this work as a citation and/or a potential source of further information does not mean that the author or the publisher endorses the information the organization or Web site may provide or recommendations it may make. Furthermore, readers should be aware that Internet Web sites listed in this work may have changed or disappeared between when this work was written and when it is read. No warranty may be created or extended by any promotional statements for this work. Neither the publisher nor the author shall be liable for any damages arising herefrom. Library of Congress Cataloging-in-Publication Data Bipolar disorder : clinical and neurobiological foundations / editors, Lakshmi N. Yatham and Mario Maj. p. cm. Includes bibliographical references and index. ISBN 978-0-470-72198-8 (cloth) 1. Manic-depressive illness. I. Yatham, Lakshmi N. II. Maj, Mario, 1953– [DNLM: 1. Bipolar Disorder. WM 207 B6161 2010] RC516.B5223 2010 616.89’5—dc22 2010005586 ISBN: 9780470721988 A catalogue record for this book is available from the British Library. Set in 9.25/12pt, Palatino by Thomson Digital, Noida, India Printed in Singapore by Markono Print Media Pte Ltd 1
2010
Contents
Preface
vii
List of Contributors
ix
12 Genetics of Bipolar Disorder
Falk W. Lohoff and Wade H. Berrettini 13 Structural Brain Imaging in Bipolar Disorder
1 From Mania to Bipolar Disorder
1
2 Clinical Features and Subtypes of Bipolar
8
Fred K. Goodwin and D.Z. Lieberman 17
Lewis L. Judd and Pamela J. Schettler 31
Mark A. Frye and Giulio Perugi 44
Jan Fawcett 6 Update on the Epidemiology of Bipolar Disorder
52
62
69
Ivan J. Torres and Gin S. Malhi 83
90
R. Sabes-Figuera, D. Razzouk and Paul E. McCrone
Robert M. Post and Marcia Kauer-SantAnna
17 Molecular Biology of Bipolar Disorder
210
228
18 Mitochondrial Dysfunction and Oxidative
244
Tadafumi Kato, Flavio Kapczinski and Michael Berk 19 Neuroendocrinology of Bipolar Illness
255
Timothy Dinan and Michael Bauer Disorder
21 Treatment Adherence in Bipolar Disorder
263
96
275
Jan Scott and Mary Jane Tacchi 22 Acute Mania
11 An Introduction to the Neurobiology of Bipolar
Illness Onset, Recurrence and Progression
16 Neurotransmitter Systems in Bipolar Disorder
Greg Murray and Allison Harvey
Hagop S. Akiskal and Kareen K. Akiskal 10 Economics of Bipolar Disorder
200
20 Circadian Rhythms and Sleep in Bipolar
9 The Genius-Insanity Debate: Focus on Bipolarity,
Temperament, Creativity and Leadership
Disorder: Focus on Cerebral Metabolism and Blood Flow
Stress
Zolt an Rihmer and Jan Fawcett 8 Neurocognition in Bipolar Disorder
In Kyoon Lyoo and Perry F. Renshaw
Ana Andreazza, Jun Feng Wang and Trevor Young
Kathleen R. Merikangas and Tracy L. Peters 7 Suicide and Bipolar Disorder
133
Marina Nakic, John H. Krystal and Zubin Bhagwagar
5 DSM-V Perspectives on Classification
of Bipolar Disorder
Diffusion Tensor Imaging, and Magnetic Resonance Spectroscopy in Bipolar Disorder
John O. Brooks III, Po W. Wang and Terence A. Ketter
4 Comorbidity in Bipolar Disorder: A Focus on
Addiction and Anxiety Disorders
Paolo Brambilla and Jair C. Soares
15 Functional Brain Imaging Studies in Bipolar
3 The Long-Term Course and Clinical Management
of Bipolar I and Bipolar II Disorders
124
14 Functional Magnetic Resonance Imaging,
David Healy Disorder
110
285
Paul E. Keck, Jr, Susan L. McElroy and John M. Hawkins
v
vi
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Contents
23 Pharmacological Treatment of Bipolar
Depression
31 Psychoeducation as a Core Element of
294
Allan H. Young and Charles B. Nemeroff
32 Cognitive-Behavioural Therapy for Bipolar
304
Alan C. Swann
342
353
367
36 Bipolar Disorder in Women
463
Benicio N. Frey, Karine A. Macritchie, Claudio N. Soares and Meir Steiner
Chris J. Bushe and Mauricio Tohen 29 Somatic Treatments for Bipolar Disorder:
384
37 Phenomenology and Treatment of Bipolar
I Disorder in Children: A Critical Review
Mark S. George
477
Gabrielle A. Carlson and Elizabeth B. Weller
30 Novel Therapeutic Strategies for Bipolar
Rodrigo Machado-Vieira, Husseini K. Manji and Carlos A. Zarate Jr
453
Amy M. Kilbourne, David E. Goodrich and Mark S. Bauer
28 Bipolar Disorder and Safety Monitoring
Disorder
443
David J. Miklowitz 35 Collaborative Care for Bipolar Disorder
Ihsan M. Salloum, Luca Pani and Tiffany Cooke
ECT, VNS and TMS
430
Holly A. Swartz, Ellen Frank, Laura E. Zajac and David J. Kupfer Disorder
27 Management of Comorbidity in Bipolar
for Clinicians: A Review of the Evidence and the Implications
Bipolar Disorder
34 Family Therapy Approaches to Bipolar
Gordon Parker and Terence A. Ketter Disorder
422
33 Interpersonal and Social Rhythm Therapy for
333
Joseph F. Goldberg and Michael Berk 26 Management of Bipolar II Disorder
Disorder Sagar V. Parikh and Jan Scott
25 Rapid Cycling Bipolar Disorder:
Phenomenology and Treatment
412
Francesc Colom and Lesley Berk
24 Practical Pharmacological Maintenance
Treatment of Bipolar Disorder
Psychological Approaches for Bipolar Disorders
395
38 Bipolar Disorder in the Elderly
488
Martha Sajatovic and Lars Vedel Kessing Index
499
Preface
Bipolar disorder is a relatively recent concept, which emerged in the middle of the 20th century. However, bipolar disorder is not a new disease. Indeed, Aretaeus of Cappadocia, in his descriptions, captured the essence of the nature and course of mood changes of mania and depression almost 2000 years ago. The objective of this book is to describe the clinical and neurobiological foundations of the modern concept of bipolar disorder as defined by the American Psychiatric Association’s Diagnostic Manual of Mental Disorders and the International Classification of Diseases. In order to capture both the American and the international perspectives, the editors deliberately chose authors from different continents for most chapters. The book is divided into four sections. The first section covers the descriptive aspects of the disorder. This section begins with an historical overview of the evolution of the concept of bipolar disorder. While Dr. Healy admits that bipolar disorder is a distinct clinical entity, he argues that the boundaries of the modern concept of bipolar disorder have been shaped primarily by the interests of the industry over the past 15 years. The next two chapters review clinical features, course and outcome in the context of new data and suggest that depressive symptoms dominate the course of bipolar disorder and that the disorder is chronic for a significant proportion of patients. Comorbidity is the rule rather than an exception for bipolar patients and this chapter illustrates some of the common comorbidities patients with bipolar disorder experience. Dr. Fawcett then outlines the DSM-V process and some of the issues that the DSM-V will address with regard to classification of bipolar disorder in the next chapter. The remaining chapters in this section emphasize that bipolar disorder is common, associated with cognitive impairment in a significant proportion of patients, that suicide risk is high, and that the disorder is
associated with significant economic burden. This section also contains a fascinating review of the genius–insanity debate. The biological aspects section begins with an overview of the neurobiology of bipolar disorder by Robert Post. Subsequent chapters address in greater detail some of the following questions: what is the current status with regard to the search for bipolar susceptibility genes? What brain regions and brain chemicals are altered in bipolar patients? Are changes in neurotransmitters and neurohormones still relevant or are changes in post-receptor signalling pathways more critical to the neurobiology of bipolar disorder? Is bipolar disorder associated with oxidative stress, mitochondrial dysfunction or alterations in biological rhythms? Treatment adherence is a major challenge in the management of bipolar disorder. Thus, the section on management begins with an overview of reasons for non-adherence and strategies to improve adherence. This is followed by a series of chapters that describe the current status of the pharmacological management of various phases and subtypes of bipolar disorder. This section also contains chapters that review the role of novel treatments, somatic treatments, and safety monitoring, as well as the role of psychological treatments as adjuncts to pharmacotherapy. The final section on special populations provides clinicians with the latest information and guidance on the management of bipolar disorders in women, children and the elderly. We hope that this book will become a useful resource for psychiatrists and other health care professionals to improve their understanding and management of bipolar disorder. Lakshmi N. Yatham Mario Maj
vii
List of Contributors
Hagop S. Akiskal University of California at San Diego, 3350 La Jolla Village Drive, San Diego, CA 92161-9116, USA Kareen K. Akiskal International Mood Center, La Jolla, CA 92093-0603, USA
John O. Brooks III Semel Institute for Neuroscience and Human Behavior, David Geffen School of Medicine at UCLA, 760 Westwood Plaza, B8-233b NPI, Los Angeles, CA 90024-1759, USA
Ana Andreazza Department of Psychiatry, University of British Columbia, 2255 Westbrook Mall, Vancouver, BC V6T 2A1, Canada
Chris J. Bushe Lilly UK, Lilly House, Priestley Road, Basingstoke, RG24 9NL, UK
Mark S. Bauer Center for Organization, Leadership, and Management Research (152M), Boston VA Healthcare System, 150 South Huntington Avenue, Boston, MA 02130, USA
Gabrielle A. Carlson Department of Child and Adolescent Psychiatry, Stony Brook University School of Medicine, Putnam Hall-South Campus, Stony Brook, NY 11794-8790, USA
Michael Bauer Department of Psychiatry and Psychotherapy, University Hospital Carl Gustav Carus, Technische Universita¨t Dresden, Fetscherstraße 74, D-01307 Dresden, Germany Lesley Berk ORYGEN Research Centre and Department Clinical & Biomedical Sciences, University of Melbourne, Victoria, Australia Michael Berk Barwon Health and the Geelong Clinic, University of Melbourne, Kitchener House, Ryrie Street, Geelong, Victoria 3220, Australia Wade H. Berrettini University of Pennsylvania School of Medicine, Room 2206, 125 South 31st Street, Philadelphia, PA 19104, USA Zubin Bhagwagar Department of Psychiatry, Yale University School of Medicine, New Haven, CT, USA; Bristol Myers Squibb, USA Paolo Brambilla Inter-University Center for Behavioural Neurosciences, Department of Pathology and Experimental & Clinical Medicine, Section of Psychiatry, University of Udine, Udine, Italy
Francesc Colom Bipolar Disorders Program, Clinical Institute of Neuroscience, IDIBAPS-CIBERSAM, Hospital Clinic Barcelona, University of Barcelona, Barcelona, Catalonia, Spain Tiffany Cooke Emory University, Rollins School of Public Health, 1518 Clifton Road Northeast Atlanta, GA 30329, USA Timothy Dinan Department of Psychiatry, Cork University Hospital, Wilton, Cork, Ireland Jan Fawcett Department of Psychiatry, University of New Mexico School of Medicine, National Institute of Albuquerque, Albuquerque, NM 87131, USA Ellen Frank Department of Psychiatry and Department of Psychology, University of Pittsburgh School of Medicine, Western Psychiatric Institute and Clinic, 3811 O’Hara Street, Pittsburgh, PA 15213, USA ix
x
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List of Contributors
Benicio N. Frey Department of Psychiatry and Behavioural Neurosciences, McMaster University and Womens Health Concerns Clinic, St. Josephs Healthcare, Hamilton, ON, Canada
Marcia Kauer-Sant’Anna Molecular Psychiatry Laboratory, Department of Psychiatry, Hospital de Clinicas de Porto Alegre, Universidade Federal do Rio Grande do Sul, Brazil
Mark A. Frye Department of Psychiatry and Psychology, Mayo Clinic, 200 First Street, Rochester, MN 55905, USA
Paul E. Keck, Jr. Lindner Center of HOPE and Department of Psychiatry, University of Cincinnati College of Medicine, 4075 Old Western Row Road, Mason, OH 45040, USA
Mark George Brain Stimulation Laboratory, MUSC IOP, Radiology and Neurosciences Medical University of South Carolina, 67 President Street, Room 502 North, PO Box 250861, Charleston, SC 29425, USA
Lars Vedel Kessing Department of Psychiatry, Rigshospitalet, University Hospital of Copenhagen, 2100 Copenhagen, Denmark
Joseph F. Goldberg Mount Sinai School of Medicine, New York, NY, USA David E. Goodrich VA Ann Arbor National Serious Mental Illness Treatment Research and Evaluation Center, 2215 Fuller Road, Ann Arbor, MI 48105, USA Fred K. Goodwin Department of Psychiatry and Behavioral Sciences, Center on Neuroscience, Medical Progress, and Society, George Washington University Medical Center, Washington, DC 20037, USA
Terence A. Ketter Department of Psychiatry and Behavioral Sciences, Stanford University School of Medicine, 401 Quarry Road, Room 2124, Stanford CA 94305, USA Amy M. Kilbourne VA Ann Arbor Serious Mental Illness Treatment Research and Evaluation Center, 2215 Fuller Road, Ann Arbor, MI 48105, USA John H. Krystal Department of Psychiatry, Yale University School of Medicine, Yale-New Haven Hospital, 300 George Street, Suite 901, New Haven, CT, 06511, USA
Allison Harvey Psychology Department, Sleep and Psychological Disorders Lab, University of California, 3210 Tolman Hall, Berkeley, CA 94720-1650, USA
David J. Kupfer Department of Psychiatry, University of Pittsburgh School of Medicine, Western Psychiatric Institute and Clinic, 3811 O’Hara Street, Pittsburgh, PA 15213, USA
John M. Hawkins Lindner Center of HOPE; Associate Professor, Department of Psychiatry, University of Cincinnati College of Medicine, 4075 Old Western Row Road, Mason, OH 45040, USA
D.Z. Lieberman George Washington University Medical Center, 2150 Pennsylvania Avn., NW, Department of Psychiatry and Behavioral Sciences, 8th Floor, Washington, DC 20037, USA
David Healy Hargest Unit, North Wales Department of Psychological Medicine, Cardiff University, Ysbyty Gwynedd, Bangor, LL57 2PW, UK
Falk W. Lohoff University of Pennsylvania School of Medicine, Department of Psychiatry Center for Neurobiology and Behavior Translation Research Laboratories., 125 South 31st Street, Room 2213, Philadelphia, PA 19104, USA
Lewis L. Judd Department of Psychiatry, University of California at San Diego (UCSD), 9500 Gilman Drive, MC: 0603, La Jolla, CA 92093-0603, USA
In Kyoon Lyoo Seoul National University, Seoul, South Korea
vio Kapczinski Fla ISBD Hospital de Clinicas, UFRGS Brizil Porto Alegre, RS, Brazil
Rodrigo Machado-Vieira Experimental Therapeutics, Mood and Anxiety Disorders Research Program, NIMH-NIH, Bldg 15K, 15 North Drive, MSC 2670, Bethesda, MD 20892, USA
Tadafumi Kato Laboratory for Molecular Dynamics of Mental Disorders, RIKEN Brain Science Institute, Hirosawa 2-1, Wako, Saitama, 350-0198, Japan
Karine A. Macritchie Institute of Mental Health, Department of Psychiatry, University of British Columbia, Suite 403 - 5950 University Blvd., Vancouver, BC V6T 1Z3, Canada
List of Contributors
Gin S. Malhi Department of Psychiatry, University of Sydney, CADE (Clinical Assessment Diagnostic Evaluation) Clinic, Royal North Shore Hospital, Sydney, Australia Husseini K. Manji Johnson & Johnson Pharmaceuticals Group, 1125 Trenton-Harbourton Road, E32000, Titusville, NJ 08560, USA Paul E. McCrone Centre for the Economics of Mental Health, Section of Community Mental Health Service and Population Research, Department PO24, Institute of Psychiatry, King’s College, De Crespigny Park, London SE5 8AF, UK Susan L. McElroy Lindner Center of HOPE and Department of Psychiatry, University of Cincinnati College of Medicine, 4075 Old Western Row Road Mason, OH 45040, USA Kathleen R. Merikangas Genetic Epidemiology Research Branch, Porter Neuroscience Research Centre, National Institute of Mental Health, Building 35, Room 1A-201, 35 Convent Drive, MSC 3720, Bethesda, MD 20892-3720, USA David J. Miklowitz UCLA Semel Institute for Neuroscience and Human Behavor Division of Child and Adolescent Psychiatry, 760 Westwood Plaza, Rm 58-217 David Geffen School of Medicine at UCLA, Los Angeles, CA 90024-1759, USA Greg Murray Faculty of Life and Social Sciences, Swinburne University of Technology, PO Box 218 John Street, Hawthorn 3122, Australia Marina Nakic Department of Psychiatry, Yale University School of Medicine, Yale-New Haven Hospital, 300 George Street, Suite 901, New Haven, CT, 06511, USA Charles B. Nemeroff Department of Psychiatry and Behavioral Sciences, University of Miami Miller School of Medicine, Miami FL, USA Luca Pani Istituto Tecnologie Biomediche, Consiglio Nazionale delle Ricerche, Sede di Cagliari-Pula and PharmaNess Scarl, Edificio 5 - Parco Scientifico e Tecnologico della Sardegna - 09010 Pula (Cagliari), Italy Sagar V. Parikh Department of Psychiatry, University Health Network, University of Toronto, Room 9M-329, Toronto Western Hospital, 399 Bathurst Street, Toronto, ON M5T 2S8, Canada
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xi
Gordon Parker School of Psychiatry, University of New South Wales (UNSW), New South Wales, Australia 2031; Black Dog Institute, Hospital Road, Prince of Wales Hospital, Ranwick, NSW 2031, Australia Giulio Perugi Department of Psychiatry, University of Pisa; Institute of Behavioural Sciences “G. De lisio”, Viale Monzone 3, 54031 Carrara, Italy Tracy L. Peters Genetic Epidemiology Research Branch, Mood and Anxiety Program, Intramural Research Program, National Institute of Mental Health, National Institute of Health, Porter Neuroscience Research Center, Building 35, Room 1A-201, 35 Convent Drive, Bethesda, MD 20892-3720, USA Robert M. Post George Washington University Medical School, Bipolar Collaborative Network, 5415 W. Cedar Kabem Suite 201B, Bethesda, MD 20814, USA D. Razzouk Department of Psychiatry, Universidade Federal de Sao Paulo (UNIFESP), Sao Paulo, Brazil Perry F. Renshaw University of Utah, Salt Lake City, UT USA n Rihmer Zolta Department of Clinical and Theoretical Mental Health, and Department of Psychiatry and Psychotherapy, Semmelweis Medical University, Ku´tvo¨lgyi Clinical Centre, Budapest, Hungary R. Sabes-Figuera Centre for the Economics of Mental Health, Health Service and Population Research Department PO24, Institute of Psychiatry, King’s College, De Crespigny Park, London SE5 8AF, UK Martha Sajatovic University Hospitals Case Medical Center, 10524 Euclid Avenue, Cleveland, OH 44106, USA Ihsan M. Salloum Department of Psychiatry, University of Miami Miller School of Medicine, 1120 NW 14th Street, Rm 1450, Miami, FL 33136, USA Pamela J. Schettler Mood Disorders Research Group, Department of Psychiatry, University of California at San Diego (UCSD), 9500 Gilman Drive, La Jolla, CA 92093-0603, USA
xii
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List of Contributors
Jan Scott University Department of Psychiatry, Newcastle University, Institute of Psychiatry, Institute of Neuroscience, Newcastle-upon-Tyne NE1 4RU, UK Claudio N. Soares Department of Psychiatry and Behavioural Neurosciences, McMaster University and Womens Health Concerns Clinic, St. Josephs Healthcare, Hamilton, ON, Canada Jair C. Soares Department of Psychiatry and Behavioral Sciences, UT Houston Medical School, Houston, TX, USA Meir Steiner Department of Psychiatry and Behavioural Neurosciences, McMaster University and Womens Health Concerns Clinic, St. Josephs Healthcare, Hamilton, ON, Canada Alan C. Swann Department of Psychiatry and Behavioral Sciences, The University of Texas Health Science Center at Houston, 1300 Moursund Street, Houston, TX 77037, USA Holly A. Swartz Department of Psychiatry, University of Pittsburgh School of Medicine, Western Psychiatric Institute and Clinic, 3811 O’Hara Street, Pittsburgh, PA 15213, USA Mary Jane Tacchi Institute of Psychiatry, Institute of Neuroscience, Newcastle University, Newcastle-upon-Tyne, NE1 7RU, UK Mauricio Tohen University of Texas Health Science Center at San Antonio, 7730 Floyd Curl Drive, San Antonio, TX 78229, USA
Sadly, Elizabeth B. Weller died during preparation of the manuscript
Ivan J. Torres Department of Psychiatry, University of British Columbia, Vancouver, BC, Canada; Riverview Hospital, British Columbia Mental Health and Addictions Services, 2601 Lougheed Highway, Coquitlam, BC V3C 4J2, Canada Jun Feng Wang Department of Psychiatry, University of British Columbia, 2255 Westbrook Mall, Vancouver, BC V6T 2A1, Canada Po W. Wang Department of Psychiatry and Behavioral Sciences, Stanford University School of Medicine, Stanford, CA 94305, USA Elizabeth B. Weller Deceased Allan H. Young Institute of Mental Health, Department of Psychiatry, University of British Columbia, Suite 430, 5950 University Blvd., Vancouver, BC V6T 1Z3, Canada Trevor Young, MD Department of Psychiatry, University of British Columbia, 2255 Westbrook Mall, Vancouver, BC V6T 2A1, Canada Laura E. Zajac Department of Psychology, University of Pittsburgh School of Medicine, Western Psychiatric Institute and Clinic, 3811 O’Hara Street, Pittsburgh, PA 15213, USA Carlos A. Zarate, Jr. Experimental Therapeutics, Mood and Anxiety Disorders Research Program, National Institute of Mental Health (NIMH-NIH), Bldg 15K, 15 North Drive, Bethesda, MD 20892-2670, USA
Plate 1 Sample magnetic resonance spectroscopy spectra from P31 MRS at 2T (A) and from H1 MRS at 3T (B). Abbreviations: ATP, adenosine tri-phosphate; MRS, Magnetic Resonance Spectroscopy; PCr, Phosphocreatine; PDE, Phosphodiesters; Pi, Inorganic Phosphate; PME, Phosphomonoesters; T, Tesla. (a) A sample P31 spectra is shown. Reprinted from [3]. Association between cortical metabolite levels and clinical manifestations of migrainous aura: An MR-spectroscopy study. Brain;130:3102–3110, by permission of Oxford University Press. (b) A sample H1 spectra is shown. Reprinted from [4]. Abnormal glutamatergic neurotransmission and neuronal-glial interactions in acute mania. Biol. Psych.; 64:718–726, by permission of Elsevier.
Plate 2 Schematic presentation of the findings from cross-sectional H1 MRS and P31 MRS studies that show differences in brain metabolite levels between adult patients with bipolar disorder and comparison subjects. Abbreviations: Cho, Choline; Cr, Creatine; Glx, Glutamate, Glutamine and g-amino butyric acid; MRS, Magnetic Resonance Spectroscopy; NAA, N-acetylaspartate; PCr, Phosphocreatine; PME, Phosphomonoesters. Regular triangles represent higher brain metabolite levels or metabolite/Cr þ PCr ratios in patients with bipolar disorder relative to comparison subjects. Inverted triangles represent lower metabolite levels or metabolite/Cr þ PCr ratios in patients with bipolar disorder relative to comparison subjects. Rectangles represent no differences in metabolite levels or metabolite/Cr þ PCr ratios between patients with bipolar disorder and comparison subjects. Bipolar Disorder: Clinical and Neurobiological Foundations Edited by Lakshmi N. Yatham and Mario Maj © 2010 John Wiley & Sons, Ltd. ISBN: 978-0-470-72198-8
Plate 3 Schematic presentation of the findings from longitudinal H1 MRS studies that examine medication effects on brain metabolite levels in adult patients with bipolar disorder. Abbreviations: Cho, Choline; Cr, Creatine; Glx, Glutamate, Glutamine and g-amino butyric acid; HDRS, 17-item Hamilton Depression Rating Scale; MRS, Magnetic Resonance Spectroscopy; NAA, N-acetylaspartate. (a) Lithium effects on brain metabolite levels in patients with bipolar disorder. Regular triangles represent increase in brain metabolite levels or metabolite/Cr þ PCr ratios in patients with bipolar disorder after lithium treatment compared to those in their baseline. Inverted triangles represent decrease in brain metabolite levels or metabolite/Cr þ PCr ratios in patients with bipolar disorder after lithium treatment compared to those in their baseline. Rectangles represent no changes in metabolite levels or metabolite/Cr þ PCr ratios in patients with bipolar disorder after lithium treatment. (b) Cytidine effect on brain metabolite levels and depressive symptoms in depressed patients with bipolar disorder. Bars represent estimated glutamate/glutamine changes from baseline in cytidine and placebo add-on patients with bipolar depression. P values above the bars indicate significant difference between treatment groups in rates of decreasing glutamate/glutamine levels throughout the treatment period with mixed-effect regression model. Squares and trend lines represent the estimated HDRS score in cytidine and placebo add-on patients with bipolar depression. Asterisks represent p < 0.01 significant difference between treatment groups in rates of improvement in HDRS scores from Week 1 through Week 4 with mixed-effect regression model. (Copied from Yoon et al. [Yoon, S.J., Lyoo, I.K., Haws, C., Kim, T.S., Cohen, B.M., Renshaw, P.F., in press. Decreased glutamate/glutamine levels may mediate cytidines efficacy in treating bipolar depression: A longitudinal proton magnetic resonance spectroscopy study. Neuropsychopharmacology.]. Courtesy should be sought).
Plate 4 Regions of increased and decreased FA in patients with bipolar disorder relative to comparison subjects. Abbreviations: Ant, Anterior; Post, Posterior; Sup, Superior. Red circles represent higher FA in patients with bipolar disorder relative to comparison subjects, blue circles represent lower FA in patients with bipolar disorder relative to comparison subjects. Parcellated white matter mask is adapted from stereotaxic white matter atlas [122].
Plate 5 Regions of increased and decreased activation under emotional processing tasks in patients with bipolar disorder. Abbreviations: Sup, Superior; Mid, Middle; Inf, Inferior. Regions of increased (red circle) and decreased (blue circle) activation under emotional processing tasks in patients with bipolar disorder from the Table .8. Regions were marked based on the Talairach coordinates, Brodmann areas or anatomical description in the literature. In patients with bipolar disorder, there were abnormal cortical and subcortical activations in the brain regions including prefrontal and temporal cortex, striatum, thalamus and amygdala when taking emotional processing tasks such as the facial affect recognition and emotional Go-NoGo tasks relative to comparison subjects.
Plate 6 A model of corticolimbic dysregulation in bipolar disorder. Areas generally associated with increased activation in bipolar disorder are in red and those with decreased activation are in blue. Note that colour-coding of regions is intended to represent the consensus findings for the region, because all findings have not been uniform. Numbers for BAs are provided where appropriate. ACC ¼ anterior cingulate cortex; AMYG ¼ amygdala; ATC ¼ anterior temporal cortex; CV ¼ cerebellar vermis; DLPFC ¼ dorsolateral prefrontal cortex; HYPTH ¼ hypothalamus; MOFC ¼ medial orbital prefrontal cortex; PHG ¼ parahippocampal gyrus; SGPFC ¼ subgenual prefrontal cortex; THAL ¼ thalamus; VLPFC ¼ ventrolateral prefrontal cortex. From Brooks et al. [6].
Plate 7 Metabolic changes associated with bipolar depression relative to healthy controls. Decreased absolute metabolism is in blue. From Brooks et al. [6].
Plate 8 Metabolic changes associated with bipolar mania relative to healthy controls. Regions with decreased metabolism are in blue, and increased metabolism in red. From Brooks et al. (2010).
Plate 9 Resting state cerebral metabolic differences in older, euthymic patients with bipolar disorder compared to healthy controls. Regions with increased metabolism in bipolar disorder patients are in red and those with decreased metabolism are in blue. From Brooks et al. [6].
CHAPTER
1
From Mania to Bipolar Disorder David Healy Hargest Unit, North Wales Department of Psychological Medicine, Cardiff University, Ysbyty Gwynedd, Bangor, UK
From Pinel to Kraepelin When the first asylums opened, around 1800, mania was a generic term for insanity. Philippe Pinels Treatise on Insanity that appeared in 1800 was accordingly named Traite sur la Manie. For 2000 years before Pinel, the chief determinant of diagnosis in medicine lay in the visible presentation of the patient. These visible presentations could lead to reliable diagnoses of tumours, diabetes, catatonia, epilepsy and insanity. The visible presentations of insanity involved flushing, overactivity and maniacal behaviour. Mania was diagnosed in patients who were overactive and who might now be seen as having schizophrenia, depression, delirium, senility, imbecility and other conditions. Pinel took a stand on the importance of science in medicine, and was the first to call for an Evidence Based Medicine. Faced with patients hospitalized for years, he was the first to incorporate the course of a patients disorders into his diagnostic considerations. He recorded outcomes where patients were treated or left untreated, and noting responses followed by relapses, argued that some disorders were periodic or recurrent and that the vast majority of available treatments made the underlying condition worse. When a final and more complete version of his treatise was published in 1809, it distinguished in its title, Traite Medico-Philosophique sur lAlienation Mentale ou la Manie, between insanity in general and a new, more specific diagnosis of mania [1]. Once this distinction was made, and mania was separated out from idiocy dementia and melancholia, the rates of admission for mania settled at approximately 50% of all admissions in asylums in Europe and America until around 1900. While asylum nomenclature remained relatively constant for a century, there was an evolution in the thinking about insanity. The idea that there might be a distinct mood faculty that could be disordered in its own right was put forward in
Bipolar Disorder: Clinical and Neurobiological Foundations Edited by Lakshmi N. Yatham and Mario Maj © 2010 John Wiley & Sons, Ltd. ISBN: 978-0-470-72198-8
the 1830s by one of Pinels pupils, Jean-Dominique Etienne Esquirol, who described profound sadness – lypemanie – as a distinct disorder. The notion of a disease entity took shape in the 1850s when two of Esquirols pupils, Jean-Pierre Falret and Jules Baillarger, both described disorders that laid the basis for what became circular insanity. Falret outlined folie circulaire; Baillarger termed his disorder folie a double forme [2]. The idea that mania or insanity might give rise to protean manifestations had posed little difficulty, but as clinicians moved towards the concept of a disease entity, they had difficulties with the idea that two clinical states that looked so different might be presentations of the same underlying disease state. In their efforts to overcome these conceptual problems, both Falret and Baillarger posited a disorder with alternating cycles of mania and melancholia of fixed length and with fixed intervals between episodes. But crucially if neither the superficial features of mania nor the superficial features of melancholia accounted for the disorder, then some common ground between them must be responsible for the disorder. Some substrate must be diseased. The new disorder was not one that commanded clinical attention. Both men conceded that what they were describing was a rare condition. The condition described was moreover at this point not clearly a mood disorder. Others described alternating or circular insanity. None of these states were bipolar affective disorder, as that term would be understood today. The first to approach modern bipolar disorder was Karl Kahlbaum who in 1883 described cyclothymia. Where circular insanity was a psychotic disorder, with regular and stable features that led to degeneration, cyclothymia was for Kahlbaum a specific mood disorder from which patients could recover. Kahlbaum also introduced disease course as a classificatory principle, but this was resisted. Most academics at the time expected a localization of clinical features in different brain areas to provide the key to unlocking the mysteries of mental illness rather than disease course. However disease course was used by Charcot to distinguish between hysteria and Tourettes syndrome, and later to distinguish between Alzheimers and Creutfeld-Jacob disease. 1
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Manic-depressive illness In 1899, building on a series of syndromes first outlined by Kahlbaum, and on his principle of disease course, but eschewing brain localization, Emil Kraepelin distinguished between two disease entities – dementia praecox and manicdepressive insanity [3]. Dementia praecox was a disorder of cognitive function where the sufferer never returns to normal. Within this group, Kraepelin included three disorders outlined by Kahlbaum – hebephrenia, catatonia and paranoia. Given that clinical course was to be the main determinant of disease status, if in the one case recovery was to be the exception, there had to be a contrasting state in which recovery was the norm. Manic-depressive illness therefore emerged as the foil to dementia praecox. Kraepelins manicdepressive illness was a disorder where sufferers recovered from acute episodes but were at risk of a relapse. For Kraepelin, a bipolar alternation between excitement and stupor could not be a classificatory principle in that a similar alternation happens in many states of dementia praecox or general paralysis of the insane. But periodic, circular and simple manias, in addition to melancholic disorders, could all be regarded as manifestations of the one illness if they showed a remitting course. Involutional melancholia brings out the rigidity with which Kraepelin held to a disease course criterion. These classic depressive psychoses had their onset over the age of 50, when patients typically presented with disturbed sleep and appetite, diurnal variation of mood and either paranoid, nihilistic or guilt-laden delusions. In 1899 Kraepelin thought that these patients were much less likely to recover than other patients with mood disorders. Clinicians now would have no doubt that this condition was a mood disorder. However, because involutional melancholia apparently failed to remit, it posed difficulties for Kraepelin. As a result, he kept involutional melancholia separate from manic-depressive illness until the eighth edition of his textbook. Kraepelins distinctions between two almost identical clinical presentations (involutional and non-involutional melancholias) and amalgamation of what appeared to be quite different clinical presentations (unipolar and bipolar affective disorders) produced an illness concept that almost certainly baffled many of his contemporaries. The puerperal psychoses further clouded the diagnostic picture. Kraepelins compelling descriptions of a characteristic confusion and fleeting hallucinatory features in these psychoses, as well as their unstable cycling states, made a good case for a separate diagnosis to either dementia praecox or manic-depressive illness. But his disease course criterion left him no option but to argue that they were in all cases either manic-depressive insanity or dementia praecox.
Between these puerperal psychoses and good prognosis psychoses with cycloid features, there was a group of patients accounting for close to 10% of admissions for serious mental illness, double the number of admissions for bipolar affective disorder, but these all disappeared from view, because polarity did not count for Kraepelin as a classificatory principle.
The reception of manic-depressive illness – the academic response When Kraepelins work was discussed both within and outside of Germany, it was largely in terms of dementia praecox. For a quarter of a century, there was little mention of manic-depressive illness. In America, Kraepelins clinical approach was welcomed by Adolf Meyer as the breakthrough psychiatry was waiting for, although he later criticized it as being too neurological, and failing to place the patients disorder within the context of their life story. In Britain, there were regular references to Kraepelins work at psychiatric meetings and in the academic literature, in a way that did not happen with other German formulations [4]. These references were to dementia praecox; some disliked the term dementia and some disliked praecox, but the concept was widely discussed, whereas manicdepressive illness was rarely raised. The French did not accept that all psychotic disorders had the same degenerative clinical course, distinguishing instead between acute and chronic psychoses and amongst a variety of chronic non-deteriorating psychoses. The discovery of chlorpromazine in France validated traditional distinctions between the chronic psychoses and schizophrenia, on the basis that schizophrenia was poorly responsive to antipsychotics [5]. Nevertheless, from 1900, dementia praecox swept rapidly into use for a number of reasons. First, many psychiatrists had been struggling with the same issues and had come up with variants of the same idea from primary dementia to adolescent insanity. Kraepelins formulation balanced simplicity and complexity. It was more complex than simply adolescent insanity but much simpler than making distinctions amongst the chronic psychoses, as the French and Kahlbaum had done. Second, before 1900, diagnoses across medicine were made on the basis of the visible presentations of patients at admission, giving rise to diagnoses of consumption, ague, debility or mania. These diagnoses were essentially descriptions of the presenting problem. Following the triumph of bacteriology, after 1900 there was a move to defer diagnoses to later in the course of the admission, after the appropriate laboratory tests had been done and there had been more time to consider which, amongst a number of differential diagnoses, best accounted for the features of the illness. This
From Mania to Bipolar Disorder
The reception of manic-depressive illness: a typical asylum The North Wales Asylum, which opened in 1848, offers an opportunity to look at the uptake of concepts like Kraepelins. In North West Wales, the overall population and ethnic mix was almost precisely the same in 2000 as it had been in 1900. Elsewhere, because of geography and rising wealth, a growing number of people had a choice of hospitals. Because of this choice, it is difficult to know how representative patients, ending up in the public or private asylums across the Western world between 1800 and 1950, were of the mental illness happening in their communities of origin. In North West Wales, because of enduring poverty and geography, those with mental illnesses had nowhere to go except to one asylum. The resulting asylum records and case registers for modern admissions shed light on a number of issues. The first is the impact of Kraepelins diagnoses of dementia praecox and manic-depressive illness on clinical practice within Britain. The second set of issues has to do with quantitative aspects of the syndromes underpinning Kraepelins diagnoses. The first thing that strikes any reader of the asylum records is that up until 1900 over 50% of patients admitted apparently had mania (Figure 1). As late as 1900, patients who were suicidal, patients with senility, and patients with what now would be called schizophrenia, were all labelled as manic. However, manic-depressive illness was not dramatically more common 100 years ago than it is now. The
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The Diagnosis of Mania as a Percentage of all Admissions to the North Wales Asylum: 1875-1924 60 50 40 30 20 10 0 20
10
05
15
19
19
19
95
00
19
19
85
80
90
18
18
18
18
75
Mania
18
applied also to psychiatry, so that from 1900 diagnoses were less likely to be made on admission, bringing the likely chronicity of a patients illness to the fore as a diagnostic feature. The time was convenient for Kraepelins new ideas. In contrast, while there were many formulations of early onset dementia, Kraepelins manic-depressive illness concept was quite idiosyncratic. The new illness also introduced a new nomenclature. Why manic-depressive illness? Why not manic-melancholic disease, given that almost all the depressions Kraepelin was faced with were melancholic in terms of their severity and clinical features? The answer may lie in a quirk in the man – he had a partiality for novelty. Melancholia was an old-fashioned word. Depression was creeping into use. The first major paper on depressive illness had come a few years earlier, in 1886, from the Danish neurologist Carl Lange [6]. When it came to manic-depressive insanity, Kraepelins concept may have ultimately survived, because he had picked a name that worked. Names as well as concepts have survival value. But it took a quarter of a century for the new illness to achieve recognition, as data from North Wales indicates.
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Fig. 1 The diagnosis of mania as a percentage of all admissions to the North Wales Asylum: 1875–1924.
explanation for this finding is, as outlined above, that a diagnosis of mania referred to any state of overactive insanity. Around 1900, primarily in response to Kraepelins impact, the use of mania as a diagnosis in North Wales began to fall, and it fell progressively to the current rate of less than 5% of patients. Two questions arise. First, when do modern diagnoses emerge in the records and, second, how many manics had what would now be diagnosed as having in fact bipolar affective disorder? The contrasting reception of dementia praecox and manic-depressive illness helps bring these points out and can be seen in the cases of Bessie Hughes and William Thomas. Bessie Hughes was a 17-year-old girl admitted on 16 October 1905 with hebephrenic and catatonic features. She was noted to be a good case of dementia praecox. The records indicate that up until then a case like Bessies would have been diagnosed as melancholia with stupor. The term dementia praecox thereafter rapidly came into use in North Wales, and was not replaced by schizophrenia in these records before 1949. In contrast, William Thomas had been admitted in 1891 at the age of 45, having been looked after at home by his family for a number of years. A businessman, who had travelled back and forth between Wales and Argentina, his family wondered if his first breakdown 17 years previously, from which he had recovered at home, had stemmed from an engagement to a Catholic woman, or whether it had been triggered by the general alarum that had accompanied an outbreak of Yellow Fever. He had recovered and continued working until his early 40s, when his family committed him to the asylum where he remained until his death. On admission, in contrast to most patients, he seemed far from manic in the sense of agitated or overactive. After some days, grandiosity and probable delusional beliefs became apparent. Periods of elation alternated with mute and almost catatonic states, and he settled down to a cycle of episodes of depression, followed by overactivity and periods of lucidity. In 1904, 13 years after admission, the notes
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indicate that his alternating states were being viewed as circular insanity. The reference to circular insanity is the first of its kind in these records, but the overall diagnosis remained mania and never became manic-depressive illness. In 1906, a national conference on the classification of insanity in Britain introduced a new set of diagnoses. This system proposed a new disorder, primary dementia, which was the equivalent of Kraepelins dementia praecox. The new national classification system subdivided mania and melancholia into recent, chronic and recurrent mania or melancholia, and introduced the term alternating insanity. None of these terms were used in North Wales but dementia praecox was and it was this that led to the fall in the frequency of diagnoses of mania. Within the affective disorders domain, RO, who was admitted in 1908 and discharged in 1909, was diagnosed with maniacal depressive insanity – a disorder not on the list. In fact, this odd use of words was a better description of his case than a diagnosis of manic-depressive insanity would suggest, in that he only presented on one occasion, showing features of agitated (or maniacal) depression without any alternation of mood. Despite the example of RO, except for clearcut cases of dementia praecox, other cases continued to be diagnosed as having mania or melancholia rather than alternating insanity or manic-depressive illness. It was not until the 1920s that we begin to find diagnoses of manic-depressive illness appearing. In September 1920, a 30-year-old sailor, RP, was admitted with grandiose beliefs and violent behaviour. He remained in hospital for over a year, during which time he had attacks of agitation at regular intervals. On discharge he was diagnosed as manic-depressive. This man was readmitted two years later and spent most of the following 15 years as an inmate of the asylum, during which time he was noted to have a clinical state that alternated from manic to depressive poles on a one month cycle. The diagnosis only came into regular use in 1924. In that year, three cases were diagnosed as manic-depressive. One was AA, whose records from 1924 outline a 60-year-old woman who had two admissions for what would now be diagnosed as psychotic depression – no hint of mania. ER, also admitted and diagnosed in 1924 as manic-depressive, had a postpartum psychosis. In 1924, WH had her tenth admission, and during this admission she was diagnosed as manic-depressive. There had been nine previous admissions starting from May 1900, mostly for mania, none of which led to this diagnosis. Later in the 1920s, the pattern of taking previous episodes into account takes hold, and also a willingness to make the diagnosis if the person during the course of one admission has distinct spells of elevated and depressed moods. In addition to mirroring the wider resistance to Kraepelins concept of manic-depressive illness, the asylum
records reveal a quantitative factor to this resistance. During the historical period 1875–1924, there were 3872 admissions from North West Wales. These came from 3172 patients. Amongst patients admitted for the first time during the 1875–1924 period, only 127 (4%) had what retrospectively appears to be a bipolar disorder. Against the background population of North West Wales, this rate of admission gives rise to 10 cases per million per year, a rate that remained constant across the 50-year period, and continues to hold true today [2,7]. In contrast, there were 1041 patients with non-affective psychoses, who between them had 1304 admissions, and 658 admissions from 568 individuals for severe depression or melancholia. These melancholias account for 17% of all admissions and over 80% of the manic-depressive cohort. Without inclusion in a larger manic-depressive group, bipolar patients would have been close to invisible, and this may have been a factor that led Kraepelin to collapse these disorders into one entity. From this perspective, it is clear why concepts such as folie circulaire, folie a double forme or alternating insanity were simply not used in a working asylum like Denbigh before 1900. Too few patients were involved. The viability of the modern concept of a bipolar affective disorder depends critically on the diagnosis of hypomanic or cyclothymic states in the community. Of the patients with retrospective bipolar diagnoses admitted to the North Wales Asylum, 60% were female, compared to the 66% Kraepelin reported. The average age of first admission was 32 years old, with the youngest admission being for a 17 year old. The average length of stay in hospital for any one episode was 6 months. Almost all patients went home well, with only a very small proportion having continuous fluctuations in clinical state that precluded discharge. This group of 127 patients had 345 admissions and on average each person had 4 admissions every 10 years. Today the district general hospital unit serving the same area has a slightly higher proportion of female admissions. The average age of first admission is 31 years old. The average length of stay is a month. But bipolar patients have 6.5 admissions every 10 years. There is therefore a substantial increase in admission prevalence [7]. In the 1875–1924 cohort, 80% of the admissions for bipolar disorder were for manic presentations. Today, over 50% of the admissions from bipolar patients are for depression. Thus either the presentation of the illness is changing, or treatment is having an impact on presentations, or we have a greater sensitivity to episodes of depression that would formerly not have led to admission. The records also shed light on involutional melancholia. When patients with melancholia admitted to North Wales Asylum between 1875 and 1924 were tracked for length of stay and rates of recovery, broken down by age, one
From Mania to Bipolar Disorder
might have expected, if Kraepelin was right, that those who had an episode of melancholia in their 50s and 60s would have much longer lengths of stay and a much lower rate of recovery. Also patients with melancholia in their 50s and 60s had a somewhat lower rate of recovery, but this was in fact governed by the greater likelihood that they would die in hospital from physical illness. The length of stay of those patients who did not die in hospital was the same as those who had an onset of the disorder earlier in life. Overall patients admitted in their 30s or 40s were 1.2 times more likely to recover than patients admitted in their 50s or 60s, hardly the behaviour of a distinct disorder [8]. Between 1875 and 1924, puerperal psychoses accounted for close to 10% of admissions of women of childbearing years and 3% of admissions overall (Table 1). This disorder was as common as bipolar affective disorder. Two different sets of women were admitted with postpartum psychoses. The larger of the two sets were women who had no mental illness prior to the postpartum period. A smaller group (20%) were women with a prior mental illness [9]. In the modern period, psychoses with a first onset in the postpartum period in North West Wales have all but vanished, while the incidence of postpartum psychoses in women with a pre-existing mental illness remains the same. Data from across Europe support these findings. If so, this would support claims that these disorders are distinct from other disorders. Alternately, if regarded as affective disorders, establishing the basis for the apparent decline in frequency of these disorders may have implications for other affective disorders.
Table 1 The incidence of postpartum psychoses in North West Wales: 1875–1924 vs. 1994–2005.
All Female Admissions All Women All Women of Child-Bearing Age All Postpartum Psychotic Admissions All Women with Postpartum Psychoses Women with no prior Mental Illness Women with Prior Mental Illness Postpartum Cases/All Admissions from Women of Child-Bearing Age All Postpartum Cases/1000 Births Postpartum Onset Cases/1000 Births All Postpartum Cases/100 000 Childbearing Yrs Postpartum Onset Cases/100 000 Childbearing Yrs
1875–1924
1994–2005
1946 1577 1100 103 101 80 21 9.2%
3956 1827 1032 7 7 1 6 0.68%
0.34 0.26 3.43
0.19 0.03 0.94
2.70
0.13
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The emergence of bipolar disorder A new chapter in the affective disorder story opened up in the psychotropic era. By this time, Manic-Depressive Illness had become a stable and accepted category, and anomalies such as calling someone who only ever had depressive episodes manic-depressive no longer registered. Two factors brought about a change. First, in 1954, Mogens Schou demonstrated that manic states responded to lithium. Second, in 1957, Karl Leonhard distinguished amongst affective disorders on the basis of polarity, separating manic-depressive illness from pure melancholia and pure depression. Several prominent European and American researchers picked up his lead. The effect of lithium appeared both to endorse the existence of a bipolar subgroup within manic-depressive illness, and put a premium on the diagnosis of a mood disorder rather than a psychotic disorder. Combined, these developments underpinned the emergence of bipolar disorder in the mid-1960s and its incorporation into DSM III in 1980. DSM III was badged as a neo-Kraepelinian revolution in psychiatry. As of 1980, bipolar disorder was still embedded within the affective disorders, of which depression was the most important. The research focus was on distinguishing between subtypes of depression so that biological markers might be discovered. The failure to discover such markers was widely attributed to the heterogeneity of the samples being studied and this had led to proposals to distinguish between neurotic and psychotic, primary and secondary, reactive and endogenous depressions and other distinctions including bipolar and unipolar depression. In the early 1970s, the bipolar/unipolar dichotomy looked amongst the less fruitful avenues of research, in that clinically there was less to distinguish bipolar and unipolar depression, for instance from neurotic and psychotic depressions or endogenous and reactive depressions. As of 1980, the effects of pharmacological and biological dissection of nervous disorders seemed more likely to lead to distinctions between ever smaller groups of disorders rather than the reverse. Lithium, for instance, seemed only helpful for a proportion of either manic-depressive or bipolar patients. In the decade from 1980 to the mid-1990s, manicdepressive illness and bipolar disorder co-existed, with Goodwin and Jamisons 1990 monograph on the illness still entitled Manic-Depressive Illness [10]. It was only in 1992, with ICD 10, that the term bipolar disorder spread beyond America. But with the launch of Depakote as a moodstabilizer in 1995, the bipolar offspring ate its manicdepressive parent. The term mood-stabilizer essentially had not existed before 1995. Sedatives had been widely used to manage manic patients prior to that, but demonstrating a sedative effect in mania is quite different to showing a drug is
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prophylactic for bipolar disorder. Depakote was licensed for the treatment of mania but its adverts claimed it was a mood-stabilizer. Had Abbott said Depakote was prophylactic, they would have broken the law, as it had not been shown to be prophylactic but the term mood-stabilizer had no precise meaning. It suggested prophylaxis and this suggestion led to the use of Depakote and other anticonvulsants for maintenance purposes, despite a failure in controlled trials to demonstrate these agents are prophylactic. Bipolar disorder, in my view, has become more a brand than a well-grounded scientific term – as successful a brand as the creation of the terms tranquilizer and SSRI. A brand is something whose value lies in the perception of a consumer rather than in a tangible benefit. Where there had been almost no uses of the term mood-stabilizer before 1995, by 2000 there were over 100 articles per year featuring this term in their titles. The dramatic and rapid switch from Manic-Depressive Illness to Bipolar Disorder in the mid-1990s took place in the absence of any clinical or research facts to underpin the switch. The term bipolar disorder is rarely found in the titles of articles listed in Medline before 1992, but its use rapidly escalates from 1995 to reach 500 articles per year by 2005, while the term manic-depressive vanished. Estimates of the frequency of bipolar disorder in the population soared to a 100-fold compared with figures for admissions to the North Wales Asylum in the period from 1875 to 1924. The possibilities offered by mood-stabilization and bipolar disorder led companies producing second generation antipsychotics into the market, greatly expanding the use of these terms. Bipolar affective disorder is unquestionably a distinct clinical type; this does not mean it is necessarily a distinct disease entity. We still do not know enough about the bases for any remitting disorders to carve nature definitively at its joints in these domains. Many clinicians and scientists associate history with postmodernism, an all but psychiatric disorder in its own right, where academics refuse to concede there is any reality to human behaviours, or to the physical underpinnings of disorders of human behaviour. That which scientists regard as hard data or even facts, post-modernists treat as texts to be interpreted and re-interpreted without external constraint. The analysis of Kraepelins concept of manic-depressive illness outlined above demonstrates how complex his concept was, and how open to revision, but it also makes clear that clinical realities were once the primary determinant of clinical concepts. Concepts arose from the clinical material. In contrast, the post-modernism at which the marketing departments of pharmaceutical companies excel think nothing of shaping the clinical material to fit a marketing concept.
In the decade from 2000, all of the companies producing antipsychotics have targeted bipolar disorder as a means to enhance sales. The companies have recognised that to do this the attitudes of primary care physicians would have to change. Market research had shown that these doctors were reluctant to use antipsychotics, but they could be reeducated to the possibilities of mood-stabilizers. These were doctors who thought that bipolar disorder was a severe mental illness comparable to schizophrenia whose treatment appropriately was either in secondary care rather than primary care – they would need to be re-educated to recognise that many of the anxious and depressed patients going through their practices could be re-conceptualized as having bipolar disorder. These points are illustrated using the documents in the public domain from litigation involving Zyprexa, but a similar scenario applies to other drugs in the group. Thus: As the current market leader in primary care, Zyprexa will continue to revolutionize the way complicated mood disorders are treated by primary care physicians. Just as Prozac revolutionized the treatment of depression in the late 1980s and throughout the 1990s, so too will Zyprexa forever change the way primary care physicians view and treat bipolar disorder [11]: The facts: up to 30% of patients with a diagnosis of depression or anxiety may actually have bipolar disorder [12].
Scenarios like Donnas have been put forward as typical: Donna is a single mom, in her mid-30s appearing in your office in drab clothing and seeming somewhat ill at ease. Her chief complaint is “I feel so anxious and irritable lately”. Today she says she has been sleeping more than usual and has trouble concentrating at work and at home. However, several appointments earlier she was talkative, elated, and reported little need for sleep. You have treated her with various medications including antidepressants with little success. . . You will be able to assure Donna that Zyprexa is safe and that it will help relieve the symptoms she is struggling with [13]. There is clearly a nexus of nervous problems that patients endure in the community without ever coming to the attention of mental health services. Company marketers have been adept at framing the symptoms these give rise to in a manner most likely to lead to a script for the remedy of the day. Donna could have featured in adverts for tranquilizers from the 1960s to the 1980s, or for antidepressants in the 1990s, and would have probably been more likely to respond to either of these treatment groups than to an antipsychotic, and less likely to be harmed by them than by an antipsychotic. There have traditionally been difficulties in seeing these conditions simply as anxiety or as depression [14]. But
From Mania to Bipolar Disorder
while bipolar affective disorders probably exist in the community without coming to the attention of the secondary services, it flies in the face of a century of psychiatric thinking to see conditions that patients like Donna have as bipolar disorder. The concept of juvenile bipolar disorder flies even more in the face of a century of psychiatric thinking, but as of 2008, upwards of a million children in the United States, in many cases preschoolers, are on mood-stabilizers for bipolar disorder, even though the condition remains unrecognized in the rest of the world [2]. While this was happening, the cycloid disorders, which provided sound clinical grounds to unpick or go beyond the Kraepelinian synthesis, remained neglected. Instead, in a return to a pre-Kraepelinian psychiatry, company marketing departments have used a template of a supposedly neo-Kraepelinian medical science to promote a form of bipolar disorder based more on the visible presentations of patients rather than on any valid classificatory basis. This new disorder would have been unrecognizable to Kraepelin, whose tombstone bears an inscription – your name may vanish but your work remains – that has become ironic.
References 1. Pinel, P. (1809/2008) Medico-Philosophical Treatise on Mental Alienation (Trans G. Hickish, D., Healyand L.C.C. Charland), Wiley-Blackwell, Chichester. 2. Healy, D. (2008) Mania, in A Short History of Bipolar Disorder, Johns Hopkins University Press, Baltimore.
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3. Kraepelin, E. (1899) Psychiatrie, in Ein Lehrbuch f€ ur Studirende und Aertze. Barth, Leipzig (Translation S. Ayed), (1960), Science History Publications, Canton MA, p. 272. 4. Ion, R.M.and Beer, M.D. (2002) The British reaction to dementia praecox 1893–1913, part 1. Hist. Psychiatr., 13, 285–304, Part 2, 13, 419–432. 5. Pichot, P. (1982) The diagnosis and classification of mental disorders in French-speaking countries. Psychol. Med., 12, 475–492. 6. Lange, C.G. (1886) Om Periodiske Depressionstilstande, Jakob Lunds, Copenhagen. 7. Harris, M., Chandran, S., Chakroborty, N.and Healy, D. (2005) Service utilization in bipolar disorder, 1890 and 1990 compared. Hist. Psychiatry, 16, 423–434. 8. Farquhar, F., Le Noury, J., Tschinkel, S. et al. (2007) The incidence and prevalence of manic-melancholic syndromes in North West Wales: 1875–2005. Acta Psych. Scand, 115 (Suppl 433), 37–43. 9. Tschinkel, S., Harris, M., Le Noury, J.and Healy, D. (2007) postpartum psychosis: two cohorts compared, 1875–1924 & 1994–2005. Psychol. Med., 37, 529–536. doi: 10/1017/ S0033291706009202 10. Goodwin, F.K. and Jamison, K.R. (1990) Manic Depressive Illness, Oxford University Press, New York. 11. Zyprexa. Primary Care Sales Force Resource Guide (2002) Zyprexa MDL 1596, Plaintiffs Exhibit 01926, page 3. 12. Zyprexa. Primary Care Sales Force Resource Guide (2002) Zyprexa MDL 1596, Plaintiffs Exhibit 01926, page 6. 13. Zyprexa. Primary Care Sales Force Resource Guide (2002) Zyprexa MDL 1596, Plaintiffs Exhibit 01926, page 7. 14. Shorter, E. and Tyrer, P. (2003) Separation of anxiety and depressive disorders: blind alley in psychopharmacology and classification of disease. Br. Med. J., 327, 158–160.
CHAPTER
2
Clinical Features and Subtypes of Bipolar Disorder Fred K. Goodwin1 and D.Z. Lieberman2 1
Department of Psychiatry and Behavioral Sciences, Center on Neuroscience, Medical Progress, and Society, George Washington University Medical Center, Washington, DC, USA 2 Department of Psychiatry and Behavioral Sciences, George Washington University Medical Center, Washington, DC, USA
Introduction: the phenomenology of cyclicity and polarity The origins of the bipolar illness concept have been reviewed in the previous chapter by David Healy. Nevertheless, before discussing the clinical features and subtypes of bipolar disorder, it is worth reiterating a few salient points concerning the evolution of the bipolar illness construct. Kraepelins unitary concept of manic-depressive illness included all recurrent mood disorders, which were differentiated from dementia praecox by a family history of mood disorders, the episodic nature of the patients illness, and the relatively benign course and outcome. In 1957 Leonhard observed that manic-depressive patients with a history of mania (whom he termed bipolar) had a higher incidence of mania in their families as compared with those with recurrent depressions only (whom he termed monopolar) [1], a distinction that was validated by the extensive family history studies in the 1960s by Perris, and independently by Angst [2]. The bipolar–unipolar distinction was formally incorporated into the American diagnostic system, DSM. In 1980, the third edition (DSM-III) was subsequently carried forward into DSM-IV, and became explicit in the international classification system in ICD-10. Unfortunately, the structure of DSM-IV (see Figure 1), which breaks out bipolar disorder as a separate illness distinct from all other mood disorders (i.e. from the depressive disorders) obscures the fact that originally the bipolar–unipolar distinction was conceived of as a way to distinguish two forms of a recurrent illness. In other words, the DSM structure gives precedence to polarity over cyclicity, obscuring the reality that one rather common variant of unipolar illness is as recurrent or cyclic as bipolar illness. Furthermore, DSM-IV really has no language for the unipolar patient with frequent recurrences, since its recurrent category is so broad as to include patients with only two depressions in a lifetime, comprising at least 80% of all patients with major depression (Figure 2).
Because cyclicity in DSM-IV-TR is largely restricted to the bipolar category, there is a tendency to include highly cyclic forms of unipolar depression within a bipolar spectrum. While common features can be observed amongst patients with diverse cyclic mood disorders, broadening the definition of bipolar disorder to such a large degree may weaken the core concept of bipolar disorder. It may also de-emphasize some of the important clinical differences between unipolar and bipolar patients. For example, one proposed definition of bipolar spectrum disorder includes recurrent unipolar patients with an early onset of illness who have a family history of bipolar disorder in a first-degree relative [3]. This definition moves beyond the clinical phenomenology of bipolar disorder to a definition based on presumptive genetic vulnerability to elevated mood states.
Clinical features of affective episodes Under the current system, the diagnosis of bipolar disorder is based on symptom presentation and the natural course of the illness. Although progress has been made in advancing our understanding of the neurobiology and genetics of bipolar disorder, we are far from being able to validate the diagnosis and sharpen its boundaries by reference to an identified aetiologic agent or a characteristic pathophysiological abnormality. There are significant challenges associated with using symptoms as a basis for diagnosis. Some patients symptoms may correspond well with published diagnostic criteria, while others are more ambiguous. Over time, debate about what constitutes the core clinical features of mood episodes has been reflected in changing diagnostic criteria in the DSM and ICD. This debate is more than an academic exercise. Because diagnosis guides treatment decisions as well as the composition of research samples, the content of the diagnostic criteria has a profound impact on patient care, as well as on our ability to advance neurobiological and genetic research on mood disorders.
Mania Bipolar Disorder: Clinical and Neurobiological Foundations Edited by Lakshmi N. Yatham and Mario Maj © 2010 John Wiley & Sons, Ltd. ISBN: 978-0-470-72198-8
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Mania represents the primary defining feature of bipolar disorder. Although primary emphasis has been placed on
Clinical Features and Subtypes
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The Diagnosis of Mania as a Percentage of all Admissions to the North Wales Asylum: 1875-1924 60 50 40 30 20 10 0 20
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Fig. 1 DSM-IV classification of mood disorders. Note: NOS ¼ not otherwise specified. Reprinted with permission from Goodwin FK, Jamison KR: Manic Depressive Illness: Bipolar Disorders and Recurrent Depression. New York, NY, Oxford University Press, 2007.
the elevation of mood, Kraepelin described activation of motoric and cognitive processes that can be the more predominant features in some patients. For example, there has been an increasing appreciation for the role of irritability in the absence of euphoria [4]. Accordingly, DSM-IV-TR allows elevated, expansive or irritable mood in the core criterion A of the diagnostic definition (Box 1). While elevated mood is a fairly specific symptom of mania and hypomania, irritability can be more ambiguous because it
is also commonly seen in bipolar depressive episodes [5] and major depressive disorder [6]. Irritability can be defined as extreme reactions to relatively minute stimuli [7], or as a low threshold for experiencing anger in response to negative emotional events [8]. Irritability is particularly prominent in paediatric bipolar disorder, although lacking in specificity [8]. Thus in children irritability is present in a number of common diagnoses including attention deficit hyperactivity disorder, anxiety disorders, and oppositional
Affective Disorders
Depressive Disorders < 3 Episodes; Onset < age 30
Recurrent (Episodic) Affective Disorders > 3 Episodes; Onset < age 30 (Kraepelin’s manic-depressive illness)
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Fig. 2 Recurrence as the primary organizing feature of the affective disorders. Note: BP ¼ bipolar; NOS ¼ not otherwise specified. Reprinted with permission from Goodwin FK, Jamison KR: Manic Depressive Illness: Bipolar Disorders and Recurrent Depression. New York, NY, Oxford University Press, 2007.
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Box 1 DSM-IV-TR Definition of a Manic Episode DSM-IV (p. 328) defines a manic episode as follows: Criterion A: A Manic Episode is a distinct period during which there is an abnormally and persistently elevated, expansive or irritable mood. This period of abnormal mood must last at least one week (or less if hospitalization is required). Criterion B: The mood disturbance must be accompanied by at least three additional symptoms from a list that includes inflated self-esteem or grandiosity, decreased need for sleep, pressure of speech, flight of ideas, distractibility, increased involvement in goal-directed activity or psychomotor agitation, and excessive involvement in pleasurable activities with a high potential for painful consequences. If the mood is irritable (rather than elevated or expansive), at least four of the above symptoms must be present. Criterion C: The symptoms do not meet criteria for a mixed episode. Criterion D: The disturbance must be sufficiently severe to cause marked impairment in social or occupational functioning or to require hospitalization, or it is characterized by the presence of psychotic features. Source: Reprinted with permission from the Diagnostic and Statistical Manual of Mental Disorders, Fourth Edition, Text Revision (Copyright 2000). American Psychiatric Association.
defiant disorder. And, of course, some level of irritability is observed in the course of normal development. Overactivity, defined in the DSM as either increased goal directed activity or psychomotor agitation, is an optional criteria for the diagnosis rather than a core criterion A symptom. A study by Benazzi suggests that overactivity may play a more central role in the diagnosis than the DSMIV-TR organization implies [9]. In a sample of 213 patients, focusing the probing for history of hypomania on overactivity in addition to mood change reduced false-negatives for a bipolar II diagnosis. Using Angsts diagnostic criteria for hypomania [10], which emphasizes overactivity rather than simply elevated mood, and comparing the results to the Structured Clinical Interview for DSM-IV, no significant differences were found between the two samples on age, gender, symptom structure of hypomania, number of episodes, episodes duration and level of functioning. Compared to elevated mood, overactive behaviour may be less vulnerable to the cognitive distortions associated with loss of insight that occurs during manic and hypomanic episodes, and therefore easier for patients to identify. The kind of psychomotor activation which is stereotyped, repetitive and purposeless, such as pacing and fidgeting (i.e. agitation) is, unfortunately, conflated with increased goal directed activity in DSM-IV-TR. Psychomotor agitation is also part of the criteria for major depressive disorder, and this overlap may serve to blur the distinction between the activation of mania and that of depression.
In order to meet the criteria for a manic episode, four or five out of nine criteria must be met. It is not necessary to have all of the symptoms listed, and for each individual patient certain symptoms may be more likely than others to accompany a manic episode. Patients may experience a degree of symptom consistency over the course of consecutive episodes. Capitalizing on this tendency, identifying personally relevant early signs of mania or hypomania is a common ingredient in a number of bipolar-specific psychotherapies, including psychoeducation [11], cognitive behavioural therapy [12], family-focused therapy [13] and interpersonal and social rhythm therapy [14]. These early symptoms, of which decreased need for sleep is a common example, may not be especially pathological in and of themselves. However, because they can be consistent and reliable predictors of serious affective decompensation, systematically documenting the nature of the symptoms, and developing a level of vigilance for their emergence, can create an opportunity for early intervention that may prevent an impending manic episode or decrease its severity. Formally evaluating the consistency of symptoms across episodes can be complex. Effects of medications, such as an antidepressant that can induce or heighten agitation, or a benzodiazepine that modulates the decreased need for sleep, may introduce variance. In addition, the timing of the assessment can lead to the presentation of differing symptoms. Carlson and Goodwin found substantial differences in symptomatology based on the stage of mania during which a subject was evaluated [15]. One study that attempted to control for these potentially confounding factors, evaluated 77 subjects during two discrete manic episodes, which occurred an average of two years apart. The authors reported that four symptom factors as well as manic severity were significantly correlated across episodes. The symptom factors were dysphoria, hedonic activation, psychosis and irritable aggression [16]. Psychotic symptoms that occur in the context of a manic episode may have special status as defining a specific subtype of bipolar disorder. Psychosis is generally associated with more severe symptoms of mania and possibly a less favourable long-term course [17]. The McLean-Harvard First-Episode Mania Study found that psychosis was a predictor of mania recurrence [18], and a recent two-year prospective study conducted in 14 European countries found that psychotic symptoms during the initial presentation predicted poor response to treatment, and chronicity of mania [19].
Depression Despite the predominance of depressive symptoms in bipolar disorder, there has been less quantitative study of the clinical features of bipolar depression than is the case for either mania or nonbipolar depression. Although the
Clinical Features and Subtypes
DSM-IV-TR does not distinguish between unipolar and bipolar depression (Box 2), studies that have compared the two generally find differences in the clinical presentations. The most widely replicated findings point to a picture of bipolar I depressed patients as having more mood lability, psychotic features, psychomotor retardation and comorbid substance abuse. In contrast, the typical unipolar patient in these studies had more anxiety, agitation, insomnia, physical complaints, anorexia and weight loss [20]. However, none of the contemporary studies of unipolar-bipolar differences match the samples for number of previous episodes (i.e. for cyclicity) and only a few even match for age of onset. Indeed, Benazzi has found that when unipolar and
Box 2 DSM-IV-TR Definition of a Major Depressive Episode DSM-IV (p. 320) defines a major depressive episode as follows: Criterion A1: The essential feature of a Major Depressive Episode is a period of at least 2 weeks during which there is either depressed mood or the loss of interest or pleasure in nearly all activities. In children and adolescents, the mood may be irritable rather than sad. The individual must also experience at least four additional symptoms drawn from a list that includes changes in appetite or weight, sleep and psychomotor activity; decreased energy; feelings of worthlessness or guilt; difficulty thinking, concentrating or making decisions; or recurrent thoughts of death or suicidal ideation, plans or attempts. To count towards a Major Depressive Episode, a symptom must either be newly present or must have clearly worsened compared with the persons pre-episode status. The symptoms must persist for most of the day, nearly every day, for at least 2 consecutive weeks. The episode must be accompanied by clinically significant distress or impairment in social, occupational or other important areas of functioning. For some individuals with milder episodes, functioning may appear to be normal, but requires markedly increased effort. The mood in a Major Depressive Episode is often described by the person as depressed, sad, hopeless, discouraged or “down in the dumps”. Criterion A2: Loss of interest or pleasure is nearly always present, at least to some degree. Criterion A3: When appetite changes are severe (in either direction), there may be a significant loss or gain in weight or, in children, a failure to make expected weight gains may be noted. Criterion A4: The most common sleep disturbance associated with a Major Depressive Episode is insomnia. Criterion A5: Psychomotor changes include agitation (e.g. the inability to sit still, pacing, hand-wringing; or pulling or rubbing of the skin, clothing or other objects) or retardation (e.g. slowed speech, thinking and body movements; increased pauses before answering; speech that is decreased in volume, inflection, amount or variety of content, or muteness). Source: Reprinted with permission from the Diagnostic and Statistical Manual of Mental Disorders, Fourth Edition, Text Revision (Copyright 2000). American Psychiatric Association.
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bipolar samples are matched for age of onset, many of the UP-BP differences disappear [21]. In bipolar II depression, some studies have found more atypical features such as hypersomnia, increased appetite, leaden paralysis and interpersonal rejection sensitivity compared to those with unipolar depression [3,22,23], but typically these studies also fail to control for cyclicity and age of onset. Compared to mania, the cumulative impact of syndromal and subsyndromal depression on role functioning is greater [24]. Thus a long-term study that evaluated bipolar patients over the course of 4 years found functional outcome was correlated with depressive but not manic symptoms [25]. Similarly, resource utilization and direct health care costs have been shown to be highest amongst bipolar depressed patients compared to those who were manic or mixed [26]. The impact of depressive symptoms on functioning is seen even in sub-syndromal presentations. In a study of bipolar patients that excluded patients who currently met the full DSM criteria for any acute mood episode, those with higher Hamilton Depression Rating Scale scores had poorer outcomes as measured by the psychosocial components of the Global Assessment of Functioning Scale [27].
Mixed states of bipolar disorder The DSM-IV-TR criteria for a mixed episode require a patient to meet the full criteria for both a manic episode and a major depressive episode (Box 3). Our knowledge of mixed states is more limited than it is for other manifestations of bipolar disorder because patients experiencing mixed episodes are often excluded from studies. This relative lack of knowledge is unfortunate because mixed states occur frequently. Although estimates vary, in one study, 40% of bipolar I inpatient admissions were for mixed episodes [28]. Mixed episodes may evolve from a depressive episode, a manic episode, or the mixed symptoms may emerge at the same time. Patients may also experience mixed symptoms when a bipolar depression is treated with an antidepressant [29]. However, this would fail to meet the strict criteria because symptoms that occur as a direct consequence of the effect of a substance are excluded by the DSM. A mixed episode may evolve into a major depressive episode, but it is uncommon for a mixed episode to become a pure mania. In an early study, patients who presented with a mixed episode accounted for 31% of 84 outpatients with manicdepressive disorder [30]. The mixed states were not associated with illness severity or cycling, but did correlate with sedative abuse and poor response to treatment. Himmelhoch and associates commented that . . .drug abuse (particularly alcohol and sedatives) alters the clinical presentation of manic-depressive swings, and the impact of
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Chapter 2
Box 3 DSM-IV-TR and ICD-10 Definitions of a Mixed Episode DSM-IV (p. 333) defines a mixed episode as follows: Criterion A: A Mixed Episode is characterized by a period of time (lasting at least 1 week) in which the criteria are met both for a manic episode and for a major depressive episode nearly every day. The individual experiences rapidly alternating moods (sadness, irritability, euphoria) accompanied by symptoms of a manic episode and a major depressive episode. The symptom presentation frequently includes agitation, insomnia, appetite dysregulation, psychotic features and suicidal thinking. Source: Reprinted with permission from the Diagnostic and Statistical Manual of Mental Disorders, Fourth Edition, Text Revision (Copyright 2000). American Psychiatric Association.
oversedation or withdrawal or both on a “pure” affective state is to make it dysphoric and mixed. More recently, Goldberg and colleagues, evaluating the long-term effects of substance abuse on the course of bipolar I disorder, also found that substance abuse was more common amongst those who had mixed states [31]. The direction of causality could not be determined from this study. Compared to patients with pure mania, those with mixed mania have been found to have more prior mixed episodes, longer hospitalizations, higher rates of comorbid obsessivecompulsive disorder, and they are more likely to be female [32]. Dilsaver and colleagues found a highly significant difference in suicidality as measured by the Schedule for Affective Disorders and Schizophrenia suicide subscale between patients with pure and mixed mania. Only 1 of 49 manic patients was suicidal, compared to 24 of 44 with mixed mania [33]. One would expect that suicidality in bipolar disorder would be associated with depressed mood. Potential additional risk factors present in a mixed episode include higher levels of energy, impulsivity and irritability. A study of 191 psychiatric inpatients and outpatients confirmed this expectation. Suicidality, as measured by the Scale for Suicidal Ideation, was highest for patients with mixed phase presentations [34]. The Scale for Suicidal Ideation measures various dimensions of suicidality, including self-destructive thoughts or wishes, the extent of the wish to die, the desire to make an actual suicide attempt, and details of any plans. Actual suicide attempts during the index episodes were also measured, and like ideation, attempts were more common in the mixed patients. Suicidality was particularly correlated with hopelessness, which was highest during the mixed phase. It is important to note, however, that suicidality is often a poorly defined construct, and whether it
correlates with or predicts actual suicide is not at all clear. See Chapter 7, Suicide and Bipolar Disorder, for an in-depth discussion of this issue. Some authors have suggested that the DSM-IV-TR definition for a mixed episode is too narrow. Failure to meet the full criteria for a major depressive episode, even by a single symptom, results in a diagnosis of a manic state. However, patients who have prominent sub-syndromal depressive symptoms may differ in clinically important ways from those with pure mania. Consequently, other definitions have been developed. The broadest definition permits the presence of one or more depressive symptoms within a manic episode to be sufficient for diagnosis of a mixed episode [35]. Swann and colleagues, using a broad definition of this nature, found that the depressive symptoms responded poorly to lithium compared to the classic manic symptoms [36]. The depressive manic patients had better outcomes on divalproex. A moderate definition midway between the strict and broad criteria has been proposed, in which a mixed episode would be defined as a full manic presentation with three or more symptoms of depression [37]. Just as limited symptoms of depression can accompany a manic episode, limited symptoms of hypomania may be present during a depressive episode. Although there is no formal DSM-IV-TR category for a patient who is experiencing simultaneous or closely juxtaposed symptoms of depression and hypomania, it appears that it is common. The Stanley Foundation Bipolar Treatment Network prospectively studied more than 900 patients for up to seven years, and evaluated the co-occurrence of depressive and hypomanic symptoms. Amongst all visits in which patients had hypomanic symptoms, 57% met criteria for mixed hypomania defined as Young Mania Rating Scale score of 12 or higher and an Inventory of Depressive Symptomatology–Clinician-Rated Version score of 15 or higher [38]. The specific diagnostic entity, depressive mixed state, has been defined as a major depressive episode plus three or more intra-episodic hypomanic symptoms (DMX3). In a sample of 151 outpatients with major depressive disorder who were presenting with psychoactive drug-free major depressive episode, 23.1% met the criteria for DMX3 [39]. The presence of DMX3 was significantly associated with variables distinguishing bipolar from strictly defined unipolar disorders: younger age at onset; greater recurrence; more atypical features; more bipolar II family history. A number of reports suggest that the number and severity of depressive symptoms during mania or hypomania is a continuous rather than a modal phenomenon. In a study of 37 outpatients, depending on the threshold used, the prevalence of mixed features during a manic or hypomanic episode rose incrementally from 5–73% [40]. Patients who met one of the threshold criteria during a given episode were no more likely than chance to have a similar symptom
Clinical Features and Subtypes
constellation during a subsequent episode. The authors concluded that dichotomizing mania and mixed episodes based on the presence of a predefined number of depressive symptoms was not supported by the data.
Diagnostic subgroups of bipolar disorder Bipolar I In one version of a mood disorder spectrum, bipolar I disorder is at one end while recurrent unipolar major depressive disorder is at the other end. Characterized by manic or mixed episodes, patients with bipolar I disorder experience the highest levels of severity with respect to elevated mood. The National Comorbidity Survey Replication, a nationally representative survey of mental disorders amongst adults in the United States, estimated a lifetime prevalence of bipolar I disorder of 1.0% [41]. Unlike major depressive disorder, which is twice as prevalent in females, the prevalence of bipolar I disorder was approximately equal for males and females (0.8 and 1.1%, respectively). One gender difference that was noted was that men were more likely than women to be initially manic, but overall, both were more likely to have a first episode characterized by depression. The typical age of onset varied from the teens to early 40s, with a mean value of 18.2 years. Patients with bipolar I disorder experience substantial morbidity and mortality, and tend to function below the level of the general population, even in between episodes when mood is euthymic (see Chapter 8: Neurocognition and Bipolar Disorder). During a two-year follow-up of patients hospitalized for a psychotic affective episode (72.6% bipolar I), almost all of the subjects achieved syndromic recovery by the end of the study. However, functional recovery was 2.6 times less likely than syndromal recovery [42]. Most of those recovering syndromally did not recover functionally by two years. Patients who had an older age of onset of their mood disorder were more likely to experience functional recovery than those who were younger when they experienced their first episode, probably reflecting more cumulative time ill. Episodes of psychosis are common, affecting at some time 75% of patients with bipolar I disorder [43]. Psychotic features are most common in mixed presentations and least common during pure depressive episodes [44]. Patients who experience psychotic episodes may represent a distinct phenotype, and there appears to be genetic overlap between these patients and patients with schizophrenia (see Chapter 12: Genetics of Bipolar Disorder).
Bipolar II Bipolar II disorder, first described by Dunner, Gershon and Goodwin [45], is characterized by at least one major depres-
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sive episode with one or more hypomanic episodes, as opposed to the manic or mixed episodes seen in bipolar I disorder. As discussed in the section on hypomania, the criteria are essentially the same as for mania; however, the manifestations are less severe. Patients diagnosed with hypomania do not require hospitalization, are not psychotic, and do not experience marked impairment in social or occupational functioning. Bipolar II disorder is described in DSM-IV-TR, but not in ICD-10. DSM-IV-TR requires hypomanic episodes to last a minimum of 4 days. This durational criterion is largely arbitrary and may not represent the best choice. Reducing the duration to two days increases the sensitivity of diagnosis, and a recent study found no differences in characteristics of patients with bipolar II disorder, whether the two or four day duration was used [46]. Using the two-day minimum duration adequately distinguishes bipolar II patients from those with major depressive disorder based on external validators such as family history and course of illness [47]. Using the more restrictive DSM-IV criteria, the National Comorbidity Survey Replication study estimated that the lifetime prevalence of bipolar II disorder was 1.1%; approximately equal to bipolar I disorder, which was 1% [41] (See Chapter 6: Epidemiology of Bipolar Disorder). The Zurich Study found an additional 2.8% of patients who experienced brief hypomania [48]. In one sample, patients with bipolar II disorder (diagnosed using the two-day duration criterion) comprised approximately half of patients who presented for treatment with a major depressive episode [49]. Bipolar II disorder is sometimes viewed as a milder form of bipolar disorder. However, the cumulative effect of the illness is no less severe than bipolar I disorder. Although mania is characterized by greater symptom intensity than hypomania, bipolar II disorder has a more chronic course, and is associated with greater episode frequency, comorbidity, suicidal behaviour [50], and more time spent depressed [51]. Bipolar II disorder can be difficult to recognize because by definition hypomanic episodes do not cause marked functional impairment. Patients may not identify episodes of hypomania as pathological, or view them as related to episodes of depression. Alternatively, episodes may manifest as brief periods of irritability and agitation, which may not be easily recognized as hypomania. As a result, misdiagnosis is common, especially when a clinician fails to include a member of the family in the intake diagnostic evaluation process. A chart review of 85 patients found that bipolar disorder was misdiagnosed as unipolar depression in 37% of patients who first saw a mental health professional after their first episode of elevated mood [52]. A inpatient study found a similar result. Bipolar disorder was misdiagnosed as unipolar depression in 40% of patients [53]. Family and genetic data suggest that there is a true separation of bipolar I and II into separate categories, as
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Chapter 2
opposed to a more continuous spectrum. Bipolar II disorder clusters within families, and appears to breed true, as evidenced by the finding that bipolar II patients have more bipolar II and unipolar relatives, and fewer bipolar I relatives compared to patients with bipolar I [54,55]. Bipolar II disorder also appears to be phenomenologically stable. In a 10-year follow-up study, only 7.5% of a sample of patients with bipolar II disorder experienced a full manic episode, compared to 66.4% of patients with bipolar I disorder [56]. By far the predominant polarity of bipolar II disorder is depression. A prospective study of the natural history of the weekly symptomatic status of bipolar II patients conducted over more than 10 years found that during times when patients experienced mood symptoms, depression was 39 times more common than hypomania (50.3% vs. 1.3%). Overall, patients were symptomatically ill 53.9% of the weeks studied [46]. A similar result was seen in patients with bipolar I disorder; however the imbalance between symptoms of depression and symptoms of mania or hypomania was not as great. That is, bipolar I patients were symptomatic 47.3% of the weeks, and depressive symptoms were 3.6 times more common than manic/hypomanic symptoms [57]. The greater predominance of depression in bipolar II disorder may contribute to the higher rates of suicidal behaviour seen in this illness. A study of psychiatric inpatients found that a prior history of a suicide attempt and suicide after discharge were more frequent amongst bipolar II patients compared to those with bipolar I disorder [45]. Similar results have been found with outpatients [58] although not all studies agree.
Cyclothymia Cyclothymia, like bipolar II disorder, is characterized by attenuated severity of symptoms in the context of a high degree of chronicity. Patients with cyclothymia experience numerous periods with hypomanic symptoms and periods with depressed symptoms that do not meet the full criteria for a major depressive disorder. Emphasizing chronicity, the diagnostic criteria require that patients are not symptom-free for more than two months at a time. Cyclothymia may be a precursor to other forms of bipolar disorder, rather than a stable diagnostic entity in itself. In a study of the natural course of cyclothymia, 35% developed full syndromal depression, hypomania or mania during drug-free follow-up [59]. Compared to patients with a definite history of mania, cyclothymic patients had milder symptoms of abnormal mood and cognition. Most showed sleep disturbances and fluctuating levels in the quality of work or school productivity. Cyclothymic patients reported periods of irritability or aggressiveness, patterns of frequent shifts in interests or plans, and drug or alcohol abuse.
Episodic promiscuity or extra-marital affairs were reported by 40% of the sample, and 25% reported joining new movements with zeal, followed by subsequent disappointment. Because of the high level of chronicity, it can be difficult to distinguish cyclothymia from personality disorders.
Conclusion The current definitions and classification schemes of bipolar disorder remain a work in progress. While the diagnoses have relatively high inter-rater reliability, there is considerable heterogeneity within each diagnostic category. Recognizing the various manifestations, which may reflect differing positions on a spectrum or alternatively genuine subgroups, can be important to treatment selection as our pharmacologic armamentarium continues to expand. Some mood stabilizing medications may work best in a specific subpopulation of patients with a bipolar diagnosis. Alternatively, some mood stabilizing treatments may be effective in a population that does not meet the current bipolar criteria, but is nevertheless characterized by recurrent affective illness that falls within the broader Kraeplinian manic-depressive conceptualization. As our understanding of this group of disorders continues to evolve, continued development of evidence-based approaches to treatment will require accurate and detailed descriptions of clinical trial samples that go beyond simple diagnosis.
References 1. Leonhard, K. (1957) Pathogenesis of manic-depressive disease. Nervenarzt, 28 (6), 271–272. 2. Angst, J. and Perris, C. (1968) On the nosology of endogenous depression. Comparison of the results of two studies. Arch. Psychiatr. Nervenkr., 210 (4), 373–386. 3. Ghaemi, S.N., Hsu, D.J., Ko, J.Y. et al. (2004) Bipolar spectrum disorder: a pilot study. Psychopathology, 37 (5), 222–226. 4. Ghaemi, S.N., Bauer, M., Cassidy, F. et al. (2008) Diagnostic guidelines for bipolar disorder: a summary of the International Society for Bipolar Disorders Diagnostic Guidelines Task Force Report. Bipolar Disord., 10 (1 Pt 2), 117–128. 5. Deckersbach, T., Perlis, R.H., Frankle, W.G. et al. (2004) Presence of irritability during depressive episodes in bipolar disorder. CNS Spectr., 9 (3), 227–231. 6. Pasquini, M., Picardi, A., Biondi, M. et al. (2004) Relevance of anger and irritability in outpatients with major depressive disorder. Psychopathology, 37 (4), 155–160. 7. Einat, H. (2006) Modelling facets of mania – new directions related to the notion of endophenotypes. J. Psychopharmacol., 20 (5), 714–722. 8. Leibenluft, E., Blair, R.J.R., Charney, D.S. and Pine, D.S. (2003) Irritability in pediatric mania and other childhood psychopathology. Ann. N.Y. Acad. Sci., 1008 (Roots of Mental Illness in Children), 201–218. 9. Benazzi, F. (2007) Testing new diagnostic criteria for hypomania. Ann. Clin. Psychiatr., 19 (2), 99–104.
Clinical Features and Subtypes 10. Angst, J., Gamma, A., Benazzi, F. et al. (2003) Toward a redefinition of subthreshold bipolarity: epidemiology and proposed criteria for bipolar-II, minor bipolar disorders and hypomania. J. Affect. Disord., 73 (1), 133–146. 11. Colom, F., Vieta, E., Reinares, M. et al. (2003) Psychoeducation efficacy in bipolar disorders: beyond compliance enhancement. J. Clin. Psychiatry, 64 (9), 1101–1105. 12. Cochran, S.D. (1984) Preventing medical noncompliance in the outpatient treatment of bipolar affective disorders. J. Consult. Clin. Psychol., 52 (5), 873–878. 13. Miklowitz, D.J., George, E.L., Richards, J.A. et al. (2003) A randomized study of family-focused psychoeducation and pharmacotherapy in the outpatient management of bipolar disorder. Arch. Gen. Psychiatry, 60 (9), 904–912. 14. Frank, E. (2005) Treating Bipolar Disorder: A Clinicians Guide to Interpersonal and Social Rhythm Therapy, The Guilford Press, New York, NY. 15. Carlson, G. A. and Goodwin, F.K. (1973) The stages of mania. A longitudinal analysis of the manic episode. Arch. Gen. Psychiatry, 28 (2), 221–228. 16. Cassidy, F., Ahearn, E.P. and Carroll, B.J. (2002) Symptom profile consistency in recurrent manic episodes. Compr. Psychiatry, 43 (3), 179–181. 17. MacQueen, G.M., Young, L.T., Robb, J.C. et al. (1997) Levels of functioning and well-being in recovered psychotic versus nonpsychotic mania. J. Affect Disord., 46 (1), 69–72. 18. Tohen, M., Zarate, C.A. Jr, Hennen, J. et al. (2003) The McLean-Harvard First-Episode Mania Study: prediction of recovery and first recurrence. Am. J. Psychiatry, 160 (12), 2099–2107. 19. Van Riel, W.G., Vieta, E., Martinez-Aran, A. et al. (2008) Chronic mania revisited: Factors associated with treatment non-response during prospective follow-up of a large European cohort (EMBLEM). World J. Biol. Psychiatry, 9 (4), 313–320. 20. Goodwin, F.K. and Jamison, K.R. (2007) Manic Depressive Illness: Bipolar Disorders and Recurrent Depression, Oxford University Press, New York, NY. 21. Benazzi, F. (2003) Is there a link between atypical and earlyonset “unipolar” depression and bipolar II disorder? Compr. Psychiat., 44 (2), 102–109. 22. Angst, J., Gamma, A., Sellaro, R. et al. (2002) Toward validation of atypical depression in the community: results of the Zurich cohort study. J. Affect. Disord., 72 (2), 125–138. 23. Akiskal, H.S. and Benazzi, F. (2005) Optimizing the detection of bipolar II disorder in outpatient private practice: toward a systematization of clinical diagnostic wisdom. J. Clin. Psychiatry, 66 (7), 914–921. 24. Gitlin, M., Swendsen, J., Heller, T. and Hammen, C. (1995) Relapse and impairment in bipolar disorder. Am. J. Psychiatry, 152 (11), 1635–1640. 25. Bauer, M.S., Kirk, G.F., Gavin, C. and Williford, W.O. (2001) Determinants of functional outcome and healthcare costs in bipolar disorder: a high-intensity follow-up study. J. Affect. Disord., 65 (3), 231–241. 26. Bryant-Comstock, L., Stender, M. and Devercelli, G. (2002) Health care utilization and costs among privately insured
27.
28. 29.
30.
31.
32.
33.
34.
35. 36.
37.
38.
39.
40.
41.
42.
43.
|
15
patients with bipolar I disorder. Bipolar Disord., 4 (6), 398–405. Altshuler, L.L., Gitlin, M.J., Mintz, J. et al. (2002) Subsyndromal depression is associated with functional impairment in patients with bipolar disorder. J. Clin. Psychiatry, 63 (9), 807–811. Kr€ uger, S., Young, L.T. and Br€ aunig, P. (2005) Pharmacotherapy of bipolar mixed states. Bipolar Disord., 7 (3), 205–215. Dilsaver, S.C. and Swann, A.C. (1995) Mixed mania: apparent induction by a tricyclic antidepressant in five consecutively treated patients with bipolar depression. Biol. Psychiatry, 37 (1), 60–62. Himmelhoch, J.M., Mulla, D., Neil, J.F. et al. (1976) Incidence and signficiance of mixed affective states in a bipolar population. Arch. Gen. Psychiatry, 33 (9), 1062–1066. Goldberg, J.F., Garno, J.L., Leon, A.C. et al. (1999) A history of substance abuse complicates remission from acute mania in bipolar disorder. J. Clin. Psychiatry, 60 (11), 733–740. McElroy, S.L., Strakowski, S.M., Keck, P.E. Jr et al. (1995) Differences and similarities in mixed and pure mania. Compr. Psychiat., 36 (3), 187–194. Dilsaver, S.C., Chen, Y.-W., Swann, A.C. et al. (1994) Suicidality in patients with pure and depressive mania. Am. J. Psychiatry, 151 (9), 1312–1315. Valtonen, H.M., Suominen, K., Mantere, O. et al. (2007) Suicidal behaviour during different phases of bipolar disorder. J. Affect Disord., 97 (1–3), 101–107. Marneros, A. (2001) Origin and development of concepts of bipolar mixed states. J. Affect. Disord., 67 (1–3), 229–240. Swann, A.C., Bowden, C.L., Morris, D. et al. (1997) Depression during mania. Treatment response to lithium or divalproex. Arch. Gen. Psychiatry, 54 (1), 37–42. McElroy, S., Keck, P. Jr, Pope, H. Jr et al. (1992) Clinical and research implications of the diagnosis of dysphoric or mixed mania or hypomania. Am. J. Psychiatry, 149 (12), 1633–1644. Suppes, T., Mintz, J., McElroy, S.L. et al. (2005) Mixed hypomania in 908 patients with bipolar disorder evaluated prospectively in the Stanley Foundation Bipolar Treatment Network: a sex-specific phenomenon. Arch. Gen. Psychiatry, 62 (10), 1089–1096. Akiskal, H.S. and Benazzi, F. (2003) Family history validation of the bipolar nature of depressive mixed states. J. Affect. Disord., 73 (1), 113–122. Bauer, M.S., Whybrow, P.C., Gyulai, L. et al. (1994) Testing definitions of dysphoric mania and hypomania: prevalence, clinical characteristics and inter-episode stability. J. Affect Disord., 32 (3), 201–211. Merikangas, K.R., Akiskal, H.S., Angst, J. et al. (2007) Lifetime and 12-month prevalence of bipolar spectrum disorder in the national comorbidity survey replication. Arch. Gen. Psychiatry, 64 (5), 543–552. Tohen, M., Hennen, J., Zarate, C.M. Jr et al. (2000) Two-year syndromal and functional recovery in 219 cases of firstepisode major affective disorder with psychotic features. Am. J. Psychiatry, 157 (2), 220–228. Tohen, M., Waternaux, C.M. and Tsuang, M.T. (1990) Outcome in Mania. A 4-year prospective follow-up of 75 patients
16
44.
45.
46.
47.
48. 49. 50.
51.
|
Chapter 2
utilizing survival analysis. Arch. Gen. Psychiatry, 47 (12), 1106–1111. Dilsaver, S.C., Chen, Y.W., Swann, A.C. et al. (1997) Suicidality, panic disorder and psychosis in bipolar depression, depressive-mania and pure-mania. Psychiatry Res., 73 (1–2), 47–56. Dunner, D.L., Gershon, E.S. and Goodwin, F.K. (1976) Heritable factors in the severity of affective illness. Biol. Psychiatry, 11 (1), 31–42. Judd, L.L., Akiskal, H.S., Schettler, P.J. et al. (2003) A prospective investigation of the natural history of the long-term weekly symptomatic status of bipolar II disorder. Arch. Gen. Psychiatry, 60 (3), 261–269. Benazzi, F. (2007) Testing predictors of bipolar-II disorder with a 2-day minimum duration of hypomania. Psychiatry Res., 153 (2), 153–162. Angst, J. (1998) The emerging epidemiology of hypomania and bipolar II disorder. J. Affect Disord., 50 (2–3), 143–151. Benazzi, F. (1999) Prevalence of bipolar II disorder in atypical depression. Eur. Arch. Psychiatry Clin. Neurosci., 249 (2), 62–65. Vieta, E. and Suppes, T. (2008) Bipolar II disorder: arguments for and against a distinct diagnostic entity. Bipolar Disord., 10 (1 Pt 2), 163–178. Suppes, T. and Dennehy, E.B. (2002) Evidence-based longterm treatment of bipolar II disorder. J. Clin. Psychiatry, 63 (Suppl 10), 29–33.
52. Ghaemi, S.N., Boiman, E.E. and Goodwin, F.K. (2000) Diagnosing bipolar disorder and the effect of antidepressants: a naturalistic study. J. Clin. Psychiatry, 61 (10), 804–808; quiz 809. 53. Ghaemi, S.N., Sachs, G.S., Chiou, A.M. et al. (1999) Is bipolar disorder still under-diagnosed? Are antidepressants overutilized? J. Affect Disord., 52 (1–3), 135–144. 54. Fieve, R.R., Go, R., Dunner, D.L. and Elston, R. (1984) Search for biological/genetic markers in a long-term epidemiological and morbid risk study of affective disorders. J. Psychiatr. Res., 18 (4), 425–445. 55. Coryell, W., Endicott, J., Reich, T. et al. (1984) A family study of bipolar II disorder. Br. J. Psychiatry, 145, 49–54. 56. Coryell, W., Endicott, J., Maser, J.D. et al. (1995) Long-term stability of polarity distinctions in the affective disorders. Am. J. Psychiatry, 152 (3), 385–390. 57. Judd, L.L., Akiskal, H.S., Schettler, P.J. et al. (2002) The longterm natural history of the weekly symptomatic status of bipolar I disorder. Arch. Gen. Psychiatry, 59 (6), 530–537. 58. Goldring, N. and Fieve, R.R. (1984) Attempted suicide in manic-depressive disorder. Am. J. Psychother, 38 (3), 373–383. 59. Akiskal, H.S., Djenderedjian, A.M., Rosenthal, R.H. and Khani, M.K. (1977) Cyclothymic disorder: validating criteria for inclusion in the bipolar affective group. Am. J. Psychiatry, 134 (11), 1227–1233.
CHAPTER
3
The Long-Term Course and Clinical Management of Bipolar I and Bipolar II Disorders Lewis L. Judd1 and Pamela J. Schettler2 1 2
Department of Psychiatry, University of California at San Diego (UCSD), La Jolla, CA, USA Mood Disorders Research Group, Department of Psychiatry, University of California at San Diego (UCSD), La Jolla, CA, USA
Introduction It is surprising that mood disorders, with their fundamental tendency for episodes to recur during the life cycle, have had so few prospective longitudinal studies of their longterm course of illness. Apart from studies by Jules Angst et al. covering 20 years or more of the life span [1,2], most long-term studies of the course of bipolar illness have been derived from the National Institute of Mental Health (NIMH) Collaborative Depression Study (CDS) [3–17]. The vast majority of treatment studies for bipolar disorders are short-term, and until recently have focused primarily on resolution of acute manic episodes. If any follow-up course is examined, it rarely extends beyond two years. Over a decade ago, our research group at the University of California, San Diego, in conjunction with our collaborators from the NIMH CDS, designed a series of studies to describe and delineate the long-term course of mood disorders. Initially, we investigated the long-term course of unipolar major depressive disorder (MDD) [18–20]. We found that unipolar MDD tends to be a chronic lifelong illness, not an illness of single isolated acute major depressive episodes surrounded by long periods of symptom free euthymia. Furthermore, we found that the long-term course of the disorder is expressed symptomatically along a continuum of depressive symptom severity, primarily involving minor, dysthymic and subsyndromal depression. Each increase or decrease in depressive symptom severity, including subsyndromal depressive symptoms, is associated with a progressive and significant increase or decrease in psychosocial impairment [20]. Recovery from a major depressive episode (MDE) with ongoing residual depressive symptoms is associated with significantly faster episode relapse, as well as with a more chronic future course of illness [21,22]. Following our work on unipolar MDD, we designed another series of investigations of patients with bipolar disor-
ders [11–17,23]. The purpose of these studies was to fill the enormous gap in empirical data concerning the long-term course and the life impacts of bipolar I (BP-I) and bipolar II (BP-II) disorders. While findings from these eight peer-reviewed studies have been reported individually in scientific publications, the present chapter afforded an opportunity to compile all of our findings about the long-term symptomatic and episodic course of bipolar I and bipolar II disorders and their associated psychosocial impairment. When first published, our analyses of the weekly symptom status of bipolar CDS patients during up to 20 years of follow-up provided the field with a uniquely detailed and comprehensive picture of the long-termcourseofbipolardisorders.Whilethepresentchapter is primarily based upon our data, we also reference reports by other groups, whose work in this rapidly advancing field of research supports, complements or extends our observations. The findings presented here have strong implications for how bipolar illnesses should be managed over time. Recommendations for this are presented at the conclusion of this chapter.
Methods of the NIMH CDS The data for these publications is derived from the clinical mood disorder cohort of the NIMH CDS [24,25]. This study is unique in that it obtains prospective, naturalistic, systematic, long-term follow-up data on the weekly symptom status of a very large cohort of patients with mood disorders diagnosed using research-based criteria. Patients entered the study in a major affective episode, during a three-year period from 1978 to 1981. Some of these subjects have now been followed for 27 years. Findings reported in this chapter were derived from data extending up to 20 years of followup, with an average of 15 years per subject, for 291 patients with bipolar I or bipolar II disorder.
Subjects Bipolar Disorder: Clinical and Neurobiological Foundations Edited by Lakshmi N. Yatham and Mario Maj © 2010 John Wiley & Sons, Ltd. ISBN: 978-0-470-72198-8
Subjects entered the CDS as inpatients or outpatients at one of five tertiary care centres, while experiencing an active 17
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Chapter 3
affective episode. All of the patients in the CDS were required to be Caucasian (genetic hypotheses were being tested), speak English, have an IQ score of at least 70, and have no evidence of any organic brain syndrome or terminal medical illness. Written informed consent was obtained for participation in the research. Patients in the CDS received a diagnosis using the Research Diagnostic Criteria (RDC) [26], based on Schedule for Affective Disorders and Schizophrenia interviews [27] and on a review of medical records. They were included in the present analysis if they met criteria for bipolar I (definite) or bipolar II (definite or probable) at entry. Since we found no difference in clinical, demographic or follow-up characteristics of patients with bipolar II disorder who had hypomanic episodes lasting 1 week or more (definite BP-II) versus three to six days (probable BP-II) [12], we combined both groups into the BPII cohort. Consistent with DSM-IV criteria [28], we excluded N ¼ 25 patients (6.8%) who had no MDD by the end of follow-up (unipolar manic/hypomanic patients and those with lifetime mania/hypomania plus minor depression/ dysthymia but no MDD). For those patients who switched from unipolar MDD to BP-I or BP-II during follow-up, their data on psychosocial impairment were included, starting from the time of their first lifetime manic or hypomanic episode [15]. Patients who ever met RDC criteria for schizophrenia or schizoaffective disorder were excluded. Interview forms rated with poor or very poor reliability of weekly symptom status or monthly psychosocial impairment were excluded from the analysis (3% of follow-up forms). The resulting analysis sample included 158 patients with BP-I (lifetime MDD and mania) and 133 patients with BP-II (lifetime MDD and hypomania, but no mania). Demographic and clinical characteristics are shown in Table 1.
Weekly psychiatric symptom ratings As described in greater detail elsewhere [11–13], trained professional raters interviewed patients every six months for the first five years and then yearly thereafter, using variations ofthe Longitudinal Interval Follow-up Evaluation (LIFE) [29]. During these semi-structured interviews, chronological memory prompts are used to obtain information on changes in weekly symptom severity for all mood and other mental disorders. This information, supplemented by available medical records, is integrated into weekly Psychiatric Status Ratings that have scale values anchored to diagnostic thresholds for RDC mental disorders. The CDS raters undergo rigorous training, resulting in intraclass correlation coefficients of 0.90 for reliability of psychiatric symptom ratings, 0.95 for recovery from major affective episodes, and 0.88 for subsequent appearance of affective symptoms [29]. For the analyses reported here, each weeks psychiatric symptom ratings for all affective conditions were combined and classified into one of eight mutually exclusive symptom
Table 1 Demographic and clinical characteristics of patients with BP-I and BP-II disorders in the NIMH CDS.
Demographics Age Female Married/Living Together Some College Intake Episode Inpatient Severity – Worst Week Global Assessment Scale (GAS) score Last Available Follow-up (years)
BP-I (N ¼ 158)
BP-II (N ¼ 133)
P Value
Mean (sd) Range % %
38.2 (12.6) 17–79 60.1 44.9
35.2 (12.7) 17–74 67.6 42.1
0.18 0.63
%
60.1
57.1
0.61
% Mean (sd)
88.6 33.6 (10.7)
66.9 37.1 (9.2)
<0.001 0.004
Mean (sd) Range
15.2 (4.7) 2.5–20.0
15.2 (4.9) 2.5–20.0
0.89
0.04
severity categories. These are three levels of severity of symptoms in the pure depressive spectrum, namely major depression (MDD), minor depression/dysthymia (MinD) and subsyndromal depression (SSD); three levels of symptom severity in the pure manic spectrum, namely mania, hypomania (Hyp.) and subsyndromal hypomania (SSH); cycling or mixed polarity (indicating change in polarity or coexistence of both manic and depressive symptoms within a given month); or the asymptomatic status (no affective symptoms, return to usual self). To analyze monthly psychosocial impairment ratings in relation to affective symptom severity and polarity, the weekly symptom status categories were then combined and coded with the most severe level of symptom severity (separately for the depressive and the manic spectrum) that occurred during any week of each one-month period of psychosocial ratings. Based on the worst level of affective symptoms recorded in that month, the entire month was then categorized into one of three levels of pure depressive symptom severity, three levels of pure manic/hypomanic symptom severity, a combination of depressive and manic/hypomanic symptoms, or asymptomatic status (no affective symptoms, return to usual self for the entire month).
Characteristics of the long-term course of bipolar illness In the remainder of this chapter, we summarize our findings about the fundamental characteristics of the long-term
The Long-Term Course and Outcome
course of bipolar I and bipolar II disorders based on the weekly affective symptom status data described above. The chapter ends with recommendations for treatment implications derived from these findings. The remainder of the chapter is organized in the following sections: 1 Chronicity of the Course of Bipolar Illness 2 Dynamic and Changeable Affective Symptom Course of Bipolar Illness 3 Affective Symptom Expression Along a Dimensional Continuum of Symptom Severity 4 Dominance of Affective Symptoms Below Syndromal Threshold of Major Depression and Mania 5 Dominance of Depressive Episodes and Symptoms 6 Psychosocial Impairment Associated with Bipolar Disorders 7 Clinical Importance of Bipolar II Disorder 8 Incomplete Recovery from Major Affective Episodes As a Predictor of Early Episode Relapse/Recurrence 9 Conclusions About the Long-Term Course of Bipolar Illness 10 Implications for the Long-Term Clinical Management of BP-I and BP-II Disorders.
Chronicity of the course of bipolar illness It is generally understood that bipolar disorders, with their repeat episodes, are chronic in nature. However, a unique picture of just how chronic these disorders really are emerged from these studies. As seen from Table 2, the Table 2 Lifetime chronicity of BP-I and BP-II disorders in the NIMH CDS.
Prior to Intake Age of Onset of First Lifetime Affective Episode First Episode before Age 21 Number of Previous Episodes (Including the Intake Episode) During Follow-up % Wks Symptomatic during 20 Yrs of Follow-up Number of Episodes during 10 Yrs after End of Intake Episode
BP-I
BP-II
P Value
Mean (sd) Range
23.6 (10.4) 1–62
22.1 (10.5) 1–64
0.22
%
49.4
53.4
0.50
Median
5.5
5.0
0.52
Mean (sd)
46.6 (34.1)
55.8 (33.1)
0.06
Median
2.5
4.0
0.05
|
19
illness begins early in life, with mean age of onset of first affective episode in the low 20s for both bipolar I and bipolar II disorders, and approximately half the samples experiencing their first affective episode before age 21. Patients entering the CDS with either bipolar disorder had already experienced a median of five separate affective episodes (including the index/intake episode). During the first 10 years of follow-up after the end of the intake episode, patients with bipolar I disorder experienced a median of 2.5 episodes and those with bipolar II disorder experienced a median of four episodes; this difference was marginally significant (P ¼ 0.05). This is consistent with Angst et al.s findings from a 27-year follow-up of a large cohort of patients hospitalized between 1959 and 1963 and evaluated at five-year intervals thereafter [2]. Those authors found that the risk of recurrence of bipolar disorders (0.4 episodes per year) was about twice that of unipolar depressive patients (0.2 episodes per year); that the risk of recurrence was slightly higher for BP-II than for BP-I; and that the risk of recurrence for all groups was constant over the life span, up to the age of 70. A new measure of chronicity, which we have been advocating for the study of both unipolar MDD and bipolar disorder, is the total percentage of weeks when subjects experience any level of affective symptoms from their illness – in other words, the percentage of time the illness is active. Measurement of total time symptomatic, regardless of the symptom severity or whether an individual is in an episode, is a more sensitive measure of illness chronicity than time in episodes, since we have demonstrated that bipolar (and unipolar) patients, even when meeting consensus criteria for recovery, frequently experience subsyndromal affective symptoms [17,21]. As shown in Table 2, patients with bipolar I disorder were symptomatic from their illness during 47% of follow-up weeks and bipolar II patients were symptomatic 56% of the time. It is very clear that bipolar disorders, both BP-I and BP-II, are intensely chronic with the patients being afflicted from the illness approximately half of the time, during up to 20 years of prospectively observed follow-up.
Dynamic and changeable affective symptom course of bipolar illness Angst and his colleagues reported that BP-II patients experience a slightly higher number of episodes per year than BP-I patients [1,2]. In a 2003 paper [14], we confirmed and extended these findings by comparing BP-I and BP-II patients on the number, duration and percentage of weeks spent in each type of affective episode, during a 10-year period after the end of their intake episode. In this study, both bipolar groups spent about 30% of the time in major or minor mood disorder episodes. BP-II patients tended to have more episodes (mean (sd) ¼ 4.2 (2.6) vs. 3.3 (2.5);
20
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Chapter 3
Table 3 Dynamic follow-up course of BP-I and BP-II disorders in the NIMH CDS.
Total Changes in Symptom Status (Changes in Severity and/or Polarity) Changes per Yr Mean (sd) More than % 5 Times per Yr Changes in Symptom Polarity Changes per Yr More than 5 Times per Yr
Mean (sd) %
BP-I
BP-II
5.9 (7.7) 35.6
3.8 (4.9) 22.5
3.5 (7.5) 19.3
1.5 (4.2) 5.6
P ¼ 0.052), including significantly more episodes of MDD and significantly more episodes of minor depression or dysthymia. BP-I patients, on the other hand, had significantly more episodes with cycling/mixed polarity (some depression and some mania/hypomania). During this 10-year period, the duration of each type of episode was slightly (non-significantly) longer for patients with BP-II than for those with BP-I. When data on episode status is supplemented with weekly data on change in the entire spectrum of affective symptom categories, the results show a strikingly high number of changes in symptom status per year for bipolar patients. As seen in Table 3, the mean total number of changes per year in symptom status (symptom severity and/or polarity) is nearly 6 for BP-I patients and approximately 4 for BP-II patients. By contrast, we found that unipolar MDD patients in the CDS changed depressive symptom severity level only
Hyp. 5% SSH 3%
Mania 2% Mixed 6%
Affective symptom expression along a dimensional continuum of symptom severity Over the long-term course, affective symptoms in bipolar disorder are expressed along a dimensional continuum of progressively increasing symptom severity, ranging from subsyndromal, through minor depressive and hypomanic affective symptoms, to symptoms at the full syndromal severity of mania and major depression. Figure 1 shows the percentage of weeks of follow-up that BP-I and BP-II subjects in the CDS spent in each of eight mutually exclusive symptom categories – three levels of depressive symptom severity, three levels of manic/hypomanic symptom severity, symptoms of mixed polarity and the asymptomatic status [13]. BP-I patients were without symptoms of the illness 53% of the time, and BP-II patients were asymptomatic only 44% of the time. This is a striking confirmation of
Hyp. 1% SSH .4%
Mixed 2.5%
MDD 13%
MDD 9% MinD 13%
two times per year [18], corroborating Angsts findings of greater change in bipolar patients compared to unipolar patients [1,2]. Shifts per year in symptom polarity are defined by a patient shifting from symptoms in the depressive spectrum to the manic spectrum or vice versa. On average, BP-I patients change polarity between three and four times per year and BP-II patients change between one and two times per year. Examination of shifts across the entire spectrum of affective symptoms complements the picture of long-term course based on episode status alone, and shows that BP-I is the more dynamic and changeable of the two disorders, while BP-II is characterized by greater chronicity and more frequent episodes. It is noteworthy that a subset of each group suffers from a highly changeable course that could be labelled as rapid cycling. What is presented here is a rather dramatic picture of the changeable and quixotic nature of the naturalistic course of bipolar disorders.
Asymptomatic 53%
Asymptomatic 44% MinD 25%
SSD 9% SSD 14%
Bipolar I
Bipolar II
Fig. 1 Mean percent weeks in each category of affective symptoms during long-term follow-up.
The Long-Term Course and Outcome
the highly chronic nature of BP-II. We found that the great majority of bipolar patients experience the full range of categories of symptom severity of both depressive and manic symptoms during their course of illness. This, combined with the information on changeability of course (above), shows that bipolar patients not only change episode status frequently, but move and flow from one category of symptom severity and polarity to another during the course of their illness. Observing bipolar patients serially or cross-sectionally is like taking a snapshot of an ongoing movie. When seen at one point in time, patients may be in an episode of mania or depression, while at another time they are likely to be experiencing minor or subsyndromal affective symptoms, and at yet another time they may be free of symptoms and euthymic. It is only when the entire, continuous symptomatic course is recorded and analyzed, that a true picture of the long-term symptomatic course of bipolar disorders can be seen.
Dominance of affective symptoms below syndromal threshold of major depression and mania Contained in Table 4 are the mean percent of follow-up weeks at the threshold of major depression or mania versus the mean percent weeks beneath that threshold – that is with symptoms at or below the threshold for minor depression or hypomania. As can be seen, most of the symptomatic course of both BP-I and BP-II disorder is below the syndromal threshold. Even though bipolar disorder is traditionally defined by episodes at the syndromal threshold of major depression or mania, most of the illness occurs over time at a mild or moderate level of affective symptom severity. These data on the dominance of subthreshold symptoms during the course of bipolar illness complement our previous findings, derived from the NIMH Epidemiological Catchment Area (ECA) study [30]. The original authors of the ECA reported that the lifetime prevalence of bipolar I disorder was 0.8%, and bipolar II disorder was 0.5% for
Table 4 Dominance of subthreshold symptoms during long-term follow-up of patients with BP-I and BP-II disorders in the NIMH CDS.
Percent of Wks with Symptoms beneath the Threshold of MDE/Mania Percent of Wks with Symptoms at the Threshold of MDE/Mania Subthreshold/Threshold
BP-I
BP-II
Mean
34.2
43.2
Mean
12.3
12.6
Ratio
<3 : 1
>3 : 1
|
21
a combined lifetime prevalence of bipolar illness of 1.3% [31]. With our reanalysis of the ECA data adding subthreshold hypomanic symptoms [23], the lifetime prevalence figures increased substantially, from 1.3 to 6.4% for the bipolar spectrum. In that study, having had symptoms at the subsyndromal hypomanic level at some time in ones life was found to be associated with significantly greater health service utilization for mental/emotional or substance abuse problems, as well as greater use of welfare and disability benefits. Subsyndromal symptoms are particularly important when they are present during an episode of the opposite polarity. Angst et al. [32] and others [33,34] have pointed out that, in persons with a history of major or even mild depression, subsyndromal hypomanic symptoms are an important indicator of bipolarity that needs to be considered during diagnosis and treatment. Investigators analyzing the NIMH STEP-BD data found that two-thirds of the 1380 subjects presenting with bipolar I or II depressive syndromes also had subsyndromal manic/hypomanic symptoms at intake, and that these were markers for a more severe form of bipolar illness [33]. Further analysis of the STEP-BD data has shown that use of adjunctive antidepressants in these subjects does not speed recovery from the index depression compared to mood stabilizers alone, and it may even increase the severity of the manic symptoms [34].
Dominance of depressive episodes and symptoms As the new picture of the long-term symptomatic course of bipolar illness began to emerge, the high prevalence of depressive episodes and symptoms was very striking. While bipolar illness has traditionally been defined and treated with a focus on the often chaotic episodes of mania, these comprise a relatively small portion of the total symptomatic course of illness. Table 5 shows the percent of weeks during long-term follow-up that bipolar patients in the CDS spent with depressive episodes and symptoms, compared
Table 5 Dominance of depressive episodes and symptoms during long-term follow-up of patients with BP-I and BP-II disorders in the NIMH CDS.
Percent of Wks with Depressive Episodes and Symptoms Percent of Wks with Manic/Hypomanic Episodes and Symptoms Depression/Mania
BP-I
BP-II
Mean
30.6
51.9
Mean
9.8
1.4
Ratio
3:1
37 : 1
22
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Chapter 3
to all weeks with manic/hypomanic episodes and symptoms. The ratio of depression to mania (D:M) in BP-I is approximately 3 : 1. The ratio in BP-II is dramatically different, with approximately 52% of the weeks involving depressive episodes and symptoms and only 1.4% of weeks when BP-II patients experience hypomanic episodes and subsyndromal hypomanic symptoms – resulting in a ratio of depressive to hypomanic symptom spectrum of 37 : 1. This provides compelling data supporting the conclusion that BP-I is primarily a depressive illness and that BP-II is almost exclusively a chronic depressive illness. This is interesting, since most of the scientific effort in the study of bipolar disorder has focused on the management of manic or mixed polarity symptoms, with far less attention to depressive episodes and symptoms. It is an important fact that depression is far more prevalent during the course of bipolar illness. Other investigators have documented the importance of depression in the long-term course of BP-I disorder. Turvey et al. [10] found that individual CDS patients with BP-I tended to have consistency across prospectively observed episodes in terms of their starting polarity, that episodes beginning with major depression were significantly longer than those beginning with mania, and that patients whose first prospectively observed episode began with depression had a significantly worse follow-up course. More recently, the 10-year McLean-Harvard First Episode Project & International Consortium for Bipolar Disorder Research found that most early morbidity after first lifetime onset of bipolar I disorder is associated with depression, and that initial depression or mixed states predict more depressive symptoms and greater overall morbidity during subsequent follow-up [35]. Coryell et al. recently reported [36] that early onset age predicts greater depressive morbidity in BP-I patients during CDS follow-up, and that depressive symptoms increasingly predominate as individuals move through their third, fourth and fifth decades of BP-I illness.
Psychosocial impairment associated with bipolar disorders Data summarized in this section are from the first investigation that we are aware of, studying psychosocial impairment associated with every level of affective symptom severity, as well as periods of euthymia in a large cohort of BP-I and BP-II patients followed prospectively for many years [15]. In Figure 2, mean ratings of global psychosocial impairment associated with various symptom status categories are presented. Results were generated by mixed regression analysis, used to model the relationship between monthly psychosocial ratings and the severity and polarity of affective symptoms within those months, as individual patients experience different symptom status categories
during long-term follow-up. The height of the bars represents mean level of impairment, and the error bars represent the 95% confidence intervals of those means, from the mixed regression analysis. As clearly conveyed in Figure 2, affective symptom severity and psychosocial disability fluctuate together during the course of bipolar illness. As we found for unipolar MDD [20], every stepwise increase or decrease in depressive symptom severity is associated with a corresponding significant, stepwise increase or decrease in psychosocial impairment in both BP-I and BP-II disorders. When subjects with either disorder have no mood disorder symptoms, no impairment is present and psychosocial functioning is rated as good. When the same patients are experiencing subsyndromal depressive symptoms, they have mild impairment; during months with symptoms at the level of minor depression or dysthymia, their psychosocial impairment is rated between mild and moderate; and when bipolar patients are experiencing symptoms at the syndromal threshold of major depression, their psychosocial functioning is rated as moderately impaired. Even subsyndromal depressive symptoms are associated with significantly more impairment than the asymptomatic (euthymic) status, for both BP-I and BP-II disorder. There is a similar picture of stepwise increases in psychosocial impairment associated with stepwise increases in manic symptom severity, for patients with BP-I disorder. By contrast, for those with BP-II disorder, hypomanic and subsyndromal hypomanic symptoms are not associated with significant increases in psychosocial impairment, and may even enhance psychosocial function. This is consistent with Akiskals and others findings that minimal disability, and possibly even enhanced psychosocial functioning, frequently occurs during subsyndromal and syndromal hypomanic periods of bipolar II disorder, which may make it difficult to diagnose hypomania [37–40]. Figure 2 also conveys that depressive symptoms, which have been seen to dominate the course of both bipolar disorders, are at least as disabling as symptoms of comparable severity in the manic/hypomanic spectrum. Data from these studies shows that much of the psychosocial disability associated with BP-I and BP-II is derived from symptoms in the depressive spectrum. This is in striking contradiction to the traditional view that mania and manic symptoms are more disabling than depression. The figure further shows that within each level of depressive symptom severity, BP-II is associated with a level of psychosocial impairment comparable to BP-I disorder. These findings again underscore the importance of depressive symptoms in BP-II. What should be very encouraging to all is the fact that when affective symptoms are abated and the patient with either BP-I or BP-II is asymptomatic, no psychosocial impairment is noted and the patients function is rated as normalized.
The Long-Term Course and Outcome
Mean Global Impairment Rating
Asymptomatic
Marked
5
Depressive Spectrum
|
23
Manic Spectrum
Patients with Bipolar I Disorder (N=158)
Impairment
4
Moderate Impairment
3
Mild Impairment
2
No Impairment
1 Asympt.
Mean Global Impairment Rating
5
SSD SSH
MinD Hypom.
MDD Mania
Patients with Bipolar II Disorder (N=133)
Marked Impairment
4
Moderate Impairment
3
Mild Impairment
2
No Impairment
1 Asympt.
SSD SSH
MinD Hypom.
Clinical importance of bipolar II disorder Bipolar II disorder is generally considered to be the lesser of the two bipolar subtypes and some think it is of little clinical significance; as a result, it not treated as often as it should be. Findings presented here provide strong evidence that these impressions of BP-II disorder are incorrect. CDS subjects with BP-II were symptomatic during 56% of weeks during an average of 15 years of follow-up; this is evidence of even greater symptomatic chronicity than for patients with BP-I disorder, who were symptomatic during 47% of weeks in their long-term course. Furthermore, BP-II patients spent approximately the same mean percentage of follow-up weeks at the full syndromal threshold of MDE as BP-I patients spent with MDE/mania [mean (sd) ¼ 12.6 (15.9) vs. 12.3 (14.6); P ¼ 0.834]. They also spent significantly more weeks with symptoms of minor depression/dysthymia or hypomania [mean (sd) ¼ 27.0 (23.3) vs. 20.1 (21.2); P ¼ 0.036]. In our study comparing the episodic course of BP-I and BP-II patients in the CDS [14], we found that those with BP-II had significantly longer intake episodes (P < 0.001), and 18% even had psychotic symptoms. They also had marginally more episodes during follow-up (P ¼ 0.052),
MDD
Fig. 2 Mean global impairment rating at each level of affective symptom severity (single polarity months).
including significantly more episodes of MDD and minor depression/dysthymia (P < 0.001 for both). Patients with BP-II disorder experienced depressive symptoms during more than half of follow-up weeks, and depressive symptoms outweighed the percent of hypomanic symptoms in a ratio of 37 : 1 (compared to a ratio of 3 : 1 for patients with BP-I disorder). This is notable because all levels of depressive symptoms, as indicated in the last section, are associated with significant psychosocial impairment. When we examined psychosocial disability averaged across all ill and well periods during the long-term course of illness for patients with BP-I and BP-II disorders [16], the mean levels of global disability for the two bipolar groups were identical and reflected a mild level of impairment. Both groups experienced some degree of impairment during nearly 60% of months during follow-up (58.3% for BP-I; 59.1% for BP-II), which included moderate to severe impairment during 30% of long-term follow-up (31.3% for BPI; 30.3% for BP-II). Impairment for both bipolar groups was slightly higher than for unipolar MDD patients (53.8% of months with some impairment, including 25.8% with moderate to severe impairment during long-term follow-up).
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We did not find any difference in BP-II disorder defined on the basis of hypomanic episodes that are longer (7 days or more) compared to shorter (from two to six days) [12]. We and others [32,39] have suggested that hypomanic episodes of either duration are part of the same disease process. Despite the evidence that bipolar II disorder is a real disorder, with its intensely chronic and depressive nature and its association with significant psychosocial impairment, treatment of BP-II tends to be overlooked [13]. Table 6 provides cogent data on somatic treatment by symptom severity and polarity categories. Within 5 of 7 symptom categories, including the asymptomatic status when patients often require maintenance treatment for prophylaxis of future episodes, CDS patients with BP-II disorder were prescribed somatic treatment significantly less often than those with BP-I disorder. This was the case even during periods when patients were experiencing symptoms at the level of major depression; BP-II patients were treated only half the time, compared to three-quarters of the time for patients with BP-I during MDE periods. Data presented here clearly shows that bipolar II disorder is not the lesser of the two bipolar subtypes, but is a serious and intensely depressive disorder in its own right, and warrants the same level of clinical management that is given to bipolar I disorder.
Incomplete recovery from major affective episodes as a predictor of early episode relapse/recurrence We previously reported that the presence of ongoing residual subsyndromal depressive symptoms following recovery from a MDE in unipolar MDD patients, although meeting the consensus definition of recovery, is associated with significantly faster episode relapse/recurrence when
Table 6 Mean percent of weeks with any prescribed somatic treatment for BP-I vs. BP-II disorder, by affective symptom category during long-term follow-up. Affective Symptom Category
BP-I
BP-II
P Value
Levels of Depressive Severity Subsyndromal Depressive Symptoms Minor Depression/Dysthymia Major Depressive Disorder
75.9% 77.2% 76.0%
51.9% 56.9% 60.4%
<0.001 <0.001 0.003
Levels of Hypomanic Severity Subsyndromal Hypomania Hypomania
91.1% 80.7%
53.3% 55.3%
0.003 0.068
Cycling/Mixed Polarity Symptoms (All Levels of Severity)
79.9%
58.8%
0.137
Asymptomatic Status (Prophylaxis)
73.7%
43.5%
<0.001
compared to full asymptomatic recovery [21,22]. We hypothesized that the same would be true in bipolar illness – namely, that residual affective symptoms seen following resolution of major affective episodes in bipolar patients would also be associated with significantly faster relapse/ recurrence of the next major affective episode. Similar to our unipolar MDD papers [21,22], recovery for our investigation in the bipolar cohort [17] also followed the current consensus definition of eight or more consecutive weeks asymptomatic or with minimal residual affective symptoms. However, dividing recovery into these two levels, we found (Figure 3) that those bipolar patients recovering from their intake MDE/manic episodes with residual affective symptoms experienced a subsequent major affective episode over five times faster than asymptomatic recoverers (median 24 weeks vs. 123 weeks, respectively; p < 0.001). We also found that those whose recovery was marked by residual affective symptoms had a significantly more chronic and severe future course. Recovery status (asymptomatic vs. residual symptoms) proved to be the strongest correlate of time to major affective episode relapse/recurrence for the bipolar cohort (p < 0.001), followed by a history of three or more affective episodes before intake (p ¼ 0.007). No other variable of the 13 examined was significantly associated with time to relapse/recurrence, once the Bonferroni correction was applied. We concluded that in bipolar disorder, the presence of residual symptoms after the resolution of a major affective episode indicates that the individual is at significant risk for rapid relapse and/or recurrence, strongly suggesting that the illness is still active. Recently, a panel of experts in bipolar disorder proposed a standardized set of definitions for patient status for use in clinical trials [41]. These include remission, defined as having no or only minimal symptoms of the affective episode for one week, and sustained remission, defined as maintaining this status for eight consecutive weeks. Our finding that recovery with residual affective symptoms predicts much faster episode relapse in unipolar [21,22] and bipolar [17] patients, however, argues for a stricter definition of episode remission based on achieving abatement of all symptoms of the episode. Berk et al. [42] re-analysed data from four pharmacologic treatment studies using a definition of remission based on achieving a Clinical Global Impression-Bipolar Version (CGI-BP) severity score of 1 (representing normal, not at all ill). Compared to the current consensus definition of recovery, which allows minimal affective symptoms to be present, these authors conclude that the stricter definition of remission, while more difficult to attain, is more clinically meaningful. We fully agree and have been advocating this since 1998 [21]. The minimum time (number of consecutive weeks) at this status needed to define a stable state of recovery needs to be determined through empirical study, and may be as short as four weeks. A stable recovery state in bipolar disorder,
Cumulative % of Subjects Remaining Free of Major Affective Episode Relapse/Recurrence
The Long-Term Course and Outcome 100
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25
Asymptomatic Recovery (N = 163) Recovery with Residual Affective Symptoms (N = 60)
75
50
Median Weeks Well
(95% Confidence Interval)
123
(89 - 179)
24
(19 - 31)
25
0
0
200
400
600
800
1000
Weeks from End of Intake MDE/Mania to Next Major Affective Episode Wilcoxon Chi Square = 35.81; P < 0.0001; Hazard Ratio = 3.36 (95% CI = 2.25 - 4.98) Judd et al., Arch Gen Psychiatry, 2008
we believe, is achieved only when the asymptomatic status is reached for a sufficient period of time for the patient to be free of risk for relapse into the previous syndromal episode.
Conclusions about the long-term course of bipolar illness From these data, we conclude that bipolar illness disorders are chronic, primarily lifelong illnesses, with strong tendencies for relapse and recurrence of major and minor affective episodes. Syndromal level episodes are interspersed with euthymic periods, during which subsyndromal symptoms are often present. The long-term symptomatic expression of bipolar disorders is dimensional in character, along a continuum of depressive and manic/hypomanic symptom severity. Affective symptoms beneath the threshold of mania and major depression dominate the course of bipolar disorders on a 3 : 1 basis. Psychosocial impairment changes in a step-wise fashion with each increase or decrease in depressive symptom severity in either bipolar I or bipolar II disorder, and with each increase or decrease in manic symptom severity in bipolar I disorder. When patients are completely without symptoms (asymptomatic), psychosocial impairment is no longer seen and the patients psychosocial function normalizes and is rated as good. The longterm course of bipolar disorders is very dynamic and changeable, with patients frequently moving from one level of symptom severity to another and from one polarity to another. Depressive episodes and symptoms dominate the course of BP-I (3 : 1 ratio) and BP-II (37 : 1 ratio). Although both bipolar disorders are primarily depressive in nature, bipolar II disorder is fundamentally a chronic depressive illness. As such, BP-II is not merely the lesser of the two bipolar disorders, but is a more serious illness than previ-
Fig. 3 Comparison of asymptomatic versus residual symptom recovery on time to next major affective episode (N ¼ 223 patients with bipolar I or bipolar II disorder). Reprinted from Judd et al., Arch Gen Psychiatry 2008; 65(4):386–394. Copyright (2008) American Medical Association. All rights reserved.
ously thought. Asymptomatic recovery from major affective episodes is associated with a significantly longer delay in episode relapse or recurrence, as well as a more benign future course of illness. The methodology of our studies, which takes into account the full range of affective symptom severity and polarity on a weekly basis, should be considered by other researchers interested in studying the long-term course of bipolar and unipolar disorders. Collection of such prospective data by trained clinical raters, using empirically established semistructured interviews such as the LIFE [29], not only provides the basis for accurate identification of the start and end of all types of affective episodes (including those below the syndromal level of MDE and mania), but also provides a complete picture of the true illness burden associated with all levels of affective symptoms, during and between episodes. The empirical findings on the long-term course of bipolar illness summarized here suggest certain principles for effective long-term clinical management strategies. These are the focus of the final section of this chapter.
Implications for the long-term clinical management of BP-I and BP-II disorders There are scores of studies presenting useful empirical data on a wide variety of pharmacological agents, and combinations of agents, used to treat acute bipolar episodes; these have been summarized in recent review papers [43,44]. Early studies focused primarily on the treatment of mania [45], but as the predominance of depression that we have reported [11–13] has gained acceptance, controlled medication trials increasingly address the treatment and prevention of bipolar episodes of depression as well [46–48],
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including mixed polarity episodes consisting of depression with concurrent subsyndromal manic/hypomanic symptoms [33]. Most of these studies are concerned with pharmacological agents to treat BP-I. It has generally been assumed that depression in BP-II responds to the same agents used to treat depression in BP-I, and that hypomania is likely to respond to the same agents that are used for mania. Recently, controlled studies have begun to be conducted examining medication effectiveness for BP-II [49]. The NIMH CDS, on which this chapter is largely based, is a naturalistic study, not a controlled treatment investigation. Some studies have examined the impact of particular classes of medication on course and outcome for unipolar [50–52] and bipolar [53–55] patients in the CDS. However, conclusions about medication selection, dosage schedules and medication combinations should be drawn with caution and confirmed only through reports of controlled clinical trials. By naturalistic is meant that patients were followed systematically while on and off medications, which were given according to the standards and protocols at each of the five academic centres where they entered the CDS in 1978 through 1981, or practices at other facilities where they received treatment during 20 years of follow-up. Somatic treatments throughout this time were systematically recorded, along with the frequency of various types of talk therapy and any periods of hospitalization. Treatments given are likely to be consistent with the best available clinical practices at the particular time and would have changed as new medications, and combinations of medications, came into use. There is little doubt that modern psychopharmacology, with its increasing numbers of mood stabilizing medications to treat bipolar illness, has revolutionized the management of these serious disorders. It has made these devastating illnesses into treatable diseases and it is no longer necessary for bipolar patients to spend significant parts of their lifetime hospitalized. Findings about the long-term course of bipolar disorders, developed using the unique CDS database, highlight the need for certain approaches to the clinical management of bipolar disorders. In the remainder of this chapter we outline a series of therapeutic strategies and health system requirements for effectively treating bipolar patients and supporting those closest to them. As many clinicians have already discovered, these therapeutic principles are proving very useful for controlling and managing these difficult, potentially devastating, chronic disorders, and for normalizing patients functioning and well-being.
Paradigm shift from acute to chronic disorders The first and perhaps most important treatment implication based on the CDS data presented here is the shift from understanding bipolar disorders as a series of acute, isolated affective episodes, to the recognition that they are
fundamentally chronic, lifelong illnesses. This necessitates a paradigm shift in the overall approach to managing bipolar disorders. We have established that, while patients with BP-I or BP-II disorder spend only 12 or 13% of longterm follow-up at the syndromal level of MDE or mania, they are symptomatic from their illnesses and psychosocially impaired during over half of their course of illness. This underscores the inherently chronic nature of bipolar illness. Recognizing the chronicity of these disorders is the first step to realizing that patients need to be treated with long-term treatment strategies such as those used for type II diabetes, chronic coronary artery disease and so on. Similarly, chronic illnesses such as BP-I and BP-II also require long-term chronic treatment strategies.
Principles for the long-term clinical management of bipolar disorders Following is a series of suggestions based on the data we have reported here, outlining strategies for how bipolar illness can best be managed throughout the patients life cycle. It is beyond the scope of this chapter to provide a comprehensive review of the large number of important medication and psychosocial treatment studies for bipolar disorder. Rather, we have referenced selected studies that are relevant to specific treatment recommendations: 1 Provide accurate, evidence-based information on the clinical characteristics and treatment of bipolar illness. It is essential, at the very beginning of treatment, to initiate an educational programme for patients, spouses, families and significant others concerning the clinical characteristics of bipolar illness, including its chronicity and very strong tendencies for episode relapse and recurrence. Special emphasis should be placed on identifying early warning signs or symptoms that may usher in an impending affective episode, together with the need to contact the clinician at the first appearance of these signs. We have noted that bipolar patients often move from an asymptomatic status to an active illness state, with progressive increases in affective symptom severity. Often, a given patient will experience the same unique symptom or set of symptoms as a precursor to each impending episode. Care should be taken by the clinician to identify the signal symptoms for each individual patient, and the patient needs to be instructed to contact the attending clinician as soon as possible when the signal symptoms appear. In addition, the process of education provides an ideal opportunity to create a treatment team made up of the clinician (as leader), the bipolar patient and willing significant others – all of whose goal is to restore and maintain full recovery for the patient. It is essential for those on the team to maintain open communication about the patients status, help monitor treatment adherence and provide support during times of crisis and other difficulties (see No. 5 below, on clinical monitoring, for details).
The Long-Term Course and Outcome
2 The necessity for strict adherence to the therapeutic regimen prescribed should be emphasized to patients, spouses, family members and significant others. It is paramount to highlight to the patient and all concerned the need for scrupulous adherence to the prescribed treatment regimens, both medication and psychosocial, thatare needed for effective treatment during both short-term and long-term management phases of the bipolar disorder. The necessity of complying with all recommended treatments should be clearly explained and discussed with the patient and significant others, so they can understand the importance of these approaches for reducing acute symptoms, stabilizing patients and maximizing their psychosocial functioning and well-being, together with preventing future episodes. 3 Explain the need for extended long-term medication regimens. We and others have found it useful to conceptualize the treatment of mood disorders, including bipolar disorders, in terms of different phases of treatment: First, acute treatment is aimed at amelioration of acute symptoms of the index episode. Second, continuation treatment extends beyond symptom resolution of the index episode, and is aimed at preventing return of the index episode (relapse), as well as achieving a stable state of recovery of at least four weeks asymptomatic, if possible. Third, the maintenance phase of treatment is focused on prevention of future new episodes (recurrence), as well as elimination of psychosocial dysfunction and impaired sense of wellbeing that is associated with even the most minor subsyndromal symptoms. The medications used (singly or in combination) during these treatment phases, along with their dosage schedule, need to be individually tailored to each patient. In deciding what medications to prescribe, clinicians need to consider the latest published research findings as well as the patients current symptom status, previous clinical history (including their patterns of cyclicity and risk for depressive vs. manic relapse), their past and current medication response, and their experience of adverse side effects. In some cases it is advisable to continue or maintain the patient indefinitely on the same medication(s) and at the same dosage that proved effective for achieving resolution of their acute episode [56]. 4 Combined treatment with medication and adjunctive psychosocial intervention is optimum. It is becoming increasingly recognized that bipolar disorders typically pose enormous short-term and long-term challenges for patients and their families, despite the best available medication regimens [35,57]. Recently, a considerable body of evidence has been building, demonstrating the effectiveness of psychosocial intervention programmes for improving both acute and long-term outcomes in bipolar illness [58–70]. At a recent roundtable [65], experts in the field concluded that, as with other chronic mental disorders, an integrated approach is best, which includes individualized programmes of psychosocial intervention (such as cogni-
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27
tive-behavioural therapy, interpersonal and social rhythm therapy, and family therapy), along with extended longterm medication regimens. These combined approaches are effective during acute, continuation and maintenance phases of treatment. The main psychosocial intervention modalities for which there is currently some empirical evidence include the following: cognitive-behavioural therapy, which is focused on assisting patients in modifying dysfunctional cognitions and behaviours; interpersonal and social rhythm therapy, which is aimed at improving interpersonal role and occupational functioning, and regularizing daily biological and social rhythms; and family therapy, which aims at reducing high levels of stress and conflict within the patients family and teaching effective strategies for coping with bipolar disorder. Another modality, group psychoeducation, provides a forum for sharing accurate, evidence-based information on the clinical characteristics and course of bipolar disorders, available treatment strategies and the necessity for strict adherence to the prescribed treatment. It is also an ideal opportunity to organize and empower the treatment team (clinician, patient, family and significant others), which has proven invaluable in helping to monitor the bipolar patient and keep them episode and symptomfree. From recent reviews of controlled clinical trials on psychosocial interventions for treatment of bipolar disorders [62,64–67], it now appears that specific psychosocial intervention modalities are most effective, depending on the time when they are introduced (acute, continuation or maintenance treatment phase), the clinical status of the patient, the past history of episode polarity and the presence of comorbid conditions. These efforts are promising and await results of further randomized controlled clinical trials confirming or extending these early observations. In the meantime, it is recommended that integrated pharmacological and psychosocial therapies be used for BP-I and BP-II during all three phases of treatment, with the specific modalities selected and applied based upon the most recent publications in this rapidly expanding area of research. 5 Clinical monitoring should be available on a regular ongoing basis. It is important for physicians who are caring for bipolar patients to maintain contact with those patients, even though they may appear to be euthymic and doing well during certain periods. Regular contact is necessary to evaluate current clinical status, adherence to treatment and patients psychosocial well-being. There should be clear two-way communication between the clinician and patient to address questions about medication compliance, dosage adjustments and any adverse side effects, along with checking to see whether the patient needs booster sessions of their psychosocial treatment. An effective treatment team is indispensable for maintaining this communication. Many academic centres have organized mood disorder clinics, where knowledgeable clinicians or case managers maintain
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Chapter 3
frequent contact with the patient and other members of the treatment team to monitor patients clinical status and early signs of impending affective episodes. It is not sufficient to treat the bipolar patient for an acute affective episode, then discharge them with instructions to return if bipolar symptoms recur. A necessary component of the long-term maintenance strategy consists of ongoing contact, careful clinical monitoring and management, and a partnership within the entire treatment team to keep the patient well and functioning optimally. 6 Treat affective episodes and symptoms to their full symptom abatement. The presence of ongoing residual affective symptoms following recovery from a major affective episode, even though it meets consensus criteria for remission, has now been shown to be associated with early episode relapse and a less benign future course of illness [17,21,22]. This indicates that the illness is still active and that until all symptoms of the index episode are fully resolved, the episode is not yet over. These findings support the idea that the optimal goal for treatment of bipolar episodes, as for unipolar MDD, should be to eliminate all residual affective symptoms, restore good psychosocial function, and achieve a sustained state of full recovery. 7 Treat depressive episodes and symptoms with equal priority and rigour as manic episodes and symptoms. Until recently, most of the clinical and research emphasis in bipolar disorders has been on the treatment of acute manic episodes. We have provided evidence here that the course of BP-I and BP-II is largely depressive. Since we published these findings [11–13], recent reports have addressed medication issues specifically for controlling the depressive phases of bipolar disorder [46–48]. As data about the highly depressive course of bipolar illness becomes more widely disseminated, we anticipate that there will be increased numbers of treatment studies focusing on bipolar depression. 8 Treat bipolar II with the same priority and rigour as bipolar I disorder. These studies underscore both the clinical importance and the disabling nature of bipolar II disorder, together with the fact that it is treated significantly less often than bipolar I disorder, even at the same levels of affective symptom severity. Bipolar II disorder is equally impairing as bipolar I disorder, because of its intensely chronic and depressive nature [16]. Patients with bipolar II disorder deserve and need equal therapeutic priority and the same methodical treatment rigour as those with bipolar I disorder, throughout their lifetime.
Summary of the expanded goals for the long-term management of bipolar disorders The first step in the treatment of patients with bipolar disorders is to ameliorate the severe symptoms of an acute affective episode. To this we now add the need to treat even
residual symptoms of the episode to their full abatement, where possible. Our findings about the chronicity of bipolar disorders underscore the importance of ongoing clinical monitoring and long-term maintenance treatment to prevent affective episode relapse and recurrence, as well as the need to treat even minor and subsyndromal affective symptoms in order to reduce the overall chronicity of the illness. Our findings of psychosocial impairment associated with all levels of affective symptom severity highlight the treatment goal of restoring bipolar patients to their optimal level of psychosocial functioning. In summary, the focus of treatment has shifted from the reduction of severe symptoms of acute episodes, to maintaining patients as symptom-free and optimally functioning as possible throughout their lifetime.
References 1. Angst, J. and Preisig, M. (1995) Course of a clinical cohort of unipolar, bipolar and schizoaffective patients. Results of a prospective study from 1959 to 1985. Schweiz Arch. Neurol. Psychiatr., 146, 5–16. 2. Angst, J., Gamma, A., Sellaro, R. et al. (2003) Recurrence of bipolar disorders and major depression. A life-long perspective. Eur. Arch. Psychiatry Clin. Neurosci., 253, 236–240. 3. Coryell, W., Keller, M., Endicott, J. et al. (1989) Bipolar II illness: course and outcome over a five-year period. Psychol. Med., 19, 129–141. 4. Keller, M.B., Lavori, P.W., Coryell, W. et al. (1993) Bipolar I: a five-year prospective follow-up. J. Nerv. Ment. Dis., 181, 238–245. 5. Winokur, G., Coryell, W., Keller, M. et al. (1993) A prospective follow-up of patients with bipolar and primary unipolar affective disorder. Arch. Gen. Psychiatry, 50, 457–465. 6. Winokur, G., Coryell, W., Akiskal, H.S. et al. (1994) Manicdepressive (bipolar) disorder: the course in light of a prospective ten-year follow-up of 131 patients. Acta Psychiatr. Scand., 89, 102–110. 7. Coryell, W., Endicott, J., Maser, J.D. et al. (1995) Long-term stability of polarity distinctions in the affective disorders. Am. J. Psychiatry, 152, 385–390. 8. Coryell, W., Turvey, C., Endicott, J. et al. (1998) Bipolar I affective disorder: predictors of outcome after 15 years. J. Affect. Disord., 50, 109–116. 9. Turvey, C.L., Coryell, W.H., Solomon, D.A. et al. (1999) Longterm prognosis of bipolar I disorder. Acta Psychiatr. Scand., 99, 110–119. 10. Turvey, C.L., Coryell, W.H., Arndt, S. et al. (1999) Polarity sequence, depression, and chronicity in bipolar I disorder. J. Nerv. Ment. Dis., 187, 181–187. 11. Judd, L.L., Akiskal, H.S., Schettler, P.J. et al. (2002) The longterm natural history of the weekly symptomatic status of bipolar I disorder. Arch. Gen. Psychiatry, 59, 530–537. 12. Judd, L.L., Akiskal, H.S., Schettler, P.J. et al. (2003) A prospective investigation of the natural history of the long-term weekly symptomatic status of bipolar II disorder. Arch. Gen. Psychiatry, 60, 261–269.
The Long-Term Course and Outcome 13. Judd, L.L., Schettler, P.J., Akiskal, H.S. et al. (2003) Long-term symptomatic status of bipolar I vs. bipolar II disorders. Int. J. of Neuropsychopharm., 6, 127–137. 14. Judd, L.L., Akiskal, H.S., Schettler, P.J. et al. (2003) The comparative clinical phenotype and long-term longitudinal episode course of bipolar I and II: a clinical spectrum or distinct disorders? J. Affect. Disord., 73, 19–32. 15. Judd, L.L., Akiskal, H.S., Schettler, P.J. et al. (2005) Psychosocial disability in the course of bipolar I and II disorders: a prospective, comparative, longitudinal study. Arch. Gen. Psychiatry, 62, 1322–1330. 16. Judd, L.L., Schettler, P.J., Solomon, D.A. et al. (2008) Psychosocial disability and work role function compared across the long-term course of bipolar I, bipolar II and unipolar major depressive disorders. J. Affect. Disord., 108, 49–58. 17. Judd, L.L., Schettler, P.J., Akiskal, H.S. et al. (2008) Residual symptom recovery from major affective episodes in bipolar disorders and rapid episode relapse/recurrence. Arch. Gen. Psychiatry, 65, 386–394. 18. Judd, L.L., Akiskal, H.S., Maser, J.D. et al. (1998) A prospective 12-year study of subsyndromal and syndromal depressive symptoms in unipolar major depressive disorders. Arch. Gen. Psychiatry, 55, 694–700. 19. Judd, L.L.,and Akiskal, H.S., (2000) Delineating the longitudinal structure of depressive Illness: beyond clinical subtypes and duration thresholds (Anna-Monika-Prize paper). Pharmacopsychiatry, 33, 3–7. 20. Judd, L.L., Akiskal, H.S., Zeller, P.J. et al. (2000) Psychosocial disability during the long-term course of unipolar major depressive disorder. Arch. Gen. Psychiatry, 57, 375–380. 21. Judd, L.L., Akiskal, H.S., Maser, J.D. et al. (1998) Major depressive disorder: a prospective study of residual subthreshold depressive symptoms as predictor of rapid relapse. J. Affect. Disord., 50, 97–108. 22. Judd, L.L., Paulus, M.J., Schettler, P.J. et al. (2000) Does incomplete recovery from first lifetime major depressive episode herald a chronic course of illness? Am. J. Psychiatry, 157, 1501–1504. 23. Judd, L.L. and Akiskal, H.S. (2003) The prevalence and disability of bipolar spectrum disorders in the U.S. population: reanalysis of the ECA database taking into account subthreshold cases. J. Affect. Disord., 73, 123–131. 24. Katz, M.M. and Klerman, G.L. (1979) Introduction: overview of the Clinical Studies Program. Am. J. Psychiatry, 136, 49–51. 25. Katz, M.M., Secunda, S.K., Hirschfeld, R.M. and Koslow, S. H. (1979) NIMH Clinical Research Branch Collaborative Program on the Psychobiology of Depression. Arch. Gen. Psychiatry, 36, 765–771. 26. Spitzer, R.L., Endicott, J. and Robins, E. (1977) Research Diagnostic Criteria for a Selected Group of Functional Disorders, 3rd edn, Biometrics Research Division, New York State Psychiatric Institute, New York. 27. Spitzer, R.L. and Endicott, J. (1979) Schedule for Affective Disorders and Schizophrenia (SADS), 3rd edn, Biometrics Research Division, New York State Psychiatric Institute, New York.
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28. American Psychiatric Association (1994) Diagnostic and Statistical Manual of Mental Disorders: DSM-IV, 4th edn, American Psychiatric Association, Washington, DC. 29. Keller, M.B., Lavori, P.W., Friedman, B. et al. (1987) The Longitudinal Interval Follow-up Evaluation: a comprehensive method for assessing outcome in prospective longitudinal studies. Arch. Gen. Psychiatry, 44, 540–548. 30. Regier, D.A., Myers, J.K., Kramer, M. et al. (1984) The NIMH Epidemiologic Catchment Area (ECA) Program: historical context, major objectives and study population characteristics. Arch. Gen. Psychiatry, 41, 934–941. 31. Regier, D.A., Farmer, M.E., Rae, D.S. et al. (1990) Comorbidity of mental disorders with alcohol and other drug abuse. Results from the Epidemiologic Catchment Area (ECA) Study. JAMA, 264, 2511–2518. 32. Angst, J., Gamma, A., Benazzi, F. et al. (2003) Toward a redefinition of subthreshold bipolarity: epidemiology and proposed criteria for bipolar-II, minor bipolar disorders and hypomania. J. Affect. Disord., 73, 133–146. 33. Goldberg, J.F., Perlis, R.H., Bowden, C.L. et al. (2009) Manic symptoms during depressive episodes in 1.380 patients with bipolar disorder: findings from the STEP-BD. Am. J. Psychiatry, 166, 173–181. 34. Goldberg, J.F., Perlis, R.H., Ghaemi, S.N. et al. (2007) Adjunctive antidepressant use and symptomatic recovery among bipolar depressed patients with concomitant manic symptoms: findings from the STEP-BD. Am. J. Psychiatry, 164, 1348–1355. 35. Salvatore, P., Tohen, M., Khalsa, H.M. et al. (2007) Longitudinal research on bipolar disorders. Epidemiol. Psichiatr. Soc., 16, 109–117. 36. Coryell, W., Fiedorowicz, J., Solomon, D. and Endicott, J. (2009) Age transitions in the course of bipolar I disorder. Psychol. Med., 39, 1247–1252. 37. Akiskal, H.S. and Akiskal, K. (1988) Re-assessing the prevalence of bipolar disorders: clinical significance and artistic creativity. Psychiatrie et Psychobiologie, 3, S29–S36. 38. Akiskal, H.S., Bourgeois, M.L., Angst, J. et al. (2000) Reevaluating the prevalence of and diagnostic composition within the broad clinical spectrum of bipolar disorders. J. Affect. Disord., 59 (suppl 1), S5–S30. 39. Akiskal, H.S. (2002) Classification, diagnosis and boundaries of bipolar disorders, in Bipolar Disorder (eds M. Maj, H.S. Akiskal, J.J. Lopez-Ibor and N. Sartorius), John Wiley & Sons, London, pp. 1–52. 40. Jamison, K.R., Gerner, R.H., Hammen, C. and Padesky, C. (1980) Clouds and silver linings: positive experiences associated with primary affective disorders. Am. J. Psychiatry, 137, 198–202. 41. Hirschfeld, R.M., Calabrese, J.R., Frye, M.A. et al. (2007) Defining the clinical course of bipolar disorder: response, remission, relapse, recurrence, and roughening. Psychopharmacol. Bull., 40, 7–14. 42. Berk, M., Ng, F., Wang, W.V. et al. (2008) The empirical redefinition of the psychometric criteria for remission in bipolar disorder. J. Affect. Disord., 106, 153–158. 43. CME Institute of Physicians Postgraduate Press, Inc. (2008) Easing the burden of bipolar disorder: from urgent situations
30
44.
45.
46.
47. 48.
49. 50.
51.
52.
53.
54.
55.
56.
57.
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to remission. Prim. Care Companion J. Clin. Psychiatry, 10, 391–402, [also available on-line at psychiatrist.com]. Fountoulakis, K.N. and Vieta, E. (2008) Treatment of bipolar disorder: a systematic review of available data and clinical perspectives. Int. J. Neuropsychopharmacol., 11, 999–1029. Grunze, H., Vieta, E., Goodwin, G.M. et al. (2009) The World Federation of Societies of Biological Psychiatry (WFSBP) guidelines for the biological treatment of bipolar disorders: update 2009 on the treatment of acute mania. World J. Biol. Psychiatry, 10, 85–116. Bowden, C.L. (2005) A different depression: clinical distinctions between bipolar and unipolar depression. J. Affect. Disord., 84, 117–125. Bowden, C.L. (2005) Treatment options for bipolar depression. J. Clin. Psychiatry, 66 (Suppl 1), 3–6. Kemp, D.E., Muzina, D.J., McIntyre, R.S. and Calabrese, J.R. (2008) Bipolar depression: trial-based insights to guide patient care. Dialogues Clin. Neurosci., 10, 181–192. Benazzi, F. (2007) Bipolar II disorder: epidemiology, diagnosis and management. CNS Drugs, 21, 727–740. Dawson, R., Lavori, P.W., Coryell, W.H. et al. (1998) Maintenance strategies for unipolar depression: an observational study of levels of treatment and recurrence. J. Affect. Disord., 49, 31–44. Leon, A.C., Keller, M.B., Warshaw, M.G. et al. (1999) Prospective study of fluoxetine treatment and suicidal behavior in affectively ill subjects. Am. J. Psychiatry, 156, 195–201. Leon, A.C., Solomon, D.A., Mueller, T.I. et al. (2003) A 20-year longitudinal observational study of somatic antidepressant treatment effectiveness. Am. J. Psychiatry, 160, 727–733. Coryell, W., Winokur, G., Solomon, D. et al. (1997) Lithium and recurrence in a long-term follow-up of bipolar affective disorder. Psychol. Med., 27, 281–289. Coryell, W., Solomon, D., Leon, A.C. et al. (1998) Lithium discontinuation and subsequent effectiveness. Am. J. Psychiatry, 155, 895–898. Coryell, W., Arndt, S., Turvey, C. et al. (2001) Lithium and suicidal behavior in major affective disorder: a case-control study. Acta Psychiatr. Scand., 104, 193–197. Kupfer, D.J., Frank, E., Perel, J.M. et al. (1992) Five-year outcome for maintenance therapies in recurrent depression. Arch. Gen. Psychiatry, 49, 769–773. Solomon, D.A., Keitner, G.I., Miller, I.W. et al. (1995) Course of illness and maintenance treatments for patients with bipolar disorder. J. Clin. Psychiatry, 56, 5–13.
58. Keller, M.B. (2004) Improving the course of illness and promoting continuation of treatment of bipolar disorder. J. Clin. Psychiatry, 65 (Suppl 15), 10–14. 59. Frank, E., Kupfer, D.J., Thase, M.D. et al. (2005) Two-year outcomes for interpersonal and social rhythm therapy in individuals with bipolar I disorder. Arch. Gen. Psychiatry, 62, 996–1004. 60. Swann, A.C. (2005) Long-term treatment in bipolar disorder. J. Clin. Psychiatry, 66 (Suppl 1), 7–12. 61. Miklowitz, D.J. and Johnson, S.L. (2006) The psychopathology and treatment of bipolar disorder. Annual Rev. Clin. Psychol., 2, 199–235. 62. Miklowitz, D.J. (2006) A review of evidence-based psychosocial interventions for bipolar disorder. J. Clin. Psychiatry, 67 (Suppl 11), 28–33. 63. Miklowitz, D.J., Otto, M.W., Frank, E. et al. (2007) Intensive psychosocial intervention enhances functioning in patients with bipolar depression: results from a 9-month randomized controlled trial. Am. J. Psychiatry, 164, 1340–1347. 64. Soares-Weiser, K., Bravo Vergel, Y., Beynon, S. et al. (2007) A systematic review and economic model of the clinical effectiveness and cost-effectiveness of interventions for preventing relapse in people with bipolar disorder. Health Technol. Assess., 11, iii–iv, ix–206. 65. Keck, P.E. Jr, McIntyre, R.S. and Shelton, R.C. (2007) Bipolar depression: best practices for the outpatient. CNS Spectr., 12 (Suppl 20), 1–14. 66. Sachs, G.S. (2008) Psychosocial interventions as adjunctive therapy for bipolar disorder. J. Psychiatr. Pract., 14 (Suppl 2), 39–44. 67. Miklowitz, D.J. (2008) Adjunctive psychotherapy for bipolar disorder: state of the evidence. Am. J. Psychiatry, 165, 1408–1419. 68. Frank, E., Soreca, I., Swartz, H.A. et al. (2008) The role of interpersonal and social rhythm therapy in improving occupational functioning in patients with bipolar I disorder. Am. J. Psychiatry, 165, 1559–1565. 69. Solomon, D.A., Keitner, G.I., Ryan, C.E. et al. (2008) Preventing recurrence of bipolar I mood episodes and hospitalizations: family psychotherapy plus pharmacotherapy versus pharmacotherapy alone. Bipolar. Disord., 10, 798–805. 70. Colom, F., Vieta, E., Sanchez-Moreno, J. et al. (2009) Group psychoeducation for stabilised bipolar disorders: 5-year outcome of a randomised clinical trial. Br. J. Psychiatry, 194, 260–265.
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4
Comorbidity in Bipolar Disorder: A Focus on Addiction and Anxiety Disorders Mark A. Frye1 and Giulio Perugi2 1 2
Department of Psychiatry and Psychology, Mayo Clinic, Rochester, MN, USA Department of Psychiatry, University of Pisa; Institute of Behavioural Sciences G. De lisio, Carrara, Italy
Introduction Bipolar affective disorder is an illness with substantial morbidity and mortality, characterized by episodic recurrence of mania/hypomania and major depression. Our current DMS- IV TR and ICD-10 based diagnoses have operationalized criteria for the specific diagnosis of bipolar I, II, and not otherwise specified with delineating course specifiers and subtype patterns. As recently reviewed by Soreca et al. [1], these criteria fail to capture the dimensional aspects and multisystem involvement of bipolar disorder. Mulitsystem or comorbid symptoms and disease, not defined as core or primary symptoms related to mood disorder, are highly prevalent and clinically relevant in the management of bipolar disorder. Two comorbid conditions that are the focus of this chapter, substance use, particularly alcohol and nicotine dependence, and anxiety disorders, clearly impact the course of bipolar illness.
Alcohol abuse and dependence Since the Kraepelian observation nearly 90 years ago [2], contemporary epidemiologic studies, including the Epidemiologic Catchment Area (ECA) study, the National Comorbidity Study (NCS), the National Comorbidity SurveyReplication (NCS-R) and the National Epidemiological Survey on Alcohol and Related Conditions (NESARC), have reported rates of alcohol abuse or dependence in bipolar disorder that are consistently higher than the general population and/or most other axis I disorders [3–8]. A subscale analysis of the ECA study [3] remarkably showed that BPI and BPII populations had the highest lifetime prevalence rate of alcohol abuse or dependence (46.2 and 39.2%, respectively) followed by schizophrenia (33.7%), panic disorder (28.7%), unipolar depression (16.5%) and the general
Bipolar Disorder: Clinical and Neurobiological Foundations Edited by Lakshmi N. Yatham and Mario Maj © 2010 John Wiley & Sons, Ltd. ISBN: 978-0-470-72198-8
population (13.8%). A lifetime diagnosis of alcohol dependence was associated with significantly increased risk of having mania in both men (Odds ratio ¼ 12.03) and women (Odds ratio ¼ 5.3) [4]. These epidemiological studies suggest that some aspect of bipolar disorder, in comparison to other serious mental illness, is associated with high rates of developing alcoholism. Clinical studies done over the past 50 years [9–13] have confirmed similar lifetime prevalence rates (8–42%). It is important to emphasize that careful assessment for dual diagnosis, ideally with a structured diagnostic interview, is critical to confirm the comorbidity. The diagnosis of bipolar illness in the presence of active substance use, in this case alcohol abuse or dependence, can be made in any or all of the following criteria: (1) the presence of a historical manic, hypomanic or depressed episode while not drinking (DSM-IV early partial or complete remission); (2) a manic, hypomanic or depressed episode that predated the onset of alcohol abuse or dependence; and (3) a manic, hypomanic or depressed episode with high moderate to severe mood symptoms with minimal drinking [14]. This is relevant as a recent study by Stewart and colleagues [15] recently examined clinical diagnoses of bipolar disorder in 21 patients participating in a community-based substance treatment programme and found only 9 out of 21 were found to have concordance with a structured diagnostic interview. A second retrospective analysis by Goldberg and associates [16], of records of 85 adults admitted to a private dual disorders chemical dependency programme, found that only 33% of individuals with suspected bipolar diagnoses actually met DSM-IV criteria, utilizing a structured diagnostic interview. Careful assessment needs to be done to confirm the dual diagnosis. Despite high prevalence rates of alcoholism in bipolar disorder, gender and specific mood state analyses have received less contemporary systematic study. As originally described by Kraepelin in 1921, alcoholism could be found in about a quarter of men with bipolar disorder but it is to be
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regarded as the consequence of debaucheries committed in excitement, not as a cause. These initial reports underscore the observation that drinking tends to be associated with acute mania. Dipsomania was also a clinical description of increased alcohol consumption during mania [17]. As most of these early studies focused predominantly on male inpatients at VA hospitals, very little is known about bipolar outpatients and bipolar women and mood state dependent drinking behaviour. In more contemporary samples, gender differences in prevalence rate, relative risk and clinical correlates of alcohol dependence in bipolar disorder have been reported. In clinical samples, gender differences in prevalence rate, relative risk and clinical correlates of alcohol dependence in bipolar disorder have been reported. Compared to bipolar men, bipolar women have an increased odds ratio of developing alcohol abuse or dependence compared to gender matched controls [18]. Compared to bipolar alcoholic men, bipolar alcoholic women have increased illness burden characterized by mixed mania, depressive episodes, polarity shifts, less time spent euthymic [18,19], history of physical and/or sexual abuse [20], increased anxiety burden including social phobia, post-traumatic stress disorder [21,22], higher rates of incarceration [23] and a greater number of maximum drinks in a 24-hour period (HallFlavin 2008 [24]). Any and all of these clinical correlates may be the reason that bipolar women do not seek medical attention for the substance use disorder. From the NESARC study, the lifetime prevalence of substance use disorders in bipolar disorder was significantly greater amongst those women with lifetime anxiety disorders; this increased risk was not identified in bipolar men [25]. Whereas it is generally known that women are more likely to seek help than men, the health care utilization pattern of bipolar I men and women with alcohol dependence appears to be different. In a second NESARC post-hoc analysis, bipolar I disorder is more likely to go untreated in men, and addiction treatment is more likely to go untreated in bipolar women. This differential pattern of gender and health care utilization in dual diagnosis patients will be relevant in how we clinically monitor patients in initial diagnostic assessment and longitudinal follow-up. Future studies should be developed to better understand and correct the under-utilization of addiction programmes for patients with bipolar disorder and to identify clinical correlates that predispose bipolar women to binge drinking.
Comorbid alcoholism and bipolar course of illness It is increasingly clear that co-occurring alcohol use disorders in bipolar disorder phenomenologically changes the illness presentation. As reviewed by [26], bipolar patients
with co-occurring alcohol use disorders in comparison to bipolar patients without co-occurring alcohol use disorders have higher rates of mixed or dysphoric mania, rapid cycling, increased manic and depressed symptom severity, and higher levels of novelty seeking, suicidality, aggressivity and impulsivity. Whatever the aetiology of the association, it is apparent that substance use may precede formal symptoms of bipolar illness and subsequently complicate the bipolar course of illness. A case controlled study by Black et al. [27] reported that patients with complicated mania (mania accompanied with an antecedent or current nonaffective psychiatric disorder, including alcohol abuse) were significantly less likely to both obtain a therapeutic trial of lithium during hospitalization for mania and achieve recovery at hospital discharge. Poor lithium outcome measures have been consistently reported when bipolar disorder is comorbid with current substance use of even a history of alcoholism ([13,28–30]; Keller et al., 1986 [31]). Interestingly, the Aagaard and Vestergaard study is the only one that identified substance use disorders as predictive of noncompliance, but not non-response. Thus, to date, it is unclear whether the lithium non-responsivity in co-occurring bipolar disorder and alcohol abuse/dependence is related to: (4) lack of aggressive mood stabilization such that subsyndromal symptoms are being self treated with alcohol; (5) side-effect intolerability promoting medication non-compliance and relapse; (6) solely non-compliance promoting relapse; or (7) the high prevalence rate of rapid cycling and dysphoric mania, which by itself, can present with higher rates of lithium failure. Further studies are needed to better identify risk factors of relapse (mood and/or alcohol) and whether, in addition to mood stabilization prophylaxis, aggressive treatment for bipolar illness can be a prophylaxis against alcohol abuse relapse.
Treatment implications for dual diagnosis bipolar disorder and alcoholism Despite landmark epidemiological studies highlighting extensive comorbidity between alcohol use disorders and bipolar disorder, recent retrospective data would suggest that patients with bipolar disorder represent the minority of patients (3%) in residential alcohol addiction treatment (Hall Flavin et al., unpublished data). These findings are similar to secondary analyses of the NESARC survey that reported that subjects with bipolar I (12.5%) and bipolar II (3%) disorder were a minority representation of subjects who sought treatment for their alcohol use disorder within the past year [32]. Individuals with undiagnosed, unstable or untreated bipolar disorder may be less motivated or viewed as less favourably to successfully engage and benefit
Comorbidity in Bipolar Disorder
from the specialized addiction treatment. Also, access to primary chemical dependency treatment services may be less available because of programme availability or reimbursement issues. It may also be that most chemical dependency treatment programmes, even those targeting the need of those with substantial psychiatric comorbidity, require a degree of behavioural stabilization that may decrease the likelihood of intervention in a chemical dependency setting during a period of acute decompensation, when substance use might be at its peak. Despite a high prevalence rate, patients with bipolar disorder and active alcohol abuse/dependence are routinely excluded from controlled clinical trials, leaving clinicians with little evidence-based medicine or randomized controlled studies to guide treatment. This routine exclusion may be related in part to the difficulties of confirming a diagnosis of bipolar disorder in the context of active drinking, but as well may be due to a lack of hypothesis-driven study designs or a lack of validated assessment tools to reliably quantify patterns of alcohol use.
Nicotine dependence The morbidity and mortality of smoking-related illnesses are substantial. Cigarette smoking is the leading preventable cause of illness and premature death in the United States. This public health problem is only magnified in patients with major mental illness and in particular in patients with bipolar disorder. The National Comorbidity Survey (NCS) reported a 1990–1992 prevalence rate of nicotine dependence amongst individuals with bipolar disorder more than twice (69 vs. 29%) that of the general population [33]. In the more recent 2001–2002 NESARC study, the 12-month prevalence rate of nicotine dependence in patients with bipolar I (35%) and II (33%) disorder was more than three-fold higher than the 12.8% prevalence rate in patients with no psychiatric comorbidity (OR 3.9 BPI, OR 3.5 BPII [7]. It is estimated that dually diagnosed nicotine dependent patients comprise more than 40% of the US tobacco market. The NCS and NESARC landmark epidemiological studies would suggest that while the prevalence of tobacco use has decreased over the course of a decade, the decrease has been less substantial in the bipolar patient population. The NCS quit rate for nicotine dependent patients without additional mental illness was 43%; the quit rate for bipolar disorder was significantly reduced at (17%) and was the lowest of all Axis I diagnoses (panic disorder ¼ 41%, major depression ¼ 38%, dysthymia ¼ 37%, alcohol abuse or dependence ¼ 34%, social phobia ¼ 33%, generalized anxiety disorder ¼ 33%, drug abuse or dependence ¼ 32%, post-traumatic stress disorder ¼ 28%). These reason that patients with bipolar disorder are not benefitting from smoking cessation therapies in the same
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way as the general population or other anxiety disorders is not known.
Bipolar disorder course of illness and nicotine dependence Nicotine impacts the course of bipolar illness in such a way where the illness is more virulent and less response to mood treatment interventions. Bipolar patients with nicotine dependence, in comparison to bipolar patients without nicotine dependence, have higher rates of mixed episodes, suicide attempts, rapid cycling, additional drug and alcohol comorbidity, greater severity of mood symptoms, and lower rates of response to mood stabilizing pharmacotherapy [34–36]. Despite the severity of mania and smoking rates as high as 70% [37], it is clear that when bipolar patients are symptomatic of their illness, they are far more likely to be depressed than manic [38,39]. In comparison to acute mania, bipolar depressive episodes are longer and more likely to be functionally disabling [40]. Recent data would suggest higher rates of hazardous drinking in bipolar patients when depressed (Abulseoud et al., 2008 [41]). To our knowledge, this phenomenon has not been systematically studied with tobacco dependence. Finally, there is increasing recognition that sub-syndromal bipolar depression (significant symptoms but not meeting DSM-IV criteria for major depressive episode) are not only a prodrome to syndromal relapse [37], but they themselves are highly prevalent and functionally disabling [38]. Moreover, subsyndromal depressive symptoms have consistently predicted poorer outcomes in smoking cessation trials (Niaura et al., 2001 [112]). The NCS and NESARC landmark epidemiological studies would suggest that while the prevalence of tobacco use has decreased over the course of a decade, the decrease has been less substantial in the bipolar patient population. This clearly has significant public health implications. It is likely that the presence of nicotine dependence plus limited access to preventative medical services may put bipolar patients at greater risk for cancer. There has been very little systematic study in this regard, but one linkage analysis based on a psychiatric inpatient diagnosis of bipolar disorder and a cancer national database, did report a significant increased standardized incidence ratio (SIR) for cancer in both bipolar women (SIR ¼ 1.75, 95% CI ¼ 1.31 to 2.18) and bipolar men (SIR ¼ 1.59, 95% CI 1.01 to 2.17, [42]). Furthermore, at least one Swedish registry study has reported increased standardized mortality ratios (SMR ¼ observed deaths/expected deaths) for respiratory death in bipolar men (3.1) and women (3.2), respectively [43]. While many of these excess deaths may be directly related to infection, it is generally assumed that these are preventable smokingrelated deaths (i.e. lung cancer, chronic obstructive pulmonary disease).
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Treatment considerations in bipolar disorder with nicotine dependence There has been remarkable progress in developing therapeutic interventions for patients with tobacco dependence [44]. Currently, there are three pharmacotherapies approved by the US Food and Drug Administration (FDA) for smoking cessation: nicotine replacement systems (gum, patch, nasal spray, inhaler and lozenge), sustained release bupropion or Zyban (aminoketone antidepressant also approved for major depression and seasonal affective disorder) and varenicline or Chantix (a4b2 nicotinic acetylcholine receptor partial agonist). According to the Public Health Service-sponsored Clinical Practice Guideline on treatment of tobacco dependence, counselling and behavioural therapies are considered the standard of care for smoking cessation treatment (SCT) [45]. These behavioural interventions have been shown to be effective in combination with smoking cessation pharmacotherapy in the general population [45–48]. In November 2007, the FDA issued an early communication on post-marketing surveillance reports of suicidal thinking associated with varenicline. In February 2008, the FDA issued an alert highlighting revisions to the Warning and Precaution section of the Chantix package insert. These changes are described as neuropsychiatric symptoms and included: behaviour change, agitation, depressed mood, suicidal ideation, and attempted and completed suicide. Most of these symptoms occurred during treatment but in some cases, symptoms developed following withdrawal of varenicline. These surveillance data cannot establish direct cause and effect. To date, there is one case report each for a vareniclineassociated manic and hypomanic episode [49,50]. A recent National Health Service pre-post comparison of abstinence rates by [51] reported 4-week abstinence rates that were higher with varenicline therapy than nicotine replacement therapy. Varenicline was equally effective in those with and without mental illness. In this study of more than 400 subjects, 27% of them (111) reported they were currently receiving treatment for mental illness. Of those, the primary diagnosis were depression (n ¼ 64), bipolar disorder (n ¼ 14), pyschosis (n ¼ 7), psychotic depression (n ¼ 24) and eating disorder (n ¼ 2). This is important preliminary data, suggesting that abstinence rates are similar if not better and that there are no significant adverse events of higher rate in mentally ill dually diagnosed nicotine dependent patients. SCTs need to be developed and optimized for the dually diagnosed. To date, there are no controlled evaluations of any SCT amongst patients with bipolar disorder. Furthermore, the trials of varenicline and other smoking-cessation clinical trials have excluded individuals with bipolar disorder. However, as compared to the general population, smoking cessation has been reported to be more difficult for
many individuals with psychiatric illness [52,53]. This may in part be related to mood symptoms and that for some patients, nicotine is acting as antidepressant. There is preclinical and clinical data documenting that cigarette smokers have reduced monoamine oxidase (MAO) activity [54]; this could potentially be optimized through MAO inibition (i.e. pharmacological mechanism of action of the several antidepressants, such as tranylcopromine or phenelzine). Several [55–57], but not all [58,59] studies in unipolar depression have reported a significant occurrence of depression following smoking cessation; the occurrence of depression seems to be related to a history of prior depressive episodes, persistent withdrawal symptoms and more difficulty with cessation. This has not been studied in bipolar disorder. Comorbidity of bipolar disorder and alcohol use disorder and nicotine dependence is a common clinical presentation and presents with significant challenges. The bipolar course of illness phenomenologically changes when addiction is present. Further work is encouraged to study these specific patterns (i.e. rapid cycling, dysphoric mania) and aetiology of comorbidity directionality (primary vs. secondary drug use) in controlled clinical trials. The question yet to be answered is whether an earlier and/or accurate diagnosis of bipolar disorder can prevent or at least attenuated the degree of subsequent addiction comorbidity or whether bipolar symptoms at onset that are diagnosed and treated can in fact attenuate or minimize the development of addiction comorbidity as a later manifestation of bipolar illness and the impact of self-medication.
Anxiety disorders Epidemiological, clinical and familial studies provide compelling evidence that anxiety disorders (ADs) may be the most prevalent psychiatric comorbidity amongst patients with Bipolar Disorder (BPD). Moreover, anxious comorbidity in individuals with BPD is associated with an intensification of symptoms, increased risk of alcohol and drug abuse, inadequate treatment response, poor functional outcome and suicidality.
Epidemiological and clinical data The reliability of lay interviewers diagnosing ADs in community-based samples is well established, while the reliability of identifying BPD cases with a predominantly mixed/dysphoric presentation is not ideal with the currently available diagnostic interviews [6,60]. Clinical studies indicate that AD comorbidity may be more prevalent in mixed and softer expressions of BPD (or bipolar spectrum) [61–63], suggesting that community-based epidemiological studies may underestimate the prevalence of AD comorbidity in BPD subpopulations.
Comorbidity in Bipolar Disorder
Chen and Dilsaver [64], analysing the ECA database, reported lifetime rates of OCD amongst probands with bipolar and unipolar disorder of 21.0 and 12.2%, respectively. Furthermore, a significant association between comorbid OCD and suicidality was reported. In the NCS [5,65], the estimated lifetime prevalence of any AD in BPD was estimated at 92.9% (odds ratio, OR ¼ 31.2). Specific phobia was the most prevalent AD comorbidity (66.6%). while Panic Disorder (PD) was the least prevalent (33.1%). The reported risk of comorbid PD and Social Phobia (SoP) is higher in BPD (Odds Ratios of 11.0 vs. 4.6, respectively) compared to unipolar disorder (Odds Ratios of 7.0 vs. 3.6, respectively). In a European sample, (Angst, 1998 [113]) reported higher rates of comorbidity with PD, SoP and Obsessive-Compulsive Disorder (OCD) in subjects meeting DSM-IV hypomania, recurrent brief hypomania and sporadic brief hypomania compared to population controls. In summary, results from community-based epidemiological studies indicate that respondents screening positive for BPD are also more likely to screen positive for an AD. The co-occurrence of AD in BPD populations is associated with suicidality and possibly an earlier age of onset of bipolar illness. Concerning clinical studies, several investigations have reported on the prevalence of ADs amongst bipolar patients. Rihmer et al. [66] described the prevalence of AD comorbidity amongst 2953 primary care patients with a diagnosable mood disorder. The estimated prevalence of any comorbid AD was lowest amongst persons with BPD-I and highest in the BPD-II patient group. The prevalence of comorbid ADs for the MDD group was intermediary between the two BPD subgroups. This finding is consistent with the observation that softer expressions of BPD are often camouflaged as anxious depression in the primary care setting [67]. MacQueen et al. [68] reported that the prevalence of any AD comorbidity in BPD was higher in subsyndromal (80.6%) than in syndromal (54%) and euthymic (38.6%) phases. In contrast, Dilsaver and Chen [69] reported that SoP and PD presenting during a bipolar episode were highly associated with suicidality, particularly in depressive phases. These observations suggest that in some patients, anxiety comorbidity is most pronounced at the extremes of affective excursions, while in others, anxiety may present primarily as an interepisodic disturbance. McElroy et al. [70] reported anxiety (n ¼ 122, 42%) and substance use disorders (n ¼ 122, 42%) as the most frequent lifetime comorbid disorders in BPD. There was no significant difference in AD comorbidity between patients with BPD-I and BPD-II. The reported lifetime and current prevalences of any AD was 42 and 30%, respectively. Lifetime Axis I comorbidity was associated with early age of onset of
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BPD symptoms, progressive severity of illness and a family history of alcoholism and drug abuse. Current anxiety comorbidity was also associated with reduced occupational functioning, a history of rapid cycling and a shortening of well intervals. The prevalence of AD and its correlates was investigated in the first 500 patients (BPDI n ¼ 360, BPDII n ¼ 115) enrolled in the Systematic Treatment Enhancement Program for BPD (STEP-BPD) [22]. The prevalences of any lifetime AD for the entire sample were greater amongst patients with BPD-I (51.2%) versus BPD-II (30.5%). The age of onset of BPD was significantly lower for patients with any lifetime AD than in patients without AD (15.6 vs. 19.4 years, respectively). Patients with a lifetime AD also had less education, shorter time euthymic, lower rates of recovery and elevated rates of lifetime suicide attempts. It was also reported that BPD with comorbid ADs had a higher prevalence of alcohol and substance use disorders. The presence of multiple ADs was independently associated with added impairment in quality of life and functioning. Consistently with other reports, the presence of a lifetime AD was significantly associated with an increased number of suicide attempts [22]. The association between ADs and alcohol and substance use disorders is an additional theme that emanates from the BPD literature. Bauer et al. [71] examined the prevalence and the correlates of comorbid substance use disorders and ADs in a sample of inpatients with BPD (n ¼ 348). ADs were associated with earlier age at onset, rapid cycling, higher probability of reporting depressive symptoms, higher rates of prior suicide attempts, greater number of prior-year episodes, higher severity of illness scores and lower quality of life. The negative effect of ADs in BPD was particularly evident in patients with BPD who also had a comorbid substance abuse disorder. Goodwin et al. [72] also reported the association between AD and substance use disorders in BPD. In particular, PD was associated with an increased prevalence of cocaine, sedative and stimulant use disorders. Relatively fewer studies have reported the prevalence of BPDs amongst AD populations. ADs are often a phenomenological antecedent to overt BPD; this calls for careful screening for BPD amongst children and adolescents reporting to health care providers with prominent anxiety symptoms [73]. A history of manic or hypomanic episodes has been observed in patients with PD-Agoraphobia [74]. The development of mania or hypomania in response to treatment with serotonin reuptake inhibitors has also been widely described in OCD case series and reports [75,76]. In a clinical study of 345 outpatients with OCD [77], lifetime comorbidity with BPD (primarily bipolar II) was 16%. Finally, patients with SoP have been found to have high rates of BPD (Himmeloch, 1998 [114]). In a Pisa-San Diego collaborative study [62,63], major depression was the most common comorbid disorder in a
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large sample of patients with AD. However, bipolar II disorder resulted widely associated with SoP (21.1%), OCD (17.7%) and in a lesser extent with PD (5.0%). The relative neglect in clinical and epidemiological research for the comorbidity between bipolar spectrum disorders and AD is especially due to underdiagnosis of bipolar II disorders (often misdiagnosed as unipolar or personality disorders) in patients with AD. It has been documented that current official diagnostic systems grossly underestimate bipolar II and related disorders and that clinicians specifically trained in bipolar II outperformed routine interviewers in such structured interviews as the SADS or the SCID [78]. Although this point goes against the grain in the literature on structured interviewing, it is consistent in suggesting that the proper identification of BPDII requires a more sophisticated approach in diagnosis.
Comorbid ADs and clinical presentation of bipolar disorder The co-occurrence of BPD and ADs seems to result in something more complex than a simple add-on effect. Multiple comorbidity and consequent symptomatological instability appear as the most relevant consequence of the anxious-bipolar co-existence [62,63]. Because of that, many of these patients receive diagnoses of borderline, narcisistic, histrionic personality disorders that in some cases prevent them from receiving adequate pharmacological treatment [79]. Increased risk of mixed states, suicidal behaviour and alcohol and drug abuse are other important prognostic implications. ADs are associated with multiple indices of poor outcome in BPD. Gaudiano and Miller [80] evaluated comorbid ADs in BPD patients, and their association with bipolar illness severity, chronicity and treatment response. Patients with BPD-AD were more likely to report severe depression, chronic illness course and negative treatment outcomes. Henry et al. [81] also reported that ADs comorbidity was associated with an earlier age of BPD onset and lower response to anticonvulsants. Boylan et al. [82] observed that BPD patients with comorbid AD had an earlier age at onset, higher frequency of rapid cycling and a higher usage of benzodiazepine treatment. Moreover, BPD patients with comorbid ADs had significantly higher rates of substance abuse or dependence, illness severity and chronicity, and a lower mean Global Assessment of Functioning (GAF) score. Different temporal relationship seems to characterize the occurrence of hypomania in individual AD subtypes [83]. Usually SoP chronologically preceded hypomanic episodes and disappeared when the latter episodes supervened. By contrast, PD and OCD symptomatology, even when preceding hypomanic episodes, often persisted during such episodes. Interestingly, a relevant proportions
of all onsets of panic attacks, in patients with comorbid PD and BPD, were during (hypo)mania [83]. These findings are consistent with the hypothesis that, at least in some patients, SoP, and to some extent OCD, seem to lie on a broad affective continuum of inhibitory restraint versus disinhibited hypomania. By contrast, PD, in the context of an (hypo)manic episode, might be interpreted as a dysphoric or mixed evolution of the symptomatology. In order to confirm these observations, further investigations should focus on the prospective assessment of patients with concomitant ADS and BPD. Indeed, retrospective methodology utilized in most clinical studies makes it difficult to ascertain the extent to which antidepressants, the most common treatment for severe AD, could explain the anxiety-bipolar comorbidity. Investigations on differential patterns of comorbidity may provide important information in distinguishing more homogeneous clinical subtypes of affective disorders from the biological, genetic and therapeutic point of view. Preliminary evidence support the hypothesis that differential risk for PD comorbidity is a promising tool in order to discern heterogeneous genetic subtypes of BPD. MacKinnon et al. [84] evaluated 528 members of 57 families ascertained for a genetic linkage study of bipolar disorder. Out of 57 bipolar probands, 10 had comorbid PD; in their relatives PD co-segregated with bipolar disorder (in particular Bipolar II and cyclothymia) at a significantly higher rate than expected by chance, suggesting that comorbid PD might be a specific marker for a familial subtype of BPD. Bipolar OCD patients represent more frequently than the non-bipolar, abuse of alcohol, sedatives, stimulants and caffeine, as well as episodic course of the AD, a greater number of major depressive episodes and suicide attempts). Moreover, they currently reported significantly higher rate of sexual obsessions and a significantly lower rate of order rituals [85]. These observations would seem to indicate that bipolar comorbidity has a strong influence on the longitudinal course and complications of OCD. In particular, long-term episodic course of OCD resulted, related to family history for mood disorders, lifetime comorbidity for panic and bipolar II disorders and late age at onset. Evidence based on a single family pedigree [86] suggests a genetic linkage between OCD and BPD, while other studies indicate increased prevalence of OCD in bipolar probands and high rates of obsessional traits in the offspring of bipolar probands [87]. Coryell [88] reported an equal incidence (2.3%) of mania in families of probands with OCD and in families with a bipolar disordered member. These findings are consistent with the hypothesis that, at least in some cases, episodic course of OCD is related to cyclical affective disorders. In a more theoretical vein, episodic OCD symptoms, in a substantial minority of cases, may be considered the phenotypic expression of an underlying affective genotype.
Comorbidity in Bipolar Disorder
As regards the relationships between SoP and BPD, in a clinical study by Himmelhoch [89], 18 patients with FS had a significant improvement of social anxiety after a treatment with MAOI (phenelzine) and RIMA (moclobemide). Out of 32 of these subjects, 14, along with the complete remission of social phobic symptomatology, developed a hypomanic episode, both according to clinical judgement and structured evaluation. On the basis of this observation, the author hypothesized that SoP might actually belong, at least in some cases, to a bipolar spectrum. It is notable that Himmelhoch concluded that social phobias special relationship with bipolar II disorder became evident only when social anxiety was perturbed by the central actions of stimulating antidepressants. Protracted social anxiety may represent, along with inhibited depression, the opposite of hypomania. Moreover, the increased susceptibility to alcohol use in some patients with SP might be related more to the presence of a bipolar diathesis [90,91], with marked reactivity to the ethanol, than to the social-phobic symptomatology per se. This hypothesis is compatible with the observation of Himle et al. [92], on SoP patients without a comorbid BPD, where alcohol use did not reduce social anxiety in performance situations and was not associated by better performance. The socializing and disinhibiting effect that many SoP patients report with alcohol use might therefore be mediated by increased confidence as part of hypomania facilitated by alcohol. The correct identification of SoP-bipolar comorbidity has relevant clinical implications as far as other concomitant disorders, symptomatological features, course and complications are concerned. Severity and generalization of the SoP symptoms, multiple comorbidity and alcohol abuse appear to be the most relevant consequences of SoPbipolar coexistence. Likewise, clinicians must investigate whether or not BPD is a comorbid condition in patients presenting with SoP. The suspicion of bipolar comorbidity should be even greater if patients presented multiple comorbidity or have been previously refractory to treatment. In summary, comorbidity with ADs in the bipolar spectrum population is associated with several indices of severity, such as a more severe subtypes of BPD, an earlier age at onset, mixed state presentations, an intensification of symptoms, poor symptomatic and functional recovery, higher rates of alcohol and substance use disorders, suicidal behaviour, diminished response to pharmacological treatment, decreased quality of life and unfavourable course and outcome.
Treatment implications of anxious comorbidity The lack of information about anxious-bipolar connections may have a negative impact on treatment choice and man-
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agement. Most of the controlled trials on BPD excluded patients with comorbid ADs and vice versa; as a consequence, the empirical basis for treating patients with anxious-bipolar comorbidity are almost exclusively founded on anecdotal reports and open clinical experiences. Overall, lithium has not been studied in AD. Some useful suggestions can be derived from clinical experiences with mood stabilizers and anti-AD agents. Bipolar patients with high anxiety ratings are less likely to respond to lithium [93]. The association of anxiety with suicidality, and less favourable treatment responses in BPD patients, has been consistently reported [22,94]. Feske et al. [94] examined the correlates of acute treatment response in 124 BPD-I patients. Anxiety symptomatology was associated with a longer time to remission in both depression and mania. Moreover, nonremitting patients were more likely to report a history of panic attacks, current or past anxiety, more severe depression and a greater number of previous affective episodes. Patients reporting a history of panic attacks also required a higher mean number of medications to achieve symptomatic remission. Controlled data suggests valproate may be more effective than lithium in mania associated with depressive features, even when the depressive features are mild [95]. Since anxiety symptoms are often seen in mixed states and may even be related to depression in mania, future studies should evaluate anxious features as possible predictors of response of mania to valproate (and other antimanic agents). Regarding AD, valproate has been used successfully in the treatment of panic disorder [96]. In addition, in an open-label study, Calabrese and Delucchi [97] noted 6that rapid-cycling BPD patients with comorbid panic attacks described reduction in their panic symptoms with valproate treatment. In addition, one open-label study [98] and one case report [99] have suggested that valproate may be helpful in the treatment of some patients with OCD, especially those with associated bipolar or epileptiform features. As regards the use of carbamazepine in AD, Uhde et al. [100] did not find carbamazepine to be an efficacious treatment for panic disorder in a double-blind, placebocontrolled study of 14 patients. In OCD, Koopowitz and Berk [101] reported beneficial results with the use of carbamazepine in two patients, while Swinson and Joffe [102] found carbamazepine was ineffective in an open-label study. Gabapentin has shown preliminary evidence of efficacy in the treatment of anxiety but not BPD. In ADs, Gabapentin has been shown to be superior to placebo in one small controlled study on SoP [103], and in another controlled study on severe PD [104]. The predictors of response to gabapentin as adjunctive treatment has been evaluated in 43 patients with BPD, who were resistant to standard moodstabilizers [90,91]. Gabapentin was administered as an
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adjunctive treatment for an eight-week period, in combination with other mood stabilizers, benzodiazepines, antidepressants and neuroleptics. Of 43 patients, 18 (41.9%), who began treatment, were considered responders; in particular gabapentin showed antidepressant and anxiolytic properties. Comorbid PD and alcohol abuse (and to a lesser extent SoP) were the best predictors of response. This finding might has relevant clinical implications as concern the treatment of anxious bipolar comorbidity, but it should be confirmed in controlled clinical trials. As regard anti-anxiety agents, Benzodiazepines are relatively safe and well tolerated when used in combination with mood stabilizers. However, long-term benzodiazepine use may be problematic in most patients, due to development of tolerance, physical dependence and withdrawal phenomena. Antidepressants are often used in the treatment of AD and bipolar depression. However, these compounds may worsen the course of the mood disorder by precipitating mania, mixed states, or rapid cycling (for review see [105]). Antidepressant-induced (hypo)manic symptoms have been reported to occur specifically in the course of treatment of virtually all AD, including obsessive compulsive disorder, panic disorder, and social phobia [106,107,114]. In BPD, prophylactic treatment with mood stabilizers may prevent antidepressant-induced switching [107,108]. When treating comorbid bipolar and AD, it is imperative to begin treatment with a mood stabilizer. Indeed, initiating an antidepressant before adequate mood stabilization has been achieved could worsen the anxiety symptoms by exacerbating the BPD. The efficacy of typical and atypical antipsychotics in the treatment of primary or comorbid AD or anxiety symptoms in major depressive or bipolar disorders was recently reviewed [109]. Six trials in primary generalized anxiety disorder (GAD), 15 in refractory OCD, 8 in posttraumatic stress disorder (PTSD), 6 in neurosis with the HAM-A, 1 in SoP and 2 in anxiety symptoms in bipolar depression were identified. Gao et al. [109] concluded that, except for trifluoperazine, there is no large, well-designed study of antipsychotics in the treatment of primary or comorbid anxiety symptoms or disorders. Most of the less welldesigned studies showed that other typical antipsychotics might be superior to placebo or as effective as benzodiazepines in the treatment of GAD and other anxiety conditions. In most studies, risperidone, olanzapine and quetiapine augmentation to antidepressants was superior to placebo in treating refractory OCD and PTSD. Both olanzapine and quetiapine significantly reduced anxiety, compared to placebo in studies of bipolar depression. The efficacy of these agents in various anxiety conditions needs to be further investigated with large, well-designed comparison studies.
In the treatment of comorbid BPD and PD, it appears reasonable to utilize as a first choice mood stabilizers who have been shown to possess some antipanic efficacy, such as valproate or adjunctive gabapentin. In patients with persistent and disabling ADs, the combination with antidepressants can be considered. Less information is available for comorbid BPD and SoP. A small positive study on gabapentin in SoP seems indicate the possible efficacy of this drug [103]. The combination of mood stabilizers such as lithium, valproate and carbamazepine with SSRIs, RIMAs or IMAOs might reduce the number of switches in these patients. However, there is almost no information on long-term outcome of patients with comorbid BPD and SoP treated with drug combinations. Bipolar OCD are amongst the most difficult patients to treat. No mood stabilizers has been shown to exert any antiOCD activity, and the effective anti-OCD pharmachological treatments (high doses of clomipramine or SSRIs) have high potential for inducing (hyo)manic switches and increasing cyclicity in BPD patients. Combination of different mood stabilizer (lithium plus antiepileptics) is often necessary, and in some cases the combination with antidepressants supposed less likely to induce rapid-cycling (i.e. MAOIs) can be utilized. However, many of these patients present residual OCD symptomatology and very severe manic or mixed episode (aggressive, hostile mood) that may require hospitalization. In some cases the combination with atypical antipsychotics (risperidone, olanzapine, quetiapine or aripiprazole) can be taken into account. Indeed, even if in some cases atypical antipsychotics has been reported to exacerbate OCD symptomatology [110,111], in others these drugs display a mood-stabilizing, anti-aggressive activity, which permit also an effective treatment of OCD symptoms. In summary, the coexistence of anxiety and bipolar spectrum disorders is a substantial clinical issue affecting a large number of patients. The frequent comorbidity between BPD and ADs has also been reported in epidemiologic samples and primary care setting, indicating that clinical referral bias is unlikely to be the main explanation for this phenomenon. Accurate diagnosis is a central concern, in patients presenting with BPD, the clinician must screen for all ADs. Likewise, clinicians must investigate whether or not BPD is a comorbid condition in patients presenting with AD. The suspicion of bipolar comorbidity should be even greater if patients presented multiple ADs, alcohol or substance abuse or have been previously refractory to treatment. The correct identification of anxious-bipolar comorbidity has relevant clinical implications as far as BPD symptomatology, course and complications are concerned. Symptomatological instability, multiple comorbidity, in particular alcohol and substance abuse, and suicidality appear as the
Comorbidity in Bipolar Disorder
most relevant consequences of anxious-bipolar coexistence. No firm recommendations can be made as to which mood stabilizer would be best for which BPD patient, based on his or her particular comorbid AD. Nonetheless, several impressions emerge from the available literature. Generally, the data support the use of valproate as the mood-stabilizer of choice for patients with comorbid PD and possibly OCD, especially if associated with prominent anxiety symptoms, mixed features and/or rapid cycling. Antidepressants, while proven effective in PD, OCD and SP, may worsen the course of BPD, especially if initiated before treatment with a moodstabilizer. If antidepressants are to be used in patients with concurrent BPD and ADs, adequate mood stabilization should first be achieved, and antidepressants then added cautiously while patients are monitored carefully for emerging symptoms of hypomania or mania. Atypical antipsychotics are widely utilized as mood stabilizing agents. On the other hand, they have not yet been systematically studied in AD, and have been hypothesized to exacerbate PD and OCD because of their serotonergic antagonistic properties.
Conclusion The use of the term comorbidity in psychiatry is questionable and raises fundamental questions regarding the validity of the utilized diagnostic criteria and classification system. The study of comorbidity in BD, however, provides an opportunity to address important clinical and research questions. Epidemiological and clinical studies have documented the high lifetime rates and risks related to substance use and AD comorbidity in BD patients. This triad of diagnoses is associated with several indices of BD severity such as earlier age at onset, mixed presentations, severity of symptoms, poor symptomatic and functional recovery, suicidal behaviour, diminished acute response to pharmacological treatment, decreased quality of life and an unfavourable course and outcome. Comorbidity of BPD with substance use disorders and AD can be challenging to diagnose and optimally treat. Further work is encouraged to study these specific patterns (i.e. rapid cycling, dysphoric mania) and aetiology of comorbidity directionality (primary vs. secondary drug use) in controlled clinical trials. The identification of temporal priority in comorbid BD may provide a more refined view of the association between BD and comorbid syndromes. Coexisting conditions, whose onset precedes BD, often occurring with AD, may obscure essential elements of the primary diagnosis, thus diminishing the possibility of early detection and timely intervention. A question yet to be answered is whether an earlier and/or accurate diagnosis of BPD can
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prevent or at least attenuate the degree of subsequent substance use disorder or whether bipolar symptoms at onset that are diagnosed and treated can in fact attenuate or minimize the development of addiction as a later manifestation of bipolar illness. Finally, despite intensified efforts to clinically characterize substance use and anxiety comorbidity in BD, the empirical base informing therapeutic decisions in the comorbid bipolar patient remains largely inadequate, as a consequence of the routine exclusion of patients with such a comorbidity from the largest randomized clinical trials for all phases of bipolar illness.
References 1. Soreca, I., Frank, E. and Kupfer, D.J. (2009) The phenomenology of bipolar disorder: what drives the high rate of medical burden and determines long-term prognosis? Depress Anxiety, 26, 73–82. 2. Kraepelin, E. (1921) Manic-depressive insanity and paranoia, in Classics in Psychiatry, Ayer Company, Publishers, Inc., Salem New Hampshire. 3. Regier, D.A., Farmer, M.E., Rae, D.S. et al. (1990) Comorbidity of mental disorders with alcohol and other drug abuse. Results from the Epidemiologic Catchment Area (ECA) Study. J. Am. Med. Assoc., 264 (19), 2511–2518. 4. Hezler, J.E. and Pryzbeck, TR. (1988) The co-occurrence of alcoholism with other psychiatric disorders in the general population and its impact on treatment. J. Stud. Alcohol., 49, 219–224. 5. Kessler, R.C., McGonagle, K.A., Zhao, S. et al. (1994) Lifetime and 12-month prevalence of DSM-III-R psychiatric disorders in the United States: results from the National Comorbidity Survey. Arch. Gen. Psychiatry, 51, 8–19. 6. Kessler, R.C., Rubinow, D.R., Holmes, C. et al. (1997) The epidemiology of DSM-III-R bipolar I disorder in a general population survey. Psychol. Med., 27, 1079–1089. 7. Grant, B.F., Dawson, D.A., Stinson, F.S. et al. (2004) The 12-month prevalence and trends in DSM-IV alcohol abuse and dependence: United States 1991–1992 and 2001–2002. Drug Alcohol Depen., 74, 223–234. 8. Grant, B.F., Hasin, D.S., Blanco, C. et al. (2005) The epidemiology of social anxiety disorder in the United States: results from the National Epidemiologic Survey on Alcohol and Related Conditions. J. Clin. Psychiatry., 66 (11), 1351–1361. 9. Cassidy, Y.W.L., Flanagan, N.B., Spellman, M. and Cohen, M.E. (1957) Clinical observations in manic-depressive disease; a quantitative study of one hundred manic-depressive patients and fifty medically sick controls. J. Am. Med. Assoc., 164 (14), 1535–1546. 10. Mayfield, D.G. and Coleman, L.L. (1968) Alcohol use and affective disorder. Dis. Nerv. Syst., 29 (7), 467–474. 11. Reich, L.H., Davies, R.K. and Himmelhoch, J.M. (1974) Excessive alcohol use in manic-depressive illness. Am. J. Psychiatry., 131 (1), 83–86.
40
|
Chapter 4
12. Morrison, J.R. (1974) Bipolar affective disorder and alcoholism. Am. J. Psychiatry., 131 (10), 1130–1133. 13. Himmelhoch, J.M., Mulla, D., Neil, J.F. et al. (1976) Incidence and signficance of mixed affective states in a bipolar population. Arch. Gen. Psychiatry, 33 (9), 1062–1066. 14. McKowen, J.W., Frye, M.A., ALtshuler, L.L. and Gitlin, M.J. (2005) Patterns of alcohol consumption in bipolar patients comorbid for alcohol abuse or dependence. Bipolar Disord., 4, 277–281. 15. Stewart, C. and El-Mallakh, R.S. (2007) Is bipolar disorder overdiagnosed among patients with substance abuse? Bipolar Disord, 9, 646–648. 16. Goldberg, J.F., Garno, J.L., Callahan, A.M. et al. (2008) Overdiagnosis of bipolar disorder among substance use disorder inpatients with mood instability. J. Clin. Psychiat., 69, 1751–1757. 17. Freed, E.X. (1970) Alcoholism and manic-depressive disorders; some perspectives. Q. J. Stud. Alcohol., 31 (1), 62–89. 18. Frye, M.A., Altshuler, L.L., McElroy, S.L. et al. (2003) Gender differences in prevalence, risk, and clinical correlates of alcoholism comorbidity in bipolar disorders. Am. J. Psychiatry, 160, 883–889. 19. Meade, C.S., McDonald, L.J., Graff, F.S. et al. (2009) A prospective study examining the effects of gender and sexual/physical abuse on mood outcomes in patients with co-occurring bipolar I and substance use disorders. Bipolar Disord., 11, 425–433. 20. Jaffee, W.B., Griffin, M.L., Gallop, M.R. et al. (2009) Depression precipitated by alcohol use in patients with co-occurring bipolar and substance use disorders. J. Clin. Psychiatry, 70, 171–176. 21. Levander, E., Frye, M.A., McElroy, S. et al. (2007) The bipolar triad: alcoholism and PTSD in bipolar women: differential lifetime anxiety comorbidity in bipolar I women with and without alcoholism. J. Affect. Disord., 101, 211–217. 22. Simon, N.M., Otto, M.W., Wisniewski, S.R. et al. (2004) Anxiety disorder comorbidity in bipolar disorder patients: data from the first 500 participants in the Systematic Treatment Enhancement Program for Bipolar Disorder (STEPBD). Am. J. Psychiatry, 161, 2222–2229. 23. McDermott, B.E., Quanbeck, C.D. and Frye, M.A. (2007) Comorbid substance use disorder in women with bipolar disorder associated with criminal arrest. Bipolar Disord., 9, 536–540. 24. Hall-Flavin, D.K., Schneekloth, T., Loukianova, L. et al. (2008) Utilization of Residential Addiction Treatment in Bipolar Disorder. Research Abstract presented at the 3rd Biennial Conference of the International Society for Bipolar Disorder. Delhi India, January 27–28. 25. Goldstein, B.I. and Levitt, A.J. (2006) A gender-focused perspective on health service utilization in comorbid bipolar I disorder and alcohol use disorders: results from the national epidemiologic survey on alcohol and related conditions. J. Clin. Psychiat., 67, 925–932. 26. Frye, M.A. and Salloum, I.M. (2006) Bipolar disorder and comorbid alcoholism: prevalence rate and treatment considerations. Bipolar Disord., 8, 677–685.
27. Black, D.W., Winokur, G., Bell, S. et al. (1988) Complicated mania. Comorbidity and immediate outcome in the treatment of mania. Arch. Gen. Psychiatry., 45, 232–236. 28. Tohen, M., Waternaux, C.M., Tsuang, M.T. and Hunt, A.T. (1990) Four-year follow-up of twenty-four first-episode manic patients. J. Affect. Disord., 19, 79–86. 29. OConnell, R.A., Mayo, J.A., Flatow, L. et al. (1991) Outcome of bipolar disorder on long-term treatment with lithium. Br. J. Psychiatry, 159, 123–129. 30. Aagaard, J. and Vestergaard, P. (1990) Predictors of outcome in prophylactic lithium treatment: a 2-year prospective study. J. Affect. Disord., 18, 259–266. 31. Keller, M.B., Lavori, P.W. et al. (1986) Differential outcome of pure manic, mixed/cycling, and pure depressive episodes in patients with bipolar illness. J. Amer. Med. Assoc., 255 (22): 3138–3142. 32. Degenhardt, L., Chiu, W.T., Sampson, N. et al. (2007) Epidemiological patterns of extra-medical drug use in the United States: evidence from the National Comorbidity Survey Replication, 2001–2003. Drug Alcohol Depen., 90, 210–223. 33. Lasser, K., Boyd, J.W., Woolhandler, S. et al. (2000) Smoking and mental illness: A population-based prevalence study. J. Am. Med. Assoc., 284 (20), 2606–2610. 34. Berk, M., Ng, F., Wang, W.V. et al. (2008) Going up in smoke: Tobacco smoking is associated with worse treatment outcomes in mania. J Affect Disord., 110 (1–2), 126–134. 35. Oquendo, M.A., Galfalvy, H., Russo, S. et al. (2004) Prospective study of clinical predictors of suicidal acts after a major depressive episode in patients with major depressive disorder or bipolar disorder. Am. J. Psychiatry, 161 (8), 1433–1441. 36. Waxmonsky, J.A., Thomas, M.R., Miklowitz, D.J. et al. (2005) Prevalence and correlates of tobacco use in bipolar disorder: data from the first 2000 participants in the Systematic Treatment Enhancement Program. Gen. Hosp. Psychiat., 27 (5), 321–328. 37. Hughes, J.R., Hatsukami, D.K., Mitchell, J.E. et al. (1986) Prevalence of smoking among psychiatric outpatients. Am. J. Psychiatry, 143 (8), 993–997. 38. Frye, M.A., Gitlin, M.J. and Altshuler, L.L. (2004) Unmet needs in bipolar depression. Depress Anxiety, 19, 199–208. 39. Frye, M.A., Yatham, L., Calabrese, J. et al. (2006) The Incidence of and Time Course of Subsyndromal Symptoms in Patients with Bipolar Disorder. J. Clin. Psychiatry, 67, 1721–1728. 40. Altshuler, L.L., Post, R.M., Black, D.O. et al. (2006) Subsyndromal depressive symptoms are associated with functional impairment in patients with bipolar disorder: results of a large, multisite study. J. Clin. Psychiat., 67 (10), 1551–1560. 41. Abulseoud, O., Hellemann, G. et al. (2008) Gender and bipolar subtype association with self-reported hazardous alcohol consumption in bipolar depression. J. Dual Diag., 4 (3): 291–302. 42. BarChana, M., Levav, I., Lipshitz, I. et al. (2008) Enhanced cancer risk among patients with bipolar disorder. J. Affect. Disord., 108 (1–2), 43–48.
Comorbidity in Bipolar Disorder 43. Osby, U., Brandt, L., Correia, N. et al. (2001) Excess mortality in bipolar and unipolar disorder in Sweden. Arch. Gen. Psychiatry, 58 (9), 844–850. 44. Ebbert, J.O., Sood, A., Hays, J.T. et al. (2007) Treating tobacco dependence: review of the best and latest treatment options. J. Thorac. Oncol., 2 (3), 249–256. 45. Fiore, M.C., Bailey, W.C. and Cohen, S.J. (2000) Treating tobacco use and dependence, in Quick Reference Guide, In U. S. D. o. H. a. H. Services, ed., Public Health Service. 46. Hurt, R.D., Sachs, D.P., Glover, E.D. et al. (1997) A comparison of sustained-release bupropion and placebo for smoking cessation. N. Engl. J. Med., 337 (17), 1195–1202. 47. Jorenby, D.E., Leischow, S.J., Nides, M.A. et al. (1999) A controlled trial of sustained-release bupropion, a nicotine patch, or both for smoking cessation. N. Engl. J. Med., 340 (9), 685–691. 48. Jorenby, D.E., Hays, J.T., Rigotti, N.A. et al. (2006) Efficacy of varenicline, an alpha4beta2 nicotinic acetylcholine receptor partial agonist, vs placebo or sustained-release bupropion for smoking cessation: a randomized controlled trial. J. Am. Med. Assoc., 296 (1), 56–63. 49. Kohen, I. and Kremen, N. (2007) Varenicline-induced manic episode in a patient with bipolar disorder. Am. J. Psychiatry, 164 (8), 1269–1270. 50. Morstad, A.E., Kutscher, E.C., Kennedy, W.K. et al. (2008) Hypomania with agitation associated with varenicline use in bipolar II disorder (February). Ann. Pharmacother., 42 (2), 288–289. 51. Stapleton, J.A., Watson, L., Spirling, L.I. et al. (2008) Varenicline in the routine treatment of tobacco dependence: a prepost comparison with nicotine replacement therapy and an evaluation in those with mental illness. Addiction, 103 (1), 146–154. 52. Addington, J., el-Guebaly, N., Campbell, W. et al. (1998) Smoking cessation treatment for patients with schizophrenia. Am. J. Psychiatry, 155 (7), 974–976. 53. Ziedonis, D.M. and George, T.P. (1997) Schizophrenia and nicotine use: report of a pilot smoking cessation program and review of neurobiological and clinical issues. Schizophrenia Bull., 23 (2), 247–254. 54. Fowler, J.S., Logan, J., Wang, G.J. et al. (2003) Monoamine oxidase and cigarette smoking. Neurotoxicology, 24 (1), 75–82. 55. Covey, L.S., Glassman, A.H. and Stetner, F. (1997) Major depression following smoking cessation. Am. J. Psychiatry, 154 (2), 263–265. 56. Glassman, A.H., Helzer, J.E., Covey, L.S. et al. (1990) Smoking, smoking cessation, and major depression. J. Am. Med. Assoc., 264 (12), 1546–1549. 57. Killen, J.D., Fortmann, S.P., Schatzberg, A. et al. (2003) Onset of major depression during treatment for nicotine dependence. Addict. Behav., 28 (3), 461–470. 58. Hitsman, B., Borrelli, B., McChargue, D.E. et al. (2003) History of depression and smoking cessation outcome: a meta-analysis. J. Consult. Clin. Psych., 71 (4), 657–663. 59. John, U., Meyer, C., Rumpf, H.J. et al. (2004) Depressive disorders are related to nicotine dependence in the
60.
61.
62.
63.
64.
65.
66.
67.
68.
69.
70.
71.
72.
73.
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population but do not necessarily hamper smoking cessation. J. Clin. Psychiat., 65 (2), 169–176. Hirschfeld, R.M., Williams, J.B., Spitzer, R.L. et al. (2000) Development and validation of a screening instrument for bipolar spectrum disorder: the Mood Disorder Questionnaire. Am. J. Psychiatry, 157, 1873–1875. Shoaib, A.M. and Dilsaver, S.C. (1995) Panic disorder in subjects with pure mania and depressive mania. Anxiety, 1, 302–304. Perugi, G., Toni, C. and Akiskal, H.S. (1999) AnxiousBipolar comorbidity: diagnostic and treatment challenges. Psychiat. Clin. N. Am., 22 (3), 565–583. Perugi, G., Akiskal, H.S., Ramacciotti, S. et al. (1999) Depressive comorbidity of panic, social phobic and obsessive-compulsive disorders re-examined: is there a bipolar connection? J. Psychiat. Res., 33, 53–61. Chen, Y.W. and Dilsaver, S.C. (1995) Comorbidity for obsessive-compulsive disorder in bipolar and unipolar disorders. Psychiatric Res., 59, 57–64. Kessler, R. (1999) Comorbidity of unipolar and bipolar depression with other psychiatric disorders in a general population survey, in Comorbidity in Affective Disorders (ed. M. Tohen), Marcel Dekker Inc., New York, pp. 1–25. Rihmer, Z., Szadoczky, E., Furedi, J. et al. (2001) Anxiety disorders comorbidity in bipolar I, bipolar II and unipolar major depression: results from a populationbased study in Hungary. J. Affect. Disord., 67 (1–3), 175–179. Manning, J.S., Haykal, R.F., Connor, P.D. and Akiskal, H.S. (1997) On the nature of depressive and anxious states in a family practice setting: The high prevalence of bipolar II and related disorders in a cohort followed longitudinally. Compr. Psychiatry, 38, 102–108. MacQueen, G.M., Marriott, M., Begin, H. et al. (2003) Subsyndromal symptoms assessed in a longitudinal, prospective follow-up of a cohort of patients with bipolar disorder. Bipolar Disord., 5, 349–355. Dilsaver, S.C. and Chen, Y.W. (2003) Social phobia, panic disorder and suicidality in subjects with pure and depressive mania. J. Affect. Disord., 77, 173–177. McElroy, S.L., Altshuler, L.L., Suppes, T. et al. (2001) Axis I psychiatric comorbidity and its relationship to historical illness variables in 288 patients with bipolar disorder. Am. J. Psychiatry, 158, 420–426. Bauer, M.S., Altshuler, L., Evans, D.R. et al. (2005) for the VA Cooperative Study # 430 Team. Prevalence and distinct correlates of anxiety, substance and combined comorbidity in a multi-site public sector sample with bipolar disorder. J. Affect. Disord., 85, 301–315. Goodwin, R.D., Stayner, D.A., Chinman, M.J. et al. (2002) The relationship between anxiety and substance use disorders among individuals with severe affective disorders. Compr. Psychiatry, 43, 245–252. Masi, G., Perugi, G., Millepiedi, S. et al. (2007) Clinical and research implications of panic-bipolar comorbidity in children and adolescents. Psychiatry Res., 153 (1), 47–54.
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74. Savino, M., Perugi, G., Simonini, E. et al. (1993) Affective comorbidity in panic disorder: is there a bipolar connection? J. Affect. Disord., 28, 155–163. 75. Rhimer, Z., Barsi, J., Belso, N. et al. (1996) Antidepressant induced hypomania in obsessive-compulsive disorder. Int. Clin. Psychopharm., 11, 203–205. 76. Kruger, S., Cooke, R.G., Hasey, G.M. et al. (1995) Comorbidity of obsessive-compulsive disorder in bipolar disorder. J. Affect. Disord., 34, 117–120. 77. Perugi, G., Akiskal, H.S., Pfanner, C. et al. (1997) The clinical impact of bipolar and unipolar affective comorbidity on obsessive-compulsive disorder. J. Affect. Disord., 46, 15–23. 78. Dunner, D.L. and Kai Tay, L. (1993) Diagnostic reliability of the history of hypomania in bipolar II patients with major depression. Compr. Psychiatry, 34, 303–307. 79. Perugi, G. and Akiskal, H.S. (2002) The soft bipolar spectrum redefined: focus on the cyclothymic, anxious-sensitive, impulse-dyscontrol and binge-eating connection in Bipolar II and related conditions. Psychiatr. Clin. North Am., 25 (4), 713–737. 80. Gaudiano, B.A. and Miller, I.W. (2005) Anxiety disorder comorbidity in bipolar I disorder: relationship to depression severity and treatment outcome. Depress Anxiety, 21, 71–77. 81. Henry, C., Bulke, D., Bellivier, F. et al. (2003) Anxiety disorders in 318 bipolar patients: prevalence and impact on illness severity and response to mood-stabilizers. J. Clin. Psychiatry, 64, 331–335. 82. Boylan, K.R., Bieling, P.J., Marriott, M. et al. (2004) Impact of comorbid anxiety disorders on outcome in a cohort of patients with bipolar disorder. J. Clin. Psychiatry, 65, 1106–1113. 83. Perugi, G., Akiskal, H.S., Toni, C. et al. (2001) The temporal relationship between anxiety disorders and (hypo)mania: a retrospective examination of 63 panic, social phobic and obsessive-compulsive patients with comorbid bipolar disorder. J. Affect. Disord., 67, 199–206. 84. MacKinnon, D.F., McMahon, F.J., Simpson, S.G. et al. (1997) Panic Disorder with familial bipolar disorder. Biol. Psychiatry, 42, 90–95. 85. Perugi, G., Akiskal, H.S., Gemignani, A. et al. (1998) Episodic course in obsessive compulsive disorder. Eur. Arch. Psychiatr. Clin. Neurosci., 248, 240–244. 86. Dilsaver, S.C. and White, K. (1986) Affective disorder and associated psychopathology: a family history study. J. Clin. Psychiatry, 47, 162–169. 87. Klein, D.N., Depue, R.A. and Slater, J.F. (1985) Inventory identification of cyclothymia. IX. Validation in offspring of bipolar I patients. Arch. Gen. Psychiatry, 43, 441–445. 88. Coryell, W. (1981) Obsessive compulsive disorder and primary unipolar depression. J. Nerv. Ment. Dis., 169, 220–224. 89. Himmelhoch, J.M. (1998) Social Anxiety, hypomania and the bipolar spectrum: data, theory and clinical issues. J. Affect. Disord., 50, 203–213. 90. Perugi, G., Toni, C., Frare, F. et al. (2002) Effectiveness of adjunctive gabapentin in resistant bipolar disorder: is it due to anxious-alcohol abuse comorbidity? J. Clin. Psychopharmacol., 22 (6), 584–591.
91. Perugi, G., Frare, F., Madaro, D. et al. (2002) Alcohol Abuse In Social Phobic Patients: Is There A Bipolar Connection? J. Affect. Disord., 68, 33–39. 92. Himle, J.A., Abelson, J.L., Haghightgou, H. et al. (1999) Effect of alcohol on social phobic anxiety. Am. J. Psychiatry, 156, 1237–1243. 93. Young, L.T., Cooke, R.G., Robb, J.C. et al. (1993) Anxious and non-anxious bipolar disorder. J. Affect. Disorder, 29, 49–52. 94. Feske, U., Frank, E., Mallinger, A.G. et al. (2000) Anxiety as a correlate of response to the acute treatment of bipolar I disorder. Am. J. Psychiatry, 157, 956–962. 95. Swann, A.C., Bowden, C.L., Morris, D. et al. (1997) Depression during mania: treatment response to lithium or divalproex. Arch. Gen. Psychiatry, 54, 37–42. 96. Lum, M., Fontaine, R., Elie, R. and Ontiveros, A. (1990) Divalproex sodiums anti-panic effect in panic disorder: a placebo-controlled study. Biol. Psychiatry, 27, 164A–165. 97. Calabrese, J.R. and Delucchi, G.A. (1990) Spectrum of efficacy of valproate in 55 patients with rapid-cycling bipolar disorder. Am. J. Psychiatry, 147, 431–434. 98. Deltito, J.A. (1994) Valproate pretreatment for the difficultto-treat patient with OCD. J. Clin. Psychiatry, 55, 500. 99. Cora-Locatelli, G., Greenberg, B.D., Martin, J.D. and Murphy, D.L. (1998) Valproate monotherapy in an SRI-intolerant OCD patient. J. Clin. Psychiatry, 59, 82. 100. Uhde, T.W., Stein, M.B. and Post, R.M. (1988) Lack of efficacy of carbamazepine in the treatment of panic disorder. Am. J. Psychiatry, 145, 1104–1109. 101. Koopowitz, L.F. and Berk, M. (1997) Response of obsessive compulsive disorder to carbamazepine in two patients with comorbid epilepsy. Ann. Clin. Psychiatry, 9, 171–173. 102. Swinson, R.P. and Joffe, R.T. (1987) Carbamazepine in obsessive-compulsive disorder. Biol. Psychiatry, 22, 1169–1171. 103. Pande, A.C., Davidson, J. and Jefferson, J. (1999). Treatment of social phobia with gabapentin: a placebo controlled study. J. Clin. Psychopharm., 19, 341–348. 104. Pollack, M.H., Matthews, J. and Scott, E.L. (1998) Gabapentin as a potential treatment for anxiety disorders. Am. J. Psychiatry, 155 (7), 992–993. 105. Ghaemi, S.N., Wingo, A.P., Filkowski, M.A. and Baldessarini, R.J. (2008) Long-term antidepressant treatment in bipolar disorder: meta-analyses of benefits and risks. Acta Psychiatr. Scand., 118 (5), 347–356. 106. Sholomskas, A.J. (1990) Mania in a panic disorder patient treated with fluoxetine. Am. J. Psychiatry, 147, 1090–1091. 107. Jann, M.W., Bitar, A.H. and Rao, A. (1982) Lithium prophylaxis of tricyclic-antidepressant-induced mania in bipolar patients. Am. J. Psychiatry, 139 (5), 683–684. 108. Kane, J.M., Quitkin, F.M., Rifkin, A. et al. (1982) Lithium carbonate and imipramine in the prophylaxis of unipolar and bipolar II illness. Arch. Gen. Psychiatry, 39, 1065–1069. 109. Gao, K., Muzina, D., Gajwani, P. and Calabrese, J.R. (2006) Efficacy of typical and atypical antipsychotics for primary
Comorbidity in Bipolar Disorder and comorbid anxiety symptoms or disorders: a review. J. Clin. Psychiatry, 67 (9), 1327–1340. 110. Baker, R.W., Chengappa, K.N., Baird, J.W. et al. (1992) Emergence of obsessive compulsive symptoms during treatment with clozapine. J. Clin. Psychiatry, 53 (12), 439–442. 111. de Haan, L., Beuk, N., Hoogenboom, B. et al. (1997) Obsessive-compulsive symptoms during treatment with olanzapine and risperidone: a prospective study of 113 patients with recent-onset schizophrenia or related disorders. J. Clin. Psychiatry, 58, 119–122.
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112. Niaura R, Britt DM, Shadel WG, Goldstein M, Abrams D, & Brown R. (2001). Symptoms of depression and survival experience among three samples of smokers trying to quit. Psychology of Addictive Behaviors, 15, 13–17. 113. Angst, J. (1998) The emerging epidemiology of hypomania and bipolar II disorder. J. Affect. Disord., 50 (2-3), 143–151. 114. Himmelhoch, J.M. (1998) Social anxiety, hypomania and the bipolar spectrum: data, theory and clinical issues. J. Affect. Disord., 50 (2–3), 203–213.
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5
DSM-V Perspectives on Classification of Bipolar Disorder Jan Fawcett Department of Psychiatry, University of New Mexico School of Medicine, Albuquerque, NM, USA
It is customary to periodically revise our diagnostic system in the field of psychiatry. This custom is justified on the assumption that over a period of time new information is developed. DSM classifications have been updated over time, periods ranging from 7 to 12 years or more in response to new information concerning the course, treatment response and more recently the familial transmission, genetic factors, biological markers and even neural substrates associated with specific diagnostic categories, as research efforts at all levels yield more information. There is also an implicit assumption that from use of the established criteria in clinical practice and research over time, design flaws inherent in any system will become evident and call for revision to further enhance the clinical utility, reliability and validity of the diagnostic categories.
An overall view of the DSM-V process Thus, the effort to revise the present DSM-IV classification for a planned DSM-V classification intended for publication in 2012, was undertaken in 2007 by the American Psychiatric Association under the direction of David Kupfer MD and Darrel Regier MD. Having been assigned the task of addressing the area of mood disorders, a Mood Disorders Work Group of knowledgeable volunteers was formed, which has been meeting both face-to-face and more frequently by conference calls reviewing the DSM-V classification and relevant scientificclinical literature. Where deemed necessary, we would elect to conduct secondary data analyses directed at specific questions, identify issues for possible revision as well as to recommend field trials to test the feasibility of certain proposed changes. We have also been challenged to reconsider the structure of the overall DSM-V, and to consider new ways to classify disorders that would reflect changes in clinical knowledge or practice as well as emerging knowl-
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edge from neurogenetic, neuroimaging and clinical research findings. Our task is to come up with a revised diagnostic classification that reflects emerging information relevant to validity of disorders and improves clinical utility in a format that, in an age of rapidly emerging new information, will not become obsolete by the time of its publication and will lend itself to the incorporation of emerging findings. We proceeded with this awe-inspiring charge. There is a hope that the resulting DSM-V would be in the greatest possible harmony with the emerging ICD 11 classification of psychiatric disorders. An effort was made to form groups of individuals, with expertise in the study of each group of disorders, into members of diagnostic category workgroups. Suggested revisions and changes reached by consensus in the workgroups will be passed on to a task force chaired by Drs Kupfer and Regier, which will be made up of Diagnosis Work Group Chairs, and various leaders and consultants in psychiatry. which have the task of visualizing the overall structure of the merging DSMV classification for approval, deferral or modification. The Mood Disorders Workgroup covers the categories major depressive disorder and bipolar disorder and all related diagnoses. We divided into sub-workgroups to more effectively work on these sub-categories in parallel. In this process, it was determined that other relevant behavioural dimensional candidates, such as suicide risk, the role of comorbid anxiety and several related categories such as seasonal affective disorder and premenstrual dysphoric disorder deserved thoughtful consideration. To deal with these issues, further sub-workgroups made up of members of the Mood Disorders Workgroup, as well as liaison members from other overlapping workgroups, such as anxiety, personality and psychotic disorders, were sought, supplemented with appointed advisors with specific expertise and research experience in these clinical areas who could make specific valuable contribution to our deliberations and recommendations, were all recruited to participate in this multilayered process. Each sub-workgroup, such as the Bipolar Sub-workgroup, regularly report their areas of discussion, and preliminary
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recommendations to and receives feedback from the entire membership of Mood Disorders Workgroup on conference calls and in face-to-face meetings as the process moves forward. This creates an iterative process where preliminary decisions are revisited by the sub-workgroups and periodically discussed in the entire mood workgroup and when approved, will be forwarded to the task force as recommendations to be considered for inclusion in the new DSM-V structure. This complex and iterative process of seeking and discussing information on questions raised by a review of the overall structure, that is the possibility and feasibility of adding a suicide risk dimension or severity dimension for anxiety to a mood disorder diagnosis, or raised by review of possible specific criteria changes such as the required duration of a symptom, for example the required duration of hypomania for bipolar II disorder and the definition of a mixed depressive state, is proceeding and being discussed by both the major depression and bipolar sub-workgroups, as well as the overall Mood Disorders Workgroup. Because of the resulting six sub-workgroups, with conference calls ranging from every two to four weeks, as well as various related group calls and adding in the task force group calls, an average of two to four calls each week occur in this process. The workgoups meet for face-to-face discussions for two days about every six months.
Ongoing work on bipolar disorder for DSM-V Understanding the review process should make it clear that there is much discussion and evaluation of possible changes for bipolar disorder in DSM-V, though few final decisions have been made at this point in the process. The members of the Bipolar Sub-workgroup include the Sub-workgroup Chairperson Trish Suppes MD, Jules Angst MD, Ray DePaulo MD, Ellen Frank PhD, Ellen Leibenluft MD, who are members of the full Mood Disorders Workgroup, which includes Bill Coryell MD, Lori Davis, MD, David Goldberg MD, James Jackson PhD, Ken Kendler MD, Mario Maj MD, Michael Phillips MD, Carlos Zarate MD and myself, as well as liaisons members from other work groups and advisors, such as Alan Swann MD who had input concerning the issue of mixed states in the Bipolar Subworkgroup and Norman Rosenthal who wrote a review of seasonal affective disorder. Liaison members from other groups, such as Kimberly Yonkers, Uli Witchen and Joen Oldham, also participated at various stages.
Criteria for recommending a change in DSM-IV The Mood Disorders Workgroup agreed on a memorandum that described criteria for recommending a change in
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DSM-IV to the task force. In summary form, this memorandum stated that a recommendation for a signuifiucant change must be sponsored by a workgroup member who would provide a rationale for the change and a review of the literature or other database analyses supporting the change. The greater the significance of the change proposed, the greater the data required to support the change. Unintended consequences of any change and how those changes would be offset by the advantages of the change would be considered. A two-thirds vote of the workgroup would be required for the proposal to be forwarded to the task force for their consideration of the recommendation.
Bipolar disorder Based on discussions of the Bipolar Sub-workgroup and the Mood Disorders Workgroup some interesting issues have emerged. This work is going on at more than one conceptual level. A review of the DSM-IV criteria, such as the possible need to include increased energy or overactivity in the diagnostic criteria and how that could best be accomplished, has been discussed [18].
Bipolar spectrum A consideration of the meaning and relevance of the distinction of mania from hypomania, as well as the utility and validity of the concept of bipolar spectrum disorder, is going on simultaneously and receiving discussion. These discussions are occurring with an awareness of a plethora of articles published over the past 15 years, raising the question of sub-threshold manic symptoms not being recognized by DSM-IV, which would alter the balance of patients diagnosed on the bipolar spectrum, increasing the rate of bipolar spectrum patients to approach the rates of patients diagnosed with true unipolar disorder [1–8,10–12,14–16,18–21,33,35,36,38,40,44,45,50,57,60,62] Some of these articles have suggested that the four-day requirement for the diagnosis of bipolar II disorder in DSM-IV, has resulted in many bipolar spectrum patients being diagnosed as unipolar depression as opposed to a two-day duration of hypomanic symptoms [4,12,16,43,62]. These publications remind us that the original concept of manic depressive disorder included patients on the basis of recurrent affective episodes and not only the occurrence of a full syndrome manic episode [5]. The literature on bipolar spectrum has also pointed out that by having criteria that are too restrictive for the recognition of manic symptoms, may lead patients to suffer from symptoms for years without a correct diagnosis of bipolar disorder and effective treatment [21,36]. For example, the criteria requiring a fourday duration of hypomania has been criticized as a barrier to the correct and timely diagnosis of bipolar disorder by some authors [4,12,62]. Studies have pointed out the negative
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consequences in many patients of ineffective responses and increased risk for suicidal behaviour from the use of antidepressant medications, without consideration of the need for concomitant treatment with mood-stabilizing medications [4,16,19,43,62]. On the other hand, a problem of overdiagnosis of bipolar disorder diagnosis has been raised by Zimmerman et al. [65]. These investigators present results of 700 patients interviewed with the SCID, which is based on DSM-IV criteria. They found that fewer than half of the patients, who reported they had been diagnosed previously with bipolar disorder, were diagnosed with bipolar disorder based on a SCID interview. Patients who self-reported a previous diagnosis of bipolar disorder that was not confirmed by the SCID did not have a significantly higher morbid risk for bipolar disorder than the patients who were negative for bipolar disorder by self-report and the SCID. This finding does not answer the question of what are the best supported criteria for a bipolar diagnosis, but addresses the manner in which various clinicians apply the criteria.
could be improved at the borders of major depression and mild or moderate manifestations of mania, hypomania or mixed states, so that patients who are actually suffering from a bipolar spectrum disorder could be earlier diagnosed and treated. On the other hand, a very high proportion of patients diagnosed with major depression may have isolated (not concurrent) manic symptoms over their course without developing bipolar disorder. In addition, with respect to a bipolar spectrum, it has been found that the clinical outcome of bipolar I and bipolar II patients is distinct enough to merit designation into these categories.
Rapid cycling bipolar disorder Thus far, the specifier of rapid cycling bipolar disorder with the DSM-IV criteria of four affective episodes in the past year has been found to be clinically useful without need of modification by the workgroup.
Bipolar depression Mixed episodes The issue of mixed manic-hypomanic and depressive states is being considered with a trend toward extending mixed states across the entire severity range of bipolar bisorder. According to DSM-IV, a mixed episode occurs only as a part of bipolar disorder, and it requires the presence of full major depression and full mania, although the literature suggests that mixed depressive states are being found throughout the spectrum of bipolar patients, as well as in patients diagnosed with unipolar depression [9,13,17,22,24,27,30,33,37,42,52,58]. Of course, there are questions of the borders between bipolar and recurrent unipolar disorder. It has been found that the incidence of unipolar depression is as great or greater than bipolar disorder in family members, while the incidence of bipolar disorder is greater in families with bipolar disorder than those without [8,25,38,63]. The issues of bipolar spectrum, and sub-threshold bipolar states, as well as the capturing of episodes of mixed states, could have a significant effect on the proportion of patients diagnosed as in the bipolar spectrum versus unipolar depression. However, a report of an analysis comparing the course of BP I versus BP II patients concluded that the phenotypes of bipolar I and bipolar II disorder are likely to exist in a disease spectrum, but since they are sufficiently distinct in their long-term outcomes (more severe episodes in BP I patients and more chronic course with a predominance of depression in BP II patients), they are best classified as two separate subtypes in official classification syndromes [39]. It appears that a significant proportion of patients classified as unipolar major depressive may ultimately be found to be in the bipolar spectrum, and perhaps they could be classified on a severity spectrum. It seems that diagnosis
Bipolar depression and its clinical characteristics relative to treatment outcome is also a concern. Is it the same as unipolar major depression or are there differences that should be recognized? The data from the large STEP-BD study showing that adjunctive SSRI antidepressants or buprorion versus placebo added double blind to mood stabilizers or atypical antipsychotics in bipolar depressed patients, showed that the efficacy as measured by durable recovery of these antidepressants was only 23% versus a 27% response for placebo over 26 weeks [53]. Further reports from STEP-BD find that anidepressants do not assist in depressive recovery in bipolar depression accompanied by symptoms of mania, and are likely to increase symptoms of dysphoria, irritablity and middle waking, [34]. The STEPBD studies of antidepressant efficacy and effectiveness certainly raise questions as to differences in treatment response, particularly in those patients with the presence of depression with manic symptoms (mixed depression) or a history of mood switching in past trials of antidepressants [6,34,48]. Another study of self reported mood switching, within 12 weeks of starting antidepressant medications, found that 44% reported at least one episode in the 338 bipolar patients studied [49]. The risk of treatment-emergent mania was found to be greatest in bipolar patients with a short duration of illness, multiple past antidepressant trials and a past history of switch with at least one antidepressant. A treatment study of 176 adult outpatients with bipolar depression over 10 weeks found that 85 responded to treatment, 45 did not respond and 46 patients had treatment-emergent mania or hypomania [30]. YMRS items of increased motor activity, pressured speech and racing thoughts were significantly associated with the outcome of mood switching in this sample. This chapter suggests that
DSM-V Perspectives on Classification
screening for mild manic symptoms would help predict patients likely to develop manic symptomatology in response to antidepressant treatment. It is interesting that some of the same symptoms are noted in patients diagnosed with unipolar major depression who later develop manic or hypomanic behaviour. Perhaps more sensitive criteria for mixed depressive and mixed manic or hypomanic states would help to sort out candidates with bipolar depression from those with unipolar depression more accurately and earlier in their course. Is bipolar depression really the same condition as unipolar depression? If not, is there a difference in symptom criteria? The Collaborative Depression Study, reported an 11-year follow-up of major depression revealing an 8.6% rate of conversion to bipolar II disorder and a 3.9% conversion rate to bipolar I Disorder – total conversion rate 12.5% [6]. The patients who converted were found to have early onset of depression, high rates of substance abuse and a high incidence of social turmoil and antisocial acts. Mood labiality alone was the most sensitive predictor (86%), though of lower sensitivity (42%). Habitual self descriptions of temperamental instability attained a predictive sensitivity of 91%. A study reported in 2007 of 744 outpatients followed since 1981–1986, found an incidence of lifetime mania of 27%, significantly associated with three factors: age of onset of depression, family history of mania and increased psychotic symptoms [48]. Another study reported on a 15-year follow-up of 74 patients with an average age of 23, were hospitalized for major depression and found that 27% had developed on or more distinct patterns of hypomania, while an additional 19% had at least one episode of bipolar I mania [26]. These investigators found that young patients with psychotic features were at particularly high risk for eventually developing mania. A recent study of 269, predominantly outpatients diagnosed as unipolar major depression and followed over 5 years, reported that 8.9% of patients diagnosed with unipolar major depression that then had a switch into symptoms of mania or hypomania and 2.8% switched to Type I when treated with antidepressant medications, also contribute to this issue [59]. One treatment study of unipolar depressed inpatients found a manic/hypomanic switch rate of 13.1%, and then compared these patients with 245 patients who did not show any switch [49]. The patients who developed a switch in response to antidepressants tended to be male and to have a higher proportion of family history of bipolar disorder. Mitchell and colleagues [45] have pointed out that while there is no point of rarity between bipolar depression and unipolar major depression, there are clinical characteristics that are more common in each form of depression. Features more common in patients who convert or later develop hypo/manic symptoms are: atypical symptoms such as hypersomnia, hyperphagia, and leaden paralysis, psychomotor retardation, psychotic features and/or path-
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ological guilt and lability of mood. Bipolar depressed patients are more likely to have an earlier age of onset of their first depressive episode, to have more prior episodes of depression, to have shorter episodes of depression and a family history of bipolar disorder. Unipolar depression patients were found to have initial insomnia/reduced sleep, appetite or weight loss, normal or increased activity levels, somatic complaints, later age of onset of first episodes, prolonged episodes and no family history of bipolar disorder. The authors suggest that a probabilistic approach to the diagnosis of bipolar/unipolar depression be developed, based on the appearance of these clinical characteristics. A subsequent study by the same group [46,47] of 217 patients with bipolar disorder with standardized interviews with a comparison with a Stanley Foundation Bipolar Disorders Network (SFBN) sample, as well as a STEP-BD sample, found sociodemographic similarities across the three samples, between samples for positive family history of bipolar disorder (40%) and unipolar depression (55%). The comparison also found similar proportions with the STEP-BD sample reporting earlier age of onset and the SFBN sample reporting higher numbers of overall episodes, but psychotic episodes and suicide attempts were less common than in the Australian sample. A recent study by Goldberg et al. [35], of 1380 STEP-BD bipolar patients with depressive episodes, found that two-thirds of this sample had concurrent manic symptoms, most often distractibility, flight of ideas, or racing thoughts and psychomotor agitation. Patients with mixed features were more likely to have an early age of onset, rapid cycling in the past year, suicide attempts and more days in the preceeding year with irritability or mood elevation. The authors conclude that manic symptoms often accompany bipolar depression, but are often overlooked when they appear less prominent than depressive features and subsyndromal manic symptoms during bipolar I or II depression demarcate a more common, severe and complex clinical state than pure bipolar depression.
Schizoaffective disorder The diagnosis of schizo-affective disorder is a contentious problem shared by the Mood Disorders Workgroup and the Psychosis Workgroup. While in its current form it has turned out to have rather low reliability, it has been found by Tohen et al. to be the most commonly used second diagnosis in a group of patients initially diagnosed as psychosis NOS. Currently, it seems that the Psychosis Workgroup is recommending that it be dropped and diagnosed by using the diagnosis of schizophrenia with a behavioural dimension of mania or depression. Because schizoaffective disorder is one of the most frequently used diagnoses, at this point it has been decided that the diagnosis will be retained in DSM-V changes in the wording of
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the criteria which will hopefully increase the reliability of this diagnosis. The psychosis Workgroup has currently proposed to retaine the diagnosis because of the frequency of its use, with changes in the diagnostic criteria aimed at making the diagnosis more reliable than it currently is.
Paediatric bipolar disorder The issue of diagnosing bipolar disorder in children is also a major issue. Bipolar disorder has a serious prognosis and often requires treatment with powerful medications that may have serious side effects and in some cases long-term medical risks, so when relying on symptom presentations and history as contrasted with laboratory tests, having the most effective diagnostic criteria is of great concern. It appears that irritability, although certainly common in bipolar disorder at all ages, is quite a promiscuous symptom across a range of diagnoses and may not be very useful in discriminating bipolar disorder from other disorders. Separating bipolar disorder from ADHD and Oppositional Defiant Disorder in children is a concern [55]. A recent study of 637 youths with a 10 item scale demonstrated good discrimination between bipolar disorder and attention deficit disorder, and showed that parents most notice elated mood, high energy, irritability and rapid changes in mood and energy as the prominent features of juvenile bipolar disorder [56,64]. The question has been raised whether children with bipolar disorder manifest shorter (as short as four hours) episodes occurring frequently over periods such as four days. This would suggest the possibility of different criteria for paediatric bipolar disorder than those currently in place for adults. On the other hand, there are obvious concerns for overdiagnosis as there must be a balance of overdiagnosis versus Underdiagnosis of paediatric bipolar disorder. A field test of criteria and further discussions with the Developmental/Lifespan Issues Task Force Committee will be required to decide this issue. A recent eight-year follow-up study of children diagnosed with bipolar disorder, showing an over 40% of recurrent mania once they are over the age of 18, provides a much needed confirmation of the potential for the accurate diagnosis of bipolar disorder in children [32]. However, concern has been expressed regarding the method of diagnosis utilized for the over-18 group in this study. It is also of great interest and importance that this study also documented a very high incidence (over 90%) of ultradian cycling (cycles of a minimum of four-hour switches) with an interview that is sensitive to this phenomenon, suggesting that it is common, but often not captured in clinical interviews. A study critically reviewing the phenomenology of paediatric bipolar disorder, the specificity of symptoms and the validity of the diagnostic construct found good support, but areas of disagreement over the use of elated mood versus irritability, and the limitations of the entity of bipolar dis-
order NOS in children [31,64]. A recent report, looking at the relative incidence of childhood-onset bipolar disorder reported by adult bipolar patients, found a 61% incidence in US patients compared with 30% report of childhood in the Netherlands or Germany [30,51]. This study found twice the genetic/familial risk for affective disorder and twice the incidence in childhood adversity in the United States. In a group of 480 adult outpatients carefully diagnosed with bipolar disorder, 14% reported an onset before age 12 and 36% reported onset in adolescence. The childhood-onset group reported an average 16-year delay until they received treatment, and both the childhood-onset and adolescentonset group had more episodes, more comorbidity and a more severe course [41]. It appears that childhood-onset bipolar onset diagnosis may not be made early enough, but that there might be disagreement around the milder forms (bipolar disorder NOS) that require attention to assure accurate, but timely diagnosis and treatment.
Behavioural dimensions In addition to an ongoing review of criteria for the diagnosis of bipolar mania, hypomania, depression, mixed states and various age-related presentations, the concept of being able to convey more useful clinical information by combining behavioural dimensions with diagnostic categories and how to do this and at the same time maintain clinical utility, is under consideration [7,61]. One candidate is a universal behavioural dimension, which might be rated as a severity dimension across diagnoses, is the presence of comorbid anxiety that emerges with the disorder, rather than as a primary comorbid anxiety disorder. Even the presence of a comorbid anxiety disorder might mean more if rated on a simple severity scale as done using the SADS-C psychic anxiety scale, which rates severity using both the intensity experienced by the patient as well as the time of the patients day dominated by anxiety [27]. The basis for this consideration is the fact that comorbid severe anxiety is not widely recognized as a high priority treatment target, while recent studies show that it is a robust predictor of poor outcome and suicidal behaviour in bipolar disorder and the range of affective disorders. Studies have shown it is very prevalent (40–50%) in bipolar disorder. If the patient meets criteria for a diagnosable anxiety disorder, this diagnosis can be made as a comorbid Axis I diagnosis, but not uncommonly the anxiety symptoms may emerge with the bipolar symptomatology and be ignored diagnostically and by under-treatment of a bipolar patient with comorbid anxiety, resulting in poor outcomes and an elevation of suicide risk [55,56]. It has also been reported that a comorbid anxiety disorders diagnosis predicts an increased risk of suicide (HR ¼ 1.81) in bipolar patients [54]. Fawcett et al. [29] found that severity of psychic anxiety in both bipolar and unipolar patients was signifi-
DSM-V Perspectives on Classification
cantly correlated with suicide risk over one year from the time of assessment. (See Chapter 7, Suicide and Bipolar Disorder). Recently, Coryell et al., studied the severity of psychic and somatic anxiety measured at baseline by the SADS-C rating scale, which was found significantly linearily correlated with time spent in a depressive episode stepwise by severity rating, over a 20-year follow-up period. Psychic anxiety severity was the strongest single correlate of time spent in depressive episodes of a 20-year follow-up [23]. It is interesting that a similar report concerning poor outcomes with antidepressant treatment has been recently made from the STAR D study of treatment outcome in patients with unipolar major depression. Anxiety severity has also be related to poor outcome in unipolar depressive patients treated in the STAR D Study [28]. This data supports the addition of a psychic anxiety dimension to all of the mood disorder diagnoses, including bipolar spectrum disorder has well as perhaps across other diagnostic categories. This clinically significant behavioural dimension, which is extrinsic to criteria for the diagnosis, would call attention to the need for treatment of anxiety symptoms and further collection of data on the significance of co-existing anxiety severity for each diagnostic category, without prematurely changing criteria for the diagnostic category. A simple scale, such as the SADS-C, would lend itself to easy use by clinicians that would not be a burden, but would increase the data available for treatment planning. A decision to add extrinsic (supraordinate) as well as intrinsic (criteria symptom severity dimensions) dimensional severity measures would be a major change in the conceptual structure of DSM-V, if adopted. Adding certain extrinsic behaviour dimensions, such as severity of psychic anxiety and severity and immediacy of suicide risk, could result in an important increase in relevant clinical information conveyed and improve the treatment of patients as well as lead to further valuable research outcome data, which could result in further progress. It has become clearer that the criteria presently used for the diagnosis of bipolar disorder as well as other diagnoses may limit our clinical perspective, by limiting the focus of our treatment efforts in such a way as to ignore important clinical dimensions presently not included in the diagnostic criteria, but which are critical to our patients clinical outcome. These issues are complex and raise the issue of clinical utility, which is a major consideration in the DSM-V process. A concept of bipolar disorder as a spectrum spanning a range of severity from very severe, psychotic behaviour to a recurrent disorder with subtle and short-lived 1–2 day bouts of hypomania followed by long episodes of depression, to traits of mood instability and periodic flamboyant behaviour that may not require treatment, may be more effective in arriving at severity cut points. True severity may also depend on comorbid symptomatology, such as substance
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abuse or anxiety severity as well as measures of disability. Such a choice might expand the numbers of patients formerly diagnosed with unipolar depression who receive an early bipolar diagnosis and result in a considerable increase in bipolar spectrum diagnoses in patients with recurrent mood disorders, relative to unipolar major depression. Adding behavioural dimensions across bipolar disorder and other diagnostic categories might considerably expand our treatment efforts and provide new targets for treatment and treatment development, resulting in improved outcomes for mood disorder and patients with other disorders. The DSM-V will need to be able to serve many masters. Busy clinicians will want it to be as simple and easy to use as possible and will not want to be burdened with changes that do not result in an obvious improvement in their practice. Research investigators will guard against changes that will diminish the value of previously collected large datasets resulting from any major changes in criteria and will set a high threshold of data driven support for proposed changes. Others will be wedded by years of hard work to certain clinical concepts and will demand solid empirical support for changes. Insurers and health care payers will be sensitive to changes, which might increase utilization and treatment expense. Ultimately, it is my hope that DSM-V can move the field ahead, with a diagnostic system that will improve treatment and encourage research in areas that need the greatest attention, by addressing newly developed knowledge and the inevitable design flaws that result in any diagnostic system. Hopefully, we can help clinicians to be more responsive to important facets and contribute to more effective treatment of the disorders we treat.
References 1. Akiskal, H.S. (2007) The emergence of bipolar spectrum: Validation among Clinical-Epidemiologic and FamilialGenetic Lines. Psychopharmacol. Bull., 40 (4), 99–115. 2. Akiskal, H.S. (1996) The prevalent spectrum of bipolar disorders:beyone DSM-IV. J. Clin. Psychopharmacol., 16 (2 suppl 1), 48–148. 3. Akiskal, H.S., Aksikal, K.K., Lancrenon, S. and Hantouche, E. (2006) Validating the soft bipolar spectrum in the French National EPIDEP Study: the prominence of BP II1/2. J. Affect. Disord., 96 (3), 207–213. 4. Akiskal, H.S. and Benazzi, S. (2005) Optimizing the detection of bipolar II disorder in outpatient practice: toward a systemization of diagnostic wisdom. J. Clin. Psychiatry., 66 (7), 914–921. 5. Akiskal, H.S., Bourgeois, M.L., Angst, J. et al. (2000) Reevaluating the prevalence and diagnostic composition within the broad clinical spectrum of bipolar disorders. J. Affect. Disord., 59 (Suppl 1), S5–S30. 6. Akiskal, H.S., Maser, J.D., Zeller, P.J. et al. (1995) Switching from unipolar to bipolar II. An 11-year prospective study of
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7.
8.
9. 10. 11.
12.
13.
14.
15. 16.
17.
18.
19.
20.
21.
22.
23.
24. 25.
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clinical and temperamental predictors in 559 patients. Arch. Gen. Psychiatry, 52 (2), 114–123. Allardyce, J., McCreadie, R.G., Morrison, G. and Van Os, J. (2007) Do symptom dimensions or categorical diagnoses best discriminate between known risk factors for psychosis? Soc. Psychiatry Psychiatr. Epidemiol., 42 (6), 429–437. Andreasen, N.C., Rice, J., Endicott, J. et al. (1987) Familial rates of affective disorder. A report for the National Institute of Mental Health Collaborative 3 study. Arch. Gen. Psychiatry, 44 (5), 461–469. Angst, J. (2007) The bipolar spectrum. Comment in Brit. J. Psychiatry, 190, 189–191. Angst, J. and Cassano, G. (2005) The mood spectrum: improving the diagnosis of bipolar disorder. Bipolar Disord., 7 (Suppl 4), 4–12. Angst, J. and Gamma, A. (2008) Diagnosis and course of affective psychoses: was Kraeplin right? Eur. Arch. Psychiatry Clin. Neurosci., 258 (Suppl 2), 107–110. Angst, J., Gamma, A., Benazzi, F. et al. (2003) Diagnostic issues in bipolar disorder. Eur. Neuropsychopharmacol., 13 (Suppl 2), S42–S50. Angst, J., Gamma, A., Sellaro, R. et al. (2003) Recurrence of bipolar disorders and major depression. A life-long perspective. Eur. Arch. Psychiatry Clin. Neurosci., 253 (5), 236–240. Bader, C.D. and Dunner, D.L. (2007) Bipolar disorder not otherwise specified in relation to the bipolar spectrum. Bipolar Disord., 9 (8), 860–867. Benazzi, F. (2007) Bipolar II disorder: epidemiology, diagnosis and management. CNS Drugs, 21 (9), 727–740. Benazzi, F. (2007) Testing predictors of bipolar-II disorder with a 2-day minimum duration of hypomania. Psychiatr. Res., 153 (2), 153–162. Epub 2007 Jul 16. Benazzi, F. (2007) Mixed depression and the dimensional view of mood disorders. Psychopathology., 40 (6), 431–439, Epub 2007 Aug 20. Benazzi, F. (2007) Is overactivity the core feature of hypomania in bipolar II disorder? Psychopathology, 40 (1), 54–60, Epub 2006 Oct 25. Benazzi, F. and Akiskal, H.S. (2008) How to best study a bipolar-related subtype among major depressive patients without spontaneous hypomania: superiority of age at onset criterion over recurrence and polarity? J. Affect. Disord., 107 (1–3), 77–88. Benazzi, F. (2006) Symptoms of depression as possible markers of bipolar II disorder. Prog. Neuropsychopharmacol. Biol. Psychiatry, 30 (3), 471–477, Epub 2006 Jan 19. Calabrese, J.R. (2008) Overview of patient care issues and treatment in bipolar spectrum and bipolar II disorder. J. Clin. Psychiatry., 69 (6), e18. Cassano, G.B., Mula, M., Rucci, P. et al. (2009) The structure of lifetime manic-hypomanic spectrum. J. Affect. Disord., 112 (1–3), 59–70. Coryell, W., Solomon, D. and Fiedorowicz, J. et al. (2009) Anxiety and outcome in bipolar disorder. American Journal of Psychiatry, 166 (11), 1238–1243. Dilsaver, S.C. and Benazzi, F. (2008) Diagnosing depressive mixed states in bipolar disorders. J. Clin. Psychiatry, 69 (7), e19. Edmonds, L.K., Mosely, B.J., Admiraal, A.J. et al. (1998) Familial bipolar disorder: preliminary results from the Otago
26.
27.
28.
29.
30.
31.
32.
33.
34.
35.
36.
37.
38.
39.
40.
familial bipolar genetic study. Aust. NZ J. Psychiatry, 32 (6), 823–829. El-Mallakh, R.S., Ghaemi, S.N., Sagduyu, K. et al. (2008) STEP-BD investigators. Antidepressant-associated chronic irritable dysphoria (ACID) in STEP-BD patients. J Affect Disord., 111 (2–3), 372–377, Epub 2008 Jun 20. Endicott, J. and Spitzer, R.L. (1987) (Schedule for Affective Disorders and Schizophrenia (SADS)). Acta. Psychiatr. Bela., 87 (4), 361–516. Fava, M., Rush, A.J., Alpert, J.E. et al. (2008) Difference in treatment outcome in outpatients with anxious versus nonanxious depression: a STAR D report. Am. J. Psychiatry., 165 (3), 342–351, Epub 2008 Jan 2. Fawcett, J., Scheftner, W.A., Fogg, L. et al. (1990) Time-related predictors of suicide in major affective disorder. Am. J. Psychiatry, 147 (9), 1189–1194. Frye, M.A., Helleman, G., McElroy, S.L. et al. (2008) Correlates of treatment-emergent mania associated with antidepressant treatment in bipolar depression. Am. J. Psychiatry., (2009) Feb; 166 (2),164–72. Galanter, C.A. and Leibenluft, E. (2008) Frontiers between attention deficit hyperactivity disorder and bipolar disorder. Child Adolesc. Psychiatr. Clin. N. Amer., 17 (2), 325–346, viii–ix. Geller, B., Tillman, R., Bolhofner, K. et al. (2008) Prospective continuity with adult bipolar I disorder; characteristics of second and third episodes; predictors of 8-year outcome. Arch. Gen. Psychiatry, 65 (10), 1125–1133. Goldberg, J.F., Harrow, M. and Whiteside, J.E. (2001) Risk for bipolar illness in patients initially hospitalized for unipolar depression. Am. J. Psychiatry, 158 (8), 1265–1270. Goldberg, J.F., Perlis, R.H., Ghaemi, S.N. et al. (2007) Adjunctive antidepressant use and symptomatic recovery among bipolar depressed patients with concomitant manic symptoms: findings from the STEP-BD. Am. J. Psychiatry, 164 (9), 1348–1355. Goldberg, J.F., Perlis, R.H. Bowden, C.L. et al. (2009) Manic symptoms during depressive episodes in 1380 patients with bipolar disorder: findings from the STEP-BD. Am. J. Psychiatry, 166 (2), 173–181. Hirschfeld, R.M. (2001) Bipolar spectrum disorder: improving its recognition and diagnosis. J. Clin. Psychiatry, 62 (Suppl 14), 5–9. Holma, K.M., Melartin, T.K., Holma, I.A. and Isometsa, E.T. (2008) Predictors for switch from unipolar major depressive disorder to bipolar disorder type I or II: a 5-year prospective study. J. Clin. Psychiatry, 69 (8), 1267–1275. Joyce, P.R., Doughty, C.J., Wells, J.E. et al. (2004) Affective disorders in the first-degree relatives of bipolar probands: results from the South Island Bipolar Study. Compr. Psychiatry, 45 (3), 168–174. Judd, L.L., Akiskal, H.S., Schettler, P.J. et al. (2003) The comparative clinical phenotype and long-term longitudinal episode course of bipolar I and II: a clinical spectrum or distinct disorders? J. Affect. Disord., 73 (1–2), 19–32. Kessler, R.C., Akiskal, H.S., Angst, J. et al. (2006) Validity of the assessment of bipolar spectrum disorders in the WHO CIDI 3.0. J. Affect. Disord., 96 (3), 259–269.
DSM-V Perspectives on Classification 41. Leverich, G.S., Post, R.M., Keck, P.E. Jr et al. (2007) The poor prognosis of childhood-onset bipolar disorder. J. Pediatr., 150 (5), 485–490. 42. Maj, M., Pirozzi, R., Magliano, L. et al. (2006) Agitated “unipolar” major depression: prevalence, phenomenology, and outcome. J. Clin. Psychiatry, 67 (5), 712–719. 43. Mak, A.D. (2009) Prevalence and correlates of bipolar II disorder in major depressive patients at a psychiatric outpatient clinic in Hong Kong. J. Affect. Disord., 112 (1–3), 201. 44. McElroy, S. (2008) Understanding the complexity of bipolar mixed episodes. J. Clin. Psychiatry, 69 (2), e06. 45. Merikangas, K.R., Akiskal, H.S., Angst, J. et al. (2007) Lifetime and 12-month prevalence of bipolar spectrum disorder in the National Comorbidity Survey replication. Arch. Gen. Psychiatry, 64 (5), 543–552. 46. Mitchell, P.B., Goodwin, G.M., Johnson, G.F. and Hirschfeld, R.M. (2008) Diagnosic guidelines for bipolar depression: a probabilistic approach. Bipolar Disorder, 10 (1 Pt 2), 144–152. 47. Mitchell, P.B., Johnson, A.K., Corry, J. et al. (2009) Characteristics of bipolar disorder in an Australian specialist outpatient clinic: comparison across large datasets. Aust. NZ Psychiatry, 43 (2), 109–117. 48. Othmer, E., Desouza, C.M., Penick, E.C. et al. (2007) Indicators of mania in depressed outpatients: a retrospective analysis of data from the Kansas 1500 study. J. Clin. Psychiatry, 68 (1), 47–51. 49. Perlis, R.H., Brown, E., Baker, R.W. and Nierenberg, A.A. (2006) Clinical features of bipolar depression versus major depressive disorder in large multicenter trials. Am. J. Psychiatry, 163 (2), 225–231. 50. Perugi, G. and Akiskal, H.S. (2002) The soft bipolar spectrum redefined: focus on the cyclothymic, anxious-sensitive, impulse-dyscontrol, and binge-eating connection in bipolar II and related conditions. Psychiatr. Clin. North Am., 25 (4), 713–737. 51. Post, R.M., Luckenbaugh, D.A., Leverich, G.S. et al. (2008) Incidence of childhood-onset bipolar illness in the USA and Europe. Br. J. Psychiatry, 192 (2), 150–151. 52. Rihmer, A., Gonda, X., Balazs, J. and Faludi, G. (2008) The importance of depressive mixed states in suicidal behavior. Neuropsychopharmacol. Hung., 10 (1), 45–49. 53. Sachs, G.S., Nierenberg, A.A., Calabrese, J.R. and Marangell, L.B. (2007) Effectiveness of adjunctive antidepressant treatment for bipolar depression. N. Engl. J. Med., 356 (17), 1711–1722, Epub 2007 Mar 28.
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54. Simon, G.E., Hunkeler, E., Fireman, B. et al. (2007) Risk of suicide attempt and suicide death in patients treated for bipolar disorder. Bipolar Disord., 9 (5), 526–530. 55. Simon, N.M., Otto, M.W., Weiss, R.D. et al. (2004) STEP-BD investigators. Pharmacotherapy for bipolar disorder and comorbid conditions: baseline data from STEP-BD. J. Clin. Psychopharmacol., 24 (5), 512–520. 56. Simon, N.M., Zalta, A.K., Otto, M.W. et al. (2007) The association of comorbid anxiety disorders with suicide attempts and suicidal ideation in outpatients with bipolar disorder. J. Psychiatr. Res., 41 (3–4), 255–264, Epub 2006 Oct 18. 57. Smith, D.J., Ghaemi, S.N. and Craddock, N. (2008) The broad spectrum of bipolar disorder: implications for research and practice (Clinical report). Journal of Psychopharmacology, 22.4, 397. 58. Suppes, T., Mintz, J., McElroy, S.L. et al. (2005) Mixed hypomania in 908 patients with bipolar disorder evaluated prospectively in the Stanley Foundation Bipolar Treatment Network: a sex-specific phenomenon. Arch. Gen. Psychiatry, 62 (10), 1089–1096. 59. Truman, C.J., Goldberg, J.F., Ghaemi, S.N. et al. (2007) Selfreported history of manic/hypomanic switch associated with antidepressant use: data from the Systematic Treatment Enhancement Program for Bipolar Disorder (STEP-BD). J. Clin. Psychiatry, 68 (10), 1472–1479. 60. Vieta, E. (2008) Defining the bipolar spectrum and treating bipolar II disorder. J. Clin. Psychiatry, 69 (4), e12. 61. Vieta, E. and Phillips, M.L. (2007) Deconstructing bipolar disorder: a critical review of its diagnostic validity and a proposal for DSM-V and ICD-11. Schizophren Bull., 33 (4), 886–892, Epub 2007 Jun 11. 62. Vieta, E. and Suppes, T. (2008) Bipolar II disorder: arguments for and against a distinct diagnostic entity. Bipolar Disord., 10 (1 Pt 2), 163–178. 63. Weissman, M.M., Gershon, E.S., Kidd, K.K. et al. (1984) Psychiatric disorders in the relatives of probands with affective disorders. The Yale University-National Institute of Mental Health Collaborative Study. Arch. Gen. Psychiatry, 41 (1), 13–21. 64. Youngstrom, E.A., Birmaher, B. and Findling, R.L. (2008) Pediatric bipolar disorder: validity, phenomenology, and recommendations for diagnosis. Bipolar Disord., 10 (1 Pt 2), 194–214. 65. Zimmerman, M., Ruggero, C.J., Chelminski, I. and Young, D. (2008) Is bipolar disorder over-diagnosed? J. Clin. Psychiatry, 69 (6), 935–940.
CHAPTER
6
Update on the Epidemiology of Bipolar Disorder Kathleen R. Merikangas and Tracy L. Peters Genetic Epidemiology Research Branch, Mood and Anxiety Program, Intramural Research Program, National Institute of Mental Health, National Institute of Health, Bethesda, MD, USA
Introduction During the past decade, the results of numerous international epidemiologic surveys using contemporary diagnostic criteria have strengthened the evidence base on the magnitude, correlates and consequences of bipolar disorder in representative samples of the general population. This work has highlighted the dramatic personal and societal impact of bipolar disorders I and II (DSM IV). The estimated disability-adjusted life years of bipolar disorder outrank all cancers and primary neurologic disorders such as epilepsy and Alzheimers disease, primarily because of its early onset and chronicity across the life span [1]. The aims of this chapter are: (1) to provide a background on epidemiology; (2) to summarize the epidemiology of bipolar disorder in adults and youth; (3) to summarize the risk factors for bipolar disorder; and (4) to discuss the family genetics of bipolar disorder.
Background on epidemiology Epidemiology is defined as the study of the distribution and determinants of diseases in human populations. Epidemiologic studies are concerned with the extent and types of illnesses in groups of people and with the factors that influence their distribution. Epidemiologists investigate the interactions that may occur amongst the host, agent and environment (the classic epidemiologic triangle) to produce a disease state. The important goal of epidemiologic studies is to identify the aetiology of a disease in order to prevent or intervene in the progression of the disorder. To achieve this goal, epidemiologic studies generally proceed from studies that specify the prevalence and distribution of a disease within a population by person, place and time (i.e. descriptive epidemiology) to more focused studies of the determinants of the disease in specific groups (i.e. analytic epidemiology) [2].
Bipolar Disorder: Clinical and Neurobiological Foundations Edited by Lakshmi N. Yatham and Mario Maj © 2010 John Wiley & Sons, Ltd. ISBN: 978-0-470-72198-8
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Descriptive epidemiologic studies are important in specifying the rates and distribution of disorders in the general population. The two major estimates of rates in epidemiology are prevalence and incidence. Both are based on the goal of identifying the proportion of cases of a particular index disease in a defined population. Prevalence rates are the number of existing cases in a defined population during a specified time period; incidence rates are the number of new cases of a disorder in a defined population during a specified time period of observation. Incidence rates are derived from prospective cohort studies. Most prevalence estimates in psychiatry include lifetime (the number of cases at any time in the lifetime of respondents, irrespective of whether the disorder is current), 12-month (the number of cases in the population during the past year) and point prevalence (the number of cases at the time of the survey). The most common estimates of prevalence in children are either point or one-year, because of the lack of reliability of lifetime estimates. Prevalence and incidence rates are generally adjusted for sex and age of the base population [2]. Epidemiologic studies are also designed to identify risk factors that influence the base rates of diseases in the general population. Differential distribution by sex, age, ethnicity, geographic site or by exposure to particular risk factors provides clues that may be tested systematically with casecontrol designs. These studies compare the association between a particular risk factor or disease correlate and the presence or absence of a given disease, after controlling for relevant confounding variables. Case-control studies generally proceed from retrospective designs defined by the presence or absence of a disease in the cases and controls, in order to identify potential associations between a particular risk factor or set of risk factors, and prospective cohort studies where the cases and controls are defined by the presence or absence of a putative risk factor, and followed prospectively to examine differential incidence of the disease. Community study data can also be applied to identify biases that may exist in treated populations and to construct case registries from which persons may serve as probands
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for analytic epidemiologic studies. Such attention to sampling issues is a major contribution of the epidemiologic approach, as individuals identified in clinical settings often constitute the top of the iceberg of the disease, and may not be representative of the general population of similarly affected individuals with respect to demographic, social or clinical characteristics [2].
Epidemiology of bipolar disorder in adults Prevalence rates Comprehensive summaries of international studies of the prevalence of bipolar disorder over the past 25 years have been provided in several subsequent published reviews [3–8]. The aggregate cross-study estimate of the lifetime prevalence of bipolar disorder is about 1.0%. Only one of the reviews of the epidemiology of bipolar disorder includes Bipolar II (BP II) and bipolar spectrum disorders [4]. As expected, it was found that the median rates increase with successively less restrictive definitions of bipolar disorder; the median lifetime prevalence rate of BP II was 1.2%, and of bipolar spectrum was 2.9%. The only systematic difference that has been found to explain the variation in rates is the actual diagnostic interview employed to generate the criteria for bipolar disorder [7]. A summary of the 12-month and lifetime prevalence rates of BP I and BP II, as defined by DSM-IV criteria, is presented in Table 1. The aggregate cross-study estimate of the lifetime
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prevalence of bipolar disorder is 1.2%, with a range of 0.0% in Nigeria [9] to 3.3 in the United States [10]. Despite these outliers, the prevalence rates of bipolar I disorder are highly consistent across studies. The lifetime prevalence rates cluster at about 1.0%, whereas the average 12-month prevalence rate is only slightly lower with a median of 0.8%, with a range from 0.2–1.8%. The prevalence of BP II was only assessed in a few studies [11–13]. Two recent studies also reported on prevalence of bipolar disorder defined by ICD10 criteria. The lifetime prevalence of ICD-10 BP I was 1.8 in Ethiopia [14] and the 12-month prevalence in Ireland was 0.2 [15]. Finally, the lifetime prevalence of DSM-III defined BP I and BP II combined was 1.6 in the NHANES survey in the United States [16]. With increased interest in evaluating the validity of the thresholds of mania and its core components, investigators are beginning to test different thresholds in general community samples. Application of the concept of sub-threshold bipolarity to the Zurich Cohort Study demonstrated the enormous consequences of varying definitions of diagnostic criteria for symptoms, duration and impairment. The broader criteria yielded rates of 5.3% for bipolar II disorder, 3.2% for minor bipolar disorder and 3.3% for hypomania [17]. Similar rates emerged from a re-analysis of the Epidemiologic Catchment Area study by Judd et al. (2003), who reported that 5.1% of the population met criteria for lifetime sub-threshold mania/hypomania [18]. Likewise, expansion of the definition of hypomania in the NCS-R study yielded a lifetime prevalence rate of 4.5% [12,19].
Table 1 Rates of DSM-IV bipolar disorders in community samples of adults. LOCATION
Study
AGE
Sample size
Method
Diagnosis
Lifetime prevalence (%)
12-Month prevalence (%)
Male Female Total Male Female Total China Germany Iraq Israel Japan Lebanon Mexico New Zealand Nigeria Switzerland United States
Lee et al. [70] Jacobi et al. [71] Alhasnawi et al. [72] Levinson et al. [73] Kawakami et al. [74] Karam et al. [75] Medina-Mora et al. [76] Baxter et al. [38] Gureje et al. [9] Angst et al. [77] Grant et al. [10] Ford et al. [78] Merikangas et al. [12]
18–70 18–65 18 21 20 18 18–65
5201 4181 4332 4859 1664 2857 5826
WMH-CIDI/DSM-IV M-CIDI/DSM-IV WMH-CIDI/DSM-IV WMH-CIDI/DSM-IV WMH-CIDI/DSM-IV CIDI 3.0/DSM-IV WMH-CIDI/DSM-IV
Bipolar I/Bipolar II Any Bipolar Bipolar Disorder Bipolar Disorder Bipolar I/Bipolar II Bipolar Disorder Bipolar I/Bipolar II
— 0.8 — — — 2.6 —
— 1.2 — — — 2.3 —
0.1 1.0 0.2 0.7 — 2.4 1.9
— 0.6 — — — — —
— 1.1 — — — — —
— 0.8 0.2 0.1 0.1 — —
16–64 18 40 12 55 18
12 992 4984 591 43 093 6082 9282
CIDI 3.0/DSM-IV WMH-CIDI/DSM-IV SPIKE/DSM-IV NESARC/DSM-IV WMH-CIDI/DSM-IV CIDI/DSM-IV
Bipolar Disorder Bipolar I/Bipolar II Bipolar I, II Bipolar I Bipolar I/Bipolar II Bipolar I
— — — 3.2 — 0.8
— — — 3.4 — 1.1
— 0.0 2.6 3.3 0.8 1.0
— — — 1.8 — —
— — — 2.2 — —
1.8 0.0 — 2.0 0.4 0.6
Bipolar II Subthreshold BPD
0.9 2.6
1.3 2.1
1.1 2.4
— —
— —
0.8 —
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Evidence for the validity of the expanded definition was provided by the clinical significance, severity, and impairment associated with sub-threshold bipolar disorder. Of particular interest, the severity of symptoms of depression and mania associated with sub-threshold bipolar disorder, suggested that the latter category did tap clinically significant manifestations of bipolar disorder that were comparable to people seeking treatment for these conditions in outpatient settings [19].
Incidence rates Most of the evidence on incidence rates (e.g. new cases in a defined population over a specified time period) of bipolar disorder has been derived from information on first admissions for bipolar disorder. Sherazi et al. (2006) reported a range of annual incidence rates of first-episode mania and bipolar I disorder from 1.7–6.5 per 100 000 per year [6]. Though some studies did report that men and women had different incidence rates, there are no consistent patterns of sex difference across studies.
Epidemiology of bipolar disorder in youth Although there has been substantial research on the epidemiology of mental disorders in children and adolescents in specific regions of the United States, there is still a striking lack of information on the national estimates of the prevalence and distribution of mental disorders in children in the US population. There is also a lack of data on the prevalence of bipolar disorder in youth from international studies. Most of the information on bipolar disorder in adolescents can be derived from ongoing longitudinal studies that have followed a sample of youth from adolescence through adulthood. These studies include community surveys of children and adolescents in New York State [20], North Carolina [21] and Oregon [22] in the United States, and in Munich, Germany [13] and Dunedin, New Zealand [23]. However, very few of these studies had sufficient sample sizes to identify cases of bipolar disorder. There are also a limited number of international population surveys that have provided information on the magnitude of bipolar disorder in youth.
Prevalence There is still a striking lack of information on the magnitude of bipolar disorder in youth. Even though there is an increasing number of population-based surveys of children and adolescents, many of these studies do not include assessment of the symptoms of mania because it is believed to be so rare [24,25]. To date, there is also a lack of data on the prevalence of bipolar disorder in youth in a nationally representative sample of US youth. The results of the
existing cross-sectional or short–term prospective studies of youth that applied DSM-IV criteria are shown in Table 2. The 12-month prevalence rates of mania range from 0.8 to 1.9%, and hypomania from 0.4–0.9% to age 18 [26–28]. A recent population survey of adolescents in Mexico City reported the highest prevalence rate of bipolar disorder in youth to date, with a one-year prevalence of 2.5% with bipolar disorder [28]. The most valid information on the prevalence and patterns of onset of bipolar disorder can be derived from prospective follow-up studies of youth through adulthood. Studies in New York State [20], North Carolina [21] and Oregon [22] in the United States, and in Munich, Germany [13] and Dunedin, New Zealand [23] have monitored prevalence of mental disorders through early adulthood. The lower half of Table 2 shows the prevalence of bipolar disorder in these studies. The results of these studies converge in estimating the prevalence of bipolar disorder at between 1.4 and 2.1%, which approximates cross-sectional prevalence rates of bipolar disorder in adult samples.
Incidence rates Prospective studies of child and adolescent samples from population surveys are the best source of incidence rates of bipolar disorder. Lewinsohn et al. (2002) found that the incidence of bipolar disorder peaks at age 14 in both males and females and decreases gradually thereafter [29]. By age 21, the rate of bipolar disorder rose to 2% in the prospective cohort studies of youth who were followed for several years [29,30]. There are also a growing number of studies that evaluate the incidence of first onset mania in clinical samples of youth. Incidence rates from these studies range from 1.7 to 2.2 per 100 000 per year, with a weighted average of 1.4% [31].
Age of onset and treatment rates in both adults and youth with bipolar disorder Age of onset Although estimates of the average age of onset of bipolar disorder from clinical samples was believed to occur in the third decade of life, retrospective estimates from the population surveys reveal that the average first onset of manic episodes occurs in the late teens to early 20s [12]. Emerging evidence from prospective studies of adolescents converges in demonstrating that the first onset of bipolar disorder generally begins in adolescence (possibly pre-adolescence) or early adulthood, with a mean age of onset of 18 years [32]. Waraich et al. (2004) showed that there was remarkable stability in the lifetime prevalence of bipolar disorder across adulthood, thereby demonstrating the chronicity of this condition across the lifespan [7].
Update on the Epidemiology
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55
Table 2 Rates of bipolar disorders in community samples of children and adolescents. Design
Authors
N
Age
Mania
Hypomania
Bipolar
13–18
1.9% (6 Mo)
0.9% (6 Mo)
—
1015
9, 11, 13
—
0.1%
0.2%
4175
11–17
0.4% (12 Mo)
0.8% (12 Mo)
—
3005
12–17
—
—
2.5% (12-Mo)
3021
14–24
—
0.4% (12Mo)
1.3% (12 Mo)
0.4% (LT)
1.4% (LT)
— —
—
Cross-Sectional Dutch Adolescent Study Verhulst et al. [27] Smoky Mountains Study Costello et al. [79] Teen Health 2000 Roberts et al. [80] Mexican Adolescent Mental Health Survey Benjet et al. [28]
760
Longitudinal (into Adulthood) Early Developmental Study of Psychopathology Wittchen et al. [13] Dunedin Longitudinal Study Cannon et al. [30] New York Longitudinal Study Velez et al. [81] Cohen et al. [20] Pine et al. [82] Oregon Adolescent Depression Project Lewinsohn, Klein, & Seeley [83]
980
26
2.0% (12Mo) —
776 760 716 1709
9–18 11–20 17–26 14–18
1507
15–19
1.0% (LT)
24
2.1% (LT)
865
—
Treatment rates
Risk factors
The studies summarized in Tables 1 and 2 have also provided substantial information about differential treatment patterns amongst samples identified from the general population. The findings indicate that about 60% of those with BPI in US community samples receive mental health treatment. Though more variable, more than half of those with BP in other countries receive treatment as well. This also suggests that half of those with bipolar disorder in the general population are not represented in mental health treatment, thereby limiting the generalizability of research conducted in these settings. Treatment rates in children have also been reported from prospective surveys. Newman et al. (1996) [23] found that approximately half of those youth in New Zealand with a 12-month episode of mania had received treatment. Moreno et al. (2007) examined data from the National Ambulatory Medical Care Survey to show that most visits by both youth and adult patients with a diagnosis of bipolar disorder included the prescription of at least one psychotropic medication, with use of mood stabilizers (generally anticonvulsants) in approximately two-thirds of the visits, and antidepressants in approximately one-third of the visits [33].
Sex
—
2.0% (T1 or T2) 1.4% 0.9% (LT)
The finding of equal rates of bipolar disorder in men and women from epidemiologic surveys was confirmed in all of the recent US population surveys [10,12,16]. Although there is consistentevidenceforanequalsexratioforbipolarIdisorder, several studies have shown that more women manifest the BP II subtype [34]. The lack of a sex difference demonstrates one of the sources of bias in clinical samples, which tend to have a greater proportion of women in psychiatric care for bipolar disorder [35]. Studies of youth also confirm the lack of sex differences in the rates of bipolar disorder and its components during adolescence [31]. However, caution should be exercised in drawing conclusions regarding the lack of sex differences in prevalence rates, because there may be differential manifestations of bipolar disorders in males and females. Whereas males may be more likely to exhibit mania, females are more likely to present with depression [36].
Other demographic factors Although many early studies of treated samples suggest that bipolar disorder was more common in upper
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socio-economic classes, the most recent US epidemiologic studies have consistently found that there are higher rates amongst those with lower income and education [10,12,16]. Likewise, rates of bipolar disorders are greater amongst those who were separated, divorced or widowed compared to those who are married or never married in all of the recent US population surveys. In contrast, a comparison of rates of bipolar disorder in high income and low income countries from the World Mental Health Survey showed that bipolar disorder was more common in high income than in low income countries (1.4 vs. 0.7%), as was disability associated with bipolar disorder [37]. Moreover, people from high income countries were nearly three times more frequently likely to enter treatment than their low income counterparts. No ethnic or racial differences in the rates of bipolar disorder have been reported in recent population surveys of the United States, including the NHANES, NCS-R and NESARC. However, there are only a limited number of studies that can truly distinguish ethnic differences because of the inclusion of sufficiently large multiethnic samples. The large sample size of the NESARC study enabled inclusion of several distinct ethnic subgroups in the US population. This study found that Native Americans reported higher rates of bipolar I disorder [10] than the other subgroups included in the survey. Another study that examined cultural subgroups is the New Zealand Mental Health Survey [38] that yielded higher rates of bipolar disorder amongst the Maori (3.4%) and Pacific people (2.7%), compared to European and other whites (1.9%).
Comorbidity Recent epidemiologic surveys have highlighted the striking magnitude of comorbidity between bipolar disorder and other Axis I DSM-IV disorders. Several population surveys confirm the strong link between anxiety disorders and bipolar disorder described in clinical samples (NCS R; NESARC, ESEMED). Data from the NCS-R revealed that more than 90% of those with lifetime BP I or BP II disorder also meet criteria for another lifetime disorder, and that 70% of those with bipolar spectrum disorders have a history of three or more disorders [12]. The disorders that are most strongly associated with bipolar disorder are anxiety disorders and substance use disorders. The NCS-R study revealed that more than 80% of those with bipolar disorder also have a lifetime history of DSM IV anxiety disorders, particularly panic attacks (e.g. 70%) and social phobia (e.g. 50%) [12]. Prospective studies of community samples provide valuable information on the temporal patterns of association between bipolar disorder and comorbid conditions. Followup studies of children have shown that bipolar disorder is associated with multiple other disorders including attention-deficit/hyperactivity disorder (ADHD) [29,33,39,40],
anxiety disorders and/or oppositional defiant disorder (ODD) [39] and conduct disorder [29]. An eight-year follow-up study of a population sample of youth from New York state revealed that childhood anxiety disorders and depression, and to a lower extent disruptive behaviour disorders, were significantly associated with the development of bipolar disorder in early adulthood [41,42]. Recent results of a high risk study of bipolar disorder confirm the anxiety-bipolar link. Duffy et al. (2007) found that rates of anxiety disorders and sleep disturbances were significantly elevated amongst offspring of bipolar probands compared to those of controls [43]. The latter work suggests that anxiety disorders may constitute an early form of expression of the developmental pathway of bipolar disorders. Future studies should attempt to distinguish whether anxiety disorders represent manifestations of the same aetiologic factors or independently elevate the risk for development of bipolar disorder. For example, one possible explanation for comorbidity in high risk samples could be parental concordance for these disorders, for example, paternal bipolar disorder and maternal anxiety disorder. The strong association between bipolar disorder with substance use disorders has also been widely described in both community and clinical samples. Retrospective research has shown that the onset of bipolar disorder generally precedes that of the substance use disorder. For example, [44] used data from a 20-year prospective cohort study to demonstrate the dramatic increase in risk of alcohol dependence associated with symptoms of mania and bipolar disorder in early adulthood. Thus, bipolar disorder can be considered a risk factor for the development of substance use disorders. Table 3 shows the strength of evidence that Table 3 Association between bipolar disorder with mental and physical disorders. Mental Disorders
Physical disorders
Disorder
Strength Disorder of evidence
Strength of evidence
Panic Attacks/ Disorder Specific Phobia Social Phobia Obsessive Compulsive Disorder Generalized Anxiety Disorder Drug Abuse/ Dependence
þþþ
þþþ
þþþ þþþ þþþ
Cardiovascular Disease Migraine Diabetes Asthma
þþ
Allergies
þþ
þþ
Back and Neck Pain Arthritis
þþ
þþþ Strong Evidence. þþ Moderate Evidence. þ Weak Evidence.
þþþ þþþ þþ
þ
Update on the Epidemiology
bipolar disorder is comorbid with different mental disorders and physical disorder.
Physical disorders Comorbidity of physical diseases with bipolar disorder has been well-recognized in clinical settings [45,46]. The recent generation of large psychiatric epidemiology studies has begun to include assessment of medical conditions that can be used to examine whether the associations that have been reported in clinical samples are associated with biases associated with either sampling or treatment. The disorders that have been most strongly associated with bipolar disorder in clinical settings include cardiovascular disorders, diabetes and migraine. Several studies of population-based samples and the recent results of the NCS-R have confirmed the strong association between migraine and bipolar symptoms/disorder [47,48]. Evaluation of physical-mental comorbidity in World Mental Health countries showed that heart disease, hypertension and back/neck pain are associated with bipolar disorder in both high and low income countries, whereas associations with arthritis, asthma and cancer are limited to high income countries. In contrast, severe headaches/migraine are more strongly associated with bipolar disorder in low income countries [37]. Health information collected in the NHANES data showed that those with bipolar disorder were more likely to rate themselves as in fair or poor health than those without affective disorders; however, other subtypes of mood disorders, including major depression and dysthymia, tended to have even stronger associations with poor health than bipolar disorder [16]. In the same study, associations emerged between all mood disorder subtypes with hypertension, but asthma was only significantly associated with major depression [16]. Although there is scant information on medical comorbidity in children with bipolar disorder, some studies of children have reported links between bipolar disorder and diabetes and cardiovascular diseases [49]. There also are several studies of systematic samples, such as the Veterans Administration [50] and health insurance claims data [51] bases, that provide strong evidence that people with bipolar disorder have high rates of physical disorders [52]. The study of health care claims by Carney and Jones (2006) found that nearly every medical disorder was more common amongst those with bipolar disorder; however, the extremely large database, lack of correction for multiple comparisons and failure to conduct multivariate analysis reduced the ability of this study to address the specificity of these associations [51].
Family history/genetics A family history of bipolar disorder is one of the strongest and most consistent risk factors for the development of this
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57
disorder. Controlled family studies yield an average 10-fold increased risk of bipolar disorder amongst adult relatives of probands with this disorder, compared to relatives of controls [53], as well as a 3.5-fold increased risk of bipolar disorder amongst relatives of probands with non-bipolar major depression. Results of a small number of twin studies yield an aggregate estimate of 3 fold greater risk amongst monozygotic compared to dizygotic twins, indicating that a significant proportion of the familiality of bipolar disorder can be attributed to genetic factors [54]. However, there is a remarkable lack of twin studies of bipolar disorder defined by modern diagnostic criteria [53]. Existing twin studies yield an average concordance rates for monozygotic twins of 40% compared to 5% for dizygotic twins, thereby suggesting a complex mode of inheritance of this condition [55]. Despite the strong evidence for familial and genetic factors underlying bipolar disorder, there is still a lack of information on susceptibility genes that have been consistently shown to have significant predictive value for the development of bipolar disorder. Although there have been many studies designed to identify candidate genes underlying bipolar disorder through either linkage (segregating within family) or association (differences between cases and controls), there are still no replicated genetic markers for bipolar disorder. The results of recent genome-wide association studies did not identify any of the candidate genes found in earlier studies, but it is anticipated that combined results of several large studies now under way may yield more presumptive evidence for susceptibility genes for in the next few years [55]. Irrespective of whether the family history represents increased genetic or environmental risk, or more likely elements of both, it is one of the most important predictors of the development of bipolar disorders in particular and mood and anxiety disorders in general youth.
Studies of offspring of bipolar probands The potential contribution of the family study can be enhanced by inclusion of a high-risk component, where individuals with a high probability for developing a specific disorder are compared to controls and followed over time. This design permits identification of the components and processes underlying disorders, early patterns of expression of these disorders, determinants of disorder progression, order of onset of comorbid disorders, and the longitudinal course and stability of symptoms and disorders. Following early studies by Meyer et al. [56], there are a growing number of studies of offspring of parents with bipolar disorder (Table 4) [57–60]. Controlled studies of offspring of parents with bipolar disorder have revealed an increased risk of a range of disorders including depression, anxiety disorders and ADHD, suggesting a lack of specificity of early manifestations of bipolarity [61]. Rates of mania and bipolar disorder
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Chapter 6
Table 4 High risk studies of bipolar disorder. Authors
N Cases
N Controls
Age
Parent group
Bipolar
Other
Controls
Bipolar Mood Anxiety ADHD Conduct/ODD Bipolar Mood Anxiety ADHD Conduct/ODD Bipolar Mood Anxiety ADHD Conduct/ODD Bipolar
10.6 21.1 25.8 24.5 19.1 16.0 32.0 32.9 32.0 22.0 20.4 52.8 23.2 10.2 0.8 8.8
— — —
— — 1.7
0.8 4.4 10.8 16.7 8.0 0 0 14.0 0 0 0 1.3 7.8 1.6 0 0
13.4 5.2 2.3 1.5 2.4 — — 2.3 — — — 14.7 6.2 6.4 — 5,2
Mood Anxiety ADHD Conduct/ODD
14.7 44.1 23.5 26.5
6.7 25.1 8.4 12.9
2.1 4.2 4.2 4.2
7.0 10,5 5.6 6.4
Birmaher et al. [60]
233
113
6–18
Singh et al. [58]
37
29
8–17
Duffy et al. [59]
207
87
8–25
Hirshfeld-Becker et al. [57]
34
179 Panic/Anx
4–10
98 Control
are generally low due to the young age of adolescent offspring in these studies; however, children of bipolar parents show greater specificity of transmission of affective disorders than do children of parents with unipolar depression [62]. The increased rates of ADHD that have been reported in some studies have been interpreted as evidence that symptoms of ADHD may be manifestations of a common underlying diathesis with bipolar disorder [40,63–66]. The prospective design of many of these studies will enable investigators to evaluate the prognostic significance of the symptoms and syndromes manifested by these children across development.
— — — — — — —
Risk ratio
unaffected subjects than in the general healthy population [67]. Table 5 lists the most promising endophenotypes that underlie bipolar disorder, including: cognitive endophenotypes, abnormal regulation of circadian rhythms (the sleep/wake cycle, hormonal rhythms, etc.), response to sleep deprivation, P300 event-related potentials, behavioural responses to psychostimulants and other medications, brain imaging endophenotypes (specifically, an increase in white matter hyperintensities (WHM)), and biochemical alterations in peripheral mononuclear cells [68,69].
Summary Endophenotypes/components of bipolar disorder Because psychiatric disorders have disparate manifestations, recent research has begun to investigate the symptoms and indices of their core underlying processes [67]. It has been proposed that these core components of diagnostic entities, or endophenotypes, are more likely to represent manifestations of the genetic factors involved in these disorders. Before a marker can be used as an endophenotype in genetic analysis, certain criteria need to be met: (1) the marker has to be associated with the illness in the population; (2) the marker has to be heritable; (3) the marker has to be state independent (i.e. present during remission); and (4) the marker also has to co-segregate with the disease within the family and have higher prevalence in high-risk
This chapter provides a comprehensive review of the magnitude of bipolar disorder in adults (DSM-IV) and children across the world. The lifetime prevalence rates, of bipolar I, cluster at about 1.0%, whereas the average 12-month
Table 5 Endophenotypes/Components of bipolar disorder. Cognitive deficits in verbal explicit memory and executive functioning. Brain Imaging: White matter hypertensities Abnormal Regulation of Circadian Rhythms Increased Latency in P300 Event-Related Potentials Behaviour Responses to Psychostimulants and Other Medications Biochemical Alterations Peripiheral Mononuclear Cells
Update on the Epidemiology
prevalence rate is only slightly lower with a median of 0.6%, with a range from 0–1.8%. There is a lack of data on the prevalence and magnitude of bipolar disorder in youth. The age of onset in bipolar disorder generally begins in adolescence, with a mean age of 18. About 60% of those with bipolar disorder I receive mental health treatment. Higher rates of bipolar disorder have been found in those with lower income and education. Comorbidity is pervasive amongst both adolescents and adults with bipolar disorder in the general population. Researchers have found bipolar to be comorbid with anxiety disorders, substance use disorders, panic attacks, social phobia and others. Family history of bipolar disorder is one of the strongest risk factors. Endophenotypes in bipolar disorder consist of abnormal regulation of circadian rhythm, imaging endophenotypes, cognitive endophentypes amongst others.
References 1. Saraceno, B. (2002) The WHO World Health Report 2001 on mental health. Epidemiol. Psichiatr. Soc., 11 (2), 83–87. 2. Merikangas, K.R., Nakamura, E.F. and Kessler, R.C. (2009) Epidemiology of mental disorders in children and adolescents. Dialogues Clin. Neurosci., 11 (1), 7–20. 3. Weissman, M.M., Bland, R.C., Canino, G.J. et al. (1996) Crossnational epidemiology of major depression and bipolar disorder. JAMA, 276 (4), 293–299. 4. Bauer, M. and Pfennig, A. (2005) Epidemiology of bipolar disorders. Epilepsia., 46 8–13. 5. Pini, S., de Queiroz, V., Pagnin, D. et al. (2005) Prevalence and burden of bipolar disorders in European countries. Eur. Neuropsychopharm., 15 (4), 425–434. 6. Sherazi, R., McKeon, P., McDonough, M. et al. (2006) Whats new? The clinical epidemiology of bipolar I disorder. Harvard Rev. Psychiat., 14 (6), 273–284. 7. Waraich, P., Goldner, E.M., Somers, J.M. and Hsu, L. (2004) Prevalence and incidence studies of mood disorders: A systematic review of the literature. Can. J. Psychiat., 49 (2), 124–138. 8. Goodwin, F. and Jamison, K. (2007) Manic-Depressive Illness, 2nd edn, Oxford University Press. 9. Gureje, O., Lasebikan, V.O., Kola, L. and Makanjuola, V.A. (2006) Lifetime and 12-month prevalence of mental disorders in the Nigerian Survey of Mental Health and Well-Being. Brit. J. Psychiat., 188 465–471. 10. Grant, B.F., Stinson, F.S., Hasin, D.S. et al. (2005) Prevalence, correlates, and comorbidity of bipolar I disorder and axis I and II disorders: Results from the National Epidemiologic Survey on Alcohol and Related Conditions. J. Clin. Psychiat., 66 (10), 1205–1215. 11. Szadoczky, E., Papp, Z., Vitrai, J. et al. (1998) The prevalence of major depressive and bipolar disorders in Hungary – Results from a national epidemiologic survey. J. Affect. Disord., 50 (2–3), 153–162. 12. Merikangas, K.R., Akiskal, H.S., Angst, J. et al. (2007) Lifetime and 12-month prevalence of bipolar spectrum disorder in the
13.
14.
15.
16.
17.
18.
19.
20.
21.
22.
23.
24.
25.
26.
27.
28.
|
59
National Comorbidity Survey replication. Arch. Gen. Psychiatry, 64 (5), 543–552. Wittchen, H.U., Nelson, C.B. and Lachner, G. (1998) Prevalence of mental disorders and psychosocial impairments in adolescents and young adults. Psychol. Med., 28 (1), 109–126. Fekadu, A., Shibre, T., Alem, A. et al. (2004) Bipolar disorder among an isolated island community in Ethiopia. J. Affect. Disord., 80 (1), 1–10. McConnell, P., Bebbington, P., McClelland, R. et al. (2002) Prevalence of psychiatric disorder and the need for psychiatric care in Northern Ireland – Population study in the District of Derry. Brit. J. Psychiat., 181, 214–219. Jonas, B.S., Brody, D., Roper, M. and Narrow, W.E. (2003) Prevalence of mood disorders in a national sample of young American adults. Soc. Psych. Psych. Epid., 38 (11), 618–624. Angst, J., Gamma, A. and Lewinsohn, P. (2002) The evolving epidemiology of bipolar disorder. World Psychiatry, 1 (3), 146–148. Judd, L.L. and Akiskal, H.S. (2003) The prevalence and disability of bipolar spectrum disorders in the US population: re-analysis of the ECA database taking into account subthreshold cases. J. Affect. Disord., 73 (1–2), 123–131. Kessler, R.C., Akiskal, H.S., Angst, J. et al. (2006) Validity of the assessment of bipolar spectrum disorders in the WHOCIDI 3.0. J. Affect. Disord., 96 (3), 259–269. Cohen, P., Cohen, J., Kasen, S. et al. (1993) An epidemiological study of disorders in late childhood and adolescence – I. Ageand gender-specific prevalence. J. Child Psychol. Psychiatry, 34 (6), 851–867. Costello, E.J., Angold, A., Burns, B.J. et al. (1996) The Great Smoky Mountains Study of youth – Goals, design, methods and the prevalence of DSM-III-R disorders. Arch. Gen. Psychiatry, 53 (12), 1129–1136. Lewinsohn, P.M., Rohde, P., Seeley, J.R. and Hops, H. (1991) Comorbidity of unipolar depression: I. Major depression with dysthymia. J. Abnorm. Psychol., 100 (2), 205–213. Newman, D.L., Moffitt, T.E., Caspi, A. et al. (1996) Psychiatric disorder in a birth cohort of young adults: prevalence, comorbidity, clinical significance, and new case incidence from ages 11 to 21. J. Consult. Clin. Psychol., 64 (3), 552–562. Canino, G., Shrout, P.E., Rubio-Stipec, M. et al. (2004) The DSM-IV rates of child and adolescent disorders in Puerto Rico: prevalence, correlates, service use, and the effects of impairment. Arch. Gen. Psychiatry, 61 (1), 85–93. Gau, S.S., Chong, M.Y., Chen, T.H. and Cheng, A.T. (2005) A 3-year panel study of mental disorders among adolescents in Taiwan. Am. J. Psychiatry, 162 (7), 1344–1350. Costello, E., Angold, A., Burns, B. et al. (1996) The Great Smoky Mountains Study of Youth. Goals, design, methods, and the prevalence of DSM-III-R disorders. Arch. Gen. Psychiatry, 53 (12), 1129–1136. Verhulst, F.C., van der Ende, J., Ferdinand, R.F. and Kasius, M.C. (1997) The prevalence of DSM-III-R diagnoses in a national sample of Dutch adolescents. Arch. Gen. Psychiatry, 54 (4), 329–336. Benjet, C., Borges, G., Medina-Mora, M.E. et al. (2009) Youth mental health in a populous city of the developing world:
60
29.
30.
31.
32.
33.
34.
35.
36.
37.
38.
39.
40.
41.
42. 43.
44.
|
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results from the Mexican Adolescent Mental Health Survey. J. Child Psychol. Psychiatry, 50 (4), 386–395. Lewinsohn, P.M., Seeley, J.R., Buckley, M.E. and Klein, D.N. (2002) Bipolar disorder in adolescence and young adulthood. Child Adolescent Psychiatry Clin. N. Am., 11 (3), 461–475. Cannon, M., Caspi, A., Moffitt, T.E. et al. (2002) Evidence for early-childhood, pan-developmental impairment specific to schizophreniform disorder: results from a longitudinal birth cohort. Arch. Gen. Psychiatry, 59 (5), 449–456. Soutullo, C.A., Chang, K.D., Diez-Suarez, A. et al. (2005) Bipolar disorder in children and adolescents: international perspective on epidemiology and phenomenology. Bipolar Disord., 7 (6), 497–506. Lewinsohn, P.M., Duncan, E.M., Stanton, A.K. and Hautzinger, M. (1986) Age at first onset for nonbipolar depression. J. Abnorm. Psychol., 95 (4), 378–383. Moreno, C., Laje, G., Blanco, C. et al. (2007) National trends in the outpatient diagnosis and treatment of bipolar disorder in youth. Arch. Gen. Psychiatry, 64 (9), 1032–1039. Benazzi, F. (2006) Symptoms of depression as possible markers of bipolar II disorder. Prog. Neuropsychopharmacol. Biol. Psychiatry, 30 (3), 471–477. Blanco, C., Laje, G., Olfson, M. et al. (2002) Trends in the treatment of bipolar disorder by outpatient psychiatrists. Am. J. Psychiatry, 159 (6), 1005–1010. Duax, J.M., Youngstrom, E.A., Calabrese, J.R. and Findling, R.L. (2007) Sex differences in pediatric bipolar disorder. J. Clin. Psychiat., 68 (10), 1565–1573. Ormel, J., Petukhova, M., Chatterji, S. et al. (2008) Disability and treatment of specific mental and physical disorders across the world. Br. J. Psychiatry, 192 (5), 368–375. Baxter, J., Kokaua, J., Wells, J.E. et al. (2006) Ethnic comparisons of the 12 month prevalence of mental disorders and treatment contact in Te Rau Hinengaro: The New Zealand Mental Health Survey. Aust. Nz. J. Psychiat., 40 (10), 905–913. Youngstrom, E., Meyers, O., Demeter, C. et al. (2005) Comparing diagnostic checklists for pediatric bipolar disorder in academic and community mental health settings. Bipolar Disord, 7 (6), 507–517. Biederman, J., Faraone, S.V., Wozniak, J. et al. (2004) Further evidence of unique developmental phenotypic correlates of pediatric bipolar disorder: findings from a large sample of clinically referred preadolescent children assessed over the last 7 years. J. Affect. Disord., 82 (Suppl 1), S45–S48. Cohen, D., Taieb, O., Flament, M. et al. (2000) Absence of cognitive impairment at long-term follow-up in adolescents treated with ECT for severe mood disorder. Am. J. Psychiatry, 157 (3), 460–462. Johnson, S.L. and Nowak, A. (2002) Dynamical patterns in bipolar depression. Pers. Soc. Psychol. Rev., 6 (4), 380–387. Duffy, A., Alda, M., Milin, R. and Grof, P. (2007) A consecutive series of treated affected offspring of parents with bipolar disorder: Is response associated with the clinical profile? Can. J. Psychiat., 52 (6), 369–376. Merikangas, K.R., Herrell, R., Swendsen, J. et al. (2008) Specificity of bipolar spectrum conditions in the comorbidity of mood and substance use disorders. Arch. Gen. Psychiatry, 65 (1), 47–52.
45. McIntyre, R.S. and Keck, P.E. Jr (2006) Comorbidity in bipolar disorder: clinical and research opportunities. Bipolar Disord., 8 (6), 645–647. 46. McIntyre, R.S., Konarski, J.Z., Soczynska, J.K. et al. (2006) Medical comorbidity in bipolar disorder: implications for functional outcomes and health service utilization. Psychiatr. Serv., 57 (8), 1140–1144. 47. Merikangas, K.R. and Stevens, D. (1997) Comorbidity of migraine and psychiatric disorders. Neurol. Clin., 15 (1), 115–123. 48. Saunders, K., Merikangas, K., Low, N.C.P. et al. (2008) Impact of comorbidity on headache-related disability. Neurology, 70 (7), 538–547. 49. Scheffer, R.E. and Linden, S. (2007) Concurrent medical conditions with pediatric bipolar disorder. Curr. Opin. Psychiatry, 20 (4), 398–401. 50. Kilbourne, A.M., Cornelius, J.R., Han, X.Y. et al. (2004) Burden of general medical conditions among individuals with bipolar disorder. Bipolar Disord., 6 (5), 368–373. 51. Carney, C.P. and Jones, L.E. (2006) Medical comorbidity in women and men with bipolar disorders: A population-based controlled study. Psychosom. Med., 68 (5), 684–691. 52. McIntyre, R.S., Soczynska, J.K., Mancini, D. et al. (2007) Comparing features of bipolar disorder to major depressive disorder in a tertiary mood disorders clinic. Ann. Clin. Psychiatry, 19 (4), 313–317. 53. Merikangas, K. and Yu, K. (2002) Genetic epidemiology of bipolar disorder. Clin. Neurosci. Res., 2 (3–4), 127–141. 54. Smoller, J.W. and Gardner-Schuster, E. (2007) Genetics of bipolar disorder. Curr. Psychiatry Rep., 9 (6), 504–511. 55. Smoller, J.W. and Finn, C.T. (2003) Family, twin, and adoption studies of bipolar disorder. Am. J. Med. Genet. C Semin. Med. Genet., 123C (1), 48–58. 56. Meyer, S.E., Carlson, G.A., Youngstrom, E. et al. (2009) Longterm outcomes of youth who manifested the CBCL-Pediatric Bipolar Disorder phenotype during childhood and/or adolescence. J. Affect. Disord., 113 (3), 227–235. 57. Hirshfeld-Becker, D.R., Biederman, J., Henin, A. et al. (2006) Psychopathology in the young offspring of parents with bipolar disorder: a controlled pilot study. Psychiatry Res., 145 (2–3), 155–167. 58. Singh, M.K., DelBello, M.P., Stanford, K.E. et al. (2007) Psychopathology in children of bipolar parents. J. Affect. Disord., 102 (1–3), 131–136. 59. Duffy, A., Alda, M., Crawford, L. et al. (2007) The early manifestations of bipolar disorder: a longitudinal prospective study of the offspring of bipolar parents. Bipolar Disord., 9 (8), 828–838. 60. Birmaher, B., Axelson, D., Monk, K. et al. (2009) Lifetime psychiatric disorders in school-aged offspring of parents with bipolar disorder: the Pittsburgh Bipolar Offspring study. Arch. Gen. Psychiatry, 66 (3), 287–296. 61. Duffy, A. (2007) Does bipolar disorder exist in children? A selected review. Can. J. Psychiatry, 52 (7), 409–417. 62. Merikangas, K.R. and Angst, J. (1995) Comorbidity and social phobia – evidence from clinical, epidemiologic, and geneticstudies. Eur. Arch. Psy. Clin. N., 244 (6), 297–303.
Update on the Epidemiology 63. Hirschfeld, R., Calabrese, J.R., Weissman, M. et al. (2002) Prevalence of bipolar spectrum in US adults. Eur. Neuropsychopharm., 12, S218–S318. 64. Biederman, J., Makris, N., Valera, E.M. et al. (2008) Towards further understanding of the comorbidity between attention deficit hyperactivity disorder and bipolar disorder: a MRI study of brain volumes. Psychol. Med., 38 (7), 1045–1056. 65. Biederman, J., Faraone, S., Mick, E. et al. (1996) Attentiondeficit hyperactivity disorder and juvenile mania: an overlooked comorbidity? J. Am. Acad. Child Adolesc. Psychiatry, 35 (8), 997–1008. 66. Chang, K.K.D., Steiner, H. and Ketter, T.A. (2000) Psychiatric phenomenology of child and adolescent bipolar offspring. J. Am. Acad. Child Psy., 39 (4), 453–460. 67. MacQueen, G.M., Hajek, T. and Alda, M. (2005) The phenotypes of bipolar disorder: relevance for genetic investigations. Mol. Psychiatry, 10 (9), 811–826. 68. Lenox, R.H., Gould, T.D. and Manji, H.K. (2002) Endophenotypes in bipolar disorder. Am. J. Med. Genet., 114 (4), 391–406. 69. Glahn, D.C., Bearden, C.E., Niendam, T.A. and Escamilla, M. A. (2004) The feasibility of neuropsychological endophenotypes in the search for genes associated with bipolar affective disorder. Bipolar Disord., 6 (3), 171–182. 70. Lee, S., Tsang, A., Zhang, M.Y. et al. (2007) Lifetime prevalence and inter-cohort variation in DSM-IV disorders in metropolitan China. Psychol. Med., 37 (1), 61–71. 71. Jacobi, F., Wittchen, H.U., Holting, C. et al. (2004) Prevalence, comorbidity and correlates of mental disorders in the general population: results from the German Health Interview and Examination Survey (GHS). Psychol. Med., 34 (4), 597–611. 72. Alhasnawi, S., Sadik, S., Rasheed, M. et al. (2009) The prevalence and correlates of DSM-IV disorders in the Iraq Mental Health Survey (IMHS). World Psychiatry, 8 (2), 97–109. 73. Levinson, D., Zilber, N., Lerner, Y. et al. (2007) Prevalence of mood and anxiety disorders in the community: results from the Israel National Health Survey. Isr. J. Psychiatry Relat. Sci., 44 (2), 94–103.
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74. Kawakami, N., Takeshima, T., Ono, Y. et al. (2005) Twelvemonth prevalence, severity, and treatment of common mental disorders in communities in Japan: preliminary finding from the World Mental Health Japan Survey 2002–2003. Psychiatry Clin. Neurosci., 59 (4), 441–452. 75. Karam, E.G., Mneimneh, Z.N., Dimassi, H. et al. (2008) Lifetime prevalence of mental disorders in Lebanon: First onset, treatment, and exposure to war. PLoS Med., 5 (4), 579–586. 76. Medina-Mora, M.E., Borges, G., Benjet, C. et al. (2007) Psychiatric disorders in Mexico: lifetime prevalence in a nationally representative sample. Brit. J. Psychiat., 190, 521–528. 77. Angst, J., Gamma, A., Neuenschwander, M. et al. (2005) Prevalence of mental disorders in the Zurich Cohort Study: a twenty year prospective study. Epidemiologia E Psichiatria Sociale, 14 (2), 68–76. 78. Ford, B.C., Bullard, K.M., Taylor, R.J. et al. (2007) Lifetime and 12-month prevalence of Diagnostic and Statistical Manual of Mental Disorders. Fourth Edition disorders among older African Americans: Findings from the national survey of American life. Am. J. Geriatr. Psychiatry, 15 (8), 652–659. 79. Costello, E.J., Angold, A., Burns, B.J. et al. (1996) The Great Smoky Mountains Study of Youth. Goals, design, methods, and the prevalence of DSM-III-R disorders. Arch. Gen. Psychiatry, 53 (12), 1129–1136. 80. Roberts, R.E., Roberts, C.R. and Xing, Y. (2007) Rates of DSMIV psychiatric disorders among adolescents in a large metropolitan area. J. Psychiatr. Res., 41 (11), 959–967. 81. Velez, C.N., Johnson, J. and Cohen, P. (1989) A longitudinal analysis of selected risk factors for childhood psychopathology. J. Am. Acad. Child Adolesc. Psychiatry, 28 (6), 861–864. 82. Pine, D.S., Cohen, P., Gurley, D. et al. (1998) The risk for earlyadulthood anxiety and depressive disorders in adolescents with anxiety and depressive disorders. Arch. Gen. Psychiatry, 55 (1), 56–64. 83. Lewinsohn, P.M., Klein, D.N. and Seeley, J.R. (2000) Bipolar disorder during adolescence and young adulthood in a community sample. Bipolar Disord, 2 (3), 281–293.
CHAPTER
7
Suicide and Bipolar Disorder n Rihmer1 and Jan Fawcett2 Zolta 1
Department of Clinical and Theoretical Mental Health, and Department of Psychiatry and Psychotherapy, Semmelweis Medical University, Ku´tv€ olgyi Clinical Centre, Budapest, Hungary 2 Department of Psychiatry, University of New Mexico School of Medicine Albuquerque, NM, USA
Introduction Despite the great clinical and public health significance of bipolar disorder, an illness with markedly elevated premature mortality, it is still underreferred, underdiagnosed and undertreated or mistreated [1,2]. This elevated risk of early death of patients with bipolar disorder is predominantly due to suicide. Up to 15% of bipolar patients die by their own hands and about half of them make one or more suicide attempts during their lifetime [3–7]. Although suicidal behaviour is very rare in the absence of current major mental illnesses [3,7,8], suicide is not the linear consequence of psychiatric disorders. It is a very complex and multicausal human behaviour involving also several psycho-social and cultural components. This chapter summarizes the clinically most important suicide risk and protective factors in bipolar disorders.
Suicide and attempted suicide in major mood disorders Harris and Barraclough [9] analysed separately the risk of completed suicide in patients with index diagnosis of unipolar major depression or bipolar disorder (37 reports and more than 11 000 patients), the patients having been followed in some studies for many decades and found that the standardized mortality ratio (SMR) for completed suicide was about 20-fold for patients with index diagnosis of unipolar major depression, and the same figure for bipolar disorders was 15. However, it should be noted that this type of analysis cannot provide a precise estimate of separate risk of suicide in unipolar depression and bipolar disorders (i.e. it overestimates the risk for unipolar and underestimates the risk of bipolar disorders). The main reason of this is that the index diagnosis often changes over the long-term course from unipolar depression to bipolar I or bipolar II illness [7,10] and in the studies reviewed by Harris and Bipolar Disorder: Clinical and Neurobiological Foundations Edited by Lakshmi N. Yatham and Mario Maj © 2010 John Wiley & Sons, Ltd. ISBN: 978-0-470-72198-8
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Barraclough [9], the distinct diagnostic category of bipolar II depression (major depressive episode with history of hypomania but not with mania), which is the most common clinical manifestation of bipolar disorders [1,7], was not considered separately. Consequently it is very likely that the majority of bipolar II patients in these studies were included into the unipolar major depressive group. Indeed, the most recent meta-analysis of 28 reports, published between 1945 and 2001 (including only patients with index diagnosis of bipolar disorder without long-term lithium treatment) by Tondo et al. [3], have found that during an average 10 years of follow-up, the SMR for completed suicide in bipolar patients was as high as 22. These authors also calculated that suicide rates in bipolar disorder patients average 0.4% per year, which is more than 25 times higher than the rate for the general population. In addition, in their very recent long-term prospective follow-up study (average 11 years) on 1983 unipolar major depressives and 843 bipolar (I þ II) patients, Tondo et al. [4] found much (5-fold) higher rate of completed suicide in bipolar I and II than in unipolar patients (0.25% of patients/ year vs. 0.05% of patients/year). This study also showed that the ratio of attempted to completed suicide in bipolar II, bipolar I and unipolar depression was 5, 11 and 10, respectively, indicating that the lethality of suicide attempts was far highest in bipolar II patients. This is in good agreement with a previously published psychological autopsy study, which showed that bipolar II patients were markedly overrepresented amongst consecutively investigated suicide victims with major depressive episode at the time of suicide [11]. On the other hand, in a 40–44 years prospective followup study of 406 formerly hospitalized (186 unipolar and 220 bipolar) major mood disorder patients, in which study the unipolar-bipolar conversion was carefully considered during the follow-up, Angst et al. [10] found that 14.5% of unipolar and 8.2% of bipolar (I þ II) patients committed suicide, and the SMR for suicide in unipolar and bipolar patients were 26 and 12, respectively. Previous suicide attempt is the most powerful predictor of completed suicide, particularly in patients with major
Suicide and Bipolar Disorder
mood disorder [7–9,12]. Considering only the 10 clinical studies (including more than 3100 patients), in which unipolar and bipolar (I þ II) patients were analyzed separately, it has been found that the lifetime rate of prior suicide attempt(s) was much higher in bipolar (I þ II) patients (mean: 28%, range: 10–61%) than in unipolar depressives (mean: 13%, range: 9.30%) [5]. A recent long-term prospective study also found that the rate of suicide attempts during the follow-up was more than double in bipolar (I þ II) than in unipolar patients [4]. Community-based epidemiological studies [13,14] also showed that the lifetime rate of prior suicide attempts was 1.5–2.5 higher in bipolar (I þ II) than in unipolar patients.
Suicide risk and protective factors in bipolar disorders Completed suicide, suicide attempt and suicidal ideation in patients with bipolar disorders occur mostly during the severe major depressive episode and less frequently in mixed affective episode and dysphoric mania, but very rarely during euphoric mania, hypomania and euthymia [6,8,12,15,16], indicating that suicidal behaviour in bipolar patients is a state- and severity-dependent phenomenon. However, since the majority of bipolar patients never commit (and up to 50% of them never attempt) suicide [3,7,12,16], risk factors, other than the major mood episode itself, such as special clinical characteristics as well as some personality, familial and psychosocial risk and protective factors, should also play a significant contributory role [3,8,12]. Most of the suicide risk factors in patients with bipolar disorders are related to the acute major (mainly depressive) episodes but there are several historical and personality factors that can help clinicians identify highly suicidal patients.
Suicide risk factors in patients with bipolar disorders The clinical conditions most alarming and associated with suicidal behaviour in bipolar disorder patients are the recent suicide attempt and the current severe (melancholic) major depressive episode, frequently accompanied by hopelessness, severe psychic anxiety, guilt, few reasons for living and suicidal ideations, agitation, insomnia and psychotic features [5–8,10,12,17–19]. Recent results also suggest that mixed depressive episode (major depression plus 3 or more co-occurring intra-depressive hypomanic symptoms, which highly corresponds to the category of agitated depression) that accounts for between 30 and 60% of major depressive episodes [19–21], substantially increases the risk of both attempted and committed suicide [15,19,22–25]. These results can explain, at least in part, the rarely occurring antidepressant-induced suicidal behaviour:
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antidepressant monotherapy, unprotected by mood stabilizers or atypical antipsychotics, particularly in bipolar and bipolar spectrum disorder (including unipolar depressive mixed state) can induce not only hypomanic/manic switches and rapid cycling, but also worsen the pre-existing mixed state or generate de novo mixed conditions, making the clinical picture more serious and ultimately leading to self-destructive behaviour [12,25,26]. Suicidal behaviour in bipolar patients, however, is not exclusively restricted to depressive episodes. In contrast to classical (euphoric) mania, where suicidal tendencies are extremely rare, suicidal thoughts and attempts are relatively common in patients with mixed affective episode and dysphoric mania, supporting the common clinical observation that suicidal behaviour in bipolar patients is linked to depressive symptomatology [6,7,10,15]. Bipolar patients show a high frequency of psychiatric and medical comorbidities [1,7,27] and it is well documented that comorbid anxiety/anxiety disorders, substance-use disorders, personality – mainly borderline personality – disorders and serious medical illnesses, particularly in the case of multiple comorbidities, also increase the risk of all forms of suicidal behaviour [5–8,12,27–30]. As the majority of bipolar suicide victims and attempters are not pharmacologically treated [5,7,12,28] and successful acute and longterm treatment of bipolar disorder substantially (by 80%) reduces the risk of both completed and attempted suicide [3,7,31], lack of medical and family support as well as the first few days of the therapy, when antidepressants usually do not work (or rarely can worsen the depression) [25], also should be considered as suicide risk factors. As for suicide risk factors related to prior course of bipolar disorders, previous suicide attempt(s), particularly in the case of violent or more lethal methods, is the most powerful single predictor of future attempts and fatal suicide [3,7,8,12]. Other historical variables, like early onset and early stage of the mood disorder [4,7,10,12,29,30], as well as rapid cycling course, predominant depressive polarity and more prior hospitalizations for depression [3,6,8,27,32] have been also shown to increase the risk of both attempted and completed suicide. Certain personality features also play a significant role in suicidal behaviour: aggressive/impulsive personality traits especially in combination with current hopelessness and pessimism [18,33–36] markedly increases the risk of suicidal behaviour in patients with bipolar disorder. The interaction between personality features and illness characteristics in suicidal behaviour was best formulated by Mann et al. [33] in their stress-diathesis model, which suggests that the suicidal behaviour in psychiatric patients is determined not only by the stressor (acute major psychiatric illness), but also by a diathesis (impulsive, aggressive, pessimistic personality traits). Cyclothymia/cyclothymic temperament also seems to be a predisposing factor for suicidal behaviour,
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as in patients with major depressive episode, cyclothymic personality was significantly related to lifetime and current suicidal behaviour (ideation and attempts) both in adult and in a paediatric sample [37–39]. Although the vast majority of suicide victims in the general population are males and the opposite is true for suicide attempters [7,9,25], this difference is much smaller amongst suicidal patients with bipolar disorder [3,8,10,29,30], suggesting that gender is not a significant predictor for committed and attempted suicide in this otherwise high-risk population. As for suicide risk factors related to personal history, early negative life events (e.g. loss of parents, living alone, emotional, physical and sexual abuse) [5,8,12,27,33], permanent adverse life situations (e.g. unemployment, disabling medical disorders), as well as acute psycho-social stressors (e.g. loss events, financial disasters), [5,8,12,27,40] are the most important and clinically useful indicators of possible suicidality, primarily if other risk factors are also present. However, acute psycho-social stressors are commonly dependent on the victims own behaviour, particularly in the case of bipolar I disorder [40]. It may be that hypomanic and manic periods can easily lead to aggressiveimpulsive behaviour, financial extravagance or episodic promiscuity, thus generating several interpersonal conflicts, marital breakdown and new negative life events, all of which have a negative impact on the further course of the illness. Family history of suicidal behaviour and/or major mood disorders in first- and second-degree relatives is also a strong risk factor for both attempted and completed suicide [8,12,27,33,34]. However, the familial component of suicidal behaviour seems to be partly independent of psychiatric disorders, as suicidal persons are over 10 times more likely than relatives of comparison subjects to attempt or complete suicide after controlling for psychopathology [41]. The clinically explorable suicide risk factors in mood disorders are listed in Table 1.
Comorbid anxiety: an imminent risk factor for suicide Over the past 20 years, the importance of the role of comorbid anxiety as a risk factor for suicide in patients with mood disorders has become increasingly clear. This evidence has recently focused on the importance of anxiety disorders and comorbid anxiety severity as a risk factor for suicide or suicide attempts in patients with bipolar disorder. The findings in this area are of clinical importance for two reasons: (1) severe psychic anxiety may be an acute or imminent risk factor for suicide, when most risk factors for suicide such as prior suicidal behaviour and hopelessness tend to predict suicide over an indefinite period of time. Clinicians are in great need of information that will help
Table 1 Clinically detectable suicide risk factors in bipolar disorders 1. Risk factors related to acute mood episodes a/Severe major depressive episode - Current suicide attempt, plan, ideation - Hopelessness, guilt, few reasons for living - Agitation, depressive mixed state (three or more intradepressive hypomanic symptoms) - Severe psychic anxiety, insomnia - Psychotic features - Bipolar II diagnosis - Comorbid Axis I (anxiety, substance-related), Axis II and serious Axis III disorders - Lack of medical treatment and family/social support - First few days of the treatment (particularly if appropriate care and co-medication is lacking), first few weeks and months after hospital discharge b/Mixed affective episode (simultaneously occurring manic and major depressive episode) c/Dysphoric mania (mania and three or more intramanic depressive symptoms) 2. Risk factors related to prior course of the illness - Previous suicide attempt/ideation (particularly the violent/highly lethal methods) - Early onset/early stage of the illness/predominantly depressive course - Rapid cycling course 3. Risk factors related to personality features - Aggressive/impulsive personality traits - Cyclothymic temperament - Same-sex orientation, bisexuality 4. Risk factors related to personal history and/or family history - Early negative life events (separation, emotional, physical and sexual abuse) - Permanent adverse life situations (unemployment, isolation) - Acute psychosocial stressors (loss events, financial catastrophe) - Family history of mood disorders (1- and 2-degree relatives) - Family history of suicide and/or suicide attempt (1- and 2-degree relatives).
them detect acute suicide risk; (2) severe psychic anxiety, when diagnosed is treatment modifiable, which raises the potential to reduce acute and chronic suicide risk with medication treatment focused on anxiety symptoms. What is the evidence relating to severe anxiety as a risk factor for suicide in bipolar disorder? In 1990, a long-term follow-up study of 954 patients with major affective disorder, including 299 patients with bipolar I and II disorder, as well as 46 with bipolar schizoaffective disorder, provided the rare opportunity for a prospective study of suicide, since 85% of the patients followed were recruited while hospitalized [17]. This study recorded that 13 (6 bipolar) patients in this group died by suicide within 12 months of hospital discharge, while at 10 years of follow-up 34 (15 bipolar) patients in this group died by suicide. Baseline symptom
Suicide and Bipolar Disorder
severity was rated on the study patients on the SADS-C scale [42], by raters who were trained and had established rating reliability across sites. Comparing symptom severity levels at baseline showed that 13 patients who had committed suicide within one year of entry into the study had significantly higher severity of psychic anxiety, panic attacks and severe (global – unable to fall asleep, mid-wakening and early awakening) insomnia than the majority who survived. Interestingly, there was no difference in the presence of standard risk factors, such as suicidal ideation (greater numerically, but not significant in the non-suicide group), prior and recent suicide attempts and hopelessness. From years 2–10 of follow-up, a history of suicidal ideation, past suicidal behaviour and severity of hopelessness did significantly correlate with an outcome of suicide. The 13 suicides occurring over one year were composed of roughly half bipolar patients, even though bipolar patients made up about only one-third of the total of patients with major affective disorder. This study found that severe psychic anxiety, panic attacks and severe (global) insomnia may be imminent or acute risk factors (weeks to a few months) for suicide compared with standard risk factors such as suicidal ideation, past suicide attempts and severe hopelessness, which may more often be long-term (months to years) risk factors for suicide. Comorbid severe anxiety may be rapidly treatment modifiable with pharmacologic intervention, reducing risk levels before a depressive episode responds to treatment. Furthermore, over the past five years, several epidemiological studies have reported a significant relationship of comorbid anxiety, especially with affective disorders and increased suicidal behaviour [43,44]. More recently findings by [30], from the STEP-BD study found from a sub-sample of 120 bipolar patients manifesting suicidal thoughts, related later suicidal behaviour to the presence of significant anxiety symptoms in this patient group. It is more difficult to study suicide rates across specific disorders because of the huge numbers of subjects required to achieve the statistical power to compare rates of suicide, which occurs about once for ever 30 attempts in the United States, and once for every three to four attempts in bipolar patients. A recent study by Simon et al. [29] of two managed care databases totalling over 32 000 bipolar patients, found that males (HR 2.7) and patients with a diagnosis of comorbid anxiety disorders had an elevated risk for suicide (HR 1.8) and suicide attempts (HR 1.4). It was of special interest that while comorbid anxiety disorders designated risk for suicide and attempts, comorbid substance abuse was able to predict elevated rates of suicide attempt (HR 2.5), but not increased rates of suicide (HR 1.02). The risk of suicide attempts was increased in youth, while suicide rates were unrelated to age. A recent analysis by Coryell et al. [45], of data from a 20-year follow-up of over 300 bipolar patients,
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has shown that severe anxiety measured by SADS-C rated psychic and somatic anxiety items at baseline predicts a significant stepwise increase in duration of time spent in depressive episodes over 20 years in patients diagnosed with bipolar disorder according to severity levels of baseline anxiety. Stordal et al. [46], looking at monthly ratings of depression and anxiety from the Hospital Anxiety and Depression rating scale in over 60 000 people, including 10 670 male and 3833 female suicides, found a correlation in the Norweigen national suicide rate and monthly variation of anxiety and depression (p < 0.001). These studies all show a general relationship between affective disorders, severe comorbid anxiety and suicide behaviours and suicide.
Suicide protective factors In contrast to several suicide risk factors, only few circumstances are known to have a protective effect against suicidal behaviour. Good family and social support, pregnancy and postpartum period, having a great number of children, holding strong religious beliefs and restricting lethal suicide methods (e.g. to reduce domestic and car exhaust gas toxicity and to introduce stricter laws on gun control) whenever possible, seem to have some protective effect [5,7,12,47,48]. The most extensively studied suicide protective factor in bipolar disorders is the acute and longterm pharmacological treatment that results in a marked decline in all forms of suicidal behaviour in this high-risk patient piopulation [3,5,10,12,31,49]. However, targeted psycho-social intervention improves the efficacy of pharmacotherapy [7,50,51]. In spite of the fact that suicide risk is the highest in patients with bipolar disorders, appropriate pharmacotherapy can reach the greatest risk reduction exactly in this patient-population. Both open clinical studies and randomized controlled trials consistently have found that long-term treatment with lithium (in some studies in combination with antidepressants and antipsychotics) markedly (by >80%) reduced the risk of competed and attempted suicide in bipolar I, bipolar I and schizoaffective patients [10,31,49,52]. Antiepileptic mood stabilizers, such as divalproex and carbamazepine, have weaker, but clinically still significant, antisuicidal effect [7,49,52]. The marked anti-suicidal effect of lithium seems to be more than the simple result of its episode-prophylactic effect, as a significant reduction in the number of subsequent suicide attempts was found not only in excellent responders (93%), but also in moderate responders (83%) and in nonresponders (49%) [53]. The clinical implication of this finding is that in case of lithium nonresponse, when the patient is at high risk of suicidal behaviour, instead of switching from lithium to another mood stabilizer, the clinician should retain lithium (even at a lower level) and combine it with another mood stabilizer.
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As for antidepressants, administered particularly in monotherapy, they hardly work in bipolar depression and sometimes they can worsen the cross-sectional clinical picture via inducing or aggravating depressive mixed states/agitation and this can lead to increased suicidality [7,22,25,54]. There is also a growing body of evidence suggesting that antidepressant and (tipycal) antipsychotic monotherapy (unprotected by mood stabilizers) can also worsen the long-tem course and outcome of bipolar disorder that may also contribute to increased suicidal risk [25,49,54,55]. However, as bipolar patients with long-term pharmacotherapy sometimes need (and more frequently receive) antidepressants and/or antipsychotics in addition to their mood stabilizers to treat breakthrough depression or mania for shorter or longer period of time, clinicians should keep their patients on these supplementary medications as short a time as possible and the main component of the acute and long-term pharmacotherapy should be the mood stabilizer monotherapy [25,49,56,57].
Suicide risk assessment and prevention Although suicide is a rare event in the community, it is frequent amongst patients with mood disorder. Most suicides would have had contact with different levels of health care some weeks and months before their death [3,5,7,12], but more than half of bipolar suicide victims were pharmacologically untreated at the time of their death [2,3,5,7]. This underlines the priority role of health care workers in suicide prevention. All patients with bipolar disorders must be carefully assessed for suicide risk (see Table 1). It is important to note that the data reviewed above suggests that severe anxiety may be an indicator of more imminent suicide that should alert a clinician, while most risk factors as suicide ideation (excluding a suicide plan), past suicide attempts and hopelessness relate to increased risk for suicide over an undetermined time frame in the presence of affective symptoms. Medications, such as the long-acting benzodiazepine, clonazepam and sedating second-generation antipsychotics, such as olanzepine and quetiapine, have been shown to significantly reduce anxiety and agitation as well as suicidal ideation in depressive, bipolar depressive and bipolar mixed states [58–63]. Careful ongoing assessment of the severity of anxiety symptoms and their treatment using a relatively simple severity scales, such as the SAD-C psychic anxiety scale in bipolar patients, may assist the clinician in reducing suicide risk and perhaps suggest a treatment intervention for acute suicide risk, in the short term and reduce long-term risk. Other treatments, such as lithium, other mood stabilizing
medications, atypical antipsychotic medications for mood stabilization and anxiety symptoms as well as psychotherapies, such as cognitive therapy and dialectical behavioural therapy, may be helpful in the long-term management of bipolar patients at high chronic risk (based on prior suicidal episodes and behaviour) for suicide. Clinicians need as much information as possible to assess suicide risk, particularly imminent risk. They also need to address treatment targets that will reduce both short-term and long-term suicide risk. Comorbid anxiety may be one valuable treatment target that is worth more careful assessment and more treatment focus in bipolar and other major mood disorder patients. A recent study by Marangell et al. [55] from the STEP-BD study, found a significant association of SSRI treatment with 93 suicidal events, including eight completed suicides (p < 0.0001). While these findings require careful interpretation, because SSRI treatment could have been a marker for depressive severity, they could also be interpreted to show that antidepressant treatment alone may not be sufficient for the prevention of suicidal behaviour and suicide in bipolar patients [49]. This suggests that attention to other risk factors, such as comorbid anxiety, may be warranted as one approach to reduce suicidal behaviour in the management of bipolar disorder. Severe, agitated and/or anxious major depression, particularly in the presence of past suicide attempt and current insomnia, is the clinical constellation that indicates the highest risk of imminent suicidal behaviour, even in the absence of direct or indirect communication of wish to die. Discussing the possibility of suicidal behaviour with the patient and family members as a common but preventable complication of acute severe bipolar and other psychiatric disorders, is particularly important and always needed. Doctors should declare that depressive disorders can be successfully treated, and that suicidal tendencies will vanish after (or even before) the recovery from depression. Patients with acute suicidal danger usually need inpatient treatment, even of an involuntary nature. In the case of severe agitation, anxiety and insomnia prompt anyiolysis with benzodiazepines and sedating atipycal antipsychotics, as well as close observation is highly recommended. Although short screening instruments are useful in clinical practice for detecting actual suicide risk, no one screening instrument can replace the optimal doctor-patient relationship, including asking the right questions at the right time, accompained by a highly professional and emphatic atmosphere. The careful estimation of all suicide risk factors (see Table 1) allows detection of suicide risk at the earliest possible time and opportunity for intervention prior to the patient making the first suicide act.
Suicide and Bipolar Disorder
References 1. Rihmer, Z. and Angst, J. (2005) Epidemiology of bipolar disorder, in Handbook of Bipolar Disorder (eds S. Kasper and R.M.A. Hirschfeld), Taylor and Francis, New York, pp. 21–35. 2. Dunner, D.L. (2003) Clinical consequences of under-recognized bipolar spectrum disorder. Bipol. Disord., 5, 456–463. 3. Tondo, L., Isacsson, G. and Baldessarini, R.J. (2003) Suicidal behaviour in bipolar disorder. CNS Drugs, 17, 491–511. 4. Tondo, L., Lepri, B. and Baldessarini, R. (2007) Suicidal risk among 2826 Sardinian major affective disorder patients. Acta. Psychiat. Scand, 116, 419–428. 5. Rihmer, Z. (2005) Prediction and prevention of suicide in bipolar disorder. Clin. Neuropsychiatry, 2, 48–54. 6. Valtonen, H., Suominen, K., Mantere, O. et al. (2005) Suicidal ideation and attempts in bipolar I and bipolar II disorders. J. Clin. Psychiat., 66, 1456–1462. 7. Goodwin, F.K. and Jamison, K.R. (2007) Manic-Depressive Illness: Bipolar disorders and recurrent Depression, Oxford University Press, New York. 8. Hawton, K., Sutton, L., Haw, C. et al. (2005) Suicide and attempted suicide in bipolar disorder: A systematic review of risk factors. J. Clin. Psychiat., 66 693–704. 9. Harris, E.C. and Barraclough, B. (1997) Suicide as an outcome for mental disorders: A meta-analysis. Brit. J. Psychiat., 170, 205–228. 10. Angst, J., Angst, F., Gerber-Werder, R. and Gamma, A. (2005) Suicide in 406 mood-disorder patients with and without long-term medication: A 40 to 44 years follow-up. Arch. Suic. Res., 9, 279–300. 11. Rihmer, Z., Barsi, J., Arato´, M. and Demeter, E. (1990) Suicide in subtypes of primary major depression. J. Affect. Disord., 18, 221–225. 12. Rihmer, Z. (2007) Suicide risk in mood disorders. Curr. Opin. Psychiat., 20, 17–22. 13. Kessler, R.C., Borges, G. and Walters, E.E. (1999) Prevalence and risk factors for lifetime suicide attempts in the National Comorbidity Survey. Arch. Gen. Psychiat., 56, 617–626. 14. Szado´czky, E., Vitrai, J., Rihmer, Z. and F€ uredi, J. (2000) Suicide attempts in the Hungarian adult population. Their relation with DIS/DSM-III-R affective and anxiety disorders. Eur. Psychiat., 15, 610–617. 15. Valtonen, H.M., Suominen, K., Haukka, J. et al. (2008) Differences in incidence of suicide attempts during phases of bipolar I and bipolar II disorders. Bipol. Disord., 10, 588–596. 16. Sokero, P., Eerola, M., Rytsala, H. et al. (2006) Decline in suicidal ideation among patients with MDD is preceded by decline in depression and hopelessness. J. Affect. Disord., 95, 95–102. 17. Fawcett, J., Scheftner, W.A., Fogg, L. et al. (1990) Time related predictors of suicide in major affective disorder. Am. J. Psychiatry, 147 (9), 1189–1194. 18. Oquendo, M.A., Galfalvy, H., Russo, S. et al. (2004) Prospective study of clinical predictors of suicidal acts after a major depressive episode in patients with major depressive disorder and bipolar disorder. Amer. J. Psychiatry, 161, 1433–1441. 19. Akiskal, H.S., Benazzi, F., Perugi, G. and Rihmer, Z. (2005) Agitated “unipolar” depression re-conceptualized as a depre-
20.
21. 22. 23.
24.
25.
26. 27.
28.
29.
30.
31.
32.
33.
34.
35.
|
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ssive mixed state: Implications for the antidepressant-suicide controversy. J. Affect. Disord., 85, 245–258. Maj, M., Pirozzi, R., Magliano, L. and Bartoli, L. (2003) Agitated depression in bipolar I disorder: Prevalence, phenomenology, and outcome. Amer. J. Psychiatry, 160, 2134–2140. Benazzi, F. (2006) Mood patterns and classification in bipolar disorder. Curr. Opin. Psychiat., 19, 1–8. Benazzi, F. (2005) Suicidal ideation and depressive mixed states. Psychother Psychosom., 74, 107–108. Sato, T., Bottlender, R., Kleindienst, N. and M€ oller, H.-J. (2005) Irritable psychomotor elation in depressed inpatients: A factor validation of mixed depression. J. Affect. Disord., 84, 187–196. Bal azs, J., Benazzi, F., Rihmer, Z. et al. (2006) The close link between suicide attempts and mixed (bipolar) depression: Implications for suicide prevention. J. Affect. Disord., 91, 133–138. Rihmer, Z. and Akiskal, H.S. (2006) Do antidepressants t(h)reat(en) depressives? Toward a clinically judicious formulation of the antidepressant-suicidality FDA advisory in light of declining national suicide statistics from many countries. J. Affect. Disord., 94, 3–13. Benazzi, F. (2003) How could antidepressants worsen unipolar depression? Psychother Psychosom, 72, 107–108. Leverich, G.S., Altshuler Frye, M.A., Suppes, T. et al. (2003) Factors associated with suicide attempts in 684 patients with bipolar disorder in the Stanley Foundation Bipolar Network. J. Clin. Psychiat., 64, 506–515. Bal azs, J., Lecrubier, Y., Csiszer, N. et al. (2003) Prevalence and comorbidity of affective disorders in persons making suicide attempts in Hungary: Importance of the first episode and of bipolar II diagnosis. J. Affect. Disord., 76, 113–119. Simon, G.E., Hunkeler, E., Fireman, B. et al. (2007) Risk of suicide attempt and suicide death in patients treated for bipolar disorder. Bipol. Disord., 9, 526–530. Simon, N.M., Zalta, A.K., Otto, M.W. et al. (2007) The association of comorbid anxiety with suicide attempts and suicidal ideation in outpatients with bipolar disorder. J. Psychiatr. Res., 41 (3–4), 255–264. Baldessarini, R.J., Tondo, L., Davis, P. et al. (2006) Decreased risk of suicides and attempts during long-term lithium treatment: A meta-analytic review. Bipol. Disord., 8, 625–639. Valtonen, H.M., Suominen, K., Mantere, O. et al. (2007) Suicidal behaviour during different phases of bipolar disorder. J. Affect. Disord., 97, 101–107. Mann, J.J., Waternaux, C., Haas, G.L. and Malone, K.M. (1999) Toward a clinical model of suicidal behavior in psychiatric patients. Amer. J. Psychiatry, 156, 181–189. MacKinnon, D.F., Potash, J.B., McMahon, F.J. et al. The National Institutes of Mental Health Bipolar Disorder Genetics Initiative (2005) Rapid mood switching and suicidality in familial bipolar disorder. Bipol. Disord., 7, 441–448. Zalsman, G., Braun, M., Arendt, M. et al. (2006) A comparison of the medical lethality of suicide attempts in bipolar and major depressive disorder. Bipol. Disord., 8, 558–565.
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36. Swann, A.C., Moeller, F.G., Steinberg, J.L. et al. (2007) Manic symptoms and impulsivity during bipolar depressive episode. Bipol. Disord., 9, 206–212. 37. Akiskal, H.S., Hantouche, E.G. and Allilare, J.F. (2003) Bipolar II with and without cyclothymic temperament: Dark and sunny expressions of soft bipolarity. J. Affect. Disord., 73, 49–57. 38. Kochman, F.J., Hantouche, E.G., Ferrari, P. et al. (2005) Cyclothymic temperament as a prospective predictor of bipolarity and suicidality in children and adolescents with major depressive disorder. J. Affect. Disord., 85, 181–189. 39. Pompili, M., Rihmer, Z., Akiskal, H.S. et al. (2008) Temperament and personality dimensions in suicidal and nonsuicidal psychiatric inpatients. Psychopathology, 41, 313–321. 40. Isometsa, E., Heikkinen, M., Henriksson, M. et al. (1995) Recent life events and completed suicide in bipolar affective disorder: A comparison with major depressive disorder in Finland. J. Affect. Disord., 33, 99–106. 41. Kim, C.D., Seguin, M., Therrien, N. et al. (2005) Familial aggregation of suicidal behavior: A family study of male suicide completers from the general population. Amer. J. Psychiatry, 162, 1017–1019. 42. Endicott, J. and Spitzer, R.L. (1978) A diagnostic interview: the schedule for affective disorders and schizophrenia. Arch. Gen. Psychiatry, 35 (7), 837–844. 43. Wunderlich, U., Bronisch, T. and Wittchen, H.U. (1998) Comorbidity patterns in adolescents and young adults with suicide attempts. Eur. aRch. Psychiatry Neurosci., 248 (2), 87–95. 44. Foley, D.L., Goldston, D.B., Costello, E.J. and Angold, A. (2006) Proximal psychiatric risk factors for suicidality in youth: the Great Smoky Mountains Study. Arch. Gen. Psychiatry, 63 (9), 1017–1024. 45. Coryell, W., Dervic, K., Oquendo, M.A. et al. (2004) Religious affiliation and suicide attempt. Amer. J. Psychiatry, 161, 2303–2308. 46. Stordal, E., Morken, G., Mykletun, A. et al. (2008) Monthly variation in prevalence of comorbid depression and anxiety in the general population at 63–65 degrees North: the Hunt study. J. Affect. Disord., 106 (3), 273–278. 47. Marzuk, P.M., Tardiff, K., Leon, A.C. et al. (1997) Lower risk of suicide during pregnancy. Amer. J. Psychiatry, 154, 122–123. 48. Driver, K. and Abed, R. (2004) Does having offspring reduce the risk of suicide in women? Int. J. Psychiat. Clin. Pract., 8, 25–29. 49. Rihmer, Z. (2007) Pharmacological prevention of suicide in bipolar patients – A realizable target. J. Affect. Disord., 103, 1–3. 50. Rucci, P., Frank, E., Kostelnik, B. et al. (2002) Suicide attempts in patients with bipolar I disorder during acute and maintenance phases of intensive treatment with pharmacotherapy and adjunctive psychotherapy. Amer. J. Psychiatry, 159, 1160–1164.
51. Michalak, E.E., Yatham, L.N. and Lam, R.W. (2004) The role of psychoeducation in the treatment of bipolar disorder: A clinical perspective. Clin. Appr. Bipol. Disord., 3, 5–11. 52. Cipriani, A., Pretty, H., Hawton, K. and Geddes, J.R. (2005) Lithium in the prevention of suicidal behavior and all causemortality in patients with mood disorders: A systematic review of randomized controlled trials. Amer. J. Psychiatry, 162, 1805–1819. 53. Ahrens, B. and Muller-Oerlinghausen, B. (2001) Does lithium excert an independent antisuicidal effect? Pharmacopsychiatry, 34, 132–136. 54. McElroy, S.L., Kotwal, R., Kaneria, R. and Keck, P.E. Jr (2006) Antidepressants and suicidal behavior in bipolar disorder. Bipol. Disord., 8, 596–617. 55. Marangell, L.B., Dennehey, E.B., Wisniewski, S.R. et al. (2008) Case-control analyses of the impact of pharmacotherapy on prospectively observed suicide attempts and completed suicides in bipolar disorder: Findings from the STEP-BD. J. Clin. Psychiatry, 69, 916–922. 56. Akiskal, H.S. (2007) Targeting suicide prevention to modifiable risk factors: Has bipolar II been overlooked? (Editorial) Acta Psychiat. Scand., 116, 395–402. 57. Sondergard, L., Lopez, A.G., Andersen, P.K. and Kessing, L.V. (2008) Mood stabilizing pharmacological treatment in bipolar disorders and the risk of suicide. Bipol. Disord., 10, 87–94. 58. Smith, W.T., Londborg, P.D., Glaudin, V. and Painter J.R. (1998) Short-term augmentation of fluoxetine withclonazepam in the treatment of depression: a double-blind study. Am. J. Psychiatry, 155, 1339–1345. 59. Smith, W.T., Londborg, P.D., Glaudin, V. and Painter J.R. (2002) Is extended clonazepam cotherapy of fluoxetine effective for outpatients with major depression? J. Affect. Disord., 70, 251–259. 60. Londborg, P.D., Smith, W.T., Glaudin, V. and Painter J.R. (2000) Short-term cotherapy with clonazepam and fluoxetine: anxiety, sleep disturbance and core symptoms of depression. J. Affect. Disord., 61, 73–79. 61. Hirschfeld, R.M., Weisler, R.H., Raines, S.R. and Macfadden, W. (2006) Quetiapine in the treatment of anxiety in patients with bipolar I or II depression: a secondary analysis from a randomized, double-blind, placebo-controlled study. J. Clin. Psychiatry. 67, 355–362. 62. McIntyre, A., Gendron, A. and McIntyre A. (2007) Quetiapine adjunct to selective serotonin reuptake inhibitors or venlafaxine in patients with major depression, comorbid anxiety, and residual depressive symptoms: a randomized, placebo-controlled pilot study. Depress Anxiety. 24, 487–494. 63. Houston, J.P., Tohen, M., Degenhardt, E.K. et al. (2009) Olanzapine-divalproex combination versus divalproex monotherapy in the treatment of bipolar mixed episodes: a double-blind, placebo-controlled study. J. Clin. Psychiatry, 70, 1540–1547.
CHAPTER
8
Neurocognition in Bipolar Disorder Ivan J. Torres1,2 and Gin S. Malhi3 1
Department of Psychiatry, University of British Columbia, Vancouver, BC, Canada Riverview Hospital, British Columbia Mental Health and Addictions Services, Coquitlam, BC, Canada 3 Discipline of Psychiatry, Sydney Medical School, University of Sydney; CADE (Clinical Assessment Diagnostic Evaluation) Clinic, Royal North Shore Hospital, Sydney, Australia 2
Introduction Bipolar disorder has traditionally been conceptualized as a dynamic illness involving the alternation between transient periods of mood instability and periods of symptom remission. Early conceptions posited that in between mood episodes, patients returned to a normal functional state, and this was an important basis for differentiating mood disorders such as bipolar disorder from schizophrenia. The idea that patients with bipolar disorder indeed return to a fully functional state in between mood episodes is no longer accepted as truth, and much of this is based on findings from the rapidly emerging literature on cognitive functioning in bipolar disorder. Specifically, this body of research has revealed that cognitive impairment is a prevalent clinical feature of bipolar disorder, and that it persists even in patients who are in a remitted or euthymic state. Cognitive impairment thus appears to occur independently of mood state and represents a core clinical feature of bipolar illness. Given the increasing recognition of the importance of impaired cognition as a clinical feature of bipolar disorder [1], the purpose of this chapter is to provide an update on the current understanding of neuropsychological functioning in bipolar illness. The organizational strategy involves first providing an evaluation of the nature and extent of cognitive dysfunction across the various mood states and across potential subtypes of the illness. This is followed by consideration of the degree to which cognitive deficits might at least partly be produced by medication side effects. In the next general section we provide a brief review of cognitive neuroimaging studies and what they are beginning to reveal about the faulty brain systems that underlie the cognitive deficits in bipolar disorder. This is followed by a discussion of likely aetiologic factors associated with the cognitive impairment. The final portion of the chapter high-
Bipolar Disorder: Clinical and Neurobiological Foundations Edited by Lakshmi N. Yatham and Mario Maj © 2010 John Wiley & Sons, Ltd. ISBN: 978-0-470-72198-8
lights the clinical significance of cognitive impairment in bipolar disorder, as is illustrated by the ability of cognitive variables to predict everyday functional outcome. We also provide a clinically focused summary of strategies for assessment of cognitive deficits, and cover the understudied area of treatments targeting cognitive deficits in bipolar illness. Before delving into the main subject matter, however, we provide a brief primer on neuropsychological assessment to serve as background for subsequent discussion throughout the chapter.
Brief overview of neuropsychological assessment The field of clinical neuropsychology concerns itself with the understanding of brain/behaviour relationships in clinical populations with documented or suspected brain dysfunction. Although the disciplines roots can be traced to work with neurosurgical and neurological patient populations, in more recent decades, clinical neuropsychology has shown increasing convergence with the field of psychiatry. This has undoubtedly been facilitated by the explosion in biological psychiatry and the universal recognition that many primary psychiatric disorders are manifestations of brain disease or illness. Even though research into neurocognitive functioning in bipolar disorder and other psychiatric disorders has been embraced by neuroscience researchers from varying disciplines and training backgrounds, the clinical practice of neuropsychology has largely remained a subspecialty of clinical psychology. The settings for clinical neuropsychological practice vary widely. Within a psychiatric context the main goals of neuropsychological assessment frequently include assistance with differential diagnosis, understanding and prediction of adaptive or real-world functioning and tracking of cognitive status across time, often in an effort to assist with assessing clinical outcome in response to treatment. The primary tool for cognitive assessment consists of the use of psychometrically validated cognitive tests, often paper and pencil, but increasingly computer-based, which have 69
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also been applied to large numbers of healthy individuals for the purpose of normative development and comparison. In this way, a given test score obtained by an individual can be compared to a reference group of healthy individuals with the same demographic characteristics (e.g. age, gender, education). Two of the key psychometric indicators of the utility of a cognitive measure include its reliability, which refers to the tests consistency of measurement, as well as the measures validity, which refers to the tests demonstrated ability to measure a particular psychological or cognitive construct. Attention to a cognitive measures psychometric properties thus forms an important basis for selection and interpretation of neuropsychological test results. Based on a patients performance on a range of such tests, inferences can be made about the individuals functioning across different cognitive domains. This forms the basis for making conclusions about differential diagnosis, aetiology of cognitive impairments and the patients adaptive or functional capabilities. Neuropsychological assessment results may also provide indirect evidence of underlying dysfunction in various brain systems. Table 1 provides a summary of some of the major cognitive domains and representative types of tasks that are frequently sampled during the course of a neuropsychological evaluation [2]. The majority of research into cognitive functioning in bipolar disorder has been conducted within the framework of clinical neuropsychology, and thus many studies have employed clinically derived psychometrically validated
cognitive tests. However, increasingly the field has also embraced methodologies from a broader cognitive neuroscience perspective, and thus newer experimental tasks and paradigms have also been used in an effort to more accurately identify the cognitive components that may be implicated in the disorder. Thus, at this point the accumulated knowledge regarding neurocognitive functioning in bipolar disorder is based on research findings from multiple and varied perspectives.
Nature of cognitive impairment in bipolar disorder Because bipolar disorder is a disorder involving experience of abnormal mood states, any effort to characterize the nature of cognitive impairment associated with the illness requires consideration of the underlying mood state. Research into neurocognitive functioning in bipolar illness has thus been conducted in symptomatic patients (in depressed, manic or mixed states) and in individuals who are free or relatively free of mood symptoms.
Cognitive deficits associated with mood symptoms Early research suggested that bipolar patients in acute depressive or manic states demonstrate disproportionate impairment on tests of cognitive functioning. Not surpris-
Table 1 Neuropsychological domains sampled in a typical neuropsychological evaluation. Cognitive domain
Specific type of cognitive task
Premorbid Intelligence Intelligence/Reasoning
Single-word reading Verbal: vocabulary, reasoning, abstraction Nonverbal: reasoning, problem solving Verbal: list, story learning and recall Nonverbal: learning, recall visual designs Auditory attention span, spatial span Sustained attention Speeded visual-motor tasks Speeded cognitive tasks Visual/spatial perception, discrimination, recognition Drawing, block construction Expressive, receptive language Confrontation Naming, repetition Attentional/set shifting, working memory Mental flexibility, perseveration Response inhibition Verbal, nonverbal fluency Organization, sequencing, dyspraxia Tactile, visual, auditory perception Fine motor speed, coordination, grip strength
Memory Attention/Concentration Processing Speed Visual-Spatial/Visual Constructional Language Executive Function
Sensory Perceptual/Psychomotor
Based on Lezak et al., 2004.
Implicated brain regions
Diffuse Medial Temporal Lobe Diencephalon Diffuse: Frontal/Parietal Diffuse Right Hemisphere Left Hemisphere, Peri-sylvian Prefrontal, Parietal, Subcortical
Pre, Post-Central Gyrus, Occipital, Superior Temporal
Neurocognition in Bipolar Disorder
ingly, this finding has been confirmed in cross-sectional studies that evaluate groups of patients in euthymic or active mood states and compare their neuropsychological performance to each other and/or to healthy individuals. A number of test-retest studies evaluating patients in symptomatic and asymptomatic mood states also support the idea that cognitive performance worsens in the midst of a depressive or manic state. In mania, patients demonstrate widespread neuropsychological impairment that includes broad deficits in sustained attention (both inattention and impulsivity), memory recall and recognition (verbal and nonverbal), executive function, judgement and decision making [3,4]. These findings implicate global dysfunction in multiple brain systems, including dorsal and ventral prefrontal brain regions in mania. Although some of the deficits subside or diminish with symptomatic resolution, other impairments persist into the euthymic state (see section on cognitive deficits in euthymia below). In a depressive state, patients with bipolar disorder also show preferential decline in attention, concentration, memory, psychomotor speed and visual-spatial function, and again, these cognitive impairments improve with resolution of the depressive episode [4]. A summary of the major cognitive deficits observed in manic and depressed states in bipolar disorder is presented in Table 2. Although the finding that patients perform worse on cognitive tasks during a mood episode is established, the source or aetiology of the poor performance in such patients is far from clear and likely multiply determined. Cognitive deficits observed in depressed or manic individuals may reflect persistent neuropsychological impairments that are inherent to the illness, or they may be secondary and more intimately linked to or represent a by-product of the mood episode itself. For example, patients in a mood state may be unable or unwilling to concentrate on a cognitive task
Table 2 Cognitive impairments associated with mood states in bipolar disorder. Depression
Mania
Sustained Attention
Sustained Attention with impulsivity Selective Attention Verbal Learning Verbal Memory including recognition Visuospatial Memory
Verbal Learning Verbal Memory Visuospatial Memory Problem Solving Verbal Fluency Cognitive Flexibility
Psychomotor Speed Based on Malhi et al., 2008.
Verbal Fluency Inhibitory Control Cognitive Flexibility Judgement Decision Making
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because of poor effort, a tendency to give up, lack of interest, irritability or distractibility arising from other preoccupations. Because patients show improved cognitive performance as mood symptoms resolve, it is likely that at least a portion of the cognitive impairment observed in symptomatic patients represents mood-state dependent impairment. From a clinical perspective, the optimistic view is that when patients in severe mood states are treated effectively, it can be expected that their cognitive deficits will likely improve to a certain degree.
Cognitive deficits in euthymic patients In the past few years there has been a surge in research studies that have attempted to further elucidate the source of cognitive impairment in bipolar disorder, by evaluating the degree to which cognitive deficits represent more persistent or trait features of the illness. The strategy has been to restrict the study of neuropsychological deficits to samples of patients who are in remitted or euthymic, rather than symptomatic mood states. The finding of cognitive impairment even in asymptomatic patients would provide some evidence that cognitive deficits at least partly represent persistent, trait-related deficits that are mood independent. To date, there have been four published meta-analytic reviews that have aimed to quantify the severity and pattern of cognitive impairment across studies that have assessed remitted patients with bipolar disorder and compared their neuropsychological performance to a healthy comparison group [5–8]. Figure 1 illustrates the aggregate findings from these meta-analytic data by plotting the mean patientcontrol effect size differences that are observed across a range of neuropsychological tests. The meta-analytic data reveal that patients show a variable pattern of performance across different cognitive domains. First, individuals with bipolar disorder show minimal to no impairment on standard measures of current or estimated premorbid intellectual functioning, such as vocabulary and single-word reading ability. This finding suggests that the cognitive deficit profile in bipolar disorder does not involve gross intellectual decline, and this likely distinguishes patients with bipolar disorder from individuals with schizophrenia [9]. Euthymic bipolar patients also show relative sparing on spatial tasks involving ability to copy geometric designs, although it should be acknowledged that these functions have been studied relatively infrequently. In addition, patients show relatively intact performance on measures of simple auditory attention span such as digit span forwards. In contrast, deficits of considerable magnitude are observed on virtually all measures of verbal learning and recall (excluding recognition), on multiple aspects of executive function (response inhibition, auditory working memory, category fluency, attentional and mental set shifting ability), on measures of visual-motor processing speed and on
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1.0
Effect Size
0.8
0.6
0.4
indices of sustained attention involving inattention (rather than impulsivity as indexed by commission errors). Even though these deficits are not likely to be attributed to global intellectual decline, it remains unclear whether the diminished performance across multiple tests reflects multiple cognitive deficits or whether there is a core cognitive deficit that impacts performance on multiple cognitive tasks. One of the inherent difficulties of using clinically derived neuropsychological tests is that they frequently rely on multiple cognitive domains for successful performance. Thus, it is difficult to isolate any core cognitive deficit(s) that may be at play. Although seemingly compelling, the meta-analytic data do not rule out the possibility that the magnitude of cognitive impairment is at least partially influenced by several moderators or confounds, the most likely candidates being presence of residual mood symptoms and effects of medications. To help rule out that cognitive impairments may be due to residual mood symptoms, several well conducted studies assessing cognitive differences between euthymic patients and controls have incorporated rigorous inclusion criteria for mood rating scores into their designs, and they have statistically covaried out the influence of mood ratings when assessing cognitive group differences [10,11]. When these steps are undertaken, cognitive deficits in the domains identified above continue to be present in patients relative to controls. In addition, in the meta-analytic study conducted by Bora et al. (2008), meta-regression techniques failed to find an association between depression rating scores and cognitive functioning across samples of euthymic patients with bipolar disorder [6]. Together, these data suggest that residual mood symptoms are not likely responsible for the considerable cognitive deficits that are observed in euthymic patients. The question of whether medication variables
CPT Commission
CPT Reaction Time
CPT Hits/Ommission
Trailmaking A
Forward Span
Spatial
Digit Symbol
Visual Delay Recall
Verbal Recognition
Verbal Delay Recall
Verbal Learning
Verbal Immed Recall
WCST categories
Stroop Interference
Trailmaking B
WCST perseveration
Fluency-Letter
Backward Span
IQ
0.0
Fluency-Category
0.2
Fig. 1 Summary of 4 meta-analyses illustrating the mean effect size differences between euthymic bipolar patients and healthy controls. Note: if an effect size for a given measure was reported in more than one meta-analysis, then the mean value was calculated. WCST ¼ Wisconsin Card Sorting Test; CPT ¼ Continuous Performance Test.
may account for some or all of the cognitive deficits observed in bipolar disorder is addressed in more detail in a subsequent section.
Cognitive deficits in subsets of patients The data presented above show that cognitive impairments are common in bipolar disorder; however, as currently conceptualized, the illness still reflects a heterogeneous disorder. It is thus possible and even probable that specific subsets of patients may be biologically distinct from others, and that these biological distinctions may also be manifested in differential cognitive impairment across subgroups of patients. A common sub-classification of bipolar disorder makes the distinction between patients who show a history of at least one prior manic or mixed episode (bipolar I) and those who present with a history of hypomanic rather than manic episode, coupled with at least one, but frequently multiple depressive episodes (bipolar II). To date, only a few studies have evaluated neuropsychological functioning in patients with bipolar I versus bipolar II. Despite some mixed results, findings from this literature show preliminary evidence of better neuropsychological functioning in patients with bipolar II relative to bipolar I. Whereas patients with bipolar I show more severe and widespread deficits in memory, attention and executive functioning, patients with bipolar II show a more restricted and less severe pattern of impairment [12,13]. Thus, in addition to other possible clinical differences between these subtypes (e.g. course, genetics, neurobiology), patients with bipolar I and II may show distinct neurocognitive profiles as well. Clearly, more research on this topic is needed, and potential confounds, such as differential illness burden between patients with bipolar I and II, need to be controlled.
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Another clinical variable that may provide a meaningful distinction amongst patients diagnosed with bipolar disorder is history of psychosis. The clinical, anatomical/ physiological and cognitive similarities between patients diagnosed with bipolar disorder and schizophrenia are substantial, and current conceptualizations posit that rather than representing distinct entities, these disorders likely lie on a continuum and share common aetiologic factors [14]. The phenotypic overlap between these two disorders is revealed by estimates that greater than half of all patients with bipolar experience psychotic symptoms. However, because not all patients with bipolar disorder experience psychosis, it is possible that the presence of psychosis may identify a distinct subset of patients that may be closer neurobiologically to patients in the schizophrenia spectrum. In order to evaluate whether these putative differences may manifest in differential neurocognitive performance, several studies have evaluated cognitive functioning in patients with and without a history of psychosis. Although findings are not universal, most studies point to evidence of preferential executive and working memory deficits in patients with a history of psychotic symptoms relative to bipolar patients without psychosis [15,16]. Moreover, in some instances, the more pronounced cognitive deficits are comparable to the more severe cognitive deficits observed in schizophrenia spectrum disorders. As is the case with the comparison between patients with bipolar I and bipolar II, several confounds including severity of illness and differential course and treatment need to be ruled out to further establish the robustness of the finding of preferential cognitive impairment in psychotic bipolar disorder. Moreover, even if such a link exists, the question of whether there is specificity to particular types of psychosis (e.g. mood congruent vs. incongruent psychosis, presence vs. absence of Schneiderian symptoms, etc.) also requires further study.
Effects of medication Because the large majority of both clinical and research patients with bipolar disorder are treated with psychotropic medications, assessment of the magnitude and pattern of neuropsychological impairment in bipolar disorder requires understanding of the potential influence of these agents upon neuropsychological functioning. Moreover, the possibility that medications may have a deleterious (this section) or a positive effect (see section at end of chapter) upon cognition should be considered. Increased understanding of the cognitive effects of psychotropic agents used to treat the illness also allows for more accurate specification of the cognitive deficits that are more likely to be inherently associated with the illness and those that are likely related to secondary factors. The influence of medication on cognitive functioning is ideally evaluated through appropriately conducted pro-
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spective randomized clinical trials in patients with bipolar disorder, or through neuropsychological studies that assess medication-free patients with bipolar disorder. Unfortunately, clinical trials aimed at assessing clinical change in bipolar disorder seldom include cognitive outcome variables, and there are relatively few existing neuropsychological studies designed specifically to evaluate drug influences on cognition in bipolar patients. Such studies aimed at assessing medication influences on cognition may also be confounded by change in the patients mood state. Thus, if an agent is observed to show cognitive improvement in the presence of improved mood, it remains unclear whether the cognitive improvement is directly associated with the treating agent or indirectly results from the improved mood. For ethical reasons it is also challenging to evaluate patients cognitively while in the unmedicated state. Moreover, patients that are untreated are more likely to exhibit mood symptoms. As a result, cognitive impairments observed in such patients might arise from the acute symptomatic state rather than from a more stable feature of the illness. Given these barriers, much of the information that is known about psychotropic effects upon cognition in bipolar disorder has been gleaned from either correlational crosssectional studies that evaluate relationships between cognitive measures and medication variables in samples with bipolar disorder, or from research investigating the influence of various agents used to treat bipolar disorder upon cognition in other neurological disorders and in healthy controls. Goldberg (2008) provides a comprehensive review of the common medications that are used to treat bipolar disorder and their effects on neuropsychological functioning in bipolar disorder [17]. Historically, lithium represents the most frequently used mood-stabilizer in bipolar illness, and there is a reasonable literature on the effects of this pharmacological agent upon cognitive functioning in psychiatric patients and healthy individuals. Based on this body of research, it appears that lithium has a reversible and subtle negative effect upon psychomotor speed and a trend toward impaired verbal memory, yet no effect on visual-spatial ability or attention and concentration, and little evidence of prolonged cumulative effect [18]. In terms of the anticonvulsant mood stabilizers that are used to treat the illness, the overall cognitive side-effect profile also appears to be relatively benign. Divalproex has been associated with subtle effects upon attention and memory ability that appear to be dose related and that are also reversible with cessation of treatment [17]. In addition, divalproex treated patients show similar cognitive functioning relative to those treated with lithium [19]. The cognitive impact of carbamazepine has been shown to include mild effects upon learning and reaction time, although these findings have been based primarily on reports on patients with epilepsy and healthy individuals [17]. Oxcarbazepine, a derivative of
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carbamazepine, compares favourably in terms of a cognitive side-effect profile in relation to carbamazepine. With the exception of topiramate, other newer anticonvulsant mood stabilizers show minimal to absent cognitive side effects. In particular, lamotrigine appears to have a favourable side-effect profile and bipolar patients treated with this agent may perform better than those treated with divalproex or carbamazepine [20]. Clearly, the most significant negative cognitive side effects have been reported with topiramate, and cognitive symptoms include diminished word finding, attention and concentration, processing speed, fluency, working memory and perceptual ability [17]. Because of this robust finding, topiramate treated patients presenting with suspected or documented cognitive difficulties should be considered candidates for medication review and/or modification. The other major class of psychotropics used to treat bipolar includes antipsychotics, most frequently the second-generation or atypical antipsychotics. Even though much of the suggestion that these agents have a minimal negative or even beneficial effect on cognition is based on evidence from patients with schizophrenia, considerably less work has evaluated the cognitive effects of these medications on patients with bipolar disorder [21]. Ironically, in samples of patients with bipolar disorder, there is some cross-sectional correlational evidence that treatment with antipsychotics may be associated with mild cognitive side effects, unlike that observed in schizophrenia [17]. Whether this may be an artefact of poorer baseline cognitive scores and thus increased room for improvement in schizophrenia remains unclear. In addition, it is possible that poorer cognitive performance in bipolar patients treated with antipsychotics reflects poorer performance in psychotic bipolar patients rather than preferential cognitive side effects resulting from the antipsychotics. Extrapolating from work that has been conducted primarily in schizophrenia, there is strong evidence that use of anticholinergic agents is associated with clinically significant reductions in attention and memory functioning [17]. Considering other less frequently employed psychotropic medications, specific serotonin reuptake inhibitors (SSRI) antidepressants appear to have minimal negative impact and in some cases may have beneficial impacts upon neuropsychological functioning; however, these findings are almost exclusively based on patients with major depression, as studies in bipolar disorder are lacking [17]. On the other hand, tricyclic antidepressants exert a significant negative impact upon verbal learning and memory that is likely associated with the anticholinergic properties of these agents [17]. A final consideration for the treatment of patients with bipolar disorder concerns the use of benzodiazepines, as these medications have known deleterious cognitive effects upon attention, memory and disinhibition. In summary, although the various medications used to treat
bipolar disorders exert a somewhat variable range of cognitive side effects, their overall impact upon cognitive functioning is relatively minor and in many cases transient. Therefore, it is unlikely that the influence of these medications accounts for the magnitude of cognitive impairment that is observed in bipolar disorder.
Neuroimaging bipolar disorder cognition Advances in neuroimaging over the past 3 decades have progressively afforded unprecedented access to the structure and function of the working brain. Arguably, magnetic resonance imaging (MRI) has undergone the greatest evolution and currently provides the most diverse and pertinent tools for examining brain processing and the ability to question the mind in a manner beyond what is possible with bedside neuropsychological testing [22]. In this section we briefly, and somewhat selectively, review some of the broad emerging insights from functional MRI studies that have examined aspects of bipolar disorder, and discuss their potential clinical salience and implications for future research in the context of cognition. A more comprehensive analysis of neuroimaging findings in bipolar disorder can be found in other chapters contained within this volume. In bipolar disorder research the problems surrounding a lack of consensus as regards diagnostic classification have made less of an impact on neuroimaging research than other fields, possibly because most studies have been conducted relatively recently over the past decade. A review of fMRI studies in bipolar disorder published in 2004 [23] noted the potential for identifying functional markers of bipolar disorder as findings from different groups [24–27] appeared to be implicating overlapping brain regions in the dysfunctional processing associated with bipolar disorder as compared to healthy controls. Since then, a number of influential models to explain bipolar disorder processing have been posited [28–30] and, though these have provided a useful framework for the interpretation of findings, many aspects of the functional differences seen in patients cannot be fully explained. Over the past five years, many more fMRI studies examining bipolar disorder [26,27,31–68] have been conducted. Most of these have been conducted in adults; however, an increasing number have examined younger populations [32,40,41,44,61–63], reflecting the heightened interest in identifying the early markers of bipolarity. In addition to the obvious population differences, the studies vary considerably in terms of the fMRI stimuli used, the paradigms employed for analysis and the extent to which potential confounds have been controlled. Medication is a prominent concern but one that is extremely difficult to manage ethically given that unmedicated bipolar patients are at greater risk of relapse. However, a few groups have attempted to identify the effects of medication by adopting longitudinal
Neurocognition in Bipolar Disorder
designs, but retention in these studies, and the numbers that are successfully scanned on two or more occasions, is extremely small (<10). In fact, samples in the majority of studies are modest (<20) and consequently most findings remain speculative. The array of stimuli that have been used in bipolar disorder fMRI studies is extensive and varied, and as such many cannot be meaningfully compared, either to each other, or indeed to the bedside neuropsychological tests from which they have been derived and adapted for the MRI environment. Clearly, the latter is also not a true reflection of reality and has by its very nature many constraints that introduce further confounds that need to be borne in mind when considering fMRI data, such as the extreme noise of the scanner and the need to remain very still during the whole procedure. Nevertheless, the findings from fMRI experiments in bipolar disorder are proving to be extremely interesting and are providing unique insights into bipolar brain processing [22]. Functional MRI studies in bipolar disorder have basically attempted to explore both state (related to periods of mood disturbance) and trait (related to personality and genetic factors) markers of the illness. In order to do this, researchers have examined bipolar patients both when they are acutely unwell, namely when suffering from symptoms of depression or mania/hypomania, and when reasonably recovered and symptom-free, namely euthymic. Across each of these groups, essentially two broad neuropsychological domains have been probed; emotion and cognition. The range of cognitive paradigms that have been used have been designed primarily to probe executive control functions such as working memory, response generation, response inhibition and sustained attention. It should be noted that in many instances the cognitive and emotional components are difficult to separate and the tests that have been utilized may in fact not be able to partition these functions. Functional MRI studies have attempted to investigate aspects of cognitive and emotional processing in bipolar disorder, using a wide variety of stimuli across the phases of the illness. These studies have been conducted predominantly in adult samples of subjects but there are a number of studies examining adolescent/paediatric populations that have demonstrated some interesting insights into the putative evolution of functional changes in bipolar disorder [32,40,41,44,61–63]. Thus far, the vast majority of studies have been cross-sectional; however, a number of ambitious studies have attempted to scan patients longitudinally with variable success [39,41,48,58,59]. The studies can be summarized according to mood state or paradigm-focus; however, the findings are not so easy to coalesce. The majority of studies have examined euthymic patients (though earlier studies, prior to 2004, began by examining depressed bipolar and indeed unipolar patients) using in particular cognitive paradigms [32,33,43,
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44,47,49–51,58–61,64–66]. Studies across each of the phases consistently show that there are functional differences in bipolar patients as compared to healthy controls and that the regions implicated are those involved in executive functioning and emotional processing, specifically the prefrontal cortex and limbic system. What is perhaps surprising is that the distinction between phases is not self-evident with many functional differences (as compared to healthy subjects) still present in euthymia. For example, a relatively consistent finding across all mood states and euthymia is increased subcortical limbic activity (amygdala, ventral striatum, hippocampus) to emotional stimuli in patients with bipolar disorder, as well as abnormal activation in prefrontal cortical areas that modulate these limbic regions. Studies that have attempted to differentiate the various mood states of bipolar disorder have shown both underactivity and hyperactivity that is not necessarily related to bipolar polarity but does distinguish illness from wellness. However, the extent to which these putative functional changes perceived on fMRI are unique to bipolar disorder remains unknown, as few studies have successfully examined comparable unipolar and bipolar depressed populations in significant numbers using the same paradigms. In conjunction with findings from neuropsychological studies, it is likely that both mood states and the very essence of having bipolar disorder contribute to significant changes in brain processing that are reflected in cognitive and emotional compromise. In this respect, studies that have examined younger populations have shown that the patterns are quite possibly different to those found in adults, and that the adult fMRI picture emerges sometime during adolescence. This is important because in addition to using fMRI to partition bipolar disorder from major depression and schizophrenia and better understand the pathophysiology of the disorder in adults, it can potentially be used to identify the emergence and early-onset of bipolar disorder and to this end it is necessary to know the pattern of MRI changes in younger years and how these evolve. Discussion of specific findings from each of the imaging studies in both adults and younger populations is beyond the scope of this chapter; however, in summary, the findings appear to implicate abnormalities in the regulation of prefrontalsubcortical circuits that subserve emotion with generally heightened activity as compared to healthy controls in these regions during youth that then diminishes with advancing years and progression of the illness. These tentative findings raise tantalizing possibilities but need to be reaffirmed and established in patients without the potentially significant confounds of medication. Large longitudinal studies coupled with even larger cross-sectional studies are needed, using perhaps standardized fMRI stimuli and paradigms. Emotional dysregulation that is perhaps a consequence of diminished cognitive control is certainly observed in bipolar patients when unwell. In adults,
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fMRI imaging studies suggest that there is a diminution of the regulatory control exerted by prefrontal structures of the brain coupled with either primary or secondary hyperactivity in subcortical structures. This pattern has not been shown to reliably change with treatment and whether it is a state or trait-marker is unclear. However, cognitive impairment is often noted in patients with bipolar disorder and it is possible that this is the primary deficit in patients that leads to corticalsubcortical neurocircuit dysfunction [24,28–30]. The next step in neuroimaging research (once initial findings have been adequately clarified and corroborated) is to localize the cognitive deficits seen neuropsychologically using imaging and to link these findings to genetic markers.
the cognitive performance of healthy first-degree relatives of patients with the illness. Because unaffected relatives share substantial genetic overlap with bipolar probands, observed cognitive deficits in healthy relatives (relative to appropriately matched healthy controls) could indicate that identified cognitive deficits have a genetic basis associated with vulnerability for the illness. This is particularly the case when cognitive abilities with high heritability are considered [70]. Identification of cognitive deficits in unaffected relatives may in turn facilitate the search for specific genetic and causal mechanisms underlying the illness. Such cognitive deficits may turn out to represent endophenotypes that are more genetically discoverable due to their presumed closer link to genes as well as their lesser biological complexity when compared to psychiatric phenotypes. Another advantage of studying high risk samples is that unlike patients, relatives of patients with the illness are free of medications and prominent mood symptoms, which as described above could exert some influence on cognitive functioning. In the past few years, an increasing number of cognitive studies in high risk populations have been published, and as of this writing there are two very recent meta-analytic studies that have been conducted on this literature [5,6]. Figure 2 summarizes these meta-analytic data by plotting the mean effect size cognitive differences between healthy first-degree relatives of patients with bipolar disorder and matched healthy controls. Although considerably attenuated relative to patients with bipolar illness (see Figure 1), healthy relatives of patients with bipolar disorder nonetheless show significant declines in the primary domains of verbal learning and memory, executive functioning (set shifting, response inhibition) and sustained attention (inattention rather than impulsivity). These data provide
Aetiology of cognitive impairment Because cognitive deficits in bipolar disorder are not likely to be fully explained by variables such as residual mood symptoms or medication effects, and because they likely at least partly reflect underlying brain dysfunction, the question of the aetiology of these core neuropsychological deficits becomes central. Two possibilities (not mutually exclusive) that have been considered are that cognitive impairments at least partly result from genetic vulnerability associated with the illness, and that cognitive impairments are the result of progressive deficits associated with increased illness burden [30,69].
Genetic vulnerability A major strategy for investigating whether cognitive impairment in bipolar disorder results from genetic susceptibility associated with the illness consists of evaluating 1.0 0.8
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Fig. 2 Summary of 2 meta-analyses illustrating the mean effect size differences between first-degree relatives of patients with bipolar disorder and healthy controls. Note: if an effect size for a given measure was reported in more than one meta-analysis, then the mean value was calculated. WCST ¼ Wisconsin Card Sorting Test; CPT ¼ Continuous Performance Test.
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evidence that at least a portion of the cognitive impairment associated with bipolar disorder is likely to be due to genetic vulnerability to the illness, and that the described deficits may serve as primary candidate endophenotypes of bipolar disorder. In addition, based on the cognitive deficits identified in relatives, the brain systems implicated include frontal-temporal-limbic brain regions. At this point, the search into the genetic basis of potential cognitive endophenotypes in bipolar disorder is in its infancy. This effort will require continued refinement of the appropriate endophenotype(s) for bipolar disorder and discovery of their genetic basis. A further approach to determining the genetic basis of the bipolar disorder phenotype is to assess whether specific candidate genes and their known or suspected biological functions are abnormally represented in bipolar disorder, and whether these genetic variants are associated with clinical features of the illness such as cognitive impairment. Although these studies are more prevalent in the context of schizophrenia, they are beginning to emerge in bipolar disorder. Burdick et al. (2007) reported an association between diagnosis of bipolar I disorder and a specific single nucleotide polymorphism (SNP) on the catechol O-methyltransferace (COMT) gene, which has been linked to prefrontal dopamine metabolism and availability [71]. Importantly, they also found an association between presence of the risk allele in patients and verbal memory performance. Similarly, the Val66Met polymorphism of the BDNF gene, which has been implicated to be involved in various mood disorders, has also been found to associate with Wisconsin Card Sorting Test performance in patients with bipolar disorder [72]. In addition, in a large cohort of families with bipolar disorder, specific allelic variants of the disrupted-in-schizophrenia-1 (DISC-1) gene, which encodes for a multifunctional protein involved in neurodevelopment and synaptic modulation, were associated with either presence of psychosis or bipolar spectrum diagnosis [73]. Moreover, these genetic variants were associated with cognitive functioning, including perseveration (psychosis) as well as processing speed and verbal fluency (bipolar spectrum). These and similar studies may provide preliminary insights into the genetic basis of bipolar disorder and its clinical features. However, the aetiology of psychiatric disorders such as bipolar disorder is likely complex and determined by multiple genetic and environmental factors [70]. Nevertheless, efforts to link genetic variants to bipolar illness and associated clinical features, such as cognitive impairment and psychosis, may help to clarify this complexity and identify the overlap between disorders such as bipolar disorder and schizophrenia.
of whether deficits may progress throughout the course of illness. The potential underlying causes of progressive decline are varied, and could include toxicity resulting from increased illness duration, chronicity, multiple episodes or cumulative treatment side effects. One indirect method of addressing whether cognitive deficits may be progressive has been to evaluate correlations between cognitive impairment and illness burden variables such as duration of illness, number of hospitalizations and number of episodes in samples of patients with bipolar disorder. In a review of this literature, Robinson et al. (2006) evaluated existing studies of cognitive functioning in bipolar disorder and compiled the correlations between neuropsychological variables and multiple illness burden variables, including number of affective episodes (manic, depressive, total), number of hospitalizations, age at illness onset, duration of illness and length of time in euthymia [69]. Their analysis revealed that poor cognitive function, especially verbal memory, was frequently associated with multiple burden variables, including previous number of affective episodes, illness duration and number of hospital admissions. Regarding mood episodes, an increasing number of manic episodes was associated with diminished delayed verbal memory and some aspects of executive function, whereas an increasing number of depressive episodes was less strongly associated with a wider range of cognitive impairment. The implication of these findings is that cognition declines as a result of an increasing number of mood episodes, hospitalizations and illness duration. However, these observations should be interpreted cautiously because of their cross-sectional correlational nature, and because of the possibility that the path of causation could be in the reverse direction. That is, it is possible that patients with poorer cognitive impairment to begin with follow a trajectory of poorer outcome that includes more mood episodes and a higher number of hospitalizations. As the authors point out, there are also other potential confounds inherent in this literature, including a likely bias for reporting positive cognition-burden correlations as well as the failure to control for other potentially important variables such as age and current symptom ratings in these correlations. As a result, although existing data provide some preliminary support for the hypothesis that cognition declines throughout the course of illness, a stronger test will need to come from longitudinal studies that track neuropsychological function in patients across time.
Progressive cognitive decline
In light of the converging evidence that cognitive impairment is highly prevalent in bipolar disorder, a further question that arises is whether these cognitive deficits have a significant impact on patients everyday functioning. If
A second major line of enquiry regarding the aetiology of cognitive deficits in bipolar disorder involves investigation
Clinical significance of cognitive impairments
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indeed cognitive impairment in bipolar disorder is predictive of an individuals real-world adaptive functioning, this underscores the urgency to identify and treat these cognitive deficits in the hope of improving functional outcome and quality of life.
cognitive assessment [78]. By linking cognition, not only to present but future psychosocial functioning, such longitudinal studies may provide further insight into the causal direction of the association between cognition and psychosocial functioning.
Cognition and functional outcome
Neuropsychological assessment in bipolar disorder
Establishing a link between the cognitive impairments observed in bipolar disorder and indices of everyday functioning, serves to reinforce the importance of detecting and understanding cognitive impairments in this population. In the same way that multiple measures have been developed for assessing cognitive impairment, there are multiple ways of measuring everyday psychosocial functioning in patients. One of the simplest and most frequent methods for measuring everyday function consists of using global ratings such as the DSM based Global Assessment of Functioning (GAF) scale or similar scales. A number of studies have been conducted, aimed at assessing the correlation between scores on global functioning scales and a range of cognitive measures. In general, these studies have revealed a consistent association between global psychosocial functioning and cognitive functioning, primarily in the domains of (verbal) memory functioning and several aspects of executive function [74]. Other investigators have also evaluated the cognitive correlates of more specific functional domains, such as occupational status. These studies also support a robust association between cognitive functioning and work status in similar cognitive domains. Importantly, the association between cognitive and functional outcome does not appear to be a function of symptomatic status, as when psychiatric symptom variables are controlled the cognition-function association persists. Nevertheless, associations between cognition and functional outcome may be stronger in symptomatic rather than euthymic samples [75]. In addition, the correlation between cognition and psychosocial functioning may be more evident in studies where functional status is derived from objective rather than subjective outcome measures. The basis for this is unclear, but may be associated with diminished insight in patients with bipolar disorder [74]. Although the large majority of studies in this area have investigated cognitive and psychosocial functioning concurrently, at least two studies have measured these outcomes longitudinally. Jaeger et al. (2007) reported that baseline measures of attention and ideational fluency were predictive of psychosocial functioning after 1 year, even after control of residual symptoms at both time points [76]. In our own work, we have recently reported that cognitive deficits are present in clinically stable patients after they have experienced their first lifetime manic episode [77]. Moreover, such early cognitive deficits observed in these patients, particularly in the memory domain, appear predictive of psychosocial functional outcome 6 months after
In light of the relevance of cognitive impairment to bipolar disorder, cognitive assessment should be considered a key element of standard of care in contemporary practice. In patients who present with diminished psychosocial functioning, neuropsychological assessment can be a useful means to help sort out the underlying determinants of dysfunction and evaluate whether cognitive factors may be contributing to poor daily function. In instances where neuropsychological deficits are minimal or absent, difficulties in functioning may then be attributed to other potential underlying factors such as mood symptoms, comorbidity, personality variables, situational factors and other variables that require attention. Due to the weak correlation between subjective patient reports of cognitive symptoms and objective testing results [79], clinicians should not exclusively rely on patient reports as the sole basis for investigating potential cognitive impairments. Similarly, self-report of cognitive complaints may not always reflect objective cognitive impairment, but instead may be associated with mood states, particularly depression. A comprehensive neuropsychological evaluation should be guided by knowledge of the cognitive functions that are most frequently implicated in bipolar disorder (Figure 1). Brief cognitive screening approaches may have some utility in initial screening of patients, but are limited by diminished psychometric properties and reduced sensitivity to cognitive impairment. This may result in increased false negative rates, particularly in individuals presenting with less severe cognitive deficits. Based on the increasing recognition that deficits are likely present at illness onset [77,80], neuropsychological evaluation is warranted early in the course of illness so that strengths and weaknesses can be identified and rehabilitative and treatment recommendations can be made. Early assessments can also establish baseline levels of neuropsychological functioning that can be used to assess longitudinal changes in cognitive functioning. Unless the goal is to assess short-term treatment effects upon cognition, neuropsychological referrals should be made when patients are relatively clinically stable and asymptomatic.
Treatment strategies for cognitive deficits At this point, the utility of neuropsychological assessment in bipolar disorder primarily lies in the delineation of
Neurocognition in Bipolar Disorder
cognitive strengths and weaknesses and in contributing to the formulation of treatment, rehabilitative and disposition plans. However, identified cognitive deficits should be increasingly considered legitimate targets for treatment interventions, and neuropsychological measures should be used as clinical outcome measures for quantifying change in patients neurocognitive status. To date there have been remarkably few controlled clinical trials assessing either the positive or negative effects of pharmacological treatments on cognition in bipolar disorder. As a result, there are no established rational or evidence based treatments for cognitive deficits in bipolar disorder [81,82]. Of the current mood stabilizers used to treat bipolar disorder, lamotrigine appears to be associated with the most positive cognitive profile, and there is at least scant evidence that this agent may lead to some improvement in cognitive function in bipolar disorder [83]. The effects of atypical antipsychotics on cognition in bipolar disorder have also been understudied, making it difficult to assess whether the modest cognitive enhancement properties that are periodically observed in schizophrenia also apply to bipolar disorder. There is some evidence suggesting possible cognitive enhancement resulting from treatment with risperidone relative to a conventional antipsychotic [84]; however, clearly more work is needed to assess the potential cognitive enhancing role of antipsychotics. The use of procholinergic cognitive enhancers has primarily been evaluated in the context of dementia and age-associated cognitive impairment, so the utility of these agents in bipolar disorder is largely unknown. Several case studies indicate that galantamine may have some positive effects on cognition, but this requires further study in controlled clinical trials [82]. It is also too early to tell whether there is a role for treatment with psychostimulants in boosting cognitive function in bipolar disorder. Pramipexole, a D2/D3 receptor agonist that increases the availability of dopamine, has been shown to have potential cognitive enhancing properties when used as an adjunctive treatment in bipolar disorder [81]. In another experimental study, there is some evidence that mifepristone, a glucocorticoid receptor antagonist, may have a positive influence on executive and memory functions based on its actions on a dysfunctional HPA system [85]. To summarize, despite the fact that treatment studies targeting cognitive deficits in patients with bipolar disorder are in their early stages, there is some cause for optimism that interventions will be developed to target this important clinical feature of bipolar disorder.
Conclusions The pace of research into cognitive functioning in bipolar disorder has accelerated rapidly within the past few years, and it is now recognized that cognitive impairment represents an important clinical feature of bipolar disorder.
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Although individuals diagnosed with bipolar disorder demonstrate a wide range of cognitive functioning, a significant proportion of patients with the diagnosis can be expected to show clinically significant cognitive impairment. Cognitive dysfunction occurs independently of mood state and is most frequently expressed through diminished performance on neuropsychological tests of attention, memory and executive functioning. Although cognitive ability in patients is influenced by acute psychiatric symptoms and medications, these variables do not account for the persistent underlying deficits observed in the illness. Increasingly, cognitive impairments have been linked to dysfunctional brain systems; however, cognitive imaging studies have employed diverse methodologies and small patient samples, thus limiting the ability to make firm conclusions. Nevertheless, these studies implicate the involvement and dysregulation of a complex distributed network of cortical, subcortical and limbic brain regions underlying abnormal cognition and emotion in the illness. Preliminary work suggests that subsets of patients with psychotic symptoms and with the bipolar I subtype may show preferential cognitive impairment; however, the validity of these findings and of putative bipolar disorder subtypes requires further study. Although the underlying cause(s) of neuropsychological deficits have yet to be revealed, it is likely that impairments reflect both fixed and progressive components, and that both genetic and neurotoxic or deteriorative influences may be present. The clinical urgency to both identify and treat neuropsychological deficits in bipolar disorder is highlighted by the consistent finding that cognitive deficits reliably predict everyday psychosocial functioning. However, there is currently a paucity of research into treatments approaches aimed at enhancing cognitive abilities in bipolar disorder, and this represents an important area for future research.
References 1. Goldberg, J.F. and Burdick, K.E. (2008) Cognitive Dysfunction in Bipolar Disorder: A Guide for Clinicians, American Psychiatric Press, Washington, DC. 2. Lezak, M.D., Howieson, D.B. and Loring, D.W. (2004) Neuropsychological Assessment, 4th edn, Oxford University Press, New York. 3. Clark, L., Iversen, S.D. and Goodwin, G.M. (2001) A neuropsychological investigation of prefrontal cortex involvement in acute mania. Am. J. Psychiatry, 158, 1605–1611. 4. Malhi, G.S., Cahill, C.S. and Mitchell, P. (2008) Impact of mood, anxiety, and psychotic symptoms on cognition in patients with bipolar disorder, in Cognitive Dysfunction in Bipolar Disorder: A Guide for Clinicians (eds J.F. Goldbergand K.E. Burdick), American Psychiatric Press, Washington, DC, pp. 89–111. 5. Arts, B., Jabben, N., Krabbendam, L. and van Os, J. (2008) Meta-analyses of cognitive functioning in euthymic bipolar
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patients and their first-degree relatives. Psychol. Med., 38, 771–785. Bora, E., Yucel, M. and Pantelis, C. (2009) Cognitive endophenotypes of bipolar disorder: A meta-analysis of neuropsychological deficits in euthymic patients and their firstdegree relatives. J. Affect. Disord., 113, 1–20. Robinson, L.J., Thompson, J.M., Gallagher, P. et al. (2006) A meta-analysis of cognitive deficits in euthymic patients with bipolar disorder. J. Affect. Disord., 93, 105–115. Torres, I.J., Boudreau, V.G. and Yatham, L.N. (2007) Neuropsychological functioning in euthymic bipolar disorder: A meta-analysis. Acta. Psychiatr. Scand., 116 (Suppl 434), 17–26. Krabbendam, L., Arts, B., van Os, J. and Aleman, A. (2005) Cognitive functioning in patients with schizophrenia and bipolar disorder: A quantitative review. Schizophr. Res., 80, 137–149. Martınez-Aran, A., Vieta, E., Colom, F. et al. (2004) Cognitive impairment in euthymic bipolar patients: Implications for clinical and functional outcome. Bipolar Disord., 6, 224–232. Thompson, J.M., Gallagher, P., Hughes, J.H. et al. (2005) Neurocognitive impairment in euthymic patients with bipolar affective disorder. Br. J. Psychiatry: The Journal of Mental Science, 186, 32–40. Simonsen, C., Sundet, K., Vaskinn, A. et al. (2008) Neurocognitive profiles in bipolar I and bipolar II disorder: Differences in pattern and magnitude of dysfunction. Bipolar Disord., 10, 245–255. Torrent, C., Martinez-Aran, A., Daban, C. et al. (2006) Cognitive impairment in bipolar II disorder. Brit. J. Psychiat., 189, 254–259. Murray, R.M., Sham, P., Van Os, J. et al. (2004) A developmental model for similarities and dissimilarities between schizophrenia and bipolar disorder. Schizophr. Res., 71, 405–416. de Almeida Rocca, C.C., de Macedo-Soares, M.B., Gorenstein, C. et al. (2008) Verbal fluency dysfunction in euthymic bipolar patients: A controlled study. J. Affect. Disord., 107, 187–192. Glahn, D.C., Bearden, C.E., Barguil, M. et al. (2007) The neurocognitive signature of psychotic bipolar disorder. Biol. Psychiatry., 62, 910–916. Goldberg, J.F. (2008) Adverse cognitive effects of psychotropic medications, in Cognitive Dysfunction in Bipolar Disorder: A Guide for Clinicians (eds J.F. Goldbergand K.E. Burdick), American Psychiatric Press, Washington, DC, pp. 137–158. Pachet, A.K. and Wisniewski, A.M. (2003) The effects of lithium on cognition: An updated review. Psychopharmacology (Berl.), 170, 225–234. Senturk, V., Goker, C., Bilgic, A. et al. (2007) Impaired verbal memory and otherwise spared cognition in remitted bipolar patients on monotherapy with lithium or valproate. Bipolar Disord., 9 (Suppl 1), 136–144. Daban, C., Martinez-Aran, A., Torrent, C. et al. (2006) Cognitive functioning in bipolar patients receiving lamotrigine: Preliminary results. J. Clin. Psychopharmacol., 26, 178–181. Macqueen, G. and Young, T. (2003) Cognitive effects of atypical antipsychotics: Focus on bipolar spectrum disorders. Bipolar Disord., 5 (Suppl 2), 53–61.
22. Malhi, G.S. and Lagopoulos, J. (2008) Making sense of neuroimaging in psychiatry. Acta Psychiatr. Scand., 117, 100–117. 23. Malhi, G.S., Lagopoulos, J., Owen, A.M. and Yatham, L.N. (2004) Bipolaroids: functional imaging in bipolar disorder. Acta Psychiatr. Scand., 110 (Suppl 422), 46–54. 24. Blumberg, H., Leung, H., Skudlarski, P.E.A. et al. (2003) A functional magnetic resonance imaging study of bipolar disorder: state- and trait-related dysfunction in ventral prefrontal cortices. Arch. Gen. Psychiatry, 60, 601–609. 25. Yurgelun-Todd, D.A., Gruber, S.A., Kanayama, G. et al. (2000) fMRI during affect discrimination in bipolar affective disorder. Bipolar Disord., 2, 237–248. 26. Malhi, G.S., Lagopoulos, J., Ward, P.B. et al. (2004) Cognitive generation of affect in bipolar depression: an fMRI study. Eur. J. Neurosci., 19, 741–754. 27. Malhi, G.S., Lagopoulos, J., Sachdev, P. et al. (2004) Cognitive generation of affect in hypomania: an fMRI study. Bipolar Disord., 6, 271–285. 28. Phillips, M.L., Drevets, W.C., Rauch, S.L. and Lane, R.D. (2003) Neurobiology of emotion perception I: The neural basis of normal emotion perception. Biol. Psychiatry, 54, 504–514. 29. Phillips, M.L., Drevets, W.C., Rauch, S.L. and Lane, R.D. (2003) The neurobiology of emotion perception II: Implications for major psychiatric disorders. Biol. Psychiatry, 54, 515–528. 30. Strakowski, S.M., Delbello, M.P. and Adler, C.M. (2005) The functional neuroanatomy of bipolar disorder: a review of neuroimaging findings. Mol. Psychiatry, 10, 105–116. 31. Abler, B., Greenhouse, I., Ongur, D. et al. (2008) Abnormal reward system activation in mania. Neuropsychopharmacology, 33, 2217–2227. 32. Adler, C.M., Delbello, M.P., Mills, N.P. et al. (2005) Comorbid ADHD is associated with altered patterns of neuronal activation in adolescents with bipolar disorder performing a simple attention task. Bipolar Disord., 7, 577–588. 33. Adler, C.M., Holland, S.K., Schmithforst, V. et al. (2004) Changes in neuronal activation in patients with bipolar disorder during performance of a working memory task. Bipolar Disord., 6, 540–549. 34. Altshuler, L., Bookheimer, S., Proenza, M.A. et al. (2005) Increased amygdala activation during mania: a functional magnetic resonance imaging study. Am. J. Psychiatry, 162, 1211–1213. 35. Altshuler, L., Bookheimer, S., Townsend, J. et al. (2008) Regional brain changes in bipolar I depression: a functional magnetic resonance imaging study. Bipolar Disord., 10, 708–717. 36. Altshuler, L., Bookheimer, S., Townsend, J. et al. (2005) Blunted activation in orbitofrontal cortex during mania: a functional magnetic resonance imaging study. Biol. Psychiatry, 58, 763–769. 37. Blumberg, H.P., Donegan, N.H., Sanislow, C.A. et al. (2005) Preliminary evidence for medication effects on functional abnormalities in the amygdala and anterior cingulate in bipolar disorder. Psychopharmacology (Berl.), 183, 308–313. 38. Caligiuri, M.P., Brown, G.G., Meloy, M.J. et al. (2006) Striatopallidal regulation of affect in bipolar disorder. J. Affect. Disord., 91, 235–242.
Neurocognition in Bipolar Disorder 39. Caligiuri, M.P., Brown, G.G., Meloy, M.J. et al. (2004) A functional magnetic resonance imaging study of cortical asymmetry in bipolar disorder. Bipolar Disord., 6, 183–196. 40. Chang, K., Adleman, N.E., Dienes, K. et al. (2004) Anomalous prefrontal-subcortical activation in familial pediatric bipolar disorder: a functional magnetic resonance imaging investigation. Arch. Gen. Psychiatry, 61, 781–792. 41. Chang, K.D., Wagner, C., Garrett, A. et al. (2008) A preliminary functional magnetic resonance imaging study of prefrontal-amygdalar activation changes in adolescents with bipolar depression treated with lamotrigine. Bipolar Disord., 10, 426–431. 42. Chen, C.H., Lennox, B., Jacob, R. et al. (2006) Explicit and implicit facial affect recognition in manic and depressed States of bipolar disorder: a functional magnetic resonance imaging study. Biol. Psychiatry, 59, 31–39. 43. Curtis, V.A., Thompson, J.M., Seal, M.L. et al. (2007) The nature of abnormal language processing in euthymic bipolar I disorder: evidence for a relationship between task demand and prefrontal function. Bipolar Disord., 9, 358–369. 44. Dickstein, D.P., Rich, B.A., Roberson-Nay, R. et al. (2007) Neural activation during encoding of emotional faces in pediatric bipolar disorder. Bipolar Disord., 9, 679–692. 45. Elliot, R., Ogilvie, A., Rubinszetin, J.S. et al. (2004) Abnormal ventral frontal response during performance of an affective go/no go task in patients with mania. Biol. Psychiatry, 55, 1163–1170. 46. Foland, L.C., Altshuler, L.L., Bookheimer, S.Y. et al. (2008) Evidence for deficient modulation of amygdala response by prefrontal cortex in bipolar mania. Psychiatry Res., 162, 27–37. 47. Gruber, S.A., Rogowska, J. and Yurgelun-Todd, D.A. (2004) Decreased activation of the anterior cingulate in bipolar patients: an fMRI study. J. Affect. Disord., 82, 191–201. 48. Haldane, M., Jogia, J., Cobb, A. et al. (2008) Changes in brain activation during working memory and facial recognition tasks in patients with bipolar disorder with Lamotrigine monotherapy. Eur. Neuropsychopharm., 18, 48–54. 49. Kronhaus, D.M., Lawrence, N.S., Williams, A.M. et al. (2006) Stroop performance in bipolar disorder: further evidence for abnormalities in the ventral prefrontal cortex. Bipolar Disord., 8, 28–39. 50. Lagopoulos, J., Ivanovski, B. and Malhi, G.S. (2007) An eventrelated functional MRI study of working memory in euthymic bipolar disorder. J. Psychiatr. Neurosci., 32, 174–184. 51. Lagopoulos, J. and Malhi, G.S. (2007) A functional magnetic resonance imaging study of emotional Stroop in euthymic bipolar disorder. Neuroreport, 18, 1583–1587. 52. Lawrence, N.S., Williams, A.M., Surguladze, S. et al. (2004) Subcortical and ventral prefrontal cortical neural responses to facial expressions distinguish patients with bipolar disorder and major depression. Biol. Psychiatry, 55, 578–587. 53. Lennox, B.R., Jacob, R., Calder, A.J. et al. (2004) Behavioural and neurocognitive responses to sad facial affect are attenuated in patients with mania. Psychol. Med., 34, 795–802. 54. Malhi, G.S., Lagopoulos, J., Owen, A.M. et al. (2007) Reduced activation to implicit affect induction in euthymic bipolar patients: an fMRI study. J. Affect. Disord., 97, 109–122.
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55. Malhi, G.S., Lagopoulos, J., Sachdev, P. et al. (2005) An emotional Stroop functional MRI study of euthymic bipolar disorder. Bipolar Disord., 7 (Suppl 5), 58–69. 56. Malhi, G.S., Lagopoulos, J., Sachdev, P.S. et al. (2007) Is a lack of disgust something to fear? A functional magnetic resonance imaging facial emotion recognition study in euthymic bipolar disorder patients. Bipolar Disord., 9, 345–357. 57. Malhi, G.S., Lagopoulos, J., Das, P. et al. (2008) A functional MRI study of theory of mind in euthymic bipolar disorder patients. Bipolar Disord., 10, 1–14. 58. Marchand, W.R., Lee, J.N., Tatcher, G.W. et al. (2007) A functional MRI study of a paced motor activation task to evaluate frontal-subcortical circuit function in bipolar depression. Psychiatry Res., 155, 221–230. 59. Marchand, W.R., Lee, J.N., Tatcher, J. et al. (2007) A preliminary longitudinal fMRI study of frontal-subcortical circuits in bipolar disorder using a paced motor activation paradigm. J. Affect. Disord., 103, 237–241. 60. Monks, P.J., Thompson, J.M., Bullmore, E.T. et al. (2004) A functional MRI study of working memory task in euthymic bipolar disorder: evidence for task-specific dysfunction. Bipolar Disord., 6, 550–564. 61. Nelson, E.E., Vinton, D.T., Berghorst, L. et al. (2007) Brain systems underlying response flexibility in healthy and bipolar adolescents: an event-related fMRI study. Bipolar Disord., 9, 810–819. 62. Pavuluri, M.N., OConnor, M.M., Harral, E. and Sweeney, J.A. (2007) Affective neural circuitry during facial emotion processing in pediatric bipolar disorder. Biol. Psychiatry, 62, 158–167. 63. Rich, B.A., Vinton, D.T., Roberson-Nay, R. et al. (2006) Limbic hyperactivation during processing of neutral facial expressions in children with bipolar disorder. Proc. Natl. Acad. Sci. USA, 103, 8900–8905. 64. Roth, R.M., Koven, N.S., Randolph, J.J. et al. (2006) Functional magnetic resonance imaging of executive control in bipolar disorder. Neuroreport, 17, 1085–1089. 65. Strakowski, S.M., Adler, C.M., Holland, S.K. et al. (2004) A preliminary FMRI study of sustained attention in euthymic, unmedicated bipolar disorder. Neuropsychopharmacology, 29, 1734–1740. 66. Strakowski, S.M., Adler, C.M., Holland, S.K. et al. (2005) Abnormal FMRI brain activation in euthymic bipolar disorder patients during a counting Stroop interference task. Am. J. Psychiatry, 162, 1697–1705. 67. Taylor Tavares, J.V., Clark, L., Furey, M.L. et al. (2008) Neural basis of abnormal response to negative feedback in unmedicated mood disorders. Neuroimage, 42, 1118–1126. 68. Wessa, M., Houenou, J., Paillere-Martinot, M.L. et al. (2007) Fronto-striatal overactivation in euthymic bipolar patients during an emotional go/nogo task. Am. J. Psychiatry, 164, 638–646. 69. Robinson, L.J. and Ferrier, I.N. (2006) Evolution of cognitive impairment in bipolar disorder: A systematic review of cross-sectional evidence. Bipolar Disord., 8, 103–116. 70. Glahn, D.C., Bearden, C.E., Niendam, T.A. and Escamilla, M.A. (2004) The feasibility of neuropsychological endophenotypes
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72.
73.
74.
75.
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in the search for genes associated with bipolar affective disorder. Bipolar Disord., 6, 171–182. Burdick, K.E., Funke, B., Goldberg, J.F. et al. (2007) COMT genotype increases risk for bipolar I disorder and influences neurocognitive performance. Bipolar Disord., 9, 370–376. Rybakowski, J.K., Borkowska, A., Skibinska, M. et al. (2006) Prefrontal cognition in schizophrenia and bipolar illness in relation to Val66Met polymorphism of the brain-derived neurotrophic factor gene. Psychiatry Clin. Neurosci., 60, 70–76. Palo, O.M., Antila, M., Silander, K. et al. (2007) Association of distinct allelic haplotypes of DISC1 with psychotic and bipolar spectrum disorders and with underlying cognitive impairments. Hum. Mol. Genet., 16, 2517–2528. Torres, I.J., DeFreitas, C.M. and Yatham, L.N. (2008) Cognition and functional outcome in bipolar disorder, in Cognitive Dysfunction in Bipolar Disorder: A Guide for Clinicians (eds J.F. Goldbergand K.E. Burdick), American Psychiatric Press, Washington, DC, pp. 217–234. Malhi, G.S., Ivanovski, B., Hadzi-Pavlovic, D. et al. (2007) Neuropsychological deficits and functional impairment in bipolar depression, hypomania and euthymia. Bipolar Disord., 9, 114–125. Jaeger, J., Berns, S., Loftus, S. et al. (2007) Neurocognitive test performance predicts functional recovery from acute exacerbation leading to hospitalization in bipolar disorder. Bipolar Disord., 9, 93–102. Torres, I.J., DeFreitas, V.G., DeFreitas, C.M. et al. (2010) Neurocognitive functioning in bipolar I patients recently recovered from a first manic episode. J. Clin. Psychiat. (doi:10.4088/JCP.08m04997yel).
78. Torres, I.J., DeFreitas, C.M., DeFreitas, V.G. et al. (submitted) Relationship between cognitive functioning and six month clinical and functional outcome in patients with first episode Bipolar I Disorder. 79. Burdick, K.E., Endick, C.J. and Goldberg, J.F. (2005) Assessing cognitive deficits in bipolar disorder: Are self-reports valid? Psychiatry Res., 136, 43–50. 80. Gruber, S.A., Rosso, I.M. and Yurgelun-Todd, D. (2008) Neuropsychological performance predicts clinical recovery in bipolar patients. J. Affect. Disord., 105, 253–260. 81. Burdick, K.E., Braga, R.J., Goldberg, J.F. and Malhotra, A.K. (2007) Cognitive dysfunction in bipolar disorder: Future place of pharmacotherapy. CNS Drugs, 21, 971–981. 82. Goldberg, J.F. and Young, L.T. (2008) Pharmacologic strategies to enhance neurocognitive function, in Cognitive Dysfunction in Bipolar Disorder: A Guide for Clinicians (eds J. F. Goldbergand K.E. Burdick), American Psychiatric Press, Washington, DC, pp. 159–194. 83. Khan, A., Ginsberg, L.D., Asnis, G.M. et al. (2004) Effect of lamotrigine on cognitive complaints in patients with bipolar I disorder. J. Clin. Psychiat., 65, 1483–1490. 84. Reinares, M., Martinez-Aran, A., Colom, F. et al. (2000) Longterm effects of the treatment with risperidone versus conventional neuroleptics on the neuropsychological performance of euthymic bipolar patients. Actas Espanolas De Psiquiatria, 28, 231–238. 85. Young, A.H., Gallagher, P., Watson, S. et al. (2004) Improvements in neurocognitive function and mood following adjunctive treatment with mifepristone (RU-486) in bipolar disorder. Neuropsychopharmacology, 29, 1538–1545.
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The Genius-Insanity Debate: Focus on Bipolarity, Temperament, Creativity and Leadership Hagop S. Akiskal1,2,3 and Kareen K. Akiskal3 1
University of California at San Diego, San Diego, CA, USA San Diego Veterans Administration Medical Center (UCA), USA 3 International Mood Center, La Jolla, CA, USA 2
Why is it that all those who have become eminent in philosophy or politics or poetry or the arts are clearly melancholics and some of them to such an extent as to be affected by diseases caused by black bile?. . . Aristotle (Problema XXX)
A great deal of new data [1–8] and several major monographs [9–14] have been published during the first decade of this century alone, documenting the relationship between mental disorders and creative achievement. Can our field bear yet another review of this topic? Like the editors of this book, we feel a new synthesis of how this complex literature is shaping up is useful, but ultimately defer the question to the judgement of the reader.
History Since at least the time of the ancient Greeks, eminence in various professions – including artistic domains – has been linked to mental disorders [15]. Socrates thought that mental illness was a divine gift, and Plato linked creativity to the inspiration deriving from madness which, interestingly, he distinguished from clinical madness. Aristotle (in our opening quote), in a more nuanced statement, observed that eminence had something to do with the melancholic temperament, and in some instances to diseases arising from the black humour (whose exact nature still escapes us!). It is important to point out that melancholia in those days did refer to a broader group of illnesses than clinical depression in contemporary psychiatry. Beyond depressive withdrawal, the Problemata described mood instability, impulsivity, alcoholism and suicidality. In Roman times, Seneca went one step further and posited that no great mind is immune from a little insanity [16].
Bipolar Disorder: Clinical and Neurobiological Foundations Edited by Lakshmi N. Yatham and Mario Maj © 2010 John Wiley & Sons, Ltd. ISBN: 978-0-470-72198-8
The foregoing concepts are reflected in more modern times in the genius-insanity thesis put forward by Cesare Lombroso [17]. According to his theory, genius and insanity had a common genetic ancestry. It is of interest that the pathology described was typified by passion, preoccupation with glory, as well as inspiration and energy followed by exhaustion. There have been data-based investigations of the nature of insanity of creative individuals in contemporary psychiatry, which will be reviewed throughout this chapter. Before doing so, it is relevant to point out that there have always been sceptics about such a relationship.
Methodologic issues Eliot Slater [18], the famed British psychiatrist, based in part on Adele Judas research on geniuses of German music, art, literature and science [19], observed that in this group, psychotic disorders overall were only slightly greater than would have been expected from a sample of ordinary men. Weisberg wrote a monograph in which the genius is considered a myth [20]. Pathography, the discipline that relates creative output to life experiences, typically those with negative valence, tends to focus on selected individuals. For instance, a book advancing the notion of creative malady [21] examined the lives of Charles Darwin, Florence Nightingale, Mary Baker Eddy, Sigmund Freud, Marcel Proust and Elizabeth Barrett Browning. On the other hand, Dean Simonton, the dean of scientific research on eminence, who investigated all major historical figures [22] and scientists [23], found common positive strengths in the psychologic make-up of his more representative sample. Finally, Don Goodwin narrowly focused on a cohort of American literary figures awarded Nobel Prizes, most of whom had extensive histories of alcoholism [24]. Charlotte Waddell, a Canadian psychiatrist, observed that there was limited scientific evidence to associate creativity with mental illness [25]. Paul Wolff, a California pathologist, went even further to suggest that if clinical 83
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chemistry had existed then. . . the mental illnesses of various historical figures in art, music and political life could have been instead diagnosed with well-known physical illnesses [26]. We would add to these critiques the methodologic point that there may well be a selective bias in biographical and media reports towards those eminent individuals who were mentally ill and confirmed the popular notion that suffering is needed for artistic creativity; the healthy artist [27] appears to have been neglected and perhaps even attained less notoriety. Although biographical studies of well-known individuals are not necessarily the most unbiased forms of information, they have been a favourite source for scholarly work [21,24,28]. The landmark development in this field that lent historic credibility to all genres of inquiries on creativity is Sir Francis Galtons Hereditary Genius [29]. A more contemporaneous work by Runyan [30] has focused on four biographies – those of Abraham Lincoln, Sigmund Freud, Vincent Van Gogh and Virginia Wolf – to illustrate how objective, verifiable information can be gathered from existing records. This monograph also provides useful methodologic insights in the examination of narratives of the lives of Jesus of Nazareth, Samuel Johnson, Benjamin Franklin, King George III of England, Daniel Paul Schreber and Malcolm X.
Is psychosis relevant to creative genius? This question is not central to our main theme on bipolarity and creativity. However, given that the role of psychosis and schizophrenia [17,31,32] has long dominated the literature on creativity, a brief discussion of it is therefore a necessary background to our theme. The first question one needs to ask is how psychosis, creativity and eminence should be defined? The question already indicates the broad nature of the inquiries undertaken historically and contemporaneously, and the relative lack of precision that has muddled some of the early studies. More often than not, psychosis and madness have not been further characterized or else relegated to the domain of schizophrenia. As far as subjects studied, it has ranged from individuals known to be mentally ill, well-known artists in the community, professionals in high national office, to students enrolled in various colleges and universities. More sophisticated and imaginative developments have evolved recently. Psychologists have explored whether psychosis identifies eminent individuals or constitutes their familial background. This brings up the interesting possibility that certain familial traits, rather than the fullblown psychosis, might be what are involved in eminence and creativity. A variant of this perspective is that the eminent individual might suffer serious bouts of disease, but
produces his or her most distinguished work in periods free from major illness, during which they would presumably be exhibiting the desired trait of the condition. In an important methodologic advance, the Chapmans [33–34] and others [35] have operationalized the latter trait and developed instruments to test it. In doing so, they have based themselves on Meehls concept of schizotypy [36]. To summarize a complex literature on creativity and psychosis, suffice it to mention the following considerations and substantive advances: 1 The similarity of primary process thinking of the schizophrenic and the free associations exhibited by artistic expressions [31]. However, Andreasen and Powers [37] have shown that such a conceptual style is more characteristic of mania than schizophrenia. 2 Janusian thinking [38,39], operationalized as the psychotic patients and creative individuals receptivity to a broad range of stimuli, which makes it possible for them to simultaneously consider mutually exclusive and contradictory ideas. 3 It has been proposed that psychedelic experiences [40,41] too can enhance a richness of perceptual experiences and associations. 4 Although schizotypy has been recently linked to visual and related artistic expressions [5], the gift most clearly familially linked to psychosis and schizophrenia is mathematics and related academic pursuits [2]. 5 The autistic spectrum [11], though distinct from schizotypy, must also be mentioned in this context, because it appears relevant to creativity in mathematical philosophy, related computer sciences and beyond. Such observations have led to the hypothesis that relatives of schizophrenic patients have a creative edge [32] which might account for their mating success [42].
Affective temperaments and achievement We return to Aristotle, who wondered whether creative eminence derived from temperament and its excesses [15]. In modern parlance, he appears to have placed the query on exceptional greatness within the dimensional space between temperament and affective disease (see Figure 1) as conceptualized by Kretschmer [43]. This conceptualization tends to address the paradox, posed by Heidi Northwood [44] on how the Greek ideal of the golden mean (i.e. a temperament) – which predisposes to a diseased pathological state (i.e. melancholia) – can be juxtaposed. This is indeed the philosophical virtue embodied in the concept of the bipolar spectrum, which extends from normative temperament to bipolar psychosis [45]. Genetically, the assumption is one of oligogenic inheritance leading to overlapping phenotypes separated by degrees of severity [47]. This concept is schematically shown in Figure 1.
Temperament
Population frequency
The Genius-Insanity Debate
Bipolar
Genetic loading Fig. 1 Temperament and bipolar disease in a spectrum concept.
In a sample of 750 affectively ill patients, even with a liberal definition of creative output, such output was largely limited to 8% of those with bipolar II and III [48]; the corresponding rate in bipolar and schizoaffective psychoses was <0.5. Investigations on eminence in the United States [49] and France [50] have shown that professional success is significantly higher in the clinically well relatives compared to bipolar probands: the same finding holds up for creativity which appears mediated in the main by the cyclothymic temperament [3,13,48]. Although creative samples have a significant excess of bipolarity (see review in [51]), with the exception of Jamisons sample [52–54], full-blown manic-depressive illness is relatively uncommon. Such data are compatible with our hypothesis that it is the dilute temperamental form of bipolarity that subserves eminence and creativity. Our collaborative study in Milan [3] has supported the role of cyclothymia in artistic creativity and of hyperthymic temperamental traits in eminence. The fact that obsessive-compulsive traits in the Milan study had a moderating influence on these traits suggests that creativity and temperament and eminence are related in a complex fashion. A perusal of the traits constituting the cyclothymic and hyperthymic temperaments is relevant to their achievements, respectively, in artistic and leadership domains: The cyclothymic Temperament [54]: labile with rapid shifts in mood, unstable in energy, self-esteem and socialization, unevenly gifted and dilettante, yet keen in perception, intense in emotions and romantic. The hyperthymic Temperament [54]: outgoing, upbeat, fun-loving, sexually driven, jocular, optimistic, confident, full of ideas, eloquent, on the go, short-sleeper, tireless, likes to be the boss, single-minded, risk-taker, and unlikely to admit to his/her meddlesome nature. Traits reported by Feist [55] – openness to experience, unconventional, self-confidence, driven, ambitious, dominant and impulsive – in meta-analytic studies of creative scientists and artists are compatible with subthreshold bipolarity, that is the traits of the cyclothymic and hyperthymic individuals listed above. Feists work, in turn, derives from the conceptual framework and landmark research by Dredvhal and Cattell [56], Barron [57] and Mackinnon [58].
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Schizotypy, in our view, to the extent it involves trait deficits in experiencing pleasure, is expected to be negatively correlated with creative output [59]. We respectfully submit that the penchant for unusual experiences in the spectrum of measures related to positive schizotypy reported amongst artists might in part reflect traits shared and/or captured by cyclothymia. We have elsewhere documented the excesses so characteristic of cyclothymic individuals in their personal, social and occupational life [60], as well as their evolutionary advantages in mating, including multiple marriages, and especially hypergamy (marrying above their social class). In blues musicians and Parisian painters and writers, our data to date published only in part [61], do suggest that creativity and eminence are associated, respectively, with the cyclothymic and hyperthymic temperaments rather than full-blown manic depressive illness per se. Ruth Richards research group [62] at Harvard has also shown the crucial role of cyclothymia in creativity. The foregoing findings and considerations are further borne out by new research from Stanford [4,6,7]. They are also compatible with earlier findings from the Iowa writers workshop by Andreasen and colleagues [63,64] – where cyclothymia and bipolar II were more prevalent than bipolar I – and Kretschmers classical treatise on the Psychology of Men of Genius [65]. In terms of how temperament enhances the creative process, we would submit it may involve both the biographic ups and downs of the cyclothymic, the energy and confidence of the hyperthymic, as well as the cognitive and perceptual changes of cyclothymia and mixity. It is wellknown that the melancholic and cyclothymic temperaments belong to the same factorial structure [66]. It is finally relevant in this context to also cite Stanghellini [67], who reported some degree of overlap between the melancholic and hyperthymic temperaments. This paradox might be understood if one considers the work-orientation of melancholic individuals between affective episodes and the habitual high energy of the hyperthymic [68].
Toward a synthesis Aristotles Problemata XXX, may have laid the foundations for much of subsequent research on creativity, achievement and eminence. As a footnote to his insight, we submit that the reason why creativity and professional eminence are associated with melancholia may arise from the fact that cyclothymic and hyperthymic temperaments constitute the foundations of melancholia [66], and the melancholia Aristotle is referring to is possibly bipolar II, or some territory in between. It is individuals with such temperaments who are possessed by intense passion and cognitive abilities for novelty and are willing to risk journeys into new realms, whether
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that be in philosophy, aesthetics, letters, science, politics or leadership in various professional domains [3]. Pies [69] provides a compelling description of Aristotles vacillation between melancholia and frenzy and, interestingly, suggests that in the passage attributed to him, the Stagirian implied that those who excel in the arts may be blessed by . . . a humoral. . .effect. . . not too hot . . . not too cold, but just right (eukraton). Such a balanced mental state implicates bipolar temperament, a condition close to health rather than the disease, in the creative process. We have elsewhere [51] suggested that artists may well be considered healthier than normal individuals. Healthier in this context refers to a value system, whereby being eminent and creative is the ultimate mental state, which trumps the conventional notion of health as average or stable. Creativity and eminence by their very nature are exceptional and beyond the statistical definition of normality – they are outliers [14]. Temperaments by their very nature occupy the terrain between normality and disease. Creativity and leadership are related, but distinct aspects of eminence, a relationship which is in need of new research vistas. Emerging data-based investigations suggest that creativity and eminence and leadership in different professional domains are related to distinct optimal mixes of temperamental and cognitive profiles [1,3,4,6,7] including, but not limited to obsessive-compulsive traits, cyclothymia, sensation-seeking, novelty-seeking and openness to experience. We further submit that talent is a necessary ingredient. How all such factors and others interact with the unique biography of the artist is one of the most fascinating, multidimensional challenges in bridging modern neurobiology and art. The interaction of these diverse factors with unique biography is perhaps where the mystery of genius lies, appearing unpredictably in time and locale. The fact that Termans IQ children grown up [70] do not necessarily turn out to be creative, suggests that high intelligence is not one or the necessary ingredients of creative achievement. In collaborating with clinical scientists and epidemiologists from many countries to validate the concept of affective temperaments [66], our instrument, the Temperament Evaluation of Memphis, Pisa, Paris and San Diego (TEMPS). has been translated into at least 25 languages, and validated in 12. One of the most provocative findings pertains to the hyperthymic, which we consider the temperament of leadership [48,71]. For instance, in Italy [72], Lebanon [73] and Argentina [74], the hyperthymic is largely situated within the first and the second standard deviation. Such data imply that at least in those specific cultures (i.e. Mediterranean or having their origins there), the hyperthymic is considered a highly desirable super-normal trait. It may represent the most balanced of all temperaments; hence, given its energy, confidence, generosity and eloquence, the hyperthymic emerges as most suitable for leadership roles. Another instrument (the CEATS), conceptually in part derived from
TEMPS-A, has also shown that the hyperthymic is superadaptive, whereas the cyclothymic is more prone to emotional instability [75]. Overall, this literature tends to indicate that leadership and creativity are relatively distinct domains of eminence. The question of melancholia and intellectual and/or artistic eminence which has so preoccupied Western thought and art history may hinge on mixity [76], the coexistence of hypomanic elements in melancholia, which itself derives from the intrusion into or intersection of cyclothymia and hyperthymia with melancholia. This is, properly speaking, the domain of the bipolar spectrum. The co-existence of opposite emotional poles, while agonizing, might simultaneously provide access to negative affect, which could yield benefits with respect to providing energy for creative achievement [77,78], while at the same time perturb their interpersonal relationships and love life, so typical of the biography of artists. The price of greatness [28] is costly, but seems to reside in the subpsychotic interface of bipolar temperaments and affective disease, what geneticists call balanced polymorphism, whereby the condition remains prevalent, despite selection pressures against it. Thus, full-blown manicdepressive illness, rather than representing what is exceptional in human beings, appears to serve as the genetic reservoir of greatness [51].
Implications for clinical practice Consistent with our reading of the literature and our own work, temperament is intimately involved in creativity, achievement and eminence. There appears, in the current literature, greater recognition of affective [13,52,79,80], especially bipolar, traits in creativity. Jamisons classic treatise [81] has had a major influence worldwide in the shift of the creativity literature from schizophrenia to bipolar disorder. This monumental work, apart from its intellectual interest, has helped in destigmatizing manic-depressive illness. Instability of mood has long been recognized as a risk amongst creative and eminent individuals [82], but only recently have we had scientifically credible studies in its support. Clinicians must note these new developments. That lithium, the most established mood-stabilizer, is not acceptable to a substantial subgroup of artists [83] represents a clinical challenge for the psychiatrist. The fact that periods of acute mental illness are generally incompatible with creative output [84], emphasizes the need for acute and preventive interventions for artists and prominent individuals. Tragedies have occurred, such as Ernest Hemingway leaving the hospital against medical advice, and shooting himself to death, are not rare events. Caring for the mental health needs of artists and eminent individuals – handling their special psychology – is a challenging clinical endeavour
The Genius-Insanity Debate
for which, to the best of our knowledge, there has never been systematic training and preparation. It is also relevant to raise a more generic, albeit rhetorical, question: Why should practising psychiatrists be interested in the relationship of creativity and mental disorder? The subject should prove to be intellectually stimulating to the clinician, and as for the patient, it helps in opening up channels of emotional expression otherwise unavailable. We summarize from a paper by Perldringer and Krambeck [85], who have expressed this process as follows: (1) permission to create without constraint is a liberating experience; (2) discovering ones hidden talents; (3) feedback by peers about ones artistic expressions serves as a form of group therapy; (4) creation of art boosts ones self-esteem and mood; and (5) Training of the generally underdeveloped nondominant hemisphere in order to be able in the future to plan and act emotionally and from a synthetic view. Given our focus on eminent individuals in this chapter, the most serious therapeutic challenge in caring for such individuals is to give in to their sense of entitlement and either omit or permit a course of treatment one would not have considered for more ordinary patients. This certainly is a therapeutic domain in need of creative approaches. Whether the temperament factors given the greater space in this chapter – which are in line with literary trends [86] – or neurobiologic considerations [87] – will ultimately illuminate the mystery of creativity is a matter of scientific progress. Since in being creative man partakes in one of the most essential attributes of God, we may never know the answer to this question.
8.
9. 10. 11. 12. 13. 14. 15.
16.
17. 18.
19.
20. 21.
References 1. Wills, G.I. (2003) Forty lives in the bebop business: mental health in a group of eminent jazz musicians. Br. J. Psychiatry, 183, 255–259. 2. Karlsson, J.L. (2004) Psychosis and academic performance. Br. J. Psychiatry, 184, 327–329. 3. Akiskal, K.K., Savino, M. and Akiskal, H.S. (2005) Temperament profiles in physicians, lawyers, managers, industrialists, architects, journalists, and artists: a study in psychiatric outpatients. J. Affect. Disord., 85, 201–206. 4. Nowakowska, C., Strong, C.M., Santosa, C.M. et al. (2005) Temperamental commonalities and differences in euthymic mood disorder patients, creative controls, and healthy controls. J. Affect. Disord., 85, 207–215. 5. Burch, G.St.J., Pavelis, C., Hemsley, D.R. and Corr, P.J. (2006) Schizotypy and creativity in visual artists. Br. Psychol. Soc., 97, 177–190. 6. Santosa, C.M., Strong, C.M., Nowakowska, C. et al. (2007) Enhanced creativity in bipolar disorder patients: A controlled study. J. Affect. Disord., 100, 31–39. 7. Strong, C., Nowakowska, C., Santosa, C.M. et al. (2007) Temperament-creativity relationships in mood disorder
22. 23. 24. 25. 26. 27.
28.
29. 30.
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patients, healthy controls, and highly creative individuals. J. Affect. Disord., 100, 41–48. Gibson, C., Folley, B.S. and Park, S. (2009) Enhanced divergent thinking and creativity in musicians: A behavioral and near-infrared spectroscopy study. Brain Cogn. 69, 162–9 Nettle, D. (2001) Strong Imagination: Madness, Creativity and Human Nature, Oxford University Press, Oxford. Bloom, H. (2003) Genius: A Mosaic of One Hundred Exemplary Creative Minds, Grand Central Publishing, New York. Fitzgerald, M. (2004) Autism and Creativity, BrunnerRoutledge, New York. Stough, C. (ed.) (2005) Neurobiology of Exceptionality, Kluwer Academic/Plenum Publishers, New York. Andreasen, N.C. (2006) The Creative Brain: The Science of Genius, Penguin Group, New York, USA. Gladwell, M. (2008) Outliers: The Story of Success, Little, Brown and Co., New York. Klibansky, R., Panofsky, E. and Saxo, F. (1979) Saturn and Melancholia: Studies in the History of Natural Philosophy, Religion, and Art, Kraus Reprint, Nendeln/Lichtenstein. Wittkower, R. and Wittkower, M. (1963) Born under Saturn: The Character and Conduct of Artists, WW Norton & Co., New York. Lombroso, C. (1894) Genio e Follia, Bocca, Torino, Italy. Slater, E. (1979) The creative personality, in Psychiatry, Genetics and Pathography: A tribute to Eliot Slater (eds M. Rothand V. Cowie), Gaskell Press, London, pp. 89–103. Juda, A. (1949) The relationship between highest mental capacity and psychic abnormalities. Am. J. Psychiatry, 106, 296–307. Weisberg, R. (1986) Creativity: Genius and Other Myths, W.H. Freeman and Company, New York. Pickering, G.W. (1974) Creative Malady: Illness in the Lives and Minds of Charles Darwin, Florence Nightingale, Mary Baker Eddy, Sigmund Freud, Marcel Proust, and Elizabeth Barrett Browning, Oxford University Press, Oxford. Simonton, D.K. (1994) Greatness: Who Makes History and Why, Guilford Press, New York. Simonton, D.K. (1988) Scientific Genius: A Psychology of Science, Cambridge University Press, Cambridge. Goodwin, D.W. (1990) Alcohol and the Writer, Penguin Group, New York, USA. Waddell, C. (1988) Creativity and mental illness: Is there a link? Can. J. Psychiatry, 43, 166–172. Wolf, P.L. (1994) If clinical chemistry had existed then. . .. Clin. Chem., 40, 328–335. Andreasen, N.C. (1981) Suffering and art: A defense of sanity, in The Healing Arts (ed. J. Trautman), University of Southern Illinois Press, Springfield, Ill. Ludwig, A.M. (1995) The Price of Greatness: Resolving the Creativity and Madness Controversy, Guilford Press, New York. Galton, F. (1869) Hereditary Genius – An Inquiry into Its Laws and Consequences, Macmillan and Co., London. Runyan, W.M. (1984) Life Histories and Psychobiography: Explorations in Theory and Method, Oxford University Press, New York.
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31. Arieti, S. (1979) From schizophrenia to creativity. Am. J. Psychotherapy, 33, 490–505. 32. Karlsson, J.L. (1966) The Biologic Basis of Schizophrenia, Charles C. Thomas, Springfield, Ill. 33. Chapman, L.J., Chapman, J.P. and Raulin, M.L. (1976) Scales for physical and social anhedonia. J. Abnorm. Psychol., 87, 374–382. 34. Chapman, L.J., Edell, W.W. and Chapman, J.P. (1980) Physical anhedonia, perceptual aberration, and psychosis proneness. Schizophr. Bull., 6, 639–656. 35. Mason, O., Claridge, G. and Jackson, M. (1995) New scales for the assessment of schizotypy. Person. Individ. Diff., 18, 7–13. 36. Meehl, P.E. (1962) Schizotaxia, schizotypy, schizophrenia. Am. Psychol., 17, 827–838. 37. Andreasen, N.J.C. and Powers, P. (1975) Creativity and psychosis: an examination of conceptual style. Arch. Gen. Psychiatry, 32, 70–73. 38. Rothenberg, A. (1971) The process of janusian thinking in creativity. Arch. Gen. Psychiatry, 24, 195–205. 39. Rothenberg, A. (1983) Psychopathology and creative cognition. A comparison of hospitalized patients, Nobel laureates, and controls. Arch. Gen. Psychiatry, 40, 937–942. 40. Sessa, B. (2008) Is it time to revisit the role of psychedelic drugs in enhancing human creativity? J. Psychopharmacol., 22, 821–827. 41. Ward, J., Thompson-Lake, D., Ely, R. et al. (2008) Synaesthesia, creativity and art: What is the link? Br. J. Psychol., 99, 127–141. 42. Nettle, D. and Clegg, H. (2006) Schizotypy, creativity and mating success in humans. Proc. R. Soc. B., 273, 611–615. 43. Kretschmer, E. (1936 trans.) Physique and Character; an Investigation of the Nature of Constitution and of the Theory of Temperament, Kegan, Paul, Trench, Trubner and Co. Ltd, London. 44. Northwood, H.(May 1998) The Melancholic Mean: the Aristotelian Problema XXX. 1. Paper presented at World Congress of Philosophy, Boston, MASS. 45. Akiskal, H.S. (2003) Validating “hard” and “soft” phenotypes within the bipolar spectrum: continuity or discontinuity? J. Affect. Disord., 73, 1–5. 46. Akiskal, H.S. (2004) De la Folie circulaire ( a double forme) au spectre bipolaire: la tendance chronique a la recidive depressive. [From circular insanity (in double form) to the bipolar spectrum: chronic tendency for depressive recurrence]. Bull. Acad. Natl. Med., 88, 285–296. 47. Kelsoe, J.R. (2003) Arguments for the genetic basis of the bipolar spectrum. J. Affect. Disord., 73, 183–197. 48. Akiskal, H.S. and Akiskal, K. (1988) Re-assessing the prevalence of bipolar disorders: Clinical significance and artistic creativity. Psychiatrie et Psychobiologie (European Psychiatry), 3, 29s–36s. 49. Coryell, W., Endicott, J., Keller, M., et al. (1989) Bipolar affective disorder and high achievement: a familial association. Am. J. Psychiatry, 146, 983–988. 50. Verdoux, H. and Bourgeois, M. (1959) Comparative study on the occupational levels of unipolar and bipolar probands and relatives. Ann. Med. Psychol., 153, 67–70.
51. Akiskal, H. and Akiskal, K. (2007) In search of Aristotle: Temperament, human nature, melancholia, creativity and eminence. J. Affect. Disorders, 100, 1–6. 52. Jamison, K.R. (1989) Mood disorders and patterns of creativity in British writers and artists. Psychiatry, 2, 125–133. 53. Jamison, K.R. (1995) Manic depressive illness and creativity. Sci. Am., 272, 62–67. 54. Akiskal, H.S., Akiskal, K., Allilaire, J.F. et al. (2005) Validating affective temperaments in their subaffective and socially positive attributes: Psychometric, clinical and familial data from the French national study. J. Affect. Disord., 85, 29–36. 55. Feist, G.J. (1988) A meta-analysis of personality in scientific and artistic creativity. Pers. Soc. Psychol. Rev., 2, 290–309. 56. Drevdahl, J.E. and Cattell, R.B. (1958) Personality and creativity in artists and writers. J. Clin. Psychol., 14, 107–111. 57. Barron, F.A. (1972) Artists in the Making, Seminar Press, New York. 58. Mackinnon, D.W. (1965) Personality and the realization of creative potential. Am. Psychol., 20, 273–281. 59. Schuldberg, D. (1990) Schizotypal and hypomanic traits, creativity, and psychological health. Creativity Res. J., 3, 218–230. 60. Akiskal, H.S., Khani, M.K. and Scott-Strauss, A. (1979) Cyclothymic temperamental disorders. Psychiatr Clin. North Am., 2, 527–554. 61. Akiskal, H.S. and Akiskal, K. (1994) Temperaments et Humeur des Musiciens de Blues. Nervure, 8, 28–304. 62. Richards, R., Kinney, D.K., Lunde, I. et al. (1988) Creativity in manic-depressives, cyclothymes, their normal relatives, and control subjects. J. Abnorm. Psychology, 97, 281–288. 63. Andreasen, N. and Canter, A. (1974) The creative writer: psychiatric symptoms and family history. Compr. Psychiatry, 15, 123–131. 64. Andreasen, N. and Glick, I.D. (1988) Bipolar affective disorder and creativity: implications and clinical management. Compr. Psychiatry, 29, 207–217. 65. Kretschmer, E.(trans 1931) Psychology of Men of Genius, Kegal Paul, Trench, Trubner & Co., London. 66. Akiskal, H.S. and Akiskal, K.K.(eds) (2005) TEMPS: Temperament Evaluation of Memphis, Pisa, Paris and San Diego. J Affect Disord, Special Issue. 85, 1–242. 67. Stanghellini, G. (2007) Exploring the margins of the bipolar spectrum: Temperamental features of the typus melancholicus. J. Affect. Disord., 100, 13–21. 68. Akiskal, H.S. and Akiskal, K. (1992) Cyclothymic, hyperthymic and depressive temperaments as subaffective variants of mood disorders, in Annual Review, vol. 11 (eds A. Tasmanand M.B. Riba), American Psychiatric Press, Washington, DC, pp. 43–62. 69. Pies, R. (2007) The historical roots of the “bipolar spectrum”: did Aristotle anticipate Kraepelins broad concept of manicdepression? J. Affect. Disord., 100, 7–11. 70. Terman, L.W. (1920–59) Genetic Studies of Genius, vol. 6, Stanford University Press, Stanford. 71. Akiskal, K.K. and Akiskal, H.S. (2005) The theoretical underpinnings of affective temperaments: implications for evolutionary foundations of bipolarity and human nature. J. Affect. Disord., 85, 231–239.
The Genius-Insanity Debate 72. Placidi, G.F., Signoretta, S., Liguori, A. et al. (1998) The SemiStructured Affective Temperament Interview (TEMPS-I): Reliability and psychometric properties in 1010 14–26 year students. J. Affect. Disord., 47, 1–10. 73. Karam, E.G., Mneimneh, Z., Salamoun, M. et al. (2005) Psychometric properties of the Lebanese-Arabic TEMPS-A: a national epidemiologic study. J. Affect. Disord., 87, 169–183. 74. Vazquez, G., Nasetta, S., Mercado, B. et al. (2008) Validation of the TEMPS-A Buenos Aires: Spanish psychometric validation of affective temperaments in a population study of Argentina. J. Affect. Disord., 108, 25–32. 75. Lara, D., Lorenzi, T.M., Borba, D.L. et al. (2008) Development and validation of the combined emotional and affective temperament scale (CEATS): towards a brief self-rated instrument. J. Affect. Disord., 111, 320–333. 76. Akiskal, H.S. and Akiskal, K.K. (2007) A mixed state core for melancholia: an exploration in history, art and clinical science. Acta Psychiatr. Scand., 115, s44–s49. 77. Simeonova, D.I., Chang, K.D., Strong, C. et al. (2005) Creativity in familial bipolar disorder. J. Psychiatr. Res., 39, 623–631.
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78. Akinola, M. and Mendes, W.B. (2008) The Dark side of creativity: biological vulnerability and negative emotions lead to greater artistic creativity. Pers. Soc. Psychol. Bull., 34, 1677–1680. 79. Janka, Z. (2004) Muveszi kreativitas es bipolaris kedelyzavar. Evforyam, 145, 1709–1718. 80. Rihmer, Z., Gonda, X. and Rihmer, A. (2006) Creativity and mental illness. Psychatr. Hung., 21, 288–290. 81. Jamison, K. (1993) Touched with Fire, Free Press, New York. 82. Post, F. (1994) Creativity of psychopathology: A study of 291 world-famous men. Br. J. Psychiatry, 165, 22–34. 83. Schou, M. (1979) Artistic productivity and lithium prophylaxis in manic-depressive illness. Br. J. Psychiatry, 135, 97–103. 84. Herbert, P.S. (1959) Creativity and mental illness. Psychiatr. Quart., 33, 534–547. 85. Poeldinger, W. and Krambeck, K. (1987) The relevance of creativity for psychiatric therapy and rehabilitation. Compr. Psychiatry, 28, 384–388. 86. Steptoe, A.(ed.) (1998) Genius and the Mind: Studies of Creativity and Temperament, Oxford University Press, Oxford. 87. Zeki, S. (1999) Inner Vision: An Exploration of Art and the Brain, Oxford University Press, Oxford.
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Economics of Bipolar Disorder R. Sabes-Figuera1, D. Razzouk2 and Paul E. McCrone1 1
Centre for the Economics of Mental Health, Health Service and Population Research Department, Institute of Psychiatry, Kings College, London, UK 2 Department of Psychiatry, Universidade Federal de Sao Paulo (UNIFESP), Sao Paulo, Brazil
Introduction Bipolar disorder (BD) is the fifth leading cause of disability in young people, and amongst mental disorders is the fourth highest cause of burden [1]. Patients with BD may delay seeking treatment, and 30–70% of patients do not access treatment [2]. The lack or delay of treatment for BD contributes to the economic and social burden; as the disorder progresses the response to treatment decreases and increases the impairment in patients global functioning. Patients with BD are more likely to have higher rates of health service use (including hospitalization) and comorbidity with physical diseases, as well as increased suicide attempts, absenteeism and unemployment, substance misuse, sexual risk behaviour and social dysfunction [3–10]. The aims of this chapter are: (1) to examine the economic impact of BD; and (2) to assess the evidence surrounding the cost-effectiveness and cost-utility of different interventions to treat BD.
Economic cost of bipolar disorder Methodological considerations Cost of illness (COI) studies do not determine how decision makers should choose between treatments and interventions, as such studies are not evaluative [11]. Nevertheless, they do provide useful information on the economic burden that the disease imposes on a society. This information can highlight processes of care and aspects of the disease where improvements and more research are needed. COI studies should consider all costs that fall on individuals and organizations. These costs can be divided into: (1) direct costs, which are those that arise from treating the disease and its consequences; and (2) indirect costs, which are those caused by reduced productivity or engagement in leisure activities.
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There are two basic approaches used in COI studies. The prevalence approach is used to assess the costs generated by the condition over a certain period of time, usually one year. Alternatively, the incidence approach can be used, in which the lifetime costs of new cases occurring within a year are calculated [12]. In addition, there are two main methods to obtain estimations of the costs. One possibility (top-down approach) is to assign a percentage of total health and other expenditures to the condition of interest. The second option (bottom-up approach) consists in evaluating the average use of services by individuals with the condition through surveys and/or medical records and extrapolating these data to the overall population affected by the condition. While there is not much disagreement about how to estimate the direct costs of care, there is much more debate as to the most appropriate way of estimating indirect costs, specifically unemployment and absenteeism. The human capital method uses the level of an individuals earnings to indicate the productivity losses caused by reduced work time. This has been criticized as it suggests greater productivity losses for those who earn more (and it is known that earnings inequalities arise for a variety of reasons). Furthermore, it may be that in the presence of unemployment someone who stops work is replaced by someone who was previously unemployed; any production loss would therefore be confined to the friction period during which recruitment takes place [13].
COI estimates One of the earliest studies was by Wyatt and Henter [14]. They established that in 1991 the cost of BD in the United States was $45 billion, based on estimations of utilization of health care and other services by BD patients. Most of the costs were indirect costs (83%), and around half of these were productivity losses of the workforce affected by the disease. The remaining indirect costs included lost productivity of homemakers, people in institutions and people who had committed suicide. Using a different approach, Begley et al. estimated the present value of lifetime societal costs of
Economics of Bipolar Disorder
persons with the onset of BD in the year 1998 in the United States [15]. They obtained data from expert opinion, employment surveys, published literature and health insurance claims and reported a lifetime cost per person of $252 212, with much variation according to severity ($11 220 for patients with single manic episodes and $624 785 for non-responsive chronic patients). The total cost for the country was estimated at $24 billion with 44% accounted for by indirect costs. Bryant-Comstock et al., analysing the same health insurance claims database used by Begley et al., compared the annual health care cost of BD patients with non-BD patients for the year 1997 [16]. This database included the health claims of 2.7 million privately insured patients. The study estimated an annual cost for the BD group of $7663 per patient, compared to $1962 for the comparator group. One limitation was that data from patients with only one episode were not included and therefore the costs may be overestimated. In a very different health care system, Das Gupta and Guest calculated the cost of BD in the United Kingdom in 1998 to be £2.1 billion [17]. Data were drawn from health care utilization databases, published data and expert opinion. As with the studies from the United States, indirect costs accounted for a substantial amount of the total (86%). Amongst the direct costs, the most costly elements were hospital admissions (35%) and community mental health care (27%). Given that they assumed a lifetime prevalence of BD of 0.5%, the estimation for the cost per person with BD was £6919 (I$10 455). In a recent study, McCrone et al. have made estimates of the cost of BD for England [18]. Attaching costs from secondary sources to prevalence estimates, they calculated total service costs in 2007 to be £1.6 billion. With the inclusion of lost employment costs the total rose to £5.2 billion. Another approach to conducting COI studies is to use survey data. From these it is possible to obtain information about the prevalence of the disease, the use of services and how the condition affects the work productivity of the individuals. In the Netherlands, Hakkart-van Roijen et al. identified participants from a national survey with a diagnosis of BD or unipolar major depressive disorder and re-interviewed them [19]. Forty individuals had a confirmed diagnosis of BD. Based on this relatively small number, the societal cost of was estimated to be D 1.9 billion for 2002. Based on a prevalence rate of 5.2%, the cost per person was D 4527. The results again revealed that indirect costs represent the most significant part of the overall costs (80%). The small sample of the study may have affected the validity of the results. For instance, there were no hospitalization costs included, because none of the respondents had reported an admission in the 4-week period before the interview.
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In a similar survey-based study in Australia, Fisher et al. reported an excess cost per person with BD of A$9878 in 2004, compared with people without BD [20]. Indirect costs represented 86% of the total cost, and the estimation of the total excess costs for the entire country based on these data was in the range of A$4.0–5.0 billion. Some costs were excluded, such as those for patients living in institutions or residential care settings. Furthermore, the authors did not find excess pharmaceutical drug costs for the BD group. The direct costs of health care borne by the government reported by this study, A$1325, can be compared with the figures provided by Sanderson et al. in their article on the costeffectiveness of specific interventions for affective disorders [21]. Analysing a large household survey of mental disorders, n ¼ 10 641, they reported a direct health care cost of A$1294 per treated case in the year 1998. A number of studies have focused just on the direct health care costs of BD. For example, Knoth et al. found that these costs in the first year after diagnosis were more than four times higher than the health care cost of the average member of the managed care plan analysed [22]. Elsewhere, Stensland et al. showed that health care costs associated with BD were $2908 higher than those for depression [23]. Other studies have focused on explaining these higher health care costs. Several studies have found that the misdiagnosis of BD, which delays appropriate treatment for these patients, increases health care costs. For instance, McCombs et al. analysed Medicaid data and found that costs increased by $91 for each month of delayed diagnosis [24]. Li et al. reported that only 5.5% of the patients in a Medicaid programme used a mood stabilizer consistently for one year [25]. The relationship between such suboptimal use of medication and higher costs was demonstrated in that study and others [26]. The influence of comorbid conditions on the health care costs of BD patients was highlighted by Guo et al., who showed that comorbidity accounted for 70% of the total cost of BD in another analysis of Medicaid data [27]. Amongst the studies that have estimated costs at the national level, only Wyatt and Henter and McCrone et al. have examined caregiver costs [14,18]. There is evidence that these carers report more physical and mental health problems, therefore increasing their own health service use [28]. Other studies have focused on the lost employment costs associated with BD. For example, Kleinman et al., in a study from the United States, found that there were on average 11.5 additional lost working days per year per employee with BD compared to those without this condition [29]. Furthermore, it has been reported by Goetzel et al. that of all mental health problems, BD generated the greatest loss of productivity to employers [30]. This review has identified a number of studies that have attempted to estimate the economic cost of BD in specific countries. The costs appear substantial in most countries.
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A common finding is that the indirect costs associated with lost employment are substantial. However, comparisons across, and even within, countries is problematic for a number of reasons. First, the total economic burden of BD clearly depends on which costs are included, the prevalence figures used and the methods that are used to estimate indirect costs. Second, different studies collect data from different sources and this can cause difficulties. For example, while those based on large administrative databases provide good information on health care costs for those in contact with services, they provide little information on those not in contact. An alternative is to use survey data. This should result in a more representative sample but the numbers tend to be low and therefore this may result in imprecise cost estimates. This is illustrated by some studies not including inpatient costs, because those included in the survey did not use this form of care. Third, quite different estimates will be produced, depending on whether topdown or bottom-up approaches are used. Each requires specific assumptions to be made.
Economic evaluations of interventions for bipolar disorder Cost of illness studies are informative but they do not tell us about the efficiency of different treatments for BD. For this, the cost of services needs to be combined with information on their outcomes. Various ways of doing this exist, with the two most common being cost-effectiveness analysis (CEA) and cost-utility analysis (CUA). In CEA, costs are linked to condition specific measures (e.g. scales to measure depression). This makes CEA clinically meaningful but does not allow interventions in one clinical area to be compared to those elsewhere. These decisions do though have to be made at a local or national level. CUA is similar to CEA but uses generic measures of outcome to enable such comparisons, with the most commonly used measure being the quality adjusted life year (QALY). With QALYs, the length of time spent in a particular health state is multiplied by a number anchored by 1 (full health) and 0 (death), to reflect the quality of life experienced during that time.
Economic evidence for the treatment of acute manic episodes Several economic studies have evaluated the cost-effectiveness of different drug treatments for acute manic or mixed episodes in BD patients. Most of these studies were sponsored by the pharmaceutical industry and analysed the efficiency of atypical antipsychotics in relation to conventional antipsychotics and/or mood-stabilizers. A number of studies have focused on the use of the drug olanzapine. In a pre-post study, Namjoshi et al. concluded that compared to the year prior to the treatment, olanzapine
resulted in improved quality of life and reduced costs for 76 patients [31]. However, given the lack of a control group, it is unclear whether these patients would have improved anyway, or whether their gains were any greater due to drug treatment. Elsewhere, Revicki et al. did use a double blind randomized design in their comparison of olanzapine with valproate [32]. Quality of life deteriorated for both groups over a short 12-week period. Costs for out-patient care were significantly higher for the olanzapine group, but this was due to the cost of medication itself. Overall health care costs were not significantly different, but this was largely because the sample all started off as inpatients and these costs dominated the others. Societal costs were not included. This study was limited by the small sample size, which was reduced further by the lack of follow-up data for many patients. In a similar study, Zhu et al. did not find significant differences in the medical costs between the same two pharmacological agents, while clinical outcomes were reported to favour olanzapine [33]. Revicki et al. compared the effectiveness and medical costs associated with valproate and lithium in a group of patients hospitalized for an acute manic or mixed episode [34]. The analysis was based on a pragmatic, multicentre open-label randomized controlled trial with a followup of 12 months. They did not find significant differences between the two treatments in terms of effectiveness nor medical costs. Klok et al. analysed the economic consequences of the use of the atypical antipsychotic quetiapine in monotherapy and in combination with lithium through a decision model [35]. The authors showed that the combination of quetiapine and lithium was more costly, but prevented more serious adverse events than other combinations of lithium with olanzapine or risperidone. As a part of a National Health Service Health Technology Assessment, Bridle et al. developed an economic model to evaluate different drug treatments for treating mania associated with BD [36]. The time horizon of the model was three weeks and the third-party payer (i.e. National Health Service) was the perspective adopted. They found that haloperidol, a conventional antipsychotic, was less costly and more effective than lithium, valproate and quetiapine. Olanzapine was more effective and more costly than haloperidol, with an incremental cost effectiveness ratio equal to £7179 per additional responder. The authors concluded that if decision makers were willing to pay this amount (or more) for each additional responder, then olanzapine would be the optimal decision. Otherwise treatment with haloperidol would be the optimal strategy. The authors acknowledged that the analysis had some limitations, including the use of secondary data, not evaluating combination therapies and not considering the costs and effects of adverse events. A study of electroconvulsive therapy (ECT) for treatment resistant BD in adolescents and young adults found that
Economics of Bipolar Disorder
outcomes were significantly better for those receiving ECT compared to those who declined it [37]. Hospital costs were less for the ECT patients due to a shorter length of stay. However, this was not a randomized comparison and the group willing to undergo ECT may have shown more improvement anyway. In addition, the sample size was very small.
Economic evidence for maintenance treatment in bipolar disorder Two different studies have analysed the economic implications of maintenance therapy with olanzapine compared to lithium treatment. In an industry-sponsored study, McKendrick et al. constructed a Markov model, relying on a single clinical trial for the effectiveness data, to assess the cost-effectiveness of these treatments from the perspective of the National Health Service in England and Wales [38]. The model showed that olanzapine prevented acute mood (manic) events with lower costs after 1 year, although this difference in costs was not statistically significant. In the United States, Zhang found opposite results in an retrospective analysis of private sector insurance claims data from health plans [39]. After controlling for other variables that could affect medical spending, it was found that compared to similar patients taking lithium, patients with BD taking olanzapine spent $5600 more each year on health care services. Calvert et al. also used a Markov model to assess the cost-effectiveness of lamotrigine treatment compared to olanzapine, lithium and no treatment in patients recently stabilized after resolution of a manic episode [40]. They populated the effectiveness part of the model with data from four clinical trials, and they adopted the perspective of the third-party payer. Lamotrigine was found to be less costly and more effective than olanzapine and no treatment. Compared with lithium, the incremental cost-effectiveness was $2400 per episode avoided, $30 per euthymic day gained, and $26 000 per QALY. These results were influenced by the low rate of depressive episodes in patients being treated with lamotrigine. In an economic evaluation alongside a clinical trial, Lam et al. evaluated the cost-effectiveness of adding cognitive therapy to standard care in the prevention of relapse in BD [41]. This study benefited from a follow-up period of 30 months. The group that received psychological treatment spent 110 fewer days with bipolar episodes and had lower health and care costs, although these differences were not statistically significant. Besides the small sample size, another limitation of the study was that the standard care group received any one of a range of pharmaceutical treatments and therefore it is not possible to compare the cost-effectiveness of therapy against any particular drug treatment.
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A economic decision model was developed as part of a clinical guideline process in the United Kingdom, using the results of a meta-analysis of RCTs to inform this model [42]. The treatments evaluated were lithium, valproate and olanzapine and these were compared to no treatment. The use of health care resources associated with the different health states of the Markov model, in the five-year period analysed, was based mainly on expert opinion. Using averted episodes as the outcome measure, the results showed that olanzapine was dominated (i.e. more expensive and less effective) by valproate, while the option of no treatment was dominated by both valproate and lithium. Valproate was more costly and more effective than lithium, with an incremental cost of £260 and £341 per additional averted episode for men and women, respectively. Nevertheless, when health benefits were measured in QALYs, the results were different, with olanzapine not being a dominated strategy. The incremental cost-effectiveness ratio (ICER) per QALY gained for valproate over lithium was £1725 for men and £1985 for women. The ICER per QALY gained for olanzapine over valproate was £5902 for men and women (for this population subgroup, after excluding valproate, the ICER per QALY gained for olanzapine over lithium was £4805). The assumptions regarding service use in this study created some uncertainty about the results. Furthermore, the contradictory results depending on the outcome measure used could be explained by the method to obtain the utility values as the basis for the QALYs. A similar decision analytic model was developed by Soares-Weiser et al. [43]. They included a more complete range of comparators (lithium, valproate, lamotrigine, carbamazepine, imipramine, olanzapine, and lithium plus imipramine) and the method to obtain clinical evidence was more refined. This Markov model estimated costs from the perspective of the UK National Health Service and health outcomes in terms of QALYs using a lifetime horizon. Two separate analyses were carried out, one for patients who had recently experienced a depressive episode and another for the ones who had suffered a manic episode. In the former, valproate was the cheapest, non-dominated alternative and lithium and the combination treatment of lithium plus imipramine were both more costly and more effective than valproate (the other alternatives were dominated). The results showed that the ICER of lithium compared with valproate was £10 409 per additional QALY. The ICER of the combination treatment compared with lithium monotherapy was £21 370 per additional QALY. In the analysis of the patients who had recently experienced a manic episode, olanzapine dominated all of the strategies with the exception of lithium monotherapy, this alternative being more costly and more effective. The ICER of lithium compared with olanzapine was estimated to be £11 359 per additional QALY.
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Economic evidence of multicomponent intervention care programmes Two different studies, both looking at interventions based in the United States, evaluated the cost-effectiveness of care programmes with multiple components that had the objective of improving quality of care and long-term outcomes for persons with BD. Simon et al. assessed outcomes and costs (with a follow-up period of two years) of a systematic care programmeprovidedbynursecaremanagers that comprised several interventions plus usual care (“a structured group psychoeducational programme,monthlytelephonemonitoring of mood symptoms and medication adherence, feedback to treating mentalhealth providers,facilitationofappropriate follow-up care, and as-needed outreach and crisis intervention”) [44]. The patients were recruited at mental health clinics of a group-model prepaid health plan. They were assigned randomly to the intervention group or to the usual care group. The clinical outcomes showed a positive effect of the intervention in the mean level of time with significant mania symptoms, with no significant effects on level of depression. After controlling for confounding variables, the incremental cost of the intervention was $1251. In a very similar study, Bauer et al. found similar clinical outcomes but in a highly ill, frequently hospitalized sample with a follow-up period of three years. In addition, the intervention group was less costly, although this difference was not significant [45].
Conclusions This chapter has demonstrated that the costs associated with BD are substantial. A disproportionate amount of the cost is due to lost employment and therefore interventions that can maintain people in the workplace would have potential economic benefits. A reasonable number of economic evaluations have now been conducted. These have generally been of pharmacological interventions and have shown mixed results. An increasing number of evaluations have used QALYs as outcome measures which is important if interventions for BD are to be compared to those in other health care areas. Future work needs to examine the impact of treatments on employment and more evaluations of psychological therapies are clearly required.
References 1. World Health Organization (WHO) (2001) The World Health Report 2001: Mental Health: New Understanding New Hope, World Health Organization, Geneva. 2. Kohn, R., Saxena, S., Levav, I. and Saraceno, B. (2004) The treatment gap in mental health care. Bulletin of the World Health Organization, 82, 858–866. 3. Woods, S.W. (2006) The economic burden of bipolar disease. J. Clin. Psychiat., 61 (suppl 113), 38–41.
4. Birnbaum, H.G., Shi, L., Dial, E. et al. (2003) Economic consequences of not recognizing bipolar disorder patient: A cross-sectional descriptive analysis. J. Clin. Psychiat., 64 1201–1209. 5. Calabrese, J.R., Hirschfeld, R.M., Reed, M. et al. (2003) Impact of a bipolar disorder on a US community sample. J. Clin. Psychiat., 64, 425–432. 6. Kilbourne, A.M., Cornelius, J.R., Han, X. et al. (2004) Burden of general medical conditions among individuals with bipolar disorder. Bipolar Disord., 6, 368–373. 7. Adling-Sobocki, P. and Wittchen, U. (2005) Cost of affective disorders in Europe. Eur. J. Neurology, 12 (suppl 1), 34–38. 8. Hirschfeld, R.M.A. and Vornik, L.A. (2005) Bipolar disorder – Costs and comorbidity. Am. J. Manag. Care, 11 (Suppl), S85–S90. 9. Matza, L.S., Rajagopalan, K.S., Thompson, C.L. and Lissovoy, G. (2005) Misdiagnosed patients with bipolar disorder: Comorbidities, treatment patterns and direct treatment costs. J. Clin. Psychiat., 66, 1432–1440. 10. Ranga, K. and Krishnan, R. (2005) Psychiatric and medical comorbidities of bipolar disorder. Psychosom. Med., 67, 1–8. 11. Drummond, M. (1992) Cost of illness studies: major headache? PharmacoEconomics, 2, 1–4. 12. Hartunian, N.S., Smart, C.N. and Thompson, M.S. (1981) The Incidence and Economic Costs of Major Health Impairments, Lexington Books. 13. Koopmanschap, M.A. and van Ineveld, B.M. (1992) Towards a new approach for estimating indirect costs of disease. Soc. Sci. Med.., 34, 1005–1010. 14. Wyatt, R.J. and Henter, I. (1995) An economic evaluation of manic-depressive illness. Soc. Psych. Psych. Epid., 30, 213–219. 15. Begley, C.E., Annegers, J.F., Swann, A.C. et al. (2001) The lifetime cost of bipolar disorder in the US: an estimate for new cases in 1998. Pharmacoeconomics, 19, 483–495. 16. Bryant-Comstock, L. et al. (2002) Health care utilization and costs among privately insured patients with bipolar I disorder. Bipolar Disord., 4, 398–405. 17. Das Gupta, R. and Guest, J.F. (2002) Annual cost of bipolar disorder to UK society. Brit. J. Psychiat., 180, 227–233. 18. McCrone, P., Dhanasiri, S., Patel, A. et al. (2008) Paying the Price, Kings Fund, London. 19. Hakkaart-van Roijen, L., Hoeijenbos, M.B., Releer, E.J. et al. (2004) The societal cost and quality of life of patients suffering from bipolar disorder in the Netherlands. Acta Psychiatr. Scand., 110, 383–392. 20. Fisher, L.J., Goldney, R.D., Dal Grande, E. et al. (2007) Bipolar disorders in Australia. A population-based study of excess costs. Soc. Psychiatry Psychiatr. Epidemiol., 42 (2), 105–109. 21. Sanderson, K., Andrews, G., Corry, J. and Lapsley, H. (2003) Reducing the burden of affective disorders: is evidencebased health care affordable? J. Affect. Disord., 77 (2), 109–125. 22. Knoth, R.L., Chen, K. and Tafesse, E. (2004) Datapoints: Costs associated with the treatment of patients with bipolar disorder in a managed care organization. Psychiatr. Serv., 55 (12), 1353. 23. Stensland, M.D., Jacobson, J.G. and Nyhuis, A. (2007) Service utilization and associated direct costs for bipolar disorder in
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24.
25.
26.
27.
28.
29.
30.
31.
32.
33.
34.
2004: an analysis in managed care. J. Affect. Disord., 101 (1–3), 187–193. McCombs, J.S., Ahn, J., Tencer, T. and Shi, L. (2007) The impact of unrecognized bipolar disorders among patients treated for depression with antidepressants in the fee-forservices California Medicaid (Medi-Cal) program: a 6-year retrospective analysis. J. Affect. Disord., 97 (1–3), 171–179. Li, J., McCombs, J.S. and Stimmel, G.L. (2002) Cost of treating bipolar disorder in the California Medicaid program. J. Affect. Disord., 7, 131–139. Harley, C., Li, H., Corey-Lisle, P. et al. (2007) Influence of medication choice and comorbid diabetes: The cost of bipolar disorder in a privately insured US population. Soc. Psychiatry Psychiatr. Epidemiol., 42 (9), 690–697. Guo, J.J., Keck, P.E., Li, H. and Patel, N.C. (2007) Treatment costs related to bipolar disorder and comorbid conditions among Medicaid patients with bipolar disorder. Psychiatr. Serv., 58 (8), 1073–1078. Perlick, D.A., Rosenheck, R.A., Miklowitz, D.J. et al. (2007) STEP-BD Family Experience Collaborative Study Group. Prevalence and correlates of burden among caregivers of patients with bipolar disorder enrolled in the Systematic Treatment Enhancement Program for Bipolar Disorder. Bipolar Disord., 9 (3), 262–273. Kleinman, N.L., Brook, R.A., Rajagopalan, K. et al. (2005) Lost time, absence costs, and reduced productivity output for employees with bipolar disorder. J. Occup. Environ. Med., 47 (11), 1117–1124. Goetzel, R.Z., Hawkins, K., Ozminkowski, R.J. and Wang, S. (2003) The health and productivity cost burden of the “top 10” physical and mental health conditions affecting six large U.S. employers in 1999. J. Occup. Environ. Med., 45 (1), 5–14. Namjoshi, M.A., Rajamannar, G., Jacobs, T. et al. (2002) Economic, clinical, and quality-of-life outcomes associated with olanzapine treatment in mania. Results from a randomized controlled trial. J. Affect. Disord., 69 (1–3), 109–118. Revicki, D.A., Paramore, L.C., Sommerville, K.W. et al. (2003) Divalproex sodium versus olanzapine in the treatment of acute mania in bipolar disorder: health-related quality of life and medical cost outcomes. J. Clin. Psychiatry, 64 (3), 288–294. Zhu, B., Tunis, S.L., Zhao, Z. et al. (2005) Service utilization and costs of olanzapine versus divalproex treatment for acute mania: results from a randomized, 47-week clinical trial. Curr. Med. Res. Opin., 21 (4), 555–564. Revicki, D.A., Hirschfeld, R.M., Ahearn, E.P. et al. (2005) Effectiveness and medical costs of divalproex versus lithium
35.
36.
37.
38.
39.
40.
41.
42.
43.
44.
45.
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95
in the treatment of bipolar disorder: results of a naturalistic clinical trial. J. Affect. Disord., 86 (2–3), 183–193. Klok, M.R., Al Hadithy, A.F., Van Schayk, N.P., et al. (2007) Pharmacoeconomics of quetiapine for the management of acute mania in bipolar I disorder. Expert Rev. Pharmacoecon. Outcomes Res., 7 (5), 459–467. Bridle, C., Palmer, S., Bagnall, A.M. et al. (2004) A rapid and systematic review and economic evaluation of the clinical and cost-effectiveness of newer drugs for treatment of mania associated with bipolar affective disorder. Health Technol. Assess., 8 (19), iii–187. Kutcher, S. and Robertson, H.A. (1995) Electroconvulsive therapy in treatment-resistant bipolar youth. J. Child Adol. Psychop., 5 (3), 167–175. McKendrick, J., Cerri, K.H., Lloyd, A. et al. (2007) Cost effectiveness of olanzapine in prevention of affective episodes in bipolar disorder in the United Kingdom. J. Psychopharmacol., 21 (6), 588–596. Zhang, Y. (2008) Cost-saving effects of olanzapine as longterm treatment for bipolar disorder. J. Ment. Health Policy Econ., 11 (3), 135–146. Calvert, N.W., Burch, S.P., Fu, A.Z. et al. (2006) The costeffectiveness of lamotrigine in the maintenance treatment of adults with bipolar I disorder. J. Manag. Care Pharm., 12 (4), 322–330. Lam, D.H., McCrone, P., Wright, K. and Kerr, N. (2005) Costeffectiveness of relapse-prevention cognitive therapy for bipolar disorder: 30-month study. Br. J. Psychiatry, 186 500–506. National Collaborating Centre for Mental Health (2006) Bipolar Disorder: The Management of Bipolar Disorder in Adults, Children and Adolescents, in Primary and Secondary Care, The British Psychological Society and Gaskell, London. Soares-Weiser, K., Bravo, V.Y., Beynon, S. et al. (2007) A systematic review and economic model of the clinical effectiveness and cost-effectiveness of interventions for preventing relapse in people with bipolar disorder. Health Technol. Assess., 11 (39), iii–206. Simon, G.E., Ludman, E.J., Bauer, M.S. et al. (2006) Long-term effectiveness and cost of a systematic care program for bipolar disorder. Arch. Gen. Psychiatry, 63 (5), 500–508. Bauer, M.S., McBride, L., Williford, W.O. et al. (2006) Collaborative care for bipolar disorder: Part II. Impact on clinical outcome, function, and costs. Psychiatr. Serv., 57 (7), 937–945.
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An Introduction to the Neurobiology of Bipolar Illness Onset, Recurrence and Progression Robert M. Post1 and Marcia Kauer-SantAnna2 1 2
George Washington University Medical School, Bipolar Collaborative Network, Bethesda, MD, USA Molecular Psychiatry Laboratory, Department of Psychiatry, Hospital de Clinicas de Porto Alegre, Universidade Federal do Rio Grande do Sul, Brazil
Introduction The neurobiology of bipolar illness is increasingly more precisely delineated and understood. Well-replicated findings have emerged in multiple areas of study, ranging from alterations in blood and cerebrospinal fluid to direct abnormalities in brain. These are seen by a variety of brain imaging techniques in patients, as well as in discrete biochemical and structural changes delineated in autopsy specimens of patients dying with a diagnosis of bipolar disorder compared with controls. Subsequent chapters in this volume will deal with many of these topics in great detail; instead, here, we wish to give a broad overview and delineate some of the many pathological mechanisms by which these changes might occur and evolve. Until recently, pathophysiological mechanisms have been viewed as largely dichotomous – residing in those related to genetic inheritance or environmental alterations. Instead, it is becoming increasingly clear that the development of the central nervous system (CNS) relies on an exquisite interplay between genetic and environmental factors and that this process continues throughout the lifetime of the individual. Thus, a fundamental question emerges as to how the pathophysiology of a complex psychiatric illness such as bipolar disorder not only may have its origins in genetic and environmental vulnerabilities, but how the illness course and its response to treatment may also depend on an intricate and ongoing interaction of these dual mechanisms. Normal processes of learning and memory and responses to environmental stressors involve short- and long-term changes in gene expression, some of which are mediated by changes in gene structure, but not gene sequence. DNA itself can be methylated and histones (around which the DNA is wrapped) can be acetylated or methylated. These
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epigenetic changes alter DNAs availability for transcription and provide new conceptual mechanisms for understanding lifelong alterations in neurobiology and behavioural responsivity based on environmental events. Recent findings also suggest that these epigenetic changes themselves may have considerable plasticity and may be amenable to alterations that could ultimately lead to new therapeutic approaches to illness vulnerability and progression. Bipolar illness is fundamentally a recurrent and potentially progressive illness requiring not only acute intervention for episodes but, in the vast majority of instances, long-term prophylactic measures to ward off manic and depressive episode recurrences. Considerable evidence suggests that episode recurrence itself may be a mediator of illness progression, further complicated by accumulating neurobiological alterations induced by stressors, substances of abuse and other environmental influences. This view leads to a fundamental reconceptualization of the illness, not only as a progressive neurobiological and somatic medical illness, but one which can be slowed or halted altogether if appropriate treatment intervention is instituted. Yet, disappointingly, all too often the illness is not recognized or well-treated in its earliest phases, and even after multiple severe episodes have occurred, appropriate long-term prophylaxis is not consistently given or accepted. Thus, it is a secondary hope that not only will this chapter help orientate the reader to subsequent, more detailed expositions of the neurobiology of bipolar illness, but further the understanding of some of the fundamental mechanisms of illness onset, progression, treatment and prevention. This information may help foster the institution of adequate treatment earlier and in a more consistent fashion in an attempt to slow or halt illness progression.
Clinical evidence for bipolar illness progression Emil Kraepelin, a century ago, delineated several aspects of the tendency for manic-depressive illness to progress:
An Introduction to the Neurobiology
(a) that successive episodes tend to recur with shorter well-intervals; and (b) that episodes later in the course of illness emerge more autonomously compared to early episodes that are often precipitated by psychosocial stressors [1]. In most studies, in which these variables were appropriately assessed, these general tendencies, which we have labelled (a) episode-sensitization [2] and (b) stress-sensitization, have been replicated [3–8] with few exceptions. Multiple other components of illness progression are manifest as well (c–g). (c) There is a general tendency for the illness to become more poorly responsive to most treatments as a function of number of prior episodes [9,10]. Similarly, there are a wealth of data demonstrating that even euthymic bipolar patients have substantial cognitive deficits; and (d) that the deficits are proportional to the number of prior episodes or duration of depressive illness [11–13]. The progressive emergence of increasing frequency, severity or duration of episodes during continuous treatment, which had previously been highly effective in preventing episodes is a (e) tolerance pattern that is indicative of another type of illness progression. This tolerance phenomenon can occur, even when full doses and adequate blood levels are maintained, suggesting that it is a pharmacodynamic rather than a pharmacokinetic tolerance process. This pattern of progressive increases in morbidity occurring during treatment often bears some resemblance to the initial progressive development of affective episodes that occurs at the beginning of the illness when it is unmedicated [14,15]. Another way in which treatment-refractoriness [14,16,17] can develop is in instances in which the illness has remained in remission on a given prophylactic treatment, but treatment is discontinued, new episodes re-emerge, and the drug is no longer effective once it is re-administered. This phenomenon has been most notably demonstrated with lithium discontinuation-induced refractoriness, but we have also seen other instances of it in patients with unipolar depression with traditional antidepressants in long-term prophylaxis [16]. This phenomenon of (f) discontinuationinduced treatment resistance, too suggests that the illness is progressive in that the occurrence of new episodes, in this case in the medication-free condition, is sufficient to change pharmaco-responsivity in the direction of treatment nonresponsiveness. This latter process may be, to some extent, analogous to that observed in treatment of malignancies, wherein the primary tumour is highly responsive to chemotherapy, but once the tumour has evolved and metastasized, it is no longer responsive to those primary agents. In bipolar disorders, a number of mechanisms could account for this phenomenon. For example, the new episode that occurs off medication may engender the typical decrements in neuroprotective factors, such as brain derived neurotrophic factor (BDNF) [18] and increases in neurotoxic factors such as oxidative stress and free radical produc-
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tion [19]. However, these episode-related changes are now occurring in the absence of the neuroprotective effects of a treatment such as lithium, which is known to induce BDNF and neurogenesis and a variety of other neuroprotective processes on its own [20]. Thus, the emergence of an episode of relatively similar severity during the offlithium period may cause a greater pathophysiologic disturbance than that which would ordinarily occur from an episode breaking through ongoing treatment. Regardless of the exact mechanisms involved, this phenomenon of additional episodes engendering treatment-refractoriness in the off-medication period is further evidence for the potential for illness progression as a function of number of episodes. (g) Many systemic manifestations of BD occur as a function of number of episodes or duration of illness. Recent studies have reported that 55–74% of bipolar patients are overweight or obese [21–23], and that they are more likely to be so compared to the general population [24]. Furthermore, the prevalence of obesity in bipolar disorder appears to be increasing with time. While obesity is a common feature of a number of psychiatric illnesses, a large epidemiologic study including 9125 patients suggested that the association between obesity and bipolar disorder was greater than that for major depressive disorder or anxiety disorders [24]. An increased prevalence of medical conditions associated with obesity, such as diabetes mellitus, hypertension, ischaemic heart disease and stroke, have been documented in bipolar patients [25,26]. Standardized mortality rates due to cardiovascular disease, are approximately twice that of the general population [26]. The cumulative effect of increased oxidative stress during mood episodes and chronic stress may in part explain the increased medical morbidity in bipolar disorder. These multiple reflections of illness progression (a–g) raise the idea of using medical staging models in BD [27,28]. Such models could guide specific, stage orientated therapeutic approaches; earlier stages would be associated with better prognosis and a higher likelihood of response, while later stages would demand more complex and potentially risky treatments. Furthermore, validation of these models could help to emphasize the need for early intervention and preventive strategies in BD. In this way, staging models for BD could optimize guidelines and algorithms, refining treatment according to an individualized, need-based management plan.
Potential neurobiological mechanisms for illness progression Given the substantial evidence that without effective treatment there is a tendency for the illness to increase in frequency, severity or duration of episodes and show increasing levels of treatment resistance, it is apparent that a
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variety of neurobiological processes could account for these phenomena. Hereditary genetic vulnerability could, itself, potentially be sufficient. This would be apparent from analogies to an illness process such as Huntingtons chorea which, once the disease process is initiated, it progresses inexorably to neurological and psychological decline, resulting in premature death. Such pure genetic determinism is highly unlikely to occur in bipolar illness for multiple reasons, including the evidence that there are many gene/environment interactions. For example, environmental insults such as the occurrence of stresses early in life interact with genetic and familial vulnerability to be associated with an earlier age of onset of illness [29–31] and a more severe course, as reflected in an increased incidence of suicidality [32] compared with those with the illness not suffering from these early life stressors. Similarly, those with a history of substance abuse have a more adverse course of illness than those without, suggesting an additional impact of neurobiological mechanisms associated with substance abuse on the pathophysiology of bipolar disorder. These clinical observations of a progressive course of BD are in line with findings of changes in brain biochemistry, function and structure between patients with early and late stages of BD [33]. For instance, morphometric studies have shown that patients with BD have changes in many brain structures in comparison to controls [34–36]. Notably, some authors reported that such neuroanatomical changes tend to be more pronounced with repeated episodes and correlate with length of illness [34,37]. Consistent with this, recent studies suggest that those that recently had their first manic episode have minimal alterations in brain structures [38]. Decreased neurotrophins and increased mediators of inflammation are amongst the potential mechanisms for neuronal and glial deterioration and progressive cognitive impairment in BD [18,39,40]. For instance, a recent report showed that TNF-alpha and IL-6 cytokines were increased in the early and late stage of BD, while BDNF levels were decreased in the late stage, but not in the early stage, when compared to controls [41]. The levels of the anti-inflammatory cytokine IL10 additionally declined in late stage of the disorder. These and other findings [42] indicate that patients with BD are likely to be in a pro-inflammatory state, which worsens in the later stages of the illness. In parallel, there is a decrease in the protective mechanisms, as indicated by a reduction in BDNF levels. One could hypothesize that BDNF levels decrease during mood episodes, but the restoration of the levels may be less likely with multiple episodes. In addition, some parameters of oxidative stress, such as 3-nitrotyrosine, are altered in the early stages of BD, while others, such as glutathione-s-transferase and glutathione reductase differ from controls only in those patients with multiple episodes, in later stages of BD [43].
Emerging data also suggests that the lowering of BDNF levels in acute episodes occurs in parallel with increased oxidative stress, suggesting that such changes occur in an orchestrated way [44]. Furthermore, there is emerging evidence of accelerated ageing process in BD, as indicated by telomere shortening and greater age-related decreases in BDNF levels in bipolar patients when compared to controls [27]. For instance, the telomere length, which has been used as a marker of ageing, was significantly shorter in those with mood disorders, representing as much as 10 years of accelerated ageing [24]. Indirect evidence also comes from studies showing increased oxidative stress in BD, which is also known to increase with ageing [45]. Notably, oxidative stress is associated with DNA damage, endothelial dysfunction and telomere shortening. These findings of accelerated agerelated processes provide further support for investigating more aggressive preventative measures.
Genetic mechanisms Large-scale whole genome studies suggest that there are reliable associations of a calcium channel (CACNA1C) and a neurotransmitter release mechanism (ANK 3) involved in vulnerability to bipolar illness. The involvement of a calcium channel is of considerable interest in regard to the overwhelming data, indicating increases in baseline and provoked levels of intracellular calcium in blood elements of patients with unipolar, and in particular, bipolar illness. Whether these relate to altered calcium channel dynamics on the membrane, or a very large body of data implicating alterations in mitochondrial dynamics and mitochondrial regulatory genes, remains to be further assessed. A particular mechanism of interest is that of two different alleles for proBDNF. The val-66-val allele of proBDNF occurs in a larger portion of the population and is the better functioning allele compared with the val-66-met allele or the met-66-met allele, which occur in smaller portions of the normal population and are less efficient [46]. These met alleles show limited transport to dendritic areas and are associated with decreased long-term potentiation in hippocampal slices, and subtle memory deficits in both normal volunteers and patient populations. The met alleles are also associated with decrements in hippocampal volume and activation as well as reduced prefrontal volumes in even normal volunteer controls [46]. What is particularly surprising, however, is that there is considerable evidence that the val-66-val allele of proBDNF is associated with an increased incidence of bipolar illness and/or earlier onsets, or the rapid cycling variant [18]. While it remains to be directly demonstrated in clinical studies, one could postulate that the better functioning val-66-val allele of proBDNF could be associated with the
An Introduction to the Neurobiology
increased pressure of speech and hyperassociativity, as well as creativity in those with mania and a diagnosis of bipolar illness in general. Moreover, Benson et al. [47] have recently demonstrated that bipolar patients, in contrast to those with unipolar illness and normal volunteer controls, have an increase in functional connectivity amongst brain regions. The usual inverse relationships between frontal cortex and amygdala or frontal cortex and cerebellum are not only not present in those with bipolar illness, but the correlations of metabolism between these and many other regions are now positive – that is, increases in one area are associated with increases in the other, and vice-versa, decreases are associated with decreases. Again, whether this hyperconnectivity and hyperassociativity seen in bipolar illness relates to the increased presence of the val-66-val allele, or some other mechanism, remains for future ascertainment. However, hypothetically, it is relatively easy to envision that such a hyper-positive associativity of multiple brain regions could, in part, account for the exaggerated overswings in mood and behaviour associated with both mania and depression, that is, the normal inverse modulatory effects of one region upon another and, particularly, prefrontal cortical suppression of amygdala and perilimbic and ventral striatal mechanisms, which appear to be hyperactive in patients with bipolar illness, does not occur [48]. However, as we make clear below, it is equally possible that such hyperassociativity is environmentally induced and potentially related to epigenetic mechanisms and not those inherent in our DNA code. Another area of promising findings in the realm of genetics is that of alterations in the CLOCK genes and related circadian rhythm genes in patients with bipolar illness. These data are now supported by the compelling studies of McClung et al., [49] and Roybal et al., [50], showing that disruptions of the clock gene are associated with behaviours in mice that are highly similar to human mania including: hyperactivity, decreased sleep, and increased reward value for cocaine, sucrose and even medial forebrain bundle stimulation. Remarkably, chronic administration of the mood stabilizer, lithium, returns many of these behavioural responses to normalcy. In addition, clock mutant mice have an increase in dopaminergic activity in the ventral striatal area and the associated behavioural abnormalities that are rescued by expressing a functional clock protein into the VTA. These data suggest inherent genetic connections between essential genes mediating circadian rhythms in the suprachiasmatic area (and in other areas of the brain) and dopaminergic transmission and cocaine reward. Mice lacking the functional clock gene also display not only an increasing cocaine reward, but also in the excitability and burst of firings of dopaminergic neurons in the VTA. These genetic data, like those discussed below for epigenetic mechanisms,
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provide a potential linkage between bipolar illness and the greatly increased proclivity for substance abuse.
Epigenetic mechanisms Long lasting effects of maternal rearing behaviour on adult neurochemistry, behaviour and stress responsivity Studies in the laboratory of M.J. Meaney [51,52] indicated that maternal licking and grooming behaviour in the immediate neonatal period is associated with long-lasting characteristics in the adult. For example, low licking and grooming is associated with increases in anxiety-like behaviour, hypersecretion of glucocorticoids and increased stress responsivity in the HPA axis. However, if offspring of low-licking mothers are cross-fostered by those with high licking and grooming traits, the offspring bear the differential signature of the high-licking mother of decreased anxiety-like behaviour and stress responsivity. This investigative group has demonstrated that such a life-long maternal programme of stress responsivity in the adult offspring is related to epigenetic mechanisms, that is low licking and grooming experiences of the neonate are associated with lower levels of the glucocorticoid receptor (GR), which is mediated by hypermethylation of the exon-17 of the GR promoter and is also associated with hyperacetylation of histone H 3-lysine-9, which reduces binding to nerve growth factor-inducible protein-A(NGF I-A). While it had initially been thought that these behavioural and biochemical characteristics were permanent, it now appears that central infusion of the histone-deacetylase inhibitor (HDAC) trichostatin A (TSA) can enhance histone H3K9 acetylation of the exon 17 of the GR promoter and change levels of hippocampal GR expression and HPA responsivity to stress. This has been further confirmed with reversal of some of these maternal-induced behavioural programmes with methionine infusions to alter the state of DNA methylation. These long-lasting, epigenetic-mediated, stable changes in adult offspring related to subtle differences in maternal licking and grooming behaviour make it clear that even very small alterations in appropriately timed maternal behaviour can induce long-lasting and life-long behavioural and biochemical characteristics, and more profound abuse or neglect could have even more major consequences. The clinical relevance of these findings has now been documented with the observations of parallel increased DNA methylation in the GR promotor in human brain. This occurred only in suicide victims who had experienced child abuse and neglect and not in those without these environmental adversities [53]. The new evidence indicating that some epigenetic mechanisms may also be potentially reversible with appropriate pharmacotherapeutic interventions raises hope for the possibility of ameliorating
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some of the long-lasting consequences of environmental adversity.
Defeat stress induced alterations in BDNF and behaviour The defeat stress paradigm provides a potentially homologous model to not only many of the behavioural characteristics of clinical depression in humans, but has parallels in terms of inducing principles (defeat stress) and pharmacotherapeutic mechanisms (antidepressants). In the defeat stress paradigm, an intruder mouse is introduced into the home cage of a resident animal, who viciously defends its territory and repeatedly defeats the intruder upon repeated presentations to the cage. This is associated with the induction of depressive-like behaviours including: social withdrawal, increased anxiety behaviour, weight loss, anhedonia (loss of preference for sucrose) and so on, as well as decrements in hippocampal BDNF and increases in BDNF in the dopaminergic pathway from the VTA to the nucleus accumbens [54,55]. Pretreatment with antidepressants reverses the defeat stress signature of low hippocampal BDNF and depressive-like behaviours. If the BDNF decreases are prevented with other genetic manipulations, the BDNF and defeat stress behaviours do not occur, indicating that the BDNF changes are critical to the resulting defeat stress behaviours. What makes these findings in adult animals of particular interest is that the repeated neonatal stresses can also change the signature of hippocampal and fronto-cortical BDNF and anxiety behaviour and stress responsivity in the adult [56]. Thus, similar to the subtle differences in maternal licking and grooming behaviour, more extreme stress experiences in an appropriate timed neonatal window can also affect neurochemistry and behaviour in a long-lasting fashion in the adult. Human data parallel these findings; adult bipolar patients who experienced serious early life adversity and trauma show lower serum BDNF levels than those without these environmental stressors [57]. Increases in BDNF in the dopaminergic pathway induced by defeat stress and cocaine sensitization In contrast to the stress-induced decrements of BDNF in the hippocampal-tri-glutamatergic neuronal circuit, defeat stress behaviours are associated with increases in BDNF in the nucleus accumbens, and such increases, if they are prevented by appropriate genetic manipulations, prevent the emergence of defeat stress behaviours [54,58]. Parallel increases in BDNF occur with chronic cocaine administration, again revealing environmentally-induced mechanisms linking depressive-like behaviours and the proclivity for substance abuse acquisition and progression [55]. This linkage is analogous to the genetically mediated mechanisms for the proclivity to substance abuse and manic-like behaviour associated with deficits in the clock gene [49,50].
The molecular mechanisms underlying the epigenetic changes induced by stress and cocaine are now being revealed. They involve not changes in the DNA sequence, but in its relative conformational openness yielding greater or lesser ease of initiating transcriptional activity [58]. This occurs at two different levels. DNA is tightly wrapped around histones and if histones are acetylated, this increases DNA openness and facilitates transcription. In contrast, if histones are methylated and phosphorylated, this can either activate or repress transcription. In addition to these histone modifications, DNA itself can be methylated and this is almost universally associated with repression of transcription. S-adenosyl methionine (SAM) is acted upon by DNA methyltransferases (DNMTs) to make methyl groups available for cytosine residues in the DNA. Most of the findings have so far revealed epigenetic mechanisms acting through histone modifications. Histone acetyl transferases (HATs) put acetyl groups on the histones and open DNA conformation, while histone deacetylases (HDACs) tighten or close the structure, making DNA less available for transcription. There is an entire group of histone deacetylase inhibitors (HDACIs), which keep the acetyl groups on the histones and maintain the open conformation, one of which is the mood stabilizing anticonvulsant valproate. Moreover, a recent study showed that treatment with an inhibitor of histone desacetylase, butyrate, reversed the hyperlocomotion induced by d-amphetamine in an animal model of mania, similarly to the effect of valproate [59]. Kumar and colleagues [60] have shown that acute cocaine or an acute electroconvulsive seizure hyperacetylates histone H4 acutely and transiently, suggesting dynamic changes in gene transcription. In contrast, chronic cocaine and chronic ECS hyperacetylate H3, inducing a chronic and stable state. This hyperacetylation of promoters 3 and 4 of BDNF are mediated by increases in the transcription factor DFOS-B and alterations in cdk5. It is interesting that acetylation of H3 builds increasingly during a week of cocaine withdrawal, resulting in the late increase in BDNF in the nucleus accumbens, which correlate with the time-frame of maximal behavioural-sensitization. Thus, changes in the degree of hyperacetylation of histone H3 account for the increases in BDNF in the nucleus accumbens and accompanying respective behaviours with both chronic cocaine and defeat stress behaviours. Krishnam et al., [61] report that they have also found increases in BDNF in the nucleus accumbens in autopsy specimens of patients with a history of depression. One could speculate that the BDNF decreases in the hippocampus noted above are related to alterations in the conscious or declarative memory system associated with amygdalo-hippocampal pathways, while the BDNF increases in the ventral striatum might be those associated with more automatic responses engaging the habit memory
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system in the striatum [62]. This inherent, automatic, unconscious mechanism in the nucleus accumbens could account for the high risk of relapse in animals and humans, even after they have been desensitized or extinguished from cocaine cues. Similarly, with repeated episodes of affective illness, episodes can emerge not only following the triggers of psychosocial stressors, but also in a more autonomous fashion as well. It has proven difficult to prevent or ward off by conscious or volitional behaviour, both recurrent affective episodes and re-instatement of substance abuse.
Only partial reversal of defeat stress epigenetic modifications by antidepressants As noted above, defeat stress results in sustained down regulation of two splice variants in the hippocampus – BDNF 3&4. This is mediated by dimethylation of histone H3 lysine 27 (H3K27) [58]. Interestingly, while antidepressants increase BDNF in the hippocampus by other pathways, the H3K27 dimethylation changes are not reversed by chronic treatment with antidepressants. Thus, this type of environmentally-induced histone modification may represent one aspect of the molecular memory or neurobiological scar that mediates the long-term increases in vulnerability that we postulate occurs and accumulates with each successive depressive episode [5,17]. It is noteable that cancer progression is likely mediated by trimethylation of H3K27, also leading to epigenetic silencing of target genes, potentially by an over expression of EZH2 a histone methyltranferase [63]. In the case of cancer progression, the over expression of EZH2 is mediated by a progressive genomic loss of a microRNA (miR-101) that normally inhibits EZH2, thus leading to dysregulaion of epigenetic pathways involved in cancer progression. The complexity of epigenetic mechanisms related to bipolar illness vulnerability and therapeutics remains to be more fully explored. In contrast to the persistence of the H3K27 dimethylation changes, the decreased BDNF levels in the hippocampus and associated defeat stress behaviours are reversed by antidepressants that remove the repression of the BDNF gene by inducing H3 acetylation and H3K4 methylation [58]. Chronic antidepressants down regulate HDAC 5 in the hippocampus only in chronic defeat stressed animals, leading to the increases in H3 acetylation (as well as H3 and K4 methylation activity in parallel) and prevention of the defeat stress behaviours. Thus, the H3K27 dimethylation induced by defeat stress is not reversed by antidepressants, even though these drugs reverse the depressive-like behaviours. To the extent that the H3K27 dimethylation leaves a permanent residue of illness vulnerability, further attempts at reversal of this epigenetic alteration are of great interest; this more complete reversal of the epigenetic effects of stressors could render the animal (or human) less vulnerable to further
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recurrences. Likewise, modifying EZH2-like methyltransferases and their regulation by microRNAs, as in cancer progression, are potential new targets of therapeutics.
Overview of the neurobiology of bipolar disorder Prefrontal cortical deficits and hypofunctions versus paralimbic hyperfunction The emerging neurobiology of bipolar illness has yielded some general patterns of the neurochemical, physiological and anatomical substrates involved. As illustrated in Figure 1, there appears to be a host of evidence of both neuronal and glial deficits yielding biochemical and physiological indices of hypo-function in prefrontal cortex of patients with bipolar disorder [9]. This stands in general contrast to considerable evidence for amygdala overactivity, hyper-reactivity and, in adults with the illness, volume increases. Parallel changes may be occurring in the extended amygdala, which merges into the ventral striatum (nucleus accumbens) with its evidence for over activity in the illness and paradoxical increases in BDNF and dopaminergic burst firing. Perhaps in concert with these opposite effects in anatomy, physiology, biochemistry and function of cortex versus mesolimbic regions are the findings that the normal inverse relationship of functional metabolic activity between prefrontal cortex and amygdala and other paralimbic areas of the brain in patients with bipolar illness, have shifted the valance towards uniform positive associativity [47]. The causative mechanisms underlying these shifts in associativity patterns are not known and the direction of causality – either episodes driving some neurobiological changes or the opposite that the severity of baseline alterations in connectivity are driving illness progression – remains to be further delineated.
Neurobiological alterations based on the environment However, the preclinical and animal model data noted above yield conclusive evidence that ill-timed and recurrent psychosocial stressors of sufficient emotional significance can change the neuro-behavioural signature of an adult animal in a stable and long-lasting fashion. D Fos B is a transcription factor that, in contrast to the immediate early genes (Fos, Jun and Ziff 268, etc.) is extremely long-lasting and thus yields the property of showing additive accumulation in relationship to the recurrence of stressors or repeated bouts of substance abuse. Thus, not only does D Fos B provide a cumulative marker for some recurrent stressors and substances of abuse, but distinguishing the patterns of histone acetylation and DNA modulation as a consequence
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Convergence of Structural, Biochemical, & Functional Abnormalities in Bipolar Illness: Cortical Deficits & Limbic Hyperactivity Imaging: Structural and Postmortem
Biochemistry & Function
DL-Pfc ↓ Gray ( Lim, Coffman) ↓ NAA (Winsberg/Ketter) ↓ Neurons esp Layer
DL-Pfc ↓ metabolism (dep.) ↓ CaCMK IIα (Xing) ↓ reelin (Costa/Guidotti) ↓ GAD67 (Guidotti) ↓ GFAP mRNA & protein ↑ cortisol ↓ MR (Xing)
DLPfc BA9 ↓ glial
III Glia esp BA24
↓ BG ↑volume (Pearlson) Hippocampus ↓ NAA (Bertolino) ↓ neuronal and synaptic markers (Eastwood & Harrison) Temporal Cortex ↓ Gray Volume (Altshuler, Hauser) ↓ NP & Spatial Navigation
BG ↑ PET metabolism
Hyp.
(Rajkowska)
BG
Pit.
C
A
H
LC
Hypothalamus ↑ CRF Pituitary
ACTH
Adrenal ↑ cortisol
↑ Amygdala (A) Volume ( Altshuler, Strakowski, Pearlson, Soares) ↓ Glial density in A (Bowley) ↑ Lateral and ↑ Third ventricle size
Fig. 1
¼ decreased and
(Ketter
H. ↓ cognitive and spatial memory Cerebellum (C) ↑Associativity, i.e., loss of reciprocal pfc-cerebellar function (Benson)
Locus Coeruleus (L.C.) ↑ # Ne cells (Baumann) ↑ Ne turnover, Ctx (Young) ↑ CSF Ne in Mania (Post) ↑ Amygdala (A) metabolism (Ketter) ↑ reactivity fMRI (Altshuler) ↓ response to Procaine (Ketter) ↑,↓ fear responses to stimuli Proportional to Neuropsychological (NP) Deficits
¼ increased.
of the accumulation of this transcription factor may yield important insights about the pathophysiology of bipolar illness and its treatment. It now appears that D Fos B and CDK5 influences on BDNF and subsequent histone H3 acetylation is one pathway leading to stable epigenetic events [58]. Distinguishing which of the pathological changes that have been revealed in the brains of bipolar patients are mediated by environmental-induced mechanisms and which are related to hereditary genetic mechanisms, may not only yield new understanding of the illness, but new approaches to targeting these alterations for therapeutics and developing new treatment strategies. While the search for single major genetic loci in bipolar disorders has been discouragingly negative, the lack of strong and replicateable findings can at the same offer an optimistic view about the lack of inevitability of illness onset and progression, despite ones genetic endowment. Whereas the single gene illnesses, such as Huntingtons chorea, convey a relatively immutable course of illness as a function of number of triple repeat sequences, the contrast in bipolar illness appears to include a panoply of modifying factors that can result in no illness at all in a relatively highly genetically vulnerable person, to a devastatingly progressive course. To the extent that more environmentally-induced epigenetic mechanisms become revealed in the bipolar illnesses, such information should yield the illness increasingly
malleable and responsive to treatment. The brain, as described by Edelson, has enormous capacity for plasticity and resilience, given its 12 billion neurons (each with an approximate average of 100 000 synapses) and four times as many glial elements. Viewing bipolar illness as a potentially progressive but highly modifiable illness, with no certain or irrevocable course or outcome, should convey a much more hopeful and optimistic view of the potentials for illness intervention and prevention.
Early onset illness as an added risk for neurobiological alterations and illness progression There is disturbing evidence that the earlier the age of onset of bipolar illness assessed retrospectively in adults (about average age 42), the more severe and disabling is the illness over the lifespan, as reported retrospectively [64] and as observed prospectively [65]. However, what remains to be seen is whether earlier, more effective intervention would yield more benign outcomes in those with early-onset bipolar illness. This is suggested by the observations that there is an inverse relationship between early age of onset and increasing duration of the lag to first treatment for mania and depression. Those with childhood onsets (before the age of 13) had an average of 15 years delay to first treatment, and adolescent-onset patients (before age 19) had an average of 10 years delay from illness onset to first
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treatment, while those with early and late adult-onset illnesses had much shorter five and three years delay, respectively. The delay to first treatment has been found to be an independent predictor of poor outcome in prospectively treated adults with bipolar disorder [66]. During these long periods of lack of treatment, those with child- and adolescent-onsets had increasing numbers of affective episodes and also had an increased amount of psychosocial adversity, as well as the new onset of substance abuse comorbidity [67]. To the extent that these factors provide additive or potentiative neurobiological mechanisms fundamental to bipolar illness at the level of epigenetic mechanisms, one can readily envision the multiple liabilities conveyed by lack of early and adequate treatment. Not only are there extremes of affective dysregulation yielding marked impairment in social and academic and, ultimately, employment roles, but one misses out on the acquisition of adequate neural and psychosocial development. These empirically observed and known consequences of poorly treated early-onset bipolar illness are now compounded by the very real possibility that a whole new level of pathophysiological processes can occur by epigenetic mechanisms and propel further stressors, episodes and abuse of substances. Childhood-onset bipolar illness appears to go through an accelerated rate of illness stage evolution compared with that of the adult variety. As such, it is even more critical from a developmental, psychosocial, and now, neurobiological perspective that adequate treatment is instituted early to avoid the wide range of adverse outcomes now observed to occur throughout childhood and adulthood. In these instances, the old adage that an ounce of prevention is worth a pound of cure not only rings true, but appears to be an underestimation of the potential difficulties a youngster with bipolar illness might encounter in the face of no or inadequate treatment. This illness on its own can be severe enough, but in the face of acquisition of a substance abuse disorder, which is 8fold more likely to occur in an adolescent with a bipolar diagnosis compared with others [68], leaves an individual with two very difficult to treat chronic recurrent illnesses, that is bipolar affective disorder and substance abuse disorder. Their additive negative psychosocial impact may be reflected in additive or new pathophysiological mechanisms. This can occur not only in basic CNS mechanisms, reviewed above, but also in peripheral mechanisms, related to accumulating allostatic loads ([69], which further increases the likelihood of the eventual onset or increased severity of a variety of medical comorbidities as well. These can ultimately have a catastrophic impact on the number of years of potential life expectancy lost in those with serious mental disorders, ranging from 13 years in the United States in states like Virginia to 25–30 years in some western states [70].
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Clinical implications for illness progression This dual view of (1) the strong empirical clinical evidence for the potential for bipolar illness progression in concert with (2) the newly revealed epigenetic putative pathophysiological mechanisms, together provides very compelling evidence for the need for dramatic reassessment of approaches to bipolar illness and its earlier intervention with preventative treatment [3,71]. These environmentally-mediated epigenetic mechanisms could be interacting with genetic mechanisms that each mediate earlier onset or a more fulminate course of illness. As noted in the Introduction, each episode of mania and depression clinically is associated with decrements in BDNF in serum (in proportion to the severity of either type of episode) [18] and decreases in platelet BDNF has now been demonstrated in childhood-onset bipolar illness as well [72]. To the extent that these changes in the periphery reflect BDNF alterations in brain as some have suggested, one could see how each episode might increase vulnerability to further neurobiological alterations associated with the illness, by virtue of decrements in BDNF and related neuroprotective factors. At the same time that there are decreases in BDNF, each episode appears to be associated with increases in oxidative stress and the ratio of pro inflammatory to anti-inflamatory cytokines. Thus, there appear to be interacting mechanisms for episode-induced illness progression by way of both increases in free radicals and other toxic substances endangering neurons and glia, as well as lack of adequate protection by neurotrophins such as BDNF. Based on the defeat stress model cited above, one would postulate that transient episode-related alterations would be mediated in part by changes in H4 acetylation, while the chronic, more longlasting consequences could be mediated by changes in H3 acetylation [58].
Cross-sensitization amongst stressors, episodes and substances of abuse such as cocaine Repetition of many different types of stressors will lead to stress sensitization or increases in behavioural reactivity, at times being manifest even when there is evidence of down regulation to the endocrine effects of the stressor. Interestingly, a variety of stressors seem to cross-sensitize to the stimulants cocaine or amphetamine [3,73–75]. That is, a stress-sensitized animal is more hyper-reactive to not only cocaine and amphetamine, but stress predisposes them to the acquisition of stimulant self-administration more readily than their non-stressed litter-mate controls. In addition, stresses are associated with the reactivation of cocaine selfadministration behaviour, even in animals and humans that have had their reactivity to cocaine cues and cravings
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extinguished. Thus, there appears to be not only the discrete phenomenon of stress-sensitization and cocaine sensitization, but cross-sensitization between these two as well. In addition, we have seen that there is a general tendency for episodes to beget further episodes in a phenomenon we have generically called episode sensitization. Bipolar and unipolar affective episodes are associated with a highly increased risk of engaging in substance abuse and also, in some instances, appear to convey the risk for increasing stress exposure, if not reactivity. Thus, we postulate there is a cross-sensitization amongst all three phenomena, that is sensitization to episodes, substances of abuse and stressors. BDNF decreases in hippocampus and in the serum clinically of humans may be part of the common mechanism of crosssensitization. At the same time, the increases in BDNF in the nucleus accumbens may be part of the over-learned or habit system over-representation of memory-like events for episodes, stressors and substances of abuse such as cocaine.
Passive and active mechanisms of illness progression Therefore, one might postulate two different types of mechanisms of sensitization to affective episodes, one a passive one associated with increase in free radicals and the other neurotoxic substances in the context of decreased neuroprotection, which could then endanger nonspecifically neuronal and glial function, or even survival. Then, in addition, there may be an active component of sensitization based on over-learned behavioural responsivity mediated, potentially in a condition- or context-dependent fashion, via BDNF and other changes in the nucleus accumbens. Given the new viewpoint about how each of these alterations could be mediated by epigenetic factors (in particular, changes in histone acetylation or methylation, and changes in DNA methylation), one begins to see how various environmental occurrences could alter DNA structure and associated transcription or repression (silencing of a large series of transcriptional events), while not altering the fundamental inherited DNA sequences [58].
Neurobiology informing clinical therapeutics The clinical empirical data for the adverse clinical, cognitive, functional and neural consequences of repeated episodes is quite clear. The empirical evidence itself supports a new view of the recurrent affective disorders as potentially progressive illnesses partially mediated by the accumulation of recurrent environmental events, including episodes themselves, as well as stressors and substances of abuse. This theoretical or kindling-like sensitization effect of the affective disorders raises a new level of concern about the importance of early institution of preventive strategies, not only
to limit illness-related morbidity and disability, but also potentially to avoid long-term course of illness alterations.
The importance of medications is thus based on a three fold rationale Effective pharmacoprophylaxis with lithium, carbamazepine or valproate will: (1) help prevent episodes and their associated morbidity; (2) prevent episode-related decreases in BDNF and increases in oxidative stress and other neurotoxic phenomena; and (3) likely mediate direct neurotrophic, neuroprotective effects on their own via their ability to increase BDNF and, with lithium and valproate, also neurogenesis. In addition, two of the atypicals, quetiapine and ziprasidone, prevent stress-induced decreases in hippocampal BDNF, and quetiapine also increases BDNF directly [76,77]. Importantly, these atypicals act in an opposite fashion on BDNF compared with the typical antipsychotic haloperidol, which exacerbates the stress-induced reduction in BDNF in the hippocampus. While the role of the unimodal antidepressants in the treatment of bipolar depression is controversial and undergoing revision with regard to an accumulation of data suggesting less than desirable efficacy and increased risk of mania induction and cycle acceleration, in the unipolar recurrent affective disorders the role of antidepressants is unequivocal in enhancing long-termprophylaxis [78,79]and, in animals, increasing both BDNF and neurogenesis. These putative mechanisms for enhancing neuroprotection have now been validated in the clinic with evidence that patients with unipolar depression who were on antidepressants more of the time do not have the hippocampal volume loss with ageing, in contrast to those on antidepressants less of the time who showed decrements in hippocampal volume [80]. Likewise, a number of studies have indicated that lithium in bipolar patients is associated with increases in markers of neuronal integrity such as NAA, as well as direct increases in cortical grey matter as revealed on the MRI [81,82].
Epigenetic effects reemphasize the need for early prevention The new data on epigenetic changes mediated by stressors and substances of abuse add to the potential long-term consequences of repeated affective illness recurrences and, at the same time, offer potential new avenues for therapeutic exploration. Previously, one recognized intermediate-term duration of neurochemical changes associated with an episode of affective illness, such as state dependent cortisol hypersecretion or BDNF decrements, likely mediated by changes in gene transcription. Given the new view of how stressors and cocaine could lead to lifelong alterations in histone and DNA conformation
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and availability for transcription, one is given even greater theoretical imputus for preventing affective episodes, their associated proclivity for substance abuse and avoiding or modulating stressor occurrence. These epigenetic-mediated changes may, on the one hand, represent episode, stressinduced and substance-induced neurobiological scars leading to illness progression, but may, in addition, mediate more active processes of illness progression associated with the appropriation or usurping of the habit learning system in the ventral striatum for accretion of behavioural pathology. Preventive approaches to the long-term management of the illness thus become of paramount importance.
Positive therapeutic potential of the convergent epigenetic effects Given the potential convergence of at least some mechanisms underlying stress sensitization, cocaine sensitization and episode-induced sensitization, a single therapeutic manoeuvre could have widespread implications for all three target systems. One potential example of this phenomenon is seen with the therapeutic approaches to substance abuse pioneered by Kalivas and associates using N-acetylcysteine (NAC) [83,84]. They observed that nucleus accumbens glutamate secretion was hyper-responsive in animals exposed to prior cocaine sensitization and put them at high risk for relapse to cocaine reinstatement (reinitiation of acquisition) upon stressor or cocaine exposure. They found that N-acetylcysteine(NAC), which alters the cysteine/glutamate exchanger in the nucleus accumbens and dampens the glutamate overactivity reduced cocaine reinstatement behaviour in animals, and subsequently showed that it had positive effects in cocaine addicts. NAC also showed positive effects in heroin and gambling addiction as well as trichotillomania. At the same time, Berk and associates [85] viewed NAC as an antioxidant and a glutathione precursor and showed that it had long-term benefit over placebo at 3 and 6 months in the treatment of residual symptoms of bipolar illness, with particularly prominent effects on bipolar depression. While it is unclear whether dampening glutamate hyper-responsivity in the nucleus accumbens or the antioxidant effects of NAC are responsible for its therapeutic effects in the affective disorders, the data on NAC make the point that a single pharmacological manipulation carries the potential dual or triple therapeutic benefit. Thus far, there is no evidence that treatment of episodes of mania and depression and preventing their recurrence in the long term alters vulnerability to the underlying mechanisms for illness recurrence; that is there are no cures. However, to the extent that epigenetic changes play a prominent role in the accumulation of illness vulnerability, potentially making whatever inherited genetic vulnerability cross the threshold for illness activation and reactivation, targeting
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epigenetic changes directly could theoretically have promise for altering some of the fundamental mediators of longterm vulnerability to recurrence. In this regard we know that valproate is a histone deacetylase inhibitor and it and other more specific HDAC inhibitors could ultimately play a role in altering some of the environmentally-induced epigenetic changes associated with the illness. Interestingly, the congener of valproate, valpromide, while it is a potent anticonvulsant, is not a HDAC inhibitor, thus raising the possibility of controlled clinical trials to show whether anticonvulsant versus epigenetic mechanisms play a role in whatever therapeutic effects are observed with these two agents. Similarly, the ability to reverse behavioural and biochemical alterations in neonatal maternal programming of adult behaviour, as well as in the defeat stress paradigm, also raises the possibility of TSA and other substances directly targeting epigenetic mechanisms that could also alter or reverse some of the long-lasting increases in illness vulnerability previously viewed as inherent in the illness and its progression.
An evolving neurobiology of bipolar disorder Pathological versus adaptive mechanisms We hope the foregoing discussion has shed some conceptual light on the rich variety of potential mechanisms involved in the neurobiology of bipolar disorder. At any level of analysis, it will be of critical importance to discern which changes are related to the primary pathology of the illness and its progression versus which are potentially endogenous adaptations and compensatory mechanisms [14]. This is essential in attempting to develop new therapeutic approaches, which could either: (1) be aimed at inhibiting the pathological processes; or (2) enhance the adaptive ones. Neurochemical alterations mediated by inherited genetic variation are at the moment not subject to amelioration, although they may be in the not-so-distant future. On the other hand, all of the environmentally-induced changes become major targets for therapeutics and more immediate attempts at intervention, prevention and reversal of those alterations.
Bipolar illness pleiomorphy and state versus trait abnormalities One of the struggles in conceptualizing the neurobiology of the affective disorders has been the difficulty in dealing with the behaviour and neurobiological over-swings occurring in opposite directions in both manic and depressive episodes and their co-occurrence in mixed states, as well as the
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almost infinite variety of frequencies of episode recurrence and cyclicity. This extreme illness pleiomorphy, further exacerbated by its multiplicity of comorbidities, makes bipolar illness particularly difficult to understand and treat. The problem is further exacerbated by the current limited understanding of the neuropathology of the illness at multiple separate levels of analysis. These include changes that reside at the level of a single gene and its protein product to a large array of multiple candidate genes and proteins successively reflecting upwards into larger regional neurochemical and physiological changes to alterations in pathways and circuits, which ultimately lead to behavioural dysregulation. The following chapters update our knowledge of the neurobiology of bipolar illness at each of these many different levels of analysis. The new view of the potential role of epigenetics in the neuropathology of bipolar illness and its therapeutics give us hope that it will yield new leverage points in better understanding and treating the illness. Transcription factors themselves can transiently induce gene activation or repression, and this level of understanding is now much further amplified by the knowledge of histone and DNA conformational modifications that make whole segments of the genome more or less accessible for gene transcription on a short- or long-term basis. Thus, common underlying mechanisms could mediate the apparent disparate neurochemical events associated with bipolar illness. These ultimately may yield common targets of therapeutics as well. If there is a general regulatory lack of control and resultant hyperactivity in systems modulating the excesses of mania, some of the same principles may apply to those modulating the excesses in the opposite direction of depressive affect and immobilization. The new findings of clock genes alterations and the pertinent animal models of mania derived from them further suggest mechanisms for the inherent connections between affective dysfunction and substance abuse comorbidity, and at the same time, potential links to the diverse alterations in frequency and cyclicity that are manifest across different individuals with bipolar disorder. Such linkages of changes in gene transcription and histone and DNA modifications also may yield new insights into factors underlying the stages of bipolar illness development and progression. These sequentially involve the: (1) baseline vulnerability state; (2) presymptomatic interval; (3) prodrome; (4) full syndrome; (5) episode recurrence; (6) illness progression; (7) treatment refractoriness; and (8) end-stage illness and premature death. Each of these stages may be reflected in differences in neurochemistry, physiology and neuroanatomy, so that assessing discrete changes as a function of illness course progression appears essential to a full understanding of the neurobiology of bipolar illness and its treatment. We know that affective illness patterns may progress from isolated intermittent episodes to more rapid and
regular recurrences and, ultimately, to continuous cycling without a well interval [16]. These can be spontaneous illness transitions or occur in association with some treatments, such as the adverse effects of unimodal antidepressants. The fact that antidepressants not only increase BDNF and neurogenesis, but also facilitate histone acetylation, could help in the conceptualization of how such a positive treatment for unipolar depression could, paradoxically, produce too much of an antidepressant drive and induce the illness to a new stage of progression. To the extent that histone and DNA modifications are involved in such transitions, this further raises the importance of not only early effective treatment of bipolar illness, but the avoidance of inappropriate treatment that could have lasting adverse effects via epigenetic mechanisms. Baldessarini et al. [86] reviewed treatment practices in a very large network of bipolar patients seen in private practice settings and, disturbingly, found that about 50% of those with new onset bipolar diagnoses were treated with antidepressant monotherapy, while many fewer patients were treated with lithium, anticonvulsants or atypical antipsychotics. Thus, prevention of both induced and spontaneous illness stage progression by dealing optimally with stresses and maximally preventing episodes and their associated high risk for substance abuse, are three critical and highly modifiable targets of not only pharmacotherapeutic but psychotherapeutic interventions as well. The early phases of understanding the complex and evolving neurobiology of bipolar disorders are continuing to reveal putative pathophysiological mechanisms not only for illness vulnerability and onset, but also their recurrence and progression to new stages of treatment refractoriness. To gain further detailed understanding of bipolar illness neurobiology, it will be increasingly important to assess it in relationship to the stage of illness evolution, as this may help explain some of the discrepant and at time apparently contradictory findings. We are used to examining neurobiology in relationships to manic and depressive states versus underlying trait vulnerability; to this we now must add the stage of illness evolution as well. Hopefully, this reconceptualization of the constantly changing and evolving pathophysiology of bipolar illness and the potential interactions of genetic and epigenetic factors driving it, will clarify some apparently discrepant findings reviewed in the following chapters. Hopefully, it will also help create a shift towards earlier and more effective treatment intervention and prevention in this paradoxical illness which, on the one hand, appears highly treatable and on the other hand potentially crippling and lethal. The insights already gained into the neurobiology of the illness may help us begin to intervene more effectively in making the course of illness a much more benign one for a larger majority of patients with the disorder.
An Introduction to the Neurobiology
References 1. Kraepelin, E. (1921) Manic Depressive Insanity and Paranoia, ES Livingstone, Edinburgh. 2. Kessing, L.V. et al. (2004) The predictive effect of episodes on the risk of recurrence in depressive and bipolar disorders – a life-long perspective. Acta Psychiatr. Scand., 109 (5), 339–344. 3. Post, R.M. and Post, S.L.W. (2004) Molecular and cellular developement vulnerabilities to the onset of affective disorders in children and adolescents: some implications for therapeutics, in Handbook of Mental Health Interventions in Children and Adolescents (ed. H. Steiner), Joss-Bass, San Fransisco, pp. 140–192. 4. Kendler, K.S., Thornton, L.M. and Gardner, C.O. (2000) Stressful life events and previous episodes in the etiology of major depression in women: an evaluation of the kindling hypothesis. Am. J. Psychiatry, 157 (8), 1243–1251. 5. Post, R.M. (1992) Transduction of psychosocial stress into the neurobiology of recurrent affective disorder. Am. J. Psychiatry, 149 (8), 999–1010. 6. Weiss, S.R.B. and Post, R.M. (1994) Caveats in the use of the kindling model of affective disorders. Toxicol. Ind. Health, 10, 421–447. 7. Dienes, K.A. et al. (2006) The stress sensitization hypothesis: understanding the course of bipolar disorder. J. Affect. Disord., 95 (1–3), 43–49. 8. Kendler, K.S., Thornton, L.M. and Gardner, C.O. (2001) Genetic risk, number of previous depressive episodes, and stressful life events in predicting onset of major depression. Am. J. Psychiatry, 158 (4), 582–586. 9. Post, R.M. et al. (2003) Morbidity in 258 bipolar outpatients followed for 1 year with daily prospective ratings on the NIMH life chart method. J. Clin. Psychiatry, 64 (6), 680–690, quiz 738–739. 10. Nolen, W.A. et al. (2004) Correlates of 1-year prospective outcome in bipolar disorder: results from the Stanley Foundation Bipolar Network. Am. J. Psychiatry, 161 (8), 1447–1454. 11. Bora, E., Yucel, M. and Pantelis, C. (2008) Cognitive endophenotypes of bipolar disorder: A meta-analysis of neuropsychological deficits in euthymic patients and their firstdegree relatives. J. Affect. Disord., 113, 1–20. 12. Torres, I.J., Boudreau, V.G. and Yatham, L.N. (2007) Neuropsychological functioning in euthymic bipolar disorder: a meta-analysis. Acta Psychiatr. Scand. (Suppl), (434), 17–26. 13. Gruber, S.A., Rosso, I.M. and Yurgelun-Todd, D. (2008) Neuropsychological performance predicts clinical recovery in bipolar patients. J. Affect. Disord., 105 (1–3), 253–260. 14. Post, R.M. and Weiss, S.R. (1996) A speculative model of affective illness cyclicity based on patterns of drug tolerance observed in amygdala-kindled seizures. Mol. Neurobiol., 13 (1), 33–60. 15. Weiss, S.R. et al. (1995) Contingent tolerance to the anticonvulsant effects of carbamazepine: relationship to loss of endogenous adaptive mechanisms. Brain Res. Brain Res. Rev., 20 (3), 305–325. 16. Post, R.M. and Leverich, G.S. (2007) Treatment of Bipolar Illness: A Casebook for Clinicians and Patients, W.W. Norton Press.
|
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17. Post, R.M. (2007) Kindling and sensitization as models for affective episode recurrence, cyclicity, and tolerance phenomena, in Animal Models of Bipolar Disorder and Mood Stabilizer Efficacy (eds T. Gould and H. Eimat), Neurosci. Biobehav. Rev., Jossey-Bass, pp. 858–873. 18. Post, R.M. (2007) Role of BDNF in bipolar and unipolar disorder: clinical and theoretical implications. J. Psychiatr. Res., 41 (12), 979–990. 19. Kapczinski, F. et al. (2008) Increased oxidative stress as a mechanism for decreased BDNF levels in acute manic episodes. Rev. Bras. Psiquiatr., 30 (3), 243–245. 20. Chuang, D.M. et al. (2002) Neuroprotective effects of lithium in cultured cells and animal models of diseases. Bipolar Disord., 4 (2), 129–136. 21. Elmslie, J.L. et al. (2000) Prevalence of overweight and obesity in bipolar patients. J. Clin. Psychiatry, 61 (3), 179–184. 22. McElroy, S.L. et al. (2002) Correlates of overweight and obesity in 644 patients with bipolar disorder. J. Clin. Psychiatry, 63 (3), 207–213. 23. Fagiolini, A. et al. (2005) Metabolic syndrome in bipolar disorder: findings from the Bipolar Disorder Center for Pennsylvanians. Bipolar Disord., 7 (5), 424–430. 24. Simon, G.E. et al. (2006) Association between obesity and psychiatric disorders in the US adult population. Arch. Gen. Psychiatry, 63 (7), 824–830. 25. Carney, C.P. and Jones, L.E. (2006) Medical comorbidity in women and men with bipolar disorders: a population-based controlled study. Psychosom. Med., 68 (5), 684–691. 26. Angst, F. et al. (2002) Mortality of patients with mood disorders: follow-up over 34–38 years. J. Affect. Disord., 68 (2–3), 167–181. 27. Yatham, L.N. et al. (2009) Accelerated age-related decrease in brain-derived neurotrophic factor levels in bipolar disorder. Int. J. Neuropsychopharmacol., 12 (1), 137–139. 28. Berk, M. et al. (2007) Setting the stage: from prodrome to treatment resistance in bipolar disorder. Bipolar Disord., 9 (7), 671–678. 29. Leverich, G.S. et al. (2002) Early physical and sexual abuse associated with an adverse course of bipolar illness. Biol. Psychiatry, 51 (4), 288–297. 30. Brown, G.R. et al. (2005) Impact of childhood abuse on the course of bipolar disorder: a replication study in U.S. veterans. J. Affect. Disord., 89 (1–3), 57–67. 31. Garno, J.L. et al. (2005) Impact of childhood abuse on the clinical course of bipolar disorder. Br. J. Psychiatry, 186 121–125. 32. Leverich, G.S. et al. (2003) Factors associated with suicide attempts in 648 patients with bipolar disorder in the Stanley Foundation Bipolar Network. J. Clin. Psychiatry, 64 (5), 506–515. 33. Post, R.M. et al. (2003) Neurobiology of bipolar illness: implications for future study and therapeutics. Ann. Clin. Psychiatry, 15 (2), 85–94. 34. Lyoo, I.K. et al. (2006) Regional cerebral cortical thinning in bipolar disorder. Bipolar Disord., 8 (1), 65–74. 35. Lopez-Larson, M.P. et al. (2002) Regional prefrontal gray and white matter abnormalities in bipolar disorder. Biol. Psychiatry, 52 (2), 93–100.
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36. Lyoo, I.K. et al. (2004) Frontal lobe gray matter density decreases in bipolar I disorder. Biol. Psychiatry, 55 (6), 648–651. 37. Strakowski, S.M. et al. (2002) Ventricular and periventricular structural volumes in first- versus multiple-episode bipolar disorder. Am. J. Psychiatry, 159 (11), 1841–1847. 38. Yatham, L.N. et al. (2007) A magnetic resonance imaging study of mood stabilizer- and neuroleptic-naive first-episode mania. Bipolar Disord., 9 (7), 693–697. 39. Kim, Y.K. et al. (2007) Imbalance between pro-inflammatory and anti-inflammatory cytokines in bipolar disorder. J. Affect. Disord., 104 (1–3), 91–95. 40. Duman, R.S. and Monteggia, L.M. (2006) A neurotrophic model for stress-related mood disorders. Biol. Psychiatry, 59 (12), 1116–1127. 41. Kauer-SantAnna, M. et al. (2008) Brain-derived neurotrophic factor and inflammatory markers in patients with early- vs. late-stage bipolar disorder. Int. J. Neuropsychopharmacol., 12, 1–12. 42. Cunha, A.B. et al. (2008) Investigation of serum high-sensitive C-reactive protein levels across all mood states in bipolar disorder. Eur. Arch. Psychiatry Clin. Neurosci., 258 (5), 300–304. 43. Andreazza, A.C. et al. (2009) 3-Nitrotyrosine and glutathione antioxidant system in patients in the early and late stages of bipolar disorder. J. Psychiatry Neurosci., 34 (4), 263–271. 44. Kapczinski, F. et al. (2008) Brain-derived neurotrophic factor and neuroplasticity in bipolar disorder. Expert Rev. Neurother., 8 (7), 1101–1113. 45. Andreazza, A.C. et al. (2007) DNA damage in bipolar disorder. Psychiatry Res., 153 (1), 27–32. 46. Egan, M.F. et al. (2003) The BDNF val66met polymorphism affects activity-dependent secretion of BDNF and human memory and hippocampal function. Cell, 112 (2), 257–269. 47. Benson, B. (2009) Interregional cerebral metabolic associativity in unipolar and bipolar disorder. Part II. Psychiatr. Res. Neuroimaging, 164, 30–47. 48. Ketter, T.A. et al. (2001) Effects of mood and subtype on cerebral glucose metabolism in treatment-resistant bipolar disorder. Biol. Psychiatry, 49 (2), 97–109. 49. McClung, C.A. et al. (2005) Regulation of dopaminergic transmission and cocaine reward by the Clock gene. Proc. Natl. Acad. Sci. USA, 102 (26), 9377–9381. 50. Roybal, K. et al. (2007) Mania-like behavior induced by disruption of CLOCK. Proc. Natl. Acad. Sci. USA, 104 (15), 6406–6411. 51. Weaver, I.C. et al. (2005) Reversal of maternal programming of stress responses in adult offspring through methyl supplementation: altering epigenetic marking later in life. J. Neurosci., 25 (47), 11045–11054. 52. Weaver, I.C., Meaney, M.J. and Szyf, M. (2006) Maternal care effects on the hippocampal transcriptome and anxiety-mediated behaviors in the offspring that are reversible in adulthood. Proc. Natl. Acad. Sci. USA, 103 (9), 3480–3485. 53. McGowan, P.O. et al. (2009) Epigenetic regulation of the glucocorticoid receptor in human brain associates with childhood abuse. Nat. Neurosci., 12 (3), 342–348.
54. Tsankova, N.M. et al. (2006) Sustained hippocampal chromatin regulation in a mouse model of depression and antidepressant action. Nat. Neurosci., 9 (4), 519–525. 55. Berton, O. et al. (2006) Essential role of BDNF in the mesolimbic dopamine pathway in social defeat stress. Science, 311 (5762), 864–868. 56. Roceri, M. et al. (2004) Postnatal repeated maternal deprivation produces age-dependent changes of brain-derived neurotrophic factor expression in selected rat brain regions. Biol. Psychiatry, 55 (7), 708–714. 57. Kauer-SantAnna, M. et al. (2007) Traumatic life events in bipolar disorder: impact on BDNF levels and psychopathology. Bipolar Disord., 9 (Suppl 1), 128–135. 58. Tsankova, N. et al. (2007) Epigenetic regulation in psychiatric disorders. Nat. Rev. Neurosci., 8 (5), 355–367. 59. Stertz, L. et al. (2008) Inhibition of histone desacetylase in amygdala and hippocampus in wistar rats treated with mood stabilizers and sodium butirate, in 28a Semana Cientı´fica do Hospital de Clı´nicas de Porto Alegre, Porto Alegre, 2008, Ann. 28a Semana Cientı´fica - Rev. do HCPA 28, 303–303. 60. Kumar, A. et al. (2005) Chromatin remodeling is a key mechanism underlying cocaine-induced plasticity in striatum. Neuron, 48 (2), 303–314. 61. Krishnan, V. et al. (2008) Calcium-sensitive adenylyl cyclases in depression and anxiety: behavioral and biochemical consequences of isoform targeting. Biol. Psychiatry, 64 (4), 336–343. 62. Mishkin, M. and Appenzeller, T. (1987) The anatomy of memory. Sci. Am., 256 (6), 80–89. 63. Varambally, S. et al. (2008) Genomic loss of microRNA-101 leads to overexpression of histone methyltransferase EZH2 in cancer. Science, 322 (5908), 1695–1699. 64. Perlis, R.H. et al. (2004) Long-term implications of early onset in bipolar disorder: data from the first 1000 participants in the systematic treatment enhancement program for bipolar disorder (STEP-BD). Biol. Psychiatry, 55 (9), 875–881. 65. Leverich, G.S. et al. (2007) The poor prognosis of childhoodonset bipolar disorder. J. Pediatr., 150 (5), 485–490. 66. Post, R. et al. (2010) Early onset bipolar disorder and treatment delay are risk factors for poor outcome in adulthood. J. Clin. Psyc., 71. 67. Geller, B. et al. (2008) Child bipolar I disorder: prospective continuity with adult bipolar I disorder; characteristics of second and third episodes; predictors of 8-year outcome. Arch. Gen. Psychiatry, 65 (10), 1125–1133. 68. Wilens, T.E. et al. (2008) Further evidence of an association between adolescent bipolar disorder with smoking and substance use disorders: a controlled study. Drug Alcohol Depend., 95 (3), 188–198. 69. Kapczinski, F. et al. (2008) Allostatic load in bipolar disorder: implications for pathophysiology and treatment. Neurosci. Biobehav. Rev., 32 (4), 675–692. 70. Newcomer, J.W. and Hennekens, C.H. (2007) Severe mental illness and risk of cardiovascular disease. JAMA, 298 (15), 1794–1796. 71. Post, R.M. and Kowatch, R.A. (2006) The health care crisis of childhood-onset bipolar illness: some recommendations for its amelioration. J. Clin. Psychiatry, 67 (1), 115–125. 72. Pandey, G.N. et al. (2008) Brain-derived neurotrophic factor gene expression in pediatric bipolar disorder: effects of
An Introduction to the Neurobiology
73. 74.
75.
76.
77.
78.
treatment and clinical response. J. Am. Acad. Child Adolesc. Psychiatry, 47 (9), 1077–1085. Kalivas, P.W. (2004) Glutamate systems in cocaine addiction. Curr. Opin. Pharmacol., 4 (1), 23–29. Kalivas, P.W. and Stewart, J. (1991) Dopamine transmission in the initiation and expression of drug- and stress-induced sensitization of motor activity. Brain Res. Brain Res. Rev., 16 (3), 223–244. Antelman, S. (1988) Stressor-induced sensitization to subsequent stress: implications for the development and treatment of clinical disorders, in Sensitization in the Nervous System (eds P. Kalivas and C. Barnes), Telford Press, Caldwell, NJ, pp. 227–254. Xu, H. et al. (2006) Synergetic effects of quetiapine and venlafaxine in preventing the chronic restraint stress-induced decrease in cell proliferation and BDNF expression in rat hippocampus. Hippocampus, 16 (6), 551–559. Park, S.W. et al. (2008) Differential effects of ziprasidone and haloperidol on immobilization stress-induced mRNA BDNF expression in the hippocampus and neocortex of rats. J. Psychiatr. Res., 43, 274–281. Davis, J.M., Wang, Z. and Janicak, P.G. (1993) A quantitative analysis of clinical drug trials for the treatment of affective disorders. Psychopharmacol. Bull., 29 (2), 175–181.
|
109
79. Cipriani, A. et al. (2006) Lithium versus antidepressants in the long-term treatment of unipolar affective disorder. Cochrane Database Syst. Rev (4), DOI: 10.1002/14651858. CD003492.pub2. 80. Sheline, Y.I., Gado, M.H. and Kraemer, H.C. (2003) Untreated depression and hippocampal volume loss. Am. J. Psychiatry, 160 (8), 1516–1518. 81. Moore, G.J. et al. (2000) Lithium increases N-acetyl-aspartate in the human brain: in vivo evidence in support of bcl-2s neurotrophic effects? Biol. Psychiatry, 48 (1), 1–8. 82. Bearden, C.E. et al. (2007) Greater cortical gray matter density in lithium-treated patients with bipolar disorder. Biol. Psychiatry, 62 (1), 7–16. 83. Baker, D.A. et al. (2003) N-acetyl cysteine-induced blockade of cocaine-induced reinstatement. Ann. N. Y. Acad. Sci., 1003, 349–351. 84. LaRowe, S.D. et al. (2006) Safety and tolerability of Nacetylcysteine in cocaine-dependent individuals. Am. J. Addict., 15 (1), 105–110. 85. Berk, M. et al. (2008) Glutathione: a novel treatment target in psychiatry. Trends Pharmacol. Sci., 29 (7), 346–351. 86. Baldessarini, R.J. et al. (2007) Patterns of psychotropic drug prescription for U.S. patients with diagnoses of bipolar disorders. Psychiatr. Serv., 58 (1), 85–91.
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Genetics of Bipolar Disorder Falk W. Lohoff and Wade H. Berrettini University of Pennsylvania School of Medicine, Philadelphia, PA, USA
Introduction The search for bipolar disorder (BPD) susceptibility genes is the subject of this chapter. As indicated by family, twin and adoption studies, BPD has substantial heritability, estimated from twin studies as approximately 65–80% of the risk [1]. Consistent with this heritability, BPD family studies demonstrate substantial familial aggregation: children of BPD parents have 9-fold increase in lifetime BPD risk, compared to the approximately 2–3% general population risk [2–10]. These same studies note a significant increase in risk for recurrent unipolar disorders (RUP) amongst the first-degree relatives of individuals with BPD. For RUP, the lifetime prevalence is at least 10% [11–13] and twin studies suggest a heritability of 40–50% [14–19]. Family studies indicated a two to three-fold increase in lifetime risk to develop RUP for first-degree relatives [4,9,20]. The familial aggregation and high heritability estimates generated early optimism that molecular genetic linkage and association techniques (useful for Mendelian disorders) would be similarly helpful in understanding the substantial genetic influence on BPD risk. As with nearly all common disorders (e.g. cardiovascular disease, alcoholism) however, unequivocal gene localization and identification has been a slow and labour intensive process. For BPD, as with all complex human disease traits, primary difficulties include: (1) no single gene is necessary and sufficient; (2) a single vulnerability allele conveys a small fraction of the total genetic risk; and (3) tremendous heterogeneity of risk alleles, meaning that large numbers of susceptibility alleles (which interact with each other and the environment) predispose to disorders, which are indistinguishable by phenotype (clinical presentation). Because the inherited susceptibilities for BPD are explained by multiple alleles, each of small effect, consistent confirmation of these risk alleles cannot be expected due to power issues, sampling variation (variations in risk allele frequencies in distinct ethnic groups) and genetic
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heterogeneity (distinctly different risk alleles occurring in indistinguishable syndromes). With this introduction, several promising linkages of BPD to genomic regions are reviewed, including some which may be shared with schizophrenia (SZ). It is highly probable that psychiatric nosology will be re-written to be consistent with genetics of the myriad diseases, which are currently subsumed under the rubric, BPD.
Genetic epidemiology of bipolar disorders Twin studies Evidence for a genetic component to BPD has been documented consistently using family, twin and adoptions studies and is summarized in Table 1. The first genetic studies of mood disorders were conducted over 70 years ago and included assessment of concordance rates for monozygotic and dizygotic twins with mood disorders [21–27]. The early studies did not distinguish between BPD and RUP; however, in nearly all these reports, RUP illness in the co-twin of a BPD index case was grounds for categorizing the twin pair as concordant. Bertelsen et al. [22] and Allen et al. [21] report that approximately 20% of concordant monozygotic twin pairs were constituted by a BPD index twin and a RUP cotwin. These older results are consistent with the more recent studies of BPD [16,28], reporting significantly higher monozygotic twins concordance rates, compared to those for dizygotic twins.
Family studies Family studies of BPD show that a spectrum of mood disorders is found amongst the first-degree relatives of BPD probands: BPI, BPII with major depression (hypomania and RUP illness in the same person), schizoaffective disorders and RUP illness [2–9,29,30]. The family studies suggest shared liability for BPD and RUP disorders. No BPD family study, conducted in an optimal manner (meaning simultaneous and blind interview of first-degree relatives of patients and controls), reports increased risk for SZ amongst
Genetics of Bipolar Disorder Table 1 Genetic epidemiology of mood disorders.
Lifetime prevalence (%) Lifetime risk for first degree relatives (fold increase) Proband-wise MZ twin concordance (%) Heritability estimate (%)
Bipolar disorder
Unipolar depression
2–3 9–10
10–15 2–3
45–70
40–50
65–80
33–42
relatives of BPD probands. Similarly, no SZ family study reports increased risk for BPD amongst relatives of SZ probands. Most importantly, these family studies were probably underpowered to detect a small increase in risk for a disorder with a base rate of 1–2% in the general population. However, several SZ family studies report increase risk for RUP and schizoaffective disorders amongst relatives of SZ probands [8,29,31,32]. These family studies are consistent with some degree of overlap in susceptibility to RUP and schizoaffective disorders for relatives of BPD probands and relatives of SZ probands. Kendler et al. [32] specifically note an increase in risk for psychotic affective disorders amongst the relatives of SZ probands. Potash et al. reported that psychotic affective disorders cluster in families [33,34]. Risk for psychotic affective disorders was significantly higher amongst the relatives of psychotic BPD probands, compared to the risk for relatives of non-psychotic BPD probands. This raises the possibility that the partial overlap in risk for BPD and SZ nosological categories is due to a subset of BPD characterized by psychotic symptoms. This subset of BPD is probably quite common, as the majority of BPD probands from the Potash et al. [33] study were psychotic. Recently, an epidemiological sample from Sweden, including 2 million nuclear families and using registry diagnoses, reported increased risk for SZ amongst relatives of BPD probands and increased risk for BPD amongst relatives of SZ probands [35]. This paper is remarkable for the size of the study population. Its main difficulty is reliance on registry diagnoses, as opposed to reliance on semistructured, in person interview data.
Adoption studies Mendlewicz and Rainer [36] reported a controlled adoption study of BPD probands, including a control group of probands with poliomyelitis [36]. The biological relatives of the BPD probands had a 31% risk for BPD or UP disorders, as opposed to 2% in the relatives of the control probands. The risk for affective disorder in biological relatives of adopted BPD patients was similar to the risk in relatives of BPD
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patients who were not adopted away (26%). Adoptive relatives do not show increased risk compared to relatives of control probands. Wender et al. [37] and Cadoret [38] studied RUP and BPD probands. Although evidence for genetic susceptibility was found, adoptive relatives of affective probands had a tendency to excess affective illness themselves, compared with the adoptive relatives of controls [37,38].
Linkage studies of bipolar disorders While linkage studies have nominated several genomic regions that might contain BPD risk alleles, inconsistent confirmation has been the rule, due to those factors mentioned earlier, including power, genetic heterogeneity and ethnic differences. The term, linkage, refers to the observation that two genetic loci, found near one another on the same chromosome, tend to be inherited together more often than expected by chance within families. Two such loci are said to be linked. The key concept of linkage is that chromosomal fragments that might harbour vulnerability genes are inherited with an illness more often then expected by chance in families. LOD (the logarithm of the odds ratio) scores refer to the probability that observed co-segregation of alleles at two loci within a family has occurred because the two loci are linked. A LOD score of more than 3 is evidence (not proof) that two DNA sequences are linked. The numerical value of the LOD score is dependent on the proposed mode of inheritance (dominant, recessive, sexlinked) and penetrance. Because the LOD score is dependent on these parameters (mode of inheritance and penetrance), it is sometimes termed a parametric statistic. This dependence on inheritance mode and penetrance distinguishes the LOD score from non-parametric statistics (including affected sibling pair and affected pedigree member methods), because such statistics are not dependent on mode of inheritance or penetrance. What level of statistical significance should be required for declaring linkage? A recommended level of statistical significance for an initial report (p 0.00 002) is a stringent criterion, based on simulations that indicate that this level of significance would occur less than five times randomly in 100 genome scans for linkage [39]. This statistical criterion assumes that all the genetic information within the pedigrees studied would be extracted, an assumption that is not true in practice. Typically, no more than approximately 80% of the genetic information in a pedigree series is extracted through genotyping. As in any other area of science however, no single report of linkage should be accepted as valid without independent confirmation. The requirement for independent confirmations (at p 0.01) is not waived, no matter what level of statistical significance has been achieved in a single report. This confirmation requirement
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should be seen within the context that valid linkages will not be confirmed in some studies. Indeed, non-confirmations should be expected, intuitively, because of population (ethnic) differences, sampling procedures and genetic heterogeneity. Suarez et al. [40] have examined the probability of confirmation in simulations. Suarez et al. [40] simulated a disorder caused by any one of six loci, and determined that a large sample size and substantial time will be required for an initial linkage to be confirmed in a second sample. From his simulations, it is clear that consistent detection of a locus of moderate effect cannot be expected. Non-confirmatory studies will always occur when an initially detected linkage is valid [40]. One of the most critical issues in confirmation of reported linkages is power. Attempts at confirmation of a reported susceptibility locus should state what power has been achieved to detect the locus initially described. For example, if a locus increases risk for BPD by a factor of 2, it may be necessary to study approximately 200 affected sibling pairs in order to have adequate (90%) power to detect such a locus [41]. Unfortunately, few studies address this key issue. If 200 affected sibling pairs are required to achieve adequate (90%) power to detect a previously described locus, then a publication with less than 150 sibling pairs does not address the central issue of confirmation. However, such power-limited publications may have an important role in meta-analyses, in that they identify invaluable sources of additional data. Comprehensive scans of the human genome have been completed with sufficient numbers (e.g. >100) of BPD individuals [42–50]. If a major locus (explaining >50% of the risk in >50% of BPD persons) existed, it would have been detected in many of these studies. Thus, no such major locus exists for BPD. There are several confirmed reports of loci of smaller effect, which can be termed susceptibility loci. These loci are neither necessary nor sufficient for disease, but increase risk for the disorder in a non-Mendelian manner. Confirmed linkage loci are summarized in Table 2. From these genome scans and from additional, smaller studies, a picture has emerged in which there are several confirmed BPD linkage regions across the genome. It is highly probable that additional confirmed BPD linkages will be identified through future linkage studies. These BPD linkage regions are confirmed by virtue of at least one study with strong statistical significance (p < 0.0001) and at least two confirmatory studies (p < 0.01). As noted elsewhere [51], in some cases, these confirmed BPD linkage regions overlap with SZ linkage reports, suggesting that the same loci may be involved in some aspects of both disorders. In an attempt to further elucidate possible BPD linkage regions, two meta-analyses of BPD genome scans have been conducted [52–54]. Badner and Gershon [52] analysed linkage results using a multiple scan probability approach, in which p values are combined across studies, after adjusting
Table 2 Linkage studies of bipolar disorder. Location
Primary report
Independent confirmations/ supportive evidence
4q32 4p15 6q16-24 8q24 12q23 13q21-32 16p12 18p11.2 18q22 21q22 22q11-13
[46] [64] [68] [43] [67] [44] [65] [81] [85] [92] [47]
[48,49,62,63] [43,44,65–67] [45,50,63,65,69–71] [45,49,54,59,72] [46,65,73–77] [47,48,60,78,79] [45,46,80] [42,82–86] [49,69,87–91] [67,93–96] [44,97,98]
Evidence from meta-analyses for genome wide significance
[55] [55] [52]
[52]
Only primary linkage studies are shown with genome-wide significance according to [39]. Negative studies are not shown.
for the size of the linkage region. These authors concluded that two genomic regions, 13q32 and 22q11-13, were the most promising loci for BPD. Segurado et al. [54] used the method of Levinson et al. [53], which ranks the p values across the genome of each study, then sums the rankings for each genomic bin. In this approach, no genomic region reached genome-wide significance, although the regions that seemed most promising were 9p, 10q, 14q and the pericentromeric region of chromosome 18 [54]. A combined analysis of 11 previous linkage scans was carried out by McQueen et al. [55]. In contrast to the two previous meta-analyses, the authors used original genotyping data and showed genome wide significant linkage for BPD on chromosomes 6q and 8q [55]. It is likely that several additional linkage loci will be identified in the future, in particular when large enough sample sizes will allow the analyses of clinical subtypes like psychotic BPD, early onset of illness or BPD with comorbid panic disorder. These subtypes have been suggested to have a strong heritable component to them [33,34,56,57]. For example, recent genome scans of psychotic BPD showed promising results to chromosome 9q31 and 8p21 [58,59] and 13q21-33 and 2p11-q14 [60]. Interestingly, 8p21 and 13q overlap with SZ, further substantiating the concept of shared genomic regions, which harbour shared susceptibility factors between BPD and SZ [61].
Candidate gene studies of bipolar disorder The human genome consists of about three billion base pairs of DNA [99]. The recent completion of draft genomic sequences of the human genome [99] is consistent with about 30 000 genes. Physical distance along the linear sequence of
Genetics of Bipolar Disorder
DNA can be expressed in terms of base pairs of DNA. The most common sequence variation in the human genome is a single nucleotide polymorphism (SNP), where there are two different nucleotides (from the possible four, adenine [A], guaine [G], thymidine [T] and cytosine [C]) found amongst homo sapiens at the same position on different chromosomes. SNPs with a common minor allele (frequency of 20%) occur approximately every 1000 base pairs of DNA [99]. Analysis of closely-spaced SNPs in outbred populations suggests a complex pattern of inheritance in which recombination is inhibited in a small region of DNA, such that blocks of DNA (containing multiple SNPs) tend to be inherited intact over many generations [100]. Thus, blocks of DNA are shared amongst present-day individuals who may have had a common ancestor 10 000 generations ago. These DNA blocks vary in length across ethnic groups [100], with typical lengths of 10–20 000 base pairs (containing multiple SNPs), but amongst outbred human populations, the block length rarely exceeds approximately 100 000 base pairs. Alleles of SNPs within a block form a haplotype (a set of alleles) that are usually inherited together across many generations. The alleles of such SNPs are said to be in strong linkage disequilibrium (LD) with each other, or associated with each other. LD refers to the fact that two (or more) alleles can be found together in unrelated individuals more often than predicted by chance. The interested reader is referred to primary reports concerning LD [100]. LD is a useful tool to investigate the relatively small genomic regions that have been implicated in the genetic origins of BPD through linkage studies (see Table 2). In this process, SNPs spaced across genes in the linkage region are assessed in large groups (ideally several hundred at least) of ethnically-matched cases and controls. Investigators compare allele and genotype frequencies amongst
Allele
1 2
3 4
RUP 5 6
7 8
9 10 11 12 13 14 15 16 17 18 19 20
Individual A Individual B Affected
Individual C Individual D Individual E Individual F
Not Affected
Individual G = risk allele
= protective allele
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groups of cases and controls. If nominally significant differences in allele or genotype frequencies are found between groups, the investigators might conclude that the tested SNP or a variant in close proximity influences risk for BPD. There have been a multitude of association studies in BPD over the past decade. Most studies have focused on neurotransmitter, neuroendocrine, neurotrophic and cellular signalling systems. Unfortunately, the nearly complete absence of pathophysiological data in BPD makes the process of rational candidate gene selection difficult. In addition, these studies have typically involved smaller numbers of BPD patients than is optimal, given that the effect size of individual alleles on risk must be small. While the lack of adequate power of some studies might explain the high degree of non-replication, other factors such as genetic heterogeneity and population differences further complicate matters. As indicated by the findings of multiple linkage loci, it is likely that there are several candidate genes that in combination contribute to the clinical phenotype of BPD. This paradigm is illustrated in Figure 1. Assume that there are 20 risk alleles, each only contributing a small fraction to the overall risk. In order to develop BPD, let us suppose we need five risk alleles. As shown, both individual A and B have BPD but share only one risk allele. Individual C has also five risk alleles but shares one risk allele with individual A and one risk allele with individual B. Individual D has also BPD risk alleles but falls in the SZ continuum. This genetic heterogeneity can explain why it is difficult to find universal risk alleles. It is more likely that several sets of risk alleles will contribute to the clinical phenotype. The degree and amount of risk alleles might explain why we observe a continuum or spectrum of the BPDs, or psychiatric disorders in general.
BPD SZ
|
Fig. 1 Model of risk and protective alleles involved in psych.
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As shown for the unaffected group, there are several scenarios which could explain unaffected status. One simple explanation is the lack of risk alleles (individual E) but another possibility includes the presence of protective alleles (as shown for individual F and G in green). While the majority of past studies have investigated risk alleles, it is becoming increasing clear that complex interactions of genetic risk and protective factors in concert with environmental stimuli contribute to the development of BPD. This observation has been made for example, in cancer genetics, with the identification of oncogenes and tumour suppressor genes [101,102]. Investigation of interaction of protective and susceptibility factors, in addition to complex gene-gene (epistatic) and gene-environment interactions, will be necessary in order to elucidate the genetic basis of complex behaviours [103]. Furthermore, epigenetic regulation and mechanisms might influence gene expression without altering the genetic code and could mediate stable changes in brain function [104]. Despite these difficulties and complexities, there are several candidate genes which deserve mention. On a general note, many candidate genes discussed here show also positive results for other psychiatric illnesses such as anxiety disorders, attention deficit hyperactivity disorder, psychotic disorders and substance use disorders, supporting the concept of shared susceptibility factors and comorbidities across diagnostic categories (Figure 1).
D-AMINO acid oxidase activator DAOA (G72)/G30 One promising candidate gene is the G72/G30 locus on 13q32, the site of a confirmed linkage in BPD (see Table 2) and SZ [52,82,105–112]. G72 is a primate-specific brainexpressed gene that activates D-amino acid oxidase [113] and was recently renamed D-amino acid oxidase activator (DAOA) (UCSC genome browser; Ensemble genome browser; National Centre for Biotechnology Information, http:// www.ncbi.nlm.nih.gov). D-amino acid oxidase may control levels of D-serine, which regulates glutamatergic receptors [114], implicated in the pathophysiology of SZ and BPD. Chumakov et al. [113] identified a haplotype from G72 SNPs (without obvious functional significance), which were in LD with SZ in a French-Canadian sample. This has been confirmed in distinct SZ populations, [113,115–117], although different haplotypes have been associated in different ethnic populations. Similarly, in BPD there have been several positive findings with distinct haplotypes in different populations [115–119]. A recent meta-analysis combined the published results at this locus and further substantiated the association of G72/G30 with BPD and SZ [120]. Although the G72/G30 locus is arguable amongst the best replicated association findings in psychiatric genetics, no clear functional variants have been yet defined at this locus and the biological relevance of this susceptibility locus remains elusive.
Brain-derived neurotrophic factor (BDNF) A second promising candidate gene is brain-derived neurotrophic factor (BDNF). BDNF is located on chromosome 11p13, a region of suggestive linkage for BPD [44,90]. Two family-based association studies showed an overtransmission of Val-allele of the functional Val66Met polymorphism [121,122]. This finding was confirmed in a large case-control association study of unrelated BPD subjects from the NIMH Genetics Initiative [123]. Additional evidence for an association of the Val allele was reported in three small childhood-onset samples: two using a family-based design [124,125] and one employing a case-control approach [126]. Furthermore, two studies report the Val allele associated with rapid cycling [127,128]. However, there are also several negative findings [127,129–135]. While some of these studies were likely underpowered, another explanation would be ethnic and clinical differences between samples. Recently, Liu et al. (2008) [213] reported results for a large sample of BPD cases and controls, concluding that the several BDNF SNPs may convey risk for BPD, including the Val allele, but the odds ratio is very modest (1.2). Most of the mentioned studies only investigated the Val66Met polymorphism. The BDNF gene structure is complex and might harbour several risk alleles in addition to the Val allele, as suggested by Liu et al. (2008). The functional consequences of the Val66Met are substantial and incompletely understood. Egan et al., demonstrated allele specific effects on intracellular trafficking and activity-dependent secretion of BDNF protein [136]. Recent studies demonstrate a role of the BDNF Val66Met polymorphism in cognition [136–140], brain structures [141] and BDNF serum levels [142]. Growing evidence suggests that BDNF is involved in the aetiology of mood disorders [143,144] and depressive personality traits [145]. Serum levels of BDNF were decreased in depressed patients when compared to controls [146–149] and postmortem brain studies in patients with BPD show decreased BDNF protein when compared to controls [150]. The use of antidepressants, electroconvulsive therapy and mood stabilizers such as lithium increase BDNF gene transcription [151–153] and infusion of BDNF into rat brain has a direct antidepressant effect in animal models of depression [154,155]. Taken together, the convergent evidence from genetic, preclinical and clinical studies makes BDNF a strong candidate for mood disorder.
Monoamine oxidase A (MAOA) There have been numerous independent association studies of BPD and RUP and an MAOA (CA)n repeat polymorphism in European [156–165] and Asian populations [166–168]. Those studies reporting a positive association [157–159, 162,166] generally detect an over-representation of allele 5 or
Genetics of Bipolar Disorder
6 of the MAOA (CA)n repeat amongst BPD patients, compared to controls, an observation that may be particularly evident amongst women [162,169–172]. The effect size is small, the odds ratio being 1.49 [162] and the sample size required for adequate power to detect is larger than most of the negative studies [156–165]. There is also an MAOA promoter polymorphism [167]. These studies involve multiple ethnic groups, case-control methods and family-based designs, with some studies having limited power to detect a small effect size. Thus, it is understandable that conflicting studies are reported.
Serotonin transporter (5HTT) Another intensively-studied candidate gene is the serotonin transporter (5HTT/SLC6A4), a functional candidate gene for which multiple BPD LD studies have been published. The 5HTT represents a logical candidate gene, as many antidepressants act through binding to the 5HTT protein [173]. There are two variants of the 5HTT that have been studied in BPD, and both have functional significance, based on in vitro analysis of these non-coding polymorphisms. The first variant is an insertion/deletion polymorphism in the promoter region (5HTTLPR). The shorter allele has much less transcriptional activity than the longer allele [174,175]. Moreover, the shorter allele has been associated with anxiety-related personality traits in humans [176]. The second variant is a variable number of tandem repeats (VNTR) polymorphism in intron 2. The two most common alleles are the 10 and 12 repeats, which confer differential transcriptional activity in an embryonic stem cell line [177]. Collier et al. [178] first reported that the 5HTT intron 2 VNTR allele 12 was in LD with BPD amongst patients from the United Kingdom [178]. Collier et al. also reported that the short allele of the 5HTT promoter variant was more common amongst 454 European BPD and recurrent unipolar patients, compared to 570 European controls, although the statistical significance was marginal (p ¼ 0.03), emphasizing the small effect size involved [174]. Analysis by genotype suggested that homozygosity for the short allele was associated with BPD (p < 0.05) and RUP (p < 0.01). Since this initial report there have been numerous replication studies with positive [179–183] and negative results [184–194]. Sampling variation and the small effect size, coupled with limited power of this sample size are probable explanations for these mixed results. Furlong et al. [195] reported results of a meta-analysis for approximately 1400 individuals of European origin, including 772 controls, 375 bipolar and 299 unipolar patients. Although there was no evidence for LD with affective disorders for the VNTR, a marginally significant result was found for the short allele of the 5HTT promoter polymorphism. This result is important, because it suggests that samples in the thousands will be necessary to draw firm
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conclusions, due to the small effect sizes involved. In another large European study, Mendlewicz et al. [191] examined the genetic contribution of the 5HTT promoter polymorphism in a case-control sample, including 539 RUP patients, 572 BPD patients and 821 controls. No evidence of LD was found for RUP or BPD, and subdividing the sample according to family history, suicidal attempts or psychotic features did not reveal any role of the promoter variant in the genetic susceptibilities to these disorders. A recent meta-analysis of published population-based and family-based association studies in BPD, investigating the 5HTTLPR and the VNTR polymorphism, showed a small effect (OR ¼ 1.12) of both SNPs [196]. Lasky-Su et al. [197] performed a meta-analysis of these SNPs for BPD and RUP and could only document a small effect (OR ¼ 1.13) of the insertion/deletion polymorphism with BPD [197]. A recent large-scale study of the 5HTTLPR promoter polymorphism failed to show an association for neuroticism, major depression or recurrent major depression [198]. Taken together, these data suggest a small but significant effect of the 44-bp insertion/deletion polymorphism (5HTTLPR) in BPD, while the role in major depression remains unclear. Several other candidate genes have been investigated in BPD, with some positive results for COMT, DAT, HTR4, DRD4, DRD2, HTR2A, DISC1, P2RX7 [199,200]. Most of these candidate genes were selected based on a priori hypotheses regarding their neurobiological function. This approach of candidate gene selection has obvious limitation, given our lack of understanding the pathophysiology of mood disorders.
Genome-wide association studies Risch and Merikangas (1996) [214] showed that association had greater power to detect causative alleles of small effect, and they argued for the genome-wide association study (GWAS) design. GWAS research is now feasible, with the discovery of over three million SNPs and the development of microarray genotyping. Because GWAS research involves testing for allele frequency differences as about 1 000 000 SNPs in large samples of cases and controls, a statistical level of p ¼ 10-7 is the equivalent of p ¼ 0.05 when searching the entire genome for association [201,202]. The stringent statistical correction for multiple-testing might mask true signals from genes that confer only modest risk of disease [203,204], although in theory this limitation could be overcome by larger sample sizes. The sample size required to achieve adequate power for expected effects sizes (odds ratios <1.5), given the correction for a genome-wide search, is the greatest limitation of this approach, as detailed in the power analysis shown in Table 3.
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Table 3 Sample Size for 80% Power in GWAS. Allele Freq.
OR 1.10
OR 1.30
OR 1.50
Additive 0.5 0.3 0.1
44 900 19 600 16 800
5580 2530 2240
2230 1050 954
Recessive 0.5 0.3 0.1
43 700 98 800 809 000
5570 12 200 99 100
2280 4860 39 000
Dominant 0.5 0.3 0.1
45 700 33 600 52 900
6320 4470 6680
2760 1900 2700
OR ¼ odds ratio Table gives number of case-control pairs needed for 80% power at a causative SNP. P ¼ 0.0000001 (statistical significance corrected for multiple hypothesis testing).
A few GWAS reports have been published in BPD. Baum et al. [205] published a DNA pooling based study of 500 cases from the NIMH Genetics Initiative, 500 NIMH controls and about 800 cases and about 800 controls collected in Germany. This study identified over 80 SNPs with nominally significant association signals in both samples. The ANK3 SNP, rs9804190, was one of approximately 80 SNPs nominally significant in both the NIMH (p ¼ 0.0020) and German samples (p ¼ 0.0087). Two larger studies employing individual genotyping have also been reported. The Welcome Trust study included 2000 BPD cases; this study reported weak evidence of association with five of the same SNP alleles detected in the Baum et al., study (WTCCC, 2008) [215], although genome-wide significance was not achieved, underscoring the need for large samples. A study of the STEP-BD sample and NIMH controls [206] yielded several SNP association signals at the 10-7 level in myosin 5B (MYO5B) and tetraspanin 8 (TSPAN8). It is noteworthy that the strongest association signals (the top ten for example) in each of these three studies were not confirmed in the other two, suggesting that the individual sample sizes lacked sufficient power to detect small effects. This sample size limitation was partially addressed by a collaborative effort, including 4387 cases and 6209 controls, which were analysed jointly using GWAS genotypes [207]. The strongest statistical signal was in the ankyrin 3 (ANK3) gene on chromosome 10q21, with single SNP and haplotype (rs4582919 – rs10994357 – rs7910492, risk haplotype CCT) analyses yielding P ¼ 109. This statistical level indicates genome-wide significance [208]. The associated SNPs spanned 195 kb in the 50 end of the gene. The odds ratio was 1.4. The characteristics of this study (a single phenotype analysed, careful control of stratification, etc.) are in accord
with those recommended recently by a panel of experts [209]. The 10q21 ANK3 location coincides with a BPD linkage signal [54]. There are several reports of nominally significant p values for SNPs in ANK3 [205,210,211]. Imputation (prediction of unassessed SNPs using genotypes of highly associated SNPs) reveals that the German sample identifies the same alleles as Ferreira et al. [207]. The study of Schulze et al. (2009) [216] was an emandation of the Baum et al. [205] study, including the German sample and additional samples. Finally, Bloss et al. [210] reported on an NIMH sample in which several ANK3 SNPs were nominally positive. Thus, ANK3 is a very promising candidate gene for BPD, although functional variants remain to be discovered. Ankyrins are peripheral membrane proteins thought to interconnect integral proteins with the spectrin-based membrane skeleton. There are three ankyrin genes, ANK1, 2 and 3. Kordeli et al. [212] described the ANK3 cDNA sequence, which has 44 exons, and is widely expressed in brain, as well as a variety of other tissues. The two largest ANK3 protein isoforms, 480 and 270 kD (also known as ankyrin G), contain an unusual serine-rich sequence, and are expressed only in the CNS [212].
Conclusions and future directions Family, twin and adoption studies of BPD are reviewed. They are, in general, consistent with substantial heritable components to risk. Multiple regions of the genome (including 18p11, 18q22, 12q24, 21q21, 13q32, 4p15, 4q32, 16p12, 8q24 and 22q11) have been implicated by several independent linkage studies in the genetic origins of BPD. It is likely that most of these regions will yield susceptibility genes within the near future, through the application of LD mapping methods and WGAS research to large sample sizes. LD approaches to candidate genes have yielded several promising candidate genes, including G72 and BDNF for BPD. In addition, molecular genetic studies of various psychiatric phenotypes document shared genomic regions between disorders, indicating a continuum between diagnostic categories rather then dichotomy. Although the field of psychiatric genetics has been plagued by positive and negative replications, promising robust findings are now emerging, such as ANK3, with the potential to lead to improved diagnosis and treatment.
References 1. Berrettini, W. (2002) Review of bipolar molecular linkage and association studies. Curr. Psychiatr. Rep., 4, 124–129. 2. Angst, J., Frey, R., Lohmeyer, B. and Zerbin-Rudin, E. (1980) Bipolar manic-depressive psychoses: results of a genetic investigation. Hum. Genet., 55, 237–254.
Genetics of Bipolar Disorder 3. Baron, M., Gruen, R., Asnis, L. and Kane, J. (1982) Schizoaffective illness, schizophrenia and affective disorders: morbidity risk and genetic transmission. Acta Psychiatr. Scand., 65, 253–262. 4. Gershon, E.S., Hamovit, J., Guroff, J.J. et al. (1982) A family study of schizoaffective, bipolar I, bipolar II, unipolar, and normal control probands. Arch. Gen. Psychiatry, 39, 1157–1167. 5. Helzer, J.E. and Winokur, G. (1974) A family interview study of male manic depressives. Arch. Gen. Psychiatry, 31, 73–77. 6. James, N.M. and Chapman, C.J. (1975) A genetic study of bipolar affective disorder. Br. J. Psychiatry, 126, 449–456. 7. Johnson, G.F. and Leeman, M.M. (1977) Analysis of familial factors in bipolar affective illness. Arch. Gen. Psychiatry, 34, 1074–1083. 8. Maier, W., Lichtermann, D., Minges, J. et al. (1993) Continuity and discontinuity of affective disorders and schizophrenia. Results of a controlled family study. Arch. Gen. Psychiatry, 50, 871–883. 9. Weissman, M.M., Gershon, E.S., Kidd, K.K. et al. (1984) Psychiatric disorders in the relatives of probands with affective disorders. The Yale University–National Institute of Mental Health Collaborative Study. Arch. Gen. Psychiatry, 41, 13–21. 10. Winokur, G., Tsuang, M.T. and Crowe, R.R. (1982) The Iowa 500: affective disorder in relatives of manic and depressed patients. Am. J. Psychiatry, 139, 209–212. 11. Moldin, S.O., Reich, T. and Rice, J.P. (1991) Current perspectives on the genetics of unipolar depression. Behav. Genet., 21, 211–242. 12. Tsuang, M.T., Taylor, L. and Faraone, S.V. (2004) An overview of the genetics of psychotic mood disorders. J. Psychiatr. Res., 38, 3–15. 13. Weissman, M.M., Bland, R.C., Canino, G.J. et al. (1996) Cross-national epidemiology of major depression and bipolar disorder. JAMA, 276, 293–299. 14. Bierut, L.J., Heath, A.C., Bucholz, K.K. et al. (1999) Major depressive disorder in a community-based twin sample: are there different genetic and environmental contributions for men and women? Arch., Gen., Psychiatry, 56, 557–563. 15. Kendler, K.S., Gardner, C.O., Neale, M.C. and Prescott, C.A. (2001) Genetic risk factors for major depression in men and women: similar or different heritabilities and same or partly distinct genes? Psychol. Med., 31, 605–616. 16. Kendler, K.S., Neale, M.C., Kessler, R.C. et al. (1993) The lifetime history of major depression in women. Reliability of diagnosis and heritability. Arch. Gen. Psychiatry, 50, 863–870. 17. McGuffin, P., Katz, R., Watkins, S. and Rutherford, J. (1996) A hospital-based twin register of the heritability of DSM-IV unipolar depression. Arch. Gen. Psychiatry, 53, 129–136. 18. Sullivan, P.F., Neale, M.C. and Kendler, K.S. (2000) Genetic epidemiology of major depression: review and metaanalysis. Am. J. Psychiatry, 157, 1552–1562. 19. Torgersen, S. (1986) Genetic factors in moderately severe and mild affective disorders. Arch. Gen. Psychiatry, 43, 222–226.
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20. Maier, W., Lichtermann, D., Minges, J. et al. (1992) Schizoaffective disorder and affective disorders with moodincongruent psychotic features: keep separate or combine? Evidence from a family study. Am. J. Psychiatry, 149, 1666–1673. 21. Allen, M.G., Cohen, S., Pollin, W. and Greenspan, S.I. (1974) Affective illness in veteran twins: a diagnostic review. Am. J. Psychiatry, 131, 1234–1239. 22. Bertelsen, A., Harvald, B. and Hauge, M. (1977) A Danish twin study of manic-depressive disorders. Br. J. Psychiatry, 130, 330–351. 23. Harvald, B. and Hauge, M. (1975) Genetics and the Epidemiology of Chronic Diseases, vol. 1163, PHS Publication, Washington, DC. 24. Kallman, F. (1954) Depression, Grune & Stratton, New York. 25. Luxenberger, H. (1930) Psychiatrisch-neurologische Zwillings pathologie. Zentralblatt fur Diagesamte Neurologie and Psychiatrie, 14, 145–180. 26. Rosanoff, A.J., Handy, L. and Plesset, I.R. (1935) The etiology of manic-depressive syndromes with special reference to their occurrence in twins. Am. J. of Psychiat., 91, 725–762. 27. Slater, E. (1936) The inheritance of manic-depressive insanity. Proc. R. Soc. Med., 29, 981–990. 28. McGuffin, P., Rijsdijk, F., Andrew, M. et al. (2003) The heritability of bipolar affective disorder and the genetic relationship to unipolar depression. Arch. Gen. Psychiatry, 60, 497–502. 29. Taylor, M.A., Berenbaum, S.A., Jampala, V.C. and Cloninger, C.R. (1993) Are schizophrenia and affective disorder related? preliminary data from a family study. Am. J. Psychiatry, 150, 278–285. 30. Tsuang, M.T., Winokur, G. and Crowe, R.R. (1980) Morbidity risks of schizophrenia and affective disorders among first degree relatives of patients with schizophrenia, mania, depression and surgical conditions. Br. J. Psychiatry, 137, 497–504. 31. Gershon, E.S., DeLisi, L.E., Hamovit, J. et al. (1988) A controlled family study of chronic psychoses. Schizophrenia and schizoaffective disorder. Arch. Gen. Psychiatry, 45, 328–336. 32. Kendler, K.S., McGuire, M., Gruenberg, A.M. et al. (1993) The Roscommon Family Study. I. Methods, diagnosis of probands, and risk of schizophrenia in relatives. Arch. Gen. Psychiatry, 50, 527–540. 33. Potash, J.B., Chiu, Y.F., MacKinnon, D.F. et al. (2003) Familial aggregation of psychotic symptoms in a replication set of 69 bipolar disorder pedigrees. Am. J. Med. Genet. B Neuropsychiatr. Genet., 116, 90–97. 34. Potash, J.B., Willour, V.L., Chiu, Y.F. et al. (2001) The familial aggregation of psychotic symptoms in bipolar disorder pedigrees. Am. J. Psychiatry, 158, 1258–1264. 35. Lichtenstein, P., Yip, B.H., Bjork, C. et al. (2009) Common genetic determinants of schizophrenia and bipolar disorder in Swedish families: a population-based study. Lancet, 373, 234–239. 36. Mendlewicz, J. and Rainer, J.D. (1977) Adoption study supporting genetic transmission in manic–depressive illness. Nature, 268, 327–329.
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37. Wender, P.H., Kety, S.S., Rosenthal, D. et al. (1986) Psychiatric disorders in the biological and adoptive families of adopted individuals with affective disorders. Arch. Gen. Psychiatry, 43, 923–929. 38. Cadoret, R.J. (1978) Evidence for genetic inheritance of primary affective disorder in adoptees. Am. J. Psychiatry, 135, 463–466. 39. Lander, E. and Kruglyak, L. (1995) Genetic dissection of complex traits: guidelines for interpreting and reporting linkage results. Nat. Genet., 11, 241–247. 40. Suarez, B.H., Hampe, C.L. and Van Eerdewegh, P. (1994) Problems of Replicating Linkage Claims in Psychiatry, American Psychiatric Press, Washington DC. 41. Hauser, E.R., Boehnke, M., Guo, S.W. and Risch, N. (1996) Affected-sib-pair interval mapping and exclusion for complex genetic traits: sampling considerations. Genet. Epidemiol., 13, 117–137. 42. Bennett, P., Segurado, R., Jones, I. et al. (2002) The Wellcome trust UK-Irish bipolar affective disorder sibling-pair genome screen: first stage report. Mol. Psychiatry, 7, 189–200. 43. Cichon, S., Schumacher, J., Muller, D.J. et al. (2001) A genome screen for genes predisposing to bipolar affective disorder detects a new susceptibility locus on 8q. Hum. Mol. Genet., 10, 2933–2944. 44. Detera-Wadleigh, S.D., Badner, J.A., Berrettini, W.H. et al. (1999) A high-density genome scan detects evidence for a bipolar-disorder susceptibility locus on 13q32 and other potential loci on 1q32 and 18p11.2. Proc. Natl. Acad. Sci. USA, 96, 5604–5609. 45. Dick, D.M., Foroud, T., Flury, L. et al. (2003) Genomewide linkage analyses of bipolar disorder: a new sample of 250 pedigrees from the National Institute of Mental Health Genetics Initiative. Am. J. Hum. Genet., 73, 107–114. 46. Ekholm, J.M., Kieseppa, T., Hiekkalinna, T. et al. (2003) Evidence of susceptibility loci on 4q32 and 16p12 for bipolar disorder. Hum. Mol. Genet., 12, 1907–1915. 47. Kelsoe, J.R., Spence, M.A., Loetscher, E. et al. (2001) A genome survey indicates a possible susceptibility locus for bipolar disorder on chromosome 22. Proc. Natl. Acad. Sci. USA, 98, 585–590. 48. Liu, J., Juo, S.H., Dewan, A. et al. (2003) Evidence for a putative bipolar disorder locus on 2p13-16 and other potential loci on 4q31, 7q34, 8q13, 9q31, 10q21-24, 13q32, 14q21 and 17q11-12. Mol. Psychiatry, 8, 333–342. 49. McInnis, M.G., Lan, T.H., Willour, V.L. et al. (2003) Genomewide scan of bipolar disorder in 65 pedigrees: supportive evidence for linkage at 8q24, 18q22, 4q32, 2p12, and 13q12. Mol. Psychiatry, 8, 288–298. 50. Rice, J.P., Goate, A., Williams, J.T. et al. (1997) Initial genome scan of the NIMH genetics initiative bipolar pedigrees: chromosomes 1, 6, 8, 10, and 12. Am. J. Med. Genet., 74, 247–253. 51. Berrettini, W. (2003) Evidence for shared susceptibility in bipolar disorder and schizophrenia. Am. J. Med. Genet., 123C, 59–64. 52. Badner, J.A. and Gershon, E.S. (2002) Meta-analysis of whole-genome linkage scans of bipolar disorder and schizophrenia. Mol. Psychiatry, 7, 405–411.
53. Levinson, D.F., Levinson, M.D., Segurado, R. and Lewis, C.M. (2003) Genome scan meta-analysis of schizophrenia and bipolar disorder, part I: Methods and power analysis. Am. J. Hum. Genet., 73, 17–33. 54. Segurado, R., Detera-Wadleigh, S.D., Levinson, D.F. et al. (2003) Genome scan meta-analysis of schizophrenia and bipolar disorder, part III: Bipolar disorder. Am. J. Hum. Genet., 73, 49–62. 55. McQueen, M.B., Devlin, B., Faraone, S.V. et al. (2005) Combined analysis from eleven linkage studies of bipolar disorder provides strong evidence of susceptibility loci on chromosomes 6q and 8q. Am. J. Hum. Genet., 77, 582–595. 56. Lin, P.I., McInnis, M.G., Potash, J.B. et al. (2005) Assessment of the effect of age at onset on linkage to bipolar disorder: evidence on chromosomes 18p and 21q. Am. J. Hum. Genet., 77, 545–555. 57. MacKinnon, D.F., Zandi, P.P., Cooper, J. et al. (2002) Comorbid bipolar disorder and panic disorder in families with a high prevalence of bipolar disorder. Am. J. Psychiatry, 159, 30–35. 58. Cheng, R., Juo, S.H., Loth, J.E. et al. (2006) Genome-wide linkage scan in a large bipolar disorder sample from the National Institute of Mental Health genetics initiative suggests putative loci for bipolar disorder, psychosis, suicide, and panic disorder. Mol. Psychiatry, 11, 252–260. 59. Park, N., Juo, S.H., Cheng, R. et al. (2004) Linkage analysis of psychosis in bipolar pedigrees suggests novel putative loci for bipolar disorder and shared susceptibility with schizophrenia. Mol. Psychiatry, 9, 1091–1099. 60. Goes, F.S., Zandi, P.P., Miao, K. et al. (2007) Moodincongruent psychotic features in bipolar disorder: familial aggregation and suggestive linkage to 2p11-q14 and 13q21-33. Am. J. Psychiatry, 164, 236–247. 61. Berrettini, W. (2004) Bipolar disorder and schizophrenia: convergent molecular data. Neuromolecular Med., 5, 109–117. 62. Adams, L.J., Mitchell, P.B., Fielder, S.L. et al. (1998) A susceptibility locus for bipolar affective disorder on chromosome 4q35. Am. J. Hum. Genet., 62, 1084–1091. 63. Schumacher, J., Kaneva, R., Jamra, R.A. et al. (2005) Genomewide scan and fine-mapping linkage studies in four European samples with bipolar affective disorder suggest a new susceptibility locus on chromosome 1p35-p36 and provides further evidence of loci on chromosome 4q31 and 6q24. Am. J. Hum. Genet., 77, 1102–1111. 64. Blackwood, D.H., He, L., Morris, S.W. et al. (1996) A locus for bipolar affective disorder on chromosome 4p. Nat. Genet., 12, 427–430. 65. Ewald, H., Flint, T., Kruse, T.A. and Mors, O. (2002) A genome-wide scan shows significant linkage between bipolar disorder and chromosome 12q24.3 and suggestive linkage to chromosomes 1p22-21, 4p16, 6q14-22, 10q26 and 16p13.3. Mol. Psychiatry, 7, 734–744. 66. Ginns, E.I., St Jean, P., Philibert, R.A. et al. (1998) A genomewide search for chromosomal loci linked to mental health wellness in relatives at high risk for bipolar affective disorder among the Old Order Amish. Proc. Natl. Acad. Sci. USA, 95, 15531–15536.
Genetics of Bipolar Disorder 67. Morissette, J., Villeneuve, A., Bordeleau, L. et al. (1999) Genome-wide search for linkage of bipolar affective disorders in a very large pedigree derived from a homogeneous population in quebec points to a locus of major effect on chromosome 12q23-q24. Am. J. Med. Genet., 88, 567–587. 68. Middleton, F.A., Pato, M.T., Gentile, K.L. et al. (2004) Genomewide linkage analysis of bipolar disorder by use of a high-density single-nucleotide-polymorphism (SNP) genotyping assay: a comparison with microsatellite marker assays and finding of significant linkage to chromosome 6q22. Am. J. Hum. Genet., 74, 886–897. 69. Lambert, D., Middle, F., Hamshere, M.L. et al. (2005) Stage 2 of the Wellcome Trust UK-Irish bipolar affective disorder sibling-pair genome screen: evidence for linkage on chromosomes 6q16-q21, 4q12-q21, 9p21, 10p14-p12 and 18q22. Mol. Psychiatry, 10, 831–841. 70. Pato, C.N., Pato, M.T., Kirby, A. et al. (2004) Genome-wide scan in Portuguese Island families implicates multiple loci in bipolar disorder: fine mapping adds support on chromosomes 6 and 11. Am. J. Med. Genet. B Neuropsychiatr. Genet., 127, 30–34. 71. Venken, T., Claes, S., Sluijs, S. et al. (2005) Genomewide scan for affective disorder susceptibility Loci in families of a northern Swedish isolated population. Am. J. Hum. Genet., 76, 237–248. 72. Friddle, C., Koskela, R., Ranade, K. et al. (2000) Full-genome scan for linkage in 50 families segregating the bipolar affective disease phenotype. Am. J. Hum. Genet., 66, 205–215. 73. Cassidy, F., Zhao, C., Badger, J. et al. (2007) Genome-wide scan of bipolar disorder and investigation of population stratification effects on linkage: Support for susceptibility loci at 4q21, 7q36, 9p21, 12q24, 14q24, and 16p13. Am. J. Med. Genet. B Neuropsychiatr. Genet., 144B (8), 1094–1096. 74. Curtis, D., Kalsi, G., Brynjolfsson, J. et al. (2003) Genome scan of pedigrees multiply affected with bipolar disorder provides further support for the presence of a susceptibility locus on chromosome 12q23-q24, and suggests the presence of additional loci on 1p and 1q. Psychiatr. Genet., 13, 77–84. 75. Dawson, E., Parfitt, E., Roberts, Q. et al. (1995) Linkage studies of bipolar disorder in the region of the Dariers disease gene on chromosome 12q23-24.1. Am. J. Med. Genet., 60, 94–102. 76. Maziade, M., Roy, M.A., Rouillard, E. et al. (2001) A search for specific and common susceptibility loci for schizophrenia and bipolar disorder: a linkage study in 13 target chromosomes. Mol. Psychiatry, 6, 684–693. 77. Shink, E., Morissette, J., Sherrington, R. and Barden, N. (2005) A genome-wide scan points to a susceptibility locus for bipolar disorder on chromosome 12. Mol. Psychiatry, 10, 545–552. 78. Badenhop, R.F., Moses, M.J., Scimone, A. et al. (2001) A genome screen of a large bipolar affective disorder pedigree supports evidence for a susceptibility locus on chromosome 13q. Mol. Psychiatry, 6, 396–403. 79. Potash, J.B., Zandi, P.P., Willour, V.L. et al. (2003) Suggestive linkage to chromosomal regions 13q31 and 22q12 in families with psychotic bipolar disorder. Am. J. Psychiatry, 160, 680–686.
|
119
80. Savitz, J., Cupido, C.L. and Ramesar, R.K. (2007) Preliminary evidence for linkage to chromosome 1q31-32, 10q23.3, and 16p13.3 in a South African cohort with bipolar disorder. Am. J. Med. Genet. B Neuropsychiatr. Genet., 144, 383–387. 81. Berrettini, W.H., Ferraro, T.N., Goldin, L.R. et al. (1997) A linkage study of bipolar illness. Arch. Gen. Psychiatry, 54, 27–35. 82. Lin, M.W., Sham, P., Hwu, H.G. et al. (1997) Suggestive evidence for linkage of schizophrenia to markers on chromosome 13 in Caucasian but not Oriental populations. Hum. Genet., 99, 417–420. 83. Mukherjee, O., Meera, P., Ghosh, S. et al. (2006) Evidence of linkage and association on 18p11.2 for psychosis. Am. J. Med. Genet. B Neuropsychiatr. Genet., 141B, 868–873. 84. Nothen, M.M., Cichon, S., Rohleder, H. et al. (1999) Evaluation of linkage of bipolar affective disorder to chromosome 18 in a sample of 57 German families. Mol. Psychiatry, 4, 76–84. 85. Stine, O.C., Xu, J., Koskela, R. et al. (1995) Evidence for linkage of bipolar disorder to chromosome 18 with a parent-of-origin effect. Am. J. Hum. Genet., 57, 1384–1394. 86. Turecki, G., Grof, P., Cavazzoni, P. et al. (1999) Lithium responsive bipolar disorder, unilineality, and chromosome 18: A linkage study. Am. J. Med. Genet., 88, 411–415. 87. De bruyn, A., Souery, D., Mendelbaum, K. et al. (1996) Linkage analysis of families with bipolar illness and chromosome 18 markers. Biol. Psychiatry, 39, 679–688. 88. Fallin, M.D., Lasseter, V.K., Wolyniec, P.S. et al. (2004) Genomewide linkage scan for bipolar-disorder susceptibility loci among Ashkenazi Jewish families. Am. J. Hum. Genet., 75, 204–219. 89. Freimer, N.B., Reus, V.I., Escamilla, M.A. et al. (1996) Genetic mapping using haplotype, association and linkage methods suggests a locus for severe bipolar disorder (BPI) at 18q22q23. Nat. Genet., 12, 436–441. 90. McInnes, L.A., Escamilla, M.A., Service, S.K. et al. (1996) A complete genome screen for genes predisposing to severe bipolar disorder in two Costa Rican pedigrees. Proc. Natl. Acad. Sci. USA, 93, 13060–13065. 91. McMahon, F.J., Hopkins, P.J., Xu, J. et al. (1997) Linkage of bipolar affective disorder to chromosome 18 markers in a new pedigree series. Am. J. Hum. Genet., 61, 1397–1404. 92. Straub, R.E., Lehner, T., Luo, Y. et al. (1994) A possible vulnerability locus for bipolar affective disorder on chromosome 21q22.3. Nat. Genet., 8, 291–296. 93. Aita, V.M., Liu, J., Knowles, J.A. et al. (1999) A comprehensive linkage analysis of chromosome 21q22 supports prior evidence for a putative bipolar affective disorder locus. Am. J. Hum. Genet., 64, 210–217. 94. Detera-Wadleigh, S.D., Badner, J.A., Goldin, L.R. et al. (1996) Affected-sib-pair analyses reveal support of prior evidence for a susceptibility locus for bipolar disorder, on 21q. Am. J. Hum. Genet., 58, 1279–1285. 95. Kwok, J.B., Adams, L.J., Salmon, J.A. et al. (1999) Nonparametric simulation-based statistical analyses for bipolar affective disorder locus on chromosome 21q22.3. Am. J. Med. Genet., 88, 99–102.
120
|
Chapter 12
96. Smyth, C., Kalsi, G., Brynjolfsson, J. et al. (1996) Further tests for linkage of bipolar affective disorder to the tyrosine hydroxylase gene locus on chromosome 11p15 in a new series of multiplex British affective disorder pedigrees. Am. J. Psychiatry, 153, 271–274. 97. Detera-Wadleigh, S.D., Badner, J.A., Yoshikawa, T. et al. (1997) Initial genome scan of the NIMH genetics initiative bipolar pedigrees: chromosomes 4, 7, 9, 18, 19, 20, and 21q. Am. J. Med. Genet., 74, 254–262. 98. Lachman, H.M., Kelsoe, J.R., Remick, R.A. et al. (1997) Linkage studies suggest a possible locus for bipolar disorder near the velo-cardio-facial syndrome region on chromosome 22. Am. J. Med. Genet., 74, 121–128. 99. Venter, J.C., Adams, M.D., Myers, E.W. et al. (2001) The sequence of the human genome. Science (New York, NY), 291, 1304–1351. 100. Gabriel, S.B., Schaffner, S.F., Nguyen, H. et al. (2002) The structure of haplotype blocks in the human genome. Science (New York, NY), 296, 2225–2229. 101. Park, B.V. (2003) Cancer Medicine, 6th edn, BC Decker, Lewiston NY. 102. Pierotti, M.A., Sozzi, G. and Croce, C.M. (2000) Oncogenes, BC Decker Inc., Hamilton, Ontario. 103. Feinberg, A.P. (2007) Phenotypic plasticity and the epigenetics of human disease. Nature, 447, 433–440. 104. Tsankova, N., Renthal, W., Kumar, A. and Nestler, E.J. (2007) Epigenetic regulation in psychiatric disorders. Nat. Rev. Neurosci., 8, 355–367. 105. Abecasis, G.R., Burt, R.A., Hall, D. et al. (2004) Genomewide scan in families with schizophrenia from the founder population of Afrikaners reveals evidence for linkage and uniparental disomy on chromosome 1. Am. J. Hum. Genet., 74, 403–417. 106. Blouin, J.L., Dombroski, B.A., Nath, S.K. et al. (1998) Schizophrenia susceptibility loci on chromosomes 13q32 and 8p21. Nat. Genet., 20, 70–73. 107. Brzustowicz, L.M., Honer, W.G., Chow, E.W. et al. (1999) Linkage of familial schizophrenia to chromosome 13q32. Am. J. Hum. Genet., 65, 1096–1103. 108. Camp, N.J., Neuhausen, S.L., Tiobech, J. et al. (2001) Genomewide multipoint linkage analysis of seven extended Palauan pedigrees with schizophrenia, by a Markov-chain Monte Carlo method. Am. J. Hum. Genet., 69, 1278–1289. 109. Cardno, A.G., Holmans, P.A., Rees, M.I. et al. (2001) A genomewide linkage study of age at onset in schizophrenia. Am. J. Med. Genet., 105, 439–445. 110. Faraone, S.V., Skol, A.D., Tsuang, D.W. et al. (2002) Linkage of chromosome 13q32 to schizophrenia in a large veterans affairs cooperative study sample. Am. J. Med. Genet., 114, 598–604. 111. Shaw, S.H., Kelly, M., Smith, A.B. et al. (1998) A genomewide search for schizophrenia susceptibility genes. Am. J. Med. Genet., 81, 364–376. 112. Wijsman, E.M., Rosenthal, E.A., Hall, D. et al. (2003) Genome-wide scan in a large complex pedigree with predominantly male schizophrenics from the island of Kosrae: evidence for linkage to chromosome 2q. Mol. Psychiatry, 8, 695–705, 643.
113. Chumakov, I., Blumenfeld, M., Guerassimenko, O. et al. (2002) Genetic and physiological data implicating the new human gene G72 and the gene for D-amino acid oxidase in schizophrenia. Proc. Natl. Acad. Sci. USA, 99, 13675–13680. 114. Stevens, E.R., Esguerra, M., Kim, P.M. et al. (2003) D-serine and serine racemase are present in the vertebrate retina and contribute to the physiological activation of NMDA receptors. Proc. Natl. Acad. Sci. USA, 100, 6789–6794. 115. Fallin, M.D., Lasseter, V.K., Avramopoulos, D. et al. (2005) Bipolar I disorder and schizophrenia: a 440-single-nucleotide polymorphism screen of 64 candidate genes among Ashkenazi Jewish case-parent trios. Am. J. Hum. Genet., 77, 918–936. 116. Schumacher, J., Jamra, R.A., Freudenberg, J. et al. (2004) Examination of G72 and D-amino-acid oxidase as genetic risk factors for schizophrenia and bipolar affective disorder. Mol. Psychiatry, 9, 203–207. 117. Williams, N.M., Green, E.K., Macgregor, S. et al. (2006) Variation at the DAOA/G30 locus influences susceptibility to major mood episodes but not psychosis in schizophrenia and bipolar disorder. Arch. Gen. Psychiatry, 63, 366–373. 118. Chen, Y.S., Akula, N., Detera-Wadleigh, S.D. et al. (2004) Findings in an independent sample support an association between bipolar affective disorder and the G72/G30 locus on chromosome 13q33. Mol. Psychiatry, 9, 87–92, image 85. 119. Hattori, E., Liu, C., Badner, J.A. et al. (2003) Polymorphisms at the G72/G30 gene locus, on 13q33, are associated with bipolar disorder in two independent pedigree series. Am. J. Hum. Genet., 72, 1131–1140. 120. Detera-Wadleigh, S.D. and McMahon, F.J. (2006) G72/G30 in schizophrenia and bipolar disorder: review and metaanalysis. Biol. Psychiatry, 60, 106–114. 121. Neves-Pereira, M., Mundo, E., Muglia, P. et al. (2002) The brain-derived neurotrophic factor gene confers susceptibility to bipolar disorder: evidence from a family-based association study. Am. J. Hum. Genet., 71, 651–655. 122. Sklar, P., Gabriel, S.B., McInnis, M.G. et al. (2002) Familybased association study of 76 candidate genes in bipolar disorder: BDNF is a potential risk locus. Brain-derived neutrophic factor. Mol. Psychiatry, 7, 579–593. 123. Lohoff, F.W., Sander, T., Ferraro, T.N. et al. (2005) Confirmation of association between the Val66Met polymorphism in the brain-derived neurotrophic factor (BDNF) gene and bipolar I disorder. Am. J. Med. Genet. B Neuropsychiatr. Genet., 139, 51–53. 124. Geller, B., Badner, J.A., Tillman, R. et al. (2004) Linkage disequilibrium of the brain-derived neurotrophic factor Val66Met polymorphism in children with a prepubertal and early adolescent bipolar disorder phenotype. Am. J. Psychiatry, 161, 1698–1700. 125. Strauss, J., Barr, C.L., George, C.J. et al. (2005) Brain-derived neurotrophic factor variants are associated with childhoodonset mood disorder: confirmation in a Hungarian sample. Mol. Psychiatry, 10, 861–867. 126. Strauss, J., Barr, C.L., George, C.J. et al. (2004) Association study of brain-derived neurotrophic factor in adults with a history of childhood onset mood disorder. Am. J. Med. Genet., 131B (1), 16–19.
Genetics of Bipolar Disorder 127. Green, E.K., Raybould, R., Macgregor, S. et al. (2006) Genetic variation of brain-derived neurotrophic factor (BDNF) in bipolar disorder: case-control study of over 3000 individuals from the UK. Br. J. Psychiatry, 188, 21–25. 128. Muller, D.J., de Luca, V., Sicard, T. et al. (2006) Brain-derived neurotrophic factor (BDNF) gene and rapid-cycling bipolar disorder: family-based association study. Br. J. Psychiatry, 189, 317–323. 129. Hong, C.J., Huo, S.J., Yen, F.C. et al. (2003) Association study of a brain-derived neurotrophic-factor genetic polymorphism and mood disorders, age of onset and suicidal behavior. Neuropsychobiology, 48, 186–189. 130. Kunugi, H., Iijima, Y., Tatsumi, M. et al. (2004) No association between the Val66Met polymorphism of the brainderived neurotrophic factor gene and bipolar disorder in a Japanese population: a multicenter study. Biol. Psychiatry, 56, 376–378. 131. Nakata, K., Ujike, H., Sakai, A. et al. (2003) Association study of the brain-derived neurotrophic factor (BDNF) gene with bipolar disorder. Neurosci. Lett., 337, 17–20. 132. Neves-Pereira, M., Cheung, J.K., Pasdar, A. et al. (2005) BDNF gene is a risk factor for schizophrenia in a Scottish population. Mol. Psychiatry, 10, 208–212. 133. Oswald, P., Del-Favero, J., Massat, I. et al. (2004) Nonreplication of the brain-derived neurotrophic factor (BDNF) association in bipolar affective disorder: a Belgian patientcontrol study. Am. J. Med. Genet., 129B, 34–35. 134. Skibinska, M., Hauser, J., Czerski, P.M. et al. (2004) Association analysis of brain-derived neurotrophic factor (BDNF) gene Val66Met polymorphism in schizophrenia and bipolar affective disorder. World J. Biol. Psychiatry, 5, 215–220. 135. Surtees, P.G., Wainwright, N.W., Willis-Owen, S.A. et al. (2007) No association between the BDNF Val66Met polymorphism and mood status in a non-clinical community sample of 7389 older adults. J. Psychiatr. Res., 41, 404–409. 136. Egan, M.F., Kojima, M., Callicott, J.H. et al. (2003) The BDNF val66met polymorphism affects activity-dependent secretion of BDNF and human memory and hippocampal function. Cell, 112, 257–269. 137. Hariri, A.R., Goldberg, T.E., Mattay, V.S. et al. (2003) Brainderived neurotrophic factor val66met polymorphism affects human memory-related hippocampal activity and predicts memory performance. J. Neurosci., 23, 6690–6694. 138. Rybakowski, J.K., Borkowska, A., Czerski, P.M. et al. (2003) Polymorphism of the brain-derived neurotrophic factor gene and performance on a cognitive prefrontal test in bipolar patients. Bipolar. Disord., 5, 468–472. 139. Rybakowski, J.K., Borkowska, A., Skibinska, M. and Hauser, J. (2006) Illness-specific association of val66met BDNF polymorphism with performance on Wisconsin Card Sorting Test in bipolar mood disorder. Mol. Psychiatry, 11, 122–124. 140. Rybakowski, J.K., Borkowska, A., Skibinska, M. et al. (2006) Prefrontal cognition in schizophrenia and bipolar illness in relation to Val66Met polymorphism of the brain-derived neurotrophic factor gene. Psychiatry Clin. Neurosci., 60, 70–76. 141. Bueller, J.A., Aftab, M., Sen, S. et al. (2006) BDNF Val66Met allele is associated with reduced hippocampal volume in healthy subjects. Biol. Psychiatry, 59, 812–815.
|
121
142. Tramontina, J., Frey, B.N., Andreazza, A.C. et al. (2007) Val66met polymorphism and serum brain-derived neurotrophic factor levels in bipolar disorder. Mol. Psychiatry, 12, 230–231. 143. Hashimoto, K., Shimizu, E. and Iyo, M. (2004) Critical role of brain-derived neurotrophic factor in mood disorders. Brain Res. Brain Res. Rev., 45, 104–114. 144. Post, R.M. (2007) Role of BDNF in bipolar and unipolar disorder: Clinical and theoretical implications. J. Psychiatr. Res., 41 (12), 979–999. 145. Lang, U.E., Hellweg, R. and Gallinat, J. (2004) BDNF serum concentrations in healthy volunteers are associated with depression-related personality traits. Neuropsychopharmacology, 29, 795–798. 146. Aydemir, O., Deveci, A. and Taneli, F. (2005) The effect of chronic antidepressant treatment on serum brain-derived neurotrophic factor levels in depressed patients: a preliminary study. Prog. Neuropsychopharmacol. Biol. Psychiatry, 29, 261–265. 147. Gonul, A.S., Akdeniz, F., Taneli, F. et al. (2005) Effect of treatment on serum brain-derived neurotrophic factor levels in depressed patients. Eur. Arch. Psy. Clin. N., 255, 381–386. 148. Karege, F., Perret, G., Bondolfi, G. et al. (2002) Decreased serum brain-derived neurotrophic factor levels in major depressed patients. Psychiatry Res., 109, 143–148. 149. Shimizu, E., Hashimoto, K., Okamura, N. et al. (2003) Alterations of serum levels of brain-derived neurotrophic factor (BDNF) in depressed patients with or without antidepressants. Biol. Psychiatry, 54, 70–75. 150. Knable, M.B., Barci, B.M., Webster, M.J. et al. (2004) Molecular abnormalities of the hippocampus in severe psychiatric illness: postmortem findings from the Stanley Neuropathology Consortium. Mol. Psychiatry, 9, 609–620, 544. 151. Fukumoto, T., Morinobu, S., Okamoto, Y. et al. (2001) Chronic lithium treatment increases the expression of brain-derived neurotrophic factor in the rat brain. Psychopharmacology (Berl.), 158, 100–106. 152. Hashimoto, R., Takei, N., Shimazu, K. et al. (2002) Lithium induces brain-derived neurotrophic factor and activates TrkB in rodent cortical neurons: an essential step for neuroprotection against glutamate excitotoxicity. Neuropharmacology, 43, 1173–1179. 153. Nibuya, M., Morinobu, S. and Duman, R.S. (1995) Regulation of BDNF and trkB mRNA in rat brain by chronic electroconvulsive seizure and antidepressant drug treatments. J. Neurosci., 15, 7539–7547. 154. Shirayama, Y., Chen, A.C., Nakagawa, S. et al. (2002) Brainderived neurotrophic factor produces antidepressant effects in behavioral models of depression. J. Neurosci., 22, 3251–3261. 155. Siuciak, J.A., Lewis, D.R., Wiegand, S.J. and Lindsay, R.M. (1997) Antidepressant-like effect of brain-derived neurotrophic factor (BDNF). Pharmacol. Biochem. Behav., 56, 131–137. 156. Craddock, N., Daniels, J., Roberts, E. et al. (1995) No evidence for allelic association between bipolar disorder and monoamine oxidase A gene polymorphisms. Am. J. Med. Genet., 60, 322–324.
122
|
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157. Furlong, R.A., Ho, L., Rubinsztein, J.S. et al. (1999) Analysis of the monoamine oxidase A (MAOA) gene in bipolar affective disorder by association studies, meta-analyses, and sequencing of the promoter. Am. J. Med. Genet., 88, 398–406. 158. Lim, L.C., Powell, J., Sham, P. et al. (1995) Evidence for a genetic association between alleles of monoamine oxidase A gene and bipolar affective disorder. Am. J. Med. Genet., 60, 325–331. 159. Muller, D.J., Serretti, A., Sicard, T. et al. (2007) Further evidence of MAO-A gene variants associated with bipolar disorder. Am. J. Med. Genet. B Neuropsychiatr. Genet., 144, 37–40. 160. Nothen, M.M., Eggermann, K., Albus, M. et al. (1995) Association analysis of the monoamine oxidase A gene in bipolar affective disorder by using family-based internal controls. Am. J. Hum. Genet., 57, 975–978. 161. Parsian, A. and Todd, R.D. (1997) Genetic association between monoamine oxidase and manic-depressive illness: comparison of relative risk and haplotype relative risk data. Am. J. Med. Genet., 74, 475–479. 162. Preisig, M., Bellivier, F., Fenton, B.T. et al. (2000) Association between bipolar disorder and monoamine oxidase A gene polymorphisms: results of a multicenter study. Am. J. Psychiatry, 157, 948–955. 163. Serretti, A., Cristina, S., Lilli, R. et al. (2002) Family-based association study of 5-HTTLPR, TPH, MAO-A, and DRD4 polymorphisms in mood disorders. Am. J. Med. Genet., 114, 361–369. 164. Syagailo, Y.V., Stober, G., Grassle, M. et al. (2001) Association analysis of the functional monoamine oxidase A gene promoter polymorphism in psychiatric disorders. Am. J. Med. Genet., 105, 168–171. 165. Turecki, G., Grof, P., Cavazzoni, P. et al. (1999) MAOA: association and linkage studies with lithium responsive bipolar disorder. Psychiatr. Genet., 9, 13–16. 166. Kawada, Y., Hattori, M., Dai, X.Y. and Nanko, S. (1995) Possible association between monoamine oxidase A gene and bipolar affective disorder. Am. J. Hum. Genet., 56, 335–336. 167. Kunugi, H., Ishida, S., Kato, T. et al. (1999) A functional polymorphism in the promoter region of monoamine oxidase-A gene and mood disorders. Mol. Psychiatry, 4, 393–395. 168. Muramatsu, T., Matsushita, S., Kanba, S. et al. (1997) Monoamine oxidase genes polymorphisms and mood disorder. Am. J. Med. Genet., 74, 494–496. 169. Deckert, J., Catalano, M., Syagailo, Y.V. et al. (1999) Excess of high activity monoamine oxidase A gene promoter alleles in female patients with panic disorder. Hum. Mol. Genet., 8, 621–624. 170. Gutierrez, B., Arias, B., Gasto, C. et al. (2004) Association analysis between a functional polymorphism in the monoamine oxidase A gene promoter and severe mood disorders. Psychiatr. Genet., 14, 203–208. 171. Lin, S., Jiang, S., Wu, X. et al. (2000) Association analysis between mood disorder and monoamine oxidase gene. Am. J. Med. Genet., 96, 12–14.
172. Schulze, T.G., Muller, D.J., Krauss, H. et al. (2000) Association between a functional polymorphism in the monoamine oxidase A gene promoter and major depressive disorder. Am. J. Med. Genet., 96, 801–803. 173. Ramamoorthy, S., Bauman, A.L., Moore, K.R. et al. (1993) Antidepressant- and cocaine-sensitive human serotonin transporter: molecular cloning, expression, and chromosomal localization. Proc. Natl. Acad. Sci. USA, 90, 2542–2546. 174. Collier, D.A., Stober, G., Li, T. et al. (1996) A novel functional polymorphism within the promoter of the serotonin transporter gene: possible role in susceptibility to affective disorders. Mol. Psychiatry, 1, 453–460. 175. Heils, A., Teufel, A., Petri, S. et al. (1996) Allelic variation of human serotonin transporter gene expression. J. Neurochem., 66, 2621–2624. 176. Lesch, K.P., Bengel, D., Heils, A. et al. (1996) Association of anxiety-related traits with a polymorphism in the serotonin transporter gene regulatory region. Science (New York, NY), 274, 1527–1531. 177. Fiskerstrand, C.E., Lovejoy, E.A. and Quinn, J.P. (1999) An intronic polymorphic domain often associated with susceptibility to affective disorders has allele dependent differential enhancer activity in embryonic stem cells. FEBS Lett., 458, 171–174. 178. Collier, D.A., Arranz, M.J., Sham, P. et al. (1996) The serotonin transporter is a potential susceptibility factor for bipolar affective disorder. Neuroreport, 7, 1675–1679. 179. Bellivier, F., Henry, C., Szoke, A. et al. (1998) Serotonin transporter gene polymorphisms in patients with unipolar or bipolar depression. Neurosci. Lett., 255, 143–146. 180. Kunugi, H., Hattori, M., Kato, T. et al. (1997) Serotonin transporter gene polymorphisms: ethnic difference and possible association with bipolar affective disorder. Mol. Psychiatry, 2, 457–462. 181. Mynett-Johnson, L., Kealey, C., Claffey, E. et al. (2000) Multimarkerhaplotypes within the serotonin transporter gene suggest evidence of an association with bipolar disorder. Am. J. Med. Genet., 96, 845–849. 182. Rees, M., Norton, N., Jones, I. et al. (1997) Association studies of bipolar disorder at the human serotonin transporter gene (hSERT; 5HTT). Mol. Psychiatry, 2, 398–402. 183. Vincent, J.B., Masellis, M., Lawrence, J. et al. (1999) Genetic association analysis of serotonin system genes in bipolar affective disorder. Am. J. Psychiatry, 156, 136–138. 184. Bellivier, F., Laplanche, J.L., Leboyer, M. et al. (1997) Serotonin transporter gene and manic depressive illness: an association study. Biol. Psychiatry, 41, 750–752. 185. Bocchetta, A., Piccardi, M.P., Palmas, M.A. et al. (1999) Family-based association study between bipolar disorder and DRD2, DRD4, DAT, and SERT in Sardinia. Am. J. Med. Genet., 88, 522–526. 186. Gutierrez, B., Arranz, M.J., Collier, D.A. et al. (1998) Serotonin transporter gene and risk for bipolar affective disorder: an association study in Spanish population. Biol. Psychiatry, 43, 843–847. 187. Hoehe, M.R., Wendel, B., Grunewald, I. et al. (1998) Serotonin transporter (5-HTT) gene polymorphisms are not
Genetics of Bipolar Disorder
188.
189.
190.
191.
192.
193.
194.
195.
196.
197.
198.
199. 200.
associated with susceptibility to mood disorders. Am. J. Med. Genet., 81, 1–3. Ikeda, M., Iwata, N., Suzuki, T. et al. (2006) No association of serotonin transporter gene (SLC6A4) with schizophrenia and bipolar disorder in Japanese patients: association analysis based on linkage disequilibrium. J. Neural. Transm., 113, 899–905. Kirov, G., Rees, M., Jones, I. et al. (1999) Bipolar disorder and the serotonin transporter gene: a family-based association study. Psychol. Med., 29, 1249–1254. Kunugi, H., Tatsumi, M., Sakai, T. et al. (1996) Serotonin transporter gene polymorphism and affective disorder. Lancet, 347, 1340. Mendlewicz, J., Massat, I., Souery, D. et al. (2004) Serotonin transporter 5HTTLPR polymorphism and affective disorders: no evidence of association in a large European multicenter study. Eur. J. Hum. Genet., 12, 377–382. Oliveira, J.R., Carvalho, D.R., Pontual, D. et al. (2000) Analysis of the serotonin transporter polymorphism (5-HTTLPR) in Brazilian patients affected by dysthymia, major depression and bipolar disorder. Mol. Psychiatry., 5, 348–349. Ospina-Duque, J., Duque, C., Carvajal-Carmona, L. et al. (2000) An association study of bipolar mood disorder (type I) with the 5-HTTLPR serotonin transporter polymorphism in a human population isolate from Colombia. Neurosci. Lett., 292, 199–202. Saleem, Q., Ganesh, S., Vijaykumar, M. et al. (2000) Association analysis of 5HT transporter gene in bipolar disorder in the Indian population. Am. J. Med. Genet., 96, 170–172. Furlong, R.A., Ho, L., Walsh, C. et al. (1998) Analysis and meta-analysis of two serotonin transporter gene polymorphisms in bipolar and unipolar affective disorders. Am. J. Med. Genet., 81, 58–63. Cho, H.J., Meira-Lima, I., Cordeiro, Q. et al. (2005) Population-based and family-based studies on the serotonin transporter gene polymorphisms and bipolar disorder: a systematic review and meta-analysis. Mol. Psychiatry, 10, 771–781. Lasky-Su, J.A., Faraone, S.V., Glatt, S.J. and Tsuang, M.T. (2005) Meta-analysis of the association between two polymorphisms in the serotonin transporter gene and affective disorders. Am. J. Med. Genet. B Neuropsychiatr. Genet., 133, 110–115. Willis-Owen, S.A., Turri, M.G., Munafo, M.R. et al. (2005) The serotonin transporter length polymorphism, neuroticism, and depression: a comprehensive assessment of association. Biol. Psychiatry, 58, 451–456. Craddock, N. and Forty, L. (2006) Genetics of affective (mood) disorders. Eur. J. Hum. Genet., 14, 660–668. Hayden, E.P. and Nurnberger, J.I. (2006) Molecular genetics of bipolar disorder. Genes, Brain Behav., 5, 85–95. doi: 10.1111/j.1601-183X.2005.00138.x
|
123
201. Frayling, T.M. (2007) Genome-wide association studies provide new insights into type 2 diabetes aetiology. Nat. Rev. Genet., 8, 657–662. 202. Orr, N. and Chanock, S. (2008) Common genetic variation and human disease. Adv. Genet., 62, 1–32. 203. Clark, A.G., Boerwinkle, E., Hixson, J. and Sing, C.F. (2005) Determinants of the success of whole-genome association testing. Genome Res. %R 101101/gr4244005, 15, 1463–1467. 204. Jorgenson, E. and Witte, J.S. (2006) A gene-centric approach to genome-wide association studies. Nat. Rev. Genet., 7, 885–891. 205. Baum, A.E., Akula, N., Cabanero, M. et al. (2008) A genomewide association study implicates diacylglycerol kinase eta (DGKH) and several other genes in the etiology of bipolar disorder. Mol. Psychiatry, 13, 197–207. 206. Sklar, P., Smoller, J.W., Fan, J. et al. (2008) Whole-genome association study of bipolar disorder. Mol. Psychiatry, 13, 558–569. 207. Ferreira, M.A., ODonovan, M.C., Meng, Y.A. et al. (2008) Collaborative genome-wide association analysis supports a role for ANK3 and CACNA1C in bipolar disorder. Nat. Genet., 40, 1056–1058. 208. Altshuler, D. and Daly, M. (2007) Guilt beyond a reasonable doubt. Nat. Genet, 39, 813–815. 209. Chanock, S.J., Manolio, T., Boehnke, M. et al. (2007) Replicating genotype-phenotype associations. Nature, 447, 655–660. 210. Smith E.N., Bloss C.S., Nievergelt C. et al. (2009) Genomewide association of bipolar disorder in European American and African American individuals. Mol. Psychiatry, 14, 755–763; PMID: 19488044. 211. Schulze, T.G., Detera-Wadleigh, S.D., Akula, N. et al. (2008) Two variants in Ankyrin 3 (ANK3) are independent genetic risk factors for bipolar disorder. Mol. Psychiatry., 14 (5), 487–491. 212. Kordeli, E., Lambert, S. and Bennett, V. (1995) AnkyrinG. A new ankyrin gene with neural-specific isoforms localized at the axonal initial segment and node of Ranvier. J. Biol. Chem., 270, 2352–2359. 213. Liu, L., Foroud, T., Xuei, X., et al. (2008) Evidence of association between brain-derived neurotrophic factor (BDNF) gene and bipolar disorder. Psych. Gen., 18, 267–74, PMID: 19018231. 214. Risch, N. and Merikangas, K. (1996) The future of genetic studies of complex human diseases. Science, 273, 1516–1517. 215. Wellcome Trust Case Control Consortium (2007) Genomewide association study of 14,000 cases of seven common diseases and 3000 shared controls. Nature, 447(7145), 661–678. 216. Schulze, T.G., Detera-Wadleigh, S.D., Akula, N. et al. (2009) NIMH Genetics Initiative Bipolar Disorder Consortium. In: Rietschel, M. and McMahon, F.J. Two variants in Ankyrin 3 (ANK3) are independent genetic risk factors for bipolar disorder. Mol. Psych., 14, 487–491.
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Structural Brain Imaging in Bipolar Disorder Paolo Brambilla1,2 and Jair C. Soares3 1
Inter-University Center for Behavioural Neurosciences, Department of Pathology and Experimental and Clinical Medicine, Section of Psychiatry, University of Udine, Udine, Italy
2
Scientific Institute, IRCCS E. Medea, Udine, Italy Department of Psychiatry and Behavioral Sciences, UT Houston Medical School, Houston, TX, USA
3
Brain imaging studies, specifically with magnetic resonance imaging (MRI), have tried in the last two decades to elucidate the anatomy of bipolar disorder, which is a severe lifelong illness that typically begins in adolescence. Recently, this research has also focused on juvenile-onset bipolar disorder, which is considered a more severe phenotype of the illness [1]. In this chapter, the most consistent findings from structural MRI studies in adult and paediatric bipolar disorder have been reviewed, suggesting future strategies for investigations in this field.
Prefrontal cortex The prefrontal cortex includes three main regions involved in the regulation of cognition and emotions, that is the anterior cingulate, the dorsolateral prefrontal cortex (DLPFC) and the orbitofrontal cortex (OFC) [2,3]. The anterior cingulate (Brodmanns areas 24, 25, 33) lies between the corpus callosum and the cingulate sulcus [4] and has extensive connections with the amygdala, insula, thalamus and OFC, which also play a role in emotional processing [5,6]. A sub-region of the anterior cingulate called the subgenual prefrontal cortex (SGPFC) (Broadman area 24) is situated ventral to the genu of the corpus callosum and plays a main role in modulating decision making/planning and mood [7,8]. The DLPFC (Broadmann areas 9 and 46) is connected with higher-order association centres in the temporal and parietal lobe and participates in working memory and executive functions [9,10]. Finally, the OFC consists of the ventral-most regions of the prefrontal cortex, extending from the anterior perforated substance to the frontal pole.
Anterior cingulate Abnormally reduced volume [11,12] and grey matter density [13,14] of anterior cingulate cortex, especially in the left
side, have been reported in bipolar patients, including first-episode manic [15] and paediatric [16–18] samples. Interestingly, grey-matter loss over time in anterior cingulate and in the SGPFC has recently been identified in adult [19,20] and juvenile bipolar disorder patients [21]. Also, loss of volume and macromolecular density of the SGPFC have been shown in bipolar patients, particularly in those with a family history of affective illness [22–25], although normal size has been reported in both adult and paediatric patients [26,27]. In addition, post-mortem studies demonstrated synaptic abnormalities [28] and decrease in neural [29,30] and glial density [31] in anterior cingulate in bipolar disorder. Consistent findings support the hypothesis of impaired dysfunction of cingulate neural circuits in bipolar illness, potentially sustaining impairment in executive functions [32,33].
Dorsolateral prefrontal cortex A couple of studies found areas encompassing the DLPFC that were significantly smaller in bipolar disorder patients compared to healthy subjects [34,35]. Such abnormalities have been reported. particularly in the left side and in male patients, even in paediatric samples [36] and may be associated with genetic variability of the interleukin-1 beta gene [37]. Pathology of glial and neuronal size and density and decreased N-acetyl aspartate (NAA) levels have also been shown in the DLPFC of bipolar patients [38–41]. In addition, DLPFC stimulation with transcranial magnetic stimulation appeared to be effective in treating refractory depression in individuals with bipolar disorder [42]. These findings suggest that DLPFC neuroplasticity and cellular resilience may be impaired in bipolar disorder [43].
Orbitofrontal cortex Bipolar Disorder: Clinical and Neurobiological Foundations Edited by Lakshmi N. Yatham and Mario Maj © 2010 John Wiley & Sons, Ltd. ISBN: 978-0-470-72198-8
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Smaller grey matter OFC volumes have been shown in adult and adolescent bipolar disorder patients in comparison to healthy controls [18,44], particularly in
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males [45]. Hypoactivation of the OFC has also been shown in bipolar patients when performing activities involving attention, inhibition and emotional processing [46–48]. This literature suggests that the OFC may be involved in disinhibition and impulsivity in bipolar disorder, considering its role in regulating impulse control and rewardguided behaviour [49,50].
Ventricles Two recent meta-analyses reported that the most consistent structural finding in bipolar disorder was the enlargement of lateral ventricles [51,52]. This correlates with prior number of affective episodes [53,54] and may characterize chronic patients, representing a sign of cortical atrophy [53]. However, several others did not find evidence of size abnormalities for either third or lateral ventricles [54–68].
Limbic structures Hippocampus The declarative memory, involving the conscious recollection, verbal reflection and explicit expression of facts and events is primarily supported by the hippocampus [69,70], which also plays a major role converting short- into longlasting memory, a process called memory consolidation. Also, a neural circuitry involving amygdala, OFC, anterior cingulate and hippocampus is crucial in information processing and in creation of emotional memories [71]. Impairment of declarative memory has been shown in bipolar disorder, even during euthymia [72,73], supporting the role of hippocampal alterations in impaired cognition. Although there is one report of right hemisphere hippocampal volume reduction in bipolar patients [74], the majority of studies of patients with bipolar disorder and matched healthy comparison subjects did not find evidence for changes in hippocampal size [53,58,75–80]. Decreased size and accelerated grey matter decline of the hippocampus have been reported in adults with bipolar disorder [74,81–83], particularly in those carrying the met allele of the val-66-met single nucleotide polymorphism (SNP) in the brain-derived neurotrophic factor (BDNF) gene [84]. Such deficits are illustrated by magnetic resonance spectroscopy (1HMRS) studies showing reduced NAA levels [85–87] and increased glutamate concentrations in the hippocampus of adult bipolar patients [88]. Moreover, some [89,90], but not all structural MRI studies [91,92], showed hippocampal atrophy in paediatric samples, predominantly in the subicular region [93]. Hypothetically, dendritic/synaptic maldevelopment or neural degeneration may take place in the bipolar brain. However, other structural MRI studies and meta-analyses reported preserved hippocampal volumes, at least in adult
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patients [52,53,76,94,95]. Discrepancies amongst the studies in adults may in part be explained by the fact that most studies focused on global hippocampus volumes and may not be able to identify differences in specific subregions, which have different developmental trajectories, cortical connections and behavioural functions [96]. Also, there is the possibility that hippocampal deficits shown in juvenile bipolar disorder may be reversed in adult patients by longterm exposure to medications, in particular to lithium [51].
Amygdala The most consistent finding in volumetric analysis of bipolar disorder patients is amygdala enlargement [76,80,97]. However, smaller [78] and normal amygdala size [74] have also been reported. Findings of enlargement of the amygdala are consistent with findings of increased cerebral blood flow and glucose metabolism in this brain structure in bipolar patients [98]. Reports of smaller amygdala volumes in children and adolescents with bipolar disorder have also been published [89,92,99]. Moreover, a direct relationship between age and left amygdala volumes was found in juvenile bipolar patients, whereas in matched healthy controls there was an inverse correlation [92]. Theoretically, abnormal pruning mechanisms in childhood and adolescence could lead to findings of enlargement in adulthood in bipolar disorder patients. Alternatively, compensatory mechanisms might be operating over time and be responsible for the anatomical changes in adulthood. Several authors have proposed that enlargement of the amygdala may represent a trait marker for bipolar disorder; however, longitudinal MR studies in childhood-onset patients and high-risk populations are needed to further characterize amygdala development in bipolar disorder. The amygdala is considered the site where emotional memory or memory for emotionally arousing events are formed and stored and is involved in processing fear and emotion in humans [100]. For this purpose, it receives input from the fronto-temporal lobes, and sends information to hippocampus, enthorinal cortex, thalamus and neocortex [101]. The amygdala is therefore believed to be a key region for the pathophysiology of bipolar disorder [102], as confirmed by several studies showing abnormally increased volumes in adult bipolar disorder patients [76,80,97]. In contrast, in paediatric patients, decreases in amygdala size have been reported [36,91,92], with an abnormal direct correlation with age [92]. In this regard, in adult bipolar patients a recent study showed a reduction of amygdala volume with age, which was not present in controls [103]. Therefore, there may be an altered developmental trajectory of the amygdala in bipolar disorder, with larger volumes in adulthood potentially resulting from abnormal neuronal pruning during childhood and adolescence. Alternatively, the neuroprotective effects of
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lithium may in part explain such anatomical changes over time [91,104].
Subcortical structures Thalamus The thalamus is a relay station between cortical and subcortical brain regions, crucial for both motor and cognitive coordination. The thalamus can be divided into multiple subnuclei with different patterns of connections [105–107]. The anterior nuclei is prominently connected with the hippocampus and cingulate gyrus, the mediodorsal nucleus is the main subcortical afferent to the prefrontal cortex, and the dorsomedial nucleus is a major site for serotonergic neurotransmission [108–110]. Some, but not all studies [53,111–114] showed significant thalamic enlargement in bipolar patients [44,80,115], even in first-episode [116]. Few studies examined thalamic size in children and adolescents with bipolar disorder, reporting smaller [117], larger [18,118] and normal size [119]. Inconsistent findings for or against changes in thalamic morphology in bipolar disorder suggests that there is no effect or that the magnitude of the effect size is very small. Future studies with larger samples including individuals across the lifespan may help to explain findings. Also, reliable methods should be developed to determine the size of specific thalamic nuclei.
Corpus callosum The corpus callosum represents the major midline white matter structure connecting the two cerebral hemispheres. It allows inter-hemispheric communication and participates in regulating attention, language and memory [127,128] and increases in size into late adolescence, primarily due to myelination [129,130]. Decreased area/length and impaired signal intensity of the corpus callosum, which is considered a marker of myelination, have been reported in adult bipolar disorder [131–134], as also confirmed by a recent metaanalysis [135]. Furthermore, abnormalities in signal intensity [136], as well as in splenium circularity [137], have been shown in the paediatric population, particularly in males. Circularity is a measure of splenium shape and may be a sign of poor brain maturation. In fact, significant correlation between callosal size and gestational age [138], mostly related to cortical thinning, have been found in the splenium of adolescents who were born prematurely. Taken together, these results suggest that there may a callosal maldevelopment in bipolar disorder patients during adolescence, potentially leading to decrease white matter density in adulthood. Future studies should longitudinally follow a single cohort to identify the development cascade of the corpus callosum in bipolar disorder and to investigate the relationship with the speed and quantity of inter-hemispheric communication.
Cerebellum and vermis Basal ganglia The basal ganglia include the caudate, putamen and globus pallidus, which are structures important for motor and emotional functions. They are connected to cortical and limbic regions by two parallel circuits, and disruption of different nodes in this circuit could result in dysregulation of affective state or mood regulation [120,121]. Larger striatal volumes (i.e. caudate and putamen) have been found in adult [53,80,122,123] and adolescent [18,99,124] bipolar patients type I, compared to healthy subjects and in bipolar twins compared to normal monozygotic twins in a small study [83]. Interestingly, duration of illness was associated with reduced volume in the lenticular nuclei (i.e. putamen and globus pallidus), particularly in bipolar disorder type I, in one study [125], but most investigations have not shown any significant differences in measures of caudate, putamen or lenticular nuclei between bipolar patients and healthy controls [57,112,114,115,125], even in adolescent patients [126]. Although conflicting, the available results suggest an important role for the basal ganglia in the pathophysiology of bipolar disorder, in particular in type I patients. Future longitudinal MRI studies should examine basal ganglia over time, in samples of bipolar I and bipolar II patients, to provide more definitive answers.
The cerebellum has extensive connections with limbic areas and cortical associative areas, supporting its role, along with the vermis, in integrating superior cognitive activities, in regulating language and in modulating mood [139–141]. Abnormally small cerebellum and vermis in bipolar patients have been shown by several [68,142–146], although not all studies [54,55,147]. In particular, those patients with higher numbers of affective episodes seem to have reduced posterior (i.e. limbic cerebellum) and flocculonodular vermis [54,142,148,149], suggesting that the cerebellar vermis may undergo atrophy during the course of bipolar illness due to neurodegenerative consequence of repeated illness episodes. However, further imaging and post-mortem studies are needed to clarify the role of cerebellum and vermis in bipolar disorder.
Conclusions Consistent structural abnormalities have been shown in bipolar disorder, particularly in anterior cingulate, hippocampus, amygdala and corpus callosum, which are all involved in mood and cognitive regulation in humans. Abnormalities in this anterior-limbic network may result in the expression of bipolar disorder by affecting inter- and
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intra-hemispheric connectivity. In terms of pathogenesis, it is still unclear whether neurodevelopment and neurodegeneration act separately or together in a unitary model of the disease. To this regard, there is evidence that neurodegenerative processes of anterior cingulate, SGPFC and hippocampus may take place over time, potentially in relation with multiple affective episodes. Hypothetically, excessive neuronal pruning/apoptosis during childhood and adolescence may subsequently be followed by neurotoxic mechanisms leading to impaired neuroplasticity and cellular resilience during the progression of the disease. However, current structural imaging studies in bipolar disorder have extensive heterogeneity, include underpowered sample size, and have appreciable chance of making type I and II errors, as pointed out by a couple of recent metaanalyses [51,52]. Also, other confounding variables, such as clinical status, medications and cross-sectional design, limit the available studies. Therefore, it is not yet known whether the reported structural changes reflect abnormal development, the disease process itself or medication exposure. In this perspective, to determine the role of these factors on brain anatomy, future longitudinal studies should follow large samples of first-episode drug-free bipolar patients, paediatric samples and subjects at high risk for the disease. Such studies will be instrumental to systematically examine the role of maldevelopment and neurodegeneration and to minimize potential confounding factors commonly found in adult samples, such as longterm medication effects, chronicity and hospitalizations. Furthermore, future studies should investigate the role of hormones on brain anatomy in bipolar patients, since androgen effects during puberty may have a different impact in males and females. Specifically, male patients seem to have increased vulnerability for developing DLPFC, OFC and corpus callosum deficits, which may be caused by neurotoxic processes driven by testosterone [150]. In fact, neuroprotective effects of oestrogen and progesterone, such as antioxidant action, diminishing of neuroexcitation and stabilization of cell membranes, have been shown [151,152]. Again, the longitudinal recruitment of pre-pubertal bipolar patients would be crucial to explore this issue, since hormonal brain maturation processes are particularly pronounced during adolescence. Indeed, an earlier illness onset, such as in juvenile bipolar patients, may provide a unique opportunity to investigate ongoing brain maturation and attempt to disentangle the impact of neurodevelopmental versus neurodegenerative factors in the pathophysiology of this condition. Finally, the impact of gene-environment interactions on brain development in patients with bipolar disorder remains to be clarified. In this perspective, imaging studies associated with neuropsychological, genetic and post-mortem studies will be extremely valuable to separate state from trait brain abnormalities and to further characterize the genetic/environmental determinants, the
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neuropathological underpinnings and the cognitive disturbances present in bipolar patients.
Acknowledgements Dr Brambilla was partly supported by grants from the American Psychiatric Institute for Research and Education (APIRE Young Minds in Psychiatry Award); the Italian Ministry for University and Research and the Italian Ministry of Health (IRCCS E. Medea). Dr Soares supported by NIH grants MH 068766, MH 69774, RR 020571.
References 1. DelBello, M.P., Adler, C.M. and Strakowski, S.M. (2006) The neurophysiology of childhood and adolescent bipolar disorder. CNS Spectr., 11, 298–311. 2. Gray, J.R., Braver, T.S. and Raichle, M.E. (2002) Integration of emotion and cognition in the lateral prefrontal cortex. Proc. Natl. Acad. Sci. USA, 99, 4115–4120. 3. Teasdale, J.D., Howard, R.J., Cox, S.G. et al. (1999) Functional MRI study of the cognitive generation of affect. Am. J. Psychiatry, 156, 209–215. 4. Vogt, B.A., Berger, G.R. and Derbyshire, S.W. (2003) Structural and functional dichotomy of human midcingulate cortex. Eur. J. Neurosci., 18, 3134–3144. 5. Barbas, H. (2000) Connections underlying the synthesis of cognition, memory, and emotion in primate prefrontal cortices. Brain. Res. Bull., 52, 319–330. 6. Lane, R.D., Reiman, E.M., Axelrod, B. et al. (1998) Neural correlates of levels of emotional awareness. Evidence of an interaction between emotion and attention in the anterior cingulate cortex. J. Cogn. Neurosci., 10, 525–535. 7. Drevets, W.C., Ongur, D. and Price, J.L. (1998) Neuroimaging abnormalities in the subgenual prefrontal cortex: implications for the pathophysiology of familial mood disorders. Mol. Psychiatry, 3, 220–226, 190–221. 8. Vogt, B.A., Nimchinsky, E.A., Vogt, L.J. and Hof, P.R. (1995) Human cingulate cortex: surface features, flat maps, and cytoarchitecture. J. Comp. Neurol., 359, 490–506. 9. Cabeza, R. and Nyberg, L. (2000) Imaging cognition II: An empirical review of 275 PET and fMRI studies. J. Cogn. Neurosci., 12, 1–47. 10. Smith, E.E. and Jonides, J. (1999) Storage and executive processes in the frontal lobes. Science, 283, 1657–1661. 11. Lochhead, R.A., Parsey, R.V., Oquendo, M.A. and Mann, J.J. (2004) Regional brain gray matter volume differences in patients with bipolar disorder as assessed by optimized voxel-based morphometry. Biol. Psychiatry, 55, 1154–1162. 12. Sassi, R.B., Brambilla, P., Hatch, J.P. et al. (2004) Reduced left anterior cingulate volumes in untreated bipolar patients. Biol. Psychiatry, 56, 467–475. 13. Doris, A., Belton, E., Ebmeier, K.P. et al. (2004) Reduction of cingulate gray matter density in poor outcome bipolar illness. Psychiatry Res., 130, 153–159.
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|
Chapter 13
14. Lyoo, I.K., Kim, M.J., Stoll, A.L. et al. (2004) Frontal lobe gray matter density decreases in bipolar I disorder. Biol. Psychiatry, 55, 648–651. 15. Yatham, L.N., Lyoo, I.K., Liddle, P. et al. (2007) A magnetic resonance imaging study of mood stabilizer- and neuroleptic-naive first-episode mania. Bipolar Disord., 9, 693–697. 16. Chiu, S., Widjaja, F., Bates, M.E. et al. (2008) Anterior cingulate volume in pediatric bipolar disorder and autism. J. Affect. Disord., 105, 93–99. 17. Kaur, S., Sassi, R.B., Axelson, D. et al. (2005) Cingulate cortex anatomical abnormalities in children and adolescents with bipolar disorder. Am. J. Psychiatry, 162, 1637–1643. 18. Wilke, M., Kowatch, R.A., DelBello, M.P. et al. (2004) Voxelbased morphometry in adolescents with bipolar disorder: first results. Psychiatry Res., 131, 57–69. 19. Farrow, T.F., Whitford, T.J., Williams, L.M. et al. (2005) Diagnosis-related regional gray matter loss over two years in first episode schizophrenia and bipolar disorder. Biol. Psychiatry, 58, 713–723. 20. Koo, M.S., Levitt, J.J., Salisbury, D.F. et al. (2008) A crosssectional and longitudinal magnetic resonance imaging study of cingulate gyrus gray matter volume abnormalities in first-episode schizophrenia and first-episode affective psychosis. Arch. Gen. Psychiatry, 65, 746–760. 21. Gogtay, N., Ordonez, A., Herman, D.H. et al. (2007) Dynamic mapping of cortical development before and after the onset of pediatric bipolar illness. J. Child Psychol. Psychiatry, 48, 852–862. 22. Drevets, W.C., Price, J.L., Simpson, J.R. Jr et al. (1997) Subgenual prefrontal cortex abnormalities in mood disorders [see comments]. Nature, 386, 824–827. 23. Hirayasu, Y., Shenton, M.E., Salisbury, D.F. et al. (1999) Subgenual cingulate cortex volume in first-episode psychosis [In Process Citation]. Am. J. Psychiatry, 156, 1091–1093. 24. Sharma, V., Menon, R., Carr, T.J. et al. (2003) An MRI study of subgenual prefrontal cortex in patients with familial and non-familial bipolar I disorder. J. Affect. Disord., 77, 167–171. 25. Bruno, S.D., Barker, G.J., Cercignani, M. et al. (2004) A study of bipolar disorder using magnetization transfer imaging and voxel-based morphometry. Brain, 127, 2433–2440. 26. Brambilla, P., Nicoletti, M.A., Harenski, K. et al. (2002) Anatomical MRI study of subgenual prefrontal cortex in bipolar and unipolar subjects. Neuropsychopharmacology, 27, 792–799. 27. Sanches, M., Sassi, R.B., Axelson, D. et al. (2005) Subgenual prefrontal cortex of child and adolescent bipolar patients: a morphometric magnetic resonance imaging study. Psychiatry Res., 138, 43–49. 28. Eastwood, S.L. and Harrison, P.J. (2001) Synaptic pathology in the anterior cingulate cortex in schizophrenia and mood disorders. A review and a Western blot study of synaptophysin, GAP-43 and the complexins. Brain Res. Bull., 55, 569–578. 29. Benes, F.M., Vincent, S.L. and Todtenkopf, M. (2001) The density of pyramidal and nonpyramidal neurons in anterior cingulate cortex of schizophrenic and bipolar subjects. Biol. Psychiatry, 50, 395–406.
30. Bouras, C., Kovari, E., Hof, P.R. et al. (2001) Anterior cingulate cortex pathology in schizophrenia and bipolar disorder. Acta Neuropathol. (Berl.), 102, 373–379. 31. Ongur, D., Drevets, W.C. and Price, J.L. (1998) Glial reduction in the subgenual prefrontal cortex in mood disorders. Proc. Natl. Acad. Sci. USA, 95, 13290–13295. 32. Brambilla, P., Macdonald, A.W. 3rd, Sassi, R.B. et al. (2007) Context processing performance in bipolar disorder patients. Bipolar Disord., 9, 230–237. 33. Zimmerman, M.E., DelBello, M.P., Getz, G.E. et al. (2006) Anterior cingulate subregion volumes and executive function in bipolar disorder. Bipolar Disord., 8, 281–288. 34. Lopez-Larson, M.P., DelBello, M.P., Zimmerman, M.E. et al. (2002) Regional prefrontal gray and white matter abnormalities in bipolar disorder. Biol. Psychiatry, 52, 93–100. 35. Soares, J.C., Kochunov, P., Monkul, E.S. et al. (2005) Structural brain changes in bipolar disorder using deformation field morphometry. Neuroreport, 16, 541–544. 36. Dickstein, D.P., Milham, M.P., Nugent, A.C. et al. (2005) Frontotemporal alterations in pediatric bipolar disorder: results of a voxel-based morphometry study. Arch. Gen. Psychiatry, 62, 734–741. 37. Papiol, S., Molina, V., Desco, M. et al. (2008) Gray matter deficits in bipolar disorder are associated with genetic variability at interleukin-1 beta gene, (2q13). Genes Brain Behav., 7, 796–801. 38. Molina, V., Sanchez, J., Sanz, J. et al. (2007) Dorsolateral prefrontal N-acetyl-aspartate concentration in male patients with chronic schizophrenia and with chronic bipolar disorder. Eur. Psychiatry, 22, 505–512. 39. Rajkowska, G. (2002) Cell pathology in bipolar disorder. Bipolar Disord., 4, 105–116. 40. Rajkowska, G., Halaris, A. and Selemon, L.D. (2001) Reductions in neuronal and glial density characterize the dorsolateral prefrontal cortex in bipolar disorder. Biol. Psychiatry, 49, 741–752. 41. Yildiz-Yesiloglu, A. and Ankerst, D.P. (2006) Neurochemical alterations of the brain in bipolar disorder and their implications for pathophysiology: a systematic review of the in vivo proton magnetic resonance spectroscopy findings. Prog. Neuropsychopharmacol. Biol. Psychiatry, 30, 969–995. 42. George, L. and Neufeld, R.W. (1987) Attentional resources and hemispheric functional asymmetry in schizophrenia. Br. J. Clin. Psychol., 26, 35–45. 43. Sanches, M., Keshavan, M.S., Brambilla, P. and Soares, J.C. (2008) Neurodevelopmental basis of bipolar disorder: A critical appraisal. Prog. Neuropsychopharmacol. Biol. Psychiatry, 32, 1617–1627. 44. Biederman, J., Makris, N., Valera, E.M. et al. (2008) Towards further understanding of the comorbidity between attention deficit hyperactivity disorder and bipolar disorder: a MRI study of brain volumes. Psychol. Med., 38, 1045–1056. 45. Najt, P., Nicoletti, M., Chen, H.H. et al. (2007) Anatomical measurements of the orbitofrontal cortex in child and adolescent patients with bipolar disorder. Neurosci. Lett., 413, 183–186. 46. Altshuler, L.L., Bookheimer, S.Y., Townsend, J. et al. (2005) Blunted activation in orbitofrontal cortex during mania:
Structural Brain Imaging
47.
48.
49.
50.
51.
52.
53.
54.
55.
56.
57.
58.
59.
60.
61.
62.
a functional magnetic resonance imaging study. Biol. Psychiatry, 58, 763–769. Fahim, C., Stip, E., Mancini-Marie, A. et al. (2007) Orbitofrontal dysfunction in a monozygotic twin discordant for postpartum affective psychosis: a functional magnetic resonance imaging study. Bipolar Disord., 9, 541–545. Kronhaus, D.M., Lawrence, N.S., Williams, A.M. et al. (2006) Stroop performance in bipolar disorder: further evidence for abnormalities in the ventral prefrontal cortex. Bipolar Disord., 8, 28–39. Monkul, E.S., Hatch, J.P., Nicoletti, M.A. et al. (2007) Frontolimbic brain structures in suicidal and non-suicidal female patients with major depressive disorder. Mol. Psychiatry, 12, 360–366. Plassmann, H., ODoherty, J. and Rangel, A. (2007) Orbitofrontal cortex encodes willingness to pay in everyday economic transactions. J. Neurosci., 27, 9984–9988. Kempton, M.J., Geddes, J.R., Ettinger, U. et al. (2008) Metaanalysis, database, and meta-regression of 98 structural imaging studies in bipolar disorder. Arch. Gen. Psychiatry, 65, 1017–1032. McDonald, C., Zanelli, J., Rabe-Hesketh, S. et al. (2004) Metaanalysis of magnetic resonance imaging brain morphometry studies in bipolar disorder. Biol. Psychiatry, 56, 411–417. Strakowski, S.M., DelBello, M.P., Zimmerman, M.E. et al. (2002) Ventricular and periventricular structural volumes in first- versus multiple-episode bipolar disorder. Am. J. Psychiatry, 159, 1841–1847. Brambilla, P., Harenski, K., Nicoletti, M. et al. (2001) MRI study of posterior fossa structures and brain ventricles in bipolar patients. J. Psychiatr. Res., 35, 313–322. Dewan, M.J., Haldipur, C.V., Lane, E.E. et al. (1988) Bipolar affective disorder. I. Comprehensive quantitative computed tomography. Acta Psychiatr. Scand, 77, 670–676. Dupont, R.M., Jernigan, T.L., Gillin, J.C. et al. (1987) Subcortical signal hyperintensities in bipolar patients detected by MRI. Psychiatry Res., 21, 357–358. Harvey, I., Persaud, R., Ron, M.A. et al. (1994) Volumetric MRI measurements in bipolars compared with schizophrenics and healthy controls. Psychol. Med., 24, 689–699. Hauser, P., Matochik, J., Altshuler, L.L. et al. (2000) MRI-based measurements of temporal lobe and ventricular structures in patients with bipolar I and bipolar II disorders. J. Affect. Disord., 60, 25–32. Iacono, W.G., Smith, G.N., Moreau, M. et al. (1988) Ventricular and sulcal size at the onset of psychosis. Am. J. Psychiatry, 145, 820–824. Johnstone, E.C., Owens, D.G., Crow, T.J. et al. (1989) Temporal lobe structure as determined by nuclear magnetic resonance in schizophrenia and bipolar affective disorder. J. Neurol. Neurosurg. Psychiatry, 52, 736–741. Lim, K.O., Rosenbloom, M.J., Faustman, W.O. et al. (1999) Cortical gray matter deficit in patients with bipolar disorder. Schizophr. Res., 40, 219–227. McDonald, W.M., Krishnan, K.R., Doraiswamy, P.M. and Blazer, D.G. (1991) Occurrence of subcortical hyperintensities in elderly subjects with mania. Psychiatry Res., 40, 211–220.
|
129
63. Risch, S.C., Lewine, R.J., Kalin, N.H. et al. (1992) Limbichypothalamic-pituitary-adrenal axis activity and ventricularto- brain ratio studies in affective illness and schizophrenia. Neuropsychopharmacology, 6, 95–100. 64. Roy, P.D., Zipursky, R.B., Saint-Cyr, J.A. et al. (1998) Temporal horn enlargement is present in schizophrenia and bipolar disorder. Biol. Psychiatry, 44, 418–422. 65. Schlegel, S. and Kretzschmar, K. (1987) Computed tomography in affective disorders. Part II. Brain density. Biol. Psychiatry, 22, 15–23. 66. Swayze, V.W.d., Andreasen, N.C., Alliger, R.J. et al. (1990) Structural brain abnormalities in bipolar affective disorder. Ventricular enlargement and focal signal hyperintensities. Arch. Gen. Psychiatry, 47, 1054–1059. 67. Tanaka, Y., Hazama, H., Fukuhara, T. and Tsutsui, T. (1982) Computerized tomography of the brain in manic-depressive patients–a controlled study. Folia Psychiatr. Neurol. Jpn., 36, 137–143. 68. Weinberger, D.R., DeLisi, L.E., Perman, G.P. et al. (1982) Computed tomography in schizophreniform disorder and other acute psychiatric disorders. Arch. Gen. Psychiatry, 39, 778–783. 69. Sala, M., Perez, J., Soloff, P. et al. (2004) Stress and hippocampal abnormalities in psychiatric disorders. Eur. Neuropsychopharmacol., 14, 393–405. 70. Wittenberg, G.M. and Tsien, J.Z. (2002) An emerging molecular and cellular framework for memory processing by the hippocampus. Trends Neurosci., 25, 501–505. 71. Poldrack, R.A. and Gabrieli, J.D. (1997) Functional anatomy of long-term memory. J. Clin. Neurophysiol., 14, 294–310. 72. Bearden, C.E., Glahn, D.C., Monkul, E.S. et al. (2006) Sources of declarative memory impairment in bipolar disorder: mnemonic processes and clinical features. J. Psychiatr. Res., 40, 47–58. 73. Martinez-Aran, A., Vieta, E., Torrent, C. et al. (2007) Functional outcome in bipolar disorder: the role of clinical and cognitive factors. Bipolar Disord., 9, 103–113. 74. Swayze, V.W.d., Andreasen, N.C., Alliger, R.J. et al. (1992) Subcortical and temporal structures in affective disorder and schizophrenia: a magnetic resonance imaging study [see comments]. Biol. Psychiatry, 31, 221–240. 75. Altshuler, L.L., Bartzokis, G., Grieder, T. et al. (1998) Amygdala enlargement in bipolar disorder and hippocampal reduction in schizophrenia: an MRI study demonstrating neuroanatomic specificity [letter]. Arch. Gen. Psychiatry, 55, 663–664. 76. Brambilla, P., Harenski, K., Nicoletti, M. et al. (2003) MRI investigation of temporal lobe structures in bipolar patients. J. Psychiatr. Res., 37, 287–295. 77. Hauser, P., Altshuler, L.L., Berrettini, W. et al. (1989) Temporal lobe measurement in primary affective disorder by magnetic resonance imaging. J. Neuropsychiatry Clin. Neurosci., 1, 128–134. 78. Pearlson, G.D., Barta, P.E., Powers, R.E. et al. (1997) Ziskind-Somerfeld Research Award 1996. Medial and superior temporal gyral volumes and cerebral asymmetry in schizophrenia versus bipolar disorder. Biol. Psychiatry, 41, 1–14.
130
|
Chapter 13
79. Sax, K.W., Strakowski, S.M., Zimmerman, M.E. et al. (1999) Frontosubcortical neuroanatomy and the continuous performance test in mania. Am. J. Psychiatry, 156, 139–141. 80. Strakowski, S.M., DelBello, M.P., Sax, K.W. et al. (1999) Brain magnetic resonance imaging of structural abnormalities in bipolar disorder. Arch. Gen. Psychiatry, 56, 254–260. 81. Bearden, C.E., Thompson, P.M., Dutton, R.A. et al. (2008) Three-dimensional mapping of hippocampal anatomy in unmedicated and lithium-treated patients with bipolar disorder. Neuropsychopharmacology, 33, 1229–1238. 82. Moorhead, T.W., McKirdy, J., Sussmann, J.E. et al. (2007) Progressive gray matter loss in patients with bipolar disorder. Biol. Psychiatry, 62, 894–900. 83. Noga, J.T., Vladar, K. and Torrey, E.F. (2001) A volumetric magnetic resonance imaging study of monozygotic twins discordant for bipolar disorder. Psychiatry Res., 106, 25–34. 84. Chepenik, L.G., Fredericks, C., Papademetris, X. et al. (2009) Effects of the Brain-Derived Neurotrophic Growth Factor Val66Met Variation on Hippocampus Morphology in Bipolar Disorder. Neuropsychopharmacology, 34, 944–951. 85. Atmaca, M., Yildirim, H., Ozdemir, H. et al. (2007) Hippocampal 1H MRS in patients with bipolar disorder taking valproate versus valproate plus quetiapine. Psychol. Med., 37, 121–129. 86. Bertolino, A., Frye, M., Callicott, J.H. et al. (2003) Neuronal pathology in the hippocampal area of patients with bipolar disorder: a study with proton magnetic resonance spectroscopic imaging. Biol. Psychiatry, 53, 906–913. 87. Scherk, H., Backens, M., Schneider-Axmann, T. et al. (2008) Neurochemical pathology in hippocampus in euthymic patients with bipolar I disorder. Acta Psychiatr. Scand., 117, 283–288. 88. Colla, M., Schubert, F., Bubner, M. et al. (2008) Glutamate as a spectroscopic marker of hippocampal structural plasticity is elevated in long-term euthymic bipolar patients on chronic lithium therapy and correlates inversely with diurnal cortisol. Mol. Psychiatry, 14, 696–704. 89. Blumberg, H.P., Kaufman, J., Martin, A. et al. (2003) Amygdala and hippocampal volumes in adolescents and adults with bipolar disorder. Arch. Gen. Psychiatry, 60, 1201–1208. 90. Frazier, J.A., Hodge, S.M., Breeze, J.L. et al. (2008) Diagnostic and sex effects on limbic volumes in early-onset bipolar disorder and schizophrenia. Schizophr. Bull., 34, 37–46. 91. Chang, K., Karchemskiy, A., Barnea-Goraly, N. et al. (2005) Reduced amygdalar gray matter volume in familial pediatric bipolar disorder. J. Am. Acad. Child Adolesc. Psychiatry, 44, 565–573. 92. Chen, B.K., Sassi, R., Axelson, D. et al. (2004) Cross-sectional study of abnormal amygdala development in adolescents and young adults with bipolar disorder. Biol. Psychiatry, 56, 399–405. 93. Bearden, C.E., Soares, J.C., Klunder, A.D. et al. (2008) Threedimensional mapping of hippocampal anatomy in adolescents with bipolar disorder. J. Am. Acad. Child Adolesc. Psychiatry, 47, 515–525. 94. Geuze, E., Vermetten, E. and Bremner, J.D. (2005) MR-based in vivo hippocampal volumetrics: 2. Findings in neuropsychiatric disorders. Mol. Psychiatry, 10, 160–184.
95. Strasser, H.C., Lilyestrom, J., Ashby, E.R. et al. (2005) Hippocampal and ventricular volumes in psychotic and nonpsychotic bipolar patients compared with schizophrenia patients and community control subjects: a pilot study. Biol. Psychiatry, 57, 633–639. 96. Gogtay, N., Nugent, T.F. 3rd, Herman, D.H. et al. (2006) Dynamic mapping of normal human hippocampal development. Hippocampus, 16, 664–672. 97. Altshuler, L.L., Bartzokis, G., Grieder, T. et al. (2000) An MRI study of temporal lobe structures in men with bipolar disorder or schizophrenia. Biol. Psychiatry, 48, 147–162. 98. Drevets, W.C. (1999) Prefrontal cortical-amygdalar metabolism in major depression [In Process Citation]. Ann. N. Y. Acad. Sci., 877, 614–637. 99. DelBello, M.P., Zimmerman, M.E., Mills, N.P. et al. (2004) Magnetic resonance imaging analysis of amygdala and other subcortical brain regions in adolescents with bipolar disorder. Bipolar Disord., 6, 43–52. 100. Cahill, L., Babinsky, R., Markowitsch, H.J. and McGaugh, J.L. (1995) The amygdala and emotional memory. Nature, 377, 295–296. 101. McGaugh, J.L., Cahill, L. and Roozendaal, B. (1996) Involvement of the amygdala in memory storage: interaction with other brain systems. Proc. Natl. Acad. Sci. USA, 93, 13508–13514. 102. Hariri, A.R., Mattay, V.S., Tessitore, A. et al. (2002) Serotonin transporter genetic variation and the response of the human amygdala. Science, 297, 400–403. 103. Doty, T.J., Payne, M.E., Steffens, D.C. et al. (2008) Agedependent reduction of amygdala volume in bipolar disorder. Psychiatry Res., 163, 84–94. 104. Foland, L.C., Altshuler, L.L., Sugar, C.A. et al. (2008) Increased volume of the amygdala and hippocampus in bipolar patients treated with lithium. Neuroreport, 19, 221–224. 105. Macchi, G. and Jones, E.G. (1997) Toward an agreement on terminology of nuclear and subnuclear divisions of the motor thalamus. J. Neurosurg., 86, 670–685. 106. Price, J.L. (1999) Prefrontal cortical networks related to visceral function and mood. Ann. N Y Acad. Sci., 877, 383–396. 107. Rodriguez, A., Whitson, J. and Granger, R. (2004) Derivation and analysis of basic computational operations of thalamocortical circuits. J. Cogn. Neurosci., 16, 856–877. 108. Guye, M., Parker, G.J., Symms, M. et al. (2003) Combined functional MRI and tractography to demonstrate the connectivity of the human primary motor cortex in vivo. Neuroimage, 19, 1349–1360. 109. Spinks, R., Magnotta, V.A., Andreasen, N.C. et al. (2002) Manual and automated measurement of the whole thalamus and mediodorsal nucleus using magnetic resonance imaging. Neuroimage, 17, 631–642. 110. Van der Werf, Y.D., Witter, M.P. and Groenewegen, H.J. (2002) The intralaminar and midline nuclei of the thalamus. Anatomical and functional evidence for participation in processes of arousal and awareness. Brain Res. Brain Res. Rev., 39, 107–140. 111. Caetano, S.C., Sassi, R., Brambilla, P. et al. (2001) MRI study of thalamic volumes in bipolar and unipolar patients and healthy individuals. Psychiatry Res., 108, 161–168.
Structural Brain Imaging 112. Haznedar, M.M., Roversi, F., Pallanti, S. et al. (2005) Frontothalamo-striatal gray and white matter volumes and anisotropy of their connections in bipolar spectrum illnesses. Biol. Psychiatry, 57, 733–742. 113. McIntosh, A.M., Job, D.E., Moorhead, T.W. et al. (2004) Voxel-based morphometry of patients with schizophrenia or bipolar disorder and their unaffected relatives. Biol. Psychiatry, 56, 544–552. 114. Strakowski, S.M., Wilson, D.R., Tohen, M. et al. (1993) Structural brain abnormalities in first-episode mania. Biol. Psychiatry, 33, 602–609. 115. Dupont, R.M., Jernigan, T.L., Heindel, W. et al. (1995) Magnetic resonance imaging and mood disorders. Localization of white matter and other subcortical abnormalities. Arch. Gen. Psychiatry, 52, 747–755. 116. Adler, C.M., DelBello, M.P., Jarvis, K. et al. (2007) Voxelbased study of structural changes in first-episode patients with bipolar disorder. Biol. Psychiatry, 61, 776–781. 117. Dasari, M., Friedman, L., Jesberger, J. et al. (1999) A magnetic resonance imaging study of thalamic area in adolescent patients with either schizophrenia or bipolar disorder as compared to healthy controls. Psychiatry Res., 91, 155–162. 118. Frazier, J.A., Giedd, J.N., Hamburger, S.D. et al. (1996) Brain anatomic magnetic resonance imaging in childhood-onset schizophrenia. Arch. Gen. Psychiatry, 53, 617–624. 119. Monkul, E.S., Nicoletti, M.A., Spence, D. et al. (2006) MRI study of thalamus volumes in juvenile patients with bipolar disorder. Depress Anxiety, 23, 347–352. 120. Alexander, G.E., DeLong, M.R. and Strick, P.L. (1986) Parallel organization of functionally segregated circuits linking basal ganglia and cortex. Annu. Rev. Neurosci., 9, 357–381. 121. Mega, M.S. and Cummings, J.L. (1994) Frontal-subcortical circuits and neuropsychiatric disorders. J. Neuropsychiatry Clin. Neurosci., 6, 358–370. 122. Aylward, E.H., Roberts-Twillie, J.V., Barta, P.E. et al. (1994) Basal ganglia volumes and white matter hyperintensities in patients with bipolar disorder. Am. J. Psychiatry, 151, 687–693. 123. Getz, G.E., DelBello, M.P., Fleck, D.E. et al. (2002) Neuroanatomic characterization of schizoaffective disorder using MRI: a pilot study. Schizophr. Res., 55, 55–59. 124. Ahn, M.S., Breeze, J.L., Makris, N. et al. (2007) Anatomic brain magnetic resonance imaging of the basal ganglia in pediatric bipolar disorder. J. Affect. Disord., 104, 147–154. 125. Brambilla, P., Harenski, K., Nicoletti, M.A. et al. (2001) Anatomical MRI study of basal ganglia in bipolar disorder patients. Psychiatry Res., 106, 65–80. 126. Sanches, M., Roberts, R.L., Sassi, R.B. et al. (2005) Developmental abnormalities in striatum in young bipolar patients: a preliminary study. Bipolar Disord., 7, 153–158. 127. Hellige, J.B., Taylor, K.B., Lesmes, L. and Peterson, S. (1998) Relationships between brain morphology and behavioral measures of hemispheric asymmetry and interhemispheric interaction. Brain Cogn., 36, 158–192. 128. Phelps, E.A., Hirst, W. and Gazzaniga, M.S. (1991) Deficits in recall following partial and complete commissurotomy. Cereb. Cortex, 1, 492–498.
|
131
129. Giedd, J.N., Blumenthal, J., Jeffries, N.O. et al. (1999) Development of the human corpus callosum during childhood and adolescence: a longitudinal MRI study. Prog. Neuropsychopharmacol. Biol. Psychiatry, 23, 571–588. 130. Keshavan, M.S., Diwadkar, V.A., DeBellis, M. et al. (2002) Development of the corpus callosum in childhood, adolescence and early adulthood. Life Sci., 70, 1909–1922. 131. Brambilla, P., Nicoletti, M., Sassi, R.B. et al. (2004) Corpus callosum signal intensity in patients with bipolar and unipolar disorder. J. Neurol. Neurosurg. Psychiatry, 75, 221–225. 132. Brambilla, P., Nicoletti, M.A., Sassi, R.B. et al. (2003) Magnetic resonance imaging study of corpus callosum abnormalities in patients with bipolar disorder. Biol. Psychiatry, 54, 1294–1297. 133. Coffman, J.A., Bornstein, R.A., Olson, S.C. et al. (1990) Cognitive impairment and cerebral structure by MRI in bipolar disorder. Biol. Psychiatry, 27, 1188–1196. 134. Hauser, P., Dauphinais, I.D., Berrettini, W. et al. (1989) Corpus callosum dimensions measured by magnetic resonance imaging in bipolar affective disorder and schizophrenia. Biol. Psychiatry, 26, 659–668. 135. Arnone, D., McIntosh, A.M., Chandra, P. and Ebmeier, K.P. (2008) Meta-analysis of magnetic resonance imaging studies of the corpus callosum in bipolar disorder. Acta Psychiatr. Scand, 118, 357–362. 136. Caetano, S.C., Silveira, C.M., Kaur, S. et al. (2008) Abnormal corpus callosum myelination in pediatric bipolar patients. J. Affect. Disord., 108, 297–301. 137. Yasar, A.S., Monkul, E.S., Sassi, R.B. et al. (2006) MRI study of corpus callosum in children and adolescents with bipolar disorder. Psychiatry Res., 146, 83–85. 138. Caldu, X., Narberhaus, A., Junque, C. et al. (2006) Corpus callosum size and neuropsychologic impairment in adolescents who were born preterm. J. Child Neurol., 21, 406–410. 139. Leiner, H.C., Leiner, A.L. and Dow, R.S. (1993) Cognitive and language functions of the human cerebellum. Trends Neurosci., 16, 444–447. 140. Makris, N., Hodge, S.M., Haselgrove, C. et al. (2003) Human cerebellum: surface-assisted cortical parcellation and volumetry with magnetic resonance imaging. J. Cogn. Neurosci., 15, 584–599. 141. Snider, R.S., Maiti, A. and Snider, S.R. (1976) Cerebellar connections to catecholamine systems: anatomical and biochemical studies. Trans. Am. Neurol. Assoc., 101, 295–297. 142. DelBello, M.P., Strakowski, S.M., Zimmerman, M.E. et al. (1999) MRI analysis of the cerebellum in bipolar disorder: a pilot study [In Process Citation]. Neuropsychopharmacology, 21, 63–68. 143. Lippmann, S., Manshadi, M., Baldwin, H. et al. (1982) Cerebellar vermis dimensions on computerized tomographic scans of schizophrenic and bipolar patients. Am. J. Psychiatry, 139, 667–668. 144. Nasrallah, H.A., Jacoby, C.G. and McCalley-Whitters, M. (1981) Cerebellar atrophy in schizophrenia and mania [letter]. Lancet, 1, 1102.
132
|
Chapter 13
145. Nasrallah, H.A., McCalley-Whitters, M. and Jacoby, C.G. (1982) Cerebral ventricular enlargement in young manic males. A controlled CT study. J. Affect. Disord., 4, 15–19. 146. Rieder, R.O., Mann, L.S., Weinberger, D.R. et al. (1983) Computed tomographic scans in patients with schizophrenia, schizoaffective, and bipolar affective disorder. Arch. Gen. Psychiatry, 40, 735–739. 147. Yates, W.R., Jacoby, C.G. and Andreasen, N.C. (1987) Cerebellar atrophy in schizophrenia and affective disorder. Am. J. Psychiatry, 144, 465–467. 148. Mills, N.P., Delbello, M.P., Adler, C.M. and Strakowski, S.M. (2005) MRI analysis of cerebellar vermal abnormalities in bipolar disorder. Am. J. Psychiatry, 162, 1530–1532.
149. Monkul, E.S., Hatch, J.P., Sassi, R.B. et al. (2008) MRI study of the cerebellum in young bipolar patients. Prog. Neuropsychopharmacol. Biol. Psychiatry, 32, 613–619. 150. Nishino, H., Nakajima, K., Kumazaki, M. et al. (1998) Estrogen protects against while testosterone exacerbates vulnerability of the lateral striatal artery to chemical hypoxia by 3-nitropropionic acid. Neurosci. Res., 30, 303–312. 151. Roof, R.L. and Hall, E.D. (2000) Estrogen-related gender difference in survival rate and cortical blood flow after impactacceleration head injury in rats. J. Neurotrauma., 17, 1155–1169. 152. Roof, R.L. and Hall, E.D. (2000) Gender differences in acute CNS trauma and stroke: neuroprotective effects of estrogen and progesterone. J. Neurotrauma, 17, 367–388.
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Functional Magnetic Resonance Imaging, Diffusion Tensor Imaging, and Magnetic Resonance Spectroscopy in Bipolar Disorder In Kyoon Lyoo1 and Perry F. Renshaw2 1 2
Seoul National University, Seoul, South Korea University of Utah, Salt Lake City, UT, USA
Introduction There have been fervent endeavours for more complete understanding of neurobiological underpinnings of bipolar disorder (BD), ultimately for the development of the better treatment options for this potentially disabling disorder. The technique of magnetic resonance imaging (MRI), developed by Lauterbur and Mansfield, has permitted various functional, chemical and anatomical studies of brain in BD, by enabling researchers to examine structure, function and chemistry of the live human brain. This chapter selectively focuses on the findings from studies using functional magnetic resonance imaging (fMRI), diffusion tensor imaging (DTI) and magnetic resonance spectroscopy (MRS) in patients with BD. For these newer techniques, there have been challenges in technical and image data analytic aspects, to which some inconsistencies in the study results may have been attributed. Some of the challenges in interpreting the data are likely to stem from the variabes in medication history or medication and different clinical characteristics of BD, such as subtypes of BD and mood states at the time of scanning. In spite of these challenges, a substantial amount of studies have successfully been conducted and reported valuable findings that have greatly contributed to a better understanding of the pathophysiology of BD. Converging evidence for altered functions, white matter structure and chemistry in frontal, striatal, thalamic and limbic system of the brain in patients with BD is reviewed and presented [Brain structural changes in BD were reviewed elsewhere in this book]. Implications of these findings are also discussed in this chapter. We show part of the results in the form of tables and figures, in order to better integrate a number of findings.
Bipolar Disorder: Clinical and Neurobiological Foundations Edited by Lakshmi N. Yatham and Mario Maj © 2010 John Wiley & Sons, Ltd. ISBN: 978-0-470-72198-8
Current knowledge from prior studies using fMRI, DTI and MRS, along with future studies with more refined neuroimaging techniques, cutting-edge analytic methods and more sophisticated study designs will not only improve the understanding on the pathophysiology of BD but also contribute to more accurately comprehend the human emotion and behaviour.
Magnetic resonance spectroscopy in bipolar disorder Introduction Recent brain MRS studies have offered the potential for in vivo measurement of brain chemistry and have enhanced our understanding of the biochemical pathophysiology of BD. Hydrogen-1 ð1 HÞ and phosphorous-31 ð31 PÞ are the most widely used nuclei in the clinical application of MRS. Studies using 1 H MRS provides insight into alterations in cerebral concentrations of N-acetylaspartate (NAA), choline-containing compounds (Cho), myoinositol (mI), creatine or phosphocreatine (Cr), glutamate/ glutamine complex (Glx), and lactate in patients with BD, while studies using 31 P MRS can provide information on alterations in cerebral levels of phosphorous containing compounds, including phosphomonoester (PME), phosphodiester (PDE), phosphocreatine (PCr), inorganic phosphate, adenosine triphosphate (ATP) (Figure 1). Changes in phosphorous containing compounds are related to the changes in high-energy phosphate and phospholipid metabolism. Since a decade ago, a substantial amount of MRS studies have examined the neurochemical alterations in BD. Based on the neurochemical and the bioenergetic findings from 1 H MRS and 31 P MRS studies (Figure 2), it has been recently suggested that the mitochondrial dysfunction [1,2], as well as the abnormalities in neuronal and glial cells, play important roles in the pathophysiology of BD. 133
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Fig. 1 Sample magnetic resonance spectroscopy spectra from 31 P MRS at 2T (A) and from 1 H MRS at 3T (B). See also Plate 1. Abbreviations: ATP, adenosine tri-phosphate; MRS, Magnetic Resonance Spectroscopy; PCr, Phosphocreatine; PDE, Phosphodiesters; Pi, Inorganic Phosphate; PME, Phosphomonoesters; T, Tesla. (a) A sample 31 P spectra is shown. Reprinted from [3]. Association between cortical metabolite levels and clinical manifestations of migrainous aura: An MR-spectroscopy study. Brain;130:3102–3110, by permission of Oxford University Press. (b) A sample 1 H spectra is shown. Reprinted from [4]. Abnormal glutamatergic neurotransmission and neuronal-glial interactions in acute mania. Biol. Psych.; 64:718–726, by permission of Elsevier.
Fig. 2 Schematic presentation of the findings from cross-sectional 1 H MRS and 31 P MRS studies that show differences in brain metabolite levels between adult patients with bipolar disorder and comparison subjects. See also Plate 2. Abbreviations: Cho, Choline; Cr, Creatine; Glx, Glutamate, Glutamine and g-amino butyric acid; MRS, Magnetic Resonance Spectroscopy; NAA, N-acetylaspartate; PCr, Phosphocreatine; PME, Phosphomonoesters. Regular triangles represent higher brain metabolite levels or metabolite/Cr þ PCr ratios in patients with bipolar disorder relative to comparison subjects. Inverted triangles represent lower metabolite levels or metabolite/Cr þ PCr ratios in patients with bipolar disorder relative to comparison subjects. Rectangles represent no differences in metabolite levels or metabolite/Cr þ PCr ratios between patients with bipolar disorder and comparison subjects.
Proton (1H) MRS N-acetylaspartate (NAA)(Table 1) The resonance from NAA is the most prominent metabolite peak and occur at 2.02 parts per million (ppm) on the 1 H spectrum. The concentration of NAA is 8–10 mmol/L [38] and NAA is the second abundant amino acid in the brain
following glutamate [1]. Since NAA is mainly located in the neurons, NAA has been regarded as a neuronal marker and the reduction of cerebral NAA levels has been thought to indicate possible neuronal injury or loss [39]. Recent studies have also suggested that NAA plays an important role in cerebral osmoregulation [40,41] and that, more importantly,
Subjects
Gender (M/F)
Mean age (SD)
Patients characteristics (subtype/current episode/ medication/illness durationa)
Bertolino et al. [7]
Cecil et al. [6]
10/7
10/7
17 controls
9/12
21 controls
17 patients
6/11
9/11
17 patients
20 controls
38 (10)
40 (13)
22 (5)
22 (7)
34 (14)
4 manic or hypomanic, 7 depressed, 6 euthymic 6 medication-free for at least 2 wk not available
9 manic, 8 mixed all medicated 5 (4) 17 BD I
PRESS
all medication-free for at least 2 wk 15.0 (12.8) 17 BD I
- each voxel 0.84 cm3
Multi-slice
spin echo sequence
- hippocampus/ DLPFC/STG/ IFG/OC/ACC/ PCC/prefrontal WM/thalamus
- 8 cm3
- # NAA/Cho ratios in bilateral hippocampus
- # NAA/Cr þ PCr ratios in bilateral hippocampus
- # NAA levels in medial prefrontal8 GM
- # NAA/Cho ratios in bilateral DLPFC
- 8 cm3
- medial medial prefrontal8 GM/medial prefrontal8 WM
- # NAA/Cr þ PCr ratios in bilateral DLPFC
Results on NAA/ Cr þ PCr ratio or NAA levelsb
- bilateral DLPFC
Regions of examined/Voxel size
1.5 T
single voxel PRESS
-1.5 T
single voxel
1.5 T
Imaging methods (field strength/ technique/ acquisition)
all euthymic
Findings of reduced NAA/Cr þ PCr or NAA levels in patients with bipolar disorder Winsberg et al. [5] 20 patients 9/11 38 (14) 10 BD I/10 BD II
Study
Table 1 Published 1 H MRS research on NAA/Cr þ PCr and NAA levels in patients with bipolar disorder.
(continued)
- no association between NAA ratios and drug treatment, clinical symptoms, and hippocampal volume
- negative correlation between medial prefrontal l8 GM NAA levels and valproate treatment duration
- positive correlations between NAA/ Cr þ PCr in DLPFC and illness duration and age
Clinical correlations
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Scherk et al. [11]
Bhagwagar et al. [10]
6/7
6/7
13 controls
9/9
18 controls
13 patients
6/10
6/6
12 controls
16 patients
6/6
12 patients
20/0
20 controls
31 (6)
32 (6)
38 (14)
37 (14)
27 (8)
28 (7)
36 (11)
39 (10)
Mean age (SD)
PRESS
12 medicated 18.7 (9.5) 12 BD I
all euthymic
all euthymic all medication-free for at least 3 mo 2 (range 0.5–10.1) 13 BD I
PRESS
not available not available 16 BD I
single voxel
1.5 T
single voxel PRESS
3T
Multi-slice
all manic
1.5 T
CSI
1.5 T
Imaging methods (field strength/ technique/ acquisition)
all euthymic
15 BD I
Patients characteristics (subtype/current episode/ medication/illness durationa)
# NAA/Cr þ PCr ratio in occipital cortex
# NAA/Cho ratios in bilateral hippocampus
- # NAA/Cr þ PCr ratios in bilateral hippocampus
- # NAA levels in bilateral hippocampus
Results on NAA/ Cr þ PCr ratio or NAA levelsb
left hippocampus/ # NAA/Cr þ PCr ratio in left left thalamus/ hippocampus left putamen 3.5 cm3 (hippocampus)/
18 cm3
occipital-parietal region
each voxel 0.84 cm3
- hippocampus
- each voxel 1.1 cm3
- hippocampus
Regions of examined/Voxel size
not examined
no association between NAA ratio and clinical characteristics
- positive correlations between bilateral hippocampal NAA ratios and YMRS scores no association between NAA ratios and illness duration and hippocampal volume
- negative correlation between right hippocampal NAA levels and illness duration - no association between NAA levels and medication dose or concentrations
Clinical correlations
|
Atmaca et al. [9]
15/0
15 patients
Deicken et al. [8]
Gender (M/F)
Subjects
Study
Table 1 (Continued)
136 Chapter 14
Cecil et al. [15]
Olvera et al. [14]
Sassi et al. [13]
Chang et al. [12]
5/4
6/4
10 controls
19/15
36 controls
9 paediatric patients
17/18
9/7
18 controls
35 paediatric patients
6/8
6/5
11 controls
14 paediatric patients
13/2
15 paediatric patients
11 (2)
10 (1)
14 (3)
13 (3)
17 (4)
16 (3)
13 (3)
13 (3)
1 medicated not available
single voxel PRESS
1.5 T
PRESS
24 medicated
4.3 (3.7) 3 BD I, 3 BD II, 1 BD NOS, 2 MDD - all euthymic
single voxel
1.5 T
STEAM
single voxel
not available
1 depressed, 13 euthymic -13 medicated 3.8 (2.4) 23 BD I, 12 BD II
1.5 T
single voxel PRESS
3T
8.2 (6.5) not available
all euthymic 14 medicated not available 10 BD I, 3 BD II, 1 BD NOS
spin echo sequence
all medicated
# NAA/Cho ratio in cerebellar vermis
# NAA levels in early puberty BD patients relative to controls no difference in NAA levels between middle/ advanced puberty BD groups and controls
8 cm3
medial frontal cortex/right frontal WM/ cerebellar vermis 8 cm3
# NAA levels in left DLPFC
# NAA levels in left DLPFC
# NAA/Cr þ PCr and NAA/Cho ratios in right DLPFC
left DLPFC
8 cm3
left DLPFC
8 cm3
-bilateral DLPFC
3.4 cm3 (thalamus)/3.3 cm3 (putamen)
(continued)
not examined
negative correlation between NAA levels and YMRS scores positive correlation between NAA levels and age
no association between NAA levels and clinical characteristics
negative correlation between NAA/ Cr þ PCr ratio in right DLPFC and illness duration
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Subjects
Gender (M/F)
Mean age (SD)
Patients characteristics (subtype/current episode/ medication/illness durationa)
Michael et al. [18]
Hamakawa et al. [17]
6/2
6/2
8 controls
7/13
20 controls
8 patients
8/15
6/14
23 patients
20 controls
41 (15)
40 (14)
37 (10)
45 (11)
44 (10)
all manic 2 medicated not available
all euthymic, 8 subjects were also examined in depressive episode 4 cases medicationfree not available not available
11 and 16 examined in depressive and euthymic states, respectively (some were examined repeatedly) 4 cases medicationfree not available 15 BD I, 8 BD II
27 cm3
single voxel
15.6 cm3
single voxel
left DLPFC
3.4 cm3
1.5 T
single voxel STEAM
STEAM
bilateral frontal cortical regions
1.5 T
STEAM
-left basal ganglia
Regions of examined/Voxel size
1.5 T
Imaging methods (field strength/ technique/ acquisition)
no difference in NAA levels between groups
no difference in NAA levels between groups
no difference in NAA levels and NAA/Cr þ PCr between groups
Results on NAA/ Cr þ PCr ratio or NAA levelsb
not examined
no association between metabolite levels and medication use
-not examined
Clinical correlations
|
Findings of no alterations in NAA/Cr þ PCr or NAA levels in patients with bipolar disorder Hamakawa et al. [16] 18 patients 5/13 46 (13) 8 BD I, 10 BD II
Study
Table 1 (Continued)
138 Chapter 14
Colla et al. [22]
Frey et al. [21]
Brambilla et al. [20]
Dager et al. [19]
10/11
10/22
32 controls
21 patients
11/21
16/16
32 controls
32 patients
2/8
10/14
24 controls
10 patients
13/16
29 patients
54 (2)
34 (9)
34 (10)
35 (10)
37 (14)
32 (8)
30 (11)
7 hypomanic, 17 depressed, 1 mixed, 7 euthymic -ll medication free at least for 2 wk 10.0 (9.6) 21 BD I
3T
bilateral hippocampus
8 cm3 single voxel
PRESS
left DLPFC
STEAM
4 medication-free at least for 2 wk 15.9 (10.3) 20 BD I, 12 BD II
8 cm3
left DLFPC
frontal WM/ cingulate/ caudate/ putamen/ thalamus/ insula/parietal WM (all bilateral)/ midline occipital each voxel 1 cm3
1.5 T
single voxel
1.5 T
PEPSI
CSI
1.5 T
1 depressed, 9 euthymic
all predominantly depressed all medication-free 13.5 (10.2) 8 BD I, 2 BD II
11 BD I, 17 BD II, 1 BD NOS
no difference in NAA levels between groups
no difference in NAA levels between groups
no difference in NAA levels between groups " NAA levels in lithium-treated patients relative to unmedicated patients and controls
no difference in NAA levels in GM and WM between groups
negative correlation between NAA levels and diurnal saliva cortisol levels (continued)
no association between NAA levels and clinical characteristics
negative association between NAA/Cho ratio and prior affective episodes
no association between NAA levels and clinical symptoms
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14 (3)
12 (3)
14 (3)
19/9
17/9
28 with prodromal symptoms 26 controls
non-age matched
22/10
8/2
10 controls
8
34 (10)
32 patient
9/1
10 paediatric patients
11/10
21 controls
36 (12)
55 (2)
Mean age (SD)
28 BD patients medicated not available
not available
PRESS
all medication free at least for 1 wk not available not available
1.5 T
PRESS
single voxel
3T
single voxel
1.5 T
bilateral thalamus
8 cm3
bilateral DLPFC
8 or 27 cm3
bilateral frontal lobes/bilateral basal ganglia
8 cm3
single voxel PRESS
not available
all manic all medicated age of onset, 25.5 (9.5) not available
ACC, parietooccipital cortex
PRESS
all medicated not available 15 BD I
-12 cm3
Regions of examined/Voxel size
3T
single voxel
Imaging methods (field strength/ technique/ acquisition)
all euthymic
Patients characteristics (subtype/current episode/ medication/illness durationa)
Findings of increased NAA/Cr þ PCr or NAA levels in patients with bipolar disorder Deicken et al. [25] 15 patients 15/0 41 (11) 15 BD I
Gallelli et al. [24]
Castillo et al. [23]
7/8
9/10
19 controls
15 patients
Gender (M/F)
Subjects
" NAA levels in bilateral thalamus
no difference in NAA/Cr þ PCr ratio between groups
no difference in NAA/Cr þ PCr ratio between groups
no difference in NAA levels between groups
Results on NAA/ Cr þ PCr ratio or NAA levelsb
no association between NAA levels and clinical characteristics
no association between NAA/Cr þ PCr ratio and medication status
not examined
no association between metabolite levels and medication status
positive correlation between hippocampal NAA and glutamate levels
Clinical correlations
|
€ u € r et al. [4] Ong
Study
Table 1 (Continued)
140 Chapter 14
15/0
38 (11)
all euthymic 13 medicated 22.1 (9.7)
Silverstone et al. [28]d
Moore et al. [27]c
40 (3)
35 (2) (VPA) 31 (3)
9/5 (lithium)
5/6
(VPA)
8/10
- 14 lithium treated patients
- 11 VPA treated patients
18 controls
(lithium)
27
3/6
9 controls
36
31 (5)
5/7
6/3
12 patients
9 controls
all euthymic 14 treated with lithium 11 treated with VPA not available
7 BD I, 4 BD II (VPA)
all depressed all medication free at least for 2 wk not available 7 BD I, 7 BD II (lithium)
4 manic all BD patients treated with lithium not available 11 BD I, 1 BD II
Effects of medication on NAA/Cr þ PCr and NAA levels in patients with bipolar disorder 37 (3) 4 BD, 4 SPR, 1 MDD Sharma et al. [26] 9 patients (4 BD, 3/6 4 SPR, 1 MDD)
15 controls
PRESS
single voxel
3T
single voxel STEAM
1.5 T
single voxel STEAM
1.5 T
Multi-slice spin echo sequence
12 cm3
left temporal cortex
right frontal/left temporal/ central occipital/left parietal regions 8 cm3
15.6 cm3
basal ganglia/ occipital cortex
each voxel 1.5 cm3
" NAA/Cr þ PCr ratio in lithiumtreated patients relative to controls no difference in NAA levels between VPAtreated patients and controls
" NAA levels in all regions with 4wk lithium treatment
" NAA/Cr þ PCr ratio in basal ganglia in lithium-treated BD patients relative to controls
(continued)
not examined
not examined
not examined
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Friedman et al. [31] f 9/12
5/7
12 controls
—
—
21 patients
6/3
9 patients
7/5
12 controls
31 (6)
30 (9)
—
66 (10)
33 (11)
36 (11)
Mean age (SD)
4T
17.4 (10.4) 9 BD I
all predominantly depressed
CSI
1.5 T
single voxel PRESS, ISIS
PRESS
5 medicated
not available all treated lithium not available 8 BD I, 13 BD II
single voxel
1.5 T
Imaging methods (field strength/ technique/ acquisition)
all depressed
BD I or BD II
Patients characteristics (subtype/current episode/ medication/illness durationa)
frontal WM/ cingulate/ caudate/ putamen/ thalamus/ insula/parietal WM (all bilateral)/ midline occipital each voxel 1 cm3
-8 cm3
ACC
27 cm3
medial frontal cortex
Regions of examined/Voxel size
no changes in GM NAA levels with lithium nor VPA treatment
positive correlation between brain lithium levels and ACC NAA levels
no difference in NAA levels between groups at baseline no changes in NAA levels with 12wk lamotrigine treatment # NAA/Cr þ PCr ratios in patients with 12-wk lamotrigine treatment relative to controls
Results on NAA/ Cr þ PCr ratio or NAA levelsb
not examined
significant interaction effect between remission status and baseline NAA levels
Clinical correlations
|
Forester et al. [30] e
17/6
23 patients
Frye et al. [29]
Gender (M/F)
Subjects
Study
Table 1 (Continued)
142 Chapter 14
6/23
9/2
11 controls
28 paediatric patients
9/2
11 paediatric patients
16 (2)
age-matched
11
all depressed all medication free at least for 1 wk (19 with past history of exposure to psychotropic medication) age of onset, 11.4 (4.0)
9 manic, 2 hypomanic 9 medicated at baseline not available 28 BD I
single voxel PRESS
1.5 T
PRESS
single voxel
1.5 T
PEPSI
8 cm3
medial PFC, bilateral prefrontal WM
8 cm3
ACC
# NAA levels in medial PFC with 6-wk lithium treatment
no changes in ACC NAA/Cr þ PCr ratio with 1-wk lithium treatment
not examined
no association between metabolite ratio and serum lithium level after lithium treatment
Abbreviations: ACC, Anterior Cingulate Cortex; BD, Bipolar Disorder; Cr, Creatine; CSI, Chemical Shift Imaging; DLPFC, Dorsolateral Prefrontal Cortex; GM, Grey Matter; IFG, Inferior Frontal Gyrus; ISIS, Image Selective In vivo Spectroscopy; MDD, Major Depressive Disorder; MRS, Magnetic Resonance Spectroscopy; NAA, N-acetylaspartate; NOS, Not Otherwise Specified; PCr, Phosphocreatine; PEPSI, Proton Echo-Planar Spectroscopic Imaging; PFC, Prefrontal Cortex; PRESS, Point Resolved Spectroscopy; SPR, Schizophrenia; STEAM, Stimulated Echo Acquisition Mode; STG, Superior Temporal Gyrus; T, Tesla; VPA, Valproate; WM, White Matter; YMRS, Young Mania Rating Scale. a Years (standard deviation). b All results presented in Table 1 are those of patients with bipolar disorder relative to comparison subjects except where indicated otherwise. c Same cohort as Moore et al. [34]. d Same cohort as Silverstone et al. [35] and Wu et al. [36]. e Lithium MRS was also conducted to measure brain lithium levels. f Participants of this study was a subgroup of subjects studied at baseline in the medication-free state [19]. g Same cohort as Patel et al. [37].
Patel et al. [33]g
Davanzo et al. [32]
12 assigned to lithium treatment/9 assigned to VPA treatment not available 2 BD II, 9 BD mixed
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NAA appears to reflect mitochondrial oxidative phosphorylation [1,42]. Synthesis of NAA from acetyl coenzyme A and aspartate catalyzed by L-aspartate N-acetyl transferase occurs in the mitochondria [43]. This step is energy dependent and is closely linked to mitochondrial activity in ATP production [44]. Until recently, a number of 1 H MRS studies have reported alterations in NAA concentrations in BD patients relative to comparison subjects. Most demonstrated reduced cerebral NAA concentrations in BD patients, while a few studies did not find the alterations in NAA concentrations. Reductions in NAA levels have been observed in the dorsolateral prefrontal cortex as well as in the hippocampus of BD patients relative to comparison subjects. With Cr and PCr as a reference peak, a study by Winsberg et al. [5] demonstrated lower bilateral dorsolateral prefrontal NAA concentrations in BD patients relative to matched comparison subjects. Similarly, lower frontal grey matter NAA concentrations were reported in patients with BD [6]. The grey matter NAA concentrations in BD patients were negatively [6] correlated with the duration of valproate treatment. Reductions in bilateral hippocampal NAA levels, evaluated using 1 H magnetic resonance spectroscopic imaging (MRSI) or 1 H MRS, have been reported in euthymic and manic BD patients [7–9,11]. The lower hippocampal NAA levels were reported to correlate with longer disease duration [8]. Medication-free patients recovered from BD were also demonstrated to have reduced occipital NAA levels relative to comparison subjects [10]. Reduced NAA concentrations in the frontal cortex as well as in the hippocampus have been interpreted to reflect the decreased neuronal integrity or neuronal dysfunction in patients with BD. Based on a recent view that NAA is closely related to mitochondrial energy metabolism, the findings of decreased NAA levels in BD patients relative to comparison subjects could also be interpreted as indirect evidence for mitochondrial dysfunction in BD [1]. In contrast, Brambilla et al. [20] did not find altered dorsolateral prefrontal NAA levels in BD patients. This negative finding was attributed in part to the fact that some of the patients were treated with lithium. Colla et al. [22] reported a similar finding to that of Brambilla et al., that is, the absence of alterations in NAA levels of euthymic BD patients with the chronic lithium treatment relative to comparison subjects. It can be suggested that treatment may normalize cerebral NAA levels of BD patients. However, there have also been studies reporting no differences in NAA levels between antipsychotics- and moodstabilizers-naive and medication-free BD patients and comparison subjects [19]. A few recent studies of manic [4] and depressed [21] BD patients did not find reductions in cerebral NAA levels of BD patients. There has been only one study reporting elevated cerebral NAA levels in BD patients, who were treated with lithium
and valproate, relative to comparison subjects. In euthymic male patients with familial BD, higher NAA levels were observed in the bilateral thalamus [25]. In child and adolescent BD patients, reductions in NAA concentrations have consistently been reported in the dorsolateral prefrontal cortex [12–14] as well as in the cerebellar vermis [15], similar to the findings previously reported in adult BD patients. However, there was no difference in cerebral NAA levels between offspring of BD patients who have a high risk for BD and comparison subjects [24]. This result may suggest, at least in part, that altered NAA levels in BD may be regarded as a disease marker rather than a trait marker. Normalization of abnormally reduced NAA concentrations with treatment, particularly with lithium administration, has been reported in several 1 H MRS studies (Figure 3a). Both longitudinal and cross-sectional studies suggested that lithium treatment may increase the cerebral NAA concentrations. Moore et al. [27] reported that a four-week lithium administration to BD patients was associated with increased NAA concentrations in the frontal, temporal, parietal and occipital regions. Lithium-treated BD patients showed the higher NAA concentrations in the frontal cortex [28] as well as in the basal ganglia [26] than comparison subjects and brain lithium levels were also associated with the higher NAA concentrations [30]. However, another longitudinal study conducted by Friedman et al. [31] did not demonstrate the NAA level increase with lithium as well as valproate treatments. In a study of paediatric BD patients, there were no changes in the anterior cingulate NAA levels with lithium treatment [32]. In another study, paediatric BD patients showed the increased medial prefrontal NAA levels [33] with short-term (one week) and long-term (six weeks) lithium treatment. Characteristics of the developing brain including an ongoing developmental process of pruning should be considered in interpreting the lithium effects on the brain of children with BD. Taken together, NAA reduction in BD patients is one of the most frequently replicated findings and the potential normalization of the NAA reduction with the treatment, lithium in particular, has been reported by a number of studies (Table 1). These findings support possible neuronal and the mitochondrial involvement in the pathophysiology of BD.
Choline-containing compounds (Cho) (Table 2) The Cho resonance is detected at 3.23 ppm and one of the major components of Cho are soluble membrane phospholipid metabolites including phosphocholine (PC), and glycerophosphocholine (GPC) [49]. Free choline and acetylcholine contribute less than 5% of the signal [49]. PC is used in the synthesis of membrane phospholipids, while
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Fig. 3 Schematic presentation of the findings from longitudinal 1 H MRS studies that examine medication effects on brain metabolite levels in adult patients with bipolar disorder. See also Plate 3. Abbreviations: Cho, Choline; Cr, Creatine; Glx, Glutamate, Glutamine and g-amino butyric acid; HDRS, 17-item Hamilton Depression Rating Scale; MRS, Magnetic Resonance Spectroscopy; NAA, N-acetylaspartate. (a) Lithium effects on brain metabolite levels in patients with bipolar disorder. Regular triangles represent increase in brain metabolite levels or metabolite/Cr þ PCr ratios in patients with bipolar disorder after lithium treatment compared to those in their baseline. Inverted triangles represent decrease in brain metabolite levels or metabolite/Cr þ PCr ratios in patients with bipolar disorder after lithium treatment compared to those in their baseline. Rectangles represent no changes in metabolite levels or metabolite/Cr þ PCr ratios in patients with bipolar disorder after lithium treatment. (b) Cytidine effect on brain metabolite levels and depressive symptoms in depressed patients with bipolar disorder. Bars represent estimated glutamate/glutamine changes from baseline in cytidine and placebo add-on patients with bipolar depression. P values above the bars indicate significant difference between treatment groups in rates of decreasing glutamate/glutamine levels throughout the treatment period with mixed-effect regression model. Squares and trend lines represent the estimated HDRS score in cytidine and placebo add-on patients with bipolar depression. Asterisks represent p < 0.01 significant difference between treatment groups in rates of improvement in HDRS scores from Week 1 through Week 4 with mixed-effect regression model. (Reprinted from Yoon et al., in press. Decreased glutamate/glutamine levels may mediate cytidines efficacy in treating bipolar depression: A longitudinal proton magnetic resonance spectroscopy study. Neuropsychopharmacology, with permission from Nature Publishing Group).
GPC is the product of degradation of membrane phospholipids [50]. Cho is required for the synthesis of the neurotransmitter acetylcholine and phosphatidylcholine, the key component of the phospholipid membrane [1]. Since acetylcholine is produced only in cholinergic neurons and the synthesis of phosphatidylcholine occurs within all cells, altered Cho signal is likely to primarily reflect the changes in phospholipid membrane metabolism [51]. Elevated cerebral Cho concentrations have frequently been reported in the 1 H MRS studies of BD. Moore et al. [45] reported that BD patients exhibited the higher Cho/Cr þ PCr ratios in the cingulate cortex than comparison subjects. Altered Cho/Cr þ PCr ratios were correlated with more severe depressive symptoms. They also investigated medication effects on cerebral Cho levels. BD patients taking antidepressant medications, but not lithium or valproate, showed reductions of Cho/Cr þ PCr ratios to the level comparable to that observed in comparison subjects. Higher Cho concentrations or Cho/Cr þ PCr ratios in BD patients relative to comparison subjects were also
observed in the basal ganglia [16,46]. In contrast, reduced frontal Cho signals were also reported in medication-free BD patients [21]. Several 1 H MRS studies examining the dorsolateral prefrontal cortex and hippocampus did not find any altered Cho levels in BD patients relative to comparison subjects [4,5,7–9,11,20,22]. Until recently, only a few 1 H MRS studies have examined the effects of medication, especially lithium, on Cho signals in BD patients. Most of the studies suggest that lithium treatment may not alter cerebral Cho levels [30,31,46,48]. However, one study suggested that chronic lithium treatment was associated with a reduction in Cho levels [36], while another study reported that BD patients treated with lithium had a higher Cho/Cr þ PCr ratio relative to comparison subjects [26]. Stoll et al. [52] examined the efficacy of choline treatment and its effects on brain metabolite levels in six treatmentrefractory patients with rapid-cycling BD. Interestingly, choline, in the presence of lithium, exerted a successful treatment efficacy and increased Cho levels in the basal ganglia. In a double-blind trial of eight lithium-treated
Subjects
Gender (M/F)
Moore et al. [45]
Hamakawa et al. [16]
5/13
6/14
5/4
6/8
20 controls
9 patientsc
14 controls
5/14
18 patients
19 controls
36 (11)
38 (10)
44 (10)
46 (13)
40 (6)
42 (10)
Mean age (SD)
predominantly depressed all mediated not available
11 and 16 examined in depressive and euthymic states, respectively (some examined repeatedly) 4 cases medication-free not available 9 BD I
STEAM
CSI
1.5 T
STEAM
each voxel 2 cm3
bilateral ACC
27 cm3
single voxel
" Cho/Cr þ PCr ratio in right ACC
" Cho levels in basal ganglia in BD patients with depressive episode " Cho/Cr þ PCr and Cho/NAA ratios in basal ganglia in BD patients with depressive or euthymic episodes
no difference in Cho/Cr þ PCr ratio between lithium-treated and non-treated patients
27 cm3
left basal ganglia
STEAM
10 treated with lithium age of onset, 31.7 8 BD I, 10 BD II
" Cho/Cr þ PCr ratio in basal ganglia
Results Cho/Cr þ Pcr or Cho levelsb
left basal ganglia
Regions of examined/ Voxel size
1.5 T
single voxel
1.5 T
Imaging methods (field strength/ technique/ acquisition)
all euthymic
10 BD I, 9 BD II
Patients characteristics (subtype/current episode/medication/ illness durationa)
positive correlation between Cho/Cr þ PCr ratio and HDRS scores
not examined
no association between Cho/Cr þ PCr ratio and age
Clinical correlations
|
Studies on the adult patients with bipolar disorder Kato et al. [46] 19 patients 5/14
Study
Table 2 Published 1 H MRS research on Cho/Cr þ PCr and Cho levels in patients with bipolar disorder.
146 Chapter 14
Deicken et al. [25]
Winsberg et al. [5]
Hamakawa et al. [17]
Frey et al. [21]
Cecil et al. [6]
15/0
9/11
20 controls
15 patients
9/11
7/13
20 controls
20 patients
8/15
10/22
32 controls
23 patients
11/21
9/12
21 controls
32 patients
6/11
17 patients
41 (11)
34 (14)
38 (14)
37 (10)
45 (11)
34 (9)
34 (10)
22 (5)
22 (7)
all euthymic all medication-free for at least 2 wk 15.0 (12.8) 15 BD I
all euthymic, 8 subjects were also examined in depressive episode 4 cases medication-free not available 10 BD I/10 BD II
7 hypomanic, 17 depressed, 1 mixed, 7 euthymic all medication free at least for 2 wk 10.0 (9.6) 15 BD I, 8 BD II
9 manic, 8 mixed all medicated 5 (4) 20 BD I, 12 BD II
17 BD I
8 cm3
single voxel
-15.6 cm3 single voxel
bilateral thalamus
8 cm3 single voxel PRESS
1.5 T
bilateral DLPFC
1.5 T
STEAM
bilateral frontal cortical regions
-1.5 T
PRESS
left DLPFC
8 cm3
medial prefrontal GM/medial prefrontal WM
1.5 T
single voxel PRESS
1.5 T
no difference in Cho levels between groups
no difference in Cho/ Cr þ PCr ratios between groups
no difference in Cho levels between groups
# Cho levels in DLPFC
# Cho levels in medial prefrontal GM
no association between Cho levels and clinical characteristics (continued)
not examined
no association between metabolite levels and medication use
no association between Cho levels and clinical characteristics
positive correlation between WM Cho levels and YMRS scores
Functional Imaging Techniques
| 147
Michael et al. [18]
Deicken et al. [8]
6/2
6/2
8 controls
20/0
20 controls
8 patients
15/0
10/7
17 controls
15 patients
10/7
15/0
15 controls
17 patients
Gender (M/F)
Subjects
41 (15)
40 (14)
36 (11)
39 (10)
38 (10)
40 (13)
38 (11)
Mean age (SD)
all manic 2 medicated not available
left DLPFC
3.4 cm3 single voxel STEAM
PRESS
12 medicated 18.7 (9.5) not available
each voxel 1.1 cm3
hippocampus
hippocampus/ DLPFC/STG/ IFG/OC/ ACC/PCC/ prefrontal WM/ thalamus
each voxel 1.5 cm3
Regions of examined/ Voxel size
1.5 T
CSI
1.5 T
- spin echo sequence
CSI
all euthymic
4 manic or hypomanic, 7 depressed, 6 euthymic 6 medication-free for at least 2 wk not available 15 BD I
1.5 T
spin echo sequence
13 medicated 22.1 (9.7) 17 BD I
Multi-slice
Imaging methods (field strength/ technique/ acquisition)
all euthymic
Patients characteristics (subtype/current episode/medication/ illness durationa)
no difference in Cho levels between groups
no difference in hippocampal Cho levels between groups
no difference in hippocampal Cho/ Cr þ PCr ratios between groups
Results Cho/Cr þ Pcr or Cho levelsb
not examined
not examined
not examined
Clinical correlations
|
Bertolino et al. [7]
Study
Table 2 (Continued)
148 Chapter 14
Scherk et al. [11]
Atmaca et al. [9]
Brambilla et al. [20]
Dager et al. [19]
6/7
6/7
13 controls
6/6
12 controls
13 patients
6/6
16/16
32 controls
12 patients
2/8
10/14
24 controls
10 patients
13/16
29 patients
31 (6)
32 (6)
27 (8)
28 (7)
35 (10)
37 (14)
32 (8)
30 (11)
all euthymic
PRESS
not available not available 13 BD I
single voxel
1.5 T
CSI
1.5 T
single voxel STEAM
1.5 T
PEPSI
CSI
1.5 T
all manic
1 depressed, 9 euthymic 4 medication-free at least for 2 wk 15.9 (10.3) 12 BD I
all predominantly depressed all medication-free 13.5 (10.2) 8 BD I, 2 BD II
11 BD I, 17 BD II, 1 BD NOS
3.5 cm3 (hippocampus)/
left
each voxel 0.84 cm3
hippocampus
8 cm3
left DLFPC
frontal WM/ cingulate/ caudate/ putamen/ thalamus/ insula/ parietal WM (all bilateral)/ midline occipital each voxel 1 cm3
hippocampus/left thalamus/left putamen
no difference in hippocampal Cho/ Cr þ PCr ratios between groups
no difference in Cho levels between groups
no difference in Cho levels in GM and WM between groups
(continued)
no difference in hippocampal Cho/Cr þ PCr ratios between groups
not examined
negative correlation between Cho levels and number of prior affective episodes
no association between Cho levels and clinical symptoms
Functional Imaging Techniques
| 149
11/10
21 controls
34 (10)
36 (12)
55 (2)
Davanzo et al. [47]
non12 (4) gender matched
13 controls
10 (2)
13 (3)
8/2
6/5
10 patients
11 controls
Studies on the adolescents or children with bipolar disorder Chang et al. [12] 15 patients 13/2 13 (3)
7/8
15 patients
9/10
19 controls
54 (2)
Mean age (SD)
PRESS
5 medicated not available
medial frontal cortex/ occipital cortex 8 cm3
1.5 T
single voxel
-8 cm3 single voxel PRESS
bilateral DLPFC
8 cm3
single voxel PRESS
3T
ACC, parietooccipital cortex
12 cm3
bilateral hippocampus
3.4 cm3 (thalamus)/ 3.3 cm3 (putamen)
Regions of examined/ Voxel size
3T
single voxel PRESS
7 manic, 3 mixed
all euthymic 14 medicated not available 10 BD I
not available
all manic all medicated age of onset, 25.5 (9.5)
all euthymic all medicated not available 15 BD I
3T
spin echo sequence
all medicated
8.2 (6.5) 21 BD I
Imaging methods (field strength/ technique/ acquisition)
Patients characteristics (subtype/current episode/medication/ illness durationa)
no difference in Cho levels between groups
no difference in Cho/ Cr þ PCr ratio between groups
no difference in Cho levels between groups
no difference in Cho levels between groups
Results Cho/Cr þ Pcr or Cho levelsb
not examined
not examined
no association between metabolite levels and medication status
not examined
Clinical correlations
|
€ u € r et al. [4] Ong
10/11
21 patients
Colla et al. [22]
Gender (M/F)
Subjects
Study
Table 2 (Continued)
150 Chapter 14
Cecil et al. [15]
Castillo et al. [23]
Olvera et al. [14]
Gallelli et al. [24]
Sassi et al. [13]
5/4
6/4
10 controls
8/2
10 controls
9 patients
9/1
10 patients
19/15
36 controls
11 (2)
10 (1)
non-age matched
8
14 (3)
13 (3)
14 (3)
17/9
17/18
12 (3)
19/9
28 with prodromal symptoms 26 controls
35 patients
14 (3)
17 (4)
22/10
9/7
18 controls
16 (3)
32 patient
6/8
14 patients
1 medicated not available
PRESS
all medication free at least for 1 wk not available 3 BD I, 3 BD II, 1 BD NOS, 2 MDD - all euthymic
single voxel PRESS
1.5 T
single voxel
medial frontal cortex/right frontal WM/ cerebellar vermis 8 cm3
bilateral frontal lobes/ bilateral basal ganglia 8 or 27 cm3
8 cm3
single voxel PRESS 1.5 T
left DLPFC
8 cm3
bilateral DLPFC
8 cm3
left DLPFC
1.5 T
PRESS
single voxel
3T
STEAM
single voxel
1.5 T
not available
not available 24 medicated 4.3 (3.7) not available
28 BD patients medicated not available 23 BD I, 12 BD II
not available
1 depressed, 13 euthymic 13 medicated 3.8 (2.4) not available
10 BD I, 3 BD II, 1 BD NOS
no difference in Cho levels between groups
no difference in Cho/ Cr þ PCr ratio between groups
no difference in Cho levels between groups
-no difference in Cho/ Cr þ PCr ratio between groups
no difference in Cho levels between groups
(continued)
not examined
not examined
not examined
not examined
negative correlation between Cho levels and number of prior affective episodes
Functional Imaging Techniques
| 151
Subjects
Gender (M/F) Mean age (SD)
Wu et al. [36] d
Stoll et al. [48]
35 (3) (VPA) 31 (3)
(VPA) 8/10
(lithium)
5/6
- 11 VPA treated patients
18 controls
40 (3)
32 (6)
9/5 (lithium)
6/0
6 controls
34 (9)
31 (5)
- 14 lithium treated patients
7/0
6/3
7 patients
9 controls
Effects of medication on Cho/Cr þ PCr and Cho levels 3/6 37 (3) Sharma et al. [26] 9 patients (4 BD, 4 SPR, 1 MDD)
Study
all euthymic 14 treated with lithium 11 treated with VPA not available
7 BD I, 4 BD II (VPA)
all euthymic all treated with lithium not available 7 BD I, 7 BD II (lithium)
4 manic all BD patients treated with lithium not available not available
4 BD, 4 SPR, 1 MDD
Patients characteristics (subtype/current episode/medication/ illness durationa)
PRESS
single voxel
3T
single voxel STEAM
1.5 T
single voxel STEAM
1.5 T
Imaging methods (field strength/ technique/ acquisition)
12 cm3
left temporal cortex
27 cm3
parietal cortex
15.6 cm3
basal ganglia/ occipital cortex
Regions of examined/ Voxel size
# Cho/Cr þ PCr ration in lithium/VPAtreated patients relative to controls
no difference in Cho/ Cr þ PCr ratio between lithiumtreated patients and controls
" Cho/Cr þ PCr ratio in basal ganglia in lithium-treated BD patients relative to controls
Results Cho/Cr þ Pcr or Cho levelsb
not examined
not examined
not examined
Clinical correlations
|
Table 2 (Continued)
152 Chapter 14
Davanzo et al. [32]
Forester et al. [30] f
Frye et al. [29]
Friedman et al. [31] e
9/2
—
—
11 controls
6/3
9 patients
9/2
7/5
12 controls
11 paediatric patients
17/6
5/7
12 controls
23 patients
9/12
21 patients
agematched
11
—
66 (10)
33 (11)
36 (11)
31 (6)
30 (9)
9 manic, 2 hypomanic 9 medicated at baseline not available
not available all treated lithium not available 2 BD II, 9 BD mixed
single voxel PRESS
1.5 T
single voxel PRESS, ISIS
8 cm3
ACC
8 cm3
ACC
PRESS
5 medicated 17.4 (10.4) 9 BD I 4T
27 cm3
single voxel
all depressed
frontal WM/ cingulate/ caudate/ putamen/ thalamus/ insula/ parietal WM (all bilateral)/ midline occipital each voxel 1 cm3
medial frontal cortex
PEPSI
CSI
1.5 T
1.5 T
all predominantly depressed 12 assigned to lithium treatment/9 assigned to VPA treatment not available BD I or BD II
8 BD I, 13 BD II
no changes in ACC Cho/ Cr þ PCr ratio with 1-wk lithium treatment
no association between brain lithium levels and ACC Cho levels
no difference in Cho levels between groups at baseline no changes in Cho levels with 12-wk lamotrigine treatment
no changes in GM Cho levels with lithium nor VPA treatment
(continued)
no association between metabolite ratio and serum lithium level after lithium treatment
not examined
not examined
Functional Imaging Techniques
| 153
—
—
—
16 (2)
Mean age (SD)
all depressed all medication free at least for 1 wk (19 with past history of exposure to psychotropic medication) -age of onset, 11.4 (4.0)
28 BD I
Patients characteristics (subtype/current episode/medication/ illness durationa)
single voxel PRESS
1.5 T
Imaging methods (field strength/ technique/ acquisition) medial PFC, bilateral prefrontal WM 8 cm3
Regions of examined/ Voxel size
Clinical correlations
not examined
Results Cho/Cr þ Pcr or Cho levelsb
no changes in Cho levels with 6-wk lithium treatment
Abbreviations: ACC, Anterior Cingulate Cortex; BD, Bipolar Disorder; Cho, Choline-containing compounds; Cr, Creatine; CSI, Chemical Shift Imaging; DLPFC, Dorsolateral Prefrontal Cortex; GM, Grey Matter; HDRS, Hamilton Depression Ration Scale; IFG, Inferior Frontal Gyrus; ISIS, Image Selective In vivo Spectroscopy; MDD, Major Depressive Disorder; MRS, Magnetic Resonance Spectroscopy; NAA, N-acetylaspartate; NOS, Not Otherwise Specified; OC, Occipital Cortex; PCC, Posterior Cingulate Cortex; PCr, Phosphocreatine; PEPSI, Proton Echo-Planar Spectroscopic Imaging; PRESS, Point Resolved Spectroscopy; SPR, Schizophrenia; STEAM, Stimulated Echo Acquisition Mode; STG, Superior Temporal Gyrus; T, Tesla; VPA, Valproate; WM, White Matter; YMRS, Young Mania Rating Scale. a Years (SD). b All results presented in Table 2 are those of patients with bipolar disorder relative to comparison subjects except where indicated otherwise. c Serial MRSI assessments (27 occasions) were performed in 9 BD patients. d Same cohort as Silverstone et al. [35] and Silverstone et al. [28]. e Participants of this study was a subgroup of subjects studied at baseline in the medication-free state [19]. f Lithium MRS was also conducted to measure brain lithium levels.
6/23
28 paediatric patients
Patel et al. [37]
Gender (M/F)
Subjects
Study
|
Table 2 (Continued)
154 Chapter 14
Functional Imaging Techniques
patients with rapid-cycling BD, Lyoo et al. [53] did not confirm the superior efficacy of choline treatment to the placebo administration. However, purine levels in the basal ganglia, measured by 1 H MRS, decreased with 12-week oral choline administration. This potentially means that exogenous choline administration may exert a beneficial effect on the mitochondrial function in BD through increased phospholipid synthesis. In child and adolescent BD patients, many of 1 H MRS studies did not find alterations in Cho levels relative to comparison subjects [12–14,23,47]. A number of, if not all, studies have reported the altered Cho levels in BD patients, which may reflect the impaired phospholipid metabolism in BD patients. However, this finding, observed in adult patients remains to be tested in paediatric BD patients and the potential treatment effects on Cho levels should be confirmed in the future studies.
Myo-inositol (mI) (Table 3) The primary resonance of mI lies at 3.56 ppm. Since mI is largely presented in glial cells, it has been suggested as a glial cell marker [54]. In addition, mI exerts its role as an osmolite and a storage form for glucose [55]. Most importantly, mI functions as a precursor to the phosphatidylinositol, which is a component of phospholipid membranes, as well as a substrate for the phosphoinositide secondmessenger system [39,56]. This potentially indicates that altered mI levels may be associated with the abnormal phospholipid metabolism and intracellular signalling systems. Since lithium has been recognized to exert its actions on the phosphoinositide system as a potent, noncompetitive inhibitor of inositol-1-phosphotase [57,58], several 1 H MRS studies to date have focused on the effects of lithium treatment on cerebral mI levels. Also, a substantial amount of preclinical evidence has suggested that the depletion of inositol pool might be the underlying mechanisms through which lithium works in patients with BD [57,58]. Moore et al. [34] reported that short-term as well as longterm administration of lithium decreased the frontal mI levels by about 30% in BD patients in their longitudinal follow-up study. This lithium treatment effect on mI levels was also observed in children with BD. Davanzo et al. [47] found higher prefrontal mI levels in paediatric BD patients than patients with intermittent explosive disorder as well as comparison subjects. A later longitudinal study by the same research group [32] reported that only seven days of lithium administration was required to bring reductions of the frontal cerebral mI levels in 11 children and adolescents with BD. In a study using 1 H MRS and 31 P MRS, Silverstone et al. [35] found that there were no differences in mI as well as PME levels between lithium-treated BD patients and comparison subjects. They explained this negative finding
|
155
as a potential normalization of pathophysiological alteration of the phosphoinositide cycle in BD patients treated with lithium. However, some 1 H MRS studies [26,30] reported opposite results, where BD patients treated with lithium had a greater mI levels than in comparison subjects. Similarly, a longitudinal follow-up study using 1 H MRSI to evaluate medication-free BD patients also reported increased mI levels with lithium treatment for over three months [31]. More recently, a six-week 1 H MRS study of adolescent BD patients did not find any alterations in the prefrontal mI levels after short-term (seven days) as well as long-term (42 days) lithium treatments [37]. It is challenging to explain and interpret the findings of opposite directions in increased, decreased, even unchanged mI concentrations with lithium treatment measured by 1 H MRS in BD patients. Lithium inhibits inositol-1-phosphotase may result in the accumulation of inositol monophosphates and at the same time the depletion of the inositol pool. Other literature suggests that long-term lithium treatment may increase the inositol-1-phosphotase activity [59–61], which would result in increase of the inositol pool. It should also be considered that mI resonance in 1 H MRS is the sum of mI and inositol monophosphates. Separate measurement of mI and inositol monophosphates, using both 31 P MRS and 1 H MRS, respectively, would be necessary to further examine the lithium effects on the phospholipid metabolism and the intracellular signalling systems. Please also see the following section on the results of 31 P MRS studies in BD for relevant issues.
Glutamate/glutamine/gamma-aminobutyric acid (GABA)(Glutamix, Glx) (Table 4) A mixture of closely related amino acids, including glutamate, glutamine and GABA, resonates between 2.1 and 2.4 ppm [39]. At low field strength, this overlapped resonance of Glx is hard to resolve separately [39]. Since the glutamate and glutamine may predominantly contribute to the Glx signal, this resonance has often been assumed to reflect alterations in the glutamate/glutamine cycle [1]. Until recently, several 1 H MRS studies have reported elevated Glx level in BD patients relative to comparison subjects. Dager et al. [19] studied 32 medication-free patients with BD using 1 H MRSI. Medication-free BD patients, mainly depressed, demonstrated elevated Glx and lactate levels in the cerebral grey matter relative to comparison subjects. Patients with acute mania also showed higher Glx/Cr þ PCr ratio and Glx levels in the prefrontal and parieto-occipital cortices relative to comparison subjects [4,18] and this was less likely to be due to medication effects [4]. Similarly, occipital glutamate þ glutamine/ Cr þ PCr ratios were higher in unmedicated recovered BD patients than in comparison subjects [10]. Colla et al. [22]
Sharma et al. [26]
Silverstone et al. [35] c
Davanzo et al. [32]
43 (3)
(lithium) 37 (3) (VPA) 31 (3) 37 (3)
10/6
(lithium) 5/6 (VPA) 9/10 3/6
- 16 lithium treated patients
- 11 VPA treated patients
9 patients (4 BD, 4 SPR, 1 MDD)
19 controls
age-matched
9/2
11 controls
11
9/2
11 paediatric patients
3/6
27
Mean age (SD)
9 controls
Gender (M/F)
36
Subjects
all euthymic 16 treated with lithium 11 treated with VPA - not available 4 BD, 4 SPR, 1 MDD
7 BD I, 4 BD II (VPA)
9 manic, 2 hypomanic 9 medicated at baseline not available 8 BD I, 8 BD II (lithium)
all depressed all medication free at least for 2 wk not available 2 BD II, 9 BD mixed
11 BD I, 1 BD II
Patients characteristics (subtype/current episode/medication/ illness durationa)
1.5 T
- basal ganglia/ occipital cortex
12 cm3 single voxel PRESS
left temporal cortex
8 cm3
ACC
right frontal/left temporal/ central occipital/left parietal regions 8 cm3
Regions of examined/ Voxel size
3.0 T
single voxel PRESS
1.5 T
single voxel STEAM
1.5 T
Imaging methods (field strength/ technique/ acquisition)
" mI/Cr þ PCr ratio in basal ganglia in lithiumtreated BD patients relative to controls
no difference in mI/Cr þ PCr ratio between three groups
# mI/Cr þ PCr ratio in ACC with 1-wk lithium treatment
# mI level in frontal region with 4-wk lithium treatment
Resultsb
not examined
not examined
no association between metabolite ratio and serum lithium level after lithium treatment
not examined
Clinical correlations
|
Effects of medication on mI/Cr þ PCr and mI levels Moore et al. [34] 12 patients 5/7
Study
Table 3 Published 1 H MRS research on mI/Cr þ PCr and mI levels in patients with bipolar disorder.
156 Chapter 14
Patel et al. [37]
Forester et al. [30] e
Friedman et al. [31] d
28 paediatric patients
6/23
—
—
5/7
12 controls
6/3
9/12
21 patients
9 patients
6/3
9 controls
16 (2)
—
66 (10)
31 (6)
30 (9)
31 (5)
not available all treated lithium not available 28 BD I
all predominantly depressed 12 assigned to lithium treatment/9 assigned to VPA treatment not available 9 BD I
4 manic all BD patients treated with lithium not available 8 BD I, 13 BD II
1.5 T
single voxel PRESS, ISIS
4T
PEPSI
CSI
1.5 T
single voxel STEAM
medial PFC, bilateral prefrontal WM
8 cm3
ACC
frontal WM/ cingulate/ caudate/ putamen/ thalamus/ insula/ parietal WM (all bilateral)/ midline occipital each voxel 1 cm3
15.6 cm3
significant changes in mI levels of medial PFC and right prefrontal WM with 6-wk lithium treatment
positive correlation between brain lithium levels and ACC mI levels
" GM mI levels with lithium treatment relative to VPA treatment or measurement error (follow-up of controls)
(continued)
positive correlation between changes in medial PFC mI levels from 1–6wk and changes in CDRS-R scores during same period
not examined
Functional Imaging Techniques
| 157
Gender (M/F)
—
Subjects
—
—
Mean age (SD)
single voxel
PRESS
all medication free at least for 1 wk (19 with past history of exposure to psychotropic medication) age of onset, 11.4 (4.0)
Imaging methods (field strength/ technique/ acquisition)
all depressed
Patients characteristics (subtype/current episode/medication/ illness durationa) 8 cm3
Regions of examined/ Voxel size
" mI levels on 6-wk treatment relative to those on 1-wk treatment
Resultsb
no association between mI levels and serum lithium levels
Clinical correlations
Abbreviations: ACC, Anterior Cingulate Cortex; BD, Bipolar Disorder; CDRS-R, Childrens Depression Rating Scale-Revised; Cr, Creatine; CSI, Chemical Shift Imaging; Glx, Glutamate and Glutamine; GM, Grey Matter; ISIS, Image Selective In vivo Spectroscopy; MDD, Major Depressive Disorder; mI, myo-Inositol; MRS, Magnetic Resonance Spectroscopy; PCr, Phosphocreatine; PEPSI, Proton Echo-Planar Spectroscopic Imaging; PFC, Prefrontal Cortex; PRESS, Point Resolved Spectroscopy; SPR, Schizophrenia; STEAM, Stimulated Echo Acquisition Mode; T, Tesla; VPA, Valproate; WM, White Matter. a Years (SD). b All results presented in Table 3 are those of patients with bipolar disorder relative to comparison subjects except where indicated otherwise. c Same cohort as Silverstone et al. [28] and Wu et al. [36]. d Participants of this study was a subgroup of subjects studied at baseline in the medication-free state [19]. e Lithium MRS was also conducted to measure brain lithium levels.
Study
|
Table 3 (Continued)
158 Chapter 14
Bhagwagar et al. [10]
Dager et al. [19]
Michael et al. [18]
6/10
9/9
18 controls
10/14
24 controls
16 patients
13/16
6/2
8 controls
29 patients
6/2
8 patients
9/12
38 (14)
37 (14)
32 (8)
30 (11)
41 (15)
40 (14)
22 (5)
Mean age (SD)a
21 controls
Gender (M/F)
22 (7)
Subjects
Studies on the adults patients with bipolar disorder Cecil et al. [6] 17 patients 6/11
Study
all euthymic
all predominantly depressed all medication-free 13.5 (10.2) 16 BD I
all manic 2 medicated not available 11 BD I, 17 BD II, 1 BD NOS
9 manic, 8 mixed all medicated 5 (4) not available
17 BD I
Patients characteristics (subtype/current episode/medication/ illness durationa)
single voxel
3T
PEPSI
CSI
1.5 T
single voxel STEAM
1.5 T
single voxel PRESS
1.5 T
Imaging methods (field strength/ technique/ acquisition)
Table 4 Published 1 H MRS research on Glx/Cr þ PCr and Glx levels in patients with bipolar disorder.
" Glx/Cr þ PCr ratio in occipital cortex
# GABA/Cr þ PCr ratio in occipital cortex
18 cm3
" lactate levels in GM
" Glx levels in GM
" Glx levels in left DLPFC
" Composite amino acid signal in medial prefrontal WM
Results on Glx/ Cr þ PCr ratio or Glx levelsb
occipital-parietal region
frontal WM/ cingulate/ caudate/ putamen/ thalamus/insula/ parietal WM (all bilateral)/ midline occipital each voxel 1 cm3
3.4 cm3
left DLPFC
8 cm3
medial prefrontal GM/medial prefrontal WM
Regions of examined/Voxel size
(continued)
no association between Glx or GABA ratios and clinical characteristics
no association between Glx or lactate levels and clinical symptoms
not examined
negative correlation between orbitofrontal WM AA levels and valproate treatment duration
Clinical correlations
Functional Imaging Techniques
| 159
Frey et al. [21]
11/21
10/22
32 controls
9/10
19 controls
32 patients
10/11
21 patients
11/10
21 controls
34 (9)
34 (10)
55 (2)
54 (2)
34 (10)
36 (12)
Mean age (SD)a
7 hypomanic, 17 depressed, 1 mixed, 7 euthymic all medication free at least for 2 wk 10.0 (9.6)
PRESS
all medicated not available 20 BD I, 12 BD II
PRESS
single voxel
1.5 T
single voxel
3T
single voxel PRESS
all euthymic
all manic all medicated age of onset, 25.5 (9.5) 21 BD I
PRESS
all medication-free for at least 3 mo 2 (range 0.5 to 10.1) 15 BD I 3T
Imaging methods (field strength/ technique/ acquisition)
Patients characteristics (subtype/current episode/medication/ illness durationa)
8 cm3
left DLPFC
12 cm3
bilateral hippocampus
8 cm3
ACC, parietooccipital cortex
Regions of examined/Voxel size
no difference in Glx levels between groups
" glutamate levels in bilateral hippocampus
" Glutamine/ glutamate ratio in ACC and parietooccipital regions
Results on Glx/ Cr þ PCr ratio or Glx levelsb
no association between Glx levels and clinical characteristics
negative correlation between glutamate levels and diurnal saliva cortisol levels positive correlation between hippocampal NAA and glutamate levels
no association between metabolite levels and medication status
Clinical correlations
|
Colla et al. [22]
7/8
15 patients
€ u € r et al. [4] Ong
Gender (M/F)
Subjects
Study
Table 4 (Continued)
160 Chapter 14
Olvera et al. [14]
Moore et al. [62]
Davanzo et al. [47]
17/18
19/15
35 patients
36 controls
15 ADHD 7 controls
not available
non-gender matched
13 controls
8 ADHD þ BD
8/2
8/2
10 patients
10 controls
14 (3)
13 (3)
6 to 13 yr old
12 (4)
10 (2)
non-age matched
Studies on the adolescents or children with bipolar disorder Castillo et al. [23] 10 patients 9/1 8
PRESS
all medication free at least for 1 wk not available 10 BD I
not available 24 medicated 4.3 (3.7)
not available 3 ADHD medicated 2 ADHD þ BD medicated not available 23 BD I, 12 BD II
PRESS
5 medicated not available not available
single voxel PRESS
1.5 T
single voxel PRESS
1.5 T
single voxel
7 manic, 3 mixed
1.5 T
single voxel
1.5 T
not available
not available
8 cm3
left DLPFC
4.8 cm3
ACC
8 cm3
medial frontal cortex/occipital cortex
8 or 27 cm3
bilateral frontal lobes/bilateral basal ganglia
no difference in Glx levels between groups
# ACC Glx/ Cr þ PCr and Glx/mI ratios in BD patients relative to ADHD þ BD patients
no difference in Glx levels between groups
" Glx/Cr þ PCr ratio in bilateral frontal lobe and basal ganglia
(continued)
not examined
not examined
not examined
not examined
Functional Imaging Techniques
| 161
Frye et al. [29]
17/6
7/5
23 patients
12 controls
5/7
33 (11)
36 (11)
31 (6)
Mean age (SD)a
12 controls
Gender (M/F)
30 (9)
Subjects
all depressed
PEPSI
12 assigned to lithium treatment/9 assigned to VPA treatment not available BD I or BD II
single voxel
1.5 T
CSI
-1.5 T
Imaging methods (field strength/ technique/ acquisition)
all predominantly depressed
8 BD I, 13 BD II
Patients characteristics (subtype/current episode/medication/ illness durationa)
27 cm3
medial frontal cortex
frontal WM/ cingulate/ caudate/ putamen/ thalamus/insula/ parietal WM (all bilateral)/ midline occipital each voxel 1 cm3
Regions of examined/Voxel size
" Glx and glutamate levels at baseline " Glx and glutamate levels in nonmelancholic depressed patients relative to melancholic subjects
# GM Glx levels with lithium treatment relative to VPA treatment or measurement error (followup of controls) no changes in GM lactate levels with lithium nor VPA treatment
Results on Glx/ Cr þ PCr ratio or Glx levelsb
not examined
Clinical correlations
|
Effects of medication on Glx/Cr þ PCr and Glx levels 21 patients 9/12 Friedman et al. [31] c
Study
Table 4 (Continued)
162 Chapter 14
Moore et al. [64]
Moore et al. [63]
—
—
11 (3)
(unmedicated)
8 atypical antipsychotics treated (unmedicated) 10 unmedicated — not available
(antipsychotic 12 manic treated)
5/5
PRESS
CSI
each voxel 4.8cm3
ACC
PRESS
7 unmedicated, 15 medicated not available 18 BD I 1.5 T
8 cm3
single voxel
10 manic, 9 mixed, 1 depressed, 2 euthymic
(8 atypical antipsychotics treated/10 unmedicated)
12 (3)
ACC
4.0 T
17.4 (10.4) 22 BD I
11 (3) 7/1 (antipsychotic treated)
3/10
10 controls
13 (4)
18 paediatric patients
9/13
22 paediatric patients
PRESS
5 medicated
" Glx/Cr þ PCr ratios in patients treated with atypical antipsychotics relative to unmedicated patients
" glutamine levels in medicated patients relative to unmedicated patients no significance difference in glutamate levels between unmedicated and medicated patients
# glutamine levels in remitted patients with 12-wk lamotrigine treatment relative to nonremitted subjects
(continued)
negative correlations between ACC Glx/Cr þ PCr ratios and YMRS/ CGI-mania scores
Trend in negative correlations between ACC glutamate levels and CDRS scores
Functional Imaging Techniques
| 163
—
—
—
16 (2)
—
all depressed all medication free at least for 1 wk (19 with past history of exposure to psychotropic medication) age of onset, 11.4 (4.0)
all depressed 18 assigned to cytidine þ VPA treatment/17 assigned to placebo þ VPA treatment 13.6 (9.2) 28 BD I
22 BD I, 13 BD II
Patients characteristics (subtype/current episode/medication/ illness durationa)
single voxel PRESS
1.5 T
single voxel PRESS
3.0 T
Imaging methods (field strength/ technique/ acquisition)
8 cm3
medial PFC, bilateral prefrontal WM
3.4 cm3
ACC
Regions of examined/Voxel size
no changes in Glx levels with 6wk lithium treatment
# ACC Glx levels with cytidine add-on treatment relative to placebo addon treatment
Results on Glx/ Cr þ PCr ratio or Glx levelsb
not examined
positive correlations between ACC Glx levels changes and HDRS score changes in cytidine add-on group not in placebo add-on group
Clinical correlations
Abbreviations: AA, Amino Acid; ACC, Anterior Cingulate Cortex; ADHD, Attention-Deficit Hyperactivity Disorder; BD, Bipolar Disorder; CDRS, Childrens Depression Rating Scale; CGI-mania, mania subscale of the Clinical Global Impression Bipolar Disorder Scale; Cr, Creatine; CSI, Chemical Shift Imaging; DLPFC, Dorsolateral Prefrontal Cortex; GABA, g-Aminobutric Acid; Glx, Glutamate and Glutamine; GM, Grey Matter; HDRS, Hamilton Depression Ration Scale; MRS, Magnetic Resonance Spectroscopy; NAA, N-acetylaspartate; NOS, Not Otherwise Specified; PCr, Phosphocreatine; PEPSI, Proton Echo-Planar Spectroscopic Imaging; PFC, Prefrontal Cortex; PRESS, Point Resolved Spectroscopy; STEAM, Stimulated Echo Acquisition Mode; T, Tesla; VPA, Valproate; WM, White Matter; YMRS, Young Mania Rating Scale. a Years (SD). b All results presented in Table 4 are those of patients with bipolar disorder relative to comparison subjects except where indicated otherwise. c Participants of this study was a subgroup of subjects studied at baseline in the medication-free state [19].
6/23
28 paediatric patients
—
—
35 (9)
Mean age (SD)a
|
Patel et al. [37]
18/17
35 patients
Yoon et al. [65]
Gender (M/F)
Subjects
Study
Table 4 (Continued)
164 Chapter 14
Functional Imaging Techniques
determined the hippocampal glutamate levels out of overlapped resolution spectrum of Glx using 3 Tesla scanner. They found elevated glutamate levels in remitted BD patients relative to comparison subjects. Based on the consistent findings of elevated Glx levels in BD, a few studies in BD patients, examining the effects of medications targeting glutamatergic neurotransmission, have been conducted. Frye et al. [29] examined prefrontal Glx levels in patients with bipolar depression. Increased prefrontal Glx levels were observed in BD patients and increased glutamine levels appeared to be reduced with treatment of 12-week lamotrigine administration. A recent longitudinal 1 H MRS study reported that 12-week cytidine supplementation to valproate decreased prefrontal Glx levels in patients with bipolar depression relative to placebo supplementation [65]. Cytidine is a dietary agent, known to exert its actions on the neuronal-glial glutamate cycling and cytidine-induced reductions in cerebral Glx levels in patients with bipolar depression were correlated with resolution of depressive symptoms (Figure 3b). Lithium treatment, but not valproate, was also suggested to decrease GM Glx levels [31]. In their study, the authors suggested that lithium may potentially normalize the bioenergetic alterations of the redox state in BD, based on the results of the GM Glx elevation from the same cohort of medication-free patients [19]. There have been some inconsistencies in the alterations of Glx levels in paediatric BD patients. As compared with healthy children, Castillo et al. [23] found that children with BD showed similarly elevated levels of Glx in the frontal and the basal ganglia regions compared to those of adult patients. Alterations in glutamatergic neurotransmission were also suggested in BD children who were comorbid with attention deficit hyperactivity disorder [62]. In contrast, Olvera et al. [14] did not find alterations in cerebral Glx levels in 35 paediatric BD patients. In the study of child and adolescent BD patients using a 4T 1 H MRS, Moore et al. [63] reported that unmedicated patients showed lower prefrontal glutamine levels than medicated patients and comparison subjects, while there was no difference in the prefrontal glutamate levels between groups. In line with these findings, a recent study of paediatric BD patients with manic episode showed lower prefrontal Glx/Cr þ PCr ratio in patients with manic episode than in those stably treated with the atypical antipsychotics [64]. Glutamatergic neurotransmissional abnormalities in patients with BD may reflect disturbed neuronal-glial interactions, which are involved in the glutamate to glutamine conversion in glial cells and glutamine to glutamate conversion in neurons [4]. This hypothesis is supported by several post-mortem studies reporting the glial cell reductions in BD [66–69]. Alternatively, increased demands on neuronal energy metabolism induced by the elevated levels of excitatory neurotransmitter including glutamate may
|
165
disconcert the normal balance between the mitochondrial oxidative phosphorylation and the glycolysis in BD [1,19]. However, further studies will be needed to confirm the role of glutamate and glutamine in the pathophysiology of BD.
Creatine (Cr)/phosphocreatine (PCr)(Table 5) Cr peak lies on 3.02 ppm on the 1 H spectrum and reflects the sum of both Cr and PCr. PCr is the central energy marker and acts as a reservoir for the generation of ATP [70]. Maintenance of equilibrium between Cr and PCr is regulated by the cellular demand for high-energy phosphate. The resonance of Cr on the 1 H spectrum has been regarded as relatively “constant” in normal brain [71] and could be thus used as the internal reference value to each metabolite peak in several 1 H MRS studies. Evidence from the recent studies, however, indicates that cerebral Cr levels could be altered in several pathological conditions [72]. Cr also exerts a role in the cerebral osmoregulation [73]. BD patients demonstrated the reduced Cr þ PCr levels in the dorsolateral prefrontal cortex [21] as well as in the hippocampus [8] relative to comparison subjects. Hamakawa et al. [17] reported that reductions in Cr þ PCr levels were greater in depressed than in euthymic BD patients. This might indicate a state-dependent alteration of Cr þ PCr levels in BD. In their study, there was a gender specific difference in Cr þ PCr concentration in BD patients. Similarly, higher Cr þ PCr levels were reported in the thalamus of male BD patients [25] relative to comparison subjects. Frye et al. [29] reported higher Cr þ PCr levels in the prefrontal cortex in patients with bipolar depression than in comparison subjects. In contrast to the previous research, there have been several studies that did not find any alterations of Cr þ PCr levels in patients with BD [6,18–20].
Phosphorous (31p) MRS (Table 6) Membrane phospholipid: phosphomonoester (PME) and phosphodiester (PDE) PMEs are composed of various metabolites including PC and phosphoetanolamine, which are the major precursors of phospholipids [84]. Inositol-1-phosphate may contribute to this resonance, particularly in conditions where it accumulates due to the inhibition of inositol-1-phosphotase [85]. PDEs include more mobile phospholipids and are the major product of phospholipid breakdown including GPC and glycerophosphoethanolamine [84]. Both signals of PME and PDE may reflect the turnover of membrane phospholipid turnover. Changes in PME and PDE signals may also indicate the alteration of membrane integrity in both neuronal and non-neuronal tissues. Several 31 P MRS studies, thus far, have suggested that changes in the cerebral PME levels may show a
Subjects
Gender (M/F)
Mean age (SD)
Frye et al. [29]
17/6
7/5
12 controls
10/22
32 controls
23 patients
11/21
20/0
20 controls
32 patients
15/0
Deicken et al. [8] 15 patients
Frey et al. [21]
7/13
20 controls
33 (11)
36 (11)
34 (9)
34 (10)
36 (11)
39 (10)
37 (10)
1.5 T
Imaging methods (field strength/ technique/ acquisition)
single voxel
PRESS
5 medicated 17.4 (10.4)
1.5 T
27 cm3
medial frontal cortex
8 cm3
single voxel
each voxel 1.1 cm3
hippocampus
left DLPFC
PRESS
Results on Cr þ PCr levelsb
no association between Cr þ PCr levels and clinical characteristics
not examined
no association between metabolite levels and medication use
Clinical correlations
not examined " Cr þ PCr levels in medial frontal cortex at baseline no changes in Cr þ PCr levels with 12-wk lamotrigine treatment
# Cr þ PCr levels in DLPFC
# Cr þ PCr levels in bilateral hippocampus
- bilateral frontal cortical # Cr þ PCr levels in left regions frontal region in depressed patients relative to euthymic patients 15.6 cm3
Regions of examined/Voxel size
1.5 T
CSI PRESS
all depressed
7 hypomanic, 17 depressed, 1 mixed, 7 euthymic all medication free at least for 2 wk 10.0 (9.6) BD I or BD II
all euthymic 12 medicated 18.7 (9.5) 20 BD I, 12 BD II
single voxel all euthymic, 8 subjects were also examined in depressive episode 4 cases medication-free STEAM not available 1.5 T 15 BD I
15 BD I, 8 BD II
Patients characteristics (subtype/current episode/medication/ illness durationa)
|
Studies on the adults patients with bipolar disorder Hamakawa 23 patients 8/15 45 (11) et al. [17]
Study
Table 5 Published 1 H MRS research on Cr þ PCr levels in patients with bipolar disorder.
166 Chapter 14
Colla et al. [22]
Brambilla et al. [20]
Dager et al. [19]
Michael et al. [18]
Cecil et al. [6]
Deicken et al. [25]
10/11
9/10
19 controls
16/16
32 controls
21 patients
2/8
10/14
24 controls
10 patients
13/16
6/2
8 controls
29 patients
6/2
9/12
21 controls
8 patients
6/11
15/0
15 controls
17 patients
15/0
15 patients
55 (2)
54 (2)
35 (10)
37 (14)
32 (8)
30 (11)
41 (15)
40 (14)
22 (5)
22 (7)
38 (11)
41 (11)
all euthymic all medicated not available
1 depressed, 9 euthymic 4 medication-free at least for 2 wk 15.9 (10.3) 21 BD I
all predominantly depressed all medication-free 13.5 (10.2) 8 BD I, 2 BD II
all manic 2 medicated not available 11 BD I, 17 BD II, 1 BD NOS
9 manic, 8 mixed all medicated 5 (4) not available
22.1 (9.7) 17 BD I
all euthymic 13 medicated
15 BD I
single voxel PRESS
3T
single voxel STEAM
1.5 T
PEPSI
CSI
1.5 T
single voxel STEAM
1.5 T
single voxel PRESS
12 cm3
bilateral hippocampus
8 cm3
left DLFPC
frontal WM/cingulate/ caudate/putamen/ thalamus/insula/ parietal WM (all bilateral)/midline occipital each voxel 1 cm3
3.4 cm3
left DLPFC
medial prefrontal8 GM/ medial prefrontal8 WM 8 cm3
each voxel 1.5 cm3
Multi-slice spin echo sequence 1.5 T
bilateral thalamus
1.5 T
no difference in Cr þ PCr levels between groups
no difference in Cr þ PCr levels between groups
no difference in Cr þ PCr levels in GM and WM between groups
no difference in Cr þ PCr levels between groups
no difference in Cr þ PCr levels between groups
no difference in Cr þ PCr levels between groups
(continued)
not examined
no association between Cr þ PCr levels and clinical characteristics
negative correlation between WM Cr levels and HDRS scores
not examined
not examined
no association between Cr þ PCr levels and clinical characteristics
Functional Imaging Techniques
| 167
11/10
21 controls
34 (10)
36 (12)
Mean age (SD)
17/18
19/15
36 controls
non-
13 controls
35 patients
8/2
9/7
18 controls
10 patients
6/8
14 patients
6/4
14 (3)
13 (3)
gender
10 (2)
17 (4)
16 (3)
11 (2)
not available 24 medicated 4.3 (3.7)
PRESS
5 medicated not available 23 BD I, 12 BD II
single voxel PRESS
1.5 T
12 (4)
matched
1 depressed, 13 euthymic single voxel 13 medicated STEAM 3.8 (2.4) 1.5 T 10 BD I
single voxel 1 medicated not available PRESS 10 BD I, 3 BD II, 1 BD NOS 1.5 T
8 cm3
left DLPFC
7 manic, 3 mixed
medial frontal cortex/ occipital cortex
8 cm3
left DLPFC
no difference in Cr þ PCr levels between groups
no difference in Cr þ PCr levels between groups single voxel
trend in # Cr þ PCr levels in left DLPFC
trend in # Cr þ PCr levels in cerebellar vermis
no difference in Cr þ PCr levels between groups
Results on Cr þ PCr levelsb
not examined
8 cm3
not examined
no association between Cr þ PCr levels and clinical characteristics
not examined
no association between metabolite levels and medication status
Clinical correlations
Abbreviations: ACC, Anterior Cingulate Cortex; BD, Bipolar Disorder; Cr, Creatine; CSI, Chemical Shift Imaging; DLPFC, Dorsolateral Prefrontal Cortex; GM, Grey Matter; HDRS, Hamilton Depression Rating Scale; MDD, Major Depressive Disorder; MRS, Magnetic Resonance Spectroscopy; NOS, Not Otherwise Specified; PCr, Phosphocreatine; PRESS, Point Resolved Spectroscopy; STEAM, Stimulated Echo Acquisition Mode; T, Tesla; WM, White Matter. a Years (SD). b All results presented in Table 5 are those of patients with bipolar disorder relative to comparison subjects except where indicated otherwise.
Olvera et al. [14]
Davanzo et al. [47]
Sassi et al. [13]
10 controls
8 cm3
single voxel PRESS
medial frontal cortex/ right frontal WM/ cerebellar vermis 8 cm3
ACC, parieto-occipital cortex
Regions of examined/Voxel size
3T
Imaging methods (field strength/ technique/ acquisition)
3 BD I, 3 BD II, 1 BD NOS, 1.5 T 2 MDD - all euthymic
all manic all medicated age of onset, 25.5 (9.5)
15 BD I
Patients characteristics (subtype/current episode/medication/ illness durationa)
|
Studies on the adolescents or children with bipolar disorder Cecil et al. [15] 9 patients 5/4 10 (1)
7/8
15 patients
€ u € r et al. [4] Ong
Gender (M/F)
Subjects
Study
Table 5 (Continued)
168 Chapter 14
Kato et al. [77]
Kato et al. [76]
4/6
gender matched
9 controls
10 patients
7/4
12/2
14 controls
11 patients
10/2
12 patients
16/0
16 controls
Deicken et al. [75]
12/0
12 patients
Deicken et al. [74]
Gender (M/F)
Subjects
Study
42 (9)
40 (11)
41 (11)
40 (10)
40 (8)
40 (11)
40 (9)
Mean age (SD)
all manic, 7 repeatedly scanned at euthymic after lithium treatment not available not available not available
all euthymic all medication free at least for 1 wk not available not available
spin echo sequence
all medication free at least for 1 wk not available not available
1.5 T
frontal lobe
not available
single voxel
DRESS
frontal lobe
25 cm3
right and left temporal lobes
25 cm3
right and left frontal lobes
Regions of examined/Voxel size
1.5 T
MRSI spin echo sequence
2T
single voxel
2T
Imaging methods (field strength/ technique/ acquisition)
all euthymic
not available
Patients characteristics (subtype/current episode/medication/ illness durationa)
Table 6 Published 31 P MRS research in patients with bipolar disorder.
# PME and pHi levels in euthymic BD patients relative to controls
" PME/total phosphorous compounds ratios in manic patients relative to euthymic patients and controls
# PME level in bilateral temporal lobes in euthymic patients
# PME level in bilateral frontal lobes in euthymic patients " PDE level in bilateral frontal lobes in euthymic patients
Resultsb
(continued)
not examined
no association between PME/ total phosphorous compounds ratios and duration/ serum levels of lithium treatment
not examined
not examined
Clinical correlations
Functional Imaging Techniques
| 169
16/24
27/33 8/21
40 patients
60 controls 29 patients
Kato et al. [80]
gender matched
17 controls
Kato et al. [79]
8/9
gender matched
10 controls
17 patients
Gender (M/F)
Subjects
40 (14) 43 (12)
42 (12)
39 (10)
40 (11)
41 (9)
Mean age (SD)
14 BD I, 15 BD II
all euthymic all patients treated with lithium, 11 with antipsychotics, 6 with antidepressants
1.5 T
single voxel DRESS
frontal lobe
not available
frontal lobe
DRESS
all medicated not available 31 BD I, 9 BD II 1.5 T
not available
single voxel
all patients repeatedly scanned at euthymic and manic states
DRESS
3 medicated at baseline not available not available frontal lobe
not available
single voxel
all depressed, all patients repeatedly scanned at euthymic after treatment
1.5 T
Regions of examined/Voxel size
Imaging methods (field strength/ technique/ acquisition)
Patients characteristics (subtype/current episode/medication/ illness durationa)
# PCr levels in BD II (all states) patients relative to controls
# PME and pHi levels in frontal lobe
# PME and pHi levels in euthymic BD patients relative to controls " PME and pHi levels in manic states relative to euthymic states in BD patients
" PME and pHi levels in depressed states relative to euthymic states in BD patients
Resultsb
no association between PME/ PCr/pHi levels and HDRS scores
no association between PME levels and ventricular enlargement
no association between PME/pHi levels and brain lithium levels
Clinical correlations
|
Kato et al. [78]
Study
Table 6 (Continued)
170 Chapter 14
Murashita et al. [82]
Kato et al. [81]
3/16
12/13
25 controls
6/15
21 controls
19 patients
8/17
27/32
25 patients
59 controls
37 (14)
46 (10)
43 (10)
40 (9)
38 (13)
all euthymic all medicated (9 lithium responders/10 lithium nonresponders) age of onset, 32.8
13 BD I. 6 BD II
patients repeatedly scanned at euthymic (21), depressed (11), or manic (12) states
—
not available
patients repeatedly scanned at euthymic (21), depressed (25), or hypomanic (10) states 15 medicated
1.5 T
phase-encoding
CSI
1.5 T
DRESS
single voxel
occipital region
not available
frontal lobe
not available
" PME levels in hypomanic or depressed BD II patients relative to controls no difference in PME levels between euthymic BD II patients and controls # PME levels in euthymic BD I patients relative to controls # left frontal PCr levels in depressed patients relative to controls # right frontal PCr levels in euthymic and manic patients relative to controls " left frontal PME levels in depressed patients relative to controls # PCr levels in postphotic stimulations relative to prephotic stimulation in lithium-resistant bipolar patients, however, neither in controls nor lithium-responders
(continued)
not examined
negative correlation between left frontal PCr levels and HDRS scores
Functional Imaging Techniques
| 171
37 (3) (VPA) 31 (3)
5/6 (VPA) 9/10
6/4
10 controls
32 (14)
all euthymic all medicated not available
all euthymic 16 treated with lithium 11 treated with VPA not available not available
7 BD I, 4 BD II (VPA)
8 BD I, 8 BD II (lithium)
Patients characteristics (subtype/current episode/medication/ illness durationa)
- single voxel DRESS
1.5 T
PRESS, ISIS
single voxel
3T
Imaging methods (field strength/ technique/ acquisition)
52.5 cm3
basal ganglia
12 cm3
left temporal cortex
Regions of examined/Voxel size
# pHi levels in BD patients relative to controls
no difference in PME levels between medicated patient groups and controls
Resultsb
not examined
not examined
Clinical correlations
Abbreviations: BD, Bipolar Disorder; CSI, Chemical Shift Imaging; DRESS, Depth Resolved Surface-coil Spectroscopy; HDRS, Hamilton Depression Rating Scale; ISIS, Image Selective In vivo Spectroscopy; MRS, Magnetic Resonance Spectroscopy; MRSI, Magnetic Resonance Spectroscopic Imaging; PCr, Phosphocreatine; PDE, Phosphodiesters; PME, Phosphomonoesters; T, Tesla; VPA, Valproate. a Years (SD). b All results presented in Table 6 are those of patients with bipolar disorder relative to comparison subjects except where indicated otherwise. c Same cohort as Silverstone et al. [28] and Wu et al. [36].
7/6
13 patients
49 (12)
(lithium)
(lithium)
- 11 VPA treated patients
Hamakawa et al. [83]
43 (3)
10/6
- 16 lithium treated patients
Silverstone et al. [35] c
19 controls
Mean age (SD)
Gender (M/F)
Subjects
Study
|
Table 6 (Continued)
172 Chapter 14
Functional Imaging Techniques
state-dependent pattern in patients with BD. Studies on euthymic BD patients have consistently demonstrated that the frontal as well as temporal PME concentrations were lower in BD patients relative to comparison subjects [74,75,78,79]. In contrast, manic or hypomanic BD patients showed the higher PME levels than euthymic BD patients [76–78,80]. It remains controversial whether lithium treatment alters the PME resonance, which also includes contributions from inositol monophosphate. Yildiz et al. [86] reported that 1 and 2 weeks of lithium administration increased PME levels in healthy volunteers. In the amphetamine challenge test of Silverstone et al. [87], amphetamine challenge after 1 week of lithium treatment increased PME levels in healthy volunteers. Silverstone et al. [35] reported in a cross-sectional study that there were no differences in PME levels between lithium or valproate-treated BD patients and comparison subjects. Authors suggested that lithium or valproate treatment may normalize the altered phosphoinositide pathway in BD patients to the levels of healthy comparison subjects.
High-energy phosphates: phosphocreatine (PCr) PCr is a high-energy phosphate formed from ATP and creatine by creatine kinase and functions as a buffer of ATP [88]. Several 31 P MRS studies, if not all, suggested altered PCr levels in patients with BD. Long-term abnormalities in cerebral PCr levels may indicate alterations in cellular metabolism, including an insufficient ATP supply for normal cellular function. Abnormally lower PCr levels [80,81] and its correlation with depressive symptoms [81] have been reported in BD patients. Photic stimulation induces immediate cell activity, which might be related to short-term decreases in PCr concentrations [46]. Murashita et al. [82] conducted a photic stimulation experiment in BD patients with the poor treatment response to lithium. They found that lithiumresistant patients showed a slower recovery from reductions in PCr levels in response to photic stimulation than comparison subjects. Taken together, these alterations of PCr in BD suggest the cellular energy metabolic disturbances that are potentially related to the pathophysiological role of mitochondrial dysfunction in patients with BD. Intracellular pH (pHi) The findings of altered pHi in BD have mainly been reported by Kato and colleagues. Euthymic BD patients consistently showed reduced pHi levels in the frontal as well as in the basal ganglia regions relative to comparison subjects [77,78,80,83]. Since the levels of pHi was positively correlated with the duration of lithium treatment [79], lower pHi levels in euthymic BD patients does not appear to be related to the treatment [89]. In contrast, compared with
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euthymic BD patients or comparison subjects, manic or depressed BD patients had higher pHi levels [77,78].
Summary and clinical implications In BD patients, even though there are some inconsistencies, altered cerebral levels of various brain metabolites have been reported (Figure 2). NAA level reduction in BD patients is one of the most consistently replicated findings, which suggests decreased neuronal viability and dysfunction of the mitochondria. Another consistent finding would be the elevated glutamate levels in BD patients relative to comparison subjects. Increased extracellular glutamate levels could cause excitatory neuronal toxicity and in turn, may have resulted in decreased levels of NAA. Rapid neuronal firing in BD patients, possibly with increased glutamate levels, may have produced more lactate, causing lactate acidosis and ultimately lowering pHi levels observed in 1P MRS studies. Higher glutamate levels in BD patients relative to comparison subjects may have been caused by disturbed neuronal-glial interactions. Altered ratios of neuron numbers and glial cell numbers [66–69] could be responsible for the disturbed glutamate-glutamine cycle. Dysfunctional mitochondrial oxidative metabolism in BD patients, which is important in discharge and reuptake of glutamate, may in part explain increased levels of glutamate [90]. Drugs acting on the glutamatergic system, such as lamotrigine and cytidine, decreased the cerebral levels of glutamine or Glx in BD patients. Although results are not stable, possibly due to sample heterogeneity or different medications and mood states, alterations in cerebral Cho, mI, Cr, PCr, PME and PDE levels suggest that there are likely to be brain energy metabolism abnormalities, membrane dysfunction and the second messenger system disturbance in BD patients. Newer agents beyond neurotransmitter theory-based ones, which are intended to rebuild cell membranes or to provide pro-mitochondrial effects, could further be tested for potential effects in BD patients. There have been efforts to measure medication effects on brain metabolites and clinical relevance with MRS methodology, a tool for measuring the brain chemistry. Lithium effect was most widely studied, However, further studies are needed to confirm the effect of lithium on brain metabolites.
Diffusion tensor imaging in bipolar disorder Introduction There has been a substantial amount of evidence that white matter (WM) abnormalities play an important role in the pathophysiology of BD. White matter hyperintensities
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(WMH) on brain MRI, which have been suggested to represent dilated perivascular spaces, localized demyelination, astrocytic gliosis and atherosclerosis, are likely to interrupt WM fibres [91–93]. Previous studies have reported a greater prevalence of WMH in BD patients than in comparison subjects [94]. The increased prevalence of WMH in BD is one of the most robust and consistently replicated abnormalities reported in BD [94]. Several conventional structural brain imaging studies have suggested global [95] and regional [96] WM volume reductions in BD patients, although a recent meta-analysis did not confirm WM volume changes in BD [94]. DTI is a relatively new imaging technique and allows direct investigations of the microstructural WM integrity by measuring the microscopic diffusion of water [97–99]. Although there are several methodological issues and controversies on the DTI analysis, quantification of the directionality and the rate of microscopic water diffusion, which are reflected in fractional anisotropy (FA) and the apparent diffusivity coefficient (ADC), respectively, have most commonly been used for analysing DTIs. Reduced FA values in the WM fibres reflect a reduction in WM integrity, while increases in ADC are associated with the microstructural changes in WM consistent with a decrease in WM integrity. This modality has widely been used in the field of clinical research on traumatic brain injury, cerebral ischaemia and ageing [100]. Since Adler et al. [101] reported reduced FA in nine BD patients, the number of DTI studies involving BD patients has continuously increased. The most popular approach for the quantitative analyses of DTI is the ROI method, which is especially useful when there are a priori hypothesized brain regions. Another approach for diffusion data quantification is a voxel-based analysis (VBA), which might be appropriate when a whole brain-wise approach is more desirable. When an ROI approach is adopted, reliable voxel placement becomes an important methodological challenge. Accurate spatial normalization of DTI image sets would help reduce spurious findings in applying a voxel-based method of assessing DTI data. However, despite this limitation, analytic methods for brain DTI data are undergoing rapid evolution and DTI is likely to remain as an important tool for examination of the microstructural WM integrity. Table 7 shows the published DTI research in patients with BD.
DTI Studies of bipolar disorder using a region-of-interest approach Since abnormalities in the frontocortico-subcortical pathways have been suggested to be closely related to psychotic and mood symptoms, the frontal WM region has been considered as a critical region of interest (ROI) for DTI analysis in BD.
Reduced FA values in the anterior frontal WM, linking the prefrontal cortex with subcortical and other cortical regions, were first reported in a DTI study of BD patients [101]. In this study, FA and ADC measures were examined in eight a priori selected frontal ROIs in nine BD patients and nine comparison subjects. Haznedar et al. [103] performed structural volumetric analyses for GM/WM of the frontal cortex, in addition to a DTI analysis, using the ROI approach. In this relatively larger sample of 40 BD patients and 36 comparison subjects, BD patients had volume reductions in GM and WM of the frontal cortex. Amongst the frontal ROIs, higher relative anisotropy in the frontal intergyral association fibres was observed in BD patients relative to comparison subjects. In contrast, BD patients had lower relative FA values in the anterior fronto-occipital fasciculus connecting the orbitofrontal cortex with the temporal and occipital lobes. Amongst the ROIs of anterior and posterior limbs of the internal capsule, the connectivity in the posterior limb of the internal capsule, which primarily consists of thalamus connections, frontopontine tracts, parietopontine tracts and corticospinal tracts, was reduced in BD patients relative to comparison subjects. A study by Beyer et al. [102], however, did not find a difference in FA in any a priori selected frontal ROIs. FA values, as well as ADC of the orbitofrontal, superior frontal and middle frontal ROIs, were calculated in 14 BD patients and 21 comparison subjects. FA of all three ROIs did not differ between groups. However, higher ADC values were observed in bilateral orbitofrontal ROIs of BD patients than of comparison subjects. This result suggests microstructural abnormalities in the orbitofrontal WM of BD patients. A later study by Regenold et al. [104] was consistent with the findings of Beyer et al. [102]. DTIs from eight BD patients were examined for mean ADC values, not FA values, in eight ROIs across cerebral lobes bilaterally. When these ADC values were compared with those of nine patients with neurological disease, increases in ADC values of bilateral frontal lobe ROIs were noted (left, p ¼ 0.015 and right, p ¼ 0.012). The cingulum bundle, which participates in prefrontotemporal connections, has frequently been examined in patients with psychiatric disorders. Wang et al. [108] placed ROI of the anterior cingulum on five coronal slices anterior to the mid-anterior commissure-posterior commissure (AC-PC) slice and ROI of the posterior cingulum on five coronal slices posterior to the mid-AC-PC slice. BD patients demonstrated reduced FA in the anterior cingulum and not in the posterior cingulum relative to comparison subjects. Several studies in BD examined the WM connectivity of the corpus [105,108,109]. Wang et al. [109] used both a voxelbased approach called Statistical Parametric Mapping (SPM; Wellcome Department of Cognitive Neurology, London,
Subjects
Gender (M/F)
Mean age (SD)
Patients characteristics (subtype/current episode/ medication/illness durationa)
Regenold et al. [104]
8 patients
6/4
matched samples
40 patientsc
36 controlsc
4/17
21 controls
Haznedar et al. [103]
4/10
6/3
Beyer et al. [102] 14 patients
9 controls
58 (13)
41 (12)
42 (11)
45 (14)
44 (18)
31 (7)
EPI
not available 17 BD I medicated not available 8 BD I
1.5T
7 directions
1.5T
EPI
6 directions
16 cyclothymia
5 manic/hypomanic, 6 depressed, 3 euthymic not available 13.6 (12.1) 17 BD I, 7 BD II,
EPI
all medicated not available not available 1.5T
25 directions
3T
Imaging methods (field strength/ number of directions/ sequence)
not available
Using the conventional voxel-based and regions-of-interest approaches Adler et al. [101] 9 patients 4/5 32 (8) 9 BD I
Study
Table 7 Published DTI research in patients with bipolar disorder. Resultsb
" ADC in the bilateral OFC ROIs
not examined
not examined
Clinical correlations
bilateral frontal/ temporal/ parietal/occipital WM
" ADC in the bilateral frontal ROIs
no associations between the numbers of hospitalization, number of affective episodes and ADC in the ROIs (continued)
not examined bilateral frontal WM/ # RA in anterior fronto-occipital anterior and fasciculus and " RA posterior limbs of in the frontal the internal intergyral capsule association fibres amongst frontal ROIs RA # RA in the posterior limb of internal capsule ROI
bilateral OFC/SFG/ MFG WM FA/ADC
prefrontal WM at 15, # FA in the anterior, superior frontal 20, 25, and 30 ROIs mm superior to the AC FA/ADC no difference in elsewhere
Regions of examined (Tool of analysis)/ Measurements
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Versace et al. [107]
11/20
11/14
25 controls
matched
31 patients
28 controls
13/23
4/6
10 controls
Bruno et al. [106] 36 patients
6/5
30 (9)
36 (9)
matched
39
32 (9)
33 (11)
55 (13)
4/6
8 controls with neurological diagnosis
11 patients
Mean age (SD)
Gender (M/F)
Subjects
14 depressed, 17 euthymic
EPI
34 medicated 13.8 31 BDI
6 directions
3T
7 directions
1.5 T
6 directions EPI
1.5T
EPI
Imaging methods (field strength/ number of directions/ sequence)
not available
all euthymic all medicated 12.0 (9.8) 25 BD I/11 BD II
all medicated 20.1 (5.4) 11 BD I
4 manic, 3 mixed, 1 depressed
Patients characteristics (subtype/current episode/ medication/illness durationa)
Resultsb
FA/longitudinal and radial diffusivity
whole brain (TBSS)
FA/ADC
whole brain (SPM)
no associations between FA or ADC and the number of admission and the disease duration
positive correlation between the onset age and ADC in the splenium
Clinical correlations
# FA in the right negative correlation uncinate fasciculus between the medication load and FA in the left optic radiation #FA in the left optic " FA in the left radiation and the uncinate right anterior fasciculus, the left thalamic radiation in optic radiation, the subjects taking and the right mood stabilizers anterior thalamic relative to those not radiation taking
" ADC in the bilateral prefrontal and right posterior frontal regions
#FA in the inferior, middle temporal and middle occipital regions
" FA in the genu of genu, left anterior, corpus callosum right anterior, splenium ROIs of corpus callosum FA/ADC
ADC
Regions of examined (Tool of analysis)/ Measurements
|
Yurgelun-Todd et al. [105]
Study
Table 7 (Continued)
176 Chapter 14
Sussmann et al. [110]
42 patients
40 controls
22/20
15/27
9/24
15/27
42 controls
Wang et al. [109] 33 patients
13/29
Wang et al. [108] 42 patients
40 (10)
29 (9)
32 (10)
29 (9)
33 (10)
7 manic or hypomanic, 7 depressed, 19 euthymic not available not available 42 BD I
1.5 T
EPI
32 directions
3T
# FA in the anterior cingulum ROI
no associations between the diagnostic subtype, the mood state, medication state, and FA in the ROIs
#FA in the left optic radiation in the depressed BD patients relative to euthymic patients
whole brain (SPM2)/ # FA in the superior thalamic radiation bilateral anterior (Voxel-based) limb of the internal capsule and uncinate fasciculus ROIs
negative correlation between the depressive symptom severity and FA in the anterior thalamic radiation (continued)
whole brain (SPM5)/ # FA in the genu, the no associations between the clinical variables rostral body, and anterior, middle, and FA in the ROIs the anterior and posterior midbody of corpus corpus callosum callosum (VoxelROIs based) FA # FA in the anterior and the middle corpus callosum ROIs (ROI based)
32 directions
EPI
FA
3T
depressed patents, 12.3 (9.8); euthymic patents, 11.8 (6.3) 25 rapid cycling
11 manic or hypomanic, 9 depressed, 22 euthymic 35 medicated not available 19 rapid cycling
anterior and posterior cingulum ROIs
EPI
all medicated
Functional Imaging Techniques
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16 controls
9/7
8/8
22/16
38 controls
Using the tractography approach Houenou 16 patients et al. [112]
15/15
19/19
38 controls
30 patients
Gender (M/F)
Subjects
41(13)
42 (13)
32 (9)
33 (9)
37 (12)
Mean age (SD)
EPI
not available 18.3 (11.1) 25 BD I/2 BD II/3 BD NOS
41 directions
EPI
all euthymic
14 medicated not available
1.5 T
EPI
all medicated not available not available
25 directions
not available
1.5 T
51 directions
Imaging methods (field strength/ number of directions/ sequence)
all euthymic
Patients characteristics (subtype/current episode/ medication/illness durationa)
Clinical correlations
# FA in the left cerebellar WM
" FA in the bilateral frontal WM
no associations between the clinical variables (illness duration and symptom severity) and fibres characteristics
" FA in bilateral frontal WM and # FA in the left cerebellum in patients without substance use disorder
# FA in the left anterior no associations between the medication use limb of the internal and FA in the ROIs capsule and the bilateral uncinate fasciculus ROIs (ROI based)
Resultsb
" the number of seed masks for reconstructed tractography; between the left subgenual subgenual cingulate, cingulate and left amygdaloamygdalohippocampal hippocampal complex, pons complex and cerebellum FA/ADC/the number of reconstructed fibres
FA/axial and radial diffusivity
whole brain (ART, TBSS)
FA
Regions of examined (Tool of analysis)/ Measurements
|
Mahon et al. [111]
Study
Table 7 (Continued)
178 Chapter 14
21/19
28/21
40 patients
49 controls
35 (11)
40 (10)
Pavuluri et al. [116]
Frazier et al. [115]
10/3
5/3
8 controls
13 patients
4/6
7/10
10 patients
17 controls
15 (3)
9 (3)
9 (2)
Studies on the adolescents or children with bipolar disorder Adler et al. [114] 11 patients 5/6 14 (2)
McIntosh et al. [113]
6 directions
3T
all medicated not available 13 BD I
1.5 T
25 directions EPI
3T
51 directions EPI
1.5 T
not available
all manic all medication-naive first episode 10 BD I
11 BD I
not available not available 18.8 (11.1)
not available
not examined
no associations between the clinical variables (illness duration, symptom severity, and treatment) and fibres characteristics
# FA in the anterior anterior corona corona radiata radiata, anterior, and posterior limbs of internal capsule, superior region of internal capsule, superior and inferior longitudinal fasciculus, cingulum, and splenium
| (continued)
not examined
no associations between superior longitudinal # FA in the superior the clinical variables frontal tracts fasciculus and (illness duration, including the cingulatesymptom severity, bilateral superior paracingulate and treatment) and longitudinal WM ROIs FA in the ROIs fasciculus and the cingulateparacingulate ROIs FA # FA in the left orbitofrontal WM and the right anterior corpus callosum
prefrontal WM at 15, # FA in the left superior-frontal 20, 25, and 30 WM tracts mm superior to the AC FA/ADC
# FA in the uncinate seed masks for fasciculus and tractography; anterior thalamic anterior thalamic radiation radiation and uncinate fasciculus FA
Functional Imaging Techniques 179
12/14
14/12
26 controls
6/9
15 controls
26 patients
Gender (M/F)
Subjects
15 (2)
16 (2)
14 (3)
Mean age (SD)
Imaging methods (field strength/ number of directions/ sequence)
6 directions
EPI
16 manic or mixed
all medicated not available
all euthymic 27 directions all medication-free for EPI at least 7 d 7 (2.2) 26 BD I 1.5 T
Patients characteristics (subtype/current episode/ medication/illness durationa)
FA/ADC
whole brain
FA/ADC/r-FCI
Regions of examined (Tool of analysis)/ Measurements
Clinical correlations
no associations between # FA in the right the duration of orbitofrontal, the treatment and FA in bilateral temporal, the ROIs and the left occipital lobe " ADC in the bilateral subgenual regions, the postcentral gyrus, the precuneus, the temporal, and the occipital regions
# r-FCI in the splenium
Resultsb
Abbreviations: AC, Anterior commissure; ADC, Apparent Diffusion Coefficient; ART, Automatic Registration Toolbox; BD, Bipolar Disorder; DTI, Diffusion Tensor Imaging; EPI, Echo Planar Imaging; FA, Fractional Anisotropy; MFG, Middle Frontal Gyrus; NOS, Not Otherwise Specified; OFC, Orbitofrontal Cortex; r-FCI, Regional Fibre Coherence Index; RA, Relative Anisotropy; ROI, Region Of Interest; SFG, Superior Frontal Gyrus; SPM, Statistical Parametric Mapping; T, Tesla; TBSS, Tract-Based Spatial Statistics; WM, White Matter. a Years (SD). b All results presented in Table 7 are those of patients with bipolar disorder relative to comparison subjects except where indicated otherwise. c Among them, DTI scans were conducted only in 33 BD patients and 34 comparison subjects.
Kafantaris et al. [117]
Study
|
Table 7 (Continued)
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Functional Imaging Techniques
United Kingdom) for a spatial normalization of images and the ROI approach in order to investigate the connectivity of the corpus callosum. They found reduced FA values in the anterior and middle, but not posterior, corpus callosum in 33 BD patients relative to 40 comparison subjects both in ROIs (at p < 0.01, Bonferroni corrected for three subregions) and voxel-based (at p < 0.005, uncorrected) DTI analyses. On the other hand, Yurgelun-Todd et al. [105] reported that 11 BD patients had higher FA values in the midline of the genu relative to 10 matched comparison subjects. Mean diffusivity of all ROIs of the corpus callosum did not differ between groups. In addition to the studies using the ROI-based analyses, there have been two studies that adopted a technique of DTI tractography, which allows the virtual reconstruction of WM bundle fibres [98,118]. Houenou et al. [112] reconstructed the WM tract between the subgenual cingulate cortex and the amygdalo-hippocampal complex and calculated the mean FA values, the mean ADC values and the number of reconstructed fibres. The results from this tractography study demonstrated that the number of tract fibres between the left subgenual cingulate cortex and left amygdalo-hippocampal complex was greater in BD patients relative to comparison subjects. There was no difference in mean FA or ADC values for all reconstructed fibre tracts between groups. In another study by McIntosh et al. [113], bilateral uncinate fasciculus and anterior thalamic radiations were segmented using the tractography methodology. They found that FA values in the reconstructed tracts of both regions were reduced in BD patients.
DTI Studies of bipolar disorder using a voxel-based approach Only a few DTI studies using a voxel-based approach have been published. Mahon et al. [111] conducted a VBA of the FA data, using the registration module of the Automatic Registration Toolbox (ART; [119]). They reported higher FA values in the bilateral frontal WM and lower FA values in the left cerebellar WM in 30 BD patients relative to 38 comparison subjects (p < 0.001, cluster size 50). Mean FA values of the extracted WM bundles from those clusters, which encompassed the fibres of corticopotine, corticospinal, superior thalamic radiation fibres and pontine crossing tract, were also different between BD patients and comparison subjects. Versace et al. [107] examined 31 BD patients and 25 comparison subjects with a voxel-based approach, employing a nonlinear registration algorithm of the Tract-based Spatial Statistics (TBSS; [120,121]). BD patients showed reduced FA values in the right uncinate fasciculus and greater FA values in the left uncinate fasciculus, left optic radiation and right anterior thalamic radiation (corrected p < 0.05). These results suggest that there
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might be a right and left asymmetry in WM tracts, which connect the orbitomedial prefrontal cortex with subcortical limbic regions. Sussmann et al. [110] used small volume corrections for the hypothesized brain regions in the voxel-based approach when studying 42 familial BD patients and 38 comparison subjects. Spatial normalization of the images was conducted using SPM2. They found reduced FA values in the superior thalamic radiation regions in BD patients relative to comparison subjects (corrected p ¼ 0.018). This seems to contrast with the results of Versace et al. [107]. With the small volume correction for the uncinate fasciculus and the anterior limb of internal capsule, FA values in both regions was reduced in BD patients compared to comparison subjects. Another voxel-based DTI study using SPM2 suggested that there are WM abnormalities in the fronto-temporal regions in BD patients [106]. Reduced FA values in the inferior and middle temporal regions, which encompass the inferior longitudinal fasciculus, was observed in BD patients (corrected p ¼ 0.04), while ADC values were higher in the bilateral prefrontal and the right posterior frontal regions of the BD patients relative to comparison subjects (corrected p < 0.05). Areas of higher ADC values involved the part of the corpus callosum and the anterior frontooccipital fasciculus connecting the prefrontal cortex with the temporal and occipital regions.
DTI Studies of paediatric bipolar disorder There have been a few DTI studies of paediatric or adolescent BD patients. Adler et al. [114] examined 11 adolescents with BD and 17 matched healthy adolescents. The mean age of study participants was 14 years old (SD 2) and all adolescents with BD were in the first episode of mania and medication-naive at the time of scanning. The ROIs were selected in the same prefrontal regions as their previous study [101]. Adolescents with BD showed similar FA reductions in the superior frontal regions to those of adult BD patients [101]. A recently published study by Pavuluri et al. [116] also reported reduced FA values in the anterior corona radiata connecting the prefrontal regions with the brainstem in 13 adolescents with BD (mean age [SD] ¼ 14.8 years [2.5]) amongst a priori selected 6 ROIs. With a larger sample size (26 patients and 26 matched comparison subjects), Kafantaris et al. [117] reported reduced FA values in the right orbitofrontal, the bilateral temporal and the left occipital regions in BD patients (mean age [SD] ¼ 16.0 years [1.5]) relative to comparison subjects (mean age [SD] ¼ 15.3 years [1.5]) at the cluster size of 100 and the significance level of uncorrected p < 0.005. In addition, BD patients had higher ADC values in the bilateral subgenual, postcentral, precuneus, temporal and occipital regions at the same statistical significance level.
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Until recently, only one DTI study of children with BD has been published. Frazier et al. [115] compared FA values between 10 children with BD (mean age [SD] ¼ 9.2 years [3.0]) and eight age-matched children using both voxelbased and ROIs analyses. Children with BD had reduced FA values in the bilateral superior frontal tracts, which encompass the superior longitudinal fasciculus and the cingulate-paracingulate WM regions relative to referent children. FA values in the left orbitofrontal WM and the right anterior corpus callosum were also reduced in children with BD compared with healthy children.
Differences in clinical characteristics may also have contributed to the inconsistency of the findings from previous DTI studies on BD. All DTI studies, except for that of Adler et al. [114], included patients who were previously exposed to medications. Only a few studies have examined the relationships between medication use and WM integrity, even as a post-hoc analysis. A more homogeneous study group would be more efficient to detect the disease-specific WM pathologies. It would be also worthwhile to adopt the longitudinal study design and to examine how the moodstabilizers and/or the antipsychotics might affect the WM pathologies.
Summary and clinical implications Although several DTI studies of individuals with BD have suggested abnormalities of WM integrity particularly in the frontal cerebral regions (Figure 4), regional differences in directionality and/or the rate of diffusion between groups suggest these findings must be interpreted with caution. DTI methodology is a relatively new technique and there have been several methods, and also controversies, regarding the details of image acquisition and image analysis, especially concerns regarding possible misregistration issue. Considering that a relatively small number of studies on BD have been published to date following the first report in 2004, further studies with more sophisticated methodology that can address the aforementioned methodological problems, are warranted. This would provide a more definitive answer on the roles of the WM integrity abnormalities in the pathophysiology of BD.
Functional magnetic resonance imaging in bipolar disorder Introduction The technique of fMRI, which can measure signal intensity changes associated with increased neural activity, was introduced in the early 1990s. It has been a mainstay of neuroimaging methodology for evaluating the functional organization of the brain. Until recently, blood-oxygenlevel-dependent (BOLD) contrast has been the most popularly used fMRI technique [123]. With good spatial and high temporal resolution, this method permits the measurement of regional differences in oxygenated blood levels over time that are associated with changes in brain activity [124,125]. In addition to its use in exploring functional localization and cognitive neuroanatomy, the fMRI technique has
Fig. 4 Regions of increased and decreased FA in patients with bipolar disorder relative to comparison subjects. Abbreviations: Ant, Anterior; Post, Posterior; Sup, Superior. See also Plate 4. Red circles represent higher FA in patients with bipolar disorder relative to comparison subjects, blue circles represent lower FA in patients with bipolar disorder relative to comparison subjects. Parcellated white matter mask is adapted from stereotaxic white matter atlas [122].
Functional Imaging Techniques
widely been used for understanding and characterizing pathophysiological mechanisms of various psychiatric disorders [126]. Frontier areas of the fMRI include the characterization of endophenotypes and markers of disease-specific traits, which may potentially be predictive of treatment response or prognosis [126]. Central clinical features of BD are abnormal emotional regulations and impaired cognitive control [127]. In both domains of pathology, the prefrontal cortical-subcortical limbic functional connectivity might play an important role. Most fMRI studies on BD have, therefore, examined functional activation of brain regions associated with emotional and fronto-executive processing. Since the first fMRI report on BD by Yurgelun-Todd et al. [128] in 2000, over 45 fMRI studies have been published to date (Table 8). Amongst them, about half of the papers have been published in 2007 and 2008. Findings from the studies employing fMRI methods have enabled functional localization of some of the pathophysiological processes, which may be responsible for the development of BD.
Emotional processing Emotional processing involves the several steps including the perception, the induction and the regulation of emotions, all of which are associated with the key symptoms of BD, such as mood instability and affective lability [156]. The ventral-limbic regions including the amygdala, the striatum, the ventral cingulate, the ventromedial prefrontal cortex, the anterior hippocampus and the anterior insula might be activated during the performance of emotional processing [157]. Impaired cognitive controls of the dorsal frontal regions and the resultant cognitive-emotional interference have been consistently hypothesized as being related to the pathophysiology of BD. Both the hyperactive ventral-limbic network and the hypoactive dorsal-cognitive network have been implicated in the major functional alterations in BD. To examine the abnormal functional connectivity in emotional processing, several experimental paradigms have been adopted in the fMRI studies on BD. Recognition of the facial expression is the most frequently used task and other emotional challenges have been used as the stimuli to activate the relevant neural responses. Yurgelun-Todd et al. [128] examined the neural response of the dorsolateral prefrontal cortex and the amygdala during the fearful and happy facial affect recognitions in 14 BD patients and 10 comparison subjects using a ROI-based analysis. BD patients showed a reduced activation in the right dorsolateral prefrontal cortex and increases in the left amygdala activation to the fearful facial affect relative to comparison subjects. Signal changes in the dorsolateral prefrontal cortex and the amygdala in response to the happy facial expression did not differ between groups.
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This result suggested that BD patients had deficits in fearful affect recognition due to a disturbed prefronto-limbic circuitry. In addition to the prefronto-limbic abnormality, some reversal of the normal right-lateralized temporal lobe activation in response to emotional prosody was reported [132]. In an auditory affect study of 10 BD patients, a greater activation in the left superior temporal gyrus was observed compared to comparison subjects [132]. This result suggested that BD patients might have left-lateralized temporal lobe responses to emotional prosody in contrast to the right-lateralized in normal subjects. Blumberg et al. [139] suggested that patterns of neural disturbances might be different according to the mood states at the time of scanning and tried to characterize stateand trait-dependent functional abnormalities in BD patients. Since then, a substantial numbers of studies have tried to accurately characterize the mood state of BD patients at the time of scanning. In a study involving 17 euthymic BD patients, Wessa et al. [135] had participants perform the emotional and nonemotional Go-NoGo task during scanning to examine the cerebral underpinnings of the influence of emotional information on cognitive processes. Activation in the temporal cortical regions was increased in BD patients relative to comparison subjects when comparing the contrast between the emotional Go-NoGo and nonemotional Go-NoGo tasks. In addition, as compared with control subjects, overactivities to emotional versus neutral distracters were observed in the orbitofrontal cortex, the insula, the caudate and the dorsal cingulate cortex of BD patients. In another fMRI study where the emotional Go-NoGo task was used, manic patients showed a similar pattern of increased responses in ventral brain regions to the emotional stimuli [129]. In this study, manic patients showed a greater activation in the left ventrolateral prefrontal cortex to emotional stimuli and the activation in ventral and medial prefrontal regions was also increased in response to emotional distracters [129]. Those studies indicated that increased activity in the ventral frontal brain regions in euthymic as well as manic patients might reflect a greater demand for inhibition of emotional stimuli in BD patients relative to comparison subjects. Similarly, Lawrence et al. [130] reported that BD patients exhibited increased neural responses in subcortical (ventral striatal, thalamic, hippocampal) and ventral prefrontal cortical regions to both positive and negative facial expressions relative to comparison subjects. In contrast, Malhi et al. [131,133] reported attenuated ventral-limbic brain activity in response to the emotional stimuli in euthymic BD patients. In the study of euthymic female BD patients (n ¼ 12, [133]), diminished overall neural responses to emotional word stimuli were observed in cortical and subcortical structures, including the inferior frontal gyrus, the middle temporal gyrus, putamen,
Mitchell et al. [132]
Malhi et al. [131]
Lawrence et al. [130]
Elliott et al. [129]
0/10
10 controls 23/0
7/4 0/10
(9 MDD)b 11 controls 10 patients
11 patients
13/8
3/8
11 controls
12 patients
4/4
8 patients
5/3
10 controls
Gender (M/F)
9/5
Subjects (BD patients/ control subjects)
43 (2)
36 (13)
37 (12)
41 (11)
38 (10)
34
aged 19 to 54 yr
Mean age (SD)
all manic or hypomanic all medicated not available
9 depressed, 3 euthymic all medicated 4 rapid cycling
(7 manic, 1 hypomanic) 7 medicated 12 BD I, 9 MDD
all manic
6 manic,1 depressed, 7 euthymic all medicated 7 BD I
not available
Patients characteristics (subtype/current episode/medication)
Auditory emotional prosody
Affect-inducing captionedpictures recognition task
Facial affect recognition task
Emotional GoNoGo task
Facial affect recognition task
Experimental paradigm
" left STG during an auditory affect task suggesting left lateralization of the normal neural response to emotional prosody
brain activation of hypomanic patients involved the prefrontal and subcortical regions including the caudate and thalamus to normally activated regions during the emotional processingc
" ventral PFC and " subcortical (ventral striatum, thalamus, hippocampus) activation to both positive and negative facial affect
" left VLPFC activation to the emotional relative to neural stimuli " left medial PFC activation to emotional distracters
# right DLPFC and " left amygdala activation to the fearful facial affect
Resultsa
not examined
not examined
lithium/antidepressant medications were related to the normalization in the subcortical and dorsal PFC activity to emotional stimuli
not examined
negative correlation between CPZ equivalent antipsychotic medication dose and the amygdala activity for male patients
Clinical correlations
|
Emotional Processing Tasks Yurgelun-Todd 14 patients et al. [128]
Study
Table 8 Published fMRI research in patients with bipolar disorder.
184 Chapter 14
Altshuler et al. [136]
Wessa et al. [135]
Chen et al. [134]
Malhi et al. [133]
5/6
9/8
17 controls
11/6
17 controls
11 patients
10/7
2/6
8 controls
17 patients
13/3
0/12
12 controls
16 patients
13/0 0/12
(12 SPR)d 13 controls 12 patients
30 (7)
32 (7)
45 (11)
45 (13)
39 (13)
41 (13)
34 (6)
32 (4) 35 (9)
all depressed 9 medicated
15 medicated 11 BD I
17 euthymic
10 BD I, 7 BD II
all medicated
8 manic, 8 depressed
all euthymic 8 medicated 16 BD I
not available all medicated 12 BD I
Face matching task
Emotional GoNoGo task
Explicit/Implicit facial affect recognition task
Emotional Stoop task
# bilateral OFC (BA47) and right DLPFC (BA 9) and " left OFC (BA10) activation during emotional facial matching
" superior and ventral frontal gyral, precentral gyral, cingulate, putamen, and thalamic activation to the happy faces in BD depressed patients " precentral and postcentral gyral, MTG, parahippocampal gyral, striatum, thalamus, and brain stem activation to the fearful faces in all BD patients "bilateral OFC, right posterior cingulate gyrus, left insula, bilateral caudate nuclei during the inhibition of emotional distracters "right MTG, ITG, and STG activation during emotional Go-NoGo condition
" left fusiform gyral activation to the sad faces in BD manic patients
# IFG, STG, MTG, putamen, caudate, thalamus, and amygdala activations to emotional word stimuli
not examined
not examined
not examined
not examined
(continued)
Functional Imaging Techniques
| 185
Adler et al. [140]
Blumberg et al. [139]
15 controls
matched samples
10/10
20 controls
15 patients
5/0 18/18
(5 SPR)f 5 controls 36 patients
5/0
5/7
12 controls
30 (9)
29 (9)
32 (11)
32 (3) 39 (10)
33 (6)
42 (11)
42 (12)
Mean age (SD)
15 euthymic 10 medicated
23 medicated not available
11 manic, 10 depressed, 15 euthymic
not available all medicated 36 BD I
not available
all medication-free for at least 10 d
all euthymic
8 BD I
Patients characteristics (subtype/current episode/medication)
N-back working memory task
Stroop task
Verbal fluency task
Facial affect recognition task
Experimental paradigm
" fronto-polar PFC, temporal cortex, basal ganglia, thalamus, and posterior parietal cortex activation during the working memory task
# left rostral regions of the ventral PFC activation during the Stroop task within BD patients: " left caudal regions of the ventral PFC activation in depressed BD relative to euthymic BD patients/# right ventral PFC activation in manic BD relative to euthymic BD patients
" medial frontal cortex, left IFG, medial parietal cortex, cerebellum, right lingual gyral activation during the verbal fluency task
" left parahippocampal gyrus and # right VLPFC, left dorsal PFC, right cingulate, and right precentral gyral activation to the emotional stimuli in BD patients at baseline # left temporal gyrus and " bilateral prefrontal cortical activation to the emotional stimuli following lamotrigine monotherapy
Resultsa
not examined
no association between symptom severity and the degree of activation
not examined
no association between the depressive symptom changes and the lamotrigine-related regional activity changes
Clinical correlations
|
Fronto-executive Function Tasks Curtis et al. [138] 5 patients
3/5
8 patients
Jogia et al. [137] e
Gender (M/F)
Subjects (BD patients/ control subjects)
Study
Table 8 (Continued)
186 Chapter 14
Altshuler et al. [145]
Strakowski et al. [144]
Strakowski et al. [143]
Monks et al. [142]
Gruber et al. [141]
4/7
9/7
16 controls
11 patients
6/10
4/6
10 controls
16 patients
4/6
12/0
12 controls
10 patients
12/0
5/6
10 controls
12 patients
8/3
11 patients
36 (8)
30 (9)
28 (7)
25 (7)
8 medicated 11 BD I
16 euthymic
all euthymic -all medication-free for at least 1 mo 16 BD I
all medicated 10 BD I
46 (4)g
26 (8)
all euthymic
46 (3)g
11 BD I
all euthymic all medicated 12 BD I
25 (4)
37 (7)
Go-NoGo task
Stroop task
Continuous performance task
Two-back working memory task; Sternberg task
Stroop task
# right lateral OFC, left cingulate cortex, right hippocampal activation during the inhibitory task
# MFG, temporal cortex, putamen, and cerebellar vermis activation during the interference task
" VLPFC, parahippocampal, amygdala, insula, and visual association cortex and # medial prefrontal and fusiform gyral activation during the attention task
# bilateral frontal, temporal, and parietal and " left precentral, right medial frontal, and left supramarginal gyral activation during the working memory task no group difference during the Sternberg task
# right ACC and " right DLPFC activation during the interference condition
negative correlation between the duration of the manic episode and right frontal activity – no association between the symptom severity and the degree of activation (continued)
psychotropic medications were related to increased activity in DLPFC and ACC
positive correlation between task performance and MTG activity in BD patients
positive correlations between task performance and right inferior frontal and bilateral VLPFC activity in BD patients
not examined
positive correlation between CPZ equivalent antipsychotic medication dose and the left DLPFC activity
Functional Imaging Techniques
| 187
Mechelli et al. [149]
Drapier et al. [148]
McIntosh et al. [147]
35 (11)
16 medicated 29 BD I
22 medicated
21/24
42 (12) 38 (11)
not available
not available 42 medicated 20 BD I
45 controls
10/10 9/20
(20 unaffected first-degree relatives) 20 controls 29 patients
37 (12) 43 (10)
all medicated 42 BD I
all euthymic
all manic or hypomanic 7 medicated 10 BD I
Patients characteristics (subtype/current episode/medication)
not available
19/18 9/11
(27 SPR)f 37 controls 20 patients
39 (11)
36 (10)
41 (13)
31 (7)
Mean age (SD)
(41 SPR)i
21/21
7/4
11 controls
42 patients
6/4
5/8
13 controls
10 patients
Gender (M/F)
Subjects (BD patients/ control subjects)
Verbal fluency task
N-back working memory task
Hayling sentence completion test
Stroop task
Experimental paradigm
interaction effect between the diagnosis and the genotype of neuregulin 1 on the right OFC and the right inferior frontal regions post-hoc analysis showed " right OFC activation in BD patients with high-risk variant
" left ventral frontal pole cortical activation during the working memory task particularly in the unaffected relatives
" left DLPFC and # right insula activation during the sentence completion taskh
# left DLPFC, left VLPFC, left fusiform gyrus, and left precuneus activation and " left OFC and MFG activation during the interference task
Resultsa
no associations between the dose of medication, IQ, and depressive symptom, severity and the degree of activation
not examined
negative correlation between the reversal learning errors and the ventral striatum and the OFC activity
positive correlations between state anxiety scores and the left DLPFC and the left precuneus activity
negative correlation between the BDI scale scores and the left OFC activity
Clinical correlations
|
Kronhaus et al. [146]
Study
Table 8 (Continued)
188 Chapter 14
Pavuluri et al. [153]
Rich et al. [152]
Chang et al. [151]
6/4
5/5
10 controls
11/10
21 controls
10 patients
10/12
10/0
10 controls
22 patients
12/0
4/6
12 patients
10 controls
14 (2)
15 (2)
15 (3)
14 (3)
14 (3)
15 (3)
15 (3)
Studies on the adolescents or children with bipolar disorder Blumberg 10 patients 4/6 14 (3) et al. [150]
all euthymic all medication-free for at least 7 d
18 medicated 10 BD I
6 hypomanic, 4 depressed, 12 euthymic
20 BD I
12 medicated
not available
not available 7 medicated 12 BD I
10 BD I
Affective face processing task
Facial affect processing task
Two-back working memory task; International affective picture system task
Stroop task
# right VLPFC and " right pregenual anterior cingulate, amygdala, and paralimbic cortex activation to both angry and happy faces
" bilateral DLPFC, IFG, and right insula activation to the negatively valenced pictures " bilateral caudate, bilateral thalamus, left MFG/SFG, and left ACC activation to the positively valenced pictures " left amygdala, accumbens, putamen, and ventral PFC activation during the process of hostile face " left amygdala and bilateral accumbens activation during the process of fear face
" bilateral ACC, left putamen, left thalamus, left DLPFC, and right IFG and # cerebellar vermis activation during the working memory task
" left putamen and left thalamus activation during the Stroop task
not examined
(continued)
no association between the current mood, the use of medications, and the degree of activation
positive correlation between the hostile rating and the left amygdala activity
not examined
positive correlation between the depressive symptom severity and the ventral striatum activity
Functional Imaging Techniques
| 189
—
—
—
16 (1)
15 (2)
14 (3)
Mean age (SD)
not available
all depressed
13 medicated 3 BD I, 3 BD II, 2 BD NOS
5 hypomanic, 21 euthymic
24 BD I, 2 BD II
Patients characteristics (subtype/current episode/medication)
International affective picture system task
Motor inhibition task
Experimental paradigm
positive correlation between the depressive symptom severity and the left DLPFC activity at baseline positive correlation between the symptom improvement with 8-wk lamotrigine treatment and changes in the bilateral amygdala activity
# bilateral caudate, putamen, accumbens, and right ventral PFC activation when failing in the motor inhibition " right ventral PFC activation during the successful motor inhibition
Resultsa
not examined
Clinical correlations
Abbreviations: ACC, Anterior Cingulate Cortex; BA, Brodmanns Area; BD, Bipolar Disorder; BDI, Beck Depression Inventory; CPZ, Chlorpromazine; DLPFC, Dorsolateral Prefrontal Cortex; fMRI, functional Magnetic Resonance Imaging; IFG, Inferior Frontal Gyrus; IQ, Intelligence Quotient; ITG, Inferior Temporal Gyrus; MDD, Major Depressive Disorder; MTG, Middle Temporal Gyrus; NOS, Not Otherwise Specified; OFC, Orbitofrontal Cortex; PFC, Prefrontal Cortex; SPR, Schizophrenia; STG, Superior Temporal Gyrus; VLPFC, Ventrolateral Prefrontal Cortex. a All results presented in Table 8 are those of patients with bipolar disorder relative to comparison subjects except where indicated otherwise. b This study was designed to directly compare the neural activity of BD and MDD during emotional processing. c The results were not from the between-group analyses. d Eleven patients with bipolar disorder were used as a psychiatric comparison group in this study. e This study examined the changes in neural activity of patients with bipolar disorder after a 12-week lamotrigine monotherapy. f This study was designed to directly compare the neural activity of BD and SPR during cognitive processing. g Standard error. h The results were of patients with bipolar disorder relative to patients with schizophrenia. i This study was of the patients with SPR and BD, which was designed to compare the subjects with high risk variant of neuregulin 1 gene and those without. j This study examined the changes in neural activity of adolescent patients with bipolar disorder after an 8-week lamotrigine monotherapy.
4/4
8 patients
9/8
17 controls
Chang et al. [155] j
12/14
26 patients
Leibenluft et al. [154]
Gender (M/F)
Subjects (BD patients/ control subjects)
|
Study
Table 8 (Continued)
190 Chapter 14
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caudate, thalamus and amygdala, in patients relative to comparison subjects. Malhi et al. [131] examined the neural responses to the positive and negative captioned pictures in each group of 10 hypomanic females and 10 comparison subjects. Regions of brain activation in hypomanic patients involved subcortical regions, including caudate and thalamus as well as routinely activated prefrontal regions during the emotional processing [131]. This means that activation of caudate and thalamus to the emotional stimuli in BD patients might be dependent on mood state. Chen et al. [134] investigated the differential patterns of neural activation in response to the facial affect recognition between manic and depressed BD patients. Both BD groups showed increased neural responses in several brain regions to fearful facial expression relative to comparison group (n ¼ 8). Manic BD patients (n ¼ 8) exhibited increased activations in the left fusiform gyrus in response to sad faces. Implicit recognition of sad faces was associated with increased activity, while explicit recognition was associated with decreased activity in the limbic and frontal regions in manic BD patients. In contrast, when recognizing the happy faces, depressed BD patients (n ¼ 8) showed overactivation in the prefronto-striato-thalamic regions, including the
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191
superior and ventral frontal gyrus, the precentral gyrus, cingulate, putamen and thalamus relative to comparison subjects. These findings are consistent with the pre-existing theory of the abnormal ventral limbic network in BD [129,131,135,158]. On the other hand, Altshuler et al. [136] reported that BD patients had impaired dorsal and ventral prefrontal function during an emotional task, which may normally subserve the cognitive control of emotional processing. In their study, depressed BD patients showed reduced activations of the bilateral orbitofrontal and the right dorsolateral prefrontal cortex during the emotional facial expression task. In addition, increased activation of the left anterior prefrontal cortex (BA 10), which may be more specific to the depressed state, was also observed in BD patients relative to comparison subjects. Although the relatively small sample sizes and the variability of experimental paradigms of fMRI studies may make it difficult to draw a firm conclusion, currently available evidence collectively suggest increased activity in the ventral prefrontal cortex and the subcortical limbic structures during emotional processing in BD patients (Figure 5). Although less consistent amongst studies,
Fig. 5 Regions of increased and decreased activation under emotional processing tasks in patients with bipolar disorder. Abbreviations: Sup, Superior; Mid, Middle; Inf, Inferior. See also Plate 5. Regions of increased (triangle) and decreased (reverse triangle) activation under emotional processing tasks in patients with bipolar disorder from the Table 8. Regions were marked based on the Talairach coordinates, Brodmann areas or anatomical description in the reports. In patients with bipolar disorder, there were abnormal cortical and subcortical activations in the brain regions including prefrontal and temporal cortex, striatum, thalamus and amygdala when taking emotional processing tasks such as the facial affect recognition and emotional Go-NoGo tasks relative to comparison subjects.
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several prefrontal subregions may also be affected during the emotional processing in BD patients.
Fronto-executive control function Executive function, including working memory and the attention, has frequently been measured with the N-back working memory task, the Stroop test and the continuous performance test. These tasks normally activate the regions of the dorsolateral, the anterior cingulate and the ventral prefrontal cortex in healthy subjects [159,160]. Since the study of Curtis et al. [138] reporting an increased prefrontal cortical activation during the verbal fluency task in BD, several fMRI studies have reported altered activities in the prefronto-limbic network during the executive tasks in BD. Blumberg et al. [139] examined 36 BD patients (11 manic, 10 depressed and 15 euthymic mood state) and 20 comparison subjects using fMRI during the Stroop task. Signal changes in the left rostral region of the ventral prefrontal cortex during the task were attenuated in BD patients relative to comparison subjects and this finding appeared to be independent of mood state at the time of scanning. Within BD patients, there were, however, differential signal changes in the caudal regions of the ventral prefrontal cortex during the task between mood states. Activation in the left caudal region of the ventral prefrontal cortex was greater in depressed patients compared to euthymic patients, while the signal activation in the right ventral prefrontal cortex was attenuated in manic BD patients compared to euthymic BD patients. In the fMRI study of Strakowski et al. [144], 16 euthymic BD patients and 16 matched comparison subjects performed a counting Stroop interference task, which normally activates the regions of the anterior cingulate and the dorsolateral prefrontal cortex [161]. BD patients showed a lower task performance than comparison subjects. Although there was no difference in activation of brain regions commonly associated with the Stroop task, the anterior cingulate and the dorsolateral prefrontal cortices, BD patients demonstrated a lesser activation in the temporal cortex, the middle frontal gyrus, putamen and midline cerebellum relative to comparison subjects. This attenuated brain activation might be related to reduced task performances in BD patients by an inefficient modulation of impulse control including error detection and response inhibition. A study of remitted BD patients [146] also suggested that there are reduced activations in the dorsolateral and ventrolateral prefrontal cortex while performing the Stroop task in BD patients. Altshuler et al. [145] measured the neural response to the Go-NoGo task in 11 BD patients with manic episode and 13 comparison subjects. BD patients exhibited reduced activities in the right lateral orbitofrontal cortex, the right hippocampus and left cingulate cortex during the task relative
to comparison subjects. Decreased orbitofrontal activation in manic BD patients may reflect impaired roles of the orbitofrontal cortex in regulating or suppressing responses. Impaired function of the orbitofrontal cortex might be related to disinhibited behaviours commonly observed in BD patients with manic episode. Strakowski et al. [143] have studied 10 medication-free and euthymic BD patients and 10 matched comparison subjects. This study aimed to evaluate the state-independent abnormalities in brain functional activation of BD irrespective of medication effect. Medication-free and euthymic patients were enrolled since both medication ([128]; Blumberg et al., [162]; [130,141]) and mood state [134,139] have been reported to have effects on the functional signal changes in response to the cognitive or emotional stimulus. Brain regions of the limbic/paralimbic (parahippocampus, amygdala and insula), the ventrolateral prefrontal and visual association cortices exhibited a greater activation during the Continuous Performance Task in BD patients than in comparison subjects. In contrast, BD patients showed a decreased activation in the medial frontal cortex and the fusiform gyrus during the task relative to comparison subjects. Authors suggested that abnormal activation in the anterior limbic network might be an alternative strategy to process the attention information in order to compensate the inappropriate emotional network activation in BD patients. Similarly, another study of euthymic BD patients, examining the neural responses to the working memory task, reported that they have overactivations in the prefrontostriato-thalamic network [140]. During the performance of the N-back Working Memory Task, activities in the frontopolar prefrontal cortex, the temporal cortex, basal ganglia, thalamus and the posterior parietal cortex were increased in BD patients relative to comparison subjects. In interpreting currently available fMRI studies, several important points need to be taken into consideration. Small sample sizes could result in type 2 error and in studies with small sample sizes, inter-individual variability in the task performance could be an important confounding factor. Difference in the mood state at the time of scanning and a wide variability of cognitive tasks employed may make it difficult to directly compare findings of fMRI studies. For example, a task-specific brain dysfunction in BD was suggested by Monks et al. [142]. Reduced activations in the bilateral frontal, temporal and parietal cortex and increased activations in the left precentral, the right medial frontal and the left supramarginal gyri were observed in BD patients during the N-back task relative to comparison subjects. However, there was no between-group difference in the brain activation while performing the Sternberg task, which can also measure a working memory load. Despite these potential limitations, fMRI studies in BD have reported findings of functional abnormalities, both
Functional Imaging Techniques
increased and reduced activity, in the dorsal and ventral prefrontal cortices during the cognitive control tasks relative to comparison subjects.
Functional neuroimaging studies comparing bipolar disorder and other psychiatric disorders There have been a few fMRI studies examining differences in brain functional activities during the emotional or cognitive tasks in BD and other major psychiatric disorders including major depression and schizophrenia. In a study of 12 patients with BD, 9 patients with major depression and 11 comparison subjects [130], euthymic or depressed BD patients exhibited increased neural responses in subcortical and ventral prefrontal cortical regions to both positive and negative facial expressions relative to comparison subjects and patients with major depression. In contrast, patients with major depression demonstrated attenuated responses to all emotional expressions relative to comparison subjects. McIntosh et al. [147] reported a differential brain activation during the Hayling Sentence Completion Task between BD patients and schizophrenia who were clinically stable at the time of scanning. Increased activity in the left dorsal prefrontal cortex was observed in BD patients, whereas activity of the right insula was attenuated in patients with schizophrenia.
Medication effects in fMRI studies of bipolar disorder There have been debates on whether and how psychotropic medications affect the brain functional alterations in BD [156]. Given that most of the functional imaging studies of bipolar populations thus far were of patients who were previously exposed to the medications, the potential confounding effects of psychotropic medications on the findings should be taken into consideration in interpreting the results. Several fMRI studies did not find any potential medication effects on neural responses to cognitive control and emotional processing [135,139,145,146,150]. Some other studies, in contrast, suggested the psychotropic medications could ameliorate abnormal neural activity during the emotional or cognitive tasks. It was suggested that medication might partly normalize abnormally increased subcortical limbic activity to emotional stimuli ([128]; Blumberg et al., 2005; [130]) and attenuated prefrontal cortical activity to cognitive control stimuli [141]. For example, a significant negative correlation between antipsychotic medication dose and amygdala activity to the emotional expression was observed [128]. Patients who were taking psychotropic medications
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193
showed a smaller increase in subcortical limbic activity to emotional stimuli (Blumberg et al., 2005; [130]). Antipsychotic medications increased neural activity in the anterior cingulate and dorsolateral prefrontal cortices in response to a cognitive control task [141]. In a recent longitudinal study of euthymic BD patients, increased activities in the temporal cortical regions and diminished activities in the prefrontal regions during facial affect recognition task seem to be normalized with a 12-week lamotrigine monotherapy [137]. Similar findings were reported in adolescents with bipolar depression [155]. Adolescents with bipolar depression treated with lamotrigine for 8 weeks showed a reduction in the right amygdala activation to the negative stimuli, which was correlated with an improvement in depressive symptoms. In conclusion, there have been some inconsistencies regarding the potential effects of the psychotropic medications, which may be attributed to the heterogeneous patterns of medication use and a wide variability of study paradigms employed. Longitudinal studies with a controlled design of each class of psychotropic medications are needed to examine the potential effects of medications on the neural responses to emotional and cognitive stimuli in BD patients.
Potential applications of fMRI study for genetic characterization of bipolar disorder Drapier et al. [148] suggested that altered frontal activation in response to a working memory task might be associated with the genetic vulnerability for BD. They designed an fMRI study comparing 20 remitted BD patients, 20 of their unaffected first-degree relatives and 20 matched comparison subjects during the N-back task. Relative to comparison subjects, neural responses in the left frontal polar cortical regions to the working memory task were increased in unaffected relatives as well as in BD patients. Authors suggested that prefrontal functional abnormalities during working memory tasks might be a potential endophenotype for BD. Recently, imaging genetic studies, which examine how the specific gene might affect the brain function and whether the specific gene-related functional changes could increase the vulnerability to the disease, has been introduced in the research of BD. Mechelli et al. [149] examined the brain function while 29 BD patients and 45 comparison subjects underwent the verbal fluency task. They found the interaction effect between the diagnosis and the genotype of neuregulin 1 on the right posterior orbitofrontal gyrus. Increased activation in the right orbitofrontal gyrus was observed only in the BD patients with the high-risk variant of neuregulin 1. This study suggested the specific genetic pattern-associated changes in prefrontal cortical activation in BD.
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fMRI studies on paediatric bipolar disorder Based on the typical features of early-onset BD and a high genetic loading for the disorder, there has been interest in the functional brain pathophysiology of paediatric and adolescent BD patients. In the study of 10 adolescents with BD (aged 10–17 years) and 10 comparison subjects (aged 11–18 years) [150], adolescents with BD demonstrated increased signal activity of the left putamen and thalamus in response to the colournaming Stroop task relative to comparison subjects. Chang et al. [151] examined 12 male paediatric BD patients with familial burden (mean age [standard deviation, SD] ¼ 14.7 years [3.0]) and matched 10 comparison males (mean age [SD] ¼ 14.4 years [3.2]). All BD children were euthymic. The 2-back visuospatial working memory task and the International Affective Picture System were selected to measure the neural responses to cognitive and affective stimuli, respectively. Similar to the study of Blumberg et al. [139,150], BD children had greater activity in the bilateral anterior cingulate cortex, left putamen, left thalamus, left dorsolateral prefrontal cortex and the right inferior frontal gyrus in response to the visuospatial working memory task relative to comparison subjects. During the affective task, BD patients showed greater activity in the bilateral dorsolateral prefrontal cortex, the inferior frontal gyrus and the right insula in response to the negatively valenced pictures relative to comparison subjects. When viewing the positively valenced pictures, BD children had greater activity in the bilateral caudate and thalamus, the left middle and superior frontal gyrus and the left anterior cingulate cortex. Authors suggested that overall overactivity in prefronto-limbic regions might be associated with a hyperactive brain state and reflective of a developmental stage of BD. Pavuluri et al. [153] reported that euthymic, unmedicated paediatric BD patients (n ¼ 10, mean age [SD] ¼ 14.9 years [1.9]) showed a reduced activation in the right side of ventrolateral prefrontal cortex and an increased activation in the right pregenual anterior cingulate, amygdala and the paralimbic cortex in response to both angry and happy faces relative to comparison subjects (n ¼ 10, mean age [SD] ¼ 14.3 years [2.4]). In line with this result, which show exaggerated neural activity of the limbic area in response to emotional stimuli, Rich et al. [152] reported that paediatric BD patients had greater activity of the left amygdala, accumbens, putamen and ventral prefrontal cortex when exposed to hostility face and greater activity of the left amygdala and bilateral accumbens when exposed to fear face, relative to comparison subjects. Impaired motor inhibition may be associated with behavioural disturbance of paediatric BD patients, including impulsivity and irritability (McClure et al., [163]). To examine the underlying functional brain abnormalities for the
deficit in motor inhibition of paediatric BD patients, Leibenluft et al. [154] examined 26 adolescents with BD (mean age [SD] ¼ 13.6 years [2.6]) and matched 17 comparison subjects (mean age [SD] ¼ 14.6 years [1.8]). When failing in the motor inhibitory task, adolescents with BD showed attenuated neural responses in the bilateral striatal and right ventral prefrontal regions relative to comparison subjects.
Acknowledgements This work was supported in part by grants from the National Institute of Health (7K24DA015116, Dr Renshaw), from the National Alliance for Schizophrenia and Affective Disorders (NARSAD Independent Investigator Award, Drs Lyoo and Renshaw) and from the Korea Research Foundation (KRF-2008-220-E00021, Drs Lyoo and Renshaw).
References 1. Stork, C. and Renshaw, P.F. (2005) Mitochondrial dysfunction in bipolar disorder: Evidence from magnetic resonance spectroscopy research. Mol. Psychiatry, 10, 900–919. 2. Kato, T. (2005) Mitochondrial dysfunction in bipolar disorder: From 31 P-magnetic resonance spectroscopic findings to their molecular mechanisms. Int. Rev. Neurobiol., 63, 21–40. 3. Schulz, U.G., Blamire, A.M., Corkill, R.G. et al. (2007) Association between cortical metabolite levels and clinical manifestations of migrainous aura: an MR-spectroscopy study. Brain, 130, 3102–3110. € ur, D., Jensen, J.E., Prescot, A.P. et al. (2008) Abnormal 4. Ong€ glutamatergic neurotransmission and neuronal-glial interactions in acute mania. Biol. Psychiatry, 64, 718–726. 5. Winsberg, M.E., Sachs, N., Tate, D.L. et al. (2000) Decreased dorsolateral prefrontal N-acetyl aspartate in bipolar disorder. Biol. Psychiatry, 47, 475–481. 6. Cecil, K.M., DelBello, M.P., Morey, R. and Strakowski, S.M. (2002) Frontal lobe differences in bipolar disorder as determined by proton MR spectroscopy. Bipolar. Disord., 4, 357–365. 7. Bertolino, A., Frye, M., Callicott, J.H. et al. (2003) Neuronal pathology in the hippocampal area of patients with bipolar disorder: A study with proton magnetic resonance spectroscopic imaging. Biol. Psychiatry, 53, 906–913. 8. Deicken, R.F., Pegues, M.P., Anzalone, S. et al. (2003) Lower concentration of hippocampal N-acetylaspartate in familial bipolar I disorder. Am. J. Psychiatry, 160, 873–882. 9. Atmaca, M., Yildirim, H., Ozdemir, H. et al. (2006) Hippocampal 1 H MRS in first-episode bipolar I patients. Prog. Neuropsychopharmacol. Biol. Psychiatry, 30, 1235–1239. 10. Bhagwagar, Z., Wylezinska, M., Jezzard, P. et al. (2007) Reduction in occipital cortex gamma-aminobutyric acid concentrations in medication-free recovered unipolar depressed and bipolar subjects. Biol. Psychiatry, 61, 806–812. 11. Scherk, H., Backens, M., Schneider-Axmann, T. et al. (2008) Neurochemical pathology in hippocampus in euthymic
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12.
13.
14.
15.
16.
17.
18.
19.
20.
21.
22.
23.
24.
25.
26.
patients with bipolar I disorder. Acta Psychiatr. Scand., 117, 283–288. Chang, K., Adleman, N., Dienes, K. et al. (2003) Decreased N-acetylaspartate in children with familial bipolar disorder. Biol. Psychiatry, 53, 1059–1065. Sassi, R.B., Stanley, J.A., Axelson, D. et al. (2005) Reduced naa levels in the dorsolateral prefrontal cortex of young bipolar patients. Am. J. Psychiatry, 162, 2109–2115. Olvera, R.L., Caetano, S.C., Fonseca, M. et al. (2007) Low levels of N-acetyl aspartate in the left dorsolateral prefrontal cortex of pediatric bipolar patients. J Child. Adolesc Psychopharmacol., 17, 461–473. Cecil, K.M., DelBello, M.P., Sellars, M.C. and Strakowski, S.M. (2003) Proton magnetic resonance spectroscopy of the frontal lobe and cerebellar vermis in children with a mood disorder and a familial risk for bipolar disorders. J. Child Adolesc. Psychopharmacol., 13, 545–555. Hamakawa, H., Kato, T., Murashita, J. and Kato, N. (1998) Quantitative proton magnetic resonance spectroscopy of the basal ganglia in patients with affective disorders. Eur. Arch. Psychiatry Clin. Neurosci., 248, 53–58. Hamakawa, H., Kato, T., Shioiri, T. et al. (1999) Quantitative proton magnetic resonance spectroscopy of the bilateral frontal lobes in patients with bipolar disorder. Psychol. Med., 29, 639–644. Michael, N., Erfurth, A., Ohrmann, P. et al. (2003) Acute mania is accompanied by elevated glutamate/glutamine levels within the left dorsolateral prefrontal cortex. Psychopharmacology (Berl.), 168, 344–346. Dager, S.R., Friedman, S.D., Parow, A. et al. (2004) Brain metabolic alterations in medication-free patients with bipolar disorder. Arch. Gen. Psychiatry, 61, 450–458. Brambilla, P., Stanley, J.A., Nicoletti, M.A. et al. (2005) 1 H magnetic resonance spectroscopy investigation of the dorsolateral prefrontal cortex in bipolar disorder patients. J. Affect. Disord., 86, 61–67. Frey, B.N., Stanley, J.A., Nery, F.G. et al. (2007) Abnormal cellular energy and phospholipid metabolism in the left dorsolateral prefrontal cortex of medication-free individuals with bipolar disorder: An in vivo 1 H MRS study. Bipolar Disord., 9 (Suppl 1), 119–127. Colla, M., Schubert, F., Bubner, M. et al. (2009) Glutamate as a spectroscopic marker of hippocampal structural plasticity is elevated in long-term euthymic bipolar patients on chronic lithium therapy and correlates inversely with diurnal cortisol. Mol. Psychiatry, 14, 696–704. Castillo, M., Kwock, L., Courvoisie, H. and Hooper, S.R. (2000) Proton mr spectroscopy in children with bipolar affective disorder: Preliminary observations. AJNR Am. J. Neuroradiol., 21, 832–838. Gallelli, K.A., Wagner, C.M., Karchemskiy, A. et al. (2005) N-acetylaspartate levels in bipolar offspring with and at high-risk for bipolar disorder. Bipolar Disord., 7, 589–597. Deicken, R.F., Eliaz, Y., Feiwell, R. and Schuff, N. (2001) Increased thalamic N-acetylaspartate in male patients with familial bipolar I disorder. Psychiatry Res., 106, 35–45. Sharma, R., Venkatasubramanian, P.N., Barany, M. and Davis, J.M. (1992) Proton magnetic resonance spectroscopy
27.
28.
29.
30.
31.
32.
33.
34.
35.
36.
37.
38.
39. 40.
41.
|
195
of the brain in schizophrenic and affective patients. Schizophr. Res., 8, 43–49. Moore, G.J., Bebchuk, J.M., Hasanat, K. et al. (2000) Lithium increases N-acetyl-aspartate in the human brain: In vivo evidence in support of bcl-2s neurotrophic effects? Biol. Psychiatry, 48, 1–8. Silverstone, P.H., Wu, R.H., ODonnell, T. et al. (2003) Chronic treatment with lithium, but not sodium valproate, increases cortical N-acetyl-aspartate concentrations in euthymic bipolar patients. Int. Clin. Psychopharmacol., 18, 73–79. Frye, M.A., Watzl, J., Banakar, S. et al. (2007) Increased anterior cingulate/medial prefrontal cortical glutamate and creatine in bipolar depression. Neuropsychopharmacology, 32, 2490–2499. Forester, B.P., Streeter, C.C., Berlow, Y.A. et al. (2009) Brain lithium levels and effects on cognition and mood in geriatric bipolar disorder: A lithium-7 magnetic resonance spectroscopy study. Am. J. Geriatr. Psychiatry, 17, 13–23. Friedman, S.D., Dager, S.R., Parow, A. et al. (2004) Lithium and valproic acid treatment effects on brain chemistry in bipolar disorder. Biol. Psychiatry, 56, 340–348. Davanzo, P., Thomas, M.A., Yue, K. et al. (2001) Decreased anterior cingulate myo-inositol/creatine spectroscopy resonance with lithium treatment in children with bipolar disorder. Neuropsychopharmacology, 24, 359–369. Patel, N.C., DelBello, M.P., Cecil, K.M. et al. (2008) Temporal change in N-acetyl-aspartate concentrations in adolescents with bipolar depression treated with lithium. J. Child Adolesc Psychopharmacol., 18, 132–139. Moore, G.J., Bebchuk, J.M., Parrish, J.K. et al. (1999) Temporal dissociation between lithium-induced changes in frontal lobe myo-inositol and clinical response in manicdepressive illness. Am. J. Psychiatry, 156, 1902–1908. Silverstone, P.H., Wu, R.H., ODonnell, T. et al. (2002) Chronic treatment with both lithium and sodium valproate may normalize phosphoinositol cycle activity in bipolar patients. Hum. Psychopharmacol., 17, 321–327. Wu, R.H., ODonnell, T., Ulrich, M. et al. (2004) Brain choline concentrations may not be altered in euthymic bipolar disorder patients chronically treated with either lithium or sodium valproate. Ann. Gen. Hosp. Psychiatry, 3, 13. Patel, N.C., DelBello, M.P., Cecil, K.M. et al. (2006) Lithium treatment effects on myo-inositol in adolescents with bipolar depression. Biol. Psychiatry, 60, 998–1004. Urenjak, J., Williams, S.R., Gadian, D.G. and Noble, M. (1993) Proton nuclear magnetic resonance spectroscopy unambiguously identifies different neural cell types. J. Neurosci., 13, 981–989. Ross, B. and Bluml, S. (2001) Magnetic resonance spectroscopy of the human brain. Anat. Rec., 265, 54–84. Baslow, M.H. (2003) N-acetylaspartate in the vertebrate brain: Metabolism and function. Neurochem. Res., 28, 941–953. Taylor, D.L., Davies, S.E., Obrenovitch, T.P. et al. (1995) Investigation into the role of N-acetylaspartate in cerebral osmoregulation. J. Neurochem., 65, 275–281.
196
|
Chapter 14
42. Madhavarao, C.N., Chinopoulos, C., Chandrasekaran, K. and Namboodiri, M.A. (2003) Characterization of the N-acetylaspartate biosynthetic enzyme from rat brain. J. Neurochem., 86, 824–835. 43. Truckenmiller, M.E., Namboodiri, M.A., Brownstein, M.J. and Neale, J.H. (1985) N-acetylation of L-aspartate in the nervous system: Differential distribution of a specific enzyme. J. Neurochem., 45, 1658–1662. 44. Patel, T.B. and Clark, J.B. (1979) Synthesis of N-acetyl-Laspartate by rat brain mitochondria and its involvement in mitochondrial/cytosolic carbon transport. Biochem. J., 184, 539–546. 45. Moore, C.M., Breeze, J.L., Gruber, S.A. et al. (2000) Choline, myo-inositol and mood in bipolar disorder: A proton magnetic resonance spectroscopic imaging study of the anterior cingulate cortex. Bipolar Disord., 2, 207–216. 46. Kato, T., Hamakawa, H., Shioiri, T. et al. (1996) Cholinecontaining compounds detected by proton magnetic resonance spectroscopy in the basal ganglia in bipolar disorder. J. Psychiatry Neurosci., 21, 248–254. 47. Davanzo, P., Yue, K., Thomas, M.A. et al. (2003) Proton magnetic resonance spectroscopy of bipolar disorder versus intermittent explosive disorder in children and adolescents. Am. J. Psychiatry, 160, 1442–1452. 48. Stoll, A.L., Renshaw, P.F., Sachs, G.S. et al. (1992) The human brain resonance of choline-containing compounds is similar in patients receiving lithium treatment and controls: An in vivo proton magnetic resonance spectroscopy study. Biol. Psychiatry, 32, 944–949. 49. Miller, B.L., Chang, L., Booth, R. et al. (1996) In vivo 1 H MRS choline: Correlation with invitro chemistry/histology. Life Sci., 58, 1929–1935. 50. Brenner, R.E., Munro, P.M., Williams, S.C. et al. (1993) The proton NMR spectrum in acute EAE: The significance of the change in the cho:Cr ratio. Magn. Reson. Med., 29, 737–745. 51. Govindaraju, V., Young, K. and Maudsley, A.A. (2000) Proton NMR chemical shifts and coupling constants for brain metabolites. NMR Biomed., 13, 129–153. 52. Stoll, A.L., Sachs, G.S., Cohen, B.M. et al. (1996) Choline in the treatment of rapid-cycling bipolar disorder: Clinical and neurochemical findings in lithium-treated patients. Biol. Psychiatry, 40, 382–388. 53. Lyoo, I.K., Demopulos, C.M., Hirashima, F. et al. (2003) Oral choline decreases brain purine levels in lithium-treated subjects with rapid-cycling bipolar disorder: A doubleblind trial using proton and lithium magnetic resonance spectroscopy. Bipolar Disord., 5, 300–306. 54. Brand, A., Richter-Landsberg, C. and Leibfritz, D. (1993) Multinuclear NMR studies on the energy metabolism of glial and neuronal cells. Dev. Neurosci., 15, 289–298. 55. Ross, B.D. (1991) Biochemical considerations in 1 H spectroscopy. Glutamate and glutamine; myo-inositol and related metabolites. NMR Biomed., 4, 59–63. 56. Kato, T., Inubushi, T. and Kato, N. (1998) Magnetic resonance spectroscopy in affective disorders. J. Neuropsychiatry Clin. Neurosci., 10, 133–147.
57. Berridge, M.J., Downes, C.P. and Hanley, M.R. (1989) Neural and developmental actions of lithium: A unifying hypothesis. Cell, 59, 411–419. 58. Williams, R.S., Cheng, L., Mudge, A.W. and Harwood, A.J. (2002) A common mechanism of action for three moodstabilizing drugs. Nature, 417, 292–295. 59. Renshaw, P.F., Joseph, N.E. and Leigh, J.S. Jr (1986) Chronic dietary lithium induces increased levels of myo-inositol1-phosphatase activity in rat cerebral cortex homogenates. Brain Res., 380, 401–404. 60. Parthasarathy, L.K., Seelan, R.S., Wilson, M.A. et al. (2003) Regional changes in rat brain inositol monophosphatase 1 (IMPase 1) activity with chronic lithium treatment. Prog. Neuropsychopharmacol. Biol. Psychiatry, 27, 55–60. 61. Kaya, N., Resmi, H., Ozerdem, A. et al. (2004) Increased inositol-monophosphatase activity by lithium treatment in bipolar patients. Prog. Neuropsychopharmacol. Biol. Psychiatry, 28, 521–527. 62. Moore, C.M., Biederman, J., Wozniak, J. et al. (2006) Differences in brain chemistry in children and adolescents with attention deficit hyperactivity disorder with and without comorbid bipolar disorder: A proton magnetic resonance spectroscopy study. Am. J. Psychiatry, 163, 316–318. 63. Moore, C.M., Biederman, J., Wozniak, J. et al. (2007) Mania, glutamate/glutamine and risperidone in pediatric bipolar disorder: A proton magnetic resonance spectroscopy study of the anterior cingulate cortex. J. Affect. Disord., 99, 19–25. 64. Moore, C.M., Frazier, J.A., Glod, C.A. et al. (2007) Glutamine and glutamate levels in children and adolescents with bipolar disorder: A 4.0-T proton magnetic resonance spectroscopy study of the anterior cingulate cortex. J. Am. Acad. Child Adolesc. Psychiatry, 46, 524–534. 65. Yoon, J., Lyoo, I.K., Haws, C. et al. (2009) Decreased glutamate/glutamine levels may mediate cytidine’s efficacy in treating bipolar depression: A longitudinal proton magnetic resonance spectroscopy study. Neuropsychopharmacology, 34, 1810–1818. € ur, D., Drevets, W.C. and Price, J.L. (1998) Glial reduc66. Ong€ tion in the subgenual prefrontal cortex in mood disorders. Proc. Natl. Acad. Sci. USA, 95, 13290–13295. 67. Rajkowska, G. (2000) Postmortem studies in mood disorders indicate altered numbers of neurons and glial cells. Biol. Psychiatry, 48, 766–777. 68. Rajkowska, G., Halaris, A. and Selemon, L.D. (2001) Reductions in neuronal and glial density characterize the dorsolateral prefrontal cortex in bipolar disorder. Biol. Psychiatry, 49, 741–752. 69. Cotter, D.R., Pariante, C.M. and Everall, I.P. (2001) Glial cell abnormalities in major psychiatric disorders: The evidence and implications. Brain Res. Bull., 55, 585–595. 70. Sauter, A. and Rudin, M. (1993) Determination of creatine kinase kinetic parameters in rat brain by NMR magnetization transfer. Correlation with brain function. J. Biol. Chem., 268, 13166–13171. 71. Pouwels, P.J. and Frahm, J. (1998) Regional metabolite concentrations in human brain as determined by quantitative localized proton MRS. Magn. Reson. Med., 39, 53–60.
Functional Imaging Techniques 72. Marshall, I., Wardlaw, J., Cannon, J. et al. (1996) Reproducibility of metabolite peak areas in 1 H MRS of brain. Magn. Reson. Imaging, 14, 281–292. 73. Bothwell, J.H., Rae, C., Dixon, R.M. et al. (2001) Hypoosmotic swelling-activated release of organic osmolytes in brain slices: Implications for brain oedema in vivo. J. Neurochem., 77, 1632–1640. 74. Deicken, R.F., Fein, G. and Weiner, M.W. (1995) Abnormal frontal lobe phosphorous metabolism in bipolar disorder. Am. J. Psychiatry, 152, 915–918. 75. Deicken, R.F., Weiner, M.W. and Fein, G. (1995) Decreased temporal lobe phosphomonoesters in bipolar disorder. J. Affect. Disord., 33, 195–199. 76. Kato, T., Shioiri, T., Takahashi, S. and Inubushi, T. (1991) Measurement of brain phosphoinositide metabolism in bipolar patients using in vivo31 P-MRS. J. Affect. Disord., 22, 185–190. 77. Kato, T., Takahashi, S. and Inubushi, T. (1992) Brain lithium concentration by 7Li- and 1 H-magnetic resonance spectroscopy in bipolar disorder. Psychiatry Res., 45, 53–63. 78. Kato, T., Takahashi, S., Shioiri, T. and Inubushi, T. (1993) Alterations in brain phosphorous metabolism in bipolar disorder detected by in vivo 31 P and 7Li magnetic resonance spectroscopy. J. Affect. Disord., 27, 53–59. 79. Kato, T., Shioiri, T., Murashita, J. et al. (1994) Phosphorus-31 magnetic resonance spectroscopy and ventricular enlargement in bipolar disorder. Psychiatry Res., 55, 41–50. 80. Kato, T., Takahashi, S., Shioiri, T. et al. (1994) Reduction of brain phosphocreatine in bipolar II disorder detected by phosphorus-31 magnetic resonance spectroscopy. J. Affect. Disord., 31, 125–133. 81. Kato, T., Shioiri, T., Murashita, J. et al. (1995) Lateralized abnormality of high energy phosphate metabolism in the frontal lobes of patients with bipolar disorder detected by phase-encoded 31 P-MRS. Psychol. Med., 25, 557–566. 82. Murashita, J., Kato, T., Shioiri, T. et al. (2000) Altered brain energy metabolism in lithium-resistant bipolar disorder detected by photic stimulated 31 P-MR spectroscopy. Psychol. Med., 30, 107–115. 83. Hamakawa, H., Murashita, J., Yamada, N. et al. (2004) Reduced intracellular ph in the basal ganglia and whole brain measured by 31 P-MRS in bipolar disorder. Psychiatry Clin. Neurosci., 58, 82–88. 84. Buchli, R., Duc, C.O., Martin, E. and Boesiger, P. (1994) Assessment of absolute metabolite concentrations in human tissue by 31 P MRS in vivo. Part I: Cerebrum, cerebellum, cerebral gray and white matter. Magn. Reson. Med., 32, 447–452. 85. Ikeda, A. and Kato, T. (2003) Biological predictors of lithium response in bipolar disorder. Psychiatry Clin. Neurosci., 57, 243–250. 86. Yildiz, A., Demopulos, C.M., Moore, C.M. et al. (2001) Effect of lithium on phosphoinositide metabolism in human brain: A proton decoupled 31 P magnetic resonance spectroscopy study. Biol. Psychiatry, 50, 3–7. 87. Silverstone, P.H., Rotzinger, S., Pukhovsky, A. and Hanstock, C.C. (1999) Effects of lithium and amphetamine
89. 90.
91.
92.
93.
94.
95.
96.
97.
98. 99.
100.
101.
102.
103.
104.
105.
197
on inositol metabolism in the human brain as measured by H and 31 P MRS. Biol. Psychiatry, 46, 1634–1641. Erecinska, M. and Silver, I.A. (1989) ATP and brain function. J. Cereb. Blood Flow Metab., 9, 2–19. Kato, T. and Kato, N. (2000) Mitochondrial dysfunction in bipolar disorder. Bipolar Disord., 2, 180–190. Clausen, T., Zauner, A., Levasseur, J.E. et al. (2001) Induced mitochondrial failure in the feline brain: Implications for understanding acute post-traumatic metabolic events. Brain Res., 908, 35–48. Soares, J.C. and Mann, J.J. (1997) The anatomy of mood disorders-review of structural neuroimaging studies. Biol. Psychiatry, 41, 86–106. Taylor, W.D., Payne, M.E., Krishnan, K.R. et al. (2001) Evidence of white matter tract disruption in MRI hyperintensities. Biol. Psychiatry, 50, 179–183. Awada, K.A., Jackson, D.R., Baumann, S.B. et al. (1998) Effect of conductivity uncertainties and modeling errors on EEG source localization using a 2-D model. IEEE Trans. Biomed. Eng., 45, 1135–1145. Kempton, M.J., Geddes, J.R., Ettinger, U. et al. (2008) Metaanalysis, database, and meta- regression of 98 structural imaging studies in bipolar disorder. Arch. Gen. Psychiatry, 65, 1017–1032. Kieseppa, T., van Erp, T.G., Haukka, J. et al. (2003) Reduced left hemispheric white matter volume in twins with bipolar I disorder. Biol. Psychiatry, 54, 896–905. Brambilla, P., Nicoletti, M.A., Sassi, R.B. et al. (2003) Magnetic resonance imaging study of corpus callosum abnormalities in patients with bipolar disorder. Biol. Psychiatry, 54, 1294–1297. Chenevert, T.L., Brunberg, J.A. and Pipe, J.G. (1990) Anisotropic diffusion in human white matter: Demonstration with MR techniques in vivo. Radiology, 177, 401–405. Basser, P.J., Mattiello, J. and LeBihan, D. (1994) MR diffusion tensor spectroscopy and imaging. Biophys. J., 66, 259–267. Pierpaoli, C., Jezzard, P., Basser, P.J. et al. (1996) Diffusion tensor MR imaging of the human brain. Radiology, 201, 637–648. Sundgren, P.C., Dong, Q., Gomez-Hassan, D. et al. (2004) Diffusion tensor imaging of the brain: Review of clinical applications. Neuroradiology, 46, 339–350. Adler, C.M., Holland, S.K., Schmithorst, V. et al. (2004) Abnormal frontal white matter tracts in bipolar disorder: A diffusion tensor imaging study. Bipolar Disord., 6, 197–203. Beyer, J.L., Taylor, W.D., MacFall, J.R. et al. (2005) Cortical white matter microstructural abnormalities in bipolar disorder. Neuropsychopharmacology, 30, 2225–2229. Haznedar, M.M., Roversi, F., Pallanti, S. et al. (2005) Frontothalamo-striatal gray and white matter volumes and anisotropy of their connections in bipolar spectrum illnesses. Biol. Psychiatry, 57, 733–742. Regenold, W.T., DAgostino, C.A., Ramesh, N. et al. (2006) Diffusion-weighted magnetic resonance imaging of white matter in bipolar disorder: A pilot study. Bipolar Disord., 8, 188–195. Yurgelun-Todd, D.A., Silveri, M.M., Gruber, S.A. et al. (2007) White matter abnormalities observed in bipolar 1
88.
|
198
106.
107.
108.
109.
110.
111.
112.
113.
114.
115.
116.
117.
118.
119.
120.
|
Chapter 14
disorder: A diffusion tensor imaging study. Bipolar Disord., 9, 504–512. Bruno, S., Cercignani, M. and Ron, M.A. (2008) White matter abnormalities in bipolar disorder: A voxel-based diffusion tensor imaging study. Bipolar Disord., 10, 460–468. Versace, A., Almeida, J.R., Hassel, S. et al. (2008) Elevated left and reduced right orbitomedial prefrontal fractional anisotropy in adults with bipolar disorder revealed by tract-based spatial statistics. Arch. Gen. Psychiatry, 65, 1041–1052. Wang, F., Jackowski, M., Kalmar, J.H. et al. (2008) Abnormal anterior cingulum integrity in bipolar disorder determined through diffusion tensor imaging. Br. J. Psychiatry, 193, 126–129. Wang, F., Kalmar, J.H., Edmiston, E. et al. (2008) Abnormal corpus callosum integrity in bipolar disorder: A diffusion tensor imaging study. Biol. Psychiatry, 64, 730–733. Sussmann, J.E., Lymer, G.K., McKirdy, J. et al. (2009) White matter abnormalities in bipolar disorder and schizophrenia detected using diffusion tensor magnetic resonance imaging. Bipolar Disord., 11, 11–18. Mahon, K., Wu, J., Malhotra, A.K. et al. (2009) A voxel-based diffusion tensor imaging study of white matter in bipolar disorder. Neuropsychopharmacology, 34, 1590–1600. Houenou, J., Wessa, M., Douaud, G. et al. (2007) Increased white matter connectivity in euthymic bipolar patients: Diffusion tensor tractography between the subgenual cingulate and the amygdalo-hippocampal complex. Mol. Psychiatry, 12, 1001–1010. McIntosh, A.M., Maniega, S.M., Lymer, G.K. et al. (2008) White matter tractography in bipolar disorder and schizophrenia. Biol. Psychiatry, 64, 1088–1092. Adler, C.M., Adams, J., DelBello, M.P. et al. (2006) Evidence of white matter pathology in bipolar disorder adolescents experiencing their first episode of mania: A diffusion tensor imaging study. Am. J. Psychiatry, 163, 322–324. Frazier, J.A., Breeze, J.L., Papadimitriou, G. et al. (2007) White matter abnormalities in children with and at risk for bipolar disorder. Bipolar Disord., 9, 799–809. Pavuluri, M.N., Yang, S., Kamineni, K. et al. (2008) Diffusion tensor imaging study of white matter fiber tracts in pediatric bipolar disorder and attention- deficit/hyperactivity disorder. Biol. Psychiatry, 65, 586–593. Kafantaris, V., Kingsley, P., Ardekani, B. et al. (2009) Lower orbital frontal white matter integrity in adolescents with bipolar I disorder. J. Am. Acad. Child Adolesc Psychiatry, 48, 79–86. Mori, S., Matsui, T., Kuze, B. et al. (1999) Stimulation of a restricted region in the midline cerebellar white matter evokes coordinated quadrupedal locomotion in the decerebrate cat. J. Neurophysiol., 82, 290–300. Ardekani, B.A., Guckemus, S., Bachman, A. et al. (2005) Quantitative comparison of algorithms for inter-subject registration of 3D volumetric brain MRI scans. J. Neurosci. Methods, 142, 67–76. Smith, S.M., Jenkinson, M., Johansen-Berg, H. et al. (2006) Tract-based spatial statistics: Voxelwise analysis of multisubject diffusion data. Neuroimage, 31, 1487–1505.
121. Smith, S.M., Johansen-Berg, H., Jenkinson, M. et al. (2007) Acquisition and voxelwise analysis of multi-subject diffusion data with tract-based spatial statistics. Nat. Protoc., 2, 499–503. 122. Mori, S., Oishi, K., Jiang, H. et al. (2008) Stereotaxic white matter atlas based on diffusion tensor imaging in an ICBM template. Neuroimage, 40, 570–582. 123. Logothetis, N.K. (2008) What we can do and what we cannot do with fMRI. Nature, 453, 869–878. 124. Ogawa, S. and Lee, T.M. (1990) Magnetic resonance imaging of blood vessels at high fields: In vivo and in vitro measurements and image simulation. Magn. Reson. Med., 16, 9–18. 125. Ogawa, S., Lee, T.M., Kay, A.R. and Tank, D.W. (1990) Brain magnetic resonance imaging with contrast dependent on blood oxygenation. Proc. Natl. Acad. Sci. USA, 87, 9868–9872. 126. Matthews, P.M., Honey, G.D. and Bullmore, E.T. (2006) Applications of fMRI in translational medicine and clinical practice. Nat. Rev. Neurosci., 7, 732–744. 127. Phillips, M.L. and Frank, E. (2006) Redefining bipolar disorder: Toward DSM-V. Am. J. Psychiatry, 163, 1135–1136. 128. Yurgelun-Todd, D.A., Gruber, S.A., Kanayama, G. et al. (2000) fMRI during affect discrimination in bipolar affective disorder. Bipolar Disord., 2, 237–248. 129. Elliott, R., Ogilvie, A., Rubinsztein, J.S. et al. (2004) Abnormal ventral frontal response during performance of an affective go/no go task in patients with mania. Biol. Psychiatry, 55, 1163–1170. 130. Lawrence, N.S., Williams, A.M., Surguladze, S. et al. (2004) Subcortical and ventral prefrontal cortical neural responses to facial expressions distinguish patients with bipolar disorder and major depression. Biol. Psychiatry, 55, 578–587. 131. Malhi, G.S., Lagopoulos, J., Sachdev, P. et al. (2004) Cognitive generation of affect in hypomania: An fMRI study. Bipolar Disord., 6, 271–285. 132. Mitchell, R.L., Elliott, R., Barry, M. et al. (2004) Neural response to emotional prosody in schizophrenia and in bipolar affective disorder. Br. J. Psychiatry, 184, 223–230. 133. Malhi, G.S., Lagopoulos, J., Sachdev, P.S. et al. (2005) An emotional stroop functional MRI study of euthymic bipolar disorder. Bipolar Disord., 7 (Suppl 5), 58–69. 134. Chen, C.H., Lennox, B., Jacob, R. et al. (2006) Explicit and implicit facial affect recognition in manic and depressed states of bipolar disorder: A functional magnetic resonance imaging study. Biol. Psychiatry, 59, 31–39. 135. Wessa, M., Houenou, J., Paillere-Martinot, M.L. et al. (2007) Fronto- striatal overactivation in euthymic bipolar patients during an emotional Go/NoGo task. Am. J. Psychiatry, 164, 638–646. 136. Altshuler, L., Bookheimer, S., Townsend, J. et al. (2008) Regional brain changes in bipolar I depression: A functional magnetic resonance imaging study. Bipolar Disord., 10, 708–717. 137. Jogia, J., Haldane, M., Cobb, A. et al. (2008) Pilot investigation of the changes in cortical activation during facial affect recognition with lamotrigine monotherapy in bipolar disorder. Br. J. Psychiatry, 192, 197–201.
Functional Imaging Techniques 138. Curtis, V.A., Dixon, T.A., Morris, R.G. et al. (2001) Differential frontal activation in schizophrenia and bipolar illness during verbal fluency. J. Affect. Disord., 66, 111–121. 139. Blumberg, H.P., Leung, H.C., Skudlarski, P. et al. (2003) A functional magnetic resonance imaging study of bipolar disorder: State- and trait-related dysfunction in ventral prefrontal cortices. Arch. Gen. Psychiatry, 60, 601–609. 140. Adler, C.M., Holland, S.K., Schmithorst, V. et al. (2004) Changes in neuronal activation in patients with bipolar disorder during performance of a working memory task. Bipolar Disord., 6, 540–549. 141. Gruber, S.A., Rogowska, J. and Yurgelun-Todd, D.A. (2004) Decreased activation of the anterior cingulate in bipolar patients: An fMRI study. J. Affect. Disord., 82, 191–201. 142. Monks, P.J., Thompson, J.M., Bullmore, E.T. et al. (2004) A functional MRI study of working memory task in euthymic bipolar disorder: Evidence for task-specific dysfunction. Bipolar Disord., 6, 550–564. 143. Strakowski, S.M., Adler, C.M., Holland, S.K. et al. (2004) A preliminary fMRI study of sustained attention in euthymic, unmedicated bipolar disorder. Neuropsychopharmacology, 29, 1734–1740. 144. Strakowski, S.M., Adler, C.M., Holland, S.K. et al. (2005) Abnormal fMRI brain activation in euthymic bipolar disorder patients during a counting stroop interference task. Am. J. Psychiatry, 162, 1697–1705. 145. Altshuler, L.L., Bookheimer, S.Y., Townsend, J. et al. (2005) Blunted activation in orbitofrontal cortex during mania: A functional magnetic resonance imaging study. Biol. Psychiatry, 58, 763–769. 146. Kronhaus, D.M., Lawrence, N.S., Williams, A.M. et al. (2006) Stroop performance in bipolar disorder: Further evidence for abnormalities in the ventral prefrontal cortex. Bipolar Disord., 8, 28–39. 147. McIntosh, A.M., Whalley, H.C., McKirdy, J. et al. (2008) Prefrontal function and activation in bipolar disorder and schizophrenia. Am. J. Psychiatry, 165, 378–384. 148. Drapier, D., Surguladze, S., Marshall, N. et al. (2008) Genetic liability for bipolar disorder is characterized by excess frontal activation in response to a working memory task. Biol. Psychiatry, 64, 513–520. 149. Mechelli, A., Prata, D.P., Fu, C.H. et al. (2008) The effects of neuregulin1 on brain function in controls and patients with schizophrenia and bipolar disorder. Neuroimage, 42, 817–826. 150. Blumberg, H.P., Martin, A., Kaufman, J. et al. (2003) Frontostriatal abnormalities in adolescents with bipolar disorder: Preliminary observations from functional MRI. Am. J. Psychiatry, 160, 1345–1347. 151. Chang, K., Adleman, N.E., Dienes, K. et al. (2004) Anomalous prefrontal- subcortical activation in familial pediatric
152.
153.
154.
155.
156.
157.
158.
159.
160.
161.
162.
163.
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bipolar disorder: A functional magnetic resonance imaging investigation. Arch. Gen. Psychiatry, 61, 781–792. Rich, B.A., Vinton, D.T., Roberson-Nay, R. et al. (2006) Limbic hyperactivation during processing of neutral facial expressions in children with bipolar disorder. Proc. Natl. Acad. Sci. USA, 103, 8900–8905. Pavuluri, M.N., OConnor, M.M., Harral, E. and Sweeney, J. A. (2007) Affective neural circuitry during facial emotion processing in pediatric bipolar disorder. Biol. Psychiatry, 62, 158–167. Leibenluft, E., Rich, B.A., Vinton, D.T. et al. (2007) Neural circuitry engaged during unsuccessful motor inhibition in pediatric bipolar disorder. Am. J. Psychiatry, 164, 52–60. Chang, K.D., Wagner, C., Garrett, A. et al. (2008) A preliminary functional magnetic resonance imaging study of prefrontal-amygdalar activation changes in adolescents with bipolar depression treated with lamotrigine. Bipolar Disord., 10, 426–431. Phillips, M.L., Ladouceur, C.D. and Drevets, W.C. (2008) A neural model of voluntary and automatic emotion regulation: Implications for understanding the pathophysiology and neurodevelopment of bipolar disorder. Mol. Psychiatry, 13, 829, 833–857. Phillips, M.L. (2003) Understanding the neurobiology of emotion perception: Implications for psychiatry. Br. J. Psychiatry, 182, 190–192. Drevets, W.C., Price, J.L., Simpson, J.R. Jr et al. (1997) Subgenual prefrontal cortex abnormalities in mood disorders. Nature, 386, 824–827. Drevets, W.C. and Raichle, M.E. (1998) Reciprocal suppression of regional cerebral blood flow during emotional versus higher cognitive processes: implications for interactions between emotion and cognition. Cognition Emotion, 12, 353–385. Hager, F., Volz, H.P., Gaser, C. et al. (1998) Challenging the anterior attentional system with a continuous performance task: A functional magnetic resonance imaging approach. Eur. Arch. Psychiatry Clin. Neurosci., 248, 161–170. Bush, G., Whalen, P.J., Rosen, B.R. et al. (1998) The counting stroop: An interference task specialized for functional neuroimaging-validation study with functional MRI. Hum. Brain Mapp., 6, 270–282. Blumberg, H.P., Donegan, N.H., Sanislow, C.A. et al. (2005) Preliminary evidence for medication effects on functional abnormalities in the amygdala and anterior cingulate in bipolar disorder. Psychopharmacology (Berl). 183, 308–313. McClure, E.B., Treland, J.E., Snow, J. et al. (2005) Deficits in social cognition and response flexibility in pediatric bipolar disorder. Am. J. Psychiatry, 162, 1644–1651.
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Functional Brain Imaging Studies in Bipolar Disorder: Focus on Cerebral Metabolism and Blood Flow John O. Brooks III1, Po W. Wang2 and Terence A. Ketter2 1 2
UCLA Semel Institute for Neuroscience and Human Behavior, Los Angeles, CA, USA Department of Psychiatry and Behavioral Sciences, Stanford University School of Medicine, Stanford, CA, USA
Introduction Cerebral metabolic studies of bipolar disorder have provided significant contributions to our understanding of the disorder and its neural substrates. In this chapter we shall consider data obtained through several different scanning modalities. Our primary focus will be the gold standard of cerebral metabolism, positron emission tomography with flourodeoxyglucose-18 (18 FDG-PET). This neuroimaging test relies on the injection of 18 FDG and the subsequent detection of its uptake in the brain, often after a period of rest, but on occasion after the patient engages in a specified activity. Although not direct assessments of metabolism, we augment our discussion with consideration of cerebral blood flow data, derived from PET with oxygen-15 water (H215O), as well as single photon emission computed tomography (SPECT) with technetium-99m hexamethylpropyleneamine oxime (99m Tc-HMPAO) or technetium99m exametazime (99m Tc-EMZ).
Overall organization In this chapter, cerebral metabolism and blood flow findings are organized around the theme of corticolimbic dysregulation, which is the hypothesis that dysregulation of a corticolimbic network is a major contributor to the clinical phenomenology of bipolar disorder. Before reviewing neuroimaging research in this context, we first describe the hypothesis and its underlying neuroanatomy. The corticolimbicnetwork model [1–4] accounts for a range of clinical symptoms and neuroimaging findings in bipolar disorder. An adaptation of this model, provided in Figure 1, providesaschematicofnetworklinkagesacrossbrainregions that have been implicated in the pathophysiology of bipolar
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disorder. We integrate this network model to link previously proposed basal ganglia-thalamocortical circuits [5] and thus provide a theoretical explanation of the metabolic changes associated with bipolar disorder. Alexander and colleagues [5] described a series of basal ganglia-thalamocortical circuits, including limbic and lateral orbitofrontal circuits implicated in affective processes, and a dorsolateral prefrontal circuit that may contribute to integration of affective processes with higher cognitive functions. Dysfunction of these circuits may lead to impaired thalamic gating or modulation of sensory or affective information, which in turn could allow such input to disrupt cognitive and motor processes and thus contribute to the clinical profiles of mood disorders. Similarly, Mega and Cummings [7] suggested that frontal-subcortical circuit dysfunction could explain many of the clinical manifestations of bipolar disorder. We shall describe three frontalsubcortical circuits in more detail: dorsolateral prefrontal, lateral orbitofrontal and anterior cingulate.
Dorsolateral prefrontal and oribitofrontal circuits The origins of the dorsolateral prefrontal subcortical circuit [7] lie in Brodmanns Areas (BA) 9 and 10, which are located in dorsal and anterior portions of the lateral convexities of the frontal lobes. From BA 9 and 10, neurons project to the caudate nucleus and then directly to the mediodorsal globus pallidus interna and indirectly to the dorsal globus pallidus externa. The dorsal global pallidus externa projects to the lateral subthalamic nucleus from which fibres terminate in the globus pallidus interna and substantia nigra pars reticulata. The output from both structures terminates in the ventral anterior and mediodorsal thalamus, which in turn projects back to BA 9 and 10 to complete the circuit. The dorsolateral prefrontal circuit receives afferent projections from BA 46 and 7a and has efferent projections to BA 46 and 8.
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pallidum as well as the rostrodorsal substantia nigra. The ventral pallidum provides projections to the magnocellular mediodorsal thalamus, which completes the circuit by projecting back to the anterior cingulate. The subgenual prefrontal cortex is the region of the anterior cingulate that is inferior and posterior to the genu of the corpus callosum and commonly described as BA 25. The subgenual prefrontal cortex has both efferent and afferent connections with the ACC, as illustrated in Figure 1.
Clinical expressions of circuits
Fig. 1 A model of corticolimbic dysregulation in bipolar disorder. Areas generally associated with increased activation in bipolar disorder are in red and those with decreased activation are in blue. Note that colour-coding of regions is intended to represent the consensus findings for the region, because all findings have not been uniform. Numbers for BAs are provided where appropriate. ACC ¼ anterior cingulate cortex; AMYG ¼ amygdala; ATC ¼ anterior temporal cortex; CV ¼ cerebellar vermis; DLPFC ¼ dorsolateral prefrontal cortex; HYPTH ¼ hypothalamus; MOFC ¼ medial orbital prefrontal cortex; PHG ¼ parahippocampal gyrus; SGPFC ¼ subgenual prefrontal cortex; THAL ¼ thalamus; VLPFC ¼ ventrolateral prefrontal cortex. From Brooks et al. [6]. See also Plate 6.
The orbitofrontal circuit [7] originates in the anterior and ventral portions of the lateral convexities of the frontal lobes in BA 10 and 11, sending projections to the ventromedial caudate, which in turn projects to the mediodorsal globus pallidus interna as well as the substantia nigra pars reticulata. The globus pallidus and the substantia nigra project to the ventral anterior thalamus and the magnocellular division of the mediodorsal thalamus. The circuit is completed through the projections of the thalamus to the lateral orbitofrontal cortex. The orbitofrontal circuit has afferent projections from the superior temporal lobe and the orbitofrontal area as well as amygdala, rostromedial thalamus, medial substantia nigra and dorsal raphe. Efferent connections from the orbitofrontal circuit extend to the orbital and medial frontal areas, the mediofrontal aspect of BA 9, portions of the anterior cingulate and the insula.
The prefrontal cortex in general, and the dorsolateral prefrontal circuit in particular, are implicated in many neurocognitive and affective modulatory functions that are relevant to bipolar disorder, such as attention, reasoning and decision making, temporal organization of behaviour, working memory, organization of information, relation of cognition and emotion and modulation of emotion. The orbitofrontal circuit mediates behaviour and impairments associated with irritability and affective liability. In healthy subjects, the anterior cingulate cortex has been associated with performance monitoring [8] and is thought to be an important mediator of motivated behaviour [7]. The dorsal and ventral aspects of the anterior cingulate appear to be related to cognitive and affective processing, respectively. The subgenual prefrontal cortex may contribute to modulation of human mood states [9]. More importantly, because of the connections between the subgenual prefrontal cortex, the anterior cingulate cortex and other limbic regions, the subgenual prefrontal cortex may play a significant role in the integration of cognitive and emotional information [4].
Summary and implications The corticolimbic network includes neuroanatomical circuits that give rise to many of the behaviours and cognitive abilities that are altered in bipolar disorder. Of course, correlative function does not itself establish causality, but a number of structural and functional studies support the hypothesis of corticolimbic dysregulation as an explanation of many features of bipolar disorder. For example, resting state functional magnetic resonance imaging studies of major depression [10] suggest that cerebral metabolic changes may reflect network dysregulation.
Anterior cingulate circuit Mega and Cummings [7] described the anterior cingulate circuit as originating in BA 24 of the anterior cingulate, which provides input to the ventral striatum (ventromedial caudate, ventral putamen, nucleus accumbens and olfactory tubercle). From the ventral striatum, there are projections to the rostromedial globus pallidus interna and ventral
Cerebral blood flow and metabolism across affective states To appreciate better the nature of corticolimbic metabolic dysregulation in bipolar disorder, we shall describe findings according to the affective state of the participants. We consider only depression, mania and euthymia because,
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Fig. 2 Metabolic changes associated with bipolar depression relative to healthy controls. Decreased absolute metabolism is in blue. From Brooks et al. [6]. See also Plate 7.
to our knowledge, there are no neuroimaging studies of exclusively mixed episodes and in general patients in mixed states have been analysed in toto with patients in other mood states (primarily mania). Many studies have been performed with medicated bipolar disorder patients, which can complicate interpretation. However, medications may not confound neuroimaging findings as much as some have contended [11].
Cerebral metabolism studies in bipolar depression Cerebral metabolic studies of bipolar depression are not as numerous as those of unipolar depression, although extant studies suggest a number of similarities between the two. Studies have commonly detected decreased dorsolateral prefrontal cortical metabolism using 18 FDG-PET [6,12–17] and cerebral blood flow using H2 15 O-PET [18] or 99m Tc-HMPAO-SPECT [19,20]. However, a few reports failed to detect differences between depressed bipolar patients and healthy controls [21–23]. In a group of 17 treatment-resistant, largely rapid-cycling, medication-free inpatients diagnosed with moderate to severe bipolar depression, Ketter et al. [16] performed resting 18 FDG-PET scans and found that, compared to healthy controls, the depressed bipolar disorder patients exhibited decreases in absolute metabolism (i.e. the actual metabolic rate computed based on arterial blood sampling and the cerebral PET scans) in the inferior, middle and superior frontal gyri (BA 8, 9, 10, 44, 45, 46). In addition, decreased absolute temporal (BA 22, 39, 40, 42) metabolic rates were observed relative to control subjects. Ketter et al. did not find evidence of regional absolute metabolic increases. When metabolic rates were normalized to whole brain metabolism, there was evidence of not only relative metabolic decreases with a similar distribution to the absolute decreases, but also relative metabolic increases in anterior
limbic and paralimbic structures including the right amygdala, putamen and caudate. Ketter et al.s [16] pattern of results may have been specific to the clinical characteristics of their sample of treatmentresistant, and in many cases rapid cycling, patients and thus not representative of bipolar depression in general. To check this possibility, Brooks et al. [6] performed a resting 18 FDG-PET study with a group of 15 medication-free depressed bipolar outpatients who were not selected on the basis of treatment resistance or rapid-cycling, and thus probably more representative of the clinical population as a whole. As illustrated in Figure 2, when compared to healthy controls, patients with bipolar depression exhibited decreased absolute metabolic rates in dorsolateral prefrontal cortex (BA 10, 46), medial orbital prefrontal cortex (BA 10, 11), anterior cingulate (BA 24, 32) and subgenual prefrontal cortex (BA 25). Analysis of normalized cerebral metabolism yielded a similar pattern of findings. Brooks et al. did not find evidence of increased absolute or normalized limbic metabolism, which suggests that limbic hypermetabolism may be specific to treatment-resistant and/or rapid-cycling bipolar depression. Brooks et al.s findings were replicated in a sample of mostly medicated patients with bipolar depression [24], where depressed patients exhibited decreased metabolism in bilateral prefrontal, insula and cingulate cortices. Brooks et al.s [6] and Ketter et al.s [16] studies included patients diagnosed with bipolar disorder type I as well as those diagnosed with type II. In a study restricted to 13 patients with type II, 18 FDG-PET scans were obtained from patients who were taking therapeutic doses of lithium or divalproex and healthy controls [25]. Interestingly, these depressed type II patients exhibited increased limbic and paralimbic metabolism (in the amygdala, orbitofrontal cortex, anterior cingulate and insula) in a fashion analogous to the study of Ketter et al. However, in a study of younger, depressed bipolar disorder patients, we did not
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find altered absolute cerebral metabolism relative to healthy controls in the dorsolateral prefrontal cortex or the subgenual prefrontal cortex [26], but did find evidence of differential relations between both regions and performance on an attention task that suggested that individual differences in subgenual prefrontal metabolism were related to attention and differences in dorsolateral prefrontal metabolism to inhibitory control. A recent study compared cerebral metabolism using 18 FDG-PET in heterogeneously medicated subjects diagnosed with bipolar (N ¼ 12) or unipolar (N ¼ 18) depression [24]. Although the sample size was limited, the authors found evidence of a greater decrease in prefrontal and anterior cingulate metabolism in depressed bipolar patients compared to healthy controls. For patients with unipolar depression, there was evidence of lower metabolism in the prefrontal cortex, posterior cingulate and insula compared to healthy controls. The authors did not find any evidence of hypermetabolic regions in their depressed patients (either bipolar or unipolar) compared to healthy controls. An older 18 FDG-PET study of 7 bipolar and 3 unipolar heterogeneously medicated patients who were depressed also reported prefrontal hypometabolism relative to healthy controls [17]. Another of the early studies of cerebral metabolism in bipolar depression revealed prefrontal hypometabolism [27]. This study compared medication-free patients diagnosed with bipolar (N ¼ 10) or unipolar (N ¼ 10) depression to patients with obsessive/compulsive disorder and depression (N ¼ 10) and controls. Although current neuroimaging analysis programs were not available, Baxter et al. [27] reported that patients with unipolar or bipolar depression exhibited similarly lower dorsolateral prefrontal metabolism compared to healthy controls. Interestingly, the authors did not find any differences between patients with unipolar depression and those with bipolar depression. Although this study suggests that there may be cerebral blood flow similarities in unipolar and bipolar depression, the analytic techniques and limited statistical power could account for the inability to detect cerebral metabolic differences between unipolar and bipolar depression in this study. In one report, in 16 mildly depressed unmedicated treatment-resistant, largely rapid-cycling, medication-free bipolar inpatients compared to healthy controls, relative metabolic activity was increased in the left prefrontal cortex, including ventrolateral structures such as the inferior frontal gyrus [16] a finding reported in some studies of unmedicated depressed unipolar patients imaged in the resting condition [21,28–30]. Some (but not all) studies have found evidence of normalized amygdala hypermetabolism. For example, Ketter et al. [16] reported amygdala hypermetabolism when their absolute 18 FDG-PET findings were normalized to whole brain metabolism. In addition, other work has reported
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amygdala hypermetabolism associated with bipolar depression in unmedicated patients [31]. The reasons for the somewhat variable findings of 18 FDG-PET studies are unclear. Studies that reported limbic hypermetabolism included medicated or unmedicated patients, as have studies that reported hypometabolism. An explanation based on the presence of cerebral metabolic subtypes is not readily supported, because the samples of the studies do not differ systematically. Moreover, there is no reason to expect such subtypes would exert such a strong influence in each study.
Cerebral blood flow studies in bipolar depression Several researchers have studied the neural substrates of bipolar depression using H2 15 O-PET-PET, which provides an index of cerebral blood flow, which is believed to vary with cerebral metabolism. In a H2 15 O-PET study involving transient induced sadness in 11 depressed and 9 euthymic bipolar disorder patients taking lithium or valproate, Kr€ uger et al. [32] found that for both depressed and euthymic patients, sadness was associated with increased blood flow in the insula and cerebellum as well as decreased blood flow in the dorsal prefrontal cortex, medial orbitofrontal cortex, posterior cingulate and temporal cortex. Euthymic patients diverged from their depressed counterparts in that only euthymic patients exhibited increased blood flow in the anterior cingulate, whereas depressed patients uniquely exhibited increased blood flow in the lateral prefrontal cortex. Prior to any mood induction, euthymic patients exhibited greater blood flow in the anterior cingulate and orbitofrontal cortex. Thus, the results from this blood flow study seem to be more consistent with 18 FDG-PET findings of prefrontal hypometabolism in bipolar depression. Cerebral blood flow does not always mirror cerebral metabolism. Indeed, in some situations blood flow and metabolism appear to be dissociated [33]. For example, there is preliminary evidence that cerebral blood flow and metabolism are positively correlated in 9 healthy controls and 9 unmedicated depressed bipolar disorder patients [33], but not in 8 unmedicated patients diagnosed with unipolar depression. Thus, there is probably a positive correlation between cerebral blood flow and metabolism in bipolar disorder.
Summary of cerebral blood flow and metabolism studies in bipolar depression Although there is some variability across studies, including a few null results, current research permits some generalizations. In terms of the corticolimbic dysregulation model, it appears that cerebral metabolism in bipolar de-
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pression is characterized by prefrontal hypometabolism, particularly in the dorsolateral and medial orbital regions. This hypometabolism is generally found in the temporal cortex as well, although deeper limbic structures have been found to exhibit hypermetabolism in certain subsets of depressed bipolar disorder subjects (e.g. rapid cycling and treatment resistant). There is also a reasonable case to be made for hypometabolism in both the anterior and posterior cingulate, to varying degrees, with probable hypometabolism in the subgenual prefrontal cortex. Blood flow studies are largely consistent with the metabolic studies in that patterns of perfusion typically overlap regions implicated in metabolic studies. In bipolar depression it appears that prefrontal circuits exhibit the most change in association with depression. Anterior cerebral blood flow and metabolism decreases often correlate with the severity of bipolar and unipolar depression [16,21,27,30,34–43]. However, some studies failed to detect such a relation [44–48]. This could result from lack of sensitivity of measures of cerebral metabolism or mood, or both. Importantly, there is notable concordance between metabolic dysregulation and structural alterations (described elsewhere in this volume).
Cerebral metabolism studies in mania The study of mania presents abundant challenges because of the volatile clinical status of manic patients. Consequently, studies of mania are few and typically characterized by small samples, even by neuroimaging standards, of patients with varying current medications. Indeed, in the past 20 years, there have only been four 18 FDG-PET studies of mania. One of the earliest 18 FDG-PET studies of mania included six unmedicated patients and, without the benefit of contemporary analytic techniques, reported increased lateral prefrontal metabolism compared to controls [27]. However, this finding was not replicated in later work.
A larger-scale study in primarily medicated patients that suggested dorsolateral prefrontal cortex dysregulation used resting 18 FDG-PET [49]. In this study, the authors performed a factor analysis on the 26 regions of interest (ROI) they defined and then argued for the existence of four categories representing: (1) an anterior/posterior gradient; (2) left amygdala/right temporal: (3) left frontal/right limbic: and (4) anterior cingulate. They computed factor scores for each patient based on the factors they defined to determine whether the groups could be distinguished based on their metabolic patterns. For both the anterior/posterior gradient factor and the left amygdala/right temporal factor, they found that 15 manic patients exhibited lower normalized metabolic rates than healthy controls. al-Mousawi et al. noted that the anterior/posterior factor largely reflected activity in the DLPFC. Thus, manic patients exhibited hypometabolism in the DLPFC relative to controls [49]. Drevets and colleagues [9] published a resting 18 FDG-PET study of paralimbic metabolic dysregulation, which reported increased resting subgenual prefrontal metabolism in four patients (only one of whom was medicated) with bipolar mania. Notably, the definition of the subgenual prefrontal cortex in Drevets study is slightly different than ones used subsequently. In particular, Drevets region of interest tends to encompass more of BA 24, which is more pregenual. The more common definition of the subgenual prefrontal cortex typically comprises BA 25, which includes the rectal gyrus. The actual significance of the differing definitions is unclear. We recently completed a resting 18 FDG-PET study in eight primarily briefly medicated patients with mania, which was remarkable for the degree to which the results were consistent with an amalgam of previous findings [50]. As shown in Figure 3, we found evidence of simultaneous decreased prefrontal metabolism as well as limbic/paralimbic hypermetabolism. Specifically, hypometabolism was found in the dorsolateral prefrontal cortex as well as a
Fig. 3 Metabolic changes associated with bipolar mania relative to healthy controls. Regions with decreased metabolism are in blue, and increased metabolism in red. From Brooks et al. (2010). See also Plate 8.
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portion of the anterior cingulate cortex. We did not find evidence of altered amygdala metabolism, but metabolism was increased in the adjacent hippocampal complex and marginally so in the subgenual prefrontal cortex. Given the variability in findings of altered amygdala metabolism in mania, it may be that such perturbations are associated with specific tasks as opposed to a state feature of mania.
Cerebral blood flow studies in mania Early studies of cerebral blood flow alterations in mania tended to be somewhat nonspecific, ranging from finding no difference between 30 medicated manic patients and controls [51] to generally increased left hemisphere cerebral blood flow in a sample of 11 mostly unmedicated manic patients [52]. In a study that investigated the relation between neurocognitive function and cerebral blood flow, Benabarre et al. [53] performed resting 99m Tc-HMPAO-SPECT scans of 7 manic, 8 hypomanic, 12 depressed and 3 euthymic unmedicated bipolar patients. Unfortunately, the results were not reported according to mood state, but Benabarre et al. found a relation between memory and decreased frontal metabolism. Another resting N-isopropyl-p123 I-iodoamphetamine 123 IMP-SPECT study suggested evidence of decreased frontal blood flow in 11 patients with bipolar mania [41]. A resting 99m Tc-EMZ-SPECT study of 7 patients who developed mania after lithium was replaced with placebo revealed evidence of increased blood flow in the anterior cingulate cortex [54]. A third resting state 99m Tc-HMPAO-SPECT study of mania found that compared to healthy controls, 5 medication-free patients with mania exhibited decreased blood flow in the right dorsal and basal temporal cortices [55]. This finding is somewhat at odds with studies that have suggested increased metabolism in deeper temporal structures. Blumberg et al.s [56] H2 15 O-PET study of five manic and six euthymic medicated bipolar patients with six healthy controls revealed a decreased activation of the prefrontal area during a word generation task. In particular, manic subjects exhibited decreased activation in BA 10 relative to control subjects. Blumberg et al. posited that decreased blood flow in the prefrontal cortex could be responsible for some of the cognitive and emotional symptoms of mania, especially impaired planning, judgement and insight. Indeed, Blumberg et al. [56] also suggested that decreased prefrontal metabolism may be associated with cognitive and emotional symptoms of mania and that impaired orbitofrontal modulation of the amygdala and hypothalamus could contribute to dysregulation of more primitive affective processes. In subsequent work, Blumberg et al. [57] studied five manic patients and six euthymic medicated patients with H2 15 O-PET and found increased left anterior cingulate activity and increased left caudate activity in manic
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compared to the euthymic patients. They hypothesized that increased anterior cingulate activity could explain the attention and cognitive dysfunction associated with mania. Rubinsztein et al. [58] compared the performance of 6 manic bipolar and 6 depressed unipolar primarily medicated patients to that of 10 controls on a decision-making task administered during H2 15 O-PET scans, which allowed assessment of regional cerebral blood flow. They found the expected performance differences amongst the groups, but also reported activation (increased blood flow) in the anterior cingulate gyrus of manic patients and reduced activation in the superior frontal gyrus. Rubinsztein et al.s findings are consistent with those of Blumberg et al. [56], who found decreased right prefrontal blood flow in a group of six manic patients compared to five euthymic bipolar patients.
Summary of cerebral blood flow and metabolism studies in mania As with bipolar depression, cerebral metabolic findings have been somewhat variable for bipolar mania, but certain themes are consistent with the hypothesis of corticolimbic dysregulation. In general, the evidence appears fairly consistent regarding prefrontal (especially orbitofrontal and dorsolateral) cortex hypometabolism associated with mania. The finding of limbic and paralimbic hypermetabolism conjointly with prefrontal hypometabolism suggests that some clinical signs of mania could reflect inadequate regulation of a hyperactive limbic network. This inadequacy of regulation could give rise to increased metabolism in the subgenual prefrontal cortex, which presumably mediates aspects of the limbic/prefrontal interface. Cerebral blood flow studies that have included different cognitive tasks suggest that metabolic dysregulation in several regions manifest as hypoactivation (dorsolateral prefrontal cortex) or hyperactivation (anterior cingulate cortex) compared to control subjects on tasks of decisionmaking or word generation.
Cerebral metabolism studies in euthymic bipolar disorder patients Few cerebral metabolic studies have targeted the euthymic phase of bipolar disorder. Yet, there is increasing evidence that at least some of the pernicious changes associated with syndromal mood episodes in bipolar disorder persist into euthymia. Thus, it is important to not only clarify mood states of study participants, but to conduct studies in different mood states. An early 18 FDG-PET study of 16 bipolar and 4 unipolar medication-free patients used mild electrical shock during the uptake phase of the scan and found evidence of decreased prefrontal metabolism in the patient group relative to healthy controls [14]. The authors suggested that this
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difference could be responsible for some of the cognitive deficits associated with the disease. Ketter and associates found that in primarily treatment resistant rapid cycling bipolar disorder unmedicated patients during euthymia compared to healthy controls, resolution of the prefrontal absolute hypometabolism and anterior paralimbic normalized hypermetabolism seen in depression, but persistence of cerebellar normalized hypermetabolism [16]. We reported a recent study that provided more comprehensive evidence of cerebral metabolic dysfunction during euthymia in bipolar disorder. We performed the first study using a group of euthymic bipolar disorder patients over the age of 50 (average age 59 years) and administered resting 18 FDG-PETscans [6]. The patient sample comprised primarily medicated patients diagnosed with bipolar disorder type I or II. Our primary focus was to explore the degree of corticolimbic metabolic dysregulation during euthymia, so we performed ROI analyses using the regions specified in Figure 1. We generated a statistical parametric map, which is shown in Figure 4. Even though the bipolar disorder patients in this sample had at most minimal affective symptoms and were taking varying medications, there was evidence of corticolimbic dysregulation. Specifically, prefrontal structures, including the dorsolateral prefrontal cortex, and to a lesser extent the ventrolateral prefrontal cortex, exhibited decreased normalized resting metabolism compared to healthy controls. Conversely, limbic (parahippocampal gyrus, amygdala) and to a lesser extent paralimbic (subgenual prefrontal cortex, anterior temporal cortex) exhibited increased normalized resting metabolism. We hypothesized that the corticolimbic metabolic dysregulation that we observed could contribute to the residual neurocognitive and behavioural changes that have been observed in older adults with bipolar disorder.
Cerebral blood flow studies in euthymic bipolar disorder patients Most studies of cerebral blood flow in the euthymic phase of bipolar disorder are task-specific. Thus, the interpretation of the studies must be made in light of the task performed as opposed to traits that could be expressed in resting state studies. A recently published resting state cerebral blood flow study of younger bipolar disorder patients during a period of euthymia employed 99m Tc-HMPAO-SPECT [59]. Consistent with the results of our 18 FDG-PET study of older adults described previously [6], the authors found that when compared to healthy controls, 16 medicated euthymic bipolar disorder patients exhibited decreased blood flow in the medial frontal, cingulate and medial temporal regions. However, this SPECT study did not report evidence of alterations in perfusion in limbic regions that would correspond to the study by Brooks et al. [6] in older adults. Results of task-related studies have been variable, and could reflect task demands, but do provide important information regarding cerebral changes. For example, a blood flow study of six euthymic medicated bipolar disorder patients did not demonstrate superior temporal abnormalities in a verbal fluency task as assessed by H215O-PET [60]. However, H215O-PET study of brain responses to novel motor sequences in 13 primarily medicated euthymic bipolar disorder type II patients revealed that instead of activating a superior parietal and supplementary motor area circuit as in controls, the bipolar disorder patients exhibited rather widespread activation of medial prefrontal and limbic structures and insula [61]. Blumberg et al. [56] used H215O-PET and a word generation task and found evidence of decreased prefrontal blood flow (BA 11) in eight primarily unmedicated euthymic bipolar I disorder patients. Deckersbach et al. [62] used H215O-PET in conjunction with the study phase of a memory test and found that
Fig. 4 Resting state cerebral metabolic differences in older, euthymic patients with bipolar disorder compared to healthy controls. Regions with increased metabolism in bipolar disorder patients are in red and those with decreased metabolism are in blue. From Brooks et al. [6]. See also Plate 9.
Functional Brain Imaging Studies in Bipolar Disorder
eight primarily unmedicated euthymic bipolar I disorder patients exhibited decreased prefrontal (BA 9, 46) blood flow compared to healthy control subjects. We reported evidence of differential associations between resting cerebral metabolism and verbal recall deficits in 16 mostly medicated older adults with bipolar disorder and 11 healthy comparison subjects [63]. Specifically, we found evidence that verbal memory deficits were more strongly related to prefrontal hypometabolism and paralimbic hypermetabolism in bipolar disorder subjects than in healthy comparison subjects.
Summary of cerebral blood flow and metabolism studies in euthymic bipolar disorder patients Because of the paucity of studies of cerebral metabolism during euthymia, conclusions that may be drawn regarding trait abnormalities of cerebral metabolic dysregulation in bipolar disorder are limited. Based on studies of older adults with bipolar disorder, it appears that repeated episodes of dysregulation of prefrontal cortex and limbic, and to some extent paralimbic, structures during affective episodes could lead to more pernicious dysregulation that persists in euthymia. The persistence of abnormalities in euthymia in older patients could be related to the combination of ageing and illness progression. Blood flow studies that have incorporated cognitive tasks support the contention that trait abnormalities are present at least in the dorsolateral prefrontal cortex and certain limbic structures.
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dysregulation of the dorsolateral prefrontal circuit and, to a lesser extent, the anterior cingulate circuit. Manic episodes appear be associated with dorsolateral, and to some degree ventrolateral, prefrontal hypometabolism. There also seems to be consensus that hypermetabolism occurs in limbic (parahippocampal gyrus and amygdala) and paralimbic (subgenual prefrontal and anterior cingulate) regions. As with bipolar depression, decreased dorsolateral prefrontal metabolism may contribute to attention deficits. Limbic hypermetabolism may contribute to the affective instability that characterizes mania. Manic episodes thus appear associated with diffuse corticolimbic dysregulation through all major circuits. Curiously, studies have not provided evidence that supports cerebral metabolic differences in the thalamus however. This could be related in part to changes being more difficult to detect due to the thalamic subregions involved having a smaller volume compared to the dorsolateral prefrontal cortex. Continued episodes of corticolimbic dysregulation, at least from a metabolic perspective, may contribute to more persistent dysregulation during euthymia. Evidence thus far appears to support this contention, although there are few cerebral metabolic studies of the euthymic phase of bipolar disorder and only one study of older euthymic patients with bipolar disorder. Longitudinal studies of cerebral metabolism across mood states and across the life span are necessary for a more comprehensive understanding of the cerebral metabolic dysregulation in bipolar disorder.
References Conclusions Cerebral metabolism and blood flow studies to date support the general contention that bipolar disorder is manifest at least in part through corticolimbic dysregulation. In particular, in older patients with bipolar disorder, dorsolateral and medial orbital prefrontal hypometabolism may persist through euthymia. Limbic and paralimbic hypermetabolism may be phenomena that increase over the course of the illness as suggested by the presence in euthymic older patients. Collectively, metabolic studies of bipolar disorder suggest several areas of corticolimbic dysregulation. It appears that in both depression and mania, dorsolateral prefrontal cortex hypometabolism contributes to the attention deficits that characterize affective episodes. Other areas of hypometabolism include the subgenual prefrontal cortex and, to some extent, the orbitofrontal cortex. Although many studies have not found evidence of limbic and/or paralimbic hypermetabolism, a few researchers report such hypermetabolism in rapid-cycling or treatment-resistant bipolar depression. Thus, in terms of cerebral metabolic changes, bipolar depression may be more associated with
1. Adler, C.M., DelBello, M.P. and Strakowski, S.M. (2006) Brain network dysfunction in bipolar disorder. CNS Spectrums, 11 (4), 312–320. 2. Brooks, J.O., Hoblyn, J.C., Woodard, S.A. et al. (2009) Corticolimbic metabolic dysregulation in euthymic older adults with bipolar disorder. J. Psychiatr. Res., 94 32–37. 3. Mayberg, H.S. (1997) Limbic-Cortical dysregulation: A proposed model of depression. J. Neuropsych. Clin. N., 9 (3), 471–481. 4. Strakowski, S.M., Delbello, M.P. and Adler, C.M. (2005) The functional neuroanatomy of bipolar disorder: A review of neuroimaging findings. Mol. Psychiatry, 10 (1), 105–116. 5. Alexander, G.E., Crutcher, M.D. and DeLong, M.R. (1990) Basal ganglia-thalamocortical circuits: Parallel substrates for motor, oculomotor, “prefrontal” and “limbic” functions. Prog. Brain Res., 85 119–146. 6. Brooks, J.O., Wang, P.W., Bonner, J.C. et al. (2009) Decreased prefrontal, anterior cingulate, insula, and ventral striatal metabolism in medication-free depressed outpatients with bipolar disorder. J. Psychiatr. Res., 43 (3), 181–188. 7. Mega, M.S. and Cummings, J.L. (1994) Frontal-Subcortical circuits and neuropsychiatric disorders. J. Neuropsych. Clin. N., 6 (4), 358–370.
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|
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8. MacDonald, A.W., Cohen, J.D., Stenger, V.A. and Carter, C.S. (2000) Dissociating the role of the dorsolateral prefrontal and anterior cingulate cortex in cognitive control. Science, 288 (5472), 1835–1838. 9. Drevets, W.C., Price, J.L., Simpson, J.R. et al. (1997) Subgenual prefrontal cortex abnormalities in mood disorders. Nature, 386 (6627), 824–827. 10. Greicius, M.D., Flores, B.H., Menon, V. et al. (2007) RestingState functional connectivity in major depression: Abnormally increased contributions from subgenual cingulate cortex and thalamus. Biol. Psychiatry, 62 (5), 429–437. 11. Phillips, M.L., Travis, M.J., Fagiolini, A. and Kupfer, D.J. (2008) Medication effects in neuroimaging studies of bipolar disorder. Am. J. Psychiatry, 165 (3), 313–320. 12. Baxter, L.R., Phelps, M.E., Mazziotta, J.C. et al. (1985) Cerebral metabolic rates for glucose in mood disorders. Studies with positron emission tomography and fluorodeoxyglucose F 18. Arch. Gen. Psychiatry, 42 (5), 441–447. 13. Buchsbaum, M.S., Cappelletti, J., Ball, R. et al. (1984) Positron emission tomographic image measurement in schizophrenia and affective disorders. Ann. Neurol, (15 Suppl), S157–S165. 14. Buchsbaum, M.S., Wu, J., DeLisi, L.E. et al. (1986) Frontal cortex and basal ganglia metabolic rates assessed by positron emission tomography with [18F]2-deoxyglucose in affective illness. J. Affect. Disord., 10 (2), 137–152. 15. Cohen, R.M., Semple, W.E., Gross, M. et al. (1989) Evidence for common alterations in cerebral glucose metabolism in major affective disorders and schizophrenia. Neuropsychopharmacology, 2 (4), 241–254. 16. Ketter, T.A., Kimbrell, T.A., George, M.S. et al. (2001) Effects of mood and subtype on cerebral glucose metabolism in treatment-resistant bipolar disorder. Biol. Psychiatry, 49 (2), 97–109. 17. Martinot, J.L., Hardy, P., Feline, A. et al. (1990) Left prefrontal glucose hypometabolism in the depressed state: A confirmation. Am. J. Psychiatry, 147 (10), 1313–1317. 18. George, M.S., Ketter, T.A., Parekh, P.I. et al. (1996) Gender differences in regional cerebral blood flow during transient self-induced sadness or happiness. Biol. Psychiatry, 40 (9), 859–871. 19. Ebert, D., Feistel, H., Barocka, A. et al. (1993) A test-retest study of cerebral blood flow during somatosensory stimulation in depressed patients with schizophrenia and major depression. Eur. Arch. Psy. Clin. N., 242 (4), 250–254. 20. Ito, H., Kawashima, R., Awata, S. et al. (1996) Hypoperfusion in the limbic system and prefrontal cortex in depression: SPECT with anatomic standardization technique. J. Nucl. Med., 37 (3), 410–414. 21. Cohen, R.M., Gross, M., Nordahl, T.E. et al. (1992) Preliminary data on the metabolic brain pattern of patients with winter seasonal affective disorder. Arch. Gen. Psychiatry, 49 (7), 545–552. 22. Goyer, P.F., Schulz, P.M., Semple, W.E. et al. (1992) Cerebral glucose metabolism in patients with summer seasonal affective disorder. J. Nuc. Med., 7 (3), 233–240. 23. Tutus, A., Simsek, A., Sofuoglu, S. et al. (1998) Changes in regional cerebral blood flow demonstrated by single photon
24.
25.
26.
27.
28.
29.
30.
31.
32.
33.
34.
35.
36.
37.
38.
emission computed tomography in depressive disorders: Comparison of unipolar vs. Bipolar Subtypes. Psychiatry Res., 83 (3), 169–177. Hosokawa, T., Momose, T. and Kasai, K. (2008) Brain glucose metabolism difference between bipolar and unipolar mood disorders in depressed and euthymic states. Prog. Neuropsychopharmacol. Biol. Psychiatry, 33 (2), 243–250. Mah, L., Zarate, C.A., Singh, J. et al. (2007) Regional cerebral glucose metabolic abnormalities in bipolar II depression. Biol. Psychiatry, 61 (6), 765–775. Brooks, J.O., Wang, P.W., Strong, C. et al. (2006) Preliminary evidence of differential relations between prefrontal cortex metabolism and sustained attention in depressed adults with bipolar disorder and healthy controls. Bipolar Disord., 8 (3), 248–254. Baxter, L.R., Schwartz, J.M., Phelps, M.E. et al. (1989) Reduction of prefrontal cortex glucose metabolism common to three types of depression. Arch. Gen. Psychiatry, 46 (3), 243–250. Baxter, L.R., Phelps, M.E., Mazziotta, J.C. et al. (1987) Local cerebral glucose metabolic rates in obsessive-compulsive disorder. A comparison with rates in unipolar depression and in normal controls. Arch. Gen. Psychiatry, 44 (3), 211–218. Biver, F., Goldman, S., Delvenne, V. et al. (1994) Frontal and parietal metabolic disturbances in unipolar depression. Biol. Psychiatry, 36 (6), 381–388. Drevets, W.C., Videen, T.O., Price, J.L. et al. (1992) A functional anatomical study of unipolar depression. Neuropsychopharmacology, 12 (9), 3628–3641. Drevets, W.C., Price, J.L., Bardgett, M.E. et al. (2002) Glucose metabolism in the amygdala in depression: Relationship to diagnostic subtype and plasma cortisol levels. Pharmacol. Biochem. Behav., 71 (3), 431–447. Kr€ uger, S., Seminowicz, D., Goldapple, K. et al. (2003) State and trait influences on mood regulation in bipolar disorder: Blood flow differences with an acute mood challenge. Biol. Psychiatry, 54 (11), 1274–1283. Dunn, R.T., Willis, M.W., Benson, B.E. et al. (2005) Preliminary findings of uncoupling of flow and metabolism in unipolar compared with bipolar affective illness and normal controls. Psychiatry Res., 140 (2), 181–198. Austin, M.P., Dougall, N., Ross, M. et al. (1992) Single photon emission tomography with 99mtc-exametazime in major depression and the pattern of brain activity underlying the psychotic/neurotic continuum. J. Affect. Disord., 26 (1), 31–43. Bench, C.J., Friston, K.J., Brown, R.G. et al. (1993) Regional cerebral blood flow in depression measured by positron emission tomography: The relationship with clinical dimensions. Psychol. Med., 23 (3), 579–590. Bonne, O., Krausz, Y., Gorfine, M. et al. (1996) Cerebral hypoperfusion in medication resistant, depressed patients assessed by tc99m HMPAO SPECT. J. Affect. Disord., 41 (3), 163–171. Iidaka, T., Nakajima, T., Suzuki, Y. et al. (1997) Quantitative regional cerebral flow measured by tc-99m HMPAO SPECT in mood disorder. Psychiatry Res., 68 (2–3), 143–154. Kanaya, T. and Yonekawa, M. (1990) Regional cerebral blood flow in depression. Jpn. J. Psychiatry. Neurol., 44 (3), 571–576.
Functional Brain Imaging Studies in Bipolar Disorder 39. Kimbrell, T.A., Ketter, T.A., George, M.S. et al. (2002) Regional cerebral glucose utilization in patients with a range of severities of unipolar depression. Biol. Psychiatry, 51 (3), 237–252. 40. OConnell, R.A., Van Heertum, R.L., Billick, S.B. et al. (1989) Single photon emission computed tomography (SPECT) with [123I]IMP in the differential diagnosis of psychiatric disorders. J. Neuropsych. Clin. N., 1 (2), 145–153. 41. OConnell, R.A., Van Heertum, R.L., Luck, D. et al. (1995) Single-Photon emission computed tomography of the brain in acute mania and schizophrenia. J. Neuroimaging, 5 (2), 101–104. 42. Schlegel, S., Aldenhoff, J.B., Eissner, D. et al. (1989) Regional cerebral blood flow in depression: Associations with psychopathology. J. Affect. Disord., 17 (3), 211–218. 43. Yazici, K.M., Kapucu, O., Erbas, B. et al. (1992) Assessment of changes in regional cerebral blood flow in patients with major depression using the 99mtc-hmpao single photon emission tomography method. Eur. J. Nucl. Med., 19 (12), 1038–1043. 44. Maes, M., Dierckx, R., Meltzer, H.Y. et al. (1993) Regional cerebral blood flow in unipolar depression measured with tc99m-hmpao single photon emission computed tomography: Negative findings. Psychiatry Res., 50 (2), 77–88. 45. Mayberg, H.S., Lewis, P.J., Regenold, W. and Wagner, H.N. (1994) Paralimbic hypoperfusion in unipolar depression. J. Nuc. Med., 35 (6), 929–934. 46. Philpot, M.P., Banerjee, S., Needham-Bennett, H. et al. (1993) 99Mtc-Hmpao single photon emission tomography in late life depression: A pilot study of regional cerebral blood flow at rest and during a verbal fluency task. J. Affect. Disord., 28 (4), 233–240. 47. Thomas, P., Vaiva, G., Samaille, E. et al. (1993) Cerebral blood flow in major depression and dysthymia. J. Affect. Disord., 29 (4), 235–242. 48. Vasile, R.G., Schwartz, R.B., Garada, B. et al. (1996) Focal cerebral perfusion defects demonstrated by 99mtc-hexamethylpropyleneamine oxime SPECT in elderly depressed patients. Psychiatry Res., 67 (1), 59–70. 49. al-Mousawi, A.H., Evans, N., Ebmeier, K.P. et al. (1996) Limbic dysfunction in schizophrenia and mania. A study using 18f-labelled fluorodeoxyglucose and positron emission tomography. Brit. J. Psychiat., 169 (4), 509–516. 50. Brooks, J. O. III, Hoblyn, J. C., and Ketter, T. A. (2010) Cerebral metabolic evidence of corticolimbic dysregulation in bipolar mania. Psychiatry Research: Neuroimaging, 181, 136–140.
|
209
51. Silfverski€ old, P. and Risberg, J. (1989) Regional cerebral blood flow in depression and mania. Arch. Gen. Psychiatry, 46 (3), 253–259. 52. Rubin, E., Sackeim, H.A., Prohovnik, I. et al. (1995) Regional cerebral blood flow in mood disorders: IV. Comparison of mania and depression. Psychiatry Res., 61 (1), 1–10. 53. Benabarre, A., Vieta, E., Martınez-Ar an, A. et al. (2005) Neuropsychological disturbances and cerebral blood flow in bipolar disorder. Aust. Nz. J. Psychiat., 39 (4), 227–234. 54. Goodwin, G.M., Cavanagh, J.T., Glabus, M.F. et al. (1997) Uptake of 99mtc-exametazime shown by single photon emission computed tomography before and after lithium withdrawal in bipolar patients: Associations with mania. Brit. J. Psych., 170, 426–430. 55. Migliorelli, R., Starkstein, S.E., Teso´n, A. et al. (1993) SPECT findings in patients with primary mania. J. Neuropsych. Clin. N., 5 (4), 379–383. 56. Blumberg, H.P., Stern, E., Ricketts, S. et al. (1999) Rostral and orbital prefrontal cortex dysfunction in the manic state of bipolar disorder. Am. J. Psychiatry, 156 (12), 1986–1988. 57. Blumberg, H.P., Stern, E., Martinez, D. et al. (2000) Increased anterior cingulate and caudate activity in bipolar mania. Biol. Psychiatry, 48 (11), 1045–1052. 58. Rubinsztein, J.S., Fletcher, P.C., Rogers, R.D. et al. (2001) Decision-Making in mania: A PET study. Brain, 124 (Pt 12), 2550–2563. 59. Culha, A.F., Osman, O., Dogang€ un, Y. et al. (2008) Changes in regional cerebral blood flow demonstrated by 99mtc-hmpao SPECT in euthymic bipolar patients. Eur. Arch. Psy. Clin. N., 258 (3), 144–151. 60. Dye, S.M., Spence, S.A., Bench, C.J. et al. (1999) No evidence for left superior temporal dysfunction in asymptomatic schizophrenia and bipolar disorder. PET study of verbal fluency. Brit. J. Psych., 175, 367–374. 61. Berns, G.S., Martin, M. and Proper, S.M. (2002) Limbic hyperreactivity in bipolar II disorder. Am. J. Psychiatry, 159 (2), 304–306. 62. Deckersbach, T., Dougherty, D.D., Savage, C. et al. (2006) Impaired recruitment of the dorsolateral prefrontal cortex and hippocampus during encoding in bipolar disorder. Biol. Psychiatry, 59 (2), 138–146. 63. Brooks, J. O. III, Hoblyn, J. C., Woodard, S. A., et al. (2009). Resting prefrontal hypometabolism and paralimbic hypermetabolism related to verbal recall deficits in euthymic older adults with bipolar disorder. American Journal of Geriatric Psychiatry, 17, 1022–1029.
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Neurotransmitter Systems in Bipolar Disorder Marina Nakic1, John H. Krystal1 and Zubin Bhagwagar1,2 1 2
Department of Psychiatry, Yale University School of Medicine, New Haven, CT, USA Bristol Myers Squibb, USA
Bipolar disorder is a severe, chronic debilitating disorder which exerts a crippling burden on individuals and their families. According to the National Comorbidity Survey replication, the lifetime prevalence for bipolar I and II disorders is 1.0% and 1.1%, respectively [1]. The World Health Organization Global Burden of Disease study ranked bipolar disorder sixth amongst all medical disorders in years of life lost to death and disability [2]. The lifetime risk of suicide in patients with diagnosis of bipolar disorder ranges from 8% to 20% [3]. Despite these worrisome statistics, pathophysiology of bipolar disorder remains largely unknown. However there is an abundance of data implicating abnormalities of monoaminergic (dopaminergic, noradrenergic, serotonergic), cholinergic, glutamatergic, GABA-ergic, glucocorticoid and peptidergic systems in pathophysiology of bipolar disorder [4]. These findings have contributed to elucidating some aspects of the pathophysiology of the bipolar disorder and influenced development of pharmacological strategies over the past several decades. The major findings implicating the involvement of the above listed neurotransmitter systems in bipolar disorders will be reviewed in this chapter.
The role of monoamines and acetylcholine in the pathophysiology of bipolar disorder Monoaminergic hypotheses The formulation of catecholamine hypothesis of mood disorders dates back to the 1960s. The hypothesis, independently developed by Bunney and Davis [5] and Schildkraut [6], postulates that a deficiency of monoamine neurotransmitters norepinephrine, dopamine and serotonin in the brain constitutes a biological basis of depression. Mania was conceptualized as a state of excess of catecholmines [6,7]. Initial evidence for the role of monoamines in affect regulation came from the observation that the antihypertensive Bipolar Disorder: Clinical and Neurobiological Foundations Edited by Lakshmi N. Yatham and Mario Maj © 2010 John Wiley & Sons, Ltd. ISBN: 978-0-470-72198-8
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agent reserpine induced depression in a subset of hypertensive patients [8,9]. Subsequent studies demonstrated that reserpine interfered with vesicular storage of serotonin and norepinephrine, thereby depleting presynaptic pool of monoamines available for release from the synapses [9,10]. Further evidence came from yet another serendipitous clinical observation that iproniazid, an antimycobacterial agent, improved mood in tubercular patients with depression [11–13]. The effect was later attributed to the ability of iproniazid to inhibit monoamine oxidase (MAO), the mitochondrial enzyme that degrades monoamines in the presynaptic nerve terminal, thus preventing degradation of serotonin, norepinephrine and dopamine. Imipramine, initially developed for the treatment of agitation in psychotic patients, was also found to have antidepressant properties [14]. Subsequently, it was discovered that it acts by inhibiting reuptake of norepinephrine and serotonin, both centrally and peripherally [15]. Evidence for the role of monoamines in pathophysiology of mania has been derived from observation of behavioural effects of drugs such as L-dopa, bromocriptine and d-amphetamine, all of which precipitated mania by enhancing central catecholaminergic transmission [16–19]. In the late 1960s, Coppen [20], Lapin and Oxenkrug [21] formulated the indoleamine hypothesis of depression attributing vulnerability to major depression to low serotonergic activity. In 1974, Prange and colleagues extended this hypothesis from major depression to bipolar disorder, by proposing a permissive hypothesis of serotonin function that suggested that reduced serotonin level sets the stage for a mood disorder, depression or mania, depending on the underlying catecholamine level. According to this hypothesis, depression ensues in the context of low serotonin and low catecholamine level, whereas mania is the result of low serotonin and abnormally high catecholamine level [22].
Monoamine metabolism and neuroanatomy Catecholamines Monoaminergic systems are extensively distributed throughout the network of brain stem, limbic, striatal and
Neurotransmitter Systems
prefrontal cortical neuronal circuits thought to support the behavioural and visceral manifestations of mood disorders [23]. The catecholamines, dopamine and norepinephrine, are synthesized from amino acids phenylalanine and tyrosine. The first and rate-limiting step in synthesis of catecholamines is the conversion of tyrosine to 3,4-dihydroxyphenylalanine (L-DOPA) by the enzyme tyrosine hydroxylase [24]. This step can be inhibited reversibly by the administration of alpha-methyl-p-tyrosine (AMPT), which therefore inhibits the production of both, norepinephrine and dopamine. The second enzyme, DOPA decarboxylase, converts L-DOPA into dopamine. In noradrenergic neurons, the third enzyme, dopamine beta-hydroxylase converts dopamine into norepinephrine. Norepinephrine is stored in synaptic vesicles until release is triggered by a nerve impulse. Dopaminergic neurons lack the enzyme dopamine beta-hydroxylase, resulting in an inability to convert dopamine to norepinephrine. Although norepinephrine is synthesized from dopamine their tissue distribution differs markedly [25,26]. The action of catecholamines is terminated by two principal enzymes, MAO, located in the mitochondria of the presynaptic neurons, and catechol-O-methyl transferase (COMT), located mainly outside of the presynaptic nerve terminal [25]. Action of these enzymes results in production of catecholamine metabolites, of which 3-methoxy-4hydroxypheylglycol (MHPG) is the major norepinephrine metabolite, and homovanillic acid (HVA) is the major dopamine metabolite. In addition to enzymatic activity, norepinephrine is removed from the extracellular space by a presynaptically located norepinephrine transporter [26]. Dopaminergic neurons similarly possess a dopamine reuptake pump, which works analogously to the norepinephrine transporter [27]. Norepinephrine exerts its effects via alpha- and beta-adrenergic receptors, located postsynaptically, and alpha-2 autoreceptors, located presynaptically, that mediate negative feedback regulatory signalling [28]. Dopamine exerts action via a plethora of receptors and autoreceptors [29–31]. The main source of norepinephrine in the brain is locus coeruleus, located in the rostral pons. Noradrenergic neurons from locus coeruleus give rise to diffuse axonal projections and innervate virtually all areas of the brain and spinal cord. The mammalian brain also contains smaller collections of additional noradrenergic and adrenergic neurons that are located in discrete regions of pons and medulla [32,33]. Locus coeruleus output is involved in flightor-fight responses and regulate level of arousal, the responses of the sympathetic nervous system including pulse rate and blood pressure, and signalling of danger to organism. Locus coeruleus receives input from numerous neurotransmitter and peptidergic systems, including serotonergic, GABAergic, glutamatergic, cholinergic and
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opioid [34]. The main source of dopamine in the brain is ventral mesencephalon, from where dopaminergic projections distribute widely throughout the central nervous system [27].
Indoleamines Serotonin (5-HT) is synthesized from tryptophan in a series of reactions involving hydroxylation of L-tryptophan to 5-hydroxytriptophan (5-HTP) via the enzyme tryptophan hydroxylase, a rate-limiting step, and decarboxylation of 5-HTP into 5-hydroxytriptamine or serotonin (5-HT) via aromatic amino acid decarboxylase [35]. Upon release, serotonin interacts with a complex system of receptors. Based on pharmacological and molecular properties at least 14 types of 5-HT receptors have been identified in mammalian brain [36,37]. The serotonin transporter in brain is responsible for the active re-uptake of serotonin back into neurons, and is situated both in perisynaptic membranes of nerve terminals and in dendritic arbors in close proximity to serotonin-containing cell bodies in the midbrain and brain stem raphe nuclei [38]. Once inside the serotonergic neuron, serotonin is metabolized by the MAO into inactive metabolite, 5-hydroxyindoleacetic acid (5-HIAA). The main location of the cell bodies of 5-HT neurons is a beaded structure called the raphe nucleus; the two main midbrain raphe nuclei, the dorsal raphe and the median raphe, project virtually to all forebrain regions, including thalamus, hypothalamus, caudate-putamen, hippocampus and neocortex [39]. Melatonin is synthesized from the tryptophan by enzyme 5-hydroxyindole-O-methyltransferase [40]. Production of melatonin by the pineal gland is under the influence of the hypothalamus, and is regulated by environmental light/ dark cycles via the suprachiasmatic nucleus. The cyclic nature of bipolar illness, as well as disturbances in sleepwake cycle all suggest that dysfunction in melatonin metabolism might be involved in pathophysiology of bipolar disorder [41]. In addition to its timekeeping functions, melatonin is an effective antioxidant and regulator of several antioxidant enzymes [40]. Melatonins cytoprotective properties may have practical implications in the treatment of neuropsychiatric disorders.
Adrenergic-cholinergic balance in mood disorders Perturbations in cholinergic transmission have long been implicated in pathophysiology of mood disorders. Since the discovery by Willoughby in 1898 that pilocarpine, a muscarinic cholinergic agonist, alleviates mania, numerous studies have demonstrated the mood-altering effects of acetlycholine modulating agents [42]. In the early 1970s, based on the above studies and animal data [43], Janowsky and colleagues developed an adrenergic-cholinergic balance
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hypothesis of bipolar disorder. This hypothesis proposed that depression represents an overabundance of central acetylcholine, relative to central adrenergic neurochemicals, and mania represents the converse [44]. In a seminal experiment, Janowsky and colleagues [44] investigated the effects of administration of a centrally acting cholinesterase inhibitor, physostigmine, or the peripherally acting cholinesteraze inhibitor, neostigmine, to manic, depressive and schizophrenic patients, as well as healthy volunteers. The study showed that administration of physostigmine but not neostigmine resulted in decreased symptoms of mania and an increase in depressive symptoms [44]. Further support for the involvement of the cholinergic system in bipolar disorder was provided in the early 1980s by Sitaram and colleagues, after demonstrating that administration of cholinergic agonist arecoline resulted in faster induction of REM sleep, suggestive of cholinergic supersensitivity in 14 bipolar patients [45]. The effect was seen whether the patients were symptomatic or in full remission.
Cholinergic metabolism and neuroanatomy Acetylcholine is synthesized from acetyl coenzyme A and choline in a reaction catalysed by the enzyme acetyltransferase [46]. Upon release, the action of acetylcholine on post synaptic receptors is terminated by the enzymes acetylcholinesterase and butyrylcholinesterase, which turn acetylcholine into inactive products [47–49]. Acetylcholine exerts its action via numerous receptors of which the main subtypes are muscarinic and nicotinic. Nicotinic receptors are ligand-gated, rapid-onset, and excitatory ion channels [50] while muscarinic receptors are G-protein-linked, and can be excitatory or inhibitory [51].
Peripheral measures The monoamine hypotheses of mood disorders postulated that depression is caused by deficient monoamine production, whereas manic states result from an increase in monoamine production [5,6]. Much of the earlier studies on the pathophysiology of mood disorders, therefore, focused on measuring levels of monoamines and their metabolites in bodily fluids. Such measurements provided evidence of dysfunction in catecholaminergic and serotonergic systems as predicted. However as can be seen below while a dysfunction of these systems was reported there was inconsistency in the specific direction of dysfunction. Therefore early studies found that in patients diagnosed with bipolar disorder, plasma and urinary norepinephrine and its metabolite MHPG levels were decreased during the depressed phase compared to euthymic state, and elevated during the manic phase [52]. However, subsequent studies failed to replicate these findings [53,54], or found that
norepinephrine concentration was lower in bipolar patients than in either unipolar depressive or disease-free controls [55]. Swann and colleagues conducted an extensive set of studies of monoamine function in bipolar patients. In one of the studies, researchers compared CSF concentrations of MHPG, HVA and 5-HIAA between the manic patients and healthy comparison individuals. The manic patients had significantly higher levels of MHPG. Levels of HVA and 5-HIAA were elevated only in female manic patients [56]. The comparison of biogenic amine levels, between mixed manic and agitated depressed patients, revealed higher MHPG in CSF, as well as higher urinary norepinephrine excretion, in a mixed manic group [57]. Later studies by the same group investigated the relationship between the catecholamine functioning, as reflected in CSF and urinary concentration of catecholamine metabolites, and psychomotor performance. The study showed performance impairment in unipolar and bipolar depressed patients, but no differences in the performance between manic patients and controls [58]. Increase in the total excretion of catecholamines and their metabolites were associated with better test performance in healthy controls and males with unipolar depression. In bipolar depressed patients, however, increase in CSF MHPG was associated with worsening of performance [58]. CSF levels of the major dopamine metabolite, HVA, have been found to be decreased in bipolar depression [54]. HVA levels in mania were reported to be higher [59,60], or not different from the control groups [56,61–63]. Studies of the CSF 5-HIAA in bipolar patients have generally produced inconsistent results [64,65]. CSF 5HIAA levels in manic patients compared with controls have been reported to be decreased [66,67], or unchanged [60,68]. Another study compared mixed bipolar patients with pure manic and unipolar depressive patients [69]. Whereas both serotonin and 5-HIAA levels were higher in the patients with pure mania than in those with depression, the mixed group could be biochemically divided into two subgroups, those resembling pure manic and pure depressive groups [69]. This has to be considered against the background of emerging literature showing that there was an association between low CSF 5-HIAA level and suicidal behaviour [61]. In general, use of the studies measuring levels of monoamines in bodily fluids has provided us with evidence of a dysfunction in these systems which have been considered key to the pathophysiology of the illness. However the discrepancy in the results could well be due to methodological limitations in determining the relative contribution of the peripheral versus central plasma and urinary metabolites, the effects of medication and insufficient information regarding the phase of the illness. Both CSF and plasma sample collection in general, pose a variety of procedural and interpretational challenges, including the effect of the
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acute stress of the procedure, and sampling at a single time point [70].
Monoamine challenge studies The monoaminergic hypothesis of mood disorders has been tested extensively using monoamine depletion techniques [71]. Transient and reversible reduction of the central levels of a particular neurotransmitter allows for the investigation of the effects of such a manipulation on mood symptoms. Synthesis of serotonin is entirely dependent on the availability of its precursor amino acid tryptophan. Therefore, manipulation of tryptophan level in the central nervous system will affect serotonin transmission. Since the only source of tryptophan for humans is diet, elimination of tryptophan is achieved by administration of tryptophanfree amino acid drink [72,73]. The manipulation of central norepinephrine has been approached in a different manner. The synthesis of catecholamines critically depends on the action of tyrosine hydroxylase. This step can be reversibly inhibited by the administration of AMPT, which therefore inhibits the production of norepinephrine and dopamine. Monoamine depletion studies have yielded mixed results in bipolar patients. Acute typtophan depletion in remitted bipolar patients revealed either no effect [74–76], or transient worsening of manic symptoms [77]. Catecholamine depletion resulted in attenuation of symptoms of acute mania in patients treated with antipsychotics [78]. The same procedure in remitted bipolar patients treated with lithium resulted in no immediate effect, but was followed by a transient relapse of hypomanic symptoms after a 24–48 hrs delay [79].
Post-mortem brain tissue studies of monoaminergic function Examination of postmortem human brain tissue has been a mainstay of research strategies in the investigation of the pathophysiology of mood disorders for over a century. Earlier studies focused on comparing number of neurons and glial cells [80,81], cortical thickness [82,83] or cell architecture [84], between patients with mood disorders and healthy controls. Subsequent sophistication in methodology allowed comparison at the cellular and subcellular level. Newer techniques employing high throughput mRNA technologies including microarray platforms (cDNA arrays and oligonucleotide-based arrays) allow evaluation of changes in expression at the level of the entire genome [85,86].
Catecholamines An extensive study [87] demonstrated no difference in the levels of norepinephrine, dopamine and serotonin in the
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hippocampus, caudate nucleus, putamen, mediodorsal thalamus, frontal, parietal, occipital or temporal cortices between the brain samples from patients with antemortem diagnosis of bipolar disorder and those from disease nonafflicted, matched controls [87]. However, the same study reported significantly increased norepinephrine turnover (MHPG/norepinephrine ratio) in the thalamus, as well as frontal, temporal and occipital cortices of bipolar patients. This could be viewed as reflecting either an excess of production or accelerated metabolism of norepinephrine. Significant reductions were detected in major serotonin metabolite 5-HIAA and serotonin/5-HIAA ratio in frontal and parietal cortex, as well as in HVA, the major dopamine metabolite, in the parietal and occipital cortex of bipolar patients [87]. Using immunocytochemistry with computerassisted quantification of immunoreactivity for tyrosine hydroxylase and tryptophan hydroxylase, Wiste and colleagues [88] recently demonstrated less tyrosine hydroxylase and tryptophan hydroxylase immunoreactivity in locus coeruleus of bipolar suicides, compared to major depression suicides and matched controls, suggesting potentially lower noradrenergic and serotonergic levels in bipolar suicides. The results of both studies were interpreted as consistent with serotonin permissive hypothesis of bipolar disorder [22,87,88]. Receptor autoradiography studies, investigating density and functional integrity of beta-adrenergic receptors in frontal, occipital or temporal cortex [87], or 5HT2A and 5HT1A receptors in frontal cortex [89,90] or hippocampus [91], revealed no differences between brain tissue samples from bipolar patients relative to control samples. On the other hand, Pantazopoulos and colleagues [92] used in situ hybridization to measure expression differences in dopamine D1 receptor mRNA in hippocampus of bipolar and schizophrenic patients. Bipolar patients demonstrated significant and sector specific decrease in D1 mRNA expression in CA2 sector of hippocampus [92].
Serotonin A decrease in the affinity of [3H]citalopram binding to the serotonin transporter has been reported in the hippocampus, but not frontal cortex of the patients with bipolar disorder [91]. The same study reported no differences in the density of serotonin transporter, or 5HT2A, 5HT1A, 5HT1D and 5HT1F receptors between the bipolar and control hippocampal samples [91]. On the other hand, Sun and colleagues, using serial analysis of gene expression method, demonstrated increased serotonin transporter mRNA level in frontal cortex of bipolar patients relative to matched controls [93]. New evidence suggests abnormalities in the interaction between the neurotransmitter receptor and G-proteins in bipolar disorder [94]. Supportive of this hypothesis is the previous demonstration of decrease in
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serotonin, isoproterenol and carbachol stimulated guanosine 50 -O-(3-[35S] thiophosphate) binding in cortical tissue from subjects with bipolar disorder [95].
Acetylcholine Severance and Yolken [96] compared nicotinic acetylcholine receptor subunit mRNA expression in prefrontal cortex of patients with antemortem diagnosis of bipolar disorder or schizophrenia, and unaffected controls, and found modest up-regulation of alpha-4 message in bipolar patients with history of psychosis relative to controls. In summary, studies investigating the levels of monoamine transmitters, or quantity and functional integrity of monoamine receptors and transporters in postmortem brain tissue of patients with bipolar disorder have not suggested a consistent direction of change of functioning. The inconsistencies might be related to the regional differences, generally small sample sizes, lack of information on the phase of illness, effects of antemortem medication regimen, freezer storage time, brain ph and postmortem interval [97,98].
Neuroimaging studies Advance in neuroimaging have brought unprecedented possibilities for in vivo studies of the human brain [99,100]. In particular, positron emission tomography (PET), single photon emission computerized tomography (SPECT) and magnetic resonance spectroscopy (MRS) enable measurement of local cerebral glucose metabolism, blood flow, receptor and transporter number and functional integrity, as well as concentrations of biochemical metabolites in a given volume of brain tissue, elucidating the contribution of neurotransmitter systems dysfunction to mood disorders.
Catecholamines In a study conducted in patients with acute mania, Pearlson and colleagues [101] used the radiotracer N-[11 C]methylspiperone to compare D2 receptor density between neuroleptic-free psychotic bipolar patients, schizophrenic patients and normal controls. Increase in D2 binding potential was demonstrated in the striatum of bipolar and schizophenic patients compared to controls, leading authors to conclude that potentially higher number of D2 receptors is marker for psychosis rather than for the specific disorder. Using D2/D3 receptor tracer iodobenzamide before and after amphetamine challenge, Anand and colleagues [102] detected no differences in D2 striatal baseline levels between euthymic bipolar patients and matched controls, nor there were differences between the two groups in the amphetamineinduced decrease in striatal iodobenzamide binding. Since a decrease in iodobenzamide binding has been shown to be related to the amount of striatal dopamine release, the
findings were interpreted as consistent with enhanced postsynaptic dopamine responsivity in bipolar disorder [102]. In another study, conducted in acutely manic patients, Yatham and colleagues [103] examined presynaptic dopaminergic function in neuroleptic- and mood-stabilizer na€ıve nonpsychotic manic patients before and after treatment with divalproex sodium by measuring [18 F]6-fluoro-L-dopa uptake in the striatum. The study revealed no significant differences in baseline [18 F]6-fluoro-L-dopa uptake between the manic patients and healthy controls. Treatment with divalproex sodium resulted in reduced [18 F]6-fluoroL-dopa uptake in patient group, possibly through decrease in aromatic L-amino acid decarboxylase [103]. D1 dopamine receptor binding was studied using the PET radioligand [11C]-SCH23390 in frontal cortex and striatum of patients with bipolar disorder in various phases of disease (euthymic, depressed and one manic) and normal controls. The binding potential was significantly lower in the frontal cortex in the patient group compared to the control group. No significant differences were detected in striatum [104].
Serotonin Studies have examined the quantitative and qualitative properties of serotonin receptors in bipolar disorder. PET imaging, using the 5HT1A receptor ligand [11 C]WAY100635, demonstrated reduction in 5HT1A binding potential in the raphe nucleus, mesiotemporal cortex, occipital cortex and postcentral gyri in a mixed group of recurrent depressed and bipolar patients [105]. More recent development of high affinity and selectivity radioligands for serotonin transporter enabled further assessment of its function in bipolar disorder [106]. One study, employing PET radioligand [11 C]( þ )McN5652, found an increase in thalamic serotonin transporter binding, and no difference in midbrain binding in a small group consisting of non-medicated, depressed or euthymic bipolar patients relative to controls [11 C]DASB [107]. However, another PET-[11 C]( þ )McN5652 study found a reduction in serotonin transporter binding in the midbrain, thalamus, putamen, amygdala, hippocampus and anterior cingulate cortex in bipolar depressed patients [106]. Cannon and colleagues [108] used a newly developed PET radioliand [11C]-3-amino-4-(2-dimethylaminomethylphenylsulfanyl)-benzonitrile ([11 C]DASB) that binds to the serotonin transporter with high affinity and selectivity, to compare serotonin transporter binding between bipolar depressed patients and healthy controls. Serotonin transporter binding was significantly increased in the insula, medial prefrontal cortex, dorsal cingulate cortex, caudate and thalamus, areas known to receive extensive innervations by serotonergic neurons. Decreased serotonin transporter binding was detected in the brainstem at the level of pontine raphe nucleus in bipolar subjects compared to controls. This data is compatible both with Ichymia study
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as well as with the report of Sun and colleagues reporting increase in serotonin transporter RNA transcript in postmortem samples of frontal cortex of individuals with bipolar disorder [93,107].
Acetylcholine Spectroscopic imaging suggests abnormalities in metabolism of choline-containing compounds in symptomatically ill bipolar patients, although the true direction of the change is unclear. Choline is a precursor and metabolite of membrane phospholipids, second-messenger compounds, and the neurotransmitter acetylcholine. The choline resonance, visible by 1 H MRS represents combined signals from several choline-containing compounds, including phosphocholine and glycerophosphocholine. Several studies so far demonstrated increase in choline concentration in the basal ganglia [109–111] and anterior cingulate cortex [112] of bipolar patients. However, other studies have demonstrated reduction of choline and NAA concentrations in orbital frontal grey matter [113], or hippocampus [114], or no difference in choline concentration in anterior cingulate [115,116], or dorsolateral prefrontal cortex [117,118] between bipolar patients and matched controls
Genetic studies Twin and other family studies indicate that genetic factors contribute substantially to the liability for developing bipolar disorder [119,120]. However, the causative genes or genetic risk factors have not been well established [121]. Recent meta-analysis of functional polymorphisms suggests that three genes coding for products involved in monoaminergic neurotransmission may be significantly associated with bipolar disorder: monoamine oxidase A [122], COMT [123] and 5-HTTLPR [119]. The most consistent finding is an association between the excess of allele 5 or 6 of the MAOA-CA repeat and bipolar disorder in female bipolar patients [122,124].
Amino acids and the pathophysiology of bipolar disorder Amino acidergic hypotheses The amino acids glutamate (Glu), gamma-aminobutyric acid (GABA) and glycine (Gly) serve as neurotransmitters at most of the mammalian central nervous system synapses [125,126]. Abnormal functioning of the glutamatergic system has been implicated in pathophysiology of numerous neuropsychiatric disorders, amongst others amiotrophic laterals sclerosis [127], Huntingtons chorea [128], Alzheimers disease [129], schizophrenia [130], epilepsy, cocaine addiction and alcohol abuse [131]. Over the past
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several years, increasing evidence suggests that dysregulation of glutamate neurotransmission contributes to the pathology of mood disorders as well [125,132,133]. The hypothesis of GABAergic dysfunction in mood disorders was initially formulated by Emrich and colleagues in 1980, following observation of the efficacy of an anticonvulsant and GABA agonist, valproate, in treatment of mania [134]. Since then, considerable preclinical and clinical data have been accumulated suggesting that GABA plays a role in affective disorders [135–137]. Through its action as the major inhibitory neurotransmitter in the brain, GABA modulates as array of behavioural and physiological mechanisms related to mood pathology, including sleep, feeding behaviour, aggression, sexual behaviour, pain responsiveness, cardiovascular regulation, thermoregulation and locomotor activity [138].
Glutamate metabolism and neuroanatomy Glutamate is the most abundant excitatory neurotransmitter in the brain, with estimated presence at 60% of the synapses [125,126]. Glutamate in the brain originates from two sources: (1) synthesized de novo from glucose via the Krebs cycle and transamination of alpha-ketoglutarate; and (2) from glutamine that is synthesized in glial cells from glutamate via action of glutamine synthetase, transported into nerve terminals, and locally converted into glutamate by glutaminase. Glutamate is released from the nerve terminal by a calcium-dependent exocytosis following cell depolarization [26]. Glutamate is essential to neurotransmission, but cytotoxic when present in excess. Rapid removal from the synaptic cleft is crucial to ensure maintenance of extracellular levels of glutamate below those that cause excitatory damage [139–141]. Clearance is accomplished through action of five, so far identified, high-affinity, sodium-dependent excitatory amino acid transporters (EAAT 1-5) located on the presynaptic terminals and neighbouring glial cells [142]. Mechanisms involved in excitotoxic action of glutamate involve damage to mitochondria from excessively high intracellular calcium level, and activation of calcium dependent kinases and proteases, with subsequent cytoskeletal damage, protein misfolding and overproduction of oxygen radicals eventually resulting in cell death [143]. Excitotoxicity from excessive glutamate stimulation has been implicated in variety of neuropsychiatric disorders [127–129], and accumulating evidence implicates excitotoxic damage in mood disorders as well and in schizophrenia [144,145]. Glutamate exerts its action through activation of ionotropic and metabotropic receptors. Ionotropic receptor subtypes bear the names of their selective agonists: Nmethyl-D-aspartate (NMDA), amino-3-hydroxy-5-methylisoxazole-4-propionic acid (AMPA) and kainate [146–148].
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Metabotropic glutamate receptors, located on neurons, pre-, post- and extra-synaptically, as well as on glia, and are classified as group I, II and III based on their interactions with regulatory G-proteins [146]. AMPA and kainate receptors mediate fast excitatory synaptic transmission and are associated primarily with voltage-independent channels that gate a depolarizing current through influx of sodium ions. AMPA receptors are heteromeric assemblies of GluR1-4 subunits [149]. Kainate receptors are composed of tetrameric combinations of three subunits, GluR5-7, KA1 and KA2 [148]. The NMDA receptor complex is endowed with a number of distinct recognition sites for endogenous and exogenous ligands, including magnesium, glycine and zinc binding sites, in addition to the transmitter binding site, and a polyamine-regulatory site. In contradistinction to other ionotropic glutamate receptors, activation of NMDA depends on simultaneous presence of glutamate and depolarization of the postsynaptic membrane. This characteristic contributes to unique property of NMDA receptors to code simultaneously occurring events, characteristic central to many forms of synaptic plasticity, including learning and memory [150]. NMDA receptors are heteromeric assemblies of an obligatory NR1 subunit with a NR2A-D and NR3A-B subunits, assembled in the endoplasmic reticulum to form functional channels with differing physiological and pharmacological properties and distinct patterns of expression and regional distribution [131]. NMDA receptors are anchored in the postsynaptic density and linked to a large complex of intracellular proteins, including PSD95, PSD93, NF-L and SAP102 [151–153].
GABA metabolism and neuroanatomy GABA is the most abundant inhibitory neurotransmitter in the mammalian brain. It is estimated that approximately 40% of neurons use GABA as a neurotransmitter [154]. In addition to acting as an inhibitory neurotransmitter, GABA participates as an intermediate in energy metabolism [155]. Most GABA neurons are local circuit interneurons, but GABA is also found on certain long projection neurons [156]. GABAergic interneurons are abundant in mood-related structures of the forebrain, including anterior cingulate cortex, hippocampus and amygdala [157]. The GABAergic system extensively interacts with the dopaminergic [158,159], glutamatergic [160] and serotonin systems [161], as well as hypothalamo-pituitary-adrenal axis [162]. GABA in GABAergic terminals is formed from glutamate in an enzymatic reaction mediated by the glutamic acid decarboxylase (GAD), using pyridoxal phosphate as a cofactor. GAD is present in at least two molecularly distinct isoforms, termed GAD65 and GAD67 [163]. GAD65 is primarily localized to axon terminals, whereas GAD67 is more abundant in neuronal cell body [164]. Upon release,
GABA is rapidly removed from synaptic cleft by a highaffinity sodium-dependent reuptake process. Four subtypes of GABA transporters (GATs) named GAT-1, GAT-2, GAT-3 and BGT-1, have been cloned. The transporters are present on both, neurons and glial cells [165]. GATs are regulated by several factors including GABA itself, brainderived neurotrophic factr (BDNF), and hormones [166]. GABA aminotransaminase is a mitochondrial enzyme primarily responsible for the degradation of GABA. Inhibitors of GABA aminotransaminase rapidly raise GABA levels in human brain [167], and possess anticonvulsant and anxiolytic properties [168]. The synaptic effects of GABA in the central nervous system are mediated through two major receptor subtypes termed GABA-A and GABA-B. GABA-A subtype is an ionotropic receptor that allows increased chlorine conductance following the binding of GABA, and is predominantly involved in fast inhibitory synaptic transmission. GABA-B receptor is a G-protein coupled receptor [137].
Peripheral measures of GABA and glutamate Changes in glutamate levels have been reported in plasma [169] and cerebrospinal fluid [170,171] of individuals afflicted with bipolar disorder, with inconsistent findings. While Frye and colleagues reported decrease in glutamate and glycine [170], Levine and colleagues reported increased glutamate in CSF in bipolar and unipolar depressed patients compared to controls [171]. Altamura and colleagues [172] reported higher glutamate plasma levels in patients with mood disorder, including bipolar disorder, compared to neurological patients with tension headache, healthy volunteers or patients with schizophrenia, anxiety or organic mental disorder. On the other hand, a study led by Palomino reported decreased levels of plasma glutamate during first psychotic episode that was part of either bipolar disorder or schizophrenia [169]. Plasma measures conducted during manic phase, demonstrated significant increase of both glutamate and glycine that persisted in remission [173]. Studies assessing CSF GABA levels reported either lower levels [174] or no differences in comparisons between bipolar patients and matched controls [59,175,176]. Studies assessing plasma GABA levels demonstrate decrease in patients with bipolar disorder irrespective of the phase of disease, in accord with Emrich hypothesis [175,177,178].
Postmortem studies A number of postmortem brain tissue studies investigated glutamate [179,180] or GABA levels, receptor density and binding properties, as well as receptor subunit and PSD components expression patterns in patients with bipolar disorder [181,182]. Although most of the studies reported
Neurotransmitter Systems
differences in those parameters, no consistency in findings emerged so far.
Glutamate Postmortem autoradiography studies use radiolabelled receptor agonists and antagonists to assess receptor density and functionality. Radioligands that interact with binding sites on NMDA receptor complex include [3 H]MK-801 that binds to an intra-channel site; [3 H]ifenprodil, that binds to a polyamine site; [3 H]CPG39653, that binds to a glutamate site; and [3 H]MDL105,519, that binds to a glycine (D-serine) co-agonist site. Radioligands [3 H]AMPA and [3 H]kainate are used as markers for the respective receptors. Using autoradiography method, Scarr and colleagues [183] compared density of hippocampal ionotropic glutamate receptors between the patients with bipolar disorder and matched controls. Whereas no changes were found in densities of AMPA and kainate receptors, decrease in [3 H]MK-801 binding was observed. However, non-significant decrease in binding of [3 H]CGP39653 led to the conclusion that the observed change reflected decrease in the number of open channels with no apparent difference in NMDA receptor density in hippocampal samples from bipolar subjects [183]. Similar decrease in [3 H]MK-801 binding was reported more recently by Beneyto and colleagues [179]. However, no changes in the expression in the NMDA receptor subunits and an increase in [3 H]MDL105,519 hippocampal binding, indicating an increase in the number of NMDAreceptor glycine binding sites, were simultaneously observed. No changes in receptor binding were detected in dorsolateral prefrontal cortex using the same radioligand methodology [180]. Decrease in NMDA NR1 subunit transcript was detected in several studies in hippocampus [91,184], dorsolateral prefrontal [180] and perirhinal cortex [179]. However, other studies have either not replicated these findings [179,185], or detected the same change in brain tissue of the patients afflicted with schizophrenia or major depressive disorder, questioning specificity of the finding to the bipolar disorder [180]. The findings are similarly inconclusive with regard to the expression of NR2A NMDA receptor subunit. NR2A mRNA expression level was found to be either decreased in hippocampus [184] and anterior cingulate cortex [182], or unchanged in the hippocampus [179] and DLPFC [180], between the patients with bipolar disorder and patients with antemortem diagnosis of MDD, schizophrenia and matched controls. Amongst the components of the NMDA-receptor associated proteins within the PSD, decrease in SAP102 mRNA expression was most consistently reported finding in brain samples from bipolar patients. Such decrease was observed in the hippocampus [184], DLPFC [180], striatum [186] and
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thalamus [187]. Reductions in PSD95 mRNA were additionally observed in striatum [186] and thalamus [187], but not DLPFC [180] of bipolar patients compared to matched controls. No changes were detected in expression of NF-L mRNA levels in DLPFC of bipolar patients [180]. Decrease in AMPA GluR3 and GluR6 receptor subunit mRNA was detected in entorhinal cortex [179]. Decrease in expression of kainate receptor KA2 was detected in the prefrontal cortex [188]. No differences were detected in the hippocampus GluR5, 6 and 7 immunoreactivity between the patients with bipolar disorder and matched controls [189]. Along similar lines, using in situ radioligand binding, no differences were detected in AMPA or kainite receptor density between hippocampal samples from patients with bipolar disorder and matched controls [183].
GABA Abnormalities in the GABAergic system have been identified in the GABA level, neuron and transporter density, as well as GABAergic receptor functioning in postmortem brain tissue of bipolar patients. GABAergic interneurons are anatomically and functionally heterogenous [80]. GABAergic interneurons can be classified by their immunoreactivity for the calciumbinding proteins parvalbumin, calbindin and calretinin [190]. Using these markers, majority of immunohistochemical studies in postmortem brains of bipolar patients found reduced number of calbindin and parvalbuminpositive cells in regions that participate in mood regulation, namely the anterior cingulate cortex [80,191], hippocampus [80,97], entorhinal [92] and dorsolateral prefrontal cortex, all suggesting that bipolar disorder might be associated with decreased levels of GABA [192]. Another interesting marker for the GABAergic interneurons is reelin, an extracellular glycoprotein involved in neuronal migration, synaptogenesis and dendritic plasticity [97,193]. Reelin expression, both at the mRNA and protein level, was significantly decreased in the prefrontal cortex [194] and the hippocampal formation of bipolar patients [181] compared to control tissue samples. Studies investigating expression of key enzymes involved in the synthesis of GABA, reported altered levels of expression of both 67 and 65 kDa isoforms. A predominant finding is a decrease in GAD67 mRNA and protein levels in multiple brain regions, including prefrontal cortex [194], anterior cingulate cortex [182], caudate nucleus and cerebellum [181]. While in some studies changes in mRNA GAD67 expression are paralleled by similar decrease in expression of GAD65 mRNA [181,195,196], other studies fail to replicate such findings [194]. In summary, a variety of differences between the brain samples from bipolar patients and matched controls were
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detected in amino acidergic systems, but the functional significance of these findings is at present unclear. Inconsistencies might be related to the regional differences, generally small sample sizes, effects of antemortem medication regimen, freezer storage time, postmortem interval and brain ph [97,98]. Assessment of receptors functionality in general can be affected by post-translational modifications, binding with other components of the receptor complex, or rate of protein degradation, none of which can be assessed by the mRNA expression studies [197]. Moreover, recent research provide evidence that synaptic NMDAR number and subunit composition are not static, but change dynamically in a cell specific and synapse-specific manner in response to neuronal activity or sensory experience [198].
Neuroimaging studies Proton MRS is providing increasingly valuable insight into the role of glutamatergic and GABAergic transmission in mood disorders [199]. Earlier MRS studies reported levels of a composite Glx peak, which contains overlapping resonances of glutamine, glutamate and GABA. Most studies conducted in patients with bipolar disorder revealed elevated Glx levels in the cortical grey matter of anterior cingulated [200], frontal cortex [201] and basal ganglia [202] in unspecified phase of the illness relative to controls, as well as in the DLPFC of acutely manic patients relative to controls [203]. Newer methodology using higher strength magnetic fields allows resolution of the Glx peak into its constituents, providing a unique insight into glutamtergic and GABAergic system function in bipolar disorder [204,205]. One such study reported elevation in hippocampal glutamate that correlated with NAA level in remitted bipolar patients on lithium maintenance [205]. Bhagwagar and colleagues reported reduction in occipital cortex GABA concentration in medication-free, recovered unipolar depressed and bipolar patients [204]. However, a recent study led by Kaufman reported no significant difference in the levels of glutamate or GABA between bipolar patients and controls [206]. Increased glutamate levels could be neurotoxic, and possibly result in anatomical abnormalities reported in brain imaging and postmortem studies. Therefore, measurement of two other chemicals, N-acetyl-aspartate (NAA) [207] and lactate [208] may provide indirect information on the neuronal functional integrity as well as assessment of brains bioenergetic status. NAA is located only to neurons, and not found in mature glial or blood cells. Decrease in NAA levels detected in dorsolateral prefrontal cortex of bipolar patients [115] may reflect neuronal loss, decreased neuronal viability or impaired neuronal functioning. Lactate is a product of anaerobic glycolysis. Increase in brain lactate is associated with seizure activity, ischaemic pathology or rigorous cognitive activation tasks [208]. Significant
reduction in both manic and depressive symptoms correlated with decrease in lactate levels [209]. In summary, most studies conducted in patients with bipolar disorder revealed elevated Glx levels, suggesting hyperglutamatergic state in several key regions involved in mood regulation. However, given the overall inconsistencies in findings, observed biochemical abnormalities likely present markers of a trait vulnerability to mood disorders, rather than neurochemical correlates of an abnormal mood state [204,210].
Genetic studies Several genetic studies have found associations between genetic polymorphisms and dysregulation of glutamatergic neurotransmission in bipolar disorder [211]. Polymorphisms in G72/G30 gene locus on chromosome 13 (13q32-33) confer susceptibility to bipolar disorder in several independent datasets [212]. Products of both genes are involved in glutamatergic signalling cascade [213].
Neuroendocrine systems and neuropeptides One of the most consistent findings in biological psychiatry is derangement of endocrine functioning in patients with mood disorders [70]. Central to regulating bodily homoeostasis and neuroendocrine response to external and internal stressors is the hypothalamus. Through action of neuropeptides, which it synthesizes and secretes, the hypothalamus controls an immense number of bodily functions, which include stress response, control of body temperature, ingestive behaviours, emotions, sexual activity, circadian cycles, blood pressure, as well as electrolyte balance [214].
Hypothalamic-pituitary-adrenal axis (HPA axis) Disturbance in homoeostatic balance, conveyed to the hypothalamus through the action of numerous neurotransmitters, including acetylcholine, noradrenaline, serotonin and GABA [215], causes activation of the HPA axis resulting in a release of a corticotropin-releasing factor (CRF) into the portal circulation, CRH-mediated release of adrenocorticotropic hormone (ACTH) from the anterior pituitary, and ACTH-mediated release of the cortisol from the adrenal gland [216–218]. CRF, a 41-amino acid peptide, exerts its action through two types of receptors, CRF1 and CRF2, and it appears that these two receptors mediate opposing effects, with CRFR1 activating and CRFR2 inhibiting, the CRF-mediated stress response. CRFR1 is the predominate subtype in limbic regions and in pituitary regulation of HPA axis activity [219]. Cortisol exerts its action through activation of two types of
Neurotransmitter Systems
receptors; type I or mineralocorticoid receptor (MR) with high affinity for endogenous corticosteroids, and type II or glucocorticoid (GR) receptors, with low affinity for cortisol [220]. Acute consequence of the HPA axis activation is mobilization of energy reserves to facilitate coping with stress. Chronic activation of the stress axis, or exogenous administration of corticosteroids for the treatment purposes, however, result in a host of neuropsychiatric disorders, of which mood disorders, including major depression, mania and delirium, are the most prominent [221,222]. Peripheral measures of hormones in bodily fluids may not provide a reliable insight into the brain functioning, as a number of associated variables, including hypothalamo/ pituitary blood flow, degree of stress, diet, sleep or level of activity, are difficult to control. Nevertheless, the evidence of HPA abnormalities have been repeatedly demonstrated in all phases of bipolar illness, and include elevated baseline serum cortisol levels, nonsupression of cortisol on the dexamethasone suppression test (DST) [223], and elevated cortisol release during the DST/CRF test [224]. Measurements of salivary cortisol yielded inconsistent results with some studies reporting increased [29], and in some no changes, in salivary cortisols level in bipolar patients compared to controls [225]. Postmortem studies investigating quantity of glucocorticoid and mineralocorticoid receptors demonstrated decreased glucocorticoid mRNA in the inferior temporal cortex, subiculum and entorhinal cortex in brain samples from patients carrying antemortem diagnosis of bipolar disorder, compared to patients with schizophrenia, unipolar depression or matched controls [226]. Another postmortem brain study found significantly lower mineralocorticoid receptor mRNA level in the dorsolateral prefrontal cortex of bipolar brain samples compared to controls [227]. Significant decrease in CRF-binding protein mRNA was detected in the amygdaloid nuclei of bipolar female and schizophrenic patients [228]. An increased number of CRF expressing neurons was found in hypothalamic paraventricular nucleus in the combined unipolar and bipolar depressed patient group [229]. This study potentially demonstrates the hyperactivity of CRH neurons, which could be related to activation of the HPA axis in patients with mood disorders. Recent interest has focused on a glucocorticoid receptor (GR) chaperone protein BCL-2 (B-cell CLL/lymphoma 2)associated athanogene (BAG1). BAG-1 attenuates glucocorticoid receptor (GR) nuclear translocation, activates ERK (extracellular signal-regulated kinase) MAP (mitogenactivated protein) kinases, and potentiates anti-apoptotic functions of BCL-2 [230]. The same study also demonstrated that that lithium/valproate induced BAG1 up-regulation attenuates GR nuclear translocation and also attenuates the activity of a reporter gene driven by GRs. BAG1 overexpression resulted in higher hippocampal levels of
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Hsp70 and lower levels of FKBP51 without changing overall GR levels or levels of Bcl-2, ERK, or pERK [231].
Hypothalamic-pituitary-thyroid axis (HPT axis) Thyroid hormones are involved in regulation of nearly every organ system in the human body. The regulation of thyroid hormone secretion is initiated by the release of hypothalamic tripeptide, thyrotropin-releasing hormone (TRH). After reaching the pituitary gland via portal circulation, TRH mediates release of the thyroid-stimulating hormone (TSH). Following release into general circulation, TSH mediates release of thyroid hormones (T3 and T4) from the thyroid gland. T3 and T4 have widespread metabolic effects and can alter many aspects of the peripheral and central nervous system functioning [232]. HPT axis dysfunction can induce a wide array of psychiatric symptoms. As early as 1864, Graves noted marked mood depression in patients with endemic goitre. Subsequent clinical observations linked hypothyroidism with depression and hyperthyroidism with euphoric states, including manic states. In particular, female patients with rapid cycling form of bipolar disorder seem to be particularly susceptible to disbalance in thyroid functioning [64].
Neuropeptide Y Neuropeptide Y (NPY) is a 36 amino acid long polypeptide, member of the pancreatic polypeptide family, and is present in extensive neuronal systems in the brain, especially in the hypothalamus and the amygdala [233]. NPY effects are mediated through at least five G-protein coupled receptor subtypes [234]. Of these, Y1 and Y2 are the most abundant in the brain. NPY coexist in neuronal cell bodies with catecholamines, GABA and somatostatin [235]. Its actions involve stimulation of food intake, modulation of circadian rhythms and regulation of release of several hypothalamic hormones, including the CRF. Numerous studies implicate NPY in regulation of mood [236]. Very few studies so far investigated involvement of NPY in pathophysiology of bipolar disorder and the results are, at present, inconclusive. Peripheral measures revealed no difference in plasma level NPY in bipolar patients stabilized on lithium and matched controls [237]. Postmortem studies revealed reduced NPY, Y1 and Y2 receptor mRNA in dorsolateral prefrontal cortex in patients with bipolar disorder and schizophrenia [238].
Substance P Substance P is an undecapeptide, with a key role in nociception. Substance P acts as an excitatory neurotransmitter in the primary afferent (dorsal root) nerve terminal in the
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mammalian spinal cord and regulates sympathetic noradrenergic function. Within the CNS, substance P is found in discrete areas of the CNS, including the amygdala, hypothalamus, substantia nigra, caudate-putamen and cortex, where it is thought to act as an excitatory neurotransmitter. Substance P is usually co-localized with one of the classic neurotransmitters, frequently serotonin. P mediates its effect via neurokinin-1 (NK-1) receptors [239]. A study of NK-1 receptor densities in the anterior cingulate cortex, measured using quantitative receptor autoradiography, in bipolar, unipolar depressed and schizophrenic patients detected no significant differences in total receptor densities amongst the groups [240]. No group differences were detected in CSF substance P immunoreactivity between bipolar manic or depressed, unipolar depressed and matched control samples [241].
Somatostatin Somatostatin has 2 active forms, 14 and 28 amino acids long, produced by alternative cleavage of a single preprotein. Somatostatin is released from the hypothalamus into portal circulation, and carried to the anterior pituitary, where it inhibits secretion of growth hormone from somatotrope cells. It exerts action through G protein-coupled receptor. Significant reduction in CSF somatostatin was observed in unipolar and bipolar depressed patients [242]. In contrast, manic patients had significantly higher CSF somatostatin compared to matched controls, in a study by Sharma and colleagues [243].
Conclusions A large number of studies have implicated abnormalities in monoaminergic (dopaminergic, noradrenergic, serotonergic), cholinergic, glutamatergic, GABA-ergic, glucocorticoid and peptidergic systems in pathophysiology of bipolar disorder [4]. Despite significant contributions of those studies, the precise pathophysiology of the bipolar disorder remains to be explored. One major obstacle in this process is the obvious heterogeneity of the mood states in bipolar disorder. The neurochemical profiles of the five different clinical manifestations of the bipolar disorder – manic, hypomanic, depressed, mixed and variable length euthymic periods are at present insufficiently characterized. The complexity and multidirectional interactions within numerous neurotransmitter systems add to difficulty interpreting observed changes as reflective of the cause of the disease, its consequence, or an organisms attempt to overcome or compensate for the effects of disease [158–161]. Inconsistencies in the data obtained may also stem from the variety of technological challenges inherent to postmortem and neuroimaging studies, as well as peripheral measures. On the other hand, development of neuroimaging technologies
that permit in vivo characterization of the anatomical, physiological and neurochemical correlates of mood disorders, enables continuous advancement towards illuminating the pathophysiology of these conditions. In recent years, it has become increasingly clear that the view that particular transmitter abnormality causes mood disorder is over-simplistic [23]. At present, it is unclear why a number of patients do not respond to bipolar disorder treatment, nor do we understand the neurobiology of the lag between the administration and biological effect of the mood stabilizers and antidepressants. This discrepancy indicates that many biochemical steps are probably involved between the primary targets and biological effects. Recent exciting developments, outside the purview of this chapter, include the cloning and characterization of the circadian genes that have shed new light on the association between the circadian rhythms and bipolar disorder [244]. A growing body of evidence in recent years is implicating signal transduction pathways and mechanisms of cellular plasticity [4,94]. It may well be that these strategies will drive future efforts to understand the pathophysiology of bipolar disorder.
References 1. Merikangas, K.R., Akiskal, H.S., Angst, J. et al. (2007) Lifetime and 12-month prevalence of bipolar spectrum disorder in the National Comorbidity Survey replication. Arch. Gen. Psychiatry, 64, 543–552. 2. Murray, C.J. and Lopez, A.D. (1997) Alternative projections of mortality and disability by cause 1990–2020: Global Burden of Disease Study. Lancet, 349, 1498–1504. 3. Bostwick, J.M. and Pankratz, V.S. (2000) Affective disorders and suicide risk: a reexamination. Am. J. Psychiatry, 157, 1925–1932. 4. Manji, H.K. and Lenox, R.H. (2000) The nature of bipolar disorder. J. Clin. Psychiatry, 61 (Supp 13), 42–57. 5. Bunney, W.E. Jr and Davis, J.M. (1965) Norepinephrine in depressive reactions. A review. Arch. Gen. Psychiatry, 13, 483–494. 6. Schildkraut, J.J. (1965) The catecholamine hypothesis of affective disorders: a review of supporting evidence. Am. J. Psychiatry, 122, 509–522. 7. Schildkraut, J.J. (1967) The catecholamine hypothesis of affective disorders. A review of supporting evidence. Int. J. Psychiatry, 4, 203–217. 8. Pletscher, A., Shore, P.A. and Brodie, B.B. (1955) Serotonin release as a possible mechanism of reserpine action. Science, 122, 374–375. 9. Shore, P.A., Silver, S.L. and Brodie, B.B. (1955) Interaction of reserpine, serotonin, and lysergic acid diethylamide in brain. Science, 122, 284–285. 10. Muller, J.C., Pryor, W.W., Gibbons, J.E. and Orgain, E.S. (1955) Depression and anxiety occurring during Rauwolfia therapy. J. Am. Med. Assoc., 159, 836–839.
Neurotransmitter Systems 11. Crane, G.E. (1956) The psychiatric side-effects of iproniazid. Am. J. Psychiatry, 112, 494–501. 12. Kline, N.S. (1958) Clinical experience with iproniazid (marsilid). J. Clin. Exp. Psychopathol., 19, 72–78; discussion 78–79. 13. Loomer, H.P., Saunders, J.C. and Kline, N.S. (1957) A clinical and pharmacodynamic evaluation of iproniazid as a psychic energizer. Psychiatr. Res. Rep. Am. Psychiatr. Assoc., 8, 129–141. 14. Kuhn, R. (1958) The treatment of depressive states with G 22355 (imipramine hydrochloride). Am. J. Psychiatry, 115, 459–464. 15. Gershon, S., Holmberg, G., Mattsson, E. et al. (1962) Imipramine hydrochloride. Its effects on clinical, autonomic, and psychological functions. Arch. Gen. Psychiatry, 6, 96–101. 16. Jouvent, R., Lecrubier, Y., Puech, A.J. et al. (1980) Antimanic effect of clonidine. Am. J. Psychiatry, 137, 1275–1276. 17. Nurnberger, J.I. Jr, Berrettini, W.H., Simmons-Alling, S. et al. (1986) Intravenous GABA administration is anxiogenic in man. Psychiatry Res., 19, 113–117. 18. Schildkraut, J.J. and Kety, S.S. (1967) Biogenic amines and emotion. Science, 156, 21–37. 19. Silverstone, T. and Cookson, J. (1983) Examining the dopamine hypotheses of schizophrenia and of mania using the prolactin response to antipsychotic drugs. Neuropharmacology, 22, 539–541. 20. Coppen, A.J. (1968) Depressed states and indolealkylamines. Adv. Pharmacol., 6, 283–291. 21. Lapin, I.P. and Oxenkrug, G.F. (1969) Intensification of the central serotoninergic processes as a possible determinant of the thymoleptic effect. Lancet, 1, 132–136. 22. Prange, A.J. Jr, Wilson, I.C., Lynn, C.W. et al. (1974) Ltryptophan in mania. Contribution to a permissive hypothesis of affective disorders. Arch. Gen. Psychiatry, 30, 56–62. 23. Drevets, W.C., Price, J.L. and Furey, M.L. (2008) Brain structural and functional abnormalities in mood disorders: implications for neurocircuitry models of depression. Brain Struct. Funct., 213, 93–118. 24. Kumer, S.C. and Vrana, K.E. (1996) Intricate regulation of tyrosine hydroxylase activity and gene expression. J. Neurochem., 67, 443–462. 25. Abell, C.W. and Kwan, S.W. (2001) Molecular characterization of monoamine oxidases A and B. Prog. Nucleic. Acid Res. Mol. Biol., 65, 129–156. 26. Cooper, J.R., Bloom, F.E. and Roth, R.H. (2003) The Biochemical Basis of Neuropharmacology, Oxford University Press. 27. Bannon, M.J., Wolf, M.E. and Roth, R.H. (1983) Pharmacology of dopamine neurons innervating the prefrontal, cingulate and piriform cortices. Eur. J. Pharmacol., 92, 119–125. 28. Nagatomo, T. and Koike, K. (2000) Recent advances in structure, binding sites with ligands and pharmacological function of beta-adrenoceptors obtained by molecular biology and molecular modeling. Life Sci., 66, 2419–2426. 29. Chiodo, L.A. (1992) Dopamine autoreceptor signal transduction in the DA cell body: a “current view”. Neurochem. Int., (20 Suppl), 81S–84S. 30. Gingrich, J.A. and Caron, M.G. (1993) Recent advances in the molecular biology of dopamine receptors. Annu. Rev. Neurosci., 16, 299–321.
|
221
31. Missale, C., Nash, S.R., Robinson, S.W. et al. (1998) Dopamine receptors: from structure to function. Physiol. Rev., 78, 189–225. 32. Redmond, D.E. Jr (1986) The possible role of locus coeruleus noradrenergic activity in anxiety-panic. Clin. Neuropharmacol., 9 (Suppl 4), 40–42. 33. Robbins, T.W. and Everitt, B.J. (1982) Functional studies of the central catecholamines. Int. Rev. Neurobiol., 23, 303–365. 34. Berridge, C.W. and Waterhouse, B.D. (2003) The locus coeruleus-noradrenergic system: modulation of behavioral state and state-dependent cognitive processes. Brain Res. Brain Res. Rev., 42, 33–84. 35. Fitzpatrick, P.F. (2000) The aromatic amino acid hydroxylases. Adv. Enzymol. Relat. Areas Mol. Biol., 74, 235–294. 36. Hoyer, D. and Martin, G. (1997) 5-HT receptor classification and nomenclature: towards a harmonization with the human genome. Neuropharmacology, 36, 419–428. 37. Hoyer, D. and Martin, G.R. (1996) Classification and nomenclature of 5-HT receptors: a comment on current issues. Behav. Brain Res., 73, 263–268. 38. Owens, M.J. and Nemeroff, C.B. (1994) Role of serotonin in the pathophysiology of depression: focus on the serotonin transporter. Clin. Chem., 40, 288–295. 39. Tork, I. (1990) Anatomy of the serotonergic system. Ann. N. Y. Acad. Sci., 600, 9–34; discussion 34–35. 40. Pandi-Perumal, S.R., Srinivasan, V., Maestroni, G.J. et al. (2006) Melatonin: Natures most versatile biological signal? Febs. J., 273, 2813–2838. 41. Zarate, C.A. Jr and Manji, H.K. (2008) Bipolar disorder: candidate drug targets. Mt. Sinai. J. Med., 75, 226–247. 42. Gershon, S. and Shaw, F.H. (1961) Psychiatric sequelae of chronic exposure to organophosphorus insecticides. Lancet, 1, 1371–1374. 43. Carlton, P.L. (1963) Cholinergic mechanisms in the control of behavior by the brain. Psychol. Rev., 70, 19–39. 44. Janowsky, D.S., el-Yousef, M.K., Davis, J.M. and Sekerke, H.J. (1972) A cholinergic-adrenergic hypothesis of mania and depression. Lancet, 2, 632–635. 45. Sitaram, N., Nurnberger, J.I. Jr, Gershon, E.S. and Gillin, J.C. (1982) Cholinergic regulation of mood and REM sleep: potential model and marker of vulnerability to affective disorder. Am. J. Psychiatry, 139, 571–576. 46. Bloc, A., Bugnard, E., Dunant, Y. et al. (1999) Acetylcholine synthesis and quantal release reconstituted by transfection of mediatophore and choline acetyltranferase cDNAs. Eur. J. Neurosci., 11, 1523–1534. 47. Collier, B., Tandon, A., Prado, M.A. and Bachoo, M. (1993) Storage and release of acetylcholine in a sympathetic ganglion. Prog. Brain. Res., 98, 183–189. 48. Parsons, S.M., Prior, C. and Marshall, I.G. (1993) Acetylcholine transport, storage, and release. Int. Rev. Neurobiol., 35, 279–390. 49. Soreq, H. and Seidman, S. (2001) Acetylcholinesterase–new roles for an old actor. Nat. Rev. Neurosci., 2, 294–302. 50. Picciotto, M.R., Caldarone, B.J., King, S.L. and Zachariou, V. (2000) Nicotinic receptors in the brain. Links between molecular biology and behavior. Neuropsychopharmacology, 22, 451–465.
222
|
Chapter 16
51. Nathanson, N.M. (2008) Synthesis, trafficking, and localization of muscarinic acetylcholine receptors. Pharmacol. Ther., 119, 33–43. 52. Schildkraut, J.J., Keeler, B.A., Papousek, M. and Hartmann, E. (1973) MHPG excretion in depressive disorders: relation to clinical subtypes and desynchronized sleep. Science, 181, 762–764. 53. Agren, H. (1980) Symptom patterns in unipolar and bipolar depression correlating with monoamine metabolites in the cerebrospinal fluid: I. General patterns. Psychiatry Res., 3, 211–223. 54. Koslow, S.H., Maas, J.W., Bowden, C.L. et al. (1983) CSF and urinary biogenic amines and metabolites in depression and mania. A controlled, univariate analysis. Arch. Gen. Psychiatry, 40, 999–1010. 55. Rudorfer, M.V., Ross, R.J., Linnoila, M. et al. (1985) Exaggerated orthostatic responsivity of plasma norepinephrine in depression. Arch. Gen. Psychiatry, 42, 1186–1192. 56. Swann, A.C., Secunda, S., Davis, J.M. et al. (1983) CSF monoamine metabolites in mania. Am. J. Psychiatry, 140, 396–400. 57. Swann, A.C., Stokes, P.E., Secunda, S.K. et al. (1994) Depressive mania versus agitated depression: biogenic amine and hypothalamic-pituitary-adrenocortical function. Biol. Psychiatry, 35, 803–813. 58. Swann, A.C., Katz, M.M., Bowden, C.L. et al. (1999) Psychomotor performance and monoamine function in bipolar and unipolar affective disorders. Biol. Psychiatry, 45, 979–988. 59. Gerner, R.H., Fairbanks, L. and Anderson, G.M. et al. (1984) CSF neurochemistry in depressed, manic, and schizophrenic patients compared with that of normal controls. Am. J. Psychiatry, 141, 1533–1540. 60. Sjostrom, R. and Roos, B.E. (1972) 5-Hydroxyindolacetic acid and homovanillic acid in cerebrospinal fluid in manic-depressive psychosis. Eur. J. Clin. Pharmacol., 4, 170–176. 61. Asberg, M. (1997) Neurotransmitters and suicidal behavior. The evidence from cerebrospinal fluid studies. Ann. N. Y. Acad. Sci., 836, 158–181. 62. Banki, C.M. and Arato, M. (1983) Amine metabolites, neuroendocrine findings, and personality dimensions as correlates of suicidal behavior. Psychiatry Res., 10, 253–261. 63. Fortunati, F., Mazure, C., Preda, A. et al. (2002) Plasma catecholamine metabolites in antidepressant-exacerbated mania and psychosis. J. Affect. Disord., 68, 331–334. 64. Goodwin, F.K. and Ghaemi, S.N. (1998) Understanding manic-depressive illness. Arch. Gen. Psychiatry, 55, 23–25. 65. Shiah, I.S. and Yatham, L.N. (2000) Serotonin in mania and in the mechanism of action of mood stabilizers: a review of clinical studies. Bipolar Disord., 2, 77–92. 66. Dencker, S.J., Malm, U., Roos, B.E. and Werdinius, B. (1966) Acid monoamine metabolites of cerebrospinal fluid in mental depression and mania. J. Neurochem., 13, 1545–1548. 67. Mendels, J., Frazer, A., Fitzgerald, R.G. et al. (1972) Biogenic amine metabolites in cerebrospinal fluid of depressed and manic patients. Science, 175, 1380–1382. 68. Ashcroft, G.W., Crawford, T.B., Eccleston, D. et al. (1966) 5-hydroxyindole compounds in the cerebrospinal fluid of patients with psychiatric or neurological diseases. Lancet, 2, 1049–1052.
69. Tandon, R., Channabasavanna, S.M. and Greden, J.F. (1988) CSF biochemical correlates of mixed affective states. Acta Psychiatr. Scand, 78, 289–297. 70. Goodwin, F.K.J.K. (2007) Manic-Depressive Illness: Bipolar Disorders and Recurrent Depression, Oxford University Press. 71. Delgado, P.L. (2000) Depression: the case for a monoamine deficiency. J. Clin. Psychiatry, 61 (Suppl 6), 7–11. 72. Moja, E.A., Cipolla, P., Castoldi, D. and Tofanetti, O. (1989) Dose-response decrease in plasma tryptophan and in brain tryptophan and serotonin after tryptophan-free amino acid mixtures in rats. Life Sci., 44, 971–976. 73. Young, S.N., Ervin, F.R., Pihl, R.O. and Finn, P. (1989) Biochemical aspects of tryptophan depletion in primates. Psychopharmacology (Berl.), 98, 508–511. 74. Benkelfat, C., Seletti, B., Palmour, R.M. et al. (1995) Tryptophan depletion in stable lithium-treated patients with bipolar disorder in remission. Arch. Gen. Psychiatry, 52, 154–156. 75. Cassidy, F., Murry, E. and Carroll, B.J. (1998) Tryptophan depletion in recently manic patients treated with lithium. Biol. Psychiatry, 43, 230–232. 76. Hughes, J.H., Dunne, F. and Young, A.H. (2000) Effects of acute tryptophan depletion on mood and suicidal ideation in bipolar patients symptomatically stable on lithium. Br. J. Psychiatry, 177, 447–451. 77. Cappiello, A., Sernyak, M.J., Malison, R.T. et al. (1997) Effects of acute tryptophan depletion in lithium-remitted manic patients: a pilot study. Biol. Psychiatry, 42, 1076–1078. 78. McTavish, S.F., McPherson, M.H., Harmer, C.J. et al. (2001) Antidopaminergic effects of dietary tyrosine depletion in healthy subjects and patients with manic illness. Br. J. Psychiatry, 179, 356–360. 79. Anand, A., Darnell, A., Miller, H.L. et al. (1999) Effect of catecholamine depletion on lithium-induced long-term remission of bipolar disorder. Biol. Psychiatry, 45, 972–978. 80. Benes, F.M. and Berretta, S. (2001) GABAergic interneurons: implications for understanding schizophrenia and bipolar disorder. Neuropsychopharmacology, 25, 1–27. 81. Ongur, D., Drevets, W.C. and Price, J.L. (1998) Glial reduction in the subgenual prefrontal cortex in mood disorders. Proc. Natl. Acad. Sci. USA, 95, 13290–13295. 82. Baumann, B., Danos, P., Krell, D. et al. (1999) Reduced volume of limbic system-affiliated basal ganglia in mood disorders: preliminary data from a postmortem study. J. Neuropsychiatry Clin. Neurosci., 11, 71–78. 83. Rajkowska, G. (1997) Morphometric methods for studying the prefrontal cortex in suicide victims and psychiatric patients. Ann. N. Y. Acad. Sci., 836, 253–268. 84. Rajkowska, G., Miguel-Hidalgo, J.J., Wei, J. et al. (1999) Morphometric evidence for neuronal and glial prefrontal cell pathology in major depression. Biol. Psychiatry, 45, 1085–1098. 85. Altar, C.A., Vawter, M.P. and Ginsberg, S.D. (2009) Target identification for CNS diseases by transcriptional profiling. Neuropsychopharmacology, 34, 18–54. 86. Palfreyman, M.G., Hook, D.J., Klimczak, L.J. et al. (2002) Novel directions in antipsychotic target identification using
Neurotransmitter Systems
87.
88.
89.
90.
91.
92.
93.
94.
95.
96.
97.
98.
99. 100.
101.
102.
gene arrays. Curr. Drug Targets CNS Neurol. Disord., 1, 227–238. Young, L.T., Warsh, J.J., Kish, S.J. et al. (1994) Reduced brain 5-HT and elevated NE turnover and metabolites in bipolar affective disorder. Biol. Psychiatry, 35, 121–127. Wiste, A.K., Arango, V., Ellis, S.P. et al. (2008) Norepinephrine and serotonin imbalance in the locus coeruleus in bipolar disorder. Bipolar Disord., 10, 349–359. Dean, B., Pavey, G., McLeod, M. et al. (2001) A change in the density of [(3)H]flumazenil, but not [(3)H]muscimol binding, in Brodmanns Area 9 from subjects with bipolar disorder. J. Affect. Disord., 66, 147–158. Gray, L., Scarr, E. and Dean, B. (2006) Serotonin 1a receptor and associated G-protein activation in schizophrenia and bipolar disorder. Psychiatry Res., 143, 111–120. Dean, B., Scarr, E., Pavey, G. and Copolov, D. (2003) Studies on serotonergic markers in the human hippocampus: changes in subjects with bipolar disorder. J. Affect. Disord., 75, 65–69. Pantazopoulos, H., Lange, N., Baldessarini, R.J. and Berretta, S. (2007) Parvalbumin neurons in the entorhinal cortex of subjects diagnosed with bipolar disorder or schizophrenia. Biol. Psychiatry, 61, 640–652. Sun, Y., Zhang, L., Johnston, N.L. et al. (2001) Serial analysis of gene expression in the frontal cortex of patients with bipolar disorder. Br. J. Psychiatry, (Suppl 41), s137–s141. Schloesser, R.J., Huang, J., Klein, P.S. and Manji, H.K. (2008) Cellular plasticity cascades in the pathophysiology and treatment of bipolar disorder. Neuropsychopharmacology, 33, 110–133. Friedman, E. and Wang, H.Y. (1996) Receptor-mediated activation of G proteins is increased in postmortem brains of bipolar affective disorder subjects. J. Neurochem., 67, 1145–1152. Severance, E.G. and Yolken, R.H. (2007) Lack of RIC-3 congruence with beta2 subunit-containing nicotinic acetylcholine receptors in bipolar disorder. Neuroscience, 148, 454–460. Knable, M.B., Barci, B.M., Webster, M.J. et al. (2004) Molecular abnormalities of the hippocampus in severe psychiatric illness: postmortem findings from the Stanley Neuropathology Consortium. Mol. Psychiatry, 9, 544, 609–620. Vawter, M.P., Tomita, H., Meng, F. et al. (2006) Mitochondrial-related gene expression changes are sensitive to agonal-pH state: implications for brain disorders. Mol. Psychiatry, 11, 615, 663–679. Rauch, S.L. and Renshaw, P.F. (1995) Clinical neuroimaging in psychiatry. Harv. Rev. Psychiatry, 2, 297–312. Stoll, A.L., Renshaw, P.F., Yurgelun-Todd, D.A. and Cohen, B.M. (2000) Neuroimaging in bipolar disorder: what have we learned? Biol. Psychiatry, 48, 505–517. Pearlson, G.D., Wong, D.F., Tune, L.E. et al. (1995) In vivo D2 dopamine receptor density in psychotic and nonpsychotic patients with bipolar disorder. Arch. Gen. Psychiatry, 52, 471–477. Anand, A., Verhoeff, P., Seneca, N. et al. (2000) Brain SPECT imaging of amphetamine-induced dopamine release in
103.
104.
105.
106.
107.
108.
109.
110.
111.
112.
113.
114.
115.
116.
117.
|
223
euthymic bipolar disorder patients. Am. J. Psychiatry, 157, 1108–1114. Yatham, L.N., Liddle, P.F., Shiah, I.S. et al. (2002) PET study of [(18)F]6-fluoro-L-dopa uptake in neuroleptic- and moodstabilizer-naive first-episode nonpsychotic mania: effects of treatment with divalproex sodium. Am. J. Psychiatry, 159, 768–774. Suhara, T., Nakayama, K., Inoue, O. et al. (1992) D1 dopamine receptor binding in mood disorders measured by positron emission tomography. Psychopharmacology (Berl.), 106, 14–18. Drevets, W.C., Frank, E., Price, J.C. et al. (1999) PET imaging of serotonin 1A receptor binding in depression. Biol. Psychiatry, 46, 1375–1387. Oquendo, M.A., Hastings, R.S., Huang, Y.Y. et al. (2007) Brain serotonin transporter binding in depressed patients with bipolar disorder using positron emission tomography. Arch. Gen. Psychiatry, 64, 201–208. Ichimiya, T., Suhara, T., Sudo, Y. et al. (2002) Serotonin transporter binding in patients with mood disorders: a PET study with [11C]( þ )McN5652. Biol. Psychiatry, 51, 715–722. Cannon, D.M., Ichise, M., Fromm, S.J. et al. (2006) Serotonin transporter binding in bipolar disorder assessed using [11C] DASB and positron emission tomography. Biol Psychiatry, 60, 207–217. Hamakawa, H., Kato, T., Murashita, J. and Kato, N. (1998) Quantitative proton magnetic resonance spectroscopy of the basal ganglia in patients with affective disorders. Eur. Arch. Psychiatry Clin. Neurosci., 248, 53–58. Kato, T., Inubushi, T. and Kato, N. (1998) Magnetic resonance spectroscopy in affective disorders. J. Neuropsychiatry Clin. Neurosci., 10, 133–147. Sharma, R., Venkatasubramanian, P.N., Barany, M. and Davis, J.M. (1992) Proton magnetic resonance spectroscopy of the brain in schizophrenic and affective patients. Schizophr. Res., 8, 43–49. Moore, C.M., Breeze, J.L., Gruber, S.A. et al. (2000) Choline, myo-inositol and mood in bipolar disorder: a proton magnetic resonance spectroscopic imaging study of the anterior cingulate cortex. Bipolar Disord., 2, 207–216. Cecil, K.M., DelBello, M.P., Morey, R. and Strakowski, S.M. (2002) Frontal lobe differences in bipolar disorder as determined by proton MR spectroscopy. Bipolar Disord., 4, 357–365. Atmaca, M., Yildirim, H., Ozdemir, H. et al. (2006) Hippocampal 1H MRS in first-episode bipolar I patients. Prog. Neuropsychopharmacol. Biol. Psychiatry, 30, 1235–1239. Molina, V., Sanchez, J., Sanz, J. et al. (2007) Dorsolateral prefrontal N-acetyl-aspartate concentration in male patients with chronic schizophrenia and with chronic bipolar disorder. Eur. Psychiatry, 22, 505–512. Patel, N.C., DelBello, M.P., Cecil, K.M. et al. (2008) Temporal change in N-acetyl-aspartate concentrations in adolescents with bipolar depression treated with lithium. J. Child Adolesc. Psychopharmacol., 18, 132–139. Brambilla, P., Stanley, J.A., Nicoletti, M.A. et al. (2005) 1H magnetic resonance spectroscopy investigation of the
224
118.
119. 120. 121.
122.
123. 124.
125.
126.
127.
128.
129. 130.
131.
132.
133.
134.
|
Chapter 16
dorsolateral prefrontal cortex in bipolar disorder patients. J. Affect. Disord., 86, 61–67. Frye, M.A., Thomas, M.A., Yue, K. et al. (2007) Reduced concentrations of N-acetylaspartate (NAA) and the NAAcreatine ratio in the basal ganglia in bipolar disorder: a study using 3-Tesla proton magnetic resonance spectroscopy. Psychiatry Res., 154, 259–265. Craddock, N. and Forty, L. (2006) Genetics of affective (mood) disorders. Eur. J. Hum. Genet., 14, 660–668. Craddock, N. and Jones, I. (1999) Genetics of bipolar disorder. J. Med. Genet., 36, 585–594. Kato, T. (2008) Molecular neurobiology of bipolar disorder: a disease of mood-stabilizing neurons? Trends Neurosci., 31, 495–503. Preisig, M., Bellivier, F., Fenton, B.T. et al. (2000) Association between bipolar disorder and monoamine oxidase A gene polymorphisms: results of a multicenter study. Am. J. Psychiatry, 157, 948–955. Jones, I. and Craddock, N. (2001) Candidate gene studies of bipolar disorder. Ann. Med., 33, 248–256. Furlong, R.A., Ho, L., Rubinsztein, J.S. et al. (1999) Analysis of the monoamine oxidase A (MAOA) gene in bipolar affective disorder by association studies, meta-analyses, and sequencing of the promoter. Am. J. Med. Genet., 88, 398–406. Sanacora, G., Zarate, C.A., Krystal, J.H. and Manji, H.K. (2008) Targeting the glutamatergic system to develop novel, improved therapeutics for mood disorders. Nat. Rev. Drug Discov., 7, 426–437. Snyder, S.H. and Ferris, C.D. (2000) Novel neurotransmitters and their neuropsychiatric relevance. Am. J. Psychiatry, 157, 1738–1751. Cluskey, S. and Ramsden, D.B. (2001) Mechanisms of neurodegeneration in amyotrophic lateral sclerosis. Mol. Pathol., 54, 386–392. Fan, M.M. and Raymond, L.A. (2007) N-methyl-D-aspartate (NMDA) receptor function and excitotoxicity in Huntingtons disease. Prog. Neurobiol., 81, 272–293. Francis, P.T. (2003) Glutamatergic systems in Alzheimers disease. Int. J. Geriatr. Psychiatry, 18, S15–S21. Paz, R.D., Tardito, S., Atzori, M. and Tseng, K.Y. (2008) Glutamatergic dysfunction in schizophrenia: from basic neuroscience to clinical psychopharmacology. Eur. Neuropsychopharmacol., 18, 773–786. Lau, C.G. and Zukin, R.S. (2007) NMDA receptor trafficking in synaptic plasticity and neuropsychiatric disorders. Nat. Rev. Neurosci., 8, 413–426. Kugaya, A. and Sanacora, G. (2005) Beyond monoamines: glutamatergic function in mood disorders. CNS Spectr., 10, 808–819. Maeng, S. and Zarate, C.A. Jr (2007) The role of glutamate in mood disorders: results from the ketamine in major depression study and the presumed cellular mechanism underlying its antidepressant effects. Curr. Psychiatry Rep., 9, 467–474. Emrich, H.M., von Zerssen, D., Kissling, W. et al. (1980) Effect of sodium valproate on mania. The GABA-hypothesis of affective disorders. Arch. Psychiatr. Nervenkr., 229, 1–16.
135. Brambilla, P., Perez, J., Barale, F. et al. (2003) GABAergic dysfunction in mood disorders. Mol. Psychiatry, 8, 721–737. 715. 136. Rajkowska, G. and Miguel-Hidalgo, J.J. (2007) Gliogenesis and glial pathology in depression. CNS Neurol. Disord. Drug Targets, 6, 219–233. 137. Sanacora, G. and Saricicek, A. (2007) GABAergic contributions to the pathophysiology of depression and the mechanism of antidepressant action. CNS Neurol. Disord. Drug Targets, 6, 127–140. 138. Paredes, R.G. and Agmo, A. (1992) GABA and behavior: the role of receptor subtypes. Neurosci. Biobehav. Rev., 16, 145–170. 139. Rothman, S.M. and Olney, J.W. (1986) Glutamate and the pathophysiology of hypoxic–ischemic brain damage. Ann. Neurol., 19, 105–111. 140. Rothstein, J.D., Jin, L., Dykes-Hoberg, M. and Kuncl, R.W. (1993) Chronic inhibition of glutamate uptake produces a model of slow neurotoxicity. Proc. Natl. Acad. Sci. USA, 90, 6591–6595. 141. Tanaka, K. (2000) Functions of glutamate transporters in the brain. Neurosci. Res., 37, 15–19. 142. OShea, R.D. (2002) Roles and regulation of glutamate transporters in the central nervous system. Clin. Exp. Pharmacol. Physiol., 29, 1018–1023. 143. Lipton, P. (1999) Ischemic cell death in brain neurons. Physiol. Rev., 79, 1431–1568. 144. Chuang, D.M., Chen, R.W., Chalecka-Franaszek, E. et al. (2002) Neuroprotective effects of lithium in cultured cells and animal models of diseases. Bipolar Disord., 4, 129–136. 145. Stone, J.M., Morrison, P.D. and Pilowsky, L.S. (2007) Glutamate and dopamine dysregulation in schizophrenia–a synthesis and selective review. J. Psychopharmacol., 21, 440–452. 146. Conn, P.J. and Pin, J.P. (1997) Pharmacology and functions of metabotropic glutamate receptors. Annu. Rev. Pharmacol. Toxicol., 37, 205–237. 147. Ishii, T., Moriyoshi, K., Sugihara, H. et al. (1993) Molecular characterization of the family of the N-methyl-D-aspartate receptor subunits. J. Biol. Chem., 268, 2836–2843. 148. Seeburg, P.H. (1993) The TINS/TiPS Lecture. The molecular biology of mammalian glutamate receptor channels. Trends Neurosci., 16, 359–365. 149. Wang, J.Q., Arora, A., Yang, L. et al. (2005) Phosphorylation of AMPA receptors: mechanisms and synaptic plasticity. Mol. Neurobiol., 32, 237–249. 150. Tsien, J.Z. (2000) Linking Hebbs coincidence-detection to memory formation. Curr. Opin. Neurobiol., 10, 266–273. 151. Ehlers, M.D. (1999) Synapse structure: glutamate receptors connected by the shanks. Curr. Biol., 9, R848–850. 152. Sans, N., Prybylowski, K., Petralia, R.S. et al. (2003) NMDA receptor trafficking through an interaction between PDZ proteins and the exocyst complex. Nat. Cell Biol., 5, 520–530. 153. Wenthold, R.J., Prybylowski, K., Standley, S. et al. (2003) Trafficking of NMDA receptors. Annu. Rev. Pharmacol. Toxicol., 43, 335–358. 154. Hendry, S.H., Schwark, H.D., Jones, E.G. and Yan, J. (1987) Numbers and proportions of GABA-immunoreactive
Neurotransmitter Systems
155.
156.
157.
158.
159.
160.
161.
162.
163.
164.
165.
166.
167.
168.
169.
170.
neurons in different areas of monkey cerebral cortex. J. Neurosci., 7, 1503–1519. Hassel, B., Johannessen, C.U., Sonnewald, U. and Fonnum, F. (1998) Quantification of the GABA shunt and the importance of the GABA shunt versus the 2-oxoglutarate dehydrogenase pathway in GABAergic neurons. J. Neurochem., 71, 1511–1518. Higo, S., Udaka, N. and Tamamaki, N. (2007) Long-range GABAergic projection neurons in the cat neocortex. J. Comp. Neurol., 503, 421–431. Jones, E.G. (1987) Ascending inputs to, and internal organization of, cortical motor areas. Ciba Found. Symp., 132, 21–39. Benes, F.M. (1997) The role of stress and dopamine-GABA interactions in the vulnerability for schizophrenia. J. Psychiatr. Res., 31, 257–275. Jones, T.H., Brown, B.L., Cullen, D.R. and Dobson, P.R. (1992) Effect of the GABAA agonist muscimol on prolactin secretion from human prolactin-secreting adenomas and GH3 rat pituitary tumour cells. Horm. Res., 37, 113–118. Ladera, C., del Carmen Godino, M., Jose Cabanero, M. et al. (2008) Pre-synaptic GABA receptors inhibit glutamate release through GIRK channels in rat cerebral cortex. J. Neurochem., 107, 1506–1517. Lee, F.J., Wang, Y.T. and Liu, F. (2005) Direct receptor cross-talk can mediate the modulation of excitatory and inhibitory neurotransmission by dopamine. J. Mol. Neurosci., 26, 245–252. Verkuyl, J.M., Karst, H. and Joels, M. (2005) GABAergic transmission in the rat paraventricular nucleus of the hypothalamus is suppressed by corticosterone and stress. Eur. J. Neurosci., 21, 113–121. Erlander, M.G., Tillakaratne, N.J., Feldblum, S. et al. (1991) Two genes encode distinct glutamate decarboxylases. Neuron., 7, 91–100. Martin, D.L. and Rimvall, K. (1993) Regulation of gammaaminobutyric acid synthesis in the brain. J. Neurochem., 60, 395–407. Conti, F., Minelli, A. and Melone, M. (2004) GABA transporters in the mammalian cerebral cortex: localization, development and pathological implications. Brain Res. Brain Res. Rev., 45, 196–212. Sarup, A., Larsson, O.M. and Schousboe, A. (2003) GABA transporters and GABA-transaminase as drug targets. Curr. Drug Targets CNS Neurol. Disord., 2, 269–277. Petroff, O.A., Rothman, D.L., Behar, K.L. et al. (1996) Human brain GABA levels rise rapidly after initiation of vigabatrin therapy. Neurology, 47, 1567–1571. Zwanzger, P. and Rupprecht, R. (2005) Selective GABAergic treatment for panic? Investigations in experimental panic induction and panic disorder. J. Psychiatry Neurosci., 30, 167–175. Palomino, A., Gonzalez-Pinto, A., Aldama, A. et al. (2007) Decreased levels of plasma glutamate in patients with firstepisode schizophrenia and bipolar disorder. Schizophr. Res., 95, 174–178. Frye, M.A., Tsai, G.E., Huggins, T. et al. (2007) Low cerebrospinal fluid glutamate and glycine in refractory affective disorder. Biol. Psychiatry, 61, 162–166.
|
225
171. Levine, J., Panchalingam, K., Rapoport, A. et al. (2000) Increased cerebrospinal fluid glutamine levels in depressed patients. Biol. Psychiatry, 47, 586–593. 172. Altamura, C.A., Mauri, M.C., Ferrara, A. et al. (1993) Plasma and platelet excitatory amino acids in psychiatric disorders. Am. J. Psychiatry, 150, 1731–1733. 173. Hoekstra, R., Fekkes, D., Loonen, A.J. et al. (2006) Bipolar mania and plasma amino acids: increased levels of glycine. Eur. Neuropsychopharmacol., 16, 71–77. 174. Berrettini, W.H., Nurnberger, J.I. Jr, Hare, T.A. et al. (1983) Reduced plasma and CSF gamma-aminobutyric acid in affective illness: effect of lithium carbonate. Biol. Psychiatry, 18, 185–194. 175. Berrettini, W.H., Nurnberger, J.I. Jr, Hare, T.A. et al. (1986) CSF GABA in euthymic manic-depressive patients and controls. Biol. Psychiatry, 21, 844–846. 176. Post, R.M., Ballenger, J.C., Hare, T.A. and Bunney, W.E. Jr (1980) Lack of effect of carbamazepine on gamma-aminobutyric acid in cerebrospinal fluid. Neurology, 30, 1008–1011. 177. Berrettini, W.H., Nurnberger, J.I. Jr, Hare, T. et al. (1982) Plasma and CSF GABA in affective illness. Br. J. Psychiatry, 141, 483–487. 178. Petty, F., Kramer, G.L., Fulton, M. et al. (1993) Low plasma GABA is a trait-like marker for bipolar illness. Neuropsychopharmacology, 9, 125–132. 179. Beneyto, M., Kristiansen, L.V., Oni-Orisan, A. et al. (2007) Abnormal glutamate receptor expression in the medial temporal lobe in schizophrenia and mood disorders. Neuropsychopharmacology, 32, 1888–1902. 180. Beneyto, M. and Meador-Woodruff, J.H. (2008) Laminaspecific abnormalities of NMDA receptor-associated postsynaptic protein transcripts in the prefrontal cortex in schizophrenia and bipolar disorder. Neuropsychopharmacology, 33, 2175–2186. 181. Fatemi, S.H., Stary, J.M., Earle, J.A. et al. (2005) GABAergic dysfunction in schizophrenia and mood disorders as reflected by decreased levels of glutamic acid decarboxylase 65 and 67 kDa and Reelin proteins in cerebellum. Schizophr. Res., 72, 109–122. 182. Woo, T.U., Walsh, J.P. and Benes, F.M. (2004) Density of glutamic acid decarboxylase 67 messenger RNA-containing neurons that express the N-methyl-D-aspartate receptor subunit NR2A in the anterior cingulate cortex in schizophrenia and bipolar disorder. Arch. Gen. Psychiatry, 61, 649–657. 183. Scarr, E., Pavey, G., Sundram, S. et al. (2003) Decreased hippocampal NMDA, but not kainate or AMPA receptors in bipolar disorder. Bipolar Disord., 5, 257–264. 184. McCullumsmith, R.E., Kristiansen, L.V., Beneyto, M. et al. (2007) Decreased NR1, NR2A, and SAP102 transcript expression in the hippocampus in bipolar disorder. Brain Res., 1127, 108–118. 185. Toro, C. and Deakin, J.F. (2005) NMDA receptor subunit NRI and postsynaptic protein PSD-95 in hippocampus and orbitofrontal cortex in schizophrenia and mood disorder. Schizophr. Res., 80, 323–330. 186. Kristiansen, L.V. and Meador-Woodruff, J.H. (2005) Abnormal striatal expression of transcripts encoding NMDA
226
187.
188.
189.
190.
191.
192.
193.
194.
195.
196.
197. 198.
199.
200.
201.
202.
|
Chapter 16
interacting PSD proteins in schizophrenia, bipolar disorder and major depression. Schizophr. Res., 78, 87–93. Clinton, S.M. and Meador-Woodruff, J.H. (2004) Abnormalities of the NMDA receptor and associated intracellular molecules in the thalamus in schizophrenia and bipolar disorder. Neuropsychopharmacology, 29, 1353–1362. Torrey, E.F., Barci, B.M., Webster, M.J. et al. (2005) Neurochemical markers for schizophrenia, bipolar disorder, and major depression in postmortem brains. Biol. Psychiatry, 57, 252–260. Benes, F.M., Todtenkopf, M.S. and Kostoulakos, P. (2001) GluR5,6,7 subunit immunoreactivity on apical pyramidal cell dendrites in hippocampus of schizophrenics and manic depressives. Hippocampus, 11, 482–491. Grateron, L., Cebada-Sanchez, S., Marcos, P. et al. (2003) Postnatal development of calcium-binding proteins immunoreactivity (parvalbumin, calbindin, calretinin) in the human entorhinal cortex. J. Chem. Neuroanat., 26, 311–316. Beasley, C.L., Zhang, Z.J., Patten, I. and Reynolds, G.P. (2002) Selective deficits in prefrontal cortical GABAergic neurons in schizophrenia defined by the presence of calcium-binding proteins. Biol. Psychiatry, 52, 708–715. Rajkowska, G., ODwyer, G., Teleki, Z. et al. (2007) GABAergic neurons immunoreactive for calcium binding proteins are reduced in the prefrontal cortex in major depression. Neuropsychopharmacology, 32, 471–482. DArcangelo, G., Miao, G.G., Chen, S.C. et al. (1995) A protein related to extracellular matrix proteins deleted in the mouse mutant reeler. Nature, 374, 719–723. Guidotti, A., Auta, J., Davis, J.M. et al. (2000) Decrease in reelin and glutamic acid decarboxylase67 (GAD67) expression in schizophrenia and bipolar disorder: a postmortem brain study. Arch. Gen. Psychiatry, 57, 1061–1069. Heckers, S., Stone, D., Walsh, J. et al. (2002) Differential hippocampal expression of glutamic acid decarboxylase 65 and 67 messenger RNA in bipolar disorder and schizophrenia. Arch. Gen. Psychiatry, 59, 521–529. Todtenkopf, M.S. and Benes, F.M. (1998) Distribution of glutamate decarboxylase65 immunoreactive puncta on pyramidal and nonpyramidal neurons in hippocampus of schizophrenic brain. Synapse, 29, 323–332. You, L. and Yin, J. (2000) Patterns of regulation from mRNA and protein time series. Metab. Eng., 2, 210–217. Mulholland, P.J. and Chandler, L.J. (2007) The thorny side of addiction: adaptive plasticity and dendritic spines. ScientificWorld J., 7, 9–21. Konarski, J.Z., McIntyre, R.S., Soczynska, J.K. and Kennedy, S.H. (2007) Neuroimaging approaches in mood disorders: technique and clinical implications. Ann. Clin. Psychiatry, 19, 265–277. Dager, S.R., Friedman, S.D., Parow, A. et al. (2004) Brain metabolic alterations in medication-free patients with bipolar disorder. Arch. Gen. Psychiatry, 61, 450–458. Michael, N., Erfurth, A. and Pfleiderer, B. (2009) Elevated metabolites within dorsolateral prefrontal cortex in rapid cycling bipolar disorder. Psychiatry Res., Apr 30; 172 (1), 78–81. Castillo, M., Kwock, L., Courvoisie, H. and Hooper, S.R. (2000) Proton MR spectroscopy in children with bipolar
203.
204.
205.
206.
207. 208.
209.
210.
211.
212.
213.
214.
215. 216.
217.
218. 219.
220.
affective disorder: preliminary observations. AJNR Am. J. Neuroradiol., 21, 832–838. Michael, N., Erfurth, A., Ohrmann, P. et al. (2003) Acute mania is accompanied by elevated glutamate/glutamine levels within the left dorsolateral prefrontal cortex. Psychopharmacology (Berl.), 168, 344–346. Bhagwagar, Z., Wylezinska, M., Jezzard, P. et al. (2007) Reduction in occipital cortex gamma-aminobutyric acid concentrations in medication-free recovered unipolar depressed and bipolar subjects. Biol. Psychiatry, 61, 806–812. Colla, M., Schubert, F., Bubner, M. et al. (2009) Glutamate as a spectroscopic marker of hippocampal structural plasticity is elevated in long-term euthymic bipolar patients on chronic lithium therapy and correlates inversely with diurnal cortisol. Mol. Psychiatry, Jul; 14 (7), 696–704, 647. Kaufman, R.E., Ostacher, M.J., Marks, E.H. et al. (2009) Brain GABA levels in patients with bipolar disorder. Prog. Neuropsychopharmacol. Biol. Psychiatry, Apr 30; 33 (3), 427–434. Tsai, G. and Coyle, J.T. (1995) N-acetylaspartate in neuropsychiatric disorders. Prog. Neurobiol., 46, 531–540. Stork, C. and Renshaw, P.F. (2005) Mitochondrial dysfunction in bipolar disorder: evidence from magnetic resonance spectroscopy research. Mol. Psychiatry, 10, 900–919. Kim, D.J., Lyoo, I.K., Yoon, S.J. et al. (2007) Clinical response of quetiapine in rapid cycling manic bipolar patients and lactate level changes in proton magnetic resonance spectroscopy. Prog. Neuropsychopharmacol. Biol. Psychiatry, 31, 1182–1188. Malhi, G.S., Ivanovski, B., Wen, W. et al. (2007) Measuring mania metabolites: a longitudinal proton spectroscopy study of hypomania. Acta Psychiatr. Scand, (Suppl), 57–66. Schiffer, H.H. (2002) Glutamate receptor genes: susceptibility factors in schizophrenia and depressive disorders? Mol. Neurobiol., 25 (2), 191–212. Chen, Y.S., Akula, N., Detera-Wadleigh, S.D. et al. (2004) Findings in an independent sample support an association between bipolar affective disorder and the G72/G30 locus on chromosome 13q33. Mol. Psychiatry, 9 (1), 87–92. Hattori, E., Liu, C., Badner, J.A. et al. (2003) Polymorphisms at the G72/G30 gene locus, on 13q33, are associated with bipolar disorder in two independent pedigree series. Am. J. Hum. Genet., 72 (5), 1131–1140. Kasckow, J.W., Aguilera, G., Mulchahey, J.J. et al. (2003) In vitro regulation of corticotropin-releasing hormone. Life Sci., 73, 769–781. Lightman, S.L. (2008) The neuroendocrinology of stress: a never ending story. J. Neuroendocrinol., 20, 880–884. Daban, C., Vieta, E., Mackin, P. and Young, A.H. (2005) Hypothalamic-pituitary-adrenal axis and bipolar disorder. Psychiatr. Clin. North Am., 28, 469–480. Holsboer, F. and Ising, M. (2008) Central CRH system in depression and anxiety–evidence from clinical studies with CRH1 receptor antagonists. Eur. J. Pharmacol., 583, 350–357. Selye, H. (1985) The nature of stress. Basal Facts, 7, 3–11. Valdez, G.R. (2006) Development of CRF1 receptor antagonists as antidepressants and anxiolytics: progress to date. CNS Drugs, 20, 887–896. Pariante, C.M. (2004) Glucocorticoid receptor function in vitro in patients with major depression. Stress, 7, 209–219.
Neurotransmitter Systems 221. McEwen, B.S. (2005) Glucocorticoids, depression, and mood disorders: structural remodeling in the brain. Metabolism, 54, 20–23. 222. Sapolsky, R.M. (2000) The possibility of neurotoxicity in the hippocampus in major depression: a primer on neuron death. Biol. Psychiatry, 48, 755–765. 223. Holsboer, F., Lauer, C.J., Schreiber, W. and Krieg, J.C. (1995) Altered hypothalamic-pituitary-adrenocortical regulation in healthy subjects at high familial risk for affective disorders. Neuroendocrinology, 62, 340–347. 224. Schmider, J., Lammers, C.H., Gotthardt, U. et al. (1995) Combined dexamethasone/corticotropin-releasing hormone test in acute and remitted manic patients, in acute depression, and in normal controls: I. Biol. Psychiatry, 38, 797–802. 225. Watson, S., Gallagher, P., Ritchie, J.C. et al. (2004) Hypothalamic-pituitary-adrenal axis function in patients with bipolar disorder. Br. J. Psychiatry, 184, 496–502. 226. Webster, M.J., Knable, M.B., OGrady, J. et al. (2002) Regional specificity of brain glucocorticoid receptor mRNA alterations in subjects with schizophrenia and mood disorders. Mol. Psychiatry, 7, 924, 985–994. 227. Xing, G.Q., Russell, S., Webster, M.J. and Post, R.M. (2004) Decreased expression of mineralocorticoid receptor mRNA in the prefrontal cortex in schizophrenia and bipolar disorder. Int. J. Neuropsychopharmacol., 7, 143–153. 228. Herringa, R.J., Roseboom, P.H. and Kalin, N.H. (2006) Decreased amygdala CRF-binding protein mRNA in postmortem tissue from male but not female bipolar and schizophrenic subjects. Neuropsychopharmacology, 31, 1822–1831. 229. Raadsheer, F.C., Hoogendijk, W.J., Stam, F.C. et al. (1994) Increased numbers of corticotropin-releasing hormone expressing neurons in the hypothalamic paraventricular nucleus of depressed patients. Neuroendocrinology, 60, 436–444. 230. Zhou, R., Gray, N.A., Yuan, P. et al. (2005) The Anti-Apoptotic, glucocorticoid receptor cochaperone protein BAG-1 is a long-term target for the actions of mood stabilizers. J. Neurosci., 25, 4493–4502. 231. Maeng, S., Hunsberger, J.G., Pearson, B. et al. (2008) BAG1 plays a critical role in regulating recovery from both maniclike and depression-like behavioral impairments. Proc. Natl. Acad. Sci., USA, 105, 8766–8771.
|
227
232. Hendrick, V., Altshuler, L. and Whybrow, P. (1998) Psychoneuroendocrinology of mood disorders. The hypothalamic-pituitary-thyroid axis. Psychiatr. Clin. North Am., 21, 277–292. 233. Heilig, M., Koob, G.F., Ekman, R. and Britton, K.T. (1994) Corticotropin-releasing factor and neuropeptide Y: role in emotional integration. Trends Neurosci., 17, 80–85. 234. Michel, M.C. (1991) Receptors for neuropeptide Y: multiple subtypes and multiple second messengers. Trends Pharmacol. Sci., 12, 389–394. 235. Kask, A., Harro, J., von Horsten, S. et al. (2002) The neurocircuitry and receptor subtypes mediating anxiolytic-like effects of neuropeptide Y. Neurosci. Biobehav. Rev., 26, 259–283. 236. Karl, T. and Herzog, H. (2007) Behavioral profiling of NPY in aggression and neuropsychiatric diseases. Peptides, 28, 326–333. 237. El Khoury, A. and Mathe, A.A. (2004) Neuropeptide y in euthymic lithium-treated women with bipolar disorder. Neuropsychobiology, 50, 239–243. 238. Caberlotto, L. and Hurd, Y.L. (1999) Reduced neuropeptide Y mRNA expression in the prefrontal cortex of subjects with bipolar disorder. Neuroreport, 10, 1747–1750. 239. Lieb, K., Treffurth, Y., Berger, M. and Fiebich, B.L. (2002) Substance P and affective disorders: new treatment opportunities by neurokinin 1 receptor antagonists? Neuropsychobiology, 45 (Suppl 1), 2–6. 240. Burnet, P.W. and Harrison, P.J. (2000) Substance P (NK1) receptors in the cingulate cortex in unipolar and bipolar mood disorder and schizophrenia. Biol. Psychiatry, 47, 80–83. 241. Berrettini, W.H., Rubinow, D.R., Nurnberger, J.I. Jr et al. (1985) CSF substance P immunoreactivity in affective disorders. Biol. Psychiatry, 20, 965–970. 242. Rubinow, D.R. (1986) Cerebrospinal fluid somatostatin and psychiatric illness. Biol. Psychiatry, 21, 341–365. 243. Sharma, R.P., Bissette, G., Janicak, P.G. et al. (1995) Elevation of CSF somatostatin concentrations in mania. Am. J. Psychiatry, 152, 1807–1809. 244. McClung, C.A. (2007) Role for the Clock gene in bipolar disorder. Cold Spring Harb. Symp. Quant. Biol., 72, 637–644.
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Molecular Biology of Bipolar Disorder Ana Andreazza, Jun Feng Wang and Trevor Young Department of Psychiatry, University of British Columbia, Vancouver, Canada
Introduction Bipolar disorder (BD) is a common, chronic, recurrent mental illness with an estimated prevalence of about 1–3% of the worldwide population [1–3]. A growing number of studies have found impaired cognitive functions in BD patients that are present even after remission of symptoms [4–6], suggesting that BD may be associated with persistent cognitive dysfunction. Furthermore, BD is a systemic disease that is frequently associated with a wide range of physiological perturbations and medical problems, including cardiovascular disease, diabetes mellitus, obesity and thyroid disease [1,7], which is directly associated with increased morbidity and mortality observed in this disorder. Despite decades of extensive genetic and pharmacological studies, the aetiology and pathophysiology of this disorder remain unclear. Neurobiological studies of mood disorders over the past 40 years have focused on neuroanatomical and neurotransmitter abnormalities [8,9]. Neuroimaging and postmortem brain studies have detected that critical neural circuit modulating emotional behaviours are disturbed in BD. These include a significantly decrease in number or density of neurons in several brain areas, such as prefrontal cortex [10,11], anterior cingulate cortex [12], hippocampal corpus ammonius (CA2) [13], hypothalamic paraventricular nucleus [14] and amygdala [15]. In addition, several studies have also reported low glial cell number in the prefrontal cortex from subjects with BD [10,16]. Thus, postmortem studies have suggested that BD might be associated with neuronal and glial cell loss in specific brain areas, supporting the current hypothesis of altered neuroplasticity and neurotransmitter regulation in BD. This evidence has resulted in a recent burgeoning field of research investigating mechanisms of receptor coupled signal transduction. Intracellular signal transduction pathways are uniquely responsible for coordinating the cellular response to
Bipolar Disorder: Clinical and Neurobiological Foundations Edited by Lakshmi N. Yatham and Mario Maj © 2010 John Wiley & Sons, Ltd. ISBN: 978-0-470-72198-8
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information impinging on the cell from multiple sources and timeframes. It follows that abnormalities in these pathways may lead to functional imbalance in multiple neurotransmitter pathways, which could account for the diverse clinical features found in BD, such as a recurrent course, mood fluctuations, psychotic features, neurovegetative symptoms and cognitive impairment. In fact, the higherorder brain functions, such as behaviour, mood and cognition, are critically dependent on signal transduction processes for their proper functioning [17]. The time lag between the pharmacologic and clinical effects of mood stabilizers also suggests that long-term cellular and molecular events are important in the drugs mechanism of action. Over the past 10 years, studies using animal models, postmortem brain tissue and lymphocytes samples have examined the intracellular signal transduction pathways linked to neurotransmitters to investigate the biological basis of BD. In this chapter, we will review the evidences for abnormalities in signal transduction pathways in BD. We will also discuss how these pathways may be relevant in the treatment of this illness with mood stabilizing medication.
Signal transduction pathways Signal transduction pathways are uniquely responsible for coordinating the cellular response to information impinging on the cell from multiple sources and time frames [17]. These pathways follow a broadly similar course that can be viewed as a molecular circuit, which can detect, amplify and integrate diverse external signals to generate cellular response such as enzyme activity, stimulation of proliferation or cell death and lastly induced gene expression [17]. Abnormalities in these pathways may lead to a functional imbalance in multiple neurotransmitter pathways, which could account for the diverse clinical features found in BD [18]. Most neurotransmitter receptors are coupled to guanine-nucleotide binding proteins (G-protein). These proteins link receptors to specific enzymes that activate second messengers, or alternatively, they link to specific ion channels. Now, the extracellular signals are integrated,
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amplified and transmitted to specific intracellular enzymes, called effectors, which catalyse the production of an extensive array of cascading second messengers. In turn, these messenger molecules act on various protein kinases [17]. The activation of these kinases is instrumental in regulating diverse intracellular processes, including gene expression, and in relating these to lasting neurobiological changes [17]. The number of findings for abnormalities in signal transduction systems in samples obtained directly from patients is growing. Indeed, animal and cell culture studies have demonstrated pharmacological effects of mood stabilizers, especially lithium, suggesting its role in neuroprotection, which range from reducing excitotoxicity through increased glutamate uptake, to regulation of a number of second messenger systems, such as adenylate cyclase (cyclic adenosine monophosphate, cAMP), phosphoinositide (PI), protein kinase C (PKC), protein kinase A (PKA), protein kinase B (AKT) and glycogen synthase kinase-3 (GSK-3) [19]. The next sections of this chapter will characterize, define and describe the alterations in signalling transduction pathways in BD. We begin by examining the membrane receptor and how they are activated by external factors. Then, we will review the second messengers that relay information from the receptor-ligand complex. Lastly, we will discuss how the second messengers transduce this information to gene expression.
Membrane receptors and their coupling to signal transduction pathways Most signal transduction involves binding of extracellular signalling molecules (or ligands) to membrane receptors to transfer the information from the environment to the cells interior. One of the most common types of signal transduction pathways involves modulating adenylyl cyclase via GTP-binding proteins, more commonly known as G proteins [17]. G-protein coupled receptors play a critical role in BD, since the monoaminergic receptors are coupled to G protein. The tyrosine kinase receptors (TRK) also have an important role in BD, owing to bind growth factors that actives a neurotrophic cascade.
G-Proteins coupled receptors in BD G-proteins are an integral part of the intracellular signalling pathway, in that they link receptors in the membrane to diverse intracellular effectors molecules and responses (Figure 1). G proteins consist of three subunits: an a subunit that binds and hydrolyzes guanosine triphosphate (GTP), and b and g subunits that are tightly bound to one another [20]. This heterogeneous protein structure allows for the coupling of a wide variety of receptors to the same or different signal transduction systems, leading to nearly infi-
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nite combinations. Even modest changes in the levels of the G proteins have the potential to markedly alter the orderly progression of events from the membrane receptors to their intracellular targets. Stimulation of GPCR causes dissociation of G-protein subunits following the binding of GTP to Ga; this can subsequently result in the activation of distinct Gaand Gbg-sensitive isoforms of adenylate cyclase, phospholipase C (PLC) and other second messengers (see Figure 1). The interaction between GPCRs and the large number of different G-protein subunits can potentially be quite diverse, as one GPCR is capable of interacting with more than one G protein to result in multifunctional signalling [21,22]. The interest in studying G proteins in BD was largely prompted by animal studies. These studies found that lithium attenuates the function of several G proteins, including the stimulatory subtype (Gas) (for review see [23]). Gas levels (but not Gai, Gaq or Gb) have been described as increased in frontal, temporal and occipital cortex from patients with BD [24–26]. Furthermore, in the same samples, [25] showed increased activity of adenylate cyclase (AC), which correlate with the increased Gas levels, denoting a functional relevance. Using [[35]S]GTPgS binding, a specific binding assay for G proteins, Friedman and Wang [26] showed that brain membrane from patients with BD has enhanced 5-HT receptor-G-protein coupling. Dowlatshahi et al. [27] demonstrated decreased occipital cortex Gas levels in subjects with BD treated with lithium (Table 1). Studies in peripheral cells have showed the same results as postmortem tissue in patients with BD. Increased Gas levels have been found in mononuclear leucocytes (MNLs) from unmedicated patients with BD [30,31]. Supporting the hypothesis that G-protein coupling may be linked to mood state, several studies have demonstrated increased coupling levels during mania [32,33]. Avissar et al. [33] showed elevations to Gas and Gai levels in MNLs of patients with BD during mania and decreased levels during depression. In addition, Schreiber et al. [32] reported enhanced binding of [[3]H]Gpp(NH)p in MNLs of patients with mania, implicating increased G-protein levels and enhanced receptormediated G-protein activation in this patient group. More recently, Hahn et al. [34] demonstrated elevated [35S]GTPgS binding to platelet membrane Gas, Gai and Gaq/11 subunits in patients with BD during the manic phase. Increased levels of Gas 45- and Gas 52-kDa were reported in platelets of patients with BD in euthymia [35]. On the other hand, Alda et al. [36] measured Gas levels in transformed lymphoblasts from lithium-responsive patients with BD but did not find differences, compared with control subjects. This suggests that mood state may be an important factor in determining changes to Gas levels in blood cells from patients with BD (Table 1). Linkage studies in BD to the gene coding for Gas have yielded negative results [37–40] and, similarly, the
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Fig. 1 Signalling transduction pathways in Bipolar Disorder. Activation of stimulatory G-protein alpha subunits (Gas) leads to binding and activation of adenyl cyclase (AC), which in turn catalyzes the conversion of ATP into cAMP). The major target for cAMP is the protein kinase A (PKA). Once PKA is activated, it phosphorylates a number of other proteins including transcription factors, which regulate gene expression. G-protein isoforms Gq/G11 promotes activation of the phosphatidylinositol-specific phospholipase-b (PLC-b) enzyme PLC in turn catalyses the hydrolysis of the inositol-containing phospholipid phosphatidylinositol 4,5-bisphosphate (PIP2) into two second messengers: inositol 1,4,5-trisphosphate (IP3) and 1,2-diacylglycerol (DAG). IP3 binds to an IP3-specific receptor on the endoplasmic reticulum surface and stimulates the release of intracellularstored Ca2 þ . The transcription factors CREB suffer phophorylation by Ca2 þ which promotes transcriptional activation of gene expression. DAG, on the other hand, activates >PKC. PKC is involved in phosphorylating other proteins in the cell, such as GSK-3b. The Wnt protein bind to the frizzled receptors, and result in inhibits GSK-3b through dishevelled protein. GSK-3b inhibition promotes activation of b-catenin transcription factors. The last pathway showed in this figure is the tyrosine kinase recptors (TRK). Trk receptor activation promote RAS pathway activation which ultimate regulate gene expression by interaction with transcription factors, that is, CREB and b-catenin.
gene-expression levels of Gas do not appear to be altered in BD postmortem brain [28]. However, there is evidence suggesting abnormalities in the coupling of neurotransmitter receptors to the G-protein signal pathways [41]. Overactivation of G-protein-coupled serotonergic (reviewed by Catapano and Manji [42]) and dopaminergic receptors [43,44] have been described in patients with BD. Indeed, studies have identified an association between the serotonergic 5HT2A receptor polymorphisms and BD and have demonstrated that the most common polymorphism associated with BD is the C516T, C135T and A-1438G [45–47].
Interestingly, abnormalities in the 5HT1A receptor binding in BD patients are normalized with chronic lithium administration [8]. The G-protein coupled dopaminergic receptors, D1 and D2, may also be associated with BD, supported by the association between the illness and the D1 receptors A48G polymorphism [48]. Massat et al. [49] found a significant association between D2 receptor and BD. Another receptor that has been received attention in BD is the G-protein receptor kinase 3 (GRK3). A recent study demonstrated significantly decreased protein and mRNA levels
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Table 1 G protein signalling in bipolar disorder. Samples
Findings
Reference
Postmortem brain Cerebral cortex
" Gas, $ Gai, Gaq, Gb $ Gas mRNA levels " coupling of 5-HT receptors to membrane of G-proteins # Gas in lithium-treated subjects # Gb, Gg and GRK3 " 3[H]Gpp(NH)p binding in patients during mania " Gas levels in unmedicated depressed patients " Gas and Gai levels in patients during mania # Gas and Gai levels in patients during depression " Gas mRNA levels in unmedicated patients " Gas 45- and Gas 52-kDa in patient in euthymia " [35S]GTPgS binding to Gas, Gai and Gaq/11 $ Gas levels in lithium-responsive patients
[24,25] [28] [26] [27] [29] [32] [31] [33]
Leukocytes
Platelets Transformed lymphoblast a
[30] [35] [34] [36]
" – increased levels, # – decreased levels and $ no alteration in relation to healthy control group.
of G-protein b3, G-protein g and GRK3 in postmortem prefrontal cortex of BD compared to control subjects [29]. The same study did not find significant group differences in the protein or mRNA levels of GRK2. GRK3 protein levels were also investigated in lymphoblatoid cell lines derived from patients with BD, these patients showed decreased GRK3 levels and these decreases correlated with disease severity [50]. Taken together, there is considerable evidence, both conceptually and experimentally, that supports altered Ga levels and function, or both. This could occur through increased receptor G-protein coupling and could play an important role in the biological basis of BD.
Tyrosine kinase receptor TRKs are transmembrane proteins with an intracellular kinase domain and an extracellular domain that binds ligand. There are many TRK proteins -at are classified into subfamilies, depending on their structural properties and ligand specificity [51–53]. These include many growth factor receptors, such as nerve insuline-like growth factor (IGF) and brain-derived neurotrophic factor (BDNF) receptors. To conduct their biochemical signals, TRK need to be activated by binding of specific ligands such as growth factor. Interaction between the receptor and the ligand stimulate autophosphorylation of tyrosines within the cytoplasmic tyrosine kinase domains of the TRKs, causing their conformational changes. The kinase domain of the receptors is subsequently activated, initiating signalling cascades of phosphorylation of downstream cytoplasmic molecules. These signals are essential to various cellular processes, such as control of cell growth, differentiation, metabolism, and migration [51,52]. The function of growth factors is mediated through the activation of TRK [53] as they interact with different sub-
types of TRK. Specifically, nerve growth factor (NGF) binds to TrkA; BDNF and neurotrophin-4 (NT4) bind to TrkB; and neurotrophin-3 (NT3) activates TrkC [53]. The activation of TRK and p75NTR receptors by neurotrophins induces regulation of several signalling pathways. The p75NTR receptor regulates three major signalling pathways: (1) NF-kB activation results in transcription of multiple genes, including several that promote neuronal survival; (2) Activation of the Jun kinase pathway similarly controls activation of several genes, some of which promote neuronal apoptosis; (3) Regulates the activity of Rho, which controls growth cone motility. Trk receptor also controls three major signalling pathways: (1) Activation of Ras results in activation of the MAP kinase-signalling cascade, which promotes neuronal differentiation including neurite outgrowth; (2) Activation of PI3 kinase through Ras or Gab1 promoting survival and growth of neurons and other cells; (3) Activation of phospholipase C g1 (PLC-g1) results in activation of Ca2 þ - and PKC regulating pathways that promote synaptic plasticity. These signalling pathways ultimately regulate gene expression by interaction with transcription factors, that is, CREB and b-catenin [51,53]. Growth factors, especially BDNF, have been extensively studied in BD (for review see [54]). BDNF exerts a role in regulating neuronal survival, structure, function and it is essential to long-term memory [55]. Decreased serum BDNF levels have been reported in BD patients in manic state [56,57] as well as in individuals with depressive symptoms [56]. During euthymia, studies have shown decreased levels [58] and unaltered BDNF levels [56] when compared to control groups. Interestingly, drug-free and medicated patients with BD showed decreased serum levels of BDNF, and these results may suggest that the association of lower serum BDNF and BD is maintained throughout pharmacotherapy, which strengthens the notion that BDNF serum levels may
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be considered a biomarker of mood episodes in BD [59]. Supporting the role of BDNF in BD, Dunham et al. [60] reported decreased expression of (pro)BDNF in hippocampus from subjects with BD or major depression. Another important factor that contributes to decreases in the expression of BDNF is ageing [61], which can contribute to age-related cognitive impairments [62]. Recent findings from our group showed accelerated age-related decreases in BDNF levels in patients with BD, in comparison to matched healthy subjects [63]. In addition, Kauer-SantAnna et al. [64] compared BDNF serum levels between early (1–3 years) and late (10–20 years) stage of the disorder, the results showing decreased BDNF levels only in late stage patients, suggesting that BDNF could be associated with illness progression. Furthermore, an accelerated ageing process has been suggested to occur in BD, as indicated by the alterations in diverse oxidative stress parameters [65–71].
Second messengers After the binding of signal proteins in the receptor, a second messenger is activated. This is responsible to amplify the stimulus and initiates a cells response cascade [17]. Second messengers include cAMP, PKA, PI, Ca2 þ , PKC and GSK-3, which typically modulate the phosphorylation state of intracellular proteins, which in turn regulate neuronal function [20]. Several studies have showed alterations in activity or levels of second messengers in BD, described below. We also have summarize this pathway in Figure 1 and the findings in BD in Tables 2–4.
The cAMP and PKA pathway One well characterized signal transduction pathway is the activation of stimulatory G-protein alpha subunits (Gas) that leads to the binding and activation of adenyl cyclase
(AC), which in turn catalyses the conversion of ATP into cAMP [20,99]. The major target for cAMP is another enzyme, cAMP-dependent protein kinase, also known as PKA (see Figure 1). Once PKA is activated, it phosphorylates a number of other proteins, including transcription factors, which regulate gene expression. This pathway is a critical step in linking short-term changes in neurotransmitter signalling to lasting neurobiological changes [100]. Several studies have reported that basal and receptoractivated AC activities are increased in patients with BD; these findings are summarized in Table 2. Postmortem brain studies of patients with BD identified increased levels of postreceptor stimulated AC activity [72] and increased levels of forskolin-stimulated cAMP production [24,25]. Studies in peripheral mononuclear cells from patients with BD suggest that there are changes in receptor and/or postreceptor sensitivity in the cAMP system without alterations to cell receptor number (reviewed by [101]). In platelet samples from treated euthymic bipolar patients, cAMPstimulated phosphorylation of Rap-1, a cAMP substrate was increased when compared to healthy subjects [76]. Interestingly, Zanardi et al. [102] showed increased basal and cAMP-stimulated protein phosphorylation after lithium treatment. Studies evaluating patients with BD in various mood states before and after treatment also have evidenced increased levels and activity of PKA, a major target for cAMP [77,78,103]. PKA activity was found increased in the temporal cortex of patients with BD [73]. Subsequent analysis of the specific PKA subunits suggests that elevated PKA activity in BD results from a state-related imbalance in the specific PKA subunits [75]. Platelets from both unmedicated euthymic and depressed patients with BD have been shown to have higher cAMP-stimulated PKA activity in comparison to healthy controls [77]. Increased levels of the PKA
Table 2 cAMP and PKA signalling in bipolar disorder. Samples
Findings
Reference
Postmortem brain Cerebral cortex
" AC activity
[72]
" fosfokolin-stimulated cAMP production " PKA levels in temporal cortex # [3 H]cAMP binding to PKA " Maximal and basal cAMP-dependent PKA activity and # PKA EC50 " PKA catalytic subunit in mania and depression, but not in euthymia. " Rap1 in mania, depression and euthymia " cAMP-stimulated PKA activity in unmedicated euthymic and depressed bipolar patients have significantly higher " PKA catalytic subunit and # [3 H]cAMP binding " basal PKA activity " PKA catalytic subunit levels
[24,25] [73] [74] [75] [76]
Platelets
Transformed lymphoblast a
[77] [89] [78]
" – increased levels, # – decreased levels and $ no alteration in relation to healthy control group.
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Table 3 PI pathway in bipolar disorder. Samples
Findings
Reference
Postmortem brain Cerebral cortex
" levels of Gaq/11 and PLC levels
[79]
" PKC levels # inositol levels in the prefrontal cortex but not in the occiptal or cerebellum # PI-coupled G-protein activation
[80] [81] [82]
Calcium Biopsy-derived Platelets
Calcium Platelets
Serum Calcium Transformed lymphoblast a
# " " # " "
Ca2 þ levels in response to odorant stimulation in olfactory neurons receptor PIP2 levels in patients during depression PKC activity in patients during mania PIP2 levels in lithium-treated patients during euthymia PKC-b1 and -b2 activity and mRNA levels in medication-free paediatric BD Intracellular Ca2 þ
[34] [83] [84] [85–88] [89] [90]
" " " " " #
Intracellular Ca2 þ in patients during mania and depression Thapsigargin-induced cytosolic Ca2 þ total and ionised Ca2 þ levels Basal Ca2 þ levels in patients with BD-1 Ca2 þ mobilisation by LPA stimulation Ca2 þ levels after LPA or Thapsigargin in lithium treated patients
[91] [92–94] [95] [96] [97] [98]
" – increased levels, # – decreased levels and $ no alteration in relation to healthy control group.
catalytic subunit in platelets were found in BD patients in the depressed or manic state compared with euthymic patients or healthy controls [76]. Interestingly, the same study showed that regardless of phase, patients with BD presented increased levels of Rap1, which is a protein substrate of PKA that has a role in regulating cell adhesion [76]. Karege et al. [78] reported that lymphoblast cells from patients with BD present increased PKA activity and reduced [3 H]cAMP binding to PKA regulatory subunits, in comparison with healthy controls. In addition, they reported that measurement of cAMP signalling system activity during PKA activation or inhibition in euthymic BD Table 4 Neurotrophic factors in bipolar disorder. Samples
Findings
Reference
Postmortem brain Hippocampus Serum
# (pro)BDNF and p75 expression
[60]
# BDNF levels in depression and mania $ BDNF levels in euthymia # BDNF unmedicated patients # BDNF levels euthymia # BDNF levels in drug-free and medicated patients # BDNF levels in late stage of the disorder but not in early stage
[56]
a
[57] [58] [59] [64]
" – increased levels, # – decreased levels and $ no alteration in relation to healthy control group.
patients revealed increased basal PKA activity, PKA catalytic subunit levels and enhanced pCREB expression in comparison with controls [104]. These findings support the involvement of cAMP and concomitant PKA activation in BD. Indeed, PKA activation has a relevant role in BD since it phosphorylates a number of other proteins, including transcription factors, which ultimately regulate gene expression and these findings are described below.
The phosphoinositide (PI) pathway Another important signalling pathway that is coupled to neurotransmitter involves the G-protein isoforms Gq/G11, which promotes the activation of phosphatidylinositolspecific phospholipase-b (PLC-b) enzyme [105]. PLC-b in turn catalyses the hydrolysis of the inositol-containing phospholipid phosphatidylinositol 4,5-bisphosphate (PIP2) into two second messengers: inositol 1,4,5-trisphosphate (IP3) and 1,2-diacylglycerol (DAG) (Figure 1) [103]. DAG remains bound to the membrane and IP3 is released as a soluble structure into the cytosol. IP3 then diffuses through the cytosol to bind to IP3-specific receptor on the endoplasmic reticulum (ER) surface and stimulates the release of intracellular-stored Ca2 þ from the smooth ER into the cytosol [106]. Many of Ca2 þ s effects are mediated by the Ca2 þ -binding protein, calmodulin, which then binds to a variety of target proteins, including protein kinases; that is, CaM kinase family (CaMK). CaMK I and IV isoforms are suggested to be involved in mediating transcriptional activation of gene expression, by phosphorylation of transcription factors, such as CREB (revised in [101]). Therefore,
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increment of intracellular Ca2 þ in neurons is directly connected with neurotransmitters release [19]. DAG, on the other hand, activates PKC, which comprises another family of kinases [107]. DAG causes PKC to move from the cytosol to the plasma membrane, where it also binds Ca2 þ and phosphatidylserine, a membrane phospholipid. These events relieve autoinhibition and cause PKC to phosphorylate various protein substrates. PKC also diffuses to sites other than the plasma membrane, such as the cytoskeleton, perinuclear sites and the nucleus [107]. Several studies have demonstrated alterations in the PI pathways in BD (reviewed in [108] and summarized in Table 3). Shimon et al. [81] have shown decreased levels of inositol in the prefrontal cortex but not in the occipital cortex or cerebellum of patients with BD. Increased levels of Gaq/ 11 and PLC [79] and diminished PI-coupled G-protein activation [82] were observed in occipital cortex from patients with BD, suggesting an adaptive increase in Gaq/11 expression as a result of deficient PI-signalling activity in BD [101]. Lymphoblastoid cell and lymphocytes from patients with BD have also demonstrated decreased levels of inositol [109], reduced inositol monophosphatase 2 (IMPA2) mRNA ([110,111] and reduced activity of IMPase [112]. Studies examining the relative content of membrane PIs have focused on the major PLC-b substrate, PIP2. Brown et al. [83] showed increased levels of PIP2 in platelets of patients with BD during depressed phase. Moreover, reduced levels of PIP2 in platelets in lithium-treated patients during euthymia have been shown [85–88]. DAG kinase is a member of the family of diacylglycerol kinases (DGKs) that play a major role in regulating the PI-signalling pathway. The major target of phosphorilation, for DGKs, is PKC [113]. This reaction is tightly regulated [114], thus even modest impairments in the function of DGKs can result in a dysregulation of PKC signalling. Recently, two completely independent genome-wide association studies have identified DGKH as a risk gene for BD. In the NIMH study, over 550 000 single nucleotide polymorphisms (SNPs) were genotyped in two independent case–control samples [115]. The 37 most significant SNPs were individually genotyped, and of these, the strongest association signal (p ¼ 1.5 108) was at a polymorphism in the DGKH gene. A second genome-wide association study, by the Wellcome Trust Case Control Consortium [37], investigated a different array of SNPs and found several in DGKH that were associated with BD at the 103 level. PKC activity has demonstrated to be increased in the manic state of patients with BD [84]. PKC levels were measured in postmortem brain tissue from subjects with BD and found increased in the frontal cortex, compared with control subjects [80]. Interestingly, lithium and valproate have been shown to have a potential role in
decreasing the levels of PKC in animal models, cell culture and platelets of lithium-treated patients (revised in [116]). On other hand, a recent study using platelets obtained from medication-free paediatric BD showed that PKC activity and the protein expression of PKC subunits beta I and beta II, but not PKC alpha or PKC delta, were significantly decreased in both membrane as well as cytosol fractions; after 8 weeks of mood stabilizer pharmacotherapy, PKC activity was significantly increased but there were no changes to any of the PKC isozymes in patients with BD [89]. These results indicate that PKC expression and activity may be associated with the molecular biology of BD and that pharmacotherapy with mood stabilizing drugs results in an increase and normalization of PKC activity in conjunction with improved clinical symptoms. Table 3 summarizes these findings. IP3 activation induces Ca2 þ release from the ER to the cytosol [106]. Although the importance of Ca2 þ in synaptic transmission and neurotransmitter release is well established, it has become increasingly apparent that Ca2 þ has a critical role in mediating diverse intracellular events; that is, synaptic plasticity, cell survival and excitotoxic cell death (reviewed in [117]). Dubovsky et al. [90] were the first to report that intracellular Ca2 þ concentration is elevated in platelets from patients with BD. Subsequently, the same group found increased free intracellular Ca2 þ in both depression and mania [79]. Increased total serum and ionized Ca2 þ has also been reported in euthymic lithium-treated patients compared with healthy controls [95]. More recently, intracellular Ca2 þ levels were examined in biopsy-derived olfactory receptor neurons from patients with BD in euthymia. Patients showed reduced Ca2 þ levels in response to odorant stimulation, whereas controls showed elevated levels [34]. In addition, elevated basal Ca2 þ concentrations have been detected in transformed B lymphoblasts in bipolar I disorder, compared with those in bipolar II disorder, major depression or healthy controls associated with abnormalities in receptor-coupled and G-protein-coupled adenylyl cyclase activity [96]. Thus, Ca2 þ homoeostasis appears altered across all mood states in BD (for summary of these results see Table 3). Agonist-induced Ca2 þ influx by thrombin, serotonin and platelet activating factor is reportedly enhanced in the cells derived from patients with BD, regardless of the agonist used [108,117]. Thapsigargin-induced cytosolic Ca2 þ response was found increased in peripheral blood cells from patients with BD [92–94]. Perova et al. [97] have shown increased Ca2 þ mobilization by lysophosphatidic acid (LPA) stimulation in B lymphoblast cell lines from patients with BD-I, as LPA has been shown to provoke Ca2 þ entry through a DAG-dependent TRPC3-like channel, and these findings suggest that the disturbance in Ca2 þ homoeostasis is probably due to disturbances in DAG-gated TRPC3 channels. Interesting, lithium attenuates LPA-stimulated
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and store depletion (thapsigargin)-induced intracellular Ca2 þ mobilization in B lymphoblast cell lines from patients with BD-I [98]. Other factors such as N-methyl-D-aspartate receptor, calcium-permeable AMPA/kainate receptor or voltage-dependent calcium channel might also cause abnormal calcium signalling in neurons. Indeed, much evidence suggests that the genes of these receptors and channels are altered in the postmortem brains of patients with BD [118], and one of the strongest pieces of evidence of GWAS was CACNA1C encoding the L-type voltagedependent Ca2 þ channel [37]. The PI pathway has shown important and consistent alteration in BD, regardless of the mood state. These alterations are characterized by decreased inositol level, increased PIP2 levels, increased intracellular Caþ 2 and increased PKC in the frontal cortex. The PI pathway is also a target for mood stabilizers, emphasizing the relevance of this pathway for the pathophysiology of BD.
Regulation of the second messenger GSK-3 by protein kinase B (AKT) and Wnt system GSK-3 has been identified as an important second messenger in BD. This is a serine/threonine protein kinase existing as two distinct gene products a and b, both recognized as a ubiquitous multifunctional enzyme involved in the modulation of many aspects of neuronal function, that is, proliferation, differentiation, axogenesis and synaptogenesis [119]. As the majority of the studies in BD have focus in the GSK-3b, this chapter will focus on this isoform. As the list of substrates phosphorylated by GSK-3b include more than 40 proteins and also include dysregulation of metabolic, signalling and structural proteins as well as inhibition of transcription factors, regulating GSK-3b activity has great impact [120]. For example, GSK-3b is highly expressed in the adult brain and is known to phosphorylate a number of important cytoskeletal proteins, such as Tau, MAP-1B and MAP-2 [121]. GSK-3b-mediated MAP-1B phosphorylation is associated with the loss and/or unbundling of stable axonal microtubules [122]. Furthermore, GSK-3b promotes the intrinsic apoptotic-signalling pathway by regulating transcription factors that control the expression of pro- and anti-apoptotic proteins, by promoting microtubule disruption and cell structural changes that occur during apoptosis, and by promoting disruption of mitochondria [123]. In this context, numerous signalling pathways are involved in controlling the inactivation of GSK-3b, including the phosphoinositide 3-kinase (PI-3K) pathway and the Wnt pathway [116]. The activation of tyrosine kinases receptors, by growth factors, causes dimerization and undergoes autophosphorylation at tyrosine residues, which allows the activation of PI-3K, then in turn promotes the phosphorylation of the membrane phospholipid PIP2 to form PIP3, which activates the protein-serine/threonine kinase Akt [99]. Akt
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then phosphorylates a number of proteins that regulate cell survival. Substrates for Akt are GSK-3a and GSK-3b that is inactivated through the phosphorylation of the single serine residues serine 21 (GSK-3a) and serine 9 (GSK-3b), which is located in the regulatory N-terminal domain [99]. Another system involved in controlling the GSK-3 status is the Wnt pathway. The Wnt protein family is composed of at least 15 secreted glycoproteins [124]. These proteins bind to the frizzled family of extracellular receptors, and result in a signal that is transduced via an intracellular protein, becoming dishevelled. Signalling through activated dishevelling inhibits GSK-3b [125]. GSK-3b inhibition promotes activation of several transcription factors, including bcatenin, HSF-1, AP-1 and CREB. These targets are believed to have a strong neuroprotective effects by allowing the transcription of specifics genes. GSK-3b has received great attention in BD, due to evidence that lithium and valproate inhibit GSK-3b through its phosphorylation (reviewed in [126]). The mechanism by which lithium increases phosphorylation levels is not yet fully delineated. One prominent pathway is the PI3K/Akt pathway. Several studies have shown that lithium increases BDNF levels in cell culture [127] and in an animal model [128] which, via the Trk B receptor, then stimulates the PI3K/Akt and MEK/ERK pathways [129,130]. Notably, the neuroprotective effects of lithium against excitotoxicity are mimicked by treatments with other GSK-3 inhibitors or by transfection with GSK-3 isoform-specific siRNA and dominant-negative mutants [131], suggesting that at least this aspect of lithiums action is mediated through GSK-3 inhibition. Valproate also increases GSK-3bs phosphorylation levels that promote GSK-3 inhibition. Lithium and valproate can activate the Wnt pathway and increase bcatenin mRNA and protein levels [132,133]. Several studies have examined the association of GSK-3 single nucleotide polymorphisms (SNPs) with BD [134–136]. In a Korean population, the 1727 A/T and 50 C/T SNPs of GSK-3 showed no difference between BD patients and controls [134], with similar results found in Caucasian populations [137]. In an Italian population, the 50 C/T SNP also showed no difference between BD and controls, but did influence the age of onset [135]. A fourth research study has found a general trend towards an association between the C allele, T/C polymorphism and BD. A closer examination of the data found a strong link between the T-50C polymorphism and females with bipolar II [136]. These four studies indicate that GSK-3 mutations are not linked to the presence of BD, with the exception of females with bipolar II disorder. Postmortem studies did not find differences in the levels of GSK-3b, b-catenin or Dvl-2 between BD, schizophrenia, major depressive disorder and controls [138]. It is conceivable that GSK-3 mutations may predict treatment efficacy. The first study that examined this issue found
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that the 50 C/T SNP mutation improved the recurrence index (frequency of episodes pre- and post-lithium treatment) following lithium administration [139]. However, subsequent studies found that neither genotype nor allele frequencies could predict a lithium response in bipolar I patients [140], nor was the T-50C polymorphism related to lithium prophylaxis [136]. Moreover, genetic and post mortem studies have not identified alteration on gene or protein expression of GSK-3 in patients with BD. However, the strong evidence that lithium regulates the phosphorulation levels of GSK-3 suggests the need for continued interest in this pathway to further understand the neurobiology of BD.
Transcription factors The activation of a transcription factor by a second messenger is the last step in the signal transduction. The consequence of transcription factor activation is a modulation of gene expression. Thus, a transcription factor is a protein that binds to specific DNA sequences and thereby controls the transfer (or transcription) of genetic information from DNA to messenger ribonucleic acid (mRNA) [141]. Transcription factors perform this function alone or with other proteins in a complex, by promoting (as an activator) or blocking (as a repressor) the recruitment of RNA polymerase to specific genes. Rather than the complete list of important transcription factors, this chapter describes the b-catenin, HSF-1, AP-1 and CREB due to the potential role in the patophysiology BD [141]. b-catenin is a proto-oncogene product and part of the canonical Wnt-1 pathway. The mechanism of regulation of b-catenin involves its phosphorylation by casein kinase 1 (CK1) at Ser-45 site and by GSK3 at Thr-41, Ser-37 and Ser-33 sites. This phosphorylation targets b-catenin to ubiquitination and degradation by the proteasome system [142]. Wnt proteins bind to a family of extracellular receptors known as frizzled. Frizzled receptors activate the intracellular protein dishevelled 1, which in turn inhibits GSK-3b. Inhibition of GSK-3 activity results in a decrease in the phosphorylation of its substrate b-catenin and hence stabilization of this transcription factor [143]. b-catenin then accumulates in the cytoplasm and translocates to the nucleus with the transcription factor Lef/Tcf to activate transcription [144]. Inhibition of GSK-3b leads to increased b-catenin levels by nonphophorylation. As b-catenin accumulates, it interacts with the transcription factor Tcf/Lef (T-cell factor/lymphoid enhancer factor), which is translocated to the nucleus. The Tcf/Lef- b-catenin complex activates the transcription of diverse genes that include several involved in the inhibition of apoptosis [144,145]. Interestingly, [146] when investigating the effects of lithium and/or VPA on b-catenin and Lef/Tcf-dependent transcription in a cerebellar granule cell line, they found that treatment with either
lithium or VPA alone resulted in a 5- to 7-fold increase in Lef activity, and that b-catenin levels were enhanced by lithium and valproate. HSF-1 is a transcription factor activated by many stress conditions; once activated, HSF-1 triggers the expression of chaperone proteins, including heat shock protein 70 (Hsp70). Hsp70 has been reported to have neuroprotective functions [147], such as blocking apoptosis by binding apoptosis protease activating factor-1 (Apaf-1), thereby preventing constitution of the apoptosome, the Apaf-1/ cytochrome c/caspase-9 activation complex [148,149] and suppressing JNK activation [150]. HSF-1 activity is suppressed by serial phosphorylation. ERK phosphorylates HSF-1 at Ser307, which then allows GSK-3b to phosphorylate HSF-1 at Ser303 [151]. GSK-3b negatively regulates HSF-1, as both DNA binding by HSF-1 and HSF-1-dependent transcription are negatively correlated with GSK-3b activity [152,153]. As already noted, lithium is a potent GSk3b inhibitor, which in turn may affect the HSF-1 pathway. Ren et al. [154] showed that lithium-induced HSP70 upregulation in a rat ischaemia/reperfusion model, which was preceded by an increase in the DNA binding activity of HSF-1. Activator protein-1 (AP-1) is a collection of homodimeric and heterodimeric complexes that contains members of the Jun, Fos, CREB and ATF families. These products bind to a common DNA site (known as the TPA response element) in the regulatory domain of the gene, and activate gene transcription in response to a variety of stimuli, including cytokines, growth factors and stress. Typically, these signals activate the MAP kinases, primarily JNK and p38, which results in AP-1 binding to a variety of genes [120]. A secondary regulator of AP-1 is GSK-3b, which phosphorylates c-Jun so as to reduce AP-1 binding activity [155]. AP-1 in turn controls a number of cellular processes including differentiation, proliferation and apoptosis. Its activation can be either neuroprotective or neurodegenerative, depending upon the particular molecules that form the AP-1 complex and their target genes [156]. Several studies have demonstrated the lithium is able to increase the activity levels of AP-1 in culture cell [157]. Valproate also increased the DNA binding activity of the AP-1 family in rat C6 glioma cells [158]. Chen et al. [159] reported that valproate also increased the mediated AP-1 gene expression. More recently, Spiliotaki et al. [160] evaluated the nuclear protein level of c-fos and JNK and the AP-1-DNA-binding in patients with BD during euthymic or depressed states. They showed that patients in a depressed state presented lower levels of c-fos and JNK and AP-1-DNA-binding than controls, whereas euthymic patients only showed decreased levels of JNK, addressing to the literature a possible state related of this pathway. CREB resides in the nucleus and spends most of its time in an inactive form. Its activation occurs after phosphorylation
Molecular Biology
at a particular amino acid (Ser-133) by a number of protein kinases, including those that are downstream targets of the signalling pathways discussed earlier in this article (PKA, MAPKs such as RSK1–3, and CaMKs) [161]. Once phosphorylated, the pCREB protein binds to a specific site in the promoter region of target genes, known as the cAMPresponse element (CRE). This leads to the production of mRNA, which is the blueprint for the synthesis of new proteins [162]. This is a critical step: in many ways it is the final link coupling the rapid fluctuations in neurotransmitter levels and receptor binding to the production of new proteins that can permanently alter the function or structure of specific brain regions. CREB also plays crucial roles in maintaining normal synaptic transmission and plasticity, such as hippocampal long-term potentiation and memory [163]. CREB is sensitive to several stimuli, including growth factors and stress, resulting in its regulation by several of the previously discussed pathways, including BDNF, MEK/ERK and GSK-3b (reviewed by [120]). CREB increases the expression of anti-apoptotic proteins, that is, members of the Bcl-2 family [164] and BDNF [165] that confer neuroprotective properties to CREB. As BDNF induces CREB activation and CREB upregulates BDNF expression, this creates a feedback loop throughout the cell survival-signalling pathway. Chronic lithium treatment alters CREB activity in excitotoxic situations by preventing glutamate-induced loss of phosphorylated CREB and CRE-driven gene expression [166]. Another line of evidence is the effect of pharmacotherapy on transcription factor activity. For example, Nibuya et al. [167] demonstrated that chronic antidepressant treatment increased rat hippocampal CREB protein and mRNA levels, as well as the binding of CREB to the CRE. Dowlatshahi et al. [168] showed higher temporal cortex CREB levels in patients with major depressive disorder treated with antidepressants in comparison with untreated patients. Zubenko et al. [169] found an association with the CREB1 polymorphism and major depressive disorder. Chen et al. [159] demonstrated that chronic lithium treatment decreased CREB phosphorylation in rat cerebral cortex and hippocampus. Recently, using a transgenic mice model, Boer et al. [170] showed decreased CRE/CREB-direct gene expression by chronic lithium treatment in hippocampus, cortex, hypothalamus and striatum and likewise reduced CREB phosphorylation. Levels of pCREB are also reported to be substantially down-regulated following depletion of adrenergic input. The effect of lithium on CREB phosphorylation is consistent with previous findings that this drug decreases cAMP signalling [171]. Chronic treatment with lithium has been shown to blunt agonist-stimulated cAMP production, and to regulate expression of specific AC isoforms and cAMP-dependent protein kinase activity in rat brain and platelets of lithium-treated BD subjects [172,173]. Recently, the CREB-c-activator, transducer of regulated
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CREB (TORC) has been identified as a novel target of lithium and shown to confer an enhancement of cAMP-induced CREB-direct gene transcription by lithium [170,174]. These results are in accordance with previous findings in temporal cortex from patients with BD [168]. The CREB family belongs to the leucine zipper family of DNA-binding proteins able to recognize the CRE. CREB1 is located on chromosome 2q32.3-q34 and exists in one of two isoforms (CREB347/CREB327), differing by a 14bp deletion [175]. CREB2 or ATF4 is located on chromosome 22q13.1 and is a repressor of CRE-dependent transcription [176]. Lastly, there is the CREB3 gene, also referred to as LUMAN, located on chromosome 9pter-p22.1. Its function has not been completely elucidated; however, it appears that CREB3 behaves as a transcriptional activator similar to CREB1. Mamdani et al. [177] studied the genetic variants associated with lithium responders and suggested that the CREB1-1H SNP and CREB1-7H SNP may be associated with BD and/or lithium response. Taken together, these findings support the involvement of transcription factor in the reponse to mood stabilizers and the neurobiology of BD. In summary, lithium increase the expression of B-catenin, HSP-1 and CREB and valproate increase the AP-1- DNA-binding and expression of B-catenin. Modulation of transcription factors by mood stabilizers are likely critical in connecting the regulation of gene expression, which can present the cell impairment by increasing expression of genes related to neuroplasticity and cell resilience.
Implications for the pathophysiology of BD and treatment Given the complexity of intracellular communication, several intracellular pathways have been implicated in the action of mood-stabilizers [178]. For example, lithium inhibits the inositol monophosphatase [179] and valproate and lithium lead to a reduction in PKC activity [180]. One of the substrates of PKC is myristoylated alanine rich C (MARCKS), which has decreased expression by lithium and valproate in neuronal culture [180]. Furthermore, studies suggests that lithium and valproate can increased levels of neurotrophic factors, such as BDNF in hippocampus of rats pre-treated with psychostimulant d-amphetamine [181]. More recent studies have suggested that mood stabilizer, especially lithium, can directly inhibits GSK-3b by competing with Mg þ 2, which may account for the antiapoptotic effects of the ion [182]. As described above lithium and valproate also activate the transcription factors CREB, B-catenin and HSP-1. Although remarkable progress has been made in our understanding of the signal transduction abnormalities associated with BD, it is important to point out that this work represents only the beginning. Findings supporting
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cAMP-signalling abnormalities in BD are extensive, and suggest increased levels of stimulatory G-protein, Gas, at least in the manic state. Studies of PI pathway, a set of findings including increased PIP2 levels and PKC activity has generally implicated alterations in this signalling pathway. Increased Ca2 þ responses in both peripheral blood cells and postmortem brain tissue of subjects with BD have been observed by several independent laboratories, broadly supporting the findings in PI signalling. Modulation of signalling pathways are central to understanding the neuroplasticity mechanism involved in BD and the mechanisms of action of the mood stabilizers. Future studies including large samples will be crucial to improve the understanding of intracellular signalling control in mood disorder, and will be a key to development of new drugs for the treatment of BD.
References 1. Kupfer, D.J. (2005) The increasing medical burden in bipolar disorder. JAMA, 293 (20), 2528–2530. 2. Belmaker, R.H. (2004) Bipolar disorder. N. Engl. J. Med., 351 (5), 476–486. 3. Merikangas, K.R., Akiskal, H.S., Angst, J. et al. (2007) Lifetime and 12-month prevalence of bipolar spectrum disorder in the National Comorbidity Survey replication. Arch. Gen. Psychiatry, 64 (5), 543–552. 4. Martinez-Aran, A., Torrent, C., Tabares-Seisdedos, R. et al. (2008) Neurocognitive impairment in bipolar patients with and without history of psychosis. J. Clin. Psychiat., 69 (2), 233–239. 5. Martinez-Aran, A., Vieta, E., Reinares, M. et al. (2004) Cognitive function across manic or hypomanic, depressed, and euthymic states in bipolar disorder. Am. J. Psychiatry, 161 (2), 262–270. 6. Torres, I.J., Boudreau, V.G. and Yatham, L.N. (2007) Neuropsychological functioning in euthymic bipolar disorder: a meta-analysis. Acta Psychiatr. Scand. Suppl. (434), 17–26. 7. Berk, M., Malhi, G.S., Hallam, K. et al. (2009) Early intervention in bipolar disorders: clinical, biochemical and neuroimaging imperatives. J. Affect. Disord., 114 (1–3), 1–13. 8. Goodwin, G.M., Martinez-Aran, A., Glahn, D.C. and Vieta, E. (2008) Cognitive impairment in bipolar disorder: neurodevelopment or neurodegeneration? An ECNP expert meeting report. Eur. Neuropsychopharmacol., 18 (11), 787–793. 9. Goodwin, F.K. (1989) The biology of recurrence: new directions for the pharmacologic bridge. J. Clin. Psychiat., 50 (Suppl.), 40–44, discussion 45–47. 10. Ongur, D., Drevets, W.C. and Price, J.L. (1998) Glial reduction in the subgenual prefrontal cortex in mood disorders. Proc. Natl. Acad. Sci. USA, 95 (22), 13290–13295. 11. Rajkowska, G., Halaris, A. and Selemon, L.D. (2001) Reductions in neuronal and glial density characterize the dorsolateral prefrontal cortex in bipolar disorder. Biol. Psychiatry, 49 (9), 741–752. 12. Benes, F.M., Vincent, S.L. and Todtenkopf, M. (2001) The density of pyramidal and nonpyramidal neurons in
13.
14.
15.
16.
17. 18.
19.
20.
21. 22.
23.
24.
25.
26.
27.
28.
anterior cingulate cortex of schizophrenic and bipolar subjects. Biol. Psychiatry, 50 (6), 395–406. Benes, F.M., Kwok, E.W., Vincent, S.L. and Todtenkopf, M.S. (1998) A reduction of nonpyramidal cells in sector CA2 of schizophrenics and manic depressives. Biol. Psychiatry, 44 (2), 88–97. Manaye, K.F., Lei, D.L., Tizabi, Y. et al. (2005) Selective neuron loss in the paraventricular nucleus of hypothalamus in patients suffering from major depression and bipolar disorder. J. Neuropathol. Exp. Neurol., 64 (3), 224–229. Bezchlibnyk, Y.B., Sun, X., Wang, J.F. et al. (2007) Neuron somal size is decreased in the lateral amygdalar nucleus of subjects with bipolar disorder. J. Psychiatr. Neurosci., 32 (3), 203–210. Rajkowska, G. (2000) Postmortem studies in mood disorders indicate altered numbers of neurons and glial cells. Biol. Psychiatry, 48 (8), 766–777. Ross, E.M. (1989) Signal sorting and amplification through G protein-coupled receptors. Neuron, 3 (2), 141–152. Bauer, M., Alda, M., Priller, J. et al. (2003) Implications of the neuroprotective effects of lithium for the treatment of bipolar and neurodegenerative disorders. Pharmacopsychiatry, 36 (Suppl. 3), S250–S254. Schloesser, R.J., Huang, J., Klein, P.S. and Manji, H.K. (2008) Cellular plasticity cascades in the pathophysiology and treatment of bipolar disorder. Neuropsychopharmacology, 33 (1), 110–133. Birnbaumer, L. (1992) Receptor-to-effector signaling through G proteins: roles for beta gamma dimers as well as alpha subunits. Cell, 71 (7), 1069–1072. Manji, H.K. and Lenox, R.H. (2000) The nature of bipolar disorder. J. Clin. Psychiat., 61 (Supp. 13), 42–57. Schloesser, M., Schnitzer, A., Ying, H. et al. (2008) iSANLA: intelligent sensor and actuator network for life science applications. Conference proceedings: Annual International Conference of the IEEE Engineering in Medicine and Biology Society.IEEE Engineering in Medicine and Biology Society. Conference, vol. 2008, pp. 2369–2372. Beaulieu, J.M., Gainetdinov, R.R. and Caron, M.G. (2009) Akt/GSK3 signaling in the action of psychotropic drugs. Annu. Rev. Pharmacol. Toxicol., 49, 327–347. Young, L.T., Li, P.P., Kish, S.J. et al. (1991) Postmortem cerebral cortex Gs alpha-subunit levels are elevated in bipolar affective disorder. Brain Res., 553 (2), 323–326. Young, L.T., Li, P.P., Kish, S.J. et al. (1993) Cerebral cortex Gs alpha protein levels and forskolin-stimulated cyclic AMP formation are increased in bipolar affective disorder. J. Neurochem., 61 (3), 890–898. Friedman, E. and Wang, H.Y. (1996) Receptor-mediated activation of G proteins is increased in postmortem brains of bipolar affective disorder subjects. J. Neurochem., 67 (3), 1145–1152. Dowlatshahi, D., MacQueen, G., Wang, J.F. et al. (2000) Increased hippocampal supragranular Timm staining in subjects with bipolar disorder. Neuroreport, 11 (17), 3775–3778. Young, L.T., Asghari, V., Li, P.P. et al. (1996) Stimulatory G-protein alpha-subunit mRNA levels are not increased in
Molecular Biology
29.
30.
31.
32.
33.
34.
35.
36.
37.
38.
39.
40.
41.
42.
43.
autopsied cerebral cortex from patients with bipolar disorder. Brain Res. Mol. Brain Res., 42 (1), 45–50. Rao, J.S., Rapoport, S.I. and Kim, H.W. (2009) Decreased GRK3 but not GRK2 expression in frontal cortex from bipolar disorder patients. Int. J. Neuropsychopharmacol., 12 (6), 851–860. Spleiss, O., van Calker, D., Sch€ arer, L., Adamovic, K., Berger, M. and Gebicke-Haerter, P.J. (1998) Abnormal G protein alpha(s) - and alpha(i2)-subunit mRNA expression in bipolar affective disorder. Mol. Psychiatry, 3 (6), 512–520. Young, L.T., Li, P.P., Kamble, A., Siu, K.P. and Warsh, J.J. (1994) Mononuclear leukocyte levels of G proteins in depressed patients with bipolar disorder or major depressive disorder. Am. J. Psychiatry, 151 (4), 594–596. Schreiber, G. and Avissar, S. (1991) Lithium sensitive G protein hyperfunction: a dynamic model for the pathogenesis of bipolar affective disorder. Med. Hypotheses, 35 (3), 237–243. Avissar, S., Nechamkin, Y., Barki-Harrington, L., Roitman, G. and Schreiber, G.(1997) Differential G protein measures in mononuclear leukocytes of patients with bipolar mood disorder are state dependent. J. Affect. Disord., 43 (2), 85–93. Hahn, C.G., Gomez, G., Restrepo, D. et al. (2005) Aberrant intracellular calcium signaling in olfactory neurons from patients with bipolar disorder. Am. J. Psychiatry, 162 (3), 616–618. Mitchell, P.B., Manji, H.K., Chen, G. et al. (1997) High levels of Gs alpha in platelets of euthymic patients with bipolar affective disorder. Am. J. Psychiatry, 154 (2), 218–223. Alda, M., Grof, P., Rouleau, G.A. et al. (2005) Investigating responders to lithium prophylaxis as a strategy for mapping susceptibility genes for bipolar disorder. Prog. Neuropsychopharmacol. Biol. Psychiatry, 29 (6), 1038–1045. Sklar, P., Smoller, J.W., Fan, J. et al. (2008) Whole-genome association study of bipolar disorder. Mol. Psychiatry, 136), 558–569. Ferreira, M.A., ODonovan, M.C., Meng, Y.A. et al. (2008) Collaborative genome-wide association analysis supports a role for ANK3 and CACNA1C in bipolar disorder. Nat. Genet., 40 (9), 1056–1058. Fan, J. and Sklar, P. (2008) Genetics of bipolar disorder: focus on BDNF Val66Met polymorphism. Novartis Found. Symp., 289, 60–72, discussion 72–73, 87–93. Fan, J., Ionita-Laza, I., McQueen, M.B. et al. (2009) Linkage disequilibrium mapping of the chromosome 6q21-22.31 bipolar I disorder susceptibility locus. Am. J. Med. Genet., 153, 29–37. Dean, O., Bush, A.I., Berk, M. et al. (2009) Glutathione depletion in the brain disrupts short-term spatial memory in the Y-maze in rats and mice. Behav. Brain Res., 198 (1), 258–262. Catapano, L.A. and Manji, H.K. (2007) G protein-coupled receptors in major psychiatric disorders. Biochim Biophys. Acta, 1768 (4), 976–993. Pearlson, G.D., Wong, D.F., Tune, L.E. et al. (1995) In vivo D2 dopamine receptor density in psychotic and nonpsychotic patients with bipolar disorder. Arch. Gen. Psychiatry, 52 (6), 471–477.
|
239
44. Wong, D.F., Pearlson, G.D., Tune, L.E. et al. (1997) Quantification of neuroreceptors in the living human brain: IV. Effect of aging and elevations of D2-like receptors in schizophrenia and bipolar illness. J. Cereb. Blood Flow Metab., 17 (3), 331–342. 45. McInnis, M.G., Lan, T.H., Willour, V.L. et al. (2003) Genomewide scan of bipolar disorder in 65 pedigrees: supportive evidence for linkage at 8q24, 18q22, 4q32, 2p12, and 13q12. Mol. Psychiatry, 8 (3), 288–298. 46. Ranade, S.S., Mansour, H., Wood, J. et al. (2003) Linkage and association between serotonin 2A receptor gene polymorphisms and bipolar I disorder. Am. J. Med. Genet., 121B (1), 28–34. 47. Chee, I.S., Lee, S.W., Kim, J.L. et al. (2001) 5-HT2A receptor gene promoter polymorphism -1438A/G and bipolar disorder. Psychiatr. Genet., 11 (3), 111–114. 48. Rybakowski, J.K., Dmitrzak-Weglarz, M., Suwalska, A. et al. (2009) Dopamine D1 receptor gene polymorphism is associated with prophylactic lithium response in bipolar disorder. Pharmacopsychiatry, 42 (1), 20–22. 49. Massat, I., Souery, D., Del-Favero, J., et al. (2002) Positive association of dopamine D2 receptor polymorphism with bipolar affective disorder in a European Multicenter Association Study of affective disorders. Am. J. Med. Genet., 114 (2), 177–185. 50. Shaltiel, G., Shamir, A., Levi, I. et al. (2006) Lymphocyte G-protein receptor kinase (GRK)3 mRNA levels in bipolar disorder. Int. J. Neuropsychopharmacol., 9 (6), 761–766. 51. Chao, M.V., Rajagopal, R. and Lee, F.S. (2006) Neurotrophin signalling in health and disease. Clin. Sci. (Lond.), 110 (2), 167–173. 52. Arevalo, J.C. and Chao, M.V. (2005) Axonal growth: where neurotrophins meet Wnts. Curr. Opin. Cell Biol., 17 (2), 112–115. 53. Chao, M.V. (2003) Neurotrophins and their receptors: a convergence point for many signalling pathways. Nat. Rev. Neurosci., 4 (4), 299–309. 54. Kapczinski, F., Dias, V.V., Frey, B.N. and Kauer-SantAnna, M. (2009) Brain-derived neurotrophic factor in bipolar disorder: beyond trait and state: comment on Decreased levels of serum brain-derived neurotrophic factor in both depressed and euthymic patients with unipolar depression and in euthymic patients with bipolar I and II disorders. Bipolar Disord., 11 (2), 221–222. 55. Post, R.M. (2007) Kindling and sensitization as models for affective episode recurrence, cyclicity, and tolerance phenomena. Neurosci. Biobehav. Rev., 31 (6), 858–873. 56. Cunha, A.B., Frey, B.N., Andreazza, A.C. et al. (2006) Serum brain-derived neurotrophic factor is decreased in bipolar disorder during depressive and manic episodes. Neurosci. Lett., 398 (3), 215–219. 57. Machado-Vieira, R., Dietrich, M.O., Leke, R. et al. (2007) Decreased plasma brain derived neurotrophic factor levels in unmedicated bipolar patients during manic episode. Biol. Psychiatry, 61 (2), 142–144. 58. Monteleone, P., Serritella, C., Martiadis, V. and Maj, M. (2008) Decreased levels of serum brain-derived neurotrophic factor in both depressed and euthymic patients with
240
59.
60.
61.
62.
63.
64.
65.
66.
67.
68.
69.
70.
71.
72.
|
Chapter 17
unipolar depression and in euthymic patients with bipolar I and II disorders. Bipolar Disord., 10 (1), 95–100. de Oliveira, G.S., Cereser, K.M., Fernandes, B.S., et al. (2009) Decreased brain-derived neurotrophic factor in medicated and drug-free bipolar patients. J. Psychiatr. Res., 43 (14), 1171 1174. Dunham, J.H., Meyer, R.C., Garcia, E.L. and Hall, R.A. (2009) GPR37 surface expression enhancement via N-terminal truncation or protein-protein interactions. Biochemistry, 48 (43), 10286–10297. Hattiangady, B., Rao, M.S., Zaman, V. and Shetty, A.K. (2006) Incorporation of embryonic CA3 cell grafts into the adult hippocampus at 4-months after injury: effects of combined neurotrophic supplementation and caspase inhibition. Neuroscience, 139 (4), 1369–1383. Gooney, M., Messaoudi, E., Maher, F.O. et al. (2004) BDNFinduced LTP in dentate gyrus is impaired with age: analysis of changes in cell signaling events. Neurobiol. Aging, 25 (10), 1323–1331. Yatham, L.N., Kapczinski, F., Andreazza, A.C. et al. (2009) Accelerated age-related decrease in brain-derived neurotrophic factor levels in bipolar disorder. Int. J. Neuropsychopharmacol., 12 (1), 137–139. Kauer-SantAnna, M., Kapczinski, F., Andreazza, A.C., et al. (2009) Brain-derived neurotrophic factor and inflammatory markers in patients with early- vs. late-stage bipolar disorder. Int. J. Neuropsychopharmacol. 12 (4), 447–458. Andreazza, A.C., Cassini, C., Rosa, A.R. et al. (2007) Serum S100B and antioxidant enzymes in bipolar patients. J. Psychiatr. Res., 41 (6), 523–529. Machado-Vieira, R., Andreazza, A.C., Viale, C.I. et al. (2007) Oxidative stress parameters in unmedicated and treated bipolar subjects during initial manic episode: a possible role for lithium antioxidant effects. Neurosci. Lett., 421 (1), 33–36. Selek, S., Savas, H.A., Gergerlioglu, H.S. et al. (2007) The course of nitric oxide and superoxide dismutase during treatment of bipolar depressive episode. J. Affect. Disord., 107, 89–94. Selek, S., Savas, H.A., Gergerlioglu, H.S. et al. (2008) The course of nitric oxide and superoxide dismutase during treatment of bipolar depressive episode. J. Affect. Disord., 107 (1–3), 89–94. Savas, H.A., Gergerlioglu, H.S., Armutcu, F. et al. (2006) Elevated serum nitric oxide and superoxide dismutase in euthymic bipolar patients: impact of past episodes. World J. BiolPsychiatry, 7 (1), 51–55. Ranjekar, P.K., Hinge, A., Hegde, M.V. et al. (2003) Decreased antioxidant enzymes and membrane essential polyunsaturated fatty acids in schizophrenic and bipolar mood disorder patients. Psychiatry Res., 121 (2), 109–122. Abdalla, D.S., Monteiro, H.P., Oliveira, J.A. and Bechara, E.J. (1986) Activities of superoxide dismutase and glutathione peroxidase in schizophrenic and manic-depressive patients. Clin. Chem., 32 (5), 805–807. Zohar, J., Lerer, B., Ebstein, R.P. and Belmaker, R.H. (1982) Lithium does not prevent agonist-induced subsensitivity of human adenylate cyclase. Biol. Psychiatry, 17 (3), 343–350.
73. Spaulding, G.F., Jessup, J.M. and Goodwin , T.J. (1993) Advances in cellular construction. J. Cell Biochem., 51 (3), 249–251. 74. Rahman, S., Li, P.P., Young, L.T. et al. (1997) Reduced [3 H] cyclic AMP binding in postmortem brain from subjects with bipolar affective disorder. J. Neurochem., 68 (1), 297–304. 75. Fields, A., Li, P.P., Kish, S.J. and Warsh, J.J. (1999) Increased cyclic AMP-dependent protein kinase activity in postmortem brain from patients with bipolar affective disorder. J. Neurochem., 73 (4), 1704–1710. 76. Perez, J., Tardito, D., Mori, S. et al. (2000) Altered Rap1 endogenous phosphorylation and levels in platelets from patients with bipolar disorder. J. Psychiatr. Res., 34 (2), 99–104. 77. Tardito, D., Mori, S., Racagni, G. et al. (2003) Protein kinase A activity in platelets from patients with bipolar disorder. J. Affect. Disord., 76 (1–3), 249–253. 78. Karege, F., Schwald, M., Papadimitriou, P. et al. (2004) The cAMP-dependent protein kinase A and brain-derived neurotrophic factor expression in lymphoblast cells of bipolar affective disorder. J. Affect. Disord., 79 (1–3), 187–192. 79. Taylor, S.J. and Exton, J.H. (1991) Two alpha subunits of the Gq class of G proteins stimulate phosphoinositide phospholipase C-beta 1 activity. FEBS Lett., 286 (1–2), 214–216. 80. Wang, H.Y. and Friedman, E. (1996) Enhanced protein kinase C activity and translocation in bipolar affective disorder brains. Biol. Psychiatry, 40 (7), 568–575. 81. Shimon, H., Agam, G., Belmaker, R.H. et al. (1997) Reduced frontal cortex inositol levels in postmortem brain of suicide victims and patients with bipolar disorder. Am. J. Psychiatry, 154 (8), 1148–1150. 82. Mathews, R., Li, P.P., Young, L.T. et al. (1997) Increased G alpha q/11 immunoreactivity in postmortem occipital cortex from patients with bipolar affective disorder. Biol. Psychiatry, 41 (6), 649–656. 83. Brown, A.S., Mallinger, A.G. and Renbaum, L.C. (1993) Elevated platelet membrane phosphatidylinositol-4,5bisphosphate in bipolar mania. Am. J. Psychiatry, 150 (8), 1252–1254. 84. Friedman, E., Wang, H.-Y., Levinson, D. et al. (1993) Altered platelet protein kinase C activity in bipolar affective disorder, manic episode. Biol. Psychiatry, 33 (7), 520–525. 85. Soares, J.C. and Mallinger, A.G. (1996) Abnormal phosphatidylinositol (PI)-signalling in bipolar disorder. Biol. Psychiatry, 39 (6), 461–464. 86. Soares, J.C., Dippold, C.S. and Mallinger, A.G. (1997) Platelet membrane phosphatidylinositol-4,5-bisphosphate alterations in bipolar disorder--evidence from a single case study. Psychiatry Res., 69 (2–3), 197–202. 87. Soares, J.C., Chen, G., Dippold, C.S. et al. (2000) Concurrent measures of protein kinase C and phosphoinositides in lithium-treated bipolar patients and healthy individuals: a preliminary study. Psychiatry Res., 95 (2), 109–118. 88. Soares, J.C., Mallinger, A.G., Dippold, C.S. et al. (1999) Platelet membrane phospholipids in euthymic bipolar disorder patients: are they affected by lithium treatment? Biol. Psychiatry, 45 (4), 453–457.
Molecular Biology 89. Pandey, G.N., Rizavi, H.S., Dwivedi, Y. and Pavuluri, M.N. (2008) Brain-derived neurotrophic factor gene expression in pediatric bipolar disorder: effects of treatment and clinical response. J. Am. Acad. Child Psy., 47 (9), 1077–1085. 90. Dubovsky, S.L., Franks, R.D., Allen, S. and Murphy, J. (1986) Calcium antagonists in mania: a double-blind study of verapamil. Psychiatry Res., 18 (4), 309–320. 91. Dubovsky, S.L., Thomas, M., Hijazi, A. and Murphy, J. (1994) Intracellular calcium signalling in peripheral cells of patients with bipolar affective disorder. Eur. Arch. Psychiatry Clin. Neurosci., 243 (5), 229–234. 92. Hough, C., Lu, S.J., Davis, C.L., Chuang, D.M. and Post, R.M. (1999) Elevated basal and thapsigargin-stimulated intracellular calcium of platelets and lymphocytes from bipolar affective disorder patients measured by a fluorometric microassa . Biol. Psychiatry, 46 (2), 247–255. 93. Kato, T., Ishiwata, M., Mori, K. et al. (2003) Mechanisms of altered Ca2 þ signalling in transformed lymphoblastoid cells from patients with bipolar disorder. Int. J. Neuropsychopharmacol., 6 (4), 379–389. 94. Perova, T., Kwan, M., Li, P.P. and Warsh, J.J. (2009) Differential modulation of intracellular Ca2 þ responses in B lymphoblasts by mood stabilizers. Int. J. Neuropsychopharmacol., 29, 1–10. 95. El Khoury, A., Petterson, U., Kallner, G. et al. (2002) Calcium homeostasis in long-term lithium-treated women with bipolar affective disorder. Prog. Neuropsychopharmacol. Biol. Psychiatry, 26 (6), 1063–1069. 96. Emamghoreishi, M., Li, P.P., Schlichter, L. et al. (2000) Associated disturbances in calcium homeostasis and G protein-mediated cAMP signaling in bipolar I disorder. Biol. Psychiatry, 48 (7), 665–673. 97. Perova, T., Wasserman, M.J., Li, P.P. and Warsh, J.J. (2008) Hyperactive intracellular calcium dynamics in B lymphoblasts from patients with bipolar I disorder. Int. J. Neuropsychopharmacol., 11 (2), 185–196. 98. Wasserman, M.J., Corson, T.W., Sibony, D. et al. (2004) Chronic lithium treatment attenuates intracellular calcium mobilization. Neuropsychopharmacol., 29 (4), 759–769. 99. Beaulieu, J.M., Tirotta, E., Sotnikova, T.D. et al. (2007) Regulation of Akt signaling by D2 and D3 dopamine receptors in vivo. J. Neurosci., 27 (4), 881–885. 100. Beavo, J.A., Bechtel, P.J. and Krebs, E.G. (1974) Activation of protein kinase by physiological concentrations of cyclic AMP. Proc. Natl. Acad. Sci. USA, 71 (9), 3580–3583. 101. Bezchlibnyk, Y. and Young, L.T. (2002) The neurobiology of bipolar disorder: focus on signal transduction pathways and the regulation of gene expression. Can. J. Psychiat., 47 (2), 135–148. 102. Zanardi, R., Racagni, G., Smeraldi, E. and Perez, J. (1997) Differential effects of lithium on platelet protein phosphorylation in bipolar patients and healthy subjects. Psychopharmacology (Berl.), 129 (1), 44–47. 103. Perez, J., Tardito, D., Mori, S. et al. (1999) Abnormalities of cyclic adenosine monophosphate signaling in platelets from untreated patients with bipolar disorder. Arch. Gen. Psychiatry, 56 (3), 248–253.
|
241
104. Karege, F., Schwald, M. and El Kouaissi, R. (2004) Druginduced decrease of protein kinase a activity reveals alteration in BDNF expression of bipolar affective disorder. Neuropsychopharmacology, 29 (4), 805–812. 105. Gould, T.D. and Manji, H.K. (2002) Signaling networks in the pathophysiology and treatment of mood disorders. J. Psychosom. Res., 53 (2), 687–697. 106. Berridge, M.J., Dawson, R.M., Downes, C.P. et al. (1983) Changes in the levels of inositol phosphates after agonistdependent hydrolysis of membrane phosphoinositides. Biochem. J., 212 (2), 473–482. 107. Perez-Gordones, M.C., Lugo, M.R., Winkler, M. et al. (2009) Diacylglycerol regulates the plasma membrane calcium pump from human erythrocytes by direct interaction. Arch. Biochem. Biophys., 489, 55–61. 108. Kato, T. (2008) Molecular neurobiology of bipolar disorder: a disease of mood-stabilizing neurons? Trends Neurosci., 31 (10), 495–503. 109. Belmaker, R.H., Shapiro, J., Vainer, E. et al. (2002) Reduced inositol content in lymphocyte-derived cell lines from bipolar patients. Bipolar Disord., 4 (1), 67–69. 110. Nemanov, L., Ebstein, R.P., Belmaker, R.H. et al. (1999) Effect of bipolar disorder on lymphocyte inositol monophosphatase mRNA levels. Int. J. Neuropsychopharmacol., 2 (1), 25–29. 111. Yoon, I.S., Li, P.P., Siu, K.P. et al. (2001) Altered IMPA2 gene expression and calcium homeostasis in bipolar disorder. Mol. Psychiatry, 6 (6), 678–683. 112. Shamir, A., Ebstein, R.P., Nemanov, L. et al. (1998) Inositol monophosphatase in immortalized lymphoblastoid cell lines indicates susceptibility to bipolar disorder and response to lithium therapy. Mol. Psychiatry, 3 (6), 481–482. 113. Newton, P.M. and Ron, D. (2007) Protein kinase C and alcohol addiction. Pharmacol. Res., 55 (6), 570–577. 114. Crotty, T., Cai, J., Sakane, F. et al. (2006) Diacylglycerol kinase delta regulates protein kinase C and epidermal growth factor receptor signaling. Proc. Natl. Acad. Sci. USA, 103 (42), 15485–15490. 115. Baum, A.E., Akula, N., Cabanero, M. et al. (2008) A genomewide association study implicates diacylglycerol kinase eta (DGKH) and several other genes in the etiology of bipolar disorder. Mol. Psychiatry, 13 (2), 197–207. 116. Zarate, C.A. Jrand Manji, H.K. (2008) Bipolar disorder: candidate drug targets. Mt. Sinai J. Med., 75 (3), 226–247. 117. Kato, T. (2008) Role of mitochondrial DNA in calcium signaling abnormality in bipolar disorder. Cell Calcium, 44 (1), 92–102. 118. Kato, T., Kakiuchi, C. and Iwamoto, K. (2007) Comprehensive gene expression analysis in bipolar disorder. Can. J. Psychiat., 52 (12), 763–771. 119. Gould, T.D., Picchini, A.M., Einat, H. and Manji, H.K. (2006) Targeting glycogen synthase kinase-3 in the CNS: implications for the development of new treatments for mood disorders. Curr. Drug Targets, 7 (11), 1399–1409. 120. Rowe, M.K. and Chuang, D.M. (2004) Lithium neuroprotection: molecular mechanisms and clinical implications. Expert Rev. Mol. Med., 6 (21), 1–18.
242
|
Chapter 17
121. Salinas, P.C. and Hall, A.C. (1999) Lithium and synaptic plasticity. Bipolar Disord., 1 (2), 87–90. 122. Lucas, F.R., Goold, R.G., Gordon-Weeks, P.R. and Salinas, P. C. (1998) Inhibition of GSK-3beta leading to the loss of phosphorylated MAP-1B is an early event in axonal remodelling induced by WNT-7a or lithium. J. Cell Sci., 111 (Pt 10), 1351–1361. 123. Beurel, E. and Jope, R.S. (2006) The paradoxical pro- and anti-apoptotic actions of GSK3 in the intrinsic and extrinsic apoptosis signaling pathways. Prog. Neurobiol., 79 (4), 173–189. 124. Wodarz, A. and Nusse, R. (1998) Mechanisms of Wnt signaling in development. Annu. Rev. Cell Dev. Biol., 14, 59–88. 125. Gould, T.D. and Manji, H.K. (2002) The Wnt signaling pathway in bipolar disorder. Neuroscientist, 8 (5), 497–511. 126. Rowe, M.K., Wiest, C. and Chuang, D.M. (2007) GSK-3 is a viable potential target for therapeutic intervention in bipolar disorder. Neurosci. Biobehav. Rev., 31 (6), 920–931. 127. Hashimoto, R., Takei, N., Shimazu, K., Christ, L., Lu, B. and Chuang, D.M. (2002) Lithium induces brain-derived neurotrophic factor and activates TrkB in rodent cortical neurons: an essential step for neuroprotection against glutamate excitotoxicity. Neuropharmacol., 43 (7), 1173–1179. 128. Frey, B.N., Andreazza, A.C., Cereser, K.M. et al. (2006) Effects of mood stabilizers on hippocampus BDNF levels in an animal model of mania. Life Sci., 79 (3), 281–286. 129. Chalecka-Franaszek, E. and Chuang, D.M. (1999) Lithium activates the serine/threonine kinase Akt-1 and suppresses glutamate-induced inhibition of Akt-1 activity in neurons. Proc. Natl. Acad. Sci. USA, 96 (15), 8745–8750. 130. Einat, H., Yuan, P., Gould, T.D. et al. (2003) The role of the extracellular signal-regulated kinase signaling pathway in mood modulation. J. Neurosci., 23 (19), 7311–7316. 131. Liang, Z.Q., Wang, X., Li, L.Y. et al. (2007) Nuclear factorkappaB-dependent cyclin D1 induction and DNA replication associated with N-methyl-D-aspartate receptor-mediated apoptosis in rat striatum. J. Neurosci. Res., 85 (6), 1295–1309. 132. Chen, G., Huang, L.D., Jiang, Y.M. and Manji, H.K. (1999) The mood-stabilizing agent valproate inhibits the activity of glycogen synthase kinase-3. J. Neurochem., 72 (3), 1327–1330. 133. Phiel, C.J. and Klein, P.S. (2001) Molecular targets of lithium action. Annu. Rev. Pharmacol. Toxicol., 41, 789–813. 134. Lee, K.Y., Ahn, Y.M., Joo, E.J. et al. (2006) No association of two common SNPs at position 1727 A/T, 50 C/T of GSK3 beta polymorphisms with schizophrenia and bipolar disorder of Korean population. Neurosci. Lett., 395 (2), 175–178. 135. Benedetti, F., Serretti, A., Colombo, C. et al. (2004) A glycogen synthase kinase 3-beta promoter gene single nucleotide polymorphism is associated with age at onset and response to total sleep deprivation in bipolar depression. Neurosci. Lett., 368 (2), 123–126. 136. Szczepankiewicz, A., Rybakowski, J.K., Suwalska, A. et al. (2006) Association study of the glycogen synthase kinase3beta gene polymorphism with prophylactic lithium response in bipolar patients. World J. Biological Psychiatry, 7 (3), 158–161.
137. Nishiguchi, N., Breen, G., Russ, C. et al. (2006) Association analysis of the glycogen synthase kinase-3beta gene in bipolar disorder. Neurosci. Lett., 394 (3), 243–245. 138. Beasley, C., Cotter, D., Khan, N. et al. (2001) Glycogen synthase kinase-3beta immunoreactivity is reduced in the prefrontal cortex in schizophrenia. Neurosci. Lett., 302 (2–3), 117–120. 139. Benedetti, F., Serretti, A., Pontiggia, A. et al. (2005) Longterm response to lithium salts in bipolar illness is influenced by the glycogen synthase kinase 3-beta -50 T/C SNP. Neurosci. Lett., 376 (1), 51–55. 140. Michelon, L., Meira-Lima, I., Cordeiro, Q. et al. (2006) Association study of the INPP1, 5HTT, BDNF, AP-2beta and GSK-3beta GENE variants and restrospectively scored response to lithium prophylaxis in bipolar disorder. Neurosci. Lett., 403 (3), 288–293. 141. Mamdani, F., Alda, M., Grof, P. et al. (2008) Lithium response and genetic variation in the CREB family of genes. Am. J. Med. Genet., 147B (4), 500–504. 142. McCarty, J.H. (2009) Cell adhesion and signaling networks in brain neurovascular units. Curr. Opin. Hematol., 16 (3), 209–214. 143. Hedgepeth, C.M., Conrad, L.J., Zhang, J. et al. (1997) Activation of the Wnt signaling pathway: a molecular mechanism for lithium action. Dev. Biol., 185 (1), 82–91. 144. Barker, N. (2008) The canonical Wnt/beta-catenin signalling pathway. Methods Mol. Biol., 468, 5–15. 145. Eastman, Q. and Grosschedl, R. (1999) Regulation of LEF-1/ TCF transcription factors by Wnt and other signals. Curr. Opin. Cell Biol., 11 (2), 233–240. 146. Leng, Y., Liang, M.H., Ren, M. et al. (2008) Synergistic neuroprotective effects of lithium and valproic acid or other histone deacetylase inhibitors in neurons: roles of glycogen synthase kinase-3 inhibition. J. Neurosci., 28 (10), 2576–2588. 147. Takayama, S., Xie, Z. and Reed, J.C. (1999) An evolutionarily conserved family of Hsp70/Hsc70 molecular chaperone regulators. J. Biol. Chem., 274 (2), 781–786. 148. Beere, H.M. and Green, D.R. (2001) Stress management heat shock protein-70 and the regulation of apoptosis. Trends Cell Biol., 11 (1), 6–10. 149. Beere, H.M., Wolf, B.B., Cain, K. et al. (2000) Heat-shock protein 70 inhibits apoptosis by preventing recruitment of procaspase-9 to the Apaf-1 apoptosome. Nat. Cell Biol., 2 (8), 469–475. 150. Hwang, S.O., Boswell, S.A., Seo, J.S. and Lee, S.W. (2008) Novel oxidative stress-responsive gene ERS25 functions as a regulator of the heat-shock and cell death response. J. Biol. Chem., 283 (19), 13063–13069. 151. Chu, B., Soncin, F., Price, B.D. et al. (1996) Sequential phosphorylation by mitogen-activated protein kinase and glycogen synthase kinase 3 represses transcriptional activation by heat shock factor-1. J. Biol. Chem., 271 (48), 30847–30857. 152. Bijur, G.N. and Jope, R.S. (2003) Glycogen synthase kinase-3 beta is highly activated in nuclei and mitochondria. Neuroreport, 14 (18), 2415–2419. 153. Xavier, I.J., Mercier, P.A., McLoughlin, C.M. et al. (2000) Glycogen synthase kinase 3beta negatively regulates both
Molecular Biology
154.
155.
156. 157.
158.
159.
160.
161.
162.
163.
164. 165.
166.
167.
168.
DNA-binding and transcriptional activities of heat shock factor 1. J. Biol. Chem., 275 (37), 29147–29152. Ren, M., Senatorov, V.V., Chen, R.W. and Chuang, D.M. (2003) Postinsult treatment with lithium reduces brain damage and facilitates neurological recovery in a rat ischemia/reperfusion model. Proc. Natl. Acad. Sci. USA, 100 (10), 6210–6215. Boyle, W.J., Smeal, T., Defize, L.H. et al. (1991) Activation of protein kinase C decreases phosphorylation of c-Jun at sites that negatively regulate its DNA-binding activity. Cell, 64 (3), 573–584. Wisdom, R. (1999) AP-1: one switch for many signals. Exp. Cell Res., 253 (1), 180–185. Asghari, V., Wang, J.F., Reiach, J.S. and Young, L.T. (1998) Differential effects of mood stabilizers on Fos/Jun proteins and AP-1 DNA binding activity in human neuroblastoma SH-SY5Y cells. Brain Res. Mol. Brain Res., 58 (1–2), 95–102. Chen, G., Yuan, P., Hawver, D.B. et al. (1997) Increase in AP-1 transcription factor DNA binding activity by valproic acid. Neuropsychopharmacology, 16 (3), 238–245. Chen, B., Wang, J.F., Hill, B.C. and Young, L.T. (1999) Lithium and valproate differentially regulate brain regional expression of phosphorylated CREB and c-Fos. Brain Res. Mol. Brain Res., 70 (1), 45–53. Spiliotaki, M., Salpeas, V., Malitas, P. et al. (2006) Altered glucocorticoid receptor signaling cascade in lymphocytes of bipolar disorder patients. Psychoneuroendocrin., 31 (6), 748–760. Meyer, T.E. and Habener, J.F. (1993) Cyclic adenosine 30 ,50 monophosphate response element binding protein (CREB) and related transcription-activating deoxyribonucleic acidbinding proteins. Endocr. Rev., 14 (3), 269–290. Shaywitz, A.J. and Greenberg, M.E. (1999) CREB: a stimulus-induced transcription factor activated by a diverse array of extracellular signals. Annu. Rev. Biochem., 68, 821–861. Kinney, J.W., Sanchez-Alavez, M., Barr, A.M. et al. (2009) Impairment of memory consolidation by galanin correlates with in vivo inhibition of both LTP and CREB phosphorylation. Neurobiol. Learn Mem., 92, 429–438. Finkbeiner, S. (2000) CREB couples neurotrophin signals to survival messages. Neuron, 25 (1), 11–14. Freeland, K., Liu, Y.Z. and Latchman, D.S. (2000) Distinct signalling pathways mediate the cAMP response element (CRE)-dependent activation of the calcitonin gene-related peptide gene promoter by cAMP and nerve growth factor. Biochem. J., 345 (Pt 2), 233–238. Kopnisky, K.L., Chalecka-Franaszek, E., Gonzalez-Zulueta, M. and Chuang, D.M. (2003) Chronic lithium treatment antagonizes glutamate-induced decrease of phosphorylated CREB in neurons via reducing protein phosphatase 1 and increasing MEK activities. Neuroscience, 116 (2), 425–435. Nibuya, M., Nestler, E.J. and Duman, R.S. (1996) Chronic antidepressant administration increases the expression of cAMP response element binding protein (CREB) in rat hippocampus. J. Neurosci., 16 (7), 2365–2372. Dowlatshahi, D., MacQueen, G.M., Wang, J.F. and Young, L. T. (1998) Increased temporal cortex CREB concentrations
169.
170.
171.
172.
173.
174.
175.
176.
177.
178.
179. 180.
181.
182.
|
243
and antidepressant treatment in major depression. Lancet, 352 (9142), 1754–1755. Zubenko, G.S., Hughes, H.B. 3rd, Maher, B.S. et al. (2002) Genetic linkage of region containing the CREB1 gene to depressive disorders in women from families with recurrent, early-onset, major depression. Am. J. Med. Genet., 114 (8), 980–987. Boer, U., Cierny, I., Krause, D. et al. (2008) Chronic lithium salt treatment reduces CRE/CREB-directed gene transcription and reverses its upregulation by chronic psychosocial stress in transgenic reporter gene mice. Neuropsychopharm., 33 (10), 2407–2415. Divish, M.M., Sheftel, G., Boyle, A. et al. (1991) Differential effect of lithium on fos protooncogene expression mediated by receptor and postreceptor activators of protein kinase C and cyclic adenosine monophosphate: model for its antimanic action. J. Neurosci. Res., 28 (1), 40–48. Manji, H.K., Potter, W.Z. and Lenox, R.H. (1995) Signal transduction pathways. Molecular targets for lithiums actions. Arch. Gen. Psychiatry, 52 (7), 531–543. Boer, U., Eglins, J., Krause, D. et al. (2007) Enhancement by lithium of cAMP-induced CRE/CREB-directed gene transcription conferred by TORC on the CREB basic leucine zipper domain. Biochem. J., 408 (1), 69–77. Heinrich, A., Boer, U., Tzvetkov, M. et al. (2009) Stimulation by lithium of the interaction between the transcription factor CREB and its co-activator TORC. Biosci. Rep., 29 (2), 77–87. Daniel, P.B. and Habener, J.F. (1998) Cyclical alternative exon splicing of transcription factor cyclic adenosine monophosphate response element-binding protein (CREB) messenger ribonucleic acid during rat spermatogenesis. Endocrinology, 139 (9), 3721–3729. Karpinski, B.A., Morle, G.D., Huggenvik, J. et al. (1992) Molecular cloning of human CREB-2: an ATF/CREB transcription factor that can negatively regulate transcription from the cAMP response element. Proc. Natl. Acad. Sci. USA, 89 (11), 4820–4824. Mamdani, F., Sequeira, A., Alda, M., Grof, P., Rouleau, G. and Turecki, G.(2007) No association between the PREP gene and lithium responsive bipolar disorder. BMC Psychiatry, 7, 9. Coyle, J.T. and Duman, R.S. (2003) Finding the intracellular signaling pathways affected by mood disorder treatments. Neuron, 38 (2), 157–160. Berridge, M.J. and Irvine, R.F. (1989) Inositol phosphates and cell signalling. Nature, 341 (6239), 197–205. Manji, H.K. and Lenox, R.H. (1999) Ziskind-Somerfeld Research Award. Protein kinase C signaling in the brain: molecular transduction of mood stabilization in the treatment of manic-depressive illness. Biol. Psychiatry, 46 (10), 1328–1351. Frey, B.N., Walss-Bass, C., Stanley, J.A. et al. (2007) Brainderived neurotrophic factor val66met polymorphism affects prefrontal energy metabolism in bipolar disorder. Neuroreport., 18 (15), 1567–1570. Rowe, M.K., Wiest, C. and Chuang, D.M. (2007) GSK-3 is a viable potential target for therapeutic intervention in bipolar disorder. Neurosci. Biobehav. Rev., 31 (6), 920–931.
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Mitochondrial Dysfunction and Oxidative Stress Tadafumi Kato1, Flavio Kapczinski2 and Michael Berk3 1
Laboratory for Molecular Dynamics of Mental Disorders, RIKEN Brain Science Institute, Saitama, Japan ISBD Hospital de Clinicas, UFRGS Brazil Porto Alegre, RS, Brazil 3 Barwon Health and the Geelong Clinic, University of Melbourne, Victoria, Australia 2
Introduction In this book, many biological aspects of bipolar disorder have been reviewed, such as genetics, brain imaging, neurotransmitters, neuroendocrinology, circadian rhythms and pharmacology. Although the biological evidence reported in bipolar disorder is yet to be integrated, mitochondrial dysfunction hypothesis has a potential to build up an integrated understanding of the biology of bipolar disorder. In this chapter, the authors try to put together these fragmental findings into a cohesive unifying hypothesis. Details of findings suggestive of mitochondrial dysfunction introduced in this chapter are also shown in other chapters. Three broad areas will be covered, pre-clinical, clinical and treatment implications.
In addition, magnetic resonance spectroscopic studies showed decreased levels of N-acetylaspartate, a marker of neuronal viability (see Chapter 14 on imaging techniques in bipolar disorder), and structural brain imaging studies showed decreased volume of several brain areas (see Chapter 13, Structural Brain Imaging in Bipolar Disorder) in patients with bipolar disorder. Lithium and valproate, two major mood stabilizers that are effective in bipolar disorder, reportedly have neuroprotective effects [5], at least partly by acting on mitochondria [6]. These findings altogether suggest that patients with bipolar disorder have vulnerability at the metabolic and cellular level, and mood stabilizers may exert their efficacy by improving such cellular vulnerability.
Cellular vulnerability in bipolar disorder Several lines of evidence show that vulnerability at the cellular level is involved in the pathophysiology of bipolar disorder. An increased incidence of subcortical hyperintensity (SCH) lesions was found in 7 out of 10 studies [1]. Because there is no specific location of the lesion causing bipolar disorder, increased incidence of SCH suggests that patients with bipolar disorder might have vulnerability at the cellular level to cellular stress. Amongst the studies of peripheral blood cells, increased levels of calcium in platelets or cultured lymphoblastoid cells are most replicated findings, supported by 11 out of 15 studies [2,3]. Because calcium is an important mediator of apoptosis, this may also be relevant to cellular vulnerability in the cells of patients with bipolar disorder. Indeed, enhanced apoptosis was reported in cultured neuroepitherium derived from patients with bipolar disorder [4].
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Phosphorous magnetic resonance spectroscopy in bipolar disorder The pathophysiological mechanism of how such vulnerability is caused in bipolar disorder is not known. The mitochondrial dysfunction hypothesis may account for such a mechanism. This hypothesis was first proposed based on the findings in phosphorus-31 magnetic resonance spectroscopy (31 P-MRS). The principle of MRS is summarized in Chapter 14, on imaging techniques in bipolar disorder. In the early 1990s, Kato and colleagues studied brain phosphorus metabolism, using 31 P-MRS in patients with bipolar disorder, and reported that phosphocreatine (PCr), a high energy phosphate found in the brain and muscles, was decreased in the frontal lobes in patients with severe depression [7]. Subsequent studies suggested that such findings in the left frontal region were seen in patients with bipolar depression, especially bipolar II disorder [8], and correlated with scores on the Hamilton rating scale [9]. Photic stimulation-induced reduction of PCr in the occipital cortex was exaggerated in patient with lithium-resistant bipolar disorder [10].
Mitochondrial Dysfunction and Oxidative Stress
The other finding, suggestive of mitochondrial dysfunction, was reduced intracellular pH observed in euthymic patients with bipolar disorder [11]. This finding was also seen in drug-free euthymic patients with bipolar disorder, and decreased pH was associated with the presence of white matter hyperintensity lesions detected by T2-weighted magnetic resonance imaging (MRI) [12]. Reduced pH was also observed in the basal ganglia and in the whole head 31 P-MR spectra [13]. Uridine, a drug used for mitochondrial diseases, is reported to alter intracellular pH in patients with bipolar disorder [14]. Amongst these findings, reduced PCr [15] and exaggerated PCr response to photic stimulation [16] were also reported in patients with mitochondrial diseases, especially chronic external ophthalmoplegia (CPEO).
Role of mitochondrial DNA deletion in bipolar disorder Mitochondrial diseases are caused by mutations of mitochondrial DNA (mtDNA). MtDNA is a 16 kb circular DNA, existing in mitochondria. There are multiple copies of mtDNA in a mitochondrion. It is speculated that mtDNA originated from ancient symbiotic life. MtDNA encodes subunits of mitochondrial proteins responsible for oxidative phosphorylation, and also tRNAs and rRNAs. Genes for enzymes required for the replication and maintenance of mtDNA are encoded in the nuclear genome. There are two types of mitochondrial diseases. One of these diseases is caused by maternally inherited heteroplasmic point mutations of mtDNA. A representative disease of this kind is Mitochondrial myopathy, Encephalopathy, Lactic Acidosis, and Stroke-like episodes (MELAS), mostly caused by mtDNA 3243A > G. mutation. The other type of disease is associated with accumulation of multiple deletions of mtDNA that is caused by autosomally inherited mutations in genes regulating mtDNA maintenance. Autosomally inherited Chronic Progressive External Opthalmoplegia (CPEO) (adCPEO) is a representative disease of this kind. Suomalainen and colleagues reported a case with adCPEO with severe retarded depression [17]. At the autopsy, the patient was found to have mtDNA deletions in the brain. Importantly, the amount of mtDNA deletions was much higher in the frontal cortex and basal ganglia, compared with muscles. This report from Finland first suggested that accumulation of mtDNA deletions in the brain might cause mood disorders. Stimulated by this finding, Stine and colleagues searched for the mtDNA deletions in the postmortem brains of patients with bipolar disorder, but they could not detect any deletions using Southern blotting [18]. Using the same samples, however, Kato and colleagues found that the mtDNA 4977 bp common deletion was slightly but significantly increased in
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bipolar disorder [19]. No such increase of 4977 bp deletion was found in bipolar disorder in the Stanley Brain Bank samples [20,21]. The next impressive work in this field was reported from Italy [22]. Siciliano and colleagues reported a family with adCPEO linked with a missense mutation of adenine nucleotide translocator 1 (ANT1) (L98P). They diagnosed the members of this family using DSM-IV criteria, and reported that all four living adult patients with CPEO in this family also had bipolar disorder. The proband, who had onset of CPEO at age 40, had bipolar disorder since her teens. Her sister having CPEO since her twenties also had bipolar disorder since her teens. The other sister, who had muscle symptoms at age 42, had onset of bipolar disorder in her 20s. Their mother had onset of bipolar disorder and CPEO at age 45. In this family, it seems as if bipolar disorder was the most prominent phenotype of the mutation. More recently, Fattal and colleagues applied the Mini International Neuropsychiatric Interview to 36 patients with mitochondrial diseases [23] and found that 6 (17%) of them had bipolar disorder and 19 (54%) had lifetime major depression. The average onset of mental disorder was 7.5 years before the diagnosis of mitochondrial diseases. There are several other studies and case reports supporting the possible relationship between mitochondrial diseases and bipolar disorder [23,24]. CPEO is a multi-system disease characterized not only by muscle symptoms such as ophthalmoplegia but also by many other symptoms. Mutations of several genes cause CPEO; POLG (polymerase g) [25], ANT1 (adenine nucleotide translocator 1) [26], Twinkle [27], POLG2 (accessory subunit of polymerase g) [28], and so on. These reports suggested that bipolar disorder and depression may be one type of manifestation of symptoms of adCPEO.
Gene expression analysis Evidence related to mitochondrial dysfunction of bipolar disorder was also reported from comprehensive gene expression analysis. Konradi and colleagues performed comprehensive gene expression analysis in the postmortem hippocampus, and found that mitochondria related genes were globally downregulated in patients with bipolar disorder [29]. Although sample pH and agonal factors, terminal condition before death, are known to profoundly affect expression levels of mitochondria related genes [30,31], there was no significant difference in sample pH amongst groups in their samples [29]. They interpreted this finding as suggestive of mitochondrial dysfunction in bipolar disorder. The same finding of global down-regulation of mitochondria related genes was replicated by other investigators [32–34]. However, the interpretation of this finding is
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still controversial. In two of these studies, mitochondriarelated gene were up-regulated rather than down-regulated when agonal/pH factors were controlled [32,33]. In the other study, it was speculated that reduced pH observed in patients with bipolar disorder may account for the downregulation of mitochondrial genes [34]. Interaction between agonal factors or medication and the disease for this finding is possible. Munakata and colleagues analysed the expression levels of mitochondria related genes, and found that LARS2 showed most prominent up-regulation [35]. LARS2 encodes an enzyme catalysing aminoacylation of leucine transfer RNA. LARS2 was up-regulated in transmitochondrial cybrids carrying the mtDNA 3243G mutation within tRNALeu(UUR). When the 3243 mutation was screened using a sensitive method with protein nucleic acid (PNA), accumulation of the 3243G in the brain was found in 2 of 15 patients with bipolar disorder and 1 of 15 patients with schizophrenia, but not in the 15 controls.
Genetics Excess transmission of bipolar disorder from a mother compared with from a father, has been noted in early genetic studies of bipolar disorder [36]. McMahon and colleagues suggested that such phenomenon might be caused by maternal transmission of mtDNA [37]. However, no mutations causative for bipolar disorder were identified by sequencing of whole mtDNA in the probands in maternally inherited pedigrees [38,39]. Munakata and colleagues also sequenced mtDNA in six patients with bipolar disorder, who developed mitochondrial disease-like somatic symptoms after the diagnosis of bipolar disorder. Amongst the sequence variations found in these subjects, 3644C, a missense mutation in a complex I subunit (ND1), was suggested to have pathological significance because this mutation caused impaired complex I activity in transmitochondrial cybrids, and this variation was significantly associated with bipolar disorder in Japanese case control analysis. While 9 out of 630 (1.4%) patients with bipolar disorder had this mutation, only 1 out of 734 controls (0.14%) had this mutation. Although mtDNA 10398 polymorphism [40] and NDUFV2 [41] encoding a complex I subunit were also reported to be associated with bipolar disorder, such findings should be treated with caution, because association finding of common variations in this size of patient population is difficult to reproduce [42].
the promoter of calmodulin kinase IIa [43]. The mice had mtDNA deletions in various brain regions, such as frontal cortex and hippocampus. Four other lines of mutant mice carrying POLG mutations have been reported so far; cardiac muscle specific D181A mice [44], mutant POLG knock-in mouse (D257A) [45,46] and cardiac muscle specific mutant POLG (Y955C) transgenic mouse [47]. While cardiac muscle specific transgenic mice showed cardiomyopathy, knock-in mice showed various ageing-associated phenotypes, such as kyphosis and alopecia. Neurobehavioral phenotypes of the two knock-in mice strains have not been reported yet. Although multiple deletions were first noticed in patients with CPEO, point mutations were also increased in the tissues of these mice. There is an ongoing debate as to whether deletions or point mutations are more important, for the phenotypes of POLG mutant mice [48]. The neuron specific mutant POLG (mPOLG) transgenic (Tg) mice did not show marked abnormality in sensorimotor functions and learning and memory. On the other hand, they showed altered intra-day wheel running activity rhythm, with high activity at the beginning of, as well as at the end of, the light phase [43]. This altered intra-day activity rhythm was improved by electroconvulsive stimulation [49]. The wheel running activity was decreased in the mice, and after the treatment with amitriptyline, a tricyclic antidepressant that can cause a manic switch in patients with bipolar disorder, the Tg mice showed manic switch-like enhancement of activity. Female mice showed robust periodic change of wheel running activity associated with oestrous cycle. This periodic activity change, as well as altered intra-day rhythm, was improved after the lithium treatment [43]. These findings supported the three validity criteria as an animal model; construct validity, supported by comorbidity of bipolar disorder with CPEO, face validity, periodic activity change and altered intra-day rhythm, and predictive validity, that is, effect of lithium treatment.
Consequence of mitochondrial dysfunction There are several possible explanations for the cause of these characteristic behavioural phenotypes. One is a calcium signalling abnormality, resulting in altered neuroplasticity. The second is progressive cell loss in particular brain region(s). The third possibility is increased generation of reactive oxygen species due to mitochondrial dysfunction.
Animal models
Calcium signalling
To study the possible role of mtDNA mutations in the brain in pathophysiology of bipolar disorder, we generated a transgenic mouse carrying mutant POLG (D181A) under
As discussed above, calcium signalling abnormalities have been reported in blood cells obtained from patients with bipolar disorder [3,50]. Basal calcium levels and calcium
Mitochondrial Dysfunction and Oxidative Stress
response to phosphoinositide-linked receptor stimulation were reported to be elevated in patients with bipolar disorder. Calcium release from endoplasmic reticulum (ER) is followed by calcium uptake by mitochondria at microdomain between these two organella. Mitochondrial calcium uptake has been reported to be involved in neuronal functions, such as exocytosis and neuroplastic changes [51]. Thus, mitochondrial dysfunction may cause altered neural functions associated with impairment of mitochondrial calcium signalling. Because the driving force behind calcium uptake by mitochondria is the proton gradient generated by mitochondrial respiratory chain, mitochondrial dysfunction may decrease membrane potential and cause impaired calcium uptake. When calcium retention capacity (CRC) was measured in isolated mitochondria obtained from the mutant POLG Tg mice, but there was no difference of CRC [52]. Contrary to their expectation, mitochondria isolated from the brains of Tg mice showed enhanced calcium uptake rate. Gene expression analysis of the brains of the Tg mice showed down-regulation of cyclophilin D (CypD) [52]. CypD is a component of permeability transition pore. A CypD inhibitor, cyclosporin A, mimicked the enhanced uptake rate in the mitochondria of Tg mice. Thus, they concluded that decrease of CypD is related to the enhanced calcium uptake rate in the mitochondria derived from Tg mice. CypD might become a potential target of drug development.
Progressive cell loss POLG mutations are not specific risk factors for bipolar disorder. Homozygotes or compound heterozygotes of POLG mutations show Alpers syndrome, CPEO or ataxia [53]. POLG mutations are also related to complex diseases, such as Parkinsons disease and diabetes mellitus [54]. Thus, POLG mutation is not a specific risk factor for bipolar disorder, but may be related to cellular vulnerability in general. In the case of Parkinsons disease, the substantia nigra has specific susceptibility to accumulate mtDNA deletions, and this may cause specific loss of dopaminergic neurons in susceptible individuals [55]. Bipolar disorder is associated with characteristic clinical course of shortening of episode interval after repeated relapses. This phenomenon has been interpreted as reflecting behavioural sensitization or kindling [56]. However, the findings noted above imply the other possibility; there are mood-stabilizing neurons in the brain, and these are gradually impaired in patients with bipolar disorder [2]. Neuropathological studies showed equivocal findings in various brain regions related to emotion, such as anterior cingulate cortex and hippocampus [2]. Reduction of neuron numbers in these regions is reported mainly in GABAergic interneurons rather than pyramidal neurons [57]. Thus,
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GABAergic interneurons may be related to the pathology of bipolar disorder. Altered intra-day activity rhythms, similar to the mutant POLG Tg mouse, have been reported in several mutant mice, and these genes are related to retino-hypothalamic pathway [58]. The retino-hypothalamic pathway is important for the regulation of circadian rhythm by light. Patients with bipolar disorder are reported to have various abnormalities of circadian rhythm regulation, such as altered melatonin response to light [59]. Thus, the retino-hypothalamic pathway may be relevant to the pathology of bipolar disorder.
Oxidative stress and mitochondrial dysfunction: a vicious cycle propelled by dopaminergic hyperactivity? Under physiological conditions, mitochondria are the major sources of reactive oxygen species (ROS), which are quenched by the anti-oxidant enzymes. In situations of imbalance between pro-oxidant/antioxidant states, oxidative damage may take place. The central nervous system is extremely vulnerable to peroxidative damage, since it is rich in oxidizable substrate, has a high oxygen tension (metabolizes 20% of total body oxygen) and a relatively low antioxidant capacity [60,61]. Excessive formation of ROS may present a threat to mitochondrial integrity and in turn, mitochondrial dysfunction can further increase the production of ROS [62]. As noted above, a number of postmortem studies have demonstrated that genes that regulate mitochondrial function are down-regulated in the hippocampus and prefrontal cortex of individuals with BD [29,32,34,63]. Another source of increased oxidative stress in BD episodes may be the increased dopaminergic system function during manic episodes [64]. First, dopamine (DA) is metabolized via monoamine oxidase (MAO) to produce hydrogen peroxide (H2O2) and dihydroxyphenylacetic acid [65,66]. H2O2, if not reduced by cellular antioxidant mechanisms such as GSH and GSH peroxidase, can react with transition metals such as iron to form hydroxyl radicals [67]. These molecules can immediately react with lipids, DNA and susceptible amino acids, thereby causing cellular damage [67]. Second, DA can suffer nonenzymatic hydroxylation in presence of Fe2 þ and H2O2 and form 6-hydroxydopamine (6-OHDA), a highly reactive quinone. This quinone is toxic to the nervous systems, and the mechanisms involved in this toxicity include endoplasmic reticulum-stress (ER-stress), activated GSK-3b by phosphorylation at tyrosine 216 and inhibition of Akt (phosphorilation at Ser473) [68]. Glutathione-S-transferase activity (GSH) provides a defence system against this toxic quinone [69,70]. MRS studies showed increased levels of Glu/Gln/GABA in adult bipolar patients (see Chapter 14, on imaging techniques in bipolar disorder). NMDA receptors are
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ionotrophic glutamate receptors that, when stimulated, allow the passage of calcium and sodium into the cell, thereby promoting the activation of p38, JNK and p53 that are generally proapoptotic [71]. In addition, JNK is related to induction of oxidative stress [72]. NMDA receptor activation triggers the activation of CAMKIV, present in mitochondrial external membrane, which may activate nitric oxide synthases (NOS1 and NOS3), thereby leading to increased nitric oxide production [73]. Activation of NMDA receptors also increases intracellular Ca2 þ levels, which when associated with oxidative stress, may trigger endoplasmic reticulum stress [74]; mitochondrial Ca2 þ uptake in combination with NO production may trigger the collapse of mitochondrial membrane potential, culminating in delayed cell death and release of free radicals [73].
Oxidative stress markers in bipolar disorder Previous studies have replicated that BD patients have higher lipid peroxidation and alterations in antioxidant enzymes in peripheral blood [75–77]. More recently, Andreazza et al. [78] studied the oxidative stress status in manic, depressive and euthymic subjects and found that individuals with BD have increased serum thiobarbituric acid reactive substance TBARS – a measure of lipid peroxidation – across all mood states. This is in line with a gene expression profile study showing that several antioxidation genes are down-regulated in BD [79]. It is well-known that oxidative stress is associated with DNA damage, endothelial dysfunction and telomere shortening. Notably, it has been recently demonstrated that BD patients have a marked increase of DNA damage in white blood cells, as assessed by single cell gel electrophoresis, and such DNA damage was correlated with the severity of symptoms [80]. Similarly, it has been found that some parameters of oxidative stress can be normalized by mood stabilizing treatment [81,82]. This is in accordance with preclinical studies showing that lithium and valproate exert antioxidant effects in vitro and in vivo [83,84]. A recent trial, assessing the potential application of the anti-oxidant N-acetyl-cysteine, has shown promising results in BD [85]. In addition, it has been reported that individuals with bipolar and unipolar disorder have accelerated telomere shortening, a measure of accelerated ageing [86]. The most important factor in accelerated telomere shortening is oxidative damage [87]. Telomere shortening is a marker of senescence and has been observed in several general medical conditions as cardiovascular disease [88] and may correlate to the excess of physical comorbidity presented by BD patients [89]. In a recent paper, Kapczinski et al. [90] have shown that within acute manic episodes, the increase in serum levels of TBARS occurs in tandem with a lowering in serum brain derived neurotrophic factor (BDNF). As mentioned above, this
can be construed as a consequence of endoplasmic reticulum stress due to pro-oxidant stated and consequent impairment in storage, folding and intracellular trafficking of BDNF. In this manner, acute mood episodes, particularly of mania, seem to be related to increased cellular damage via oxidative stress and a less active neurotrophic defence system. The net result of such episode-related changes may be cell endangerment and activation of pro-apoptotic cascades [91,92].
Treatment studies The evidence of oxidative stress as a component of the pathophysiology of major psychiatric disorders has resulted in prior therapeutic attempts to modulate oxidation biology. Many of these studies have targeted compounds that are not a core part of endogenous defences. Trials of conventional antioxidants, such as vitamins E and C, have showed inconsistent results in the treatment of schizophrenia and for tardive dyskinesia, and as a result have not been adopted by clinicians [93,94]. Some impact on symptomatology has been reported [95–98]. Methodological issues, including sample size, and the use of non-placebo controlled and non-randomized designs, make interpretation difficult. A further group of studies have examined the impact of known and widely used agents, and attempted to elucidate if they have any impact on oxidative pathways.
Effects of known treatment on oxidative systems Supporting a role of oxidative biology in the pathophysiology of major psychiatric disorders is a consistent thread of evidence that known treatments of diverse classes are able to modulate oxidative processes. It has been shown that oxidative systems are modulated by atypical antipsychotics. In some studies, state dependant changes are seen, such that oxidative dysregulation changes with symptom resolution. In two published studies in schizophrenia, Zhang described that baseline serum SOD, which differed from control values, shifted towards control levels with treatment [99,100]. Similarly, Dhakale showed that MDA and ascorbic acid tended to normalize with treatment [96]. Atypical and typical antipsychotics appear to differ in their oxidative profile. In animal models, haloperidol but not atypical agents were shown to increase oxidative stress [101]. The atypical agents clozapine, olanzapine and risperidone, reversed the haloperidol induced oxidative stress [102]. The glutathione precursor, N-acetylcysteine (NAC) is reported to reduce haloperidol induced oxidative stress [103]. The atypicals, olanzapine and quetiapine, have been shown to protect PC12 cells against oxidative stress [104,105].
Mitochondrial Dysfunction and Oxidative Stress
A handful of studies have shown normalization of oxidative disturbances following antidepressant treatment, supporting a modulatory role for these agents on oxidative systems [106–108], although there are negative studies [109]. In preclinical studies, varying antidepressants have been reported to correct GSH depletion following the inescapable shock behavioural model of depression [110]. Venlafaxine, moclobemide and phenelzine have all been shown to have effects on oxidative systems [111–113]. Similarly, mood stabilizers have documented antioxidant properties. In the amphetamine model of mania, both lithium and valproate prevented amphetamine-induced hyperactivity and prevented lipid peroxidation [84]. Valproate inhibits lipid peroxidation and protein oxidation in neuronal tissue culture models [114]. Both lithium and valproate block glutamate-induced intracellular calcium release, lipid peroxidation, protein oxidation, DNA fragmentation and cell death [83], and they additionally increase expression of the endoplasmic reticulum stress proteins calreticulin, GRP78 and GRP94 [115], levels of the anti-apoptotic factor bcl-2 [116], glutamate-cysteine ligase and glutathione [117], and they diminish cytochrome c release and caspase-2 activation [118]. They therefore share multiple actions across oxidative targets. Carbamazepine and lamotrigine share the ability to increase glutathione levels and glutamate-cysteine ligase gene expression, and this suggests common mechanisms of action amongst treatments used [117]. Indeed, these actions on oxidative biology, in addition to the shared effects on neurotrophins, unite these classes of agents with otherwise superficially diverse receptor profiles. An additional line of evidence supporting the role of oxidative stress in bipolar disorder derives from treatment studies demonstrating normalization of peripheral oxidative markers with treatment [76,81,119,120]. In a case report of twins, both presenting with mania, increased baseline levels of TBARS, SOD and DNA damage, and decreased CAT were described. The twin who responded to treatment showed normalization of TBARS and SOD; in contrast, oxidative markers did not change in the twin who refused treatment and remained manic [81]. Lithium treatment of mania has been shown to reduce lipid peroxidation, as measured by TBARS and SOD, returning them to control levels [82]. Similarly, treatment with lithium or the combination of lithium and olanzapine in individuals with mania has been shown to normalize some oxidative parameters, including TBARS, catalase, glutathione peroxidase and SOD [121]. Treatment of bipolar depression has also been shown to modify SOD [122].
Glutathione precursors Antioxidants have widely different pharmacokinetic and pharmacodynamic profiles; while vitamin E buffers lipid radicals, uric acid and bilirubin are free radical scavengers
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and coenzyme Q10 decreases mitochondrial ROS generation. Because of the centrality of the GSH system, GSH is probably the most generic antioxidant. GSH itself is not bioavailable and NAC, which is a precursor of cysteine, the rate-limiting step in GSH synthesis, is a viable precursor of GSH. NAC has been shown to replenish GSH in animal models of GSH depletion [123]. It also has the advantage of known tolerability and safety, in addition to widespread availability. NAC is used widely available for paracetamol overdose, as a renal protectant and as a mucolytic. Early trials of NAC have suggested efficacy in cocaine use [124–127] and refractory obsessive compulsive disorder [128], as well as OCD spectrum disorders [129]. Beneficial effects of NAC on mood have been documented in a double-blind, placebo-controlled study of NAC in patients with mild chronic bronchitis [130]. In schizophrenia, a randomized, multicentre, double-blind, placebo-controlled study of 140 patients showed moderate effect sizes on the PANSS negative, general and total scales, and the CGI improvement and severity scales. NAC treatment also reduced akathisia [131]. In a six-month randomized, double-blind, multicentre, placebo-controlled study of NAC, dosed at 2 g daily (N ¼ 75), improvements in the moderate to high effect sizes on measures of depression, quality of life and functionality in bipolar disorder were seen. As with the trial in schizophrenia, effects were lost after treatment discontinuation. In this trial, adverse effects did not differentiate from placebo, again akin to the results of the schizophrenia trial [85]. These data suggest that glutathione depletion may be a remediable component of the
Treatment
Pathophysiology
Atypical Antipsychotics
Dopaminergic Dysfunction
N-Acetylcysteine
Oxidative stress nDNA mutations
Vicious cycle
mtDNA mutations Lithium Valproate
ER stress dysfunction Mitochondrial Ca2+ dysregulation
Uridine Coenzyme Q10
Cellular vulnerability
Altered Neuroplasticity
Impairment of mood stabilizing neurons Fig. 1 Role of mitochondrial dysfunction and oxidative stress in bipolar disorder.
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etiopathogenesis of bipolar disorder, and plays a role in the genesis of depressive symptoms in particular. 10.
Conclusion In conclusion, mounting evidence suggests the role of mitochondrial function as aetiological factor for bipolar disorder. Mitochondrial dysfunction is suggested to cause oxidative stress. Multiple lines of evidence support the role of oxidative stress in the pathophysiology of bipolar disorder. Mood stabilizing agents have antioxidant properties and treatment to ameliorate oxidative stress such as Naetylcysteine is effective for bipolar disorder. Based on these lines of evidence, we here propose that vicious cycle of dopaminergic hyperactivity associated with mania and oxidative stress would cause bipolar disorder in individuals with mitochondrial dysfunction, and established and proposed treatments for bipolar disorder are effective for some point of this vicious cycle (Figure 1). This integrative hypothesis of bipolar disorder would explain many of characteristic features of bipolar disorder, and provide insight into new therapeutic targets for this difficult disorder.
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References 1. Videbech, P. (1997) MRI findings in patients with affective disorder: a meta-analysis. Acta Psychiatr. Scand., 96, 157–168. 2. Kato, T. (2008) Molecular neurobiological basis of bipolar disorder: A disease of “mood stabilizing neurons?” Trends Neurosci., 31, 495–503. 3. Warsh, J.J., Andreopoulos, S. and Li, P.P. (2004) Role of intracellular calcium signaling in the pathophysiology and pharmacotherapy of bipolar disorder: current status. Clinical Neuroscience Research, 4, 201–213. 4. McCurdy, R.D., Feron, F., Perry, C. et al. (2006) Cell cycle alterations in biopsied olfactory neuroepithelium in schizophrenia and bipolar I disorder using cell culture and gene expression analyses. Schizophr. Res., 82, 163–173. 5. Nonaka, S., Hough, C.J. and Chuang, D.M. (1998) Chronic lithium treatment robustly protects neurons in the central nervous system against excitotoxicity by inhibiting Nmethyl-D-aspartate receptor-mediated calcium influx. Proc. Natl. Acad. Sci. USA, 95, 2642–2647. 6. Chen, G., Huang, L.D., Jiang, Y.M. et al. (1999) The moodstabilizing agent valproate inhibits the activity of glycogen synthase kinase-3. J. Neurochem., 72, 1327–1330. 7. Kato, T., Takahashi, S., Shioiri, T. et al. (1992) Brain phosphorous metabolism in depressive disorders detected by phosphorus-31 magnetic resonance spectroscopy. J. Affect. Disord., 26, 223–230. 8. Kato, T., Takahashi, S., Shioiri, T. et al. (1994) Reduction of brain phosphocreatine in bipolar II disorder detected by phosphorus-31 magnetic resonance spectroscopy. J. Affect. Disord., 31, 125–133. 9. Kato, T., Shioiri, T., Murashita, J. et al. (1995) Lateralized abnormality of high energy phosphate metabolism in the
16.
17.
18.
19.
20.
21.
22.
23.
frontal lobes of patients with bipolar disorder detected by phase-encoded 31P-MRS. Psychol. Med., 25, 557–566. Murashita, J., Kato, T., Shioiri, T. et al. (2000) Altered brain energy metabolism in lithium-resistant bipolar disorder detected by photic stimulated 31P-MR spectroscopy. Psychol. Med., 30, 107–115. Kato, T., Takahashi, S., Shioiri, T. et al. (1993) Alterations in brain phosphorous metabolism in bipolar disorder detected by in vivo 31P and 7Li magnetic resonance spectroscopy. J. Affect. Disord., 27, 53–59. Kato, T., Murashita, J., Kamiya, A. et al. (1998) Decreased brain intracellular pH measured by 31P-MRS in bipolar disorder: a confirmation in drug-free patients and correlation with white matter hyperintensity. Eur. Arch. Psychiatry Clin. Neurosci., 248, 301–306. Hamakawa, H., Murashita, J., Yamada, N. et al. (2004) Reduced intracellular pH in the basal ganglia and whole brain measured by 31P-MRS in bipolar disorder. Psychiatry Clin. Neurosci., 58, 82–88. Jensen, J.E., Daniels, M., Haws, C. et al. (2008) Triacetyluridine (TAU) decreases depressive symptoms and increases brain pH in bipolar patients. Exp. Clin. Psychopharm., 16, 199–206. Barbiroli, B., Montagna, P., Martinelli, P. et al. (1993) Defective brain energy metabolism shown by in vivo 31P MR spectroscopy in 28 patients with mitochondrial cytopathies. J. Cereb. Blood Flow Metab., 13, 469–474. Rango, M., Bozzali, M., Prelle, A. et al. (2001) Brain activation in normal subjects and in patients affected by mitochondrial disease without clinical central nervous system involvement: a phosphorus magnetic resonance spectroscopy study. J. Cereb. Blood Flow Metab., 21, 85–91. Suomalainen, A., Majander, A., Haltia, M. et al. (1992) Multiple deletions of mitochondrial DNA in several tissues of a patient with severe retarded depression and familial progressive external ophthalmoplegia. J. Clin. Invest., 90, 61–66. Stine, O.C., Luu, S. and Zito, M. (1993) The possible association between affective disorder and partially deleted mitochondrial DNA. Biol. Psychiatry, 42, 311–316. Kato, T., Stine, O.C., McMahon, F.J. et al. (1997) Increased levels of a mitochondrial DNA deletion in the brain of patients with bipolar disorder. Biol. Psychiatry, 42, 871–875. Sabunciyan, S., Kirches, E., Krause, G. et al. (2007) Quantification of total mitochondrial DNA and mitochondrial common deletion in the frontal cortex of patients with schizophrenia and bipolar disorder. J. Neural. Transm., 114, 665–674. Fuke, S., Kametani, M. and Kato, T. (2008) Quantitative analysis of the 4977-bp common deletion of mitochondrial DNA in postmortem frontal cortex from patients with bipolar disorder and schizophrenia. Neurosci. Lett., 439, 173–177. Siciliano, G., Tessa, A., Petrini, S. et al. (2003) Autosomal dominant external ophthalmoplegia and bipolar affective disorder associated with a mutation in the ANT1 gene. Neuromuscul. Disord., 13, 162–165. Fattal, O., Link, J., Quinn, K. et al. (2007) Psychiatric comorbidity in 36 adults with mitochondrial cytopathies. CNS Spectr., 12, 429–438.
Mitochondrial Dysfunction and Oxidative Stress 24. Kato, T. (2001) The other, forgotten genome: mitochondrial DNA and mental disorders. Mol. Psychiatry, 6, 625–633. 25. Van Goethem, G., Dermaut, B., Lofgren, A. et al. (2001) Mutation of POLG is associated with progressive external ophthalmoplegia characterized by mtDNA deletions. Nat. Genet., 28, 211–212. 26. Kaukonen, J., Juselius, J.K., Tiranti, V. et al. (2000) Role of adenine nucleotide translocator 1 in mtDNA maintenance. Science, 289, 782–785. 27. Spelbrink, J.N., Li, F.Y., Tiranti, V. et al. (2001) Human mitochondrial DNA deletions associated with mutations in the gene encoding Twinkle, a phage T7 gene 4-like protein localized in mitochondria. Nat. Genet., 28, 223–231. 28. Longley, M.J., Clark, S., Yu Wai Man, C. et al. (2006) Mutant POLG2 disrupts DNA polymerase gamma subunits and causes progressive external ophthalmoplegia. Am. J. Hum. Genet., 78, 1026–1034. 29. Konradi, C., Eaton, M., MacDonald, M.L. et al. (2004) Molecular evidence for mitochondrial dysfunction in bipolar disorder. Arch. Gen. Psychiatry, 61, 300–308. 30. Li, J.Z., Vawter, M.P., Walsh, D.M. et al. (2004) Systematic changes in gene expression in postmortem human brains associated with tissue pH and terminal medical conditions. Hum. Mol. Genet., 13, 609–616. 31. Tomita, H., Vawter, M.P., Walsh, D.M. et al. (2004) Effect of agonal and postmortem factors on gene expression profile: quality control in microarray analyses of postmortem human brain. Biol. Psychiatry, 55, 346–352. 32. Iwamoto, K., Bundo, M. and Kato, T. (2005) Altered expression of mitochondria-related genes in postmortem brains of patients with bipolar disorder or schizophrenia, as revealed by large-scale DNA microarray analysis. Hum. Mol. Genet., 14, 241–253. 33. Vawter, M.P., Tomita, H., Meng, F. et al. (2006) Mitochondrial-related gene expression changes are sensitive to agonal-pH state: implications for brain disorders. Mol. Psychiatry, 11, 615, 663–679. 34. Sun, X., Wang, J.F., Tseng, M. et al. (2006) Downregulation in components of the mitochondrial electron transport chain in the postmortem frontal cortex of subjects with bipolar disorder. J. Psychiatry Neurosci., 31, 189–196. 35. Munakata, K., Iwamoto, K., Bundo, M. et al. (2005) Mitochondrial DNA 3243A>G mutation and increased expression of LARS2 gene in the brains of patients with bipolar disorder and schizophrenia. Biol. Psychiatry, 57, 525–532. 36. Winokur, G. and Reich, T. (1970) Two genetic factors in manic-depressive disease. Compr. Psychiatry, 11, 93–99. 37. McMahon, F.J., Stine, O.C., Meyers, D.A. et al. (1995) Patterns of maternal transmission in bipolar affective disorder. Am. J. Hum. Genet., 56, 1277–1286. 38. Kirk, R., Furlong, R.A., Amos, W. et al. (1999) Mitochondrial genetic analyses suggest selection against maternal lineages in bipolar affective disorder. Am. J. Hum. Genet., 65, 508–518. 39. McMahon, F.J., Chen, Y.S., Patel, S. et al. (2000) Mitochondrial DNA sequence diversity in bipolar affective disorder. Am. J. Psychiatry, 157, 1058–1064.
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40. Kato, T., Kunugi, H., Nanko, S. et al. (2001) Mitochondrial DNA polymorphisms in bipolar disorder. J. Affect. Disord., 62, 151–164. 41. Washizuka, S., Kakiuchi, C., Mori, K. et al. (2003) Association of mitochondrial complex I subunit gene NDUFV2 at 18p11 with bipolar disorder. Am. J. Med. Genet., 120B, 72–78. 42. Newton-Cheh, C. and Hirschhorn, J.N. (2005) Genetic association studies of complex traits: design and analysis issues. Mutat. Res., 573, 54–69. 43. Kasahara, T., Kubota, M., Miyauchi, T. et al. (2006) Mice with neuron-specific accumulation of mitochondrial DNA mutations show mood disorder-like phenotypes. Mol. Psychiatry, 11, 577–593. 523. 44. Zhang, D., Mott, J.L., Chang, S.W. et al. (2000) Construction of transgenic mice with tissue-specific acceleration of mitochondrial DNA mutagenesis. Genomics, 69, 151–161. 45. Trifunovic, A., Wredenberg, A., Falkenberg, M. et al. (2004) Premature ageing in mice expressing defective mitochondrial DNA polymerase. Nature, 429, 417–423. 46. Kujoth, G.C., Hiona, A., Pugh, T.D. et al. (2005) Mitochondrial DNA mutations, oxidative stress, and apoptosis in mammalian aging. Science, 309, 481–484. 47. Lewis, W., Day, B.J., Kohler, J.J. et al. (2007) Decreased mtDNA, oxidative stress, cardiomyopathy, and death from transgenic cardiac targeted human mutant polymerase gamma. Lab. Invest., 87, 326–335. 48. Vermulst, M., Wanagat, J., Kujoth, G.C. et al. (2008) DNA deletions and clonal mutations drive premature aging in mitochondrial mutator mice. Nat. Genet., 40, 392–394. 49. Kasahara, T., Kubota, M., Miyauchi, T. et al. (2008) A marked effect of electroconvulsive stimulation on behavioral aberration of mice with neuron-specific mitochondrial DNA defects. PLoS One, 3, e1877. 50. Kato, T. (2008) Role of mitochondrial DNA in calcium signaling abnormality in bipolar disorder. Cell Calcium, 44, 92–102. 51. Mattson, M.P. (2007) Mitochondrial regulation of neuronal plasticity. Neurochem. Res., 32, 707–715. 52. Kubota, M., Kasahara, T., Nakamura, T. et al. (2006) Abnormal Ca2 þ dynamics in transgenic mice with neuronspecific mitochondrial DNA defects. J. Neurosci., 26, 12314–12324. 53. Chinnery, P.F. and Zeviani, M. (2008) 155th ENMC workshop: polymerase gamma and disorders of mitochondrial DNA synthesis, 21–23 September 2007, Naarden, The Netherlands. Neuromuscul. Disord., 18, 259–267. 54. Luoma, P., Melberg, A., Rinne, J.O. et al. (2004) Parkinsonism, premature menopause, and mitochondrial DNA polymerase gamma mutations: clinical and molecular genetic study. Lancet, 364, 875–882. 55. Bender, A., Schwarzkopf, R.M., McMillan, A. et al. (2008) Dopaminergic midbrain neurons are the prime target for mitochondrial DNA deletions. J. Neurol., 255, 1231–1235. 56. Post, R.M. and Weiss, S.R. (1996) A speculative model of affective illness cyclicity based on patterns of drug tolerance observed in amygdala-kindled seizures. Mol. Neurobiol., 13, 33–60.
252
|
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57. Benes, F.M., Lim, B., Matzilevich, D. et al. (2007) Regulation of the GABA cell phenotype in hippocampus of schizophrenics and bipolars. Proc. Natl. Acad. Sci. USA, 104, 10164–10169. 58. Kato, T. (2007) Mitochondrial dysfunction as the molecular basis of bipolar disorder: therapeutic implications. CNS Drugs, 21, 1–11. 59. Lewy, A.J., Wehr, T.A., Goodwin, F.K. et al. (1981) Manicdepressive patients may be supersensitive to light. Lancet, 1, 383–384. 60. Halliwell, B. (2001) Role of free radicals in the neurodegenerative diseases: therapeutic implications for antioxidant treatment. Drugs Aging, 18, 685–716. 61. Takuma, K., Baba, A. and Matsuda, T. (2004) Astrocyte apoptosis: implications for neuroprotection. Prog. Neurobiol., 72, 111–127. 62. Serrano, F. and Klann, E. (2004) Reactive oxygen species and synaptic plasticity in the aging hippocampus. Ageing Res. Rev., 3, 431–443. 63. MacDonald, M.L., Naydenov, A., Chu, M. et al. (2006) Decrease in creatine kinase messenger RNA expression in the hippocampus and dorsolateral prefrontal cortex in bipolar disorder. Bipolar Disord., 8, 255–264. 64. Berk, M., Dodd, S., Kauer-Santanna, M. et al. (2007) Dopamine dysregulation syndrome: implications for a dopamine hypothesis of bipolar disorder. Acta Psychiatr. Scand. Suppl., 116, 41–49. 65. Maker, H.S., Weiss, C., Silides, D.J. et al. (1981) Coupling of dopamine oxidation (monoamine oxidase activity) to glutathione oxidation via the generation of hydrogen peroxide in rat brain homogenates. J. Neurochem., 36, 589–593. 66. Berman, S.B. and Hastings, T.G. (1999) Dopamine oxidation alters mitochondrial respiration and induces permeability transition in brain mitochondria: implications for Parkinsons disease. J. Neurochem., 73, 1127–1137. 67. Halliwell, B. and Gutteridge, J.M. (1999) Free Radicals in Biology and Medicine, 3rd edn, Clarendon, Oxford. 68. Chen, G., Bower, K.A., Ma, C. et al. (2004) Glycogen synthase kinase 3beta (GSK3beta) mediates 6-hydroxydopamineinduced neuronal death. Faseb J., 18, 1162–1164. 69. Baez, S., Segura-Aguilar, J., Widersten, M. et al. (1997) Glutathione transferases catalyse the detoxication of oxidized metabolites (o-quinones) of catecholamines and may serve as an antioxidant system preventing degenerative cellular processes. Biochem. J., 324 (Pt 1), 25–28. 70. Halliwell, B. (2006) Oxidative stress and neurodegeneration: where are we now? J. Neurochem., 97, 1634–1658. 71. Rowe, M.K. and Chuang, D.M. (2004) Lithium neuroprotection: molecular mechanisms and clinical implications. Exp. Rev. Mol. Med., 6, 1–18. 72. McCubrey, J.A., Lahair, M.M. and Franklin, R.A. (2006) Reactive oxygen species-induced activation of the MAP kinase signaling pathways. Antioxid. Redox Signal, 8, 1775–1789. 73. Duchen, M.R. (2000) Mitochondria and calcium: from cell signalling to cell death. J. Physiol., 529 (Pt 1), 57–68. 74. Carter, C.J. (2007) Multiple genes and factors associated with bipolar disorder converge on growth factor and stress
75.
76.
77.
78.
79.
80. 81.
82.
83.
84.
85.
86.
87.
88.
89.
90.
activated kinase pathways controlling translation initiation: implications for oligodendrocyte viability. Neurochem. Int., 50, 461–490. Ranjekar, P.K., Hinge, A., Hegde, M.V. et al. (2003) Decreased antioxidant enzymes and membrane essential polyunsaturated fatty acids in schizophrenic and bipolar mood disorder patients. Psychiatry Res., 121, 109–122. Ozcan, M.E., Gulec, M., Ozerol, E. et al. (2004) Antioxidant enzyme activities and oxidative stress in affective disorders. Int. Clin. Psychopharmacol., 19, 89–95. Kuloglu, M., Atmaca, M., Tezcan, E. et al. (2002) Antioxidant enzyme activities and malondialdehyde levels in patients with obsessive-compulsive disorder. Neuropsychobiology, 46, 27–32. Andreazza, A.C., Cassini, C., Rosa, A.R. et al. (2007) Serum S100B and antioxidant enzymes in bipolar patients. J. Psychiatr. Res., 41, 523–529. Benes, F.M., Matzilevich, D., Burke, R.E. et al. (2006) The expression of proapoptosis genes is increased in bipolar disorder, but not in schizophrenia. Mol. Psychiatry, 11, 241–251. Andreazza, A.C., Frey, B.N., Erdtmann, B. et al. (2007) DNA damage in bipolar disorder. Psychiatry Res., 153, 27–32. Frey, B.N., Andreazza, A.C., Kunz, M. et al. (2007) Increased oxidative stress and DNA damage in bipolar disorder: a twin-case report. Prog. Neuropsychopharmacol. Biol. Psychiatry, 31, 283–285. Machado-Vieira, R., Dietrich, M.O., Leke, R. et al. (2007) Decreased plasma brain derived neurotrophic factor levels in unmedicated bipolar patients during manic episode. Biol. Psychiatry, 61, 142–144. Shao, L., Young, L.T. and Wang, J.F. (2005) Chronic treatment with mood stabilizers lithium and valproate prevents excitotoxicity by inhibiting oxidative stress in rat cerebral cortical cells. Biol. Psychiatry, 58, 879–884. Frey, B.N., Valvassori, S.S., Reus, G.Z. et al. (2006) Effects of lithium and valproate on amphetamine-induced oxidative stress generation in an animal model of mania. J. Psychiatry Neurosci., 31, 326–332. Berk, M., Copolov, D.L., Dean, O. et al. (2008) N-acetyl cysteine for depressive symptoms in bipolar disorder – a double-blind randomized placebo-controlled trial. Biol. Psychiatry, 64, 468–475. Simon, N.M., Smoller, J.W., McNamara, K.L. et al. (2006) Telomere shortening and mood disorders: preliminary support for a chronic stress model of accelerated aging. Biol. Psychiatry, 60, 432–435. Saretzki, G. and Von Zglinicki, T. (2002) Replicative aging, telomeres, and oxidative stress. Ann. N Y Acad. Sci., 959, 24–29. Brouilette, S., Singh, R.K., Thompson, J.R. et al. (2003) White cell telomere length and risk of premature myocardial infarction. Arterioscler. Thromb. Vasc. Biol., 23, 842–846. McIntyre, R.S., Soczynska, J.K., Beyer, J.L. et al. (2007) Medical comorbidity in bipolar disorder: re-prioritizing unmet needs. Curr. Opin. Psychiatry, 20, 406–416. Kapczinski, F., Frey, B.N., Andreazza, A.C. et al. (2008) Increased oxidative stress as a mechanism for decreased
Mitochondrial Dysfunction and Oxidative Stress
91.
92.
93.
94.
95.
96.
97.
98.
99.
100.
101.
102.
103.
104.
105.
BDNF levels in acute manic episodes. Rev. Bras. Psiquiatr., 30, 243–245. Kapczinski, F., Frey, B.N., Kauer-SantAnna, M. et al. (2008) Brain-derived neurotrophic factor and neuroplasticity in bipolar disorder. Exp. Rev. Neurother., 8, 1101–1113. Kapczinski, F., Vieta, E., Andreazza, A.C. et al. (2008) Allostatic load in bipolar disorder: implications for pathophysiology and treatment. Neurosci. Biobehav. Rev., 32, 675–692. Adler, L.A., Edson, R., Lavori, P. et al. (1998) Long-term treatment effects of vitamin E for tardive dyskinesia. Biol. Psychiatry, 43, 868–872. Straw, G.M., Bigelow, L.B. and Kirch, D.G. (1989) Haloperidol and reduced haloperidol concentrations and psychiatric ratings in schizophrenic patients treated with ascorbic acid. J. Clin. Psychopharmacol., 9, 130–132. Lohr, J.B. and Caligiuri, M.P. (1996) A double-blind placebocontrolled study of vitamin E treatment of tardive dyskinesia. J. Clin. Psychiatry, 57, 167–173. Dakhale, G.N., Khanzode, S.D., Khanzode, S.S. et al. (2005) Supplementation of vitamin C with atypical antipsychotics reduces oxidative stress and improves the outcome of schizophrenia. Psychopharmacology (Berl.), 182, 494–498. Arvindakshan, M., Ghate, M., Ranjekar, P.K. et al. (2003) Supplementation with a combination of omega-3 fatty acids and antioxidants (vitamins E and C) improves the outcome of schizophrenia. Schizophr. Res., 62, 195–204. Sivrioglu, E.Y., Kirli, S., Sipahioglu, D. et al. (2007) The impact of omega-3 fatty acids, vitamins E and C supplementation on treatment outcome and side effects in schizophrenia patients treated with haloperidol: an openlabel pilot study. Prog. Neuropsychopharmacol. Biol. Psychiatry, 31, 1493–1499. Zhang, X.Y., Zhou, D.F., Cao, L.Y. et al. (2003) Elevated blood superoxide dismutase in neuroleptic-free schizophrenia: association with positive symptoms. Psychiatry Res., 117, 85–88. Zhang, X.Y., Zhou, D.F., Cao, L.Y. et al. (2003) The effect of risperidone treatment on superoxide dismutase in schizophrenia. J. Clin. Psychopharmacol., 23, 128–131. Parikh, V., Khan, M.M. and Mahadik, S.P. (2003) Differential effects of antipsychotics on expression of antioxidant enzymes and membrane lipid peroxidation in rat brain. J. Psychiatr. Res., 37, 43–51. Pillai, A., Parikh, V., Terry, A.V. Jr et al. (2007) Longterm antipsychotic treatments and crossover studies in rats: differential effects of typical and atypical agents on the expression of antioxidant enzymes and membrane lipid peroxidation in rat brain. J. Psychiatr. Res., 41, 372–386. Harvey, B.H., Joubert, C., du Preez, J.L. et al. (2008) Effect of chronic N-acetyl cysteine administration on oxidative status in the presence and absence of induced oxidative stress in rat striatum. Neurochem. Res., 33, 508–517. Wei, Z., Bai, O., Richardson, J.S. et al. (2003) Olanzapine protects PC12 cells from oxidative stress induced by hydrogen peroxide. J. Neurosci. Res, 73, 364–368. Wang, H., Xu, H., Dyck, L.E. et al. (2005) Olanzapine and quetiapine protect PC12 cells from beta-amyloid peptide
106.
107.
108.
109.
110.
111.
112.
113.
114.
115.
116.
117.
118.
119.
120.
|
253
(25-35)-induced oxidative stress and the ensuing apoptosis. J. Neurosci. Res, 81, 572–580. Bilici, M., Efe, H., Koroglu, M.A. et al. (2001) Antioxidative enzyme activities and lipid peroxidation in major depression: alterations by antidepressant treatments. J. Affect. Disord., 64, 43–51. Khanzode, S.D., Dakhale, G.N., Khanzode, S.S. et al. (2003) Oxidative damage and major depression: the potential antioxidant action of selective serotonin re-uptake inhibitors. Redox Rep., 8, 365–370. Herken, H., Gurel, A., Selek, S. et al. (2007) Adenosine deaminase, nitric oxide, superoxide dismutase, and xanthine oxidase in patients with major depression: impact of antidepressant treatment. Arch. Med. Res., 38, 247–252. Sarandol, A., Sarandol, E., Eker, S.S. et al. (2007) Major depressive disorder is accompanied with oxidative stress: short-term antidepressant treatment does not alter oxidative-antioxidative systems. Hum. Psychopharmacol., 22, 67–73. Pal, S.N. and Dandiya, P.C. (1994) Glutathione as a cerebral substrate in depressive behavior. Pharmacol. Biochem. Behav., 48, 845–851. Eren, I., Naziroglu, M., Demirdas, A. et al. (2007) Venlafaxine modulates depression-induced oxidative stress in brain and medulla of rat. Neurochem. Res., 32, 497–505. Verleye, M., Steinschneider, R., Bernard, F.X. et al. (2007) Moclobemide attenuates anoxia and glutamate-induced neuronal damage in vitro independently of interaction with glutamate receptor subtypes. Brain Res., 1138, 30–38. Lee, C.S., Han, E.S. and Lee, W.B. (2003) Antioxidant effect of phenelzine on MPP þ -induced cell viability loss in differentiated PC12 cells. Neurochem. Res., 28, 1833–1841. Wang, J.F., Azzam, J.E. and Young, L.T. (2003) Valproate inhibits oxidative damage to lipid and protein in primary cultured rat cerebrocortical cells. Neuroscience, 116, 485–489. Shao, L., Sun, X., Xu, L. et al. (2006) Mood stabilizing drug lithium increases expression of endoplasmic reticulum stress proteins in primary cultured rat cerebral cortical cells. Life Sci., 78, 1317–1323. Chen, G., Zeng, W.Z., Yuan, P.X. et al. (1999) The moodstabilizing agents lithium and valproate robustly increase the levels of the neuroprotective protein bcl-2 in the CNS. J. Neurochem., 72, 879–882. Cui, J., Shao, L., Young, L.T. et al. (2007) Role of glutathione in neuroprotective effects of mood stabilizing drugs lithium and valproate. Neuroscience, 144, 1447–1453. Lai, J.S., Zhao, C., Warsh, J.J. et al. (2006) Cytoprotection by lithium and valproate varies between cell types and cellular stresses. Eur. J. Pharmacol., 539, 18–26. Henneman, D.H. and Altschule, M.D. (1951) Immediate effects of shock therapies, epinephrine and ACTH on blood glutathione level of psychotic patients. J. Appl. Physiol., 3, 411–416. Gergerlioglu, H.S., Savas, H.A., Bulbul, F. et al. (2007) Changes in nitric oxide level and superoxide dismutase activity during antimanic treatment. Prog. Neuropsychopharmacol. Biol. Psychiatry, 31, 697–702.
254
|
Chapter 18
121. Aliyazicioglu, R., Kural, B., Colak, M. et al. (2007) Treatment with lithium, alone or in combination with olanzapine, relieves oxidative stress but increases atherogenic lipids in bipolar disorder. Tohoku J. Exp. Med., 213, 79–87. 122. Selek, S., Savas, H.A., Gergerlioglu, H.S. et al. (2008) The course of nitric oxide and superoxide dismutase during treatment of bipolar depressive episode. J. Affect. Disord., 107, 89–94. 123. Dean, O., van den Buuse, M., Copolov, D. et al. (2004) Nacetyl cysteine inhibits depletion of brain glutathione levels in rats: implications for schizophrenia. Int. J. Neuropsychopharmacol., 7, 262. 124. Baker, D.A., McFarland, K., Lake, R.W. et al. (2003) N-acetyl cysteine-induced blockade of cocaine-induced reinstatement. Ann. N Y Acad. Sci., 1003, 349–351. 125. LaRowe, S.D., Mardikian, P., Malcolm, R. et al. (2006) Safety and tolerability of N-acetylcysteine in cocaine-dependent individuals. Am. J. Addict., 15, 105–110. 126. Mardikian, P.N., LaRowe, S.D., Hedden, S. et al. (2007) An open-label trial of N-acetylcysteine for the treatment of
127.
128.
129.
130.
131.
cocaine dependence: a pilot study. Prog. Neuropsychopharmacol. Biol. Psychiatry, 31, 389–394. LaRowe, S.D., Myrick, H., Hedden, S. et al. (2007) Is cocaine desire reduced by N-acetylcysteine? Am. J. Psychiatry, 164, 1115–1117. Lafleur, D.L., Pittenger, C., Kelmendi, B. et al. (2006) Nacetylcysteine augmentation in serotonin reuptake inhibitor refractory obsessive-compulsive disorder. Psychopharmacology (Berl.), 184, 254–256. Odlaug, B.L. and Grant, J.E. (2007) N-acetyl cysteine in the treatment of grooming disorders. J. Clin. Psychopharmacol., 27, 227–229. Hansen, N.C., Skriver, A., Brorsen-Riis, L. et al. (1994) Orally administered N-acetylcysteine may improve general wellbeing in patients with mild chronic bronchitis. Respir. Med., 88, 531–535. Berk, M., Copolov, D., Dean, O. et al. (2008) N-acetyl cysteine as a glutathione precursor for schizophrenia – a doubleblind, randomized, placebo-controlled trial. Biol. Psychiatry, 64, 361–368.
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Neuroendocrinology of Bipolar Illness Timothy Dinan1 and Michael Bauer2 1 2
Department of Psychiatry, Cork University Hospital, Wilton, Cork, Ireland Department of Psychiatry and Psychotherapy, University Hospital Carl Gustav Carus, Technische Universit€at Dresden, Fetscherstraße 74, D-01307 Dresden, Germany
Despite advances in pharmacology, bipolar disorder remains enigmatic from a pathophysiological perspective. Over the past 30 years, numerous studies have been conducted examining endocrine aspects of major depression. Far fewer studies have been conducted on patients with bipolar illness than in patients with unipolar depression. There are several reasons for this, including the fact that unipolar depression is more common, it is difficult to maintain bipolar patients drug-free for any appreciable length of time and the simplistic but commonly held perception until relatively recently that mania was the biological inverse of depression hampered activity in the field. Over the past decade several important studies have been published examining neuroendocrine aspects of bipolar illness and while some of these studies are limited by the fact that medicated patients were recruited, some investigators have conducted studies in patients who were drug-free for an adequate period. We thus have a body of knowledge regarding hypothalamic-pituitary-adrenal axis (HPA) and hypothalamic-pituitary-thyroid axis (HPT) function in bipolar illness and these axes will be the primary focus of this chapter. Earlier studies tended to focus on monoaminergic regulation of anterior pituitary hormone release, in an effort to determine the sensitivity of monoaminergic receptors.
include 5-hydroxytryptamine (5-HT), noradrenaline, acetylcholine and the opioids. Under basal conditions corticotropin releasing hormone (CRH) produced by the parvicellular neurones is the dominant regulator of the axis [2]. In situations of chronic stress, many parvicellar neurones co-express vasopressin (AVP), which plays an important role in sustaining HPA activation [3]. CRH and AVP act synergistically on the anterior pituitary corticotropes to bring about the release of ACTH [4]. This in turn stimulates release of cortisol from the adrenal cortex, which feeds back to suppress the axis. Negative feedback is defined in terms of speed of response into immediate, intermediate and delayed. Much of the research in psychiatry has focused on delayed feedback. While high cortisol provides a break on HPA activity, it simultaneously has potent immuno-suppressive actions. Major depression has long been recognized as a disorder, frequently driven by psychosocial stress and associated with changes in HPA activity. Numerous studies have explored HPA activity in unipolar major depression but fewer studies have examined HPA activity in bipolar patients.
Basal HPA activity in bipolar disorder HPA regulation There is overwhelming evidence to indicate that adaptation to chronic stress involves response from the neuroendocrine system. While acute stress activates the sympathoadrenal medullary system (SAM), resulting in the components of the fight or flight response with a release of catecholamines, chronic stress results in alterations of the HPA with changes in the release of cortisol [1]. A wide variety of neurotransmitters influence the hypothalamic paraventricular nucleus regulation of the HPA. These transmitters
Bipolar Disorder: Clinical and Neurobiological Foundations Edited by Lakshmi N. Yatham and Mario Maj © 2010 John Wiley & Sons, Ltd. ISBN: 978-0-470-72198-8
Various measurements of cortisol output have been reported in bipolar illness. These include measurements of cortisol in plasma, saliva and urine. Few studies have focused on CSF measurements. However, Swann et al. [5] found elevated CSF cortisol in mania, similar to that reported for depression. In a comprehensive study of salivary cortisol secretion, Deshauer et al. [6] obtained six salivary samples per day for three days in bipolar patients in remission and 28 offspring of bipolar patients. The advantages of measuring salivary cortisol include ease of collection and the fact that salivary cortisol is not protein bound and therefore a reflection of biologically active cortisol. No differences in salivary cortisol levels were observed at any time point. The data indicate that when bipolar patients are in remission, salivary cortisol levels are 255
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normal. Furthermore, subjects with a family history of bipolar illness do not show elevated salivary cortisol levels. These findings are in contrast to those of Wedekind et al. [7], who examined nocturnal urinary cortisol secretion in bipolar patients who were currently depressed at the beginning and end of inpatient treatment. They found elevations in cortisol, which were especially pronounced in bipolar psychotic patients. They conclude that the HPA over-activity is a trait rather than a state marker. The most sensitive time point for detecting differences between patient groups and healthy volunteers in terms of salivary cortisol is the level immediately taken upon wakening. Eighteen clinically stable lithium responsive patients were compared with healthy controls in terms of waking cortisol levels [8]. Even when clinically well, the bipolar patients had elevated morning cortisol. In a similar preliminary study, Ellenbogen et al. [9] examined morning and afternoon salivary cortisol levels in 10 normal adolescent offspring of bipolar patients and 10 matched offspring of parents without a history of mental illness. Salivary cortisol levels were higher in the offspring of bipolar patients than the matched controls. Again, the data suggest that the HPA in the first-degree relatives of bipolar patients show abnormalities at an early age. While overall the data are inconsistent, they do point to increased cortisol levels in bipolar patients.
Dexamethasone suppression test (DST) The low dose (1 mg) DST is the most extensively investigated test in the history of biological psychiatry but its usefulness in a clinical setting is limited due to low sensitivity and specificity. It is fundamentally a test of delayed feedback in the HPA. While the DST has been examined primarily in depression, studies in manic patients have been undertaken. Rates of non-suppression in mania are in the 40–50% range, similar to those reported for depression. However, as in the case of depression, the abnormality usually normalizes with effective treatment.
Dexamethasone/CRH test This test assesses both forward drive and feedback activity in the HPA and is carried out by administering dexamethasone (DEX) the evening prior to CRH challenge. Subjects usually receive an oral dose of DEX 1.5 mg at 23:00 h followed by CRH 1 mg/kg. Blood samples are collected at 15:00, 15:15, 15:30, 15:45, 16:00 and 16:15 h. It is well established that patients with major depression have an enhanced ACTH release, relative to healthy controls, when CRH is administered after DEX. The reason for this enhancement is not fully understood, though it has been postulated that enhanced vasopressin activity in depression may be involved.
Rybakowski and Twardowska [10] examined 40 patients with depression, 16 bipolars and 24 unipolars, both during an acute episode of depression and in remission. They found that during depressive episodes bipolar patients had a greater cortisol response to DEX/CRH than unipolar patients and there was a significant correlation between the endocrine response and the severity of depression. Furthermore, this anomaly persisted in the bipolars, even in remission. Schmider et al. [11] tested acute and remitted manic patients, those in acute depression and healthy controls. ACTH and cortisol release were significantly increased in both manic and depressed patients in comparison to healthy subjects. In remission manic patients had a decreased response but nonetheless a response significantly higher than seen in controls. The data indicate that in either an acute manic episode or in remission, bipolar patients have abnormalities in HPA function. A more comprehensive study of the DEX/CRH test in bipolar patients in remission was carried out by the Newcastle group [12]. They examined 53 bipolar patients, of whom 27 were in remission and 28 healthy controls. The bipolar patients had an enhanced cortisol response to the DEX/CRH relative to the controls. They conclude that the DEX/CRH test is abnormal in both remitted and nonremitted bipolar patients. Patients with a rapid cycling form of bipolar I disorder were investigated by Watson et al. [13]. Five patients were sequentially tested with DEX/CRH. The results were stable over time, suggesting that the test yields results that are independent of the mood state in such patients.
DEX/vasopressin test The release of ACTH from the anterior pituitary is under the joint control of CRH acting through CRH1 receptors and vasopressin acting on V3 (sometimes called V1b) receptors. The latter become more important during chronic stress. Dinan et al. [14] demonstrated increased responsiveness in these receptors in patients with major depression. They used desmopressin to stimulate ACTH release and found that patients with major depression released more ACTH than did healthy subjects. Watson et al. [15] examined DEX/ negative feedback on AVP release in 64 patients with mood disorder and 21 controls. 41 patients were bipolar and the remainder had chronic depressive disorder. 21 of the bipolars were in remission, 10 were depressed and 10 were rapidcycling. All subjects were administered DEX 1.5 mg at 23.00 h. On the following afternoon at 15.00 h, blood was collected for AVP measurement. Post-DEX levels were significantly higher in patients with bipolar illness and chronic depressive than matched healthy controls. It is not clear from the study whether or not AVP levels were elevated at baseline or whether the AVP emanates from the paraventricular nucleus or the magnocellular nucleus of the hypo-
Neuroendocrinology of Bipolar Illness
thalamus. However, it is tempting to speculate that the HPA over-activity seen in patients with bipolar illness may be driven by excess AVP.
CRH receptor studies Two CRH receptors are known, CRHR1 and CRHR2. Wasserman et al. [16] analysed single nucleotide polymorphisms (SNPs) in the CRH1 gene, in family trios with suicide attempter offspring (n ¼ 542), by using the transmission disequilibrium test both in a two-staged screening/replication sample design and in detailed re-analysis in the entire sample. Stratification based on the levels of lifetime stress showed reproducible association and linkage of a SNP in the CRHR1 gene (rs4 792 887) to suicide attempters exposed to low levels of stress (P ¼ 0.002), amongst whom most males were depressed (P ¼ 0.001). The identified allele may represent a part of the genetic susceptibility for suicidality by increasing HPA axis activity upon exposure to low levels of stress. Stratakis et al. [17] investigated genetic linkage between the CRH gene and bipolar disorder in 22 pedigrees. A short tandem repeat (STR) polymorphism adjacent to the CRH gene on human chromosomal region 8q13 was used to examine linkage. Affected sibling pair (ASP) and the likelihood-based disequilibrium tests revealed non-significant values. The authors conclude that the CRH gene is not linked to bipolar disorder and that if genes involved in the regulation of stress response are indeed linked to bipolar disorder, the search should be directed towards those that regulate CRH secretion or its effects on target tissues. De Luca et al. [18] conducted such a study. They exclusively studied bipolar patients and searched for markers conferring genetic susceptibility to suicide, by typing three polymorphisms of the CRHR2 gene, CRHR2(CA), CRHR2(GT) and CRHR2(GAT) in 312 families, where at least one subject had DSM-IV bipolar disorder. Family based association analyses in the suicide attempters using FBAT yielded no difference in the distribution of the alleles for all three markers. HBAT analysis for quantitative measures on suicide-related traits showed association between haplotype 5-2-3 and higher severity. The current results show that haplotype variation at the CRHR2 locus is associated with suicidal behaviour.
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The functioning of GR in lymphocytes of bipolar patients was explored by Spillotaki et al. [19]. Fifteen bipolar depressed patients, 15 bipolar euthymics taking lithium monotherapy and 25 matched controls were studied. Whole cell and nuclear extracts from lymphocytes were immunoblotted for GR, c-fos, c-jun N-terminal kinase (JNK) and nuclear factor-kappa B (NF-kappaB. Nuclear aliquots were submitted to electrophoretic mobility shift assay for GR, activator protein-1 (AP-1) and nuclear factor-kappa B. Intracellular signalling of GR, AP-1 and JNK was observed to be altered in bipolar patients. In a postmortem brain study [20], MR mRNA expression was assessed using in situ hybridization in the prefrontal cortex of patients with bipolar illness, major depression, schizophrenia and nonpsychiatric controls. In the dorsolateral prefrontal cortex Brodmanns area 9 (BA 9), MR mRNA was significantly lower (p < 0.05) in all laminae (I–VI) in bipolar patients, and in laminae I, III, IV and VI in schizophrenics than in the controls. MR mRNA in BA 9 was negatively correlated with the duration of psychiatric illnesses. These results provide the first evidence of deficient prefrontal MR mRNA expression in bipolar disorder. Whether these findings may be linked to HPA alterations in bipolar illness is not clear.
Thyroid hormones Certain clinical facts about thyroid hormones and the brain have been known for over a century. Thyroid hormone metabolism plays a critical role in human brain development, and in the mature brain significant disturbances of the thyroid economy may profoundly alter mental function, including perception, cognition and emotion. Both excess production (hyperthyroidism) and inadequate thyroid hormone production (hypothyroidism) are associated with changes in mood and intellectual performance, and severe hypothyroidism can mimic melancholic depression and dementia in adults [21,22]. However, these facts have been tantalizing. If disturbed mood and behaviour is present in patients who suffer primary thyroid disorders, then is it possible that changes in the HPT axis play a role in the aetiology of mood and other psychiatric disorder? And if so, then might the thyroid hormones have value in the treatment of psychiatric illness, particularly affective illness?
Corticoid receptors
Thyroid status in patients with affective disorders
Cortisol binds to both glucocortioid receptors (GR) and mineralocorticoid receptors (MR). The former are found throughout the brain and show increasing occupancy with stress induced elevations in cortisol. MR receptors have the highest concentration in the septo-hippocampal projection and occupancy varies with the diurnal fluctuation in cortisol.
Based upon the clinical evidence that hypothyroidism can mimic depressive symptoms, the implicit hypothesis driving many of the clinical treatment studies is that individuals who respond to adjunctive thyroid treatment have a failing thyroid economy, or suffer subclinical thyroid disease. Several lines of evidence suggest that there may be abnormalities in thyroid hormone metabolism in patients with
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affective disorders, and that these may not be readily apparent with the standard tests to screen for thyroid disease. In fact, the vast majority of patients with primary affective disorders (>90%) have thyroid hormone blood levels within the euthyroid range [23]. However, within that normal range the thyroid hormone economy appears to be predictive of therapeutic response, with growing evidence that thyroid hormone levels in the low-normal range or below the normal range (i.e. thyroid hypofunction) can result in a sub-optimal treatment outcome. The most consistent finding in patients during the depressive phase of illness, compared to controls and healthy subjects, is an elevation of serum concentrations of total and free T4 (with normal T3 levels), which fall upon recovery and correlate with the speed at which that recovery occurs. Similarly, Frye et al. [24] have reported that within the normal range a low level of free thyroxin (fT4) in patients with bipolar disorder is associated with more affective episodes and greater severity of depression during prophylactic lithium treatment. In another study, lower free thyroxin index (FTI) values and higher TSH values within the normal range were significantly associated with poorer treatment response in bipolar patients during the depressed phase [25]. Taken together these observations suggest that higher serum levels of thyroxin are adaptive in depression – much as an increase in thyroid metabolism is an adaptive response to cold stress – and that a robust thyroid economy confers an advantage that promotes rapid recovery following antidepressants treatment. Thus, a working hypothesis in seeking to explain these clinical observations is that thyroid hormones modulate the severity and course of depression rather than playing a specific pathogenic role. The hypothesis that thyroid hormones act as modulators in affective illness is further strengthened by studies of the relationship between thyroid function and the clinical course of bipolar disorder, especially that of the rapid cycling variant.
Rapid cycling bipolar disorder When examining thyroid function in bipolar illness, it is useful to distinguish between rapid cycling and non-rapid cycling bipolar disorder. By DSM IV definition, patients with a rapid cycling course of disease suffer four or more episodes of illness per year. Approximately 10–15% of bipolar patients experience rapid cycling; while similar to other bipolar patients nosologically and demographically, they tend to have a longer duration of illness and a more refractory course. Furthermore, women are disproportionately represented, making up 80–95% of rapid cycling patients, compared to about 50% of non-rapid cycling patients [22]. A variety of factors may predispose bipolar illness to a rapid cycling course, including treatment with tricyclic antidepressants (TCA), monoamine oxidase inhibitors (MAOI) and lithium.
There is also a longstanding debate as to whether thyroid axis abnormalities contribute to the development of rapid cycling in patients with bipolar disorder [26]. Several studies have found an association amongst indices of low thyroid function or clinical hypothyroidism and rapid cycling, while other studies refute this association. For example, one larger study reported that 23% of 30 patients with rapid cycling bipolar disorder had grade I hypothyroidism, while 27% had grade II and 10% had grade III abnormalities [27]. The results from various studies are inconsistent, and the conclusions to be drawn are often limited by their retrospective design and lack of a healthy control comparison group. Most importantly, many studies included patients who were receiving prophylactic long-term lithium treatment. The adverse effects of lithium on thyroid function do certainly have an impact on thyroid indices. On the other hand, cross-sectional studies of unmedicated patients with rapid cycling bipolar disorder have found no abnormalities in basal thyroid-stimulating hormone (TSH) and thyroxine levels. It was postulated that patients with rapid cycling may manifest no thyroid abnormalities until physiologically challenged by antithyroid stressors. Such stressors may include spontaneously occurring thyroid disease or goiterogenic drugs such as lithium. In a recent controlled study, when previously unmedicated patients with rapid cycling were challenged with therapeutic doses of lithium, a significantly higher delta TSH after thyrotropin-releasing hormone stimulation was found than in age- and gendermatched healthy controls who also received lithium [28]. This result suggests that some patients with bipolar disorder have a dysfunction in the HPT axis that remains latent until the axis is challenged by the thyroprivic effect of lithium, and that changes in the thyroid economy may play a modulating role in the development of the rapid cycling pattern.
Thyroid autoimmunity Lithium therapy for patients with affective disorders has long been acknowledged to induce thyroid dysfunction. Although it was noted early on that lithium-induced thyroid failure could occur without the presence of thyroid autoimmunity, the role of thyroid autoimmunity in the development of lithium-induced thyroid disorders remains unclear. Some studies have reported a high prevalence for antithyroid antibodies in patients with affective disorders receiving lithium therapy, suggesting that thyroid autoimmunity may mediate the antithyroid effects of lithium. Other studies have not found an increased prevalence of antithyroid antibodies in patients with affective disorders receiving lithium when compared to the general population, normal controls or controls with psychiatric disorders [29]. Furthermore, patients who have thyroid
Neuroendocrinology of Bipolar Illness
autoimmunity prior to lithium exposure may show a rise in antibody titres, and have an increased risk of developing hypothyroidism while receiving lithium therapy. Specifically, thyroid peroxidase (TPO) antibodies were reported to be elevated in bipolar disorder with a prevalence of 28%, while results from other studies were inconsistent with reported rates ranging from 0–43%. In community studies, the rates of prevalence of TPO antibodies generally range from about 12–18%. The estimate of TPO antibody prevalence will vary with the sensitivity and specificity of the testing methodology, is increased in females, in old age, when TSH levels are abnormally high or low, and when individuals with known thyroid disease are included in the population. The impact of increasing age and female gender on the detection of TPO antibodies has also been noted in patients with affective disorders. Elevated thyroid antibodies were also reported in some studies of patients with unipolar depression, but not in others. It was also hypothesized that autoimmune thyroiditis, with TPO antibody as marker, may be a potential endophenotype for bipolar disorder, and is related to the genetic vulnerability to develop bipolar disorder rather than to the disease process itself. While offspring of parents with bipolar disorder were found to have increased vulnerability to develop thyroid autoimmunity as compared to high-school-aged controls, this was independent of any psychiatric disorder or symptoms. Thyroid antibody status was also associated with an increased risk for lithium-induced hypothyroidism, but not with current or former lithium treatment [30].
Thyroid hormones in the treatment of mood disorders Efforts to employ thyroid extract and thyroxine alone as therapeutic agents were rarely successful but since Pranges classic triiodothyronine (T3) acceleration studies in the late 1960s, a series of open and controlled clinical trials have confirmed the adjunctive therapeutic value of thyroid hormones in unipolar and bipolar mood disorders. As early as the 1930s, Norwegian physicians used desiccated sheep thyroid gland to treat patients with cyclic mood disorders. While thyroid hormone monotherapy is not an adequate treatment for patients with primary mood disorders, since the late 1960s, a series of open and controlled clinical trials have confirmed the therapeutic value of adjunctive treatment with thyroid hormones in mood disorders. Specifically, there is some evidence that T3 can accelerate the therapeutic response to tricyclic antidepressants, and in treatment-resistant depression, T3 may augment the response to tricyclic antidepressants although the results have been inconsistent. T3 has also been shown to augment the response to sertraline but not to paroxetine. In a series of open-label studies, adjunctive treatment with supraphysiological doses of Levothyroxine (L-T4) was
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found to be effective in the maintenance treatment of patients with severe rapid cycling or resistant bipolar disorder who did not respond to standard measures [31–34]. Supraphysiological L-T4 may also have immediate therapeutic value in antidepressant-resistant bipolar and unipolar depressed patients during a phase of refractory depression [35,36]. In these patients with malignant affective disorder, doses of 250–600 mg/d L-T4 are required to achieve therapeutic effect, much higher than those used in the treatment of primary thyroid disorders. Although treatment with supraphysiological T4 requires close monitoring, the hyperthyroxinemia is tolerated surprisingly well. No serious effects, including loss of bone mineral density, were observed even in patients treated for extended periods [37,38]. The low incidence of adverse effects and high tolerability reported by patients with affective disorders who are receiving high dose thyroid hormone therapy contrasts with that typically seen in patients with primary thyroid disease. For example, patients with thyroid carcinoma treated with high doses of L-T4 to achieve suppression of TSH commonly complain of the symptoms of thyrotoxicosis. In summary, thyroid hormone supplementation is now widely accepted as an effective treatment enhancement, especially for patients with refractory bipolar disorders. The question remains, however, as to why this should be so.
Potential mechanisms of action What evidence is there to support this conjecture of a central disturbance of brain-thyroid metabolism in some patients who suffer refractory affective illness? Despite the clinical evidence of a close relationship between thyroid status and behavioural disturbance, metabolic effects of thyroid hormones in the adult mammalian brain have rarely been investigated in vivo. In part, this lack of curiosity may be traced to reports in the 1950s and 1960s that suggested that oxygen consumption in the mature human brain did not change with thyroid status. But the absence of a technology capable of direct in vivo measurement of brain thyroid metabolism is also responsible. That still does not exist, but the evaluation of cerebral blood flow and metabolism by functional brain imaging techniques is a starting point and recent studies have provided promising insights into the thyroid-brain relationship [39,40]. Following the lead of earlier clinical treatment studies, the effects of adjunctive supraphysiological doses of L-T4 on relative brain activity as a surrogate index of cerebral glucose metabolism were studied in euthyroid women with bipolar depression using PET technology with [18F-] fluorodeoxyglucose as the radiotracer [41]. At baseline, pretreatment, bipolar depressed women had functional abnormalities in prefrontal and limbic brain areas compared to healthy controls. Over seven weeks, the treatment with L-T4
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significantly improved mood and was accompanied by significant changes in relative brain activity. In particular, L-T4 treatment was associated with a widespread relative deactivation of limbic and subcortical structures, including the amygdala, hippocampus, caudate nucleus, ventral striatum, thalamus and cerebellar vermis. The findings suggest that in these treatment-resistant patients L-T4 produces mood improvement by actions on the specific limbic and subcortical circuits that have been implicated in the pathophysiology of mood disorders. Thyroid hormone receptors are widely distributed in the brain. Many of the limbic system structures where thyroid hormone receptors are prevalent have been implicated in the pathogenesis of mood disorders. However, the cellular and molecular mechanisms underlying these metabolic effects, and the specific neuropharmacological basis and functional pathways for the modulatory effects of thyroid hormones on mood, are yet to be understood. Interactions of the thyroid and neurotransmitter systems, primarily norepinephrine and serotonin, which are generally believed to play a major role in the regulation of mood and behaviour, may contribute to the mechanism of action in the developing and mature brain [42,43]. There is robust evidence, particularly from animal studies, that the modulatory effects on the serotonin system may be due to an increase in serotonergic neurotransmission [40]. Thyroid hormones also interact with other neurotransmitter systems involved in mood regulation, including dopamine postreceptor and signal transducing processes, as well as gene regulatory mechanisms. Furthermore, within the CNS, the regulatory cascade through which the thyroid hormones, particularly T3, exert their effects is not well understood: deiodinase activity, nuclear binding to genetic loci and ultimately protein synthesis may all be involved [39]. Other proposed mechanisms for thyroid involvement in the aetiology of mood disorders include disturbances or reactive hyperactivity in the HPT axis, as manifested in the blunted TSH response to TRH found in some patients with depression. In summary, thyroid hormones have a multitude of effects on the central nervous system, and it is now widely recognized that disturbances of mood and cognition often emerge in association with putative disturbance of thyroid metabolism in the brain. As knowledge in basic science and appropriate technology evolve, understanding of the role of thyroid hormone function in the adult brain will continue to be refined. Studies of the biology of thyroid hormone action shows that these hormones play an important role in normal brain function and that current laboratory tests on thyroid status may not provide a sufficiently accurate measure of thyroid hormone function within the CNS. In patients with primary thyroid disorders, both excess and inadequate thyroid hormones can induce behavioural abnormalities that mimic depression, mania
and dementia. These neuropsychiatric impairments are generally reversible following return to euthyroid status, although some defects may persist in a subset of patients. In patients with bipolar disorders, thyroid hormones appear to be capable of modulating the phenotypic expression of their illness. Even though most patients with primary mood disorders do not have overt thyroid disease, relative abnormalities in thyroid function are associated with a worse outcome. Furthermore, the adjunctive use of supraphysiological doses of L-T4 in malignant bipolar disorders frequently provides remission without adverse physiological effects where all other treatments have failed. As clinicians gain more profound knowledge about the interactions of thyroid hormones, behaviour and mood, they advance their understanding of the pathophysiology and treatment options for bipolar disorder and depression. Additional research with rigorous scientific designs is still needed to confirm the efficacy, safety and feasibility of thyroid hormone therapy in severely ill patients with mood disorders.
Monoamines and pituitary hormones It was first demonstrated more than 25 years ago that stimulation of noradrenergic alpha-2 receptors brought about the release of growth hormone (GH) and that such a response is blunted in major depression. This was interpreted as indicative of a subsensitivity of the alpha-2 receptor in depression. Anseau et al. [44] found blunted GH release following clonidine (alpha-2 agonist) challenge in seven manic patients. Similar responses were reported by Dinan et al. [45] in patients challenged with the noradrenergic re-uptake inhibitor desipramine. It is interesting to note that cholinergic inputs also regulate GH release and that manic patients challenged with the acetylcholinesterase inhibitor pyridostigmine show exaggerated release of GH. The data indicate an imbalance between noradrenergic and cholinergic regulation. The fact that 5HT receptors stimulate prolactin release has been used to study the sensitivity of such receptors. Studies using a variety of probe drugs demonstrate a 5HT receptor subsensitivity in unipolar major depression. Far fewer studies have been conducted in bipolar patients. When healthy subjects are administered d-fenfluramine, the 5HT releasing agent and re-uptake inhibitor, a significant increase in prolactin levels is observed. Unipolar depressives show a blunted response to this challenge. In a study of manic patients, Thakore et al. [46] found blunted responses similar to those found in depression.
Conclusions and future directions Bipolar illness is a challenging disorder to manage and improved therapies will only arise from an increased
Neuroendocrinology of Bipolar Illness
understanding of pathophysiology. Part of that increased understanding will involve neuroendocrine investigations. While studies in drug-free and drug-na€ıve patients are required, the major necessity is for large-scale longitudinal studies of newly diagnosed patients. Only by studying patients prospectively in different phases of their illness can we achieve real understanding of the evolving biology. This may be even more important in female patients where the hormonal milieu alters not only across the menstrual cycle but from the pre- to post-menopausal stages. The plethora of cross-sectional studies currently available have significant limitations. Prospective studies may not only help increase understanding of the disorder but possibly detect new targets for pharmacological intervention.
References 1. Rubin, R., Dinan, T.G. and Scott, L.V. (2001) The neuroendocrinology of affective disorders, in Hormones, Brain and Behaviour (eds D. Pfaff, A.P. Arnold, A.M. Etgen et al.), Academic Press, New York. 2. Vale, W., Spiess, J., Rivier, C. and Rivier, J. (1981) Characterisation of a 41 residue ovine hypothalamic peptide that stimulates secretion of the corticotropin and beta-endorphin. Science, 213, 1394–1399. 3. Dinan, T.G. and Scott, L.V. (2005) Anatomy of melancholia: focus on the hypothalamic-pituitary-adrenal axis overactivation and the role of vasopressin. J. Anat., 207, 259–264. 4. Aguilera, G. (1994) Regulation of pituitary ACTH secretion during chronic stress. Front. Neuroendocrinol., 15, 321–350. 5. Swann, A.C., Stokes, P.E., Casper, R. et al. (1992) Hypothalamic-pituitary-adrenocortical function in mixed and pure mania. Acta Psychiat. Scand., 85, 270–274. 6. Deshauser, D., Duffy, A., Alda, M. et al. (2003) The cortisol awakening response in bipolar illness: a pilot study. Can. J. Psychiat., 48, 462–466. 7. Wedekind, D., Preiss, B., Cohrs, S. et al. (2007) Relationship between nocturnal urinary corrtisol excretion and symptom severity in subgroups of patients with depressive disorders. Neuropsychobiology, 56, 119–122. 8. Deshauer, D., Duffy, A., Alda, M. et al. (2003) The cortisol awakening response in bipolar illness: a pilot study. Can. J. Psychiat., 48 (7), 462–466. 9. Ellenbogen, M.A., Hodgins, S. and Walker, C.D. (2004) High levels of cortisol among adolescent offspring of parents with bipolar disorder: a pilot study. Psychoneuroendocrinol., 29, 99–106. 10. Rybakowski, J.K. and Twardowska, K. (1999) The dexamethasone/corticotrophin-releasing hormone test in depression in bipolar and unipolar affective illness. J. Psychiat. Res., 33, 363–370. 11. Schmider, J., Lammers, C.H., Gotthardt, U. et al. (1995) Combined dexamethasone/corticotropin-releasing hormone test in acute and remitted manic patients, in acute depression, and in normal controls: I. Biol. Psychiatry, 38 (12), 797–802.
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12. Watson, S., Gallagher, P., Ritchie, J.C. et al. (2004) Hypothalamic-pituitary-adrenal axis function in patients with bipolar disorder. Brit. J. Psychiat., 184, 496–502. 13. Watson, S., Thompson, J.M., Malik, N. et al. (2005) Temporal stability of the dex/CRH test in patients with rapid-cycling bipolar I disorder: a pilot study. Aust. NZ J. Psychiat., 39, 244–248. 14. Dinan, T.G., Lavelle, E., Scott, L.V. et al. (1999) Desmopressin normalises the blunted adrenocorticotropin response to corticotropin-releasing hormone in melancholic depression: evidence of enhanced vasopressinergic responsivity. J. Clin. Endocrinol. Metab., 84, 2238–2240. 15. Watson, S., Gallagher, P., Ferrier, N. and Young, A.H. (2006) Post-dexamethasone arginine vasopressin levels in patients with severe mood disorders. J. Psychiat. Res., 40, 353–359. 16. Wasserman, D., Sokolowski, M., Rozanov, V. and Wasserman, J. (2008) The CRHR1 gene: a marker for suicidality in depressed males exposed to low stress. Genes Brain Behav., 7 (1), 14–19. 17. Stratakis, C.A., Sarlis, N.J., Berrettini, W.H. et al. (1997) Lack of linkage between the corticotrophin-releasing hormone (CRH) gene and bipolar affective disorder. Mol. Psychiat., 2, 483–485. 18. De Luca, V., Tharmalingam, S. and Kennedy, J.L. (2007) Association study between the corticotrophin-releasing hormone receptor 2 gene and suicidality in bipolar disorder. Eur. Psychiat., 22, 282–287. 19. Spillotaki, M., Salpeas, V., Malitas, P. et al. (2006) Altered glucocorticoid receptor signalling cascade in lymphocytes of bipolar disorder patients. Psychoneuroendocrinol., 31, 748–760. 20. Xing, G.Q., Russell, S., Webster, M.J. and Post, R.M. (2004) Decreased expression of mineralscorticoid receptor mRNA in the prefrontal cortex in n achizophrenia and bipolar disorder. Int. J. Neuropsychopharmaol., 7, 143–153. 21. Whybrow, P.C., Prange, A.J. Jr and Treadway, C.R. (1969) Mental changes accompanying thyroid gland dysfunction. Arch. Gen. Psychiatry, 20, 48–63. 22. Bauer, M., Beaulieu, S., Dunner, D.L. et al. (2008) Rapid cycling bipolar disorder – diagnostic concepts. Bipolar Disord., 10, 153–162. 23. OConnor, D., Gwirtsman, H. and Loosen, P.T. (2003) Thyroid function in psychiatric disorders, in Psychoneuroendocrinology: The Scientific Basis of Clinical Practice (eds O.M. Wolkowitz and T.J. Rothschild), American Psychiatric Press, Inc., Washington DC. 24. Frye, M.A., Denicoff, K.D., Bryan, A.L. et al. (1999) Association between lower serum free T4 and greater mood instability and depression in lithium-maintained bipolar patients. Am. J. Psychiatr., 156, 1909–1914. 25. Cole, D.P., Thase, M.E., Mallinger, A.G. et al. (2002) Slower treatment response in bipolar depression predicted by lower pretreatment thyroid function. Am. J. Psychiatr., 159, 116–121. 26. Cowdry, R.W., Wehr, T.A., Zis, A.P. and Goodwin, F.K. (1983) Thyroid abnormalities associated with rapid-cycling bipolar illness. Arch. Gen. Psychiatr., 40, 414–420. 27. Bauer, M.S. and Whybrow, P.C. (1990) Rapid cycling bipolar affective disorders. II. Treatment of refractory rapid cycling
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28.
29.
30.
31.
32.
33.
34.
35.
36.
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with high-dose levothyroxine: a preliminary study. Arch. Gen. Psychiatr., 47, 435–440. Gyulai, L., Bauer, M., Bauer, M.S. et al. (2003) Thyroid hypofunction in patients with rapid cycling bipolar disorder after lithium challenge. Biol. Psychiatry, 53, 899–905. Baethge, C., Blumentritt, H., Bergh€ ofer, A. et al. (2005) Longterm lithium treatment and thyroid antibodies: a controlled study. J. Psychiatry Neurosci., 30 (6), 423–427. Kupka, R.W., Nolen, W.A., Post, R.M. et al. (2002) High rate of autoimmune thyroiditis in bipolar disorder: lack of association with lithium exposure. Biol. Psychiatry, 51, 305–311. Stancer, H.C. and Persad, E. (1982) Treatment of intractable rapid-cycling manic-depressive disorder with levothyroxine. Arch. Gen. Psychiatr., 39, 311–312. Bauer, M.S. and Whybrow, P.C. (1990) Rapid cycling bipolar affective disorders. II. Treatment of refractory rapid cycling with high-dose levothyroxine: a preliminary study. Arch. Gen. Psychiatr., 47, 435–440. Baumgartner, A., Bauer, M. and Hellweg, R. (1994) Treatment of intractable non-rapid cycling bipolar affective disorder with high-dose thyroxine: an open clinical trial. Neuropsychopharmacol., 10, 183–189. Bauer, M., Bergh€ ofer, A., Bschor, T. et al. (2002) Supraphysiological doses of L-thyroxine in the maintenance treatment of prophylaxis-resistant affective disorders. Neuropsychopharmacol., 27, 620–628. Bauer, M., Hellweg, R., Gr€ af, K.J. and Baumgartner, A. (1998) Treatment of refractory depression with high-dose thyroxine. Neuropsychopharmacol., 18, 444–455. Bauer, M., Szuba, M.P. and Whybrow, P.C. (2003) Psychiatric and behavioral manifestations of hyper- and hypothyroidism, in Psychoneuroendocrinology: The Scientific Basis of Clinical Practice (eds O.M. Wolkowitz and T.J. Rothschild), American Psychiatric Press, Inc., Washington DC, pp. 419–444.
37. Gyulai, L., Bauer, M., Espana-Garcia, F. et al. (2001) Bone mineral density in pre- and post-menopausal women with affective disorder treated with long-term L-thyroxine augmentation. J. Affect. Disord., 66, 185–191. 38. Bauer, M., Heinz, A. and Whybrow, P.C. (2002) Thyroid hormones, serotonin and mood: of synergy and significance in the adult brain. Mol. Psychiatr., 7, 140–156. 39. Bauer, M., Goetz, T., Glenn, T. and Whybrow, P.C. (2008) The thyroid-brain interaction in thyroid disorders and mood disorders. J. Neuroendocrinol., 20, 1101– 1114. 40. Bauer, M., Silverman, D.H.S., Schlagenhauf, F. et al. (2009) Brain glucose metabolism in hypothyroidism: a positron emission tomography study before and after thyroid hormone replacement therapy. J. Clin. Endocrinol. Metab., 94 (8), 2992–2999. 41. Bauer, M., London, E.D., Rasgon, N. et al. (2005) Supraphysiological doses of levothyroxine alter regional cerebral metabolism and improve mood in bipolar depression. Mol. Psychiatry., 10 (5), 456–469. 42. Henley, W.N. and Koehnle, T.J. (1997) Thyroid hormones and the treatment of depression: An examination of basic hormonal actions in the mature mammalian brain. Synapse, 27, 36–44. 43. Whybrow, P.C. and Prange, A.J. Jr (1981) A hypothesis of thyroid-catecholamine-receptor interaction. Arch. Gen. Psychiatr., 38, 106–113. 44. Ansseau, m., von Frenckell, R., Cerfontaine, J.L. et al. (1987) Neuroendocrine evaluation of catecholaminergic neurotransmission in mania. Psychiat. Res., 22, 193–206. 45. Dinan, T.G., Yatham, L.N., OKeane, V. and Barry, S. (1991) Blunting of noradrenergic stimulated growth hormone release in mania. Am. J. Psychiat., 148, 936–938. 46. Thakore, J.H., OKeane, V. and Dinan, T.G. (1996) dfenfluramine-induced prolactin responses in mania: evidence for serotonergic subsensitivity. Am. J. Psychiatry, 153 (11), 1460–1463.
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Circadian Rhythms and Sleep in Bipolar Disorder Greg Murray1 and Allison Harvey2 1 2
Swinburne University of Technology, Hawthorn, Australia Sleep and Psychological Disorders Lab, University of California, Berkeley, CA, USA
Introduction and overview Circadian rhythm hypotheses have been prominent in the explanation of bipolar disorder (BD) for more than 20 years [1,2], and changes in sleep are part of diagnostic criteria [3]. Biological rhythmicity is also a priority for patients, who report significant concern about their sleep [4], and readily appreciate the importance of rhythm stability [5]. In short, there is consensus that biological rhythms play a critical role in the emotion dysregulation at the heart of BD.1 Biological rhythm approaches to BD complement the explanatory approaches discussed elsewhere in this volume, and this chapter includes numerous examples of overlap between circadian/sleep pathways and other targets of investigation. The aim of this review chapter is to encourage further research into these important pathways, by tracing the limits of scientific knowledge about biological rhythms in BD. We first outline the basics of circadian rhythms and sleep, highlighting the challenge of empirically separating these two factors. Subsequently, literature on circadian- and sleep-moderation of emotion is reviewed, largely focusing on non-clinical populations. Evidence for an association between biological rhythms and BD is detailed next, and causal inferences considered. The following section considers potential mechanisms of biological rhythm action in BD, particularly the impact of clock genes. Finally, we introduce clinical implications of the fact that biological rhythmicity is modified by behaviour (Section 20.6).
Circadian rhythms and sleep Circadian system
ment with the earths cyclic environment by predicting critical environmental change [6]. In mammals, the circadian pacemaker responsible for the temporal internal organization and generation of endogenous rhythms of approximately 24 h is located in the hypothalamic suprachiasmatic nucleus (SCN, [7]).2 At the molecular level, intrinsically rhythmic cells of the SCN generate self-sustained rhythmicity via an autoregulatory transcription-translation feedback loop regulating expression of the Period (Per1, Per2, Per3), cryptochrome (Cry1, Cry2), TIM, DEC1 and DEC2 genes [8].3 The endogenous period generated in the SCN is close to, but generally not equal to 24-hour. The process by which the pacemaker is both set to a 24-hour period and kept in appropriate phase with seasonally shifting astronomical day length is called entrainment. An important property of the circadian system, therefore, is its fundamentally open nature, and this open nature includes feedback to the pacemaker from clock-controlled activity of the organism [10]. Entrainment occurs via zeitgebers (environmental events that can affect phase and period of the clock), the most prominent of which is the daily alteration of light and dark due to the planets rotation [11]. To a lesser degree, the SCN is also responsive to non-photic cues, including arousal/locomotor activity, social cues, feeding, sleep deprivation and temperature [12].
Sleep Phylogenetically, sleep is a more recent and less ubiquitous adaptation than circadian rhythmicity [13]. The specific adaptive function of sleep is unknown, but the fact that sleep is strongly conserved in mammals [14], and evidence
The endogenous circadian time-keeping system, strongly conserved across species, is adapted to optimize engage2
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The term biological rhythms is used to encompass both circadian and sleep-wake processes. Bipolar Disorder: Clinical and Neurobiological Foundations Edited by Lakshmi N. Yatham and Mario Maj © 2010 John Wiley & Sons, Ltd. ISBN: 978-0-470-72198-8
Endogenous circadian oscillators are in fact located in cells throughout the body. The circadian system is organized hierarchically, with the SCN clock as overarching pacemaker of cellular circadian oscillators in most peripheral body cells. 3 Molecular genetic investigations into the circadian system have been so successful that they have been forwarded as a model for exploring other domains of interest [9].
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for marked physical and cognitive consequences of sleep deprivation in humans (e.g. [15]), suggest that sleep serves an important function. Evidence is also accumulating for sleeps role in particular types of cognition [16], memory consolidation and brain plasticity [17–19,21]. Based on characteristic physiological patterns, normal sleep can be divided into two distinct states: rapid eye movement (REM) and non-rapid eye movement (NREM). During REM (or paradoxical) sleep, the brain is highly activated, the muscles of the body are paralysed and dreaming occurs. In NREM, growth hormone is preferentially secreted and protein synthesis is increased, leading to the view that NREM may be critical for energy conservation and restoration. Characteristic EEG patterns support NREM sleep being further categorized into substages: (1) drowsiness, transition to sleep, lowest arousal thresholds; (2) light sleep; (3) and (4) deep sleep, highest arousal thresholds. Together, (3) and (4) are often called delta or slow wave sleep (SWS) [22]. On a typical night, sleep of a young adult begins in Stage (1) NREM and progresses through deeper NREM stages. The first episode of REM sleep occurs approximately 80–100 minutes after sleep onset. Thereafter, NREM sleep and REM sleep cycle with a period of approximately 90 minutes. NREM stages (3) and (4) concentrate in the early cycles and REM sleep episodes lengthen across the night. Therefore, in a normal night of sleep, SWS predominates in the early part of the sleep phase, while REM is more prevalent later in the night. Indeed, we are most likely to wake through the gate of REM sleep.
The relationship between circadian and sleep processes The sleep-wake cycle is regulated by two processes, one of which is the clock-like circadian system described above (typically called Process C). The second factor is sleeps (hourglass-like) homoeostatic self-modulation (or Process S [23]). Process S is accumulated during wakefulness, dissipates during sleep and regulates duration and structure of sleep on the basis of the history of sleep and wakefulness. The bidirectional interaction between processes C and S predicts the propensity, timing and internal structure of sleep [24].4 A family of models, prominently Borbelys twoprocess model [27] and the opponent process model [28]
4
The interaction of these two processes regulates not only the sleepwake cycle: nervous system activity, neurobehavioural performance and hormonal levels are demonstrably moderated by this interaction [25]. The two also determine the macro-architecture of sleep, with the SCN primarily driving the timing of REM, and Process S determining the timing of SWS [26].
share the assumption of two interacting processes in sleep regulation, and differ in the nature of the proposed interaction.5 The neurobiology of the C S interaction in sleep regulation is not fully understood. Research by Saper and others [31–33] supports a model of sleep in which arousal is mediated by discrete neuronal populations of the ascending reticular activating system, which project to the thalamus and basal forebrain. The mechanism by which this arousal system is curtailed to produce sleep involves the ventrolateral preoptic nucleus (VLPO). Mutual inhibition between arousal circuits and the VLPO ensure stability in either end state (asleep or awake) and rapid switching between the two. This so-called flip/flop switch [31] is modulated by a circadian alerting signal (operating through multiple relays in the hypothalamus), and, on the other side of the switch, the homoeostatic sleep drive.6 The neural mechanisms of the sleep homoeostat are unknown, but there is growing evidence that the wake-linked accumulation of the purine nucleoside adenosine may be involved through its inhibition of arousal circuits [34,35], potentially via astrocytes [36]. Under normal conditions Process C and Process S operate in synchrony [26], and in the field we can only observe the sleep-wake cycle, which is a complex endpoint of volition, circadian afferents and the sleep homoeostat. Most of what we know about separate circadian and sleep processes therefore comes from laboratory studies. In the forced desynchrony (FD) protocol, a non-24 h sleep wake schedule (typically 28 h) is enforced. Under these conditions, the circadian oscillator continues to cycle at approximately 24 h and desynchronizes from the sleep/wake cycle, which adopts the enforced 28-h period, thereby enabling separate estimate of circadian and sleephomoeostatic components [37]. The sleep disruption and isolation of the multi-day FD protocol make it unsuitable for individuals vulnerable to emotion dysregulation. Indeed, most FD studies screen participants to ensure they are exceptionally phlegmatic (S. Lockley, personal communication, March 2007), and no FD studies in BD have been reported.
5 Additional factors, including sleep inertia [29] and ultradian cycling between NREM and REM phases within sleep [30] are added in some models.
The same pathways are involved in a second flip/flop switch regulating the alternation between REM and NREM sleep. The sleep active neurons in the VLPO send a major output to the REM-off side of the REM switch. The orexin neurons in the lateral hypothalamus reinforce the wake side of the wake-sleep switch, and send an excitatory projection to the same REM-off target, thus preventing switching from wake into REM. 6
Circadian Rhythms and Sleep in Bipolar Disorder
Sleep, circadian function and affect As in the study of other psychiatric disorders, it is not uncommon to conceptualize BD as the extreme clinical manifestation of a neurobehavioral trait that is distributed throughout the population. Specifically, BD can be characterized as a pathologically elevated propensity to emotional dysregulation [38–40]. Before reviewing the known associations between biological rhythms and BD, it is therefore useful to review findings linking biological rhythms and emotion regulation in normal populations.
Sleep disturbance and emotion Behavioural data support the lay assumption that sleep disturbance strongly increases negative mood [41–46]. Sleep loss has been shown to not only increase negative emotional response to goal-thwarting events, but also decrease positive emotional responses to goal-enhancing events [47].7 High levels of emotional arousal can also disturb sleep, raising the possibility of vicious cycles between sleep disturbance and emotion dysregulation [49]. At the neural systems level, sleep deprivation has been linked to decreased medial-prefrontal cortical activity and increased amygdala activation, a distribution of activation consistent with impaired top-down regulation of emotional responses [50]. Conversely, emotion circuits affect homoeostatic and circadian drives for sleep [51,52].
Circadian interactions with emotion The circadian system modulates current mood state, specifically states of positive affect [53–56] and challenges to the circadian system, such as shift work and jet lag have negative consequences for mood [57,58]. Under naturalistic conditions, emotional state also moderates circadian function via its influence on social rhythms, light exposure, arousal and sleep [12,59]. Bidirectional influence can also be traced at the neurobiologic level: afferents from the SCN project via the paraventricular thalamic nucleus to the mesolimbic dopaminergic reward system [60], while emotion circuits impact circadian (and homoeostatic) aspects of sleep regulation [51].
Particular importance of REM sleep in emotion regulation The sleep state most strongly regulated by the SCN, REM sleep, may be particularly important in emotional processing and emotional regulation. Key findings include correlations between pre-sleep mood and REM parameters, 7
In contrast, the manic ascent of BD may involve a positive feedback loop between decreased sleep and increased response to goal-enhancing events [48].
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prospective associations between dream content and psychological outcomes, and REM-facilitated recall of emotional information [61,62]. There is also converging evidence concerning the neurobiology of REM-supported emotional processing (see, [63–67]). Stickgold has proposed a neurocognitive model of dream construction and function in which dreaming is the conscious awareness of critical offline cortical generation functions occurring during sleep – the particular features of dreaming are consistent with activation of neural networks supporting weak cortical associations in the absence of dorsolateral prefrontal cortex or hippocampal feedback, but in the presence of active error detection circuits in the anterior cingulate cortex [19,20].
Neurotransmitters and the sleep circadian emotion interaction At least two neurotransmitter circuits are involved in the link between biological rhythms and emotion. First, dopaminergic pathways, especially cells of the ventral tegmental area (VTA) and zona compacta of the substantia nigra (SNc) are strongly implicated in reward motivation and positive affects [68–70]. Dopamine has been called a key substance in the regulation of sleep-wake [71], and dopaminergic neurons of the VTA and SNc are again implicated [72], particularly in REM sleep [73]. Dopaminergic pathways also have multiple interactions with the SCN [60,74,75]. Second, serotonergic pathways have pronounced (albeit complex) relationships with anxiety and stress responses [76]. Serotonergic pathways are critical in circadian function ([77]; and vice versa, [78]), sleep per se [33,79] and the interaction between stress and sleep [46,80–83].
From normal populations to patients with BD The above review presents strong behavioural evidence for the notion that emotion and emotion regulation are associated with sleep (particularly REM sleep) and with circadian function. Neuroanatomical pathways subserving these associations have been outlined, and the putative role of two critical neurotransmitters (dopamine and serotonin) has been described. It seems reasonable to propose that the same relationships hold in patients with BD, and indeed to hypothesize that the symptoms of mood episodes in BD may be attributable, at least in part, to the pathways described here. It is particularly noteworthy that an independent literature argues for dopaminergic and serotonergic circuits as critical pathways in BD [84,85].
Sleep, circadian function and mood symptoms in BD A number of specific links have been demonstrated between BD and circadian and/or sleep function. Our aim here is to
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critically consider the nature and implications of these known associations, and it is useful to group findings as shown in Box 1.
length and mood change in BD has been found in a number of studies [110,112–115]. .
Experimental and treatment effects -Deliberate sleep deprivation is a same-day powerful treatment
Box 1 Associations between BD and biological rhythm function .
Neurobiology shared between BD and biological rhythms -Circadian and sleep function are subserved by the same brain regions [86] and neurotransmitters [84,85] putatively involved in mood disorder. -Polymorphisms in circadian genes have been associated with symptoms of BD in pre-clinical and human studies [87–90].
.
Biological rhythms as diatheses to BD -Sleep disturbance and instability of 24 h rhythms continues when BD patients are not acutely ill [4,91–94]. -Dysregulation of 24 h activity rhythms has been reported in a familial high risk sample [95]. -Neuroticism, the primary (albeit non-specific) temperamental predisposition to BD, may be associated with circadian instability [96]. -Biological sensitivity to light, as measured in night-time suppression of the pineal hormone melatonin, has been proposed as a trait marker of vulnerability to BD [97]
for bipolar (and unipolar) depression [112,116]. Maintenance of the therapeutic effect beyond the next sleep phase is a target of current research [117]. -In a recent study, combined sleep deprivation, sleep phase advance and timed light was an effective adjunctive intervention for bipolar depression [118]. -Bright light can induce symptoms of mania [117], and has significant effects on bipolar depression [119]. -Experimentally induced sleep deprivation induces hypomania or mania in a proportion of patients [111,112] -Bright light can induce symptoms of mania, and dark therapy has been found to stabilize patients with rapid cycling BD [117,120]. -Effective treatments for BD (lithium, antidepressants, anxioloytics, electroconvulsive therapy) affect circadian function [121–123]. Lithium and selective serotonin re-uptake inhibitors impact genes involved in circadian function [77,124–126]. -Improved social rhythmicity decreases relapse in BD [127].
-Delayed circadian phase of melatonin secretion has been reported in euthymic BD patients [98], and BD patients self-report as more evening type [99]. .
Cross-sectional associations -Some clinical features of BD are timed phenomena: diurnal variation in mood and early morning wakening in depression, as well as seasonal and other cyclic variation in symptoms, are suggestive of circadian involvement [100]. -Circadian rhythms (including activity, body temperature, melatonin, cortisol and thyrotropin) are altered in episodes of BD (see, for a review [101,102]). -Mania is strongly associated with decreased need for sleep, and insomnia and hypersomnia are both reliably found in bipolar depression (see, for a review, [103]). -Episodes of BD have been associated with sleep polysomnographic changes ([104–106]). The most consistent finding is abnormalities of REM sleep in both mania and bipolar depression (typically shorter latency and increased density, see [103]).
.
Predictive relationships -Episodes of BD can be precipitated by zeitgeber challenges, including seasonal change and time zone travel (see, for a review [107]). -Sleep disturbance is the most common prodrome of mania, and a significant prodromal symptom of bipolar depression [108].8 Altered sleep often precedes deterioration in clinical state and worsens further during an episode [108,110,111].
8
Sleep reduction has been called the final common pathway in the genesis of mania [109].
The findings summarized in Box 1 indicate that most phases of BD (depressed, manic, episode prodrome and inter-episode periods) are cross-sectionally associated with prominent sleep and/or circadian rhythm abnormalities. What is the significance of this conclusion? Disturbed sleep has significant impacts on quality of life in BD [128,129]. Also, as described above, sleep disturbance has detrimental impacts on emotion regulation in normal populations, an effect which may be greater in patients with BD. The primary consequence of this conclusion, then, is that outcomes in BD can be improved by addressing associated sleep difficulties. Moreover, due to the interdependency between sleep and circadian processes, it is reasonable to expect that interventions targeting sleep disturbance in BD may ameliorate circadian abnormalities and vice versa [130,131]. Such interventions are briefly introduced below. A range of evidence also suggests that sleep disturbance plays a causal role in BD. Not only is there prospective data linking sleep to mood in BD, but sleep changes reliably precede episodes (especially mania) and correlate with symptom load. Most strikingly, manipulation of sleep (sleep deprivation) improves bipolar depression and can induce hypomania/mania in some patients. This conclusion also aligns with current clinical practice, in which sleep monitoring is a central relapse prevention strategy [132]. The literature cited in Box 1 also provides support for circadian function as a causal pathway to BD. First, relapse can be precipitated by zeitgeber challenge (particularly light
Circadian Rhythms and Sleep in Bipolar Disorder
manipulations) and effective treatments for acute episodes moderate circadian parameters. Second, a range of data suggests that circadian instability may act as a trait-like vulnerability or diathesis to BD. For example, activity and sleep disruptions are found outside episodes and in children of BD patients. Further evidence for a circadian diathesis comes from a possible link between circadian function and the general vulnerability trait neuroticism, and from preclinical and human studies suggesting an association between specific clock genes and BD. This conclusion is also consistent with existing approaches which emphasize circadian instability as an element of pathogenesis and a target for relapse prevention efforts ([101,130,133–135]).
Mechanisms underpinning biological rhythm involvement in BD The mechanisms by which biological rhythms affect the development, course and treatment of BD are not known. Early hypotheses emphasized gross abnormalities in circadian function, including short intrinsic period of the oscillator [136], phase advance [137], phase delay [138] and attenuated circadian amplitude [96,139,140]. The relation between Process C and S has also been implicated [141], and Process S itself has been hypothesized to underpin the therapeutic effect of sleep deprivation [143]. Coupling to external zeitgebers is critical in some models [127,140,143,144]. Physiological investigations of these molar hypotheses have been scarceover the pastdecade[2],and themethodological issues raised above are a barrier to progress. As research into molar circadian hypotheses has waned, the study of the genetics of circadian function in BD has expanded, and the remainder of this section is devoted to this burgeoning literature. As noted above, the molecular basis of the circadian clock is well understood, permitting the investigation of specific circadian genes that potentially influence BD. Traditional candidate gene studies have found trends for an association between BD and the CLOCK gene [145,146], but findings are inconsistent [147]. A single nucleotide polymorphism in the 30 flanking region of CLOCK has also been associated with clinical features of BD, namely patterns of more activity in the evening, delayed sleep onset and less sleep [148], higher rates of initial, middle and early insomnia [149], recurrence of illness episodes [149] and changes in neural response [87]. Several studies show that the mood stabilizer lithium affects circadian rhythms through the glycogen synthase kinase 3 beta gene (GSK-3b, [126,150,151]). Valproic acid may act via the same intracellular signalling pathway [152,153]. Investigations of associations between BD, its clinical features and GSK-3b, have not been consistent [154–156]. Findings for an association with the NR1D1
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gene, regulation of which by GSK-3b is important for clock function, are also mixed [157,158]. Other circadian genes for which some support exists include PER3 [159,160], ARNTL [100,160] and TIMELESS [100]. In addition, Shi et al. [146] reported an interaction between CLOCK and two other genes of interest for their potential circadian function (BHLHB2, CSNK1E). In one genome-wide association study [161], the gene VGCNL1 (the mouse homologue of which regulates circadian function) had a significant association with caseness. Larger genome-wide studies have not identified circadian gene associations [162,163]. Pre-clinical studies observing the effect of gene mutations have been a fruitful source of hypotheses. Mice with a mutation in the CLOCK gene show robust sensitization to cocaine and increases in the preference for and reward value of cocaine [90,164]. These mice also have increased dopaminergic activity in the ventral tegmental area (VTA) which may be responsible for the increase in the reward value of cocaine [164]. Notably, CLOCK mutant mice also show mania-like behaviour, which is reversed by lithium treatment [165] and this reversal is mediated by altered regulation of dopamine release in the VTA [164]. Evidence for a BD-relevant pathway linking circadian genes to the dopaminergic reward system is consistent with the strong comorbidity between BD and substance abuse [166], the association between manic states and psychostimulant use [167], and the action of atypical antipsychotic medications for mania [152]. A dopaminergic reward clock gene circuit has been reliably demonstrated in non-human species (e.g. [168,169]) and is strongly implicated in human mood regulation [55,86,170–173].9 It is important to situate these clock gene findings within the broader genetics of BD (see Chapter 12, on Genetics of Bipolar Disorder). Like other psychiatric disorders, BD is probably inherited polygenetically, with numerous genes adding small effects to overall risk [161]. Evidence from human studies suggests that these genetic effects are probabilistic, non-specific, contingent on gene gene environment interactions, and causally remote from the phenotype [176].10 Given small genetic effects on risk, it is not surprising that failure to replicate associations is common, and that researchers have sought to refine the phenotype under investigation. In particular, endophenotypes (quantitative phenotypes
9
Clock genes in the mesolimbic system (i.e. beyond the SCN) play a significant role in the reward clock gene interaction (e.g. [175,176]). 10
Indeed, genes identified as elevating risk for BD are not accurately characterised as pathogenic. The gene DGKH, for example, has support from genome-wide association studies as one of the stronger predictors of BD diagnosis. The majority of patients have this gene (89.9% in a Europeanorigin sample, [162]), but so do the majority of healthy controls (84.7%, op. cit.).
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intermediate between the genotype and the disorder [177]), are a major focus of contemporary study. Disturbance of circadian function is commonly forwarded as a candidate endophenotype for BD [89,100,178–181].
Psychosocial interventions targeting biological rhythms in BD Interactions between biology and psychosocial factors cannot be ignored in a biological rhythm approach to BD [182]. The circadian system is adapted to be open to external cues, and environmental manipulations (particularly light exposure) have predictable effects on amplitude and phase of the endogenous oscillator [183,184]. Under naturalistic conditions, human exposure to zeitgebers is gated by behaviour, prominently the sleep-wake cycle (above). The sleep-wake cycle is in turn moderated by volitional and social factors, and mediated partly through cognitive mechanisms (above). Biological rhythms therefore function as an open loop crossing multiple levels of the person and their environment. Psychosocial factors are integral to a biological rhythm explanation of BD, a conclusion which underpins the recent development of novel adjunctive psychosocial interventions for BD. The social zeitgeber hypothesis proposes that fundamental circadian instability in BD can be moderated by increased stabilization of daily rhythms and zeitgeber exposure [133]. This hypothesis takes clinical form in Social Rhythm Therapy ([185], see Chapter 33, on Interpersonal and Social Rhythm Therapy), which is a largely behavioural psychotherapy aimed at helping patients maintain stability in their social rhythms and so reduce the risk of relapse. In the treatment of BD, Social Rhythm Therapy is typically integrated with principles from interpersonal psychotherapy in a treatment known as Interpersonal and Social Rhythm Therapy (IPSRT, [185]). IPSRT has proven effective in two large studies [127,186]. Interest in biological rhythm management is expanding alongside growing research into adjunctive psychosocial treatments for BD [117,133,187,188]. Rhythm stabilization is a core component in most adjunctive psychosocial treatments for BD [134], including Cognitive Behavioural Therapy (see Chapter 32, Cognitive-Behavioural Therapy). Improving sleep quality is an important component of rhythm stabilization, and has functional benefits in its own right [189]. Interestingly, management of the sleep-wake cycle is a commonly reported well-being strategy amongst people with BD [190]. Our qualitative investigations suggest that this strategy is appealing not only because it is judged effective: it is empowering for patients to understand that a core element of BD biology is partly under their control (unpublished data). Chronotherapeutic interventions are an important target for further study. Future research into these interventions
should seek to identify moderators (e.g. light sensitivity, severity and diagnosis, temperament, gender) and mediators (e.g. sleep quality, sleep architecture, circadian rhythmicity, daytime arousal) of treatment outcome. Our knowledge of possible interactions between behavioural and pharmacological treatments is also limited. The recent discovery that lights neurobiological effects are blueshifted [191,192] encourages a more sophisticated definition of dosage in light treatment for BD.
Summary and conclusions Four main themes can be drawn from the present review. First, standard laboratory protocols for separating sleep and circadian function may not be feasible in vulnerable populations, so the biologically important distinction between these processes is difficult to investigate. Fundamental questions can instead be addressed by extrapolation from well populations, perhaps quantified by their degree of risk for BD. Second, biological rhythm pathways are interwoven with other pathways implicated in BD (e.g. monoamines, GSK3b) and future research should actively address this complexity. Third, the wide variety of evidence demonstrating biological rhythm involvement in BD is a rich source of hypotheses for future work in this burgeoning area. Research in humans is yet to discover mechanisms of large effect, but preclinical studies suggest the reward circadian interaction may be particularly fruitful. Finally, interventions built on chronobiological principles should be energetically investigated. These interventions are theoretically plausible, benign, economical and attractive to patients. In conclusion, research into sleep and circadian dysfunction in BP is an exciting, challenging and rewarding avenue for the future. It has potential to significantly broaden our understanding of one of the most serious of the mental illnesses and to improve the quality of life and functioning of patients.
References 1. Goodwin, F. and Jamison, K. (1990) Manic-Depressive Illness, Oxford University Press, NY. 2. Goodwin, F.K. and Jamison, K.R. (2007) Manic-Depressive Illness: Bipolar Disorders and Recurrent Depression, Oxford University Press, New York. 3. American Psychiatric Association (2000) Diagnostic and Statistical Manual of Mental Disorders: DSM-IV-TR, 4th Text Revision edn, Author, Washington, DC. 4. Harvey, A.G., Schmidt, D.A., Scarna, A. et al. (2005) Sleeprelated functioning in euthymic patients with bipolar disorder, patients with insomnia, and subjects without sleep problems. Am. J. Psychiatry, 162 (1), 50–57. 5. Frank, E. (2005) Treating Bipolar Disorder: A Clinicians Guide to Interpersonal and Social Rhythm Therapy, Guilford Press, NY.
Circadian Rhythms and Sleep in Bipolar Disorder 6. Moore-Ede, C.M. (1986) Physiology of the circadian timing system: predictive versus reactive homeostasis. Am. J. Physiol., 250, R737–R752. 7. Reppert, S.M. and Weaver, D.R. (2002) Coordination of circadian timing in mammals. Nature, 418, 935–941. 8. Takahashi, J.S., Hong, H.-K., Ko, C.H. and McDearmon, E.L. (2008) The genetics of mammalian circadian order and disorder: implications for physiology and disease. Nat. Rev. Genet., 9 (10), 764–775. 9. Takahashi, J.S., Shimomura, K. and Kumar, V. (2008) Searching for genes underlying behavior: lessons from circadian rhythms. Science, 322 (5903), 909–912. 10. Mrosovsky, N. (1999) Critical assessment of methods and concepts in nonphotic phase shifting. Biol. Rhythm Res., 30 (2), 135–148. 11. Roennebert, T. and Foster, R.G. (1997) Twilight times: light and the circadian system. Photochem. Photobiol., 66, 549–561. 12. Mistlberger, R.E., Antle, M.C., Glass, J.D. and Miller, J.D. (2000) Behavioral and serotonergic regulation of circadian rhythms. Biol. Rhythm Res., 31 (3), 240–283. 13. Rial, R.V., Nicolau, M.C., Gamundi, A. et al. (2007) The trivial function of sleep. Sleep Med. Rev., 11 (4), 311–325. 14. Zepelin, H., Siegel, J.M. and Tobler, I. (2005) Mammalian sleep, in Principles and Practice of Sleep Medicine, 4th edn (eds M.H. Kryger, T. Roth and W.C. Dement), Elsevier Saunders, Philadelphia, pp. 91–100. 15. Durmer, J.S. and Dinges, D.F. (2005) Neurocognitive consequences of sleep deprivation. Semin. Neurol., 25 (1), 117–129. 16. Wagner, U., Gais, S., Haider, H. et al. (2004) Sleep inspires insight. Nature, 427 (6972), 352–355. 17. Frank, M.G. and Benington, J.H. (2006) The role of sleep in memory consolidation and brain plasticity: dream or reality? Neuroscientist, 12 (6), 477–488. 18. Hu, P., Stylos-Allan, M. and Walker, M.P. (2006) Sleep facilitates consolidation of emotional declarative memory. Psychol. Sci., 17 (10), 891–898. 19. Stickgold, R. (2005) Sleep-dependent memory consolidation. Nature, 437 (7063), 1272–1278. 20. Stickgold, R. (2005) Why we dream, in Principles and Practice of Sleep Medicine (eds M.H. Kryger, T. Roth and W.C. Dement), Elsevier, Philadelphia, pp. 579–587. 21. Stickgold, R. and Walker, M.P. (2007) Sleep-dependent memory consolidation and reconsolidation. Sleep Med., 8 (4), 331–343. 22. Shneerson, J.M. (2000) Handbook of Sleep Medicine, Blackwell, Oxford. 23. Borbely, A.A. (1980) Sleep: circadian rhythm versus recovery process, in Functional States of the Brain: Their Determinants (eds M. Koukkou, D. Lehmann and J. Angst), Elsevier, Amsterdam, pp. 151–161. 24. Dijk, D.-J. and Franken, P. (2005) Interaction of sleep homeostasis and circadian rhythmicity: dependent or independent systems? in Principles and Practice of Sleep Medicine (eds M.H. Kryger, T. Roth and W.C. Dement), Saunders, Philadelphia, pp. 418–434. 25. Wyatt, J.K., Ritz-De Cecco, A., Czeisler, C.A. and Dijk, D.J. (1999) Circadian temperature and melatonin rhythms,
26.
27. 28.
29.
30.
31.
32.
33.
34.
35. 36.
37.
38.
39.
40. 41.
42.
|
269
sleep, and neurobehavioral function in humans living on a 20-h day. Am. J. Physiol., 277 (4 Pt 2), R1152–R1163. Czeisler, C.A., Buxton, O.M. and Khalsa, S.B.S. (2005) The human circadian timing system and sleep-wake regulation, in Principles and Practice of Sleep Medicine, 4th edn (eds M.H. Kryger, T. Roth and W.C. Dement), Elsevier, Philadelphia, pp. 375–394. Borbely, A.A. (1982) A two process model of sleep regulation. Hum. Neurobiol., 1 (3), 195–204. Edgar, D.M., Dement, W.C. and Fuller, C.A. (1993) Effect of SCN lesions on sleep in squirrel monkeys: evidence for opponent processes in sleep-wake regulation. J. Neurosci., 13 (3), 1065–1079. Folkard, S. and Akerstedt, T. (1992) A three-process model of the regulation of alertness-sleepiness, in Sleep, Arousal, and Performance (eds R.J. Broughton and R.D. Ogilvie), Basel, Birkhauser, Verlag, Boston, pp. 11–26. McCarley, R.W. and Hobson, J.A. (1975) Neuronal excitability modulation over the sleep cycle: a structural and mathematical model. Science, 189 (4196), 58–60. Fuller, P.M., Gooley, J.J. and Saper, C.B. (2006) Neurobiology of the sleep-wake cycle: sleep architecture, circadian regulation, and regulatory feedback. J. Biol. Rhythms, 21 (6), 482–493. Gooley, J.J. and Saper, C.B. (2005) Anatomy of the mammalian circadian system, in Principles and Practice of Sleep Medicine, 4th edn (eds M.H. Kryger, T. Roth and W.C. Dement), Elsevier, Philadelphia, pp. 335–350. Saper, C.B., Scammell, T.E. and Lu, J. (2005) Hypothalamic regulation of sleep and circadian rhythms. Nature, 437 (7063), 1257–1263. Heller, H.C. (2006) A global rather than local role for adenosine in sleep homeostasis. Sleep, 29 (11), 1382–1383. discussion 1387–1389. Landolt, H.P. (2008) Sleep homeostasis: a role for adenosine in humans? Biochem. Pharmacol., 75 (11), 2070–2079. Halassa, M.M., Florian, C., Fellin, T. et al. (2008) Astroctic modulation of sleep homeostasis and cognitive consequences of sleep loss. Neuron, 61, 213–219. Czeisler, C.A., Duffy, J.F., Shanahan, T.L. et al. (1999) Stability, precision, and near-24-hour period of the human circadian pacemaker. Science, 284 (5423), 2177–2181. Miklowitz, D.J. and Johnson, S.L. (2006) The psychopathology and treatment of bipolar disorder. Ann. Rev. Clin. Psychol., 2, 199–235. Murray, G., Goldstone, E. and Cunningham, E. (2007) Personality and the predisposition(s) to bipolar disorder: Heuristic benefits of a two-dimensional model. Bipolar Disord., 9, 453–461. Phillips, M.L. (2006) The neural basis of mood dysregulation in bipolar disorder. Cogn. Neuropsychiatry, 11 (3), 233–249. Dinges, D.F., Pack, F., Williams, K. et al. (1997) Cumulative sleepiness, mood disturbance, and psychomotor vigilance performance decrements during a week of sleep restricted to 4–5 hours per night. Sleep, 20 (4), 267–277. Drake, C.L., Roehrs, T.A., Burduvali, E. et al. (2001) Effects of rapid versus slow accumulation of eight hours of sleep loss. Psychophysiology, 38 (6), 979–987.
270
|
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43. El-Sheikh, M., Buckhalt, J.A., Mark Cummings, E. and Keller, P. (2007) Sleep disruptions and emotional insecurity are pathways of risk for children. J. Child Psychol. Psychiatry, 48 (1), 88–96. 44. Franzen, P.L., Siegle, G.J. and Buysse, D.J. (2008) Relationships between affect, vigilance, and sleepiness following sleep deprivation. J. Sleep Res., 17 (1), 34–41. 45. Hamilton, N.A., Catley, D. and Karlson, C. (2007) Sleep and the affective response to stress and pain. Health Psychol., 26 (3), 288–295. 46. Novati, A., Roman, V., Cetin, T. et al. (2008) Chronically restricted sleep leads to depression-like changes in neurotransmitter receptor sensitivity and neuroendocrine stress reactivity in rats. Sleep, 31 (11), 1579–1585. 47. Zohar, D., Tzischinsky, O., Epstein, R. and Lavie, P. (2005) The effects of sleep loss on medical residents emotional reactions to work events: a cognitive-energy model. Sleep, 28 (1), 47–54. 48. Johnson, S.L. (2005) Mania and dysregulation in goal pursuit: a review. Clin. Psychol. Rev., 25 (2), 241–262. 49. Dahl, R.E. and Lewin, D.S. (2002) Pathways to adolescent health sleep regulation and behavior. J. Adolesc. Health, 31 (6 Suppl.), 175–184. 50. Yoo, S.S., Gujar, N., Hu, P. et al. (2007) The human emotional brain without sleep – a prefrontal amygdala disconnect. Curr. Biol., 17 (20), R877–R878. 51. Saper, C.B., Cano, G. and Scammell, T.E. (2005) Homeostatic, circadian, and emotional regulation of sleep. J. Comp. Neurol., 493 (1), 92–98. 52. Yoshida, K., McCormack, S., Espana, R.A. et al. (2006) Afferents to the orexin neurons of the rat brain. J. Comp. Neurol., 494 (5), 845–861. 53. Boivin, D.B., Czeisler, C.A., Dijk, D.-J. et al. (1997) Complex interaction of the sleep-wake cycle and circadian phase modulates mood in healthy subjects. Arch. Gen. Psychiatry, 54, 145–152. 54. Murray, G., Allen, N.B. and Trinder, J. (2002) Mood and the circadian system: Investigation of a circadian component in positive affect. Chronobiol. Int., 19 (6), 1151–1169. 55. Murray, G., Nicholas, C.L., Kleiman, J., et al. (2009) Natures clocks and human mood: The circadian system modulates reward motivation. Emotion, 9 (5), 705–716. 56. Thayer, R.E. (1987) Problem perception, optimism, and related states as a function of time of day (diurnal rhythm) and moderate exercise: two arousal systems in interaction. Motiv. Emotion, 11 (1), 19–36. 57. Reinberg, A. and Ashkenazi, I. (2008) Internal desynchronization of circadian rhythms and tolerance to shift work. Chronobiol. Int., 25 (4), 625–643. 58. Srinivasan, V., Spence, D.W., Pandi-Perumal, S.R. et al. (2008) Jet lag: therapeutic use of melatonin and possible application of melatonin analogs. Travel Med. Infect. Dis., 6 (1–2), 17–28. 59. Ehlers, C.L., Frank, E. and Kupfer, D.J. (1988) Social zeitgebers and biological rhythms. Arch. Gen. Psychiatry, 45, 948–952. 60. Sleipness, E.P., Sorg, B.A. and Jansen, H.T. (2007) Diurnal differences in dopamine transporter and tyrosine hydrox-
61.
62.
63.
64.
65.
66.
67.
68.
69.
70.
71.
72.
73.
74.
75.
76.
77.
ylase levels in rat brain: dependence on the suprachiasmatic nucleus. Brain Research, 1129 (1), 34–42. Cartwright, R., Agargun, M.Y., Kirkby, J. and Friedman, J.K. (2006) Relation of dreams to waking concerns. Psychiatry Res., 141 (3), 261–270. Harvey, A.G., Mullin, B.C. and Hinshaw, S.P. (2006) Sleep and circadian rhythms in children and adolescents with bipolar disorder. Dev. Psychopathol., 18 (4), 1147–1168. Cantero, J.L., Atienza, M., Stickgold, R. et al. (2003) Sleepdependent theta oscillations in the human hippocampus and neocortex. J. Neurosci., 23 (34), 10897–10903. Maquet, P., Peters, J.-M., Aerts, J. et al. (1996) Functional neuroanatomy of human rapid-eye-movement sleep and dreaming. Nature, 383, 163–166. Maquet, P., Ruby, P., Maudoux, A. et al. (2005) Human cognition during REM sleep and the activity profile within frontal and parietal cortices: a reappraisal of functional neuroimaging data. Prog. Brain Res., 150, 219–227. Nishida, M., Pearsall, J., Buckner, R.L. and Walker, M.P. (2009) REM sleep, prefrontal theta, and the consolidation of human emotional memory. Emotion, 19 (5), 1158–1166. Wagner, U. and Born, J. (2008) Memory consolidation during sleep: interactive effects of sleep stages and HPA regulation. Stress, 11 (1), 28–41. Ashby, F.G., Isen, A.M. and Turken, A.U. (1999) A neuropsychological theory of positive affect and its influence on cognition. Psychol. Rev., 106 (3), 529–550. Barbano, M.F. and Cador, M. (2007) Opioids for hedonic experience and dopamine to get ready for it. Psychopharmacology (Berl.), 191 (3), 497–506. Bressan, R.A. and Crippa, J.A. (2005) The role of dopamine in reward and pleasure behaviour – review of data from preclinical research. Acta Psychiatr. Scand. Suppl 427, 14–21. Lima, M.M., Andersen, M.L., Reksidler, A.B. et al. (2008) Blockage of dopaminergic D(2) receptors produces decrease of REM but not of slow wave sleep in rats after REM sleep deprivation. Behav. Brain Res., 188 (2), 406–411. Monti, J.M. and Monti, D. (2007) The involvement of dopamine in the modulation of sleep and waking. Sleep Med. Rev., 11 (2), 113–133. Dahan, L., Astier, B., Vautrelle, N. et al. (2007) Prominent burst firing of dopaminergic neurons in the ventral tegmental area during paradoxical sleep. Neuropsychopharmacology, 32 (6), 1232–1241. Yuferov, V., Butelman, E.R. and Kreek, M.J. (2005) Biological clock: biological clocks may modulate drug addiction. Eur. J. Hum. Genet., 13 (10), 1101–1103. Yujnovsky, I., Hirayama, J., Doi, M. et al. (2006) Signaling mediated by the dopamine D2 receptor potentiates circadian regulation by CLOCK:BMAL1. Proc. Natl. Acad. Sci. USA, 103 (16), 6386–6391. Charney, D.S. (2004) Psychobiological mechanisms of resilience and vulnerability: implications for successful adaptation to extreme stress. Am. J. Psychiatry, 161 (2), 195–216. Sprouse, J., Braselton, J. and Reynolds, L. (2006) Fluoxetine modulates the circadian biological clock via phase advances of suprachiasmatic nucleus neuronal firing. Biol. Psychiatry, 60 (8), 896–899.
Circadian Rhythms and Sleep in Bipolar Disorder 78. Yuan, Q., Lin, F., Zheng, X. and Sehgal, A. (2005) Serotonin modulates circadian entrainment in Drosophila. Neuron, 47 (1), 115–127. 79. Adrien, J. (2002) Neurobiological bases for the relation between sleep and depression. Sleep Med. Rev., 6 (5), 341–351. 80. Brummett, B.H., Krystal, A.D., Ashley-Koch, A. et al. (2007) Sleep quality varies as a function of 5-HTTLPR genotype and stress. Psychosom. Med., 69 (7), 621–624. 81. Machado, R.B., Tufik, S. and Suchecki, D. (2008) Chronic stress during paradoxical sleep deprivation increases paradoxical sleep rebound: association with prolactin plasma levels and brain serotonin content. Psychoneuroendocrinology, 33 (9), 1211–1224. 82. Meerlo, P., Sgoifo, A. and Suchecki, D. (2008) Restricted and disrupted sleep: effects on autonomic function, neuroendocrine stress systems and stress responsivity. Sleep Med. Rev., 12 (3), 197–210. 83. Roman, V., Walstra, I., Luiten, P.G. and Meerlo, P. (2005) Too little sleep gradually desensitizes the serotonin 1A receptor system. Sleep, 28 (12), 1505–1510. 84. Berk, M., Dodd, S., Kauer-Santanna, M. et al. (2007) Dopamine dysregulation syndrome: implications for a dopamine hypothesis of bipolar disorder. Acta Psychiatr. Scand. Suppl 434, 41–49. 85. Oquendo, M.A., Hastings, R.S., Huang, Y.Y. et al. (2007) Brain serotonin transporter binding in depressed patients with bipolar disorder using positron emission tomography. Arch. Gen. Psychiatry, 64 (2), 201–208. 86. Nestler, E.J., Barrot, M., DiLeone, R.J. et al. (2002) Neurobiology of depression. Neuron, 34 (1), 13–25. 87. Benedetti, F., Radaelli, D., Bernasconi, A. et al. (2008) Clock genes beyond the clock: CLOCK genotype biases neural correlates of moral valence decision in depressed patients. Genes Brain Behav., 7 (1), 20–25. 88. Desan, P.H., Oren, D.A., Malison, R. et al. (2000) Genetic polymorphism at the CLOCK gene locus and major depression. Am. J. Med. Genet., 96, 48–421. 89. Mitterauer, B. (2000) Clock genes, feedback loops and their possible role in the etiology of bipolar disorders: an integrative model. Med. Hypotheses, 55 (2), 155–159. 90. Roybal, K., Theobold, D., Graham, A. et al. (2007) Mania-like behavior induced by disruption of CLOCK. Proc. Natl. Acad. Sci. USA, 104 (15), 6406–6411 91. Jones, S.H., Hare, D.J. and Evershed, K. (2005) Actigraphic assessment of circadian activity and sleep patterns in bipolar disorder. Bipolar Disord., 7 (2), 176–186. 92. Knowles, J.B., Cairns, J., MacLean, A.W. et al. (1986) The sleep of remitted bipolar depressives: comparison with sex and age-matched controls. Can. J. Psychiatry, 31 (4), 295–298. 93. Millar, A., Espie, C.A. and Scott, J. (2004) The sleep of remitted bipolar patients: a controlled naturalistic study using actigraphy. J. Affect. Disord., 80, 145–513. 94. Sitaram, N., Nurnberger, J.I. Jr, Gershon, E.S. and Gillin, J.C. (1982) Cholinergic regulation of mood and REM sleep: potential model and marker of vulnerability to affective disorder. Am. J. Psychiatry, 139 (5), 571–576.
|
271
95. Jones, S.H., Tai, S., Evershed, K. et al. (2006) Early detection of bipolar disorder: a pilot familial high-risk study of parents with bipolar disorder and their adolescent children. Bipolar Disord., 8 (4), 362–372. 96. Murray, G., Allen, N.B., Trinder, J. and Burgess, H. (2002) Is weakened circadian rhythmicity a characteristic of neuroticism? J. Affect. Disord., 72 (3), 281–289. 97. Hallam, K.T., Olver, J.S., Chambers, V. et al. (2006) The heritability of melatonin secretion and sensitivity to bright nocturnal light in twins. Psychoneuroendocrinology, 31 (7), 867–875. 98. Nurnberger, J.I. Jr, Adkins, S., Lahiri, D.K. et al. (2000) Melatonin suppression by light in euthymic bipolar and unipolar patients. Arch. Gen. Psychiatry, 57 (6), 572–579. 99. Wood, J., Birmaher, B., Axelson, D. et al. (2009) Replicable differences in preferred circadian phase between bipolar disorder patients and control individuals. Psychiatry Res., 166 (2–3), 201–209. 100. Mansour, H.A., Monk, T.H. and Nimgaonkar, V.L. (2005) Circadian genes and bipolar disorder. Ann. Med., 37 (3), 196–205. 101. Jones, S.H. (2001) Circadian rhythms, multilevel models of emotion and bipolar disorder: an initial step towards integration? Clin. Psychol. Rev., 21 (8), 1193–1209. 102. Pandi-Perumal, S.R., Moscovitch, A., Srinivasan, V. et al. (2009) Bidirectional communication between sleep and circadian rhythms and its implications for depression: Lessons from agomelatine. Prog. Neurobiol., 88 (4), 267–271. 103. Harvey, A.G. (2008) Sleep and circadian rhythms in bipolar disorder: seeking synchrony, harmony, and regulation. Am. J. Psychiatry, 165 (7), 820–829. 104. Hudson, J.I., Lipinski, J.F., Frankenburg, F.R. et al. (1988) Electroencephalographic sleep in mania. Arch. Gen. Psychiatry, 45, 267–273. 105. Hudson, J.I., Lipinski, J.F., Keck, P.E. et al. (1992) Polysomnographic characteristics of young manic patients. Arch. Gen. Psychiatry, 49, 378–383. 106. Riemann, D., Voderholer, U. and Berger, M. (2002) Sleep and sleep-wake manipulations in bipolar depression. Neuropsychobiology, 45 (Suppl. 1), 7–12. 107. Murray, G. (2006) Seasonality, Personality and the Circadian Regulation of Mood, Nova Science, NY. 108. Jackson, A., Cavanagh, J. and Scott, J. (2003) A systematic review of manic and depressive prodromes. J. Affect. Disord., 74 (3), 209–217. 109. Wehr, T.A., Sack, D.A. and Rosenthal, N.E. (1987) Sleep reduction as a final common pathway in the genesis of mania. Am. J. Psychiatry, 144, 201–204. correction 144, 542. 110. Bauer, M., Grof, P., Rasgon, N. et al. (2006) Temporal relation between sleep and mood in patients with bipolar disorder. Bipolar Disord., 8 (2), 160–167. 111. Colombo, C., Benedetti, F., Barbini, B. et al. (1999) Rate of switch from depression into mania after therapeutic sleep deprivation in bipolar depression. Psychiatry Res., 86 (3), 267–270. 112. Barbini, B., Bertelli, S., Colombo, C. and Smeraldi, E. (1996) Sleep loss, a possible factor in augmenting manic episode. Psychiatry Res., 65 (2), 121–125.
272
|
Chapter 20
113. Leibenluft, E., Albert, P.S., Rosenthal, N.E. and Wehr, A. (1996) Relationship between sleep and mood in patients with rapid-cycling bipolar disorder. Psychiatry Res., 63, 161–168. 114. Murray, G., Judd, F. and Bullock, B. (2007) Circadian and sleep/wake variables as predictors of relapse in bipolar disorder. [abstract]. Bipolar Disord., 9 (S 2), 10. 115. Perlman, C.A., Johnson, S.L. and Mellman, T.A. (2006) The prospective impact of sleep duration on depression and mania. Bipolar Disord., 8 (3), 271–274. 116. Barbini, B., Benedetti, F., Colombo, C. et al. (2005) Dark therapy for mania: a pilot study. Bipolar Disord., 7 (1), 98–101. 117. Benedetti, F., Barbini, B., Colombo, C. and Smeraldi, E. (2007) Chronotherapeutics in a psychiatric ward. Sleep Med. Rev., 11 (6), 509–522. 118. Wu, J.C., Kelsoe, J.R., Schachat, C. et al. (2009) Rapid and sustained antidepressant response with sleep deprivation and chronotherapy in bipolar disorder. Biol. Psychiatry, 66 (3), 198–301. 119. Terman, M. (2007) Evolving applications of light therapy. Sleep Med. Rev., 11 (6), 497–507. 120. Wirz-Justice, A., Quinto, C., Cajochen, C. et al. (1999) A rapid-cycling bipolar patient treated with long nights, bedrest, and light. Biol. Psychiatry, 45 (8), 1075–1077. 121. Abe, M., Herzog, E.D. and Block, G.D. (2000) Lithium lengthens the circadian period of individual suprachiasmatic nucleus neurons. Neuroreport, 11 (14), 3261–3264. 122. Manji, H.K., Moore, G.J. and Chen, G. (2001) Bipolar disorder: leads from the molecular and cellular mechanisms of action of mood stabilisers. Br. J. Psychiatry, 178 (Suppl. 41), S107–S119. 123. Padiath, Q.S., Paranjpe, D., Jain, S. and Sharma, V.K. (2004) Glycogen synthase kinase 3B as a likely target for the action of lithium on circadian clocks. Chronobiol. Int., 21 (1), 43–55. 124. Dokucu, M.E., Yu, L. and Taghert, P.H. (2005) Lithium- and valproate-induced alterations in circadian locomotor behavior in Drosophila. Neuropsychopharmacology, 30 (12), 2216–2224. 125. Duncan, J.W.C. (1996) Circadian rhythms and the pharmacology of affective illness. Pharmacol. Ther., 71 (3), 253–312. 126. Yin, L., Wang, J., Klein, P.S. and Lazar, M.A. (2006) Nuclear receptor Rev-erbalpha is a critical lithium-sensitive component of the circadian clock. Science, 311 (5763), 1002–1005. 127. Frank, E., Kupfer, D.J., Thase, M.E. et al. (2005) Two-year outcomes for interpersonal and social rhythm therapy in individuals with bipolar I disorder. Arch. Gen. Psychiatry, 62 (9), 996–1004. 128. Giglio, L.M., Andreazza, A.C., Andersen, M. et al. (2008) Sleep in bipolar patients. Sleep Breath., 13 (2), 169–173. 129. Michalak, E.E., Murray, G., Young, A.H. and Lam, R.W. (2007) Quality of life impairment in bipolar disorder, in Quality of Life Impairment in Schizophrenia, Mood and Anxiety Disorders: From Brain Functions to Clinical Practice (ed. M. Ritsner), Springer, NY. 130. Frank, E., Gonzalez, J.M. and Fagiolini, A. (2006) The importance of routine for preventing recurrence in bipolar disorder. Am. J. Psychiatry, 163 (6), 981–985.
131. Frank, E., Swartz, H.A. and Boland, E. (2007) Interpersonal and social rhythm therapy: an intervention addressing rhythm dysregulation in bipolar disorder. Dialogues Clin. Neurosci., 9 (3), 325–332. 132. Horn, M., Scharer, L., Walser, S. et al. (2002) Comparison of long-term monitoring methods for bipolar affective disorder. Neuropsychobiology, 45 (Suppl. 1), 27–32. 133. Grandin, L.D., Alloy, L.B. and Abramson, L.Y. (2006) The social zeitgeber theory, circadian rhythms, and mood disorders: Review and evaluation. Clin. Psychol. Rev., 26 (6), 679–694. 134. Miklowitz, D.J., Goodwin, G.M., Bauer, M.S. and Geddes, J. R. (2008) Common and specific elements of psychosocial treatments for bipolar disorder: a survey of clinicians participating in randomized trials. J. Psychiatr. Pract., 14 (2), 77–85. 135. Yatham, L.N., Kennedy, S.H., ODonovan, C. et al. (2006) Canadian Network for Mood and Anxiety Treatments (CANMAT) guidelines for the management of patients with bipolar disorder: update 2007. Bipolar Disord., 8 (6), 721–739. 136. Kripke, D.F., Mullaney, D.J., Atkinson, M. and Wolf, S. (1978) Circadian rhythm disorders in manic-depressives. Biol. Psychiatry, 13 (3), 335–351. 137. Wehr, T.A., Wirz-Justice, A. and Goodwin, F.K. (1979) Phase advance of the circadian sleep-wake cycle as an antidepressant. Science, 206 (9), 710–713. 138. Lewy, A.J., Sack, R.L., Singer, C.M. et al. (1989) Winter depression and the phase-shift hypothesis for bright lights therapeutic effects: History theory and experimental evidence, in Seasonal Affective Disorders and Phototherapy (eds N. E. Rosenthal and M.C. Blehar), Guilford Press, New York, pp. 295–310. 139. Czeisler, C.A., Kronauer, R.E., Mooney, J.J. et al. (1987) Biologic rhythm disorders, depression and phototherapy: A new hypothesis. Psychiat. Clin. N. Am., 10 (4), 687–709. 140. Teicher, M.H., Glod, C.A., Harper, D. et al. (1993) Locomotor activity in depressed children and adolescents, I: Circadian dysregulation. J. Am. Acad. Child Psy., 32, 760–769. 141. Boivin, D.B. (2000) Influence of sleep-wake and circadian rhythm disturbances in psychiatric disorders. J. Psychiatr. Neurosci., 25 (5), 446–459. 142. Wirz-Justice, A. (2006) Biological rhythm disturbances in mood disorders. Int Clin Psychopharmacol, 21 (Suppl. 1), S11–S15. 143. Ehlers, C.L., Kupfer, D.J., Frank, E. and Monk, T.H. (1993) Biological rhythms and depression: The role of zeitgebers and zeitstorers. Depression, 1, 285–293. 144. Healy, D. and Waterhouse, J.M. (1990) The circadian system and affective disorders: Clocks or rhythms? Chronobiol. Int., 7 (1), 5–10. 145. Kripke, D.F., Nievergelt, C.M., Joo, E. et al. (2009) Circadian polymorphisms associated with affective disorders. J. Circadian Rhythms, 7, 2. 146. Shi, J., Wittke-Thompson, J.K., Badner, J.A. et al. (2008) Clock genes may influence bipolar disorder susceptibility and dysfunctional circadian rhythm. Am. J. Med. Genet. B Neuropsychiatr. Genet., 147B (7), 1047–1055.
Circadian Rhythms and Sleep in Bipolar Disorder 147. Kishi, T., Kitajima, T., Ikeda, M. et al. (2009) Association study of clock gene (CLOCK) and schizophrenia and mood disorders in the Japanese population. Eur. Arch. Psychiatry Clin. Neurosci., 259 (5), 293–297. 148. Benedetti, F., Dallaspezia, S., Fulgosi, M.C. et al. (2007) Actimetric evidence that CLOCK 3111 T/C SNP influences sleep and activity patterns in patients affected by bipolar depression. Am. J. Med. Genet. B Neuropsychiatr. Genet., 144B (5), 631–635. 149. Benedetti, F., Serretti, A., Colombo, C. et al. (2003) Influence of CLOCK gene polymorphism on circadian mood fluctuation and illness recurrence in bipolar depression. Am. J. Med. Genet. B Neuropsychiatr. Genet., 123B (1), 23–26. 150. Beaulieu, J.M., Sotnikova, T.D., Yao, W.D. et al. (2004) Lithium antagonizes dopamine-dependent behaviors mediated by an AKT/glycogen synthase kinase 3 signaling cascade. Proc. Natl. Acad. Sci. USA, 101 (14), 5099–5104. 151. Gould, T.D. and Manji, H.K. (2005) Glycogen synthase kinase-3: a putative molecular target for lithium mimetic drugs. Neuropsychopharmacology, 30 (7), 1223–1237. 152. Coyle, J.T. (2007) What can a clock mutation in mice tell us about bipolar disorder? Proc. Natl. Acad. Sci. USA, 104 (15), 6097–6098. 153. Li, X., Bijur, G.N. and Jope, R.S. (2002) Glycogen synthase kinase-3beta, mood stabilizers, and neuroprotection. Bipolar Disord., 4 (2), 137–144. 154. Benedetti, F., Bernasconi, A., Lorenzi, C. et al. (2004) A single nucleotide polymorphism in glycogen synthase kinase 3beta promoter gene influences onset of illness in patients affected by bipolar disorder. Neurosci. Lett., 355 (1–2), 37–40. 155. Benedetti, F., Serretti, A., Colombo, C. et al. (2004) A glycogen synthase kinase 3-beta promoter gene single nucleotide polymorphism is associated with age at onset and response to total sleep deprivation in bipolar depression. Neurosci. Lett., 368 (2), 123–126. 156. Yang, S., Van Dongen, H.P., Wang, K. et al. (2009) Assessment of circadian function in fibroblasts of patients with bipolar disorder. Mol. Psychiatry, 14 (2), 143–155. 157. Kishi, T., Kitajima, T., Ikeda, M. et al. (2008) Association analysis of nuclear receptor Rev-erb alpha gene (NR1D1) with mood disorders in the Japanese population. Neurosci. Res., 62 (4), 211–215. 158. Severino, G., Manchia, M., Contu, P. et al. (2009) Association study in a Sardinian sample between bipolar disorder and the nuclear receptor REV-ERBalpha gene, a critical component of the circadian clock system. Bipolar Disord., 11 (2), 215–220. 159. Artioli, P., Lorenzi, C., Pirovano, A. et al. (2007) How do genes exert their role? Period 3 gene variants and possible influences on mood disorder phenotypes. Eur. Neuropsychopharmacol., 17 (9), 587–594. 160. Nievergelt, C.M., Kripke, D.F., Barrett, T.B. et al. (2006) Suggestive evidence for association of the circadian genes PERIOD3 and ARNTL with bipolar disorder. Am. J. Med. Genet. B Neuropsychiatr. Genet., 141B (3), 234–241. 161. Baum, A.E., Akula, N., Cabanero, M. et al. (2008) A genomewide association study implicates diacylglycerol kinase eta
162.
163.
164.
165.
166.
167. 168.
169.
170.
171.
172. 173.
174.
175.
176.
177.
178.
179.
|
273
(DGKH) and several other genes in the etiology of bipolar disorder. Mol. Psychiatry, 13 (2), 197–207. W.T.C.C. Consortium (2007) Genome-wide association study of 14,000 cases of seven common diseases and 3,000 shared controls. Nature, 447, 661–678. Sklar, P., Smoller, J.W., Fan, J. et al. (2008) Whole-genome association study of bipolar disorder. Mol. Psychiatry, 13 (6), 558–569. McClung, C.A., Sidiropoulou, K., Vitaterna, M. et al. (2005) Regulation of dopaminergic transmission and cocaine reward by the Clock gene. Proc. Natl. Acad. Sci. USA, 102 (26), 9377–9381. Roybal, K., Theobold, D., Graham, A. et al. (2007) Mania-like behavior induced by disruption of CLOCK. Proc. Natl. Acad. Sci. USA, 104 (15), 6406–6411. Falcon, E. and McClung, C.A. (2009) A role for the circadian genes in drug addiction. Neuropharmacology, 56 (Suppl. 1), 91–96. Brown, E.S. (2005) Bipolar disorder and substance abuse. Psychiatr. Clin. N. Am., 28 (2), 415–425. Abarca, C., Albrecht, U. and Spanagel, R. (2002) Cocaine sensitization and reward are under the influence of circadian genes and rhythm. Proc. Natl. Acad. Sci. USA, 99 (13), 9026–9030. Andretic, R., Chaney, S. and Hirsh, J. (1999) Requirement of circadian genes for cocaine sensitization in Drosophila. Science, 285 (5430), 1066–1068. Hampp, G., Ripperger, J.A., Houben, T. et al. (2008) Regulation of monoamine oxidase A by circadian-clock components implies clock influence on mood. Curr. Biol., 18 (9), 678–683. Lamont, E.W., Legault-Coutu, D., Cermakian, N. and Boivin, D.B. (2007) The role of circadian clock genes in mental disorders. Dialogues Clin. Neurosci., 9 (3), 333–342. McClung, C.A. (2007) Circadian genes, rhythms and the biology of mood disorders. Pharmacol. Ther., 114 (2), 222–232. Nestler, E.J. and Carlezon, W.A. Jr (2006) The mesolimbic dopamine reward circuit in depression. Biol. Psychiatry, 59 (12), 1151–1159. Imbesi, M., Yildiz, S., Dirim Arslan, A. et al. (2009) Dopamine receptor-mediated regulation of neuronal “clock” gene expression. Neuroscience, 158 (2), 537–544. Shieh, K.R. (2003) Distribution of the rhythm-related genes rPERIOD1, rPERIOD2, and rCLOCK, in the rat brain. Neuroscience, 118 (3), 831–843. Kendler, K.S. (2005) “A gene for . . .”: the nature of gene action in psychiatric disorders. Am. J. Psychiatry, 162 (7), 1243–1252. Gottesman, I.I. and Gould, T.D. (2003) The endophenotype concept in psychiatry: etymology and strategic intentions. Am. J. Psychiatry, 160 (4), 636–645. Bunney, W.E. and Bunney, B.G. (2000) Molecular clock genes in man and lower animals: Possible implications for circadian abnormalities in depression. Neuropsychopharmacology, 22 (4), 335-345. Hasler, G., Drevets, W.C., Gould, T.D. et al. (2006) Toward constructing an endophenotype strategy for bipolar disorders. Biol. Psychiatry 60 (2), 93–105.
274
|
Chapter 20
180. Lenox, R.H., Gould, T.D. and Manji, H.K. (2002) Endophenotypes in bipolar disorder. Am. J. Med. Genet., 114 (4), 391–406. 181. Papadimitriou, G.N., Calabrese, J.R., Dikeos, D.G. and Christodoulou, G.N. (2005) Rapid cycling bipolar disorder: biology and pathogenesis. Int. J. Neuropsychopharmacol., 8 (2), 281–292. 182. Wehr, T.A. and Goodwin, F.K. (1983) Circadian Rhythms in Psychiatry, Boxwood Press, Pacific Grove, Cal. 183. Czeisler, C.A. and Wright, K.P. Jr (1999) Influence of light on circadian rhythmicity in humans, in Regulation of Sleep and Circadian Rhythms (eds F.W. Turek and P.C. Zee), Dekker, New York, pp. 149–180. 184. Indic, P., Forger, D.B., St Hilaire, M.A. et al. (2005) Comparison of amplitude recovery dynamics of two limit cycle oscillator models of the human circadian pacemaker. Chronobiol. Int., 22 (4), 6–13–629. 185. Frank, E., Kupfer, D.J., Ehlers, C.L. et al. (1994) Interpersonal and social rhythm therapy for bipolar disorder: Integrating interpersonal and behavioural approaches. Behav. Therapist, 17, 143–149.
186. Miklowitz, D.J., Otto, M.W., Frank, E. et al. (2007) Psychosocial treatments for bipolar depression: a 1-year randomized trial from the Systematic Treatment Enhancement Program. Arch. Gen. Psychiatry, 64 (4), 419–426. 187. Wirz-Justice, A., Benedetti, F., Berger, M.A. et al. (2005) Chronotherapeutics (light and wake therapy) in affective disorders. Psychol. Med., 35, 939–944. 188. Wirz-Justice, A., Benedetti, F. and Terman, M. (2009) Chronotherapeutics for Affective Disorders: A Clinicians Manual for Light & Wake Therapy, 1st edn, Karger, Basel. 189. Harvey, A.G. (2008) Sleep and circadian rhythms in bipolar disorder: Seeking synchrony, harmony, and regulation. Am. J. Psychiatry, 165, 820–829. 190. Russell, S.J. and Browne, J.L. (2005) Staying well with bipolar disorder. Aust. NZ J. Psychiatry, 39 (3), 187–193. 191. Anderson, J.L., Glod, C.A., Dai, J. et al. (2009) Lux vs. wavelength in light treatment of Seasonal Affective Disorder. Acta Psychiatr. Scand., 120 (3), 203–212. 192. Vandewalle, G., Balteau, E., Phillips, C. et al. (2006) Daytime light exposure dynamically enhances brain responses. Curr. Biol., 16 (16), 1616–1621.
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Treatment Adherence in Bipolar Disorder Jan Scott1 and Mary Jane Tacchi2 1 2
Department of Psychiatry, Newcastle University; Institute of Psychiatry, Institute of Neuroscience, Newcastle-upon-Tyne, UK Institute of Psychiatry, Institute of Neuroscience, Newcastle University, Newcastle-upon-Tyne, UK
Introduction The safe and successful delivery of efficacious treatments for bipolar disorders relies upon the patients (and often their caregivers) ability and willingness to accept and engage with the services provided, and to adhere with an agreed regime of medication and/or other interventions that make up the individuals treatment plan. Understanding the complexity and maximizing the effectiveness of the interaction between the clinician and patient lies at the heart of achieving meaningful engagement with any treatment proposals. Collaboration between the clinician and patient is a critical first step if patient outcomes are to reflect the goals of both parties. The potential gain from a positive collaboration and a healthy clinician-patient working alliance is that patients report greater satisfaction with the services, largely as a consequence of increased trust in their clinicians and being offered the opportunity for more active participation in treatment decision making. The latter ensures that patients are more likely to view treatment options as acceptable, which in turn may increase adherence with currently prescribed or recommended treatments; it increases the likelihood of active help-seeking (especially in the prodromal phase of new episodes); and improves the probability of longer-term engagement with services, which is vital given the natural history of the disorder. The converse of all these benefits is largely true of unsatisfactory collaborations; many individuals who are treatment nonadherent, report at least one past experience of a negative therapeutic alliance. The chapter begins with a brief overview of research on medication non-adherence in bipolar disorders and then focuses on findings regarding individuals at risk of nonadherence that may be more informative when trying to address the problem in clinical settings. It then briefly highlights the general principles of engagement, as strategies
Bipolar Disorder: Clinical and Neurobiological Foundations Edited by Lakshmi N. Yatham and Mario Maj © 2010 John Wiley & Sons, Ltd. ISBN: 978-0-470-72198-8
that enhance adherence are unlikely to be effective unless practised within the context of an appropriate therapeutic relationship. This is followed by an overview of a health beliefs model that may help clinicians in their attempts to enhance treatment adherence and some simple strategies that can be employed in day-to-day clinical practice to reduce the risk of non-adherence.
Adherence It is widely acknowledged that the impressive benefits of medication observed under controlled research conditions are rarely replicated in clinical practice. In the past this efficacy-effectiveness gap was frequently attributed to drug pharmacokinetics and pharmacodynamics. It was some time before non-adherence with prescribed treatment regimens was recognized as the factor accounting for most of the variance in outcomes. Early attempts to understand non-adherences focused on socio-demographic and illness characteristics that might somehow explain adherence behaviour, and the general assumption was that individuals with severe mental disorders were at higher risk of nonadherence than those with physical disorders, and that they often failed to adhere because of lack of insight or lack of tolerance of treatment side-effects. Sadly, the view that a new medication, with fewer or different side effects, would resolve the problem is at odds with the evidence – namely, it is clear that the proportion of patients demonstrating significant levels of non-adherence (missing 30% of their medication per month) has not changed since the 1950s to the present day, a period during which there has been an exponential increase in the number of available medications with very different side-effect profiles from their predecessors. Furthermore, the prevalence of non-adherence in patients with bipolar disorders parallels the rates in physical disorders such as diabetes, epilepsy and hypertension. The chronic disease management approaches that have been successful in improving the treatment of these lifespan medical disorders drew heavily on the literature on health belief models, which in turn emphasize the role of patient 275
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attitudes and beliefs about a disorder and its treatment and how these may influence adherence behaviours. These models have now begun to permeate into mental health and research on non-adherence increasingly focuses on how patient and caregiver beliefs about the disorder and its treatment, and the interactions between key individuals, can dramatically influence the degree of adherence. Some key issues in the development of our understanding of adherence behaviour will be briefly reviewed below. Early reviews of socio-demographic and general clinical factors associated with non-adherence in bipolar disorders ([1]) cited factors such as younger age, male gender, history of grandiosity, and complaints of missing highs. However, the hypothesis that basic socio-demographic variables directly predict adherence is undermined by contradictory findings and is not strongly supported by recent more sophisticated research [2]. For example, out of 12 studies, 5 identified a possible association between younger age and non-adherence; one found a trend in the same direction but reported no association and six did not find any association [3]. Also, any relationship between age, gender and non-adherence might be better explained by a third variable, such as the high prevalence of comorbid drug and/or alcohol misuse in young males with bipolar disorder. Similarly, a detailed review of the association between insight and adherence tends to suggest that while this may be relevant in some cases at certain times, for example when presenting with episode acute mania or psychotic depression, the more subtle concept of illness awareness (which captures aspects of denial of illness in clear conscience) is a better explanatory variable. Also, there is a growing literature suggesting that cognitive impairments (rather than insight alone) may adversely affect adherence [4]. Side effects were considered to have a detrimental effect on adherence in early studies, but again the research is undermined by the fact that many of the studies reporting this association failed to measure any other possible influences on adherence. Recent studies indicates that while sideeffects may reduce adherence in some individuals (while others will tolerate exactly the same side effect at an equal or worse level of severity), there is a difference between subjective and objective measures of side effects. If side effects are differentiated in this way, it is notable that fear of rather than the actual experience of side effects may be a better predictor of non-adherence [5]. Early research identifying at risk populations is of only minimal utility in day-to-day clinical settings where a clinician wishes to assess individual factors that determine likely behaviour patterns. The exploration of individual beliefs is proving increasing fruitful. For example, Pope and Scott (2003 [6]) confirmed Jamisons findings on subjective reasons for non-adherence, with both studies highlighting that two of the most frequently reported beliefs associated with non-adherence were that patients disliked
the idea that their moods were controlled by medication and disliked taking medication as it reminded them that they had a chronic illness. It was also found that many patients reported that when they felt well they thought there was no need to take medication. This factor is often overlooked, but is also critically important in clinical practice – as it identifies that adherence is not a static behaviour; patients adherence levels may fluctuate – so they cannot be classified permanently as adherent or non-adherent. Other individuals and interactions may also influence adherence behaviour. For example, a factor analysis of dimensions of adherence behaviour demonstrated that acceptance of medication (affinity) was the most important predictor of adherence, while negative interactions with clinicians (negative alliance) was endorsed four times more frequently by non-adherent as compared with adherent patients [2]. It was also noted that individuals with bipolar disorders who were non-adherent were more likely to be living with family members who were significantly less knowledgeable about bipolar disorder and its treatment and were more critical of the patient than the families of adherent subjects [5]. These findings confirm earlier research by Miklowitz, Perlicke and others that individuals with bipolar disorder living in high expressed emotion environments, particularly if this was also accompanied by a negative affective style of interaction or high caregiver burden, were at high risk of non-adherence and relapse. Figure 1 identifies those factors for which there is consistent evidence of an association with non-adherence or where the balance of research findings favour an association.
Therapeutic relationships The therapeutic relationship refers to a series of interactions between the clinician and patient. It is the vehicle through which engagement proceeds and time spent enhancing this interaction will increase the likelihood of satisfaction for all parties. All clinicians will be aware that some of their own therapeutic relationships develop more easily than others: knowledge about the process can help to improve interactions and overcome obstacles in clinician-patient encounters that the clinician finds more challenging personally. Individuals with bipolar disorders may present in markedly different ways at appointments and sometimes, for example, when a patient has symptoms of irritability and mania, the individual may show an amazing ability to hit a nerve and/or challenge the clinician, despite the latters most skilled attempts to avoid any confrontation. Taking the time to reflect on ones own actions and reactions in such circumstances, and reflecting on any recurring patterns in interactions deemed difficult is invaluable in clarifying ways to modify ones own behaviours to try to maintain a functional working alliance, especially when circumstances
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Basic Demographics, Illness or Treatment Factors Comorbid Substance Misuse Past History of Non-Adherence with Medical or Psychiatric Treatments Cognitive Impairments Lack of Insight Subjective Experience of Side Effects Fear of Side Effects
Individual, Family or Patient-Professional Relationship Factors Negative Expectations of or Attitudes toward Treatment eg ‘Taking medication everyday reminds me I have a chronic illness’; ‘I feel I am controlled by drugs’ Lack of Illness Awareness or Denial of Severity Poor Therapeutic Alliance Significant Others: Beliefs or Lack of Knowledge about Bipolar Disorder High Levels of Critical Comments EE Family) Fig. 1 Factors associated with increased risk of nonadherence in bipolar disorders.
dictate that the patient may not be able to modify their own modus operandi at that moment. It goes without saying that many clinicians intuitively develop healthy alliances with patients, but others may need to more consciously practise the effective and skilful handling of a consultation with manic patients, or even with an individual who is struggling to come to terms with the diagnosis and the likely need for treatment. Furthermore, it often falls to the senior clinicians to try to impart knowledge to less experienced colleagues about how to maintain collaboration with individuals with bipolar disorder, given some of the potentially challenging presentations that occur. The following sections briefly offer an aide memoir of some of the key research findings on these topics. DiMatteo [7] described the factors that are important in promoting a positive doctor-patient interaction. Most clinicians are aware of the essentials, such as the presence of warmth, positive regard, a lack of tension and non-verbal expressiveness. However, it is worth highlighting that, for example, the clinicians communication style often dictates the success of the therapeutic relationship. McCabe and Priebe [8] concluded that the extent to which patients feel listened to and the extent to which their specific concerns are addressed significantly affect the patients and caregivers views of the consultation. Di Matteo also noted that physicians who could accurately read body language developed more effective interpersonal relationships, emphasizing that communication occurs on many different levels.
Various models have been proposed to characterize the doctor-patient relationship and many promote the idea that this relationship should be an equal partnership rather than the clinician being in a position of authority and dictating the outcome of the process. In reality it is not always possible or ethical to endorse all choices expressed by patients, and/ or the responsibilities of clinical management mean it is sometimes necessary to take decisions on behalf of a patient without their agreement (such as involuntary admission). However, the general principle of seeking collaboration between both parties increases the prospect of effective two-way communication so that each person is aware of the others point of view and by increasing the possibility of early intervention in crises may actually reduce the likelihood of involuntary admission (see Figure 1). Ideally, the key elements for effective collaboration in the care and treatment of an individual with bipolar disorder will include the development of a shared understanding of the problem(s) to be addressed followed by open discussion and negotiation regarding the nature of any interventions to be tried and the interventions will target the jointly agreed goals of treatment.
Developing a shared understanding and agreeing treatment goals Most patients will attend a clinician at a time when they believe this person can help alleviate their distress and/or
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help them function at their desired level. Very few individuals with bipolar disorder will achieve enduring improvements in their quality of life without taking medication. However, many individuals desperately want to achieve their desired level of functioning through their own efforts, without taking long-term medication. Clinicians cannot ignore this dilemma and so they need to develop ways of working with patients who hold such views that maximize the chances of treatment adherence. The first principle to consider is that adherence with any treatment is more likely to occur if the clinician and patient agree on the problems they are tackling, the goals of treatment and the interventions that will be used to produce the required changes. In this approach, the use of medication is identified as one of several components of a multi-dimensional treatment package, and benefits of medication (especially what it can and cannot do) can be clarified and its specific role agreed.
Beliefs about illness Patients attending consultations have already begun to develop their own model of their difficulties and how these can be overcome. As such the clinician needs to explore this in order to decide if the patient is likely to accept medication. The use of a health belief model called the cognitive representation of illness [2,9] is a useful framework that allows clinicians to begin to explore a patients understanding of their problems, their attitudes and expectations about treatment, and to gauge their coping style. Spending time exploring the five key themes of this model: identity, cause, time line, consequences, can it be cured or controlled (see Figure 2). It is notable that while individuals vary enormously in their beliefs about their problems and how to overcome them, the ideas expressed by anyone can virtually always be organized within these five key themes, no matter
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what their background, culture or ethnicity. The core element in the process of beginning the treatment process is that in the first instance the clinician understands the patients model of what is happening to them, not vice versa. The rationale is that the patients misunderstandings, negative views or beliefs are more likely to produce barriers to implementing effective treatment and thus the primary goal is not simply to ascertain if the patient meets all the diagnostic criteria for a disorder, but fundamentally must identify the immediate road blocks to successful collaboration and clinical management. With established patients and/or those who are not acutely unwell, it is useful to examine the patients understanding of their perception of the threat posed to them by any illness recurrence, most importantly whether they regard themselves as susceptible to future episodes and if so, whether they view any consequences of relapse as potentially serious (e.g. would a severe episode requiring hospitalization have a detrimental effect on their life). The essential element in this discussion is that the focus in on the risk to that individual as the evidence is that patients do not relate to general information (about risk of relapse) to their own situation without clear and specific personalization. This will give some indication of the prospects for adherence with continuation and maintenance treatments.
Goals of treatment Research on patients views of their reasons for seeking treatment for bipolar disorder is illuminating. Very few patients, even when acutely unwell, would state that their primary goal is to get medication. A depressed patient may desires ranging from to be able to sleep, or to return to work as quickly as possible. A clinician may recognize that prescribing medication may immediately begin to help with
Engagement is a multi-dimensional phenomenon comprising at least six key components: appointment keeping, client-therapist interaction, communication, openness, collaboration with treatment and medication adherence.
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Clinical management approaches are more likely to succeed if they include: engagement, negotiation of the structure of the intervention, agreed approaches to communication, agreement on the role and involvement of carers, discussion of shared and individual responsibilities, safety and containment issues.
Fig. 2 Key points in engagement and clinical management.
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Identity of problem. What does the individual think it is? Do they view it as a mental disorder?
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Cause. What ideas do they entertain about what has caused their problem(s)?
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Timeline. How long do they think it will last? Do they think it is transient, may persist or may be recurrent?
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Consequences. How do they think it will affect them? Do they think there may be any serious consequences of not having treatment?
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Cure. Does the individual think the problem can be cured or controlled? How has the individual attempted to cope with the symptoms and how do they appraise the effectiveness of their coping strategies?
the former, may then help improve the patients mental state and be a vehicle to achieving the return to work. However, it is important to recognize the subtle difference between the patient and clinician agreeing on the goals of their collaboration and agreeing the means of achieving the goals. This cannot be ignored as it is especially likely to need to be addressed when identifying how medication plays a part in long-term goals. For example, if the patient expresses a wish to get back to work, the clinician can introduce the idea that they need to identify the key steps involved in moving towards that goal; by asking questions, the clinician and patient can identify what the patient would need to be able to do in order to do their job. This guided process usually helps the patient catalogue several key milestones, such as being able to sleep and wake refreshed; to be able to concentrate for extended periods of time, being able to organize basic living routines and manage on a day-to-day basis, and so on. The clinician and patient can then discuss how to achieve each of these steps and the use of medication to improve sleep, concentration and reduce certain symptoms (or stabilize mental state) is now seen as a logical part of the process; planning daily activities and keeping a diary of what the patient did compared with what they planned can also be agreed as an essential part of working towards the goal. This shared decision making is a constructive way of educating patients about the process of change and where medication can be beneficial, while retaining their sense of autonomy and/or control over treatment decisions that affect their well-being. It also emphasizes that treatment is not medication alone [2].
Three questions to aid effective prescribing A simple process that can be used by a clinician is that before writing a prescription they ask themselves does this
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Fig. 3 Key themes to explore to establish patients illness model (adapted from Scott and Tacchi, 2002).
individual patient find the proposed medication regime – Acceptable? Understandable? Manageable? If the answer to any of these questions is no – concordance has not been achieved and adherence is unlikely. Indeed, do not waste time writing a prescription; it may not even be presented at a pharmacy! Continue the dialogue until an option is found that meets these criteria.
Is the treatment acceptable? Obviously agreement on the nature of the problem is a critical first step, as it will allow the patient make informed choices about the treatments available. If there are gaps in the patients understanding or areas of uncertainty that mean the clinician and patient do not yet have a shared view, there may still need to be further work before prescribing medication is likely to be followed by adherence. It is important to consider not only what information is needed by the patient, but how additional information might be provided and what approach is most likely to be acceptable to the individual (e.g. the clinician offering information leaflets to the patient vs. encouraging self discovery by the patient contacting advocacy groups or directly accessing information from appropriate Internet Web sites). The views of the patients significant others (e.g. relatives, partner) are also important, as these may influence the patients beliefs about their problems and/or attitudes towards proposed treatments. Taking all these aspects into account, the clinician can gauge whether or not the patient requires further help or information to aid their understanding of the particular problems. If the clinician understands the patients perspective, and has found common ground, it is relatively straightforward to determine what treatment options make sense to that patient at that moment and which may be more acceptable than others. Understanding and recording which proposed
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interventions are likely to be rejected by the individual is also necessary. Relatively few clinicians assess this in detail, yet a few moments spent establishing whether a patient has heard of, for example drug X, and then whether they have any reaction (positive or negative) to the suggestion of trying it, could prevent treatments being prescribed that are never likely to be accepted by the individual [2]. There are also practicalities with regard to acceptability of intervention, (which partly overlap with whether the treatment is manageable), for example the form the medication takes, that is injectable or oral, tablets or syrup, and frequency of dosing. Lingham and Scott [3] noted that if a patient chooses the form of medication and dosing regimen they are much more likely to adhere to this than if this is selected for them. Much has been written about how side effects of prescribed medication may affect adherence. However, when asked directly, patients rank this as only the seventh most important reason why they fail to adhere [10]. The presence of side effects per se does not predict non-adherence as accurately as either the patients fear of experiencing side effects or a lack of knowledge about how to manage common side effects should they occur [5,11]. An open discussion about these concerns from the outset may help to allay anxieties and also provide practical solutions should common side effects occur; for example, chewing sugar free gum to overcome a dry mouth, and so on. Being proactive in offering advice on common problems is likely to reduce the risk of non-adherence if the side effect does occur, and offers the opportunity to differentiate between side effects that are a nuisance and/or unpleasant but not dangerous versus adverse effects that will need the patient to seek urgent attention, without causing alarm.
Is the treatment understandable? Once the patients own model or representation of the disorder is understood, it becomes clear where there are gaps in their knowledge that may hinder their understanding of the treatment rationale. If the patient and clinician have very divergent ideas on aetiology, time is needed to identify or establish some shared ground and agreed targets for any treatment interventions, for example if the patient reports disturbed sleep, the need to alleviate this may lead to agreement being reached about medication being prescribed for this symptom, even if the patient is less convinced by the clinicians view of the diagnosis of the syndrome and the need for longer-term medication. If medication is successful in ameliorating a problem the patient considers important, it hopefully offers the clinician an opportunity to then revisit the possible role of medication in the overall treatment plan. This approach is preferable to trying to rush the patient into complying with the clinicians preferred approach and/or trying to use evidence of undesirable clinical and personal consequences to push or even frighten the patient into
a treatment agreement they are not really engaged with (and will more than likely not adhere to once they have left the clinic). Many clinicians try to help patients by giving a mini educational lecture on the disorder and its treatment and emphasizing the dire consequences of not adhering with treatment, hoping that the information and the fact that their presentation clearly fits with established knowledge will somehow mean the patient will now accept the diagnosis proffered and treatment suggested. This may sometimes be true, but evidence on psycho-education clearly shows that didactic approaches and information alone do not change the patients attitudes or beliefs, and therefore neither improve adherence or outcomes. The worst case scenario is that this actually increases the chances of nonattendance as the patient fears disapproval from the expert whose advice they have failed to follow. As such, it is important to avoid lecturing the patient as, rather than helping the patient gain an understanding of the need for treatment, patients frequently report feeling talked at and the effect can be the opposite of what is desired as it may undermine engagement with services or adherence. Guiding the patient to discover information for themselves and then discussing what they have found out will often help reinforce that the relationship is collaborative and that the clinician wants to hear and understand the patients perspective. This approach hopefully will increase the future prospects of gaining acceptance of an appropriate medication regime from what Gary Sachs describes as a menu of reasonable options. Clinicians can sometimes take for granted that patients understand why they are taking medication if they are symptom-free. It is vital to check that the patient understands the difference between medications taken as an acute treatment, for example aspirin for a headache, and that which is taken long term to avoid a problem occurring, for example anti-hypertensives to prevent increases in blood pressure and thus avoid any negative health consequences of this. This is especially important as bipolar disorders often requires combinations of medications – some which get you well (acute treatments with antidepressants or anti-manic agents) and those that keep you well (moodstabilizers). Adherence with the latter is especially likely to be problematic to an individual who is symptom free; unless they are clear these medications are primarily targeted at preventing symptoms developing and have made their own decisions regarding their personal likelihood (susceptibility) of experiencing a further relapse and whether the consequences are tolerable (severity of symptoms, disruption to lifestyle, problems associated with possible admissions).
Is the treatment manageable? There are a number of practical considerations when prescribing medication, which again may be overlooked in
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a busy clinical practice. Checking simple things, however, often makes a significant difference – again the emphasis is initially on asking not telling and ensuring knowledge about the practicalities have not been assumed for example Does the patient know the name of the medication that is being prescribed, the doses, how often this needs to be taken and what to do if they forget to take a dose? Does the patient know who will provide further prescriptions and what will happen if a change of dose is recommended (e.g. how will they get a new perscription, how long will it take to make the changeover)? These are not issues that are always covered, but research with patients identifies that lack of information and/or misunderstandings of certain statements in the literature provided with prescription medications can cause confusion and reduce adherence, for example when questioned, patients who read a statement should not be taken with alcohol frequently reported that they excluded medication doses on days they attended a social event, as they did not know whether the consequences would be minor (feeling drowsy) or dangerous (life threatening interactions). It takes only a few moments to ensure such issues have been clarified for a patient, and it may make the difference between a medication regime being regarded as effective and ineffective. Finally, the clinician needs to check if there is any other additional help that would increase the likelihood that adherence will be maintained by this particular patient, for example, as noted in the section on acceptability, providing practical advice on how to manage any common side effects can prevent non-adherence. Patients prescribed medication can also be encouraged to use simple behavioural techniques to increase their likelihood of adherence such as keeping a written record, using prompts such as mobile phone alarm bleeps, or pairing taking medication with another regular activity such as brushing their teeth. The use of once daily dosing is often hailed as an important technique for improving adherence, but again the actual evidence suggests choice of regime is the significant component, that is if the patient prefers to take the medication once a day and/or they know this will improve their chances of successful adherence, the prescription of a medication that has a slow release or long acting preparation is useful, but clinicians must establish, not assume, that the patient has a preference for taking the medication once a day rather than more frequently. A practical approach to some of the above issues is to provide a wallet sized treatment card for the patient to carry with them, outlining the information on medication and including a contact number if the patient experiences any difficulties. A shared written treatment plan also offers an opportunity to improve awareness of adherence issues rather than simply documenting the interventions, personnel involved, and so on. This can be helpful as it allows the clinician and patient to openly discuss and identify in
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advance any potential adherence problems and the possible solutions that the patient can instigate for themselves. For example, adding a specific section to the plan about the benefits to the individual of the particular treatment regime and sections highlighting potential problems, with ways to overcome difficulties with adherence (usually a list of bullet points on possible barriers to adherence followed by a further list on how these might be overcome). The patient may chose to involve carers in the process. However, even if those individuals are not engaged in any specific support strategies, it is useful and often important (with the patients permission) to ensure that, for example family members or social care coordinators share an understanding of the nature of the disorder, and the key issues relating to treatment to ensure concordance exists across all the key individuals involved in the patients life.
Monitoring and enhancing adherence Adherence is a dynamic process, it is not a static all or nothing phenomena and indeed those individuals who take all or none of their prescribed medications are very rare. There is both inter-individual and intra-individual variation and even someone who has benefited from medication may show differences in their adherence pattern over time. The level of non-adherence that may adversely affect clinical outcome is not easy to determine, but a crude rule of thumb is that if someone omits >¼30% prescribed medication over a month, the risk of relapse increases by about 10% every month. As such, it is necessary to regularly monitor where an individual is in their own cycle of adherence. It is important to create an atmosphere where the patient feels able to discuss the issue and any questions need to be constructed to ensure they are non-judgemental. Simple examples are: many individuals find it hard to stick with a course of tablets: Do you ever have any trouble taking all of your medication as prescribed? Are there times when it is more difficult to remember to take your medications? Does your medication regime fit in with your lifestyle? Do you ever try and cope on your own without your medication? The last question is particularly useful for establishing non-adherence in those who have negative attitudes or beliefs about medication (the other questions hint more at forgetting). Questions that allude to coping without medication or resolving problems independently are especially important, as this reflects the underlying rationale of many individuals with bipolar disorders, that is they are not wilfully disregarding advice from a clinician who they may well trust, but rather are desperately trying to avoid a sense of being controlled by or dependant on medication.
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It is good clinical practice to establish patterns of adherence and have some agreed means of recording this from the outset (e.g. a simple diary note through to a more detailed mood diary record), as this will prevent an accusatory feel if this were introduced some time after commencing with a newly prescribed medication. The possible drivers of medication non-adherence need to be explored in order to determine the most useful techniques to overcome this problem. Scott (1999 [12]) distinguishes between non-intentional and intentional adherence, which require different approaches. Unintentional non-adherence usually occurs when patients forget medications or find it difficult to establish regular patterns of adherence. A review of records of taking medication may however expose a different type of problem, namely that certain situations increase the individuals risk for non-adherence or that the primary problem relates to negative attitudes towards medication rather than difficulty in establishing a pattern of behaviour. Intentional non-adherence is usually an indication of cognitive barriers to engaging with medication such as beliefs that trying harder would allow the individual to deal with the symptoms without recourse to medication. Unintentional non-adherence is more likely to respond to a behavioural approach, but in practice both forms of nonadherence are usually tackled with these interventions initially. As noted in the previous section, negotiating the medication schedule and including patient preferences should be incorporated whenever possible. Use of a medi-pack or dosette that allows the daily medication regime to be organized in advance and self-monitoring of adherence is also helpful. Intentional non-adherence is not always easy to address in general day-to-day practice. However, some simple approaches to exploring attitudes and beliefs can be used. First, it is important to discover if there is a specific pattern to non-adherence, for example, are there specific days, times or situations where there is a high risk of omitting prescribed medication. Again the emphasis is then on guiding the patient to examine his or her own cognitions and behaviours, for example, a business man who omitted lithium prior to important contract meetings because he thought it would make him dopey. Simple experiments can then be devised to test out these ideas, for example, carefully monitoring how he felt if he did take lithium before one contract meeting and then comparing this with a meeting when he did not take it. The information can then be used to discuss what solutions might be reasonable – was there actual evidence that the lithium was adversely affecting his performance? Could there be any other explanation, for example, was he tired because he had not slept well the night before? Did anyone else notice he was dopey or is this only a subjective phenomenon, might it relate to anxiety
about undertaking public presentations? After exploring these aspects, the clinician might be able to allay concerns that taking lithium had more benefits than costs, but by approaching the problem in this way, the patient may then be able to discuss whether he had any other issues with lithium, whether his adherence was affected in other circumstances not so far discussed and whether his real preference was actually to have a discussion about a change to a different mood stabilizer. While many clinicians would be unhappy or concerned about implementing such a change, there would be little point in avoiding or dismissing such a discussion. Failure to act in the face of these warning signs might mean the patient simply votes with their feet and does not come back to see the clinician or stops the lithium in an unsupervised and hurried manner – all of which increase the risk of relapse. In some instances, clinicians may have to reluctantly accept the patient is not going to take medication for a period of time. However, the first thing to establish is whether this is a no medication or a no treatment option. If the client chooses to stop medication (and assuming compulsory treatment is not being considered nor justified at that moment) then it is vital that both parties plan the medication withdrawal programme and appointment frequency increases to ensure the patient receives additional support and help regarding non-medication coping strategies. Rather than withdrawing, the clinician needs to enter a dialogue about the need for gradual withdrawal to try to reduce immediate risks of relapse, and the need for the client to feel able to inform the clinician if they stop the medication more quickly than they plan, and so on. Also, clinicians should remember that often – when trying to get patients to try a new treatment – they negotiate an experiment – often asking the patient to try the medication for six weeks with the clinician and patient evaluating the costs and benefits of this regimen. It is therefore sensible to try to use the same approach regarding stopping medication, that is, will the patient agree the length of time this medication-free experiment will last and the frequency of future clinical reviews. Most importantly, the clinician and patient need to agree clear criteria in advance about how they will identify the end point of an unsuccessful experiment – under what circumstances would the patient accept medication again. A record should then be kept of symptoms and agreed outcomes to make an accurate assessment of progress and the patient should ideally also identify someone outside the clinical setting whom they trust who will also help monitor their progress and can advocate on their behalf, particularly if they experience symptoms of a recurrence. At such a time, the clinician will hopefully have a further opportunity to negotiate a trial of medication [13]. By viewing bipolar disorder and its treatment from a longterm perspective, the clinician can hopefully maintain
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High Concerns
Sceptical
Ambivalent
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High Necessity Indifferent
Accepting
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a therapeutic alliance with the patient and work through these difficult periods.
Future directions – using a necessities-concerns framework Non-adherence with medication in bipolar disorder is prevalently costly and associated with poor clinical outcome. In common with other chronic conditions, however, approaches employed in routine practice have met with limited success. This is partly because the interventions have too often focused on assumed reasons for non-adherence, such as lack of insight, troublesome side-effects and unsatisfactory dosing regimens, rather than addressing the key patient beliefs that act as barriers to adherence [14] (See Figure 3). One model, which is now showing promise, is the Necessity-Concerns Framework [15]. This simply suggests that patients motivation to begin and continue treatment is influenced by their personal beliefs about treatment and how they judge their personal need for treatment relative to their personal concerns about potential adverse effects. Clatworthy et al. [16] have recently published a study that estimated how more than 250 individuals with bipolar disorders balance perceived needs against concerns and how these beliefs influenced adherence. The study found that scores on ratings scales of beliefs about treatment were the only significant predictors of reported adherence to medication; low adherence was associated with higher concerns about treatment and lower perceived personal need for treatment, such that for every one unit increase in the persons score on the concerns rating scale employed, the odds of low adherence more than doubled. In contrast, for every one unit increase in perceived need, the odds of reporting low adherence halved. The relationship between necessity beliefs, concerns and adherence offer a target for interventions to help patients resolve treatment dilemmas and develop optimal adherence to appropriately prescribed medication by addressing
Fig. 4 The necessity-concerns framework.
treatment perceptions (necessity beliefs and concerns). For example, individuals can be classified according their expressions of Necessity and Concerns. As shown in Figure 4, this identifies four sub-groups of individuals according to their views of medication-Accepting (high necessity, low concerns), Ambivalent (high necessity, high concerns), Sceptical (low necessity, high concerns), or Indifferent (low necessity, low concern). Using this type of approach, the clinicians initial goal would be to ensure that the patients adherence behaviour was informed by a realistic evaluation of the likely benefit and risks of treatment, rather than by potentially misplaced beliefs and concerns. However, knowing where an individual is located within this framework then gives the clinician an opportunity to target their interventions and shape their comments to take into account the underlying but subtly different issues that influence adherence behaviour in those who are ambivalent (tackle concerns) or sceptical (tackle concerns and enhance necessity). It is hoped that this might prove a useful conceptual map that enables clinicians to elicit and respond to patients personal beliefs about bipolar disorders and devise simple strategies to optimize engagement and adherence with prescribed medication.
References 1. Goodwin, F. and Jamison, K. (1990) Manic Depressive Illness, 1st edn, OUP, Oxford. 2. Tacchi, M.J. and Scott, J. (2005) Improving Adherence in Schizophrenia and Bipolar Disorders, John Wiley & Sons Ltd, England. 3. Lingham, R. and Scott, J. (2002) Treatment non-adherence in affective disorders. Acta Psychiatr. Scand, 105, 164–172. 4. Martinez-Aran, A., Scott, J. et al. (2009) Treatment nonadherence and neurocognitive impairment in bipolar disorder. J. Clin. Psych. 70 (7), 1017–1023. 5. Scott, J. and Pope, M. (2002) Nonadherence with mood stabilizers: prevalence and predictors. J. Clin. Psychiatry, 63 (5), 384–390.
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6. Pope, M. and Scott, J. (2003) Do clinicians understand why patients stop taking mood-stabilizers? J. Affect. Disorders, 74, 298–291. 7. DiMatteo, M. (1979) A social-psychological analysis of physician patient rapport: Toward a science of the art of medicine. J. Soc. Issues, 35, 12–33. 8. McCabe, R. and Priebe, S. (2004) The therapeutic relationship in the treatment of severe mental illness. Int. J. Soc. Psychiatr., 50 (2), 115–128. 9. Levanthal, H., Diefenbach, M. and Levanthal, E. (1992) Illness cognition: using common sense to understand treatment adherence and affect cognition interactions. Cognitive Ther. Res., 6, 143–163. 10. Morselli, P. and Elgie, R. (2003) GAMIAN-Europe/BEAM survey I: Global analysis of a patient questioknnaire circulated to 3450 members of 12 European advocacy groups operating in the field of mood disorders. Bipolar Disord., 5, 265–278.
11. Kikkert, M. et al. (2006) Medication adherence in schizophrenia: exploring patients, carers and professionals views. Schizophr. Bull., 32 (4), 786–794. 12. Scott, J. (1999) Cognitive approaches to improving adherence with Medication. Adv. Psych. Treatment, 5, 338–347. 13. Scott, J. (2002) Overcoming Mood Swings, Constable Robinson, England. 14. Scott, J. and Tacchi, M.J. (2002) A pilot study of concordance therapy for individuals with bipolar disorder who are nonadherent with lithium prophylaxis. Bipolar Disord., 4, 286–293. 15. Horne, R. (2003) Treatment perceptions and self regulation, in The Self-Regulation of Health and Illness Behaviour (eds L. Cameronand H. Leventhal), Routledge, London, pp. 138–153. 16. Clatworthy, J., Bowskill, R., Parham, R. et al. (2008) Understanding medication non-adherence in bipolar disorders using a Necessity-Concerns Framework. J. Affect. Disord., 116, 51–55.
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Acute Mania Paul E. Keck, Jr1, Susan L. McElroy2 and John M. Hawkins3 1
Lindner Center of HOPE; Craig & Frances Lindner; Department of Psychiatry, University of Cincinnati College of Medicine, Mason, OH, USA 2, 3 Lindner Center of HOPE; Department of Psychiatry, University of Cincinnati College of Medicine, Mason, OH, USA
Introduction Manic and mixed episodes occurring during the course of bipolar disorder are amongst the most serious acute psychiatric syndromes, often constituting a medical emergency and the need for hospitalization to ensure safety and allow aggressive treatment. The primary goal of treatment of manic and mixed episodes is rapid symptom improvement, with subsequent goals of full remission of symptoms and recovery of vocational and psychosocial function [1]. Treatment recommendation and monitoring of treatment response require consideration of the type and severity of presenting symptoms, including the presence of psychosis, depressive symptoms (degree of mixed syndrome), agitation and risk of violence; and consideration of illness characteristics such as episode frequency, co-occurring psychiatric and medical illnesses, and personal and family history of treatment response. Pharmacotherapy has been the cornerstone of treatment for bipolar manic and mixed episodes since the 1950s, but the therapeutic armamentarium has expanded greatly since then, especially over the past 15 years. Medicines with demonstrated efficacy in the treatment of manic and mixed episodes are summarized in Table 1. These medicines include agents from a broad range of pharmacologic classes, including first- and second-generation antipsychotics, lithium and several antiepileptics. In three to four week clinical trials administered as monotherapy, these medicines usually produce response rates of approximately 50% (defined as a reduction of symptoms of at least 50%) [2]. Since relatively few patients (<25%) achieve remission over a three to four week interval, combination treatment is a common strategy in clinical practice to improve short-term response and remission rates [3]. Below we review the
Bipolar Disorder: Clinical and Neurobiological Foundations Edited by Lakshmi N. Yatham and Mario Maj © 2010 John Wiley & Sons, Ltd. ISBN: 978-0-470-72198-8
clinical trials supporting the efficacy of various agents in the treatment of acute manic and mixed episodes in adults. We also discuss the use of electroconvulsive therapy in the treatment of acute mania and conclude with agents with promise in the treatment of acute mania as well as agents that were once thought to possibly possess antimanic activity, but where such efficacy has not been demonstrated.
Lithium Efficacy studies Lithium has been effectively used to treat acute bipolar manic and mixed episodes for over 50 years [4]. In randomized, double-blind, clinical trials, lithium was superior in efficacy compared with placebo [5–8], and comparable in efficacy with divalproex [9], carbamazepine [10,11], risperidone [12], olanzapine [13], quetiapine [14], aripiprazole [15], and first generation antipsychotics [16–22].
Clinical features associated with response Patients with and without psychosis responded equally well to lithium in the studies summarized above. In other analyses of lithium response, patients with predominantly euphoric or classic manic symptoms [23] and few lifetime mood episodes [24] displayed better lithium response rates than patients with predominantly mixed symptoms, numerous prior episodes and rapid cycling [25].
Dosing and therapeutic response Lithium doses titrated to the achieve plasma concentrations at the upper end of the therapeutic range (1.0–1.4 mmol/L) may be more efficacious at ameliorating manic symptoms than lower therapeutic plasma concentrations [26]. The rate of lithium titration may also affect rate of response. In one study, rapid rates of lithium dose escalation were associated with rate of reduction in manic symptoms [27]. With more 285
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Table 1 Agents with demonstrated efficacy in the treatment of acute bipolar mania. Lithium Antiepileptics Valproic acid Carbamazepine First Generation Antipsychotics Chlorpromazine Haloperidol Second Generation Antipsychotics Risperidone Olanzapine Quetiapine Ziprasidone Aripiprazole Paloperidone Asenapine
gradual titration, for example starting doses of 900 mg/d with incremental increases based on plasma concentrations, response to lithium occurred within 7–14 days in the randomized, controlled trials that employed this strategy [28].
Tolerability Higher therapeutic range plasma concentrations appear to be better tolerated during acute mania than when manic symptoms have subsided. Moreover, lithium doses required for effective maintenance treatment may be lower than those required to produce rapid acute antimanic effects [29]. Side effects commonly reported with lithium during acute mania trials include tremor, nausea, polydipsia, polyuria, weight gain and cognitive slowing. Serum creatinine levels and thyroid function tests require monitoring at the initiation of treatment and during follow-up maintenance therapy.
Valproic acid Efficacy studies The efficacy of formulations of valproic acid in the treatment of acute bipolar manic and mixed episodes was demonstrated in clinical trials of superiority versus placebo [9,30–33], and comparability in mean reduction of manic symptoms and response rates versus haloperidol [34] and olanzapine [35]. In a second head-to-head comparison trial with olanzapine, olanzapine-treated patients displayed a greater mean reduction in manic symptoms and a greater proportion achieved remission compared with divalproextreated patients [36]. Valproic acid has been studied as an adjunctive treatment in patients with manic episodes receiving first-generation antipsychotics [37]. In this trial, patients receiving the combination of valproic acid and an
antipsychotic displayed significantly greater response rates and required lower mean doses of antipsychotic compared with patients receiving antipsychotic and placebo.
Clinical features associated with response The presence of psychotic symptoms [34], depressive symptoms [23] and recent history of frequent mood episodes [38] did not appear to negatively impact response to valproic acid in clinical trials in which these features were assessed. This suggests that predictors of response to valproic acid in acute manic and mixed episodes may be broader than those associated with lithium [23].
Dosing and therapeutic response In contrast to lithium administration, one advantage of valproic acid administration is the strategy of initiating treatment with a starting dose that produces therapeutic plasma concentrations within 24 hours. Five studies examined the efficacy and tolerability of oral loading doses (20–30 mg/kg/day) of the divalproex or divalproex extended release formulations of valproic acid [30,34,35,39,40]. This dosing strategy was generally well tolerated with some evidence of more rapid response than with gradual titration starting at 750 mg/d. As with lithium, antimanic response to valproic acid appears to increase with titration to the upper end of the therapeutic range [35,41]. Again, similar to lithium, side effects, not surprisingly, also increase in frequency at higher plasma concentrations.
Tolerability Divalproex is the most commonly studied formulation of valproic acid in clinical trials in patients with acute bipolar mania. This formulation appears to be better tolerated than valproic acid [40]. Side effects commonly reported in clinical trials of divalproex in bipolar mania include nausea, vomiting, tremor, weight gain, somnolence and cognitive slowing. Rare adverse events associated with valproic acid formulations include pancreatitis, thrombocytopenia, significant hepatic transaminase elevation, hepatic failure and hyperammonemic encephalopathy in patients with urea cycle disorders. Therapeutic monitoring for patients receiving valproic acid includes plasma concentration, hepatic transaminase concentrations and platelet count.
Carbamazepine Efficacy studies The extended release beaded formulation of carbamazepine is the most well studied formulation of carbamazepine in clinical trials in acute bipolar manic and mixed
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episodes [42,43]. In these two placebo-controlled trials, carbamazepine was superior to placebo, findings which replicated the results of an earlier placebo-controlled crossover study [44]. In other clinical trials in patients with acute bipolar mania, carbamazepine was comparable in efficacy to lithium [10,11] and chlorpromazine [45,46]. However, in one small pilot comparison trial, patients receiving valproic acid displayed a better response compared with patients receiving carbamazepine [47]. These findings need to be replicated in a larger, adequately powered comparison trial. Oxcarbazepine has been an intriguing alternative to carbamazepine because, unlike carbamazepine, oxcarbazepine does not induce its own metabolism, has a lower rate of side effects and is generally better tolerated. However, data supporting the efficacy of oxcarbazepine in the treatment of acute bipolar manic and mixed episodes to date are not compelling. Initial interest was piqued when oxcarbazepine was found to exert comparable improvement in manic symptoms in small controlled trials versus haloperidol [48] and lithium [49], respectively. These initial results were not borne out in a recent large, multicentre placebo-controlled trial in adolescents [50]. In this latter, seven-week study, oxcarbazepine was not superior to placebo in reduction of manic symptoms.
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No clear plasma concentration-response relationship has been identified for carbamazepine in the treatment of acute mania. Concentrations between 4 and 12 microgram/mL are usually associated with response in mania and epilepsy, and neurological side effects often become pronounced at concentrations >12 microgram/mL [54].
Tolerability Side effects may limit treatment with carbamazepine more than with most other antimanic agents [54]. Common side effects reported in clinical trials in acute mania include sedation, ataxia, diplopia, nystagmus, transient leucopenia and rash. Rare but serious side effects include StevensJohnson syndrome, agranulocytosis, aplastic anaemia and hepatitis. Since carbamazepine can affect cardiac conduction, it should be used with caution in patients with heart block and other cardiac conduction problems [54]. Carbamazepine is also associated with hyponatremia in some patients, and can be especially troublesome in older patients [54]. Routine work-up and therapeutic monitoring for patients receiving carbamazepine includes an electrocardiogram, complete blood count and hepatic transaminase concentrations. Patient education about the signs and symptoms of Stevens-Johnson syndrome and blood dyscrasias may be more important than blood monitoring [54].
Clinical features associated with response Predictors of carbamazepine response have not been replicated in more than one study to date. Findings from individual studies suggest that carbamazepine may be less efficacious in patients who do not respond to or adequately tolerate lithium [46,51], but more efficacious than lithium in patients with atypical presentations of mania [52], and in patients with a stable or decreasing episode frequency [53]. Patients with mixed episodes did not respond as well as patients with manic episodes in one study [42], but patients with each type of episode responded equally well in another [43]. Severity of manic episode or the presence of psychosis has not been a predictor of response [42,43].
Dosing and therapeutic response Since data regarding the efficacy of oxcarbazepine in the treatment of acute mania are lacking at present, dosing and therapeutic response for carbamazepine only will be discussed. Loading strategies for carbamazepine treatment of acute mania do not appear to be viable due to the potential for adverse and treatment-limiting neurological side effects with this approach [54]. Starting doses in most carbamazepine clinical trials in acute mania have typically been 400–800 mg/d, with gradual titration by 200 mg/d every two to four days as tolerated and to clinical response [54].
First-generation (typical) antipsychotics Efficacy studies Chlorpromazine and haloperidol are the only two firstgeneration antipsychotics examined in placebo-controlled trials in acute bipolar mania [55,56]; both agents were superior to placebo. In addition, these and other first generation agents have been found to exert similar antimanic efficacy when compared with lithium [16–22], valproic acid [34], carbamazepine [46,47], and second-generation antipsychotics [56–59].
Clinical features associated with response First-generation agents have the advantages of rapid acute efficacy, and efficacy in treating psychotic as well as manic symptoms. However, they have the disadvantages of extrapyramidal side effects, prolactin elevation and risk of worsening depressive symptoms [57,60].
Dosing and therapeutic response Dosage ranges of first-generation antipsychotics used in the treatment of acute exacerbations of schizophrenia are usually used and effective in the treatment of acute bipolar mania.
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Tolerability
Clinical features associated with response
As described above, first-generation antipsychotic agents have side effects overall that are shared by this group of medications, and largely mediated by their strong binding affinities to the postsynaptic dopamine D2 receptor. These include, commonly, extrapyramidal side effects, akathisia, prolactin elevation and cognitive dulling. These agents are also associated with rare but serious side effects such as tardive dyskinesia and neuroleptic malignant syndrome.
In most of the trials reviewed above, response to secondgeneration antipsychotics was similar in patients with or without psychosis and in manic and mixed episodes. The exception to this generalization was in trials of quetiapine, which excluded patients with mixed episodes. Thus, data from placebo-controlled trials regarding the efficacy of quetiapine in mixed episodes are lacking.
Second-generation (atypical) antipsychotics Efficacy studies With the exception of clozapine, all atypical antipsychotics widely available to date, including olanzapine [61,62], risperidone [63,64], quetiapine [14,56], ziprasidone [65,66] and aripiprazole [15,67,68], have been shown to be superior to placebo as monotherapy in the treatment of acute mania in at least two placebo-controlled trials. As summarized above, when compared with haloperidol [56–59], lithium [12–15,69], divalproex [35,70] and each other [71], second-generation agents exerted similar antimanic efficacy. The only exception was one study in which olanzapine-treated patients had significantly greater mean improvement in manic symptoms compared with divalproex-treated patients [36]. Differences in study design, statistical power and initial dosing of olanzapine and divalproex likely explain the different results between the two comparison trials [35,36]. A number of studies have examined the efficacy of secondgeneration antipsychotics compared with placebo in combination with lithium, divalproex [72–78] or carbamazepine [79]. In the majority of these trials, the addition of a second-generation antipsychotic was superior to placebo in reduction of manic symptoms and time to initial improvement [72–77]. In an adjunctive study of ziprasidone versus placebo in combination with lithium, the ziprasidone group displayed a greater and more rapid improvement initially, but this difference was not sustained at two weeks of treatment, possibly because patients in lithium titration finally reached a therapeutic effect by this time point. In one [79] of two [73,79] adjunctive risperidone trials, the risperidone group was not superior to the placebo group overall, but this may have been due to the inclusion of patients receiving carbamazepine and subsequent induction of hepatic metabolism of risperidone leading to subtherapeutic levels. The prototypical second-generation antipsychotic, clozapine, has not been studied in placebo-controlled trials in acute bipolar mania. However, reports of its efficacy in large case series of patients with treatment refractory bipolar disorder provide supportive data for its use when other agents are inadequately effective [80,81].
Dosing and therapeutic response For olanzapine, in the two placebo-controlled trials, the rate of improvement was faster with an initial starting dose of 15 mg/d [62], compared with 10 mg/d [61]. One study specifically compared rapid dose escalation (20–40 mg/d) with gradual titration (starting at 10 mg/d) and found significant reductions in agitation within the first day of administration of the rapid escalation strategy compared with usual titration [82]. For risperidone, doses of 4 mg/d appear to be rapidly efficacious (within three days) [63], with a lower risk of extrapyramidal side effects compared with higher doses [64]. In the quetiapine monotherapy clinical trials, the mean modal dose associated with antimanic efficacy was approximately 600 mg/d [83]. Ziprasidone appeared to have increasing antimanic efficacy within the range of doses studied in monotherapy clinical trials of 80–160 mg/d. Aripiprazole was initiated at doses of 15 or 30 mg/d in monotherapy clinical trials.
Tolerability The second-generation antipsychotics, not unexpectedly given their different pharmacological profiles, differ somewhat in common side effects reported in monotherapy trials. In short-term acute mania trials, the most common side effects associated with olanzapine were somnolence, constipation, dry mouth, increased appetite, weight gain and orthostatic hypotension. For risperidone, common side effects reported in acute mania trials included prolactin elevation, akathisia, somnolence, dyspepsia and nausea. Headache, dry mouth, constipation, weight gain, somnolence and dizziness were the most common reported side effects in acute mania trials of quetiapine monotherapy. Common ziprasidone side effects reported monotherapy mania trials were headache, somnolence, extrapyramidal side effects, akathisia and dizziness. Lastly, for aripiprazole, common side effects reported included headache, nausea, vomiting, constipation, insomnia and akathisia. Although the risks of tardive dyskinesia and neuroleptic malignant syndrome appear to be substantially less than with first -generation antipsychotics, second-generation agents are not entirely devoid of these risks.
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Electroconvulsive therapy Efficacy studies Electroconvulsive therapy remains an important nonpharmacological treatment option for patients who do not respond well to or tolerate pharmacotherapy, or who have severe, psychotic or catatonic symptoms. Four small controlled trials have examined the efficacy of electroconvulsive therapy in the treatment of acute bipolar mania [84–87]. In these studies, electroconvulsive therapy was superior to lithium [84], and the combination of lithium and haloperidol [85] in reduction of manic symptoms. When used in combination with chlorpromazine, electroconvulsive therapy was superior to sham therapy [86]. Recently, bifrontal electoconvulsive therapy was reported to produce more rapid improvement in manic symptoms compared with bitemporal electroconvulsive therapy [87].
Clinical features associated with response As there are few controlled trials of electroconvulsive therapy in mania, there are limited data on clinical features associated with response. Importantly, the presence of severe manic symptoms, psychosis and catatonia do not predict poor response. In one trial, the presence of depressive symptoms at baseline was associated with response to electroconvulsive therapy [84].
New potential antimanic agents Two new second-generation antipsychotic agents, paloperidone and asenapine, were superior to placebo and comparable in efficacy to quetiapine and olanzapine, respectively in a large multicentre trial in patients with acute bipolar mania [88–90]. To our knowledge, no other new second-generation antipsychotics, including bifeprunox, have yet been studied in controlled trials in bipolar mania. Perhaps the most intriguing new agent to be found promising in preliminary controlled trials in acute bipolar mania is tamoxifen [91,92]. Based on findings that suggest that protein kinase C (PKC) activity may be altered in mania, these trials sought to determine whether a PKC inhibitor, tamoxifen, would exert significant improvement in manic symptoms. In each study, patients receiving tamoxifen displayed significantly greater improvement compared with patients receiving placebo, and tamoxifen was well tolerated. These promising initial positive results require replication in a larger study.
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not been shown to possess such efficacy when studied in randomized, controlled clinical trials. These include verapamil [93,94], topiramate [95], lamotrigine [96,97] and gabapentin [98].
Clinical recommendations Acute manic and mixed episodes, with or without psychosis, often constitute a medical emergency, and frequently require hospital admission to ensure the safety of patients and others, as well as to provide a therapeutic environment for rapid recovery. Antimanic agents are the cornerstone of treatment of bipolar manic and mixed episodes. As reviewed above, the therapeutic armamentarium has expanded dramatically in the last 15 years. Monotherapy or combination therapy (most commonly a second-generation antipsychotic agent and lithium, valproate or carbamazepine) represent standard treatment approaches. Doses of antimanic agents often need to be titrated to the higher end of therapeutic ranges to achieve rapid improvement, balanced against the risk of side effects [99]. Since manic or mixed episodes form just one phase of the overall challenge of assisting patients in the management of bipolar disorder, two different, and at times competing treatment needs, warrant consideration: the need to rapidly ameliorate symptoms to ensure safety, reduce morbidity and hasten recovery versus the need to recommend an antimanic agent that may need to be used not just in acute treatment, but sustained into maintenance therapy. Thus, agents that have side effects, for example sedation, that may be beneficially acutely, may not be as advantageous in longterm treatment. Similarly, the choice of combination therapy over monotherapy may have short-term benefits in hastening recovery, but pose the dilemma in longer-term treatment of obscuring which agent is the most effective and complicating treatment by the burden of additive side effects. The studies reviewed above provide a compendium of the evidence-based treatment of acute bipolar manic and mixed episodes. Selection or recommendation of specific agents or combinations of agents requires the consideration of prior treatment response, the presence of potential predictors of response, patient preference, severity of the acute episode, the presence of co-occurring psychiatric and other medical conditions, history of side effects and tolerability, and other considerations such as the likelihood of treatment adherence, and cost and availability of one regimen over another [99].
Summary Agents without demonstrated antimanic efficacy Over the past decade, a number of medications, which showed early promise as potential antimanic agents, have
Less than 15 years ago, only lithium and the first-generation antipsychotics, along with electroconvulsive therapy, were effective treatments for patients with acute bipolar manic or mixed episodes. The number of available agents has
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expanded dramatically since then, offering patients with bipolar disorder therapeutic options where none previously existed. Since mania is often a medical emergency, expanding treatments for this phase of bipolar disorder has no doubt substantially reduced human suffering and the potential risks of harm to self and others posed by acute manic states.
References 1. Keck, P.E. Jr and McElroy, S.L. (2009) Treatment of bipolar disorder, in Textbook of Psychopharmacology, 4th edn (eds A.F. Schatzberg and C.B. Nemeroff), American Psychiatric Publishing, Inc., Washington, DC, pp. 334–353. 2. Suppes, T., Dennehy, E.B., Hirschfeld, R.M.A. et al. (2005) The Texas Implementation of Medication Algorithms: update to the algorithms for the treatment of bipolar I disorder. J. Clin. Psychiat., 66, 870–886. 3. Perlis, R.H., Welge, J.A., Vornik, L.A. et al. (2006) Atypical antipsychotics in the treatment of mania: a meta-analysis of randomized, placebo-controlled trials. J. Clin. Psychiat., 67, 509–516. 4. Goodwin, F.K. and Jamison, K.R. (2007) Manic-Depressive Illness: Bipolar Disorders and Recurrent Depression, Oxford University Press, New York, NY. 5. Goodwin, F.K., Murphy, D.L. and Bunney, W.E. Jr (1969) Lithium carbonate treatment of depression and mania: a longitudinal double-blind study. Arch. Gen. Psychiatry, 21, 486–496. 6. Maggs, R. (1963) Treatment of manic illness with lithium carbonate. Brit. J. Psychiat., 109, 56–65. 7. Schou, M., Juel-Nielson, E., Stromgren, E. et al. (1954) The treatment of manic psychoses by administration of lithium salts. J. Neurol. Neurosur. Ps., 17, 250–260. 8. Stokes, P.E., Shamoian, C.A., Stoll, P.M. et al. (1971) Efficacy of lithium as acute treatment of manic-depressive illness. Lancet, 1, 1319–1325. 9. Bowden, C.L., Brugger, A.M., Swann, A.C. et al. (1994) Efficacy of divalproex vs lithium and placebo in the treatment of mania. JAMA, 271, 918–924. 10. Lerer, B., Moore, N., Meyendorff, E. et al. (1987) Carbamazepine versus lithium in mania: a double-blind study. J. Clin. Psychiat., 48, 89–93. 11. Small, J.G., Klapper, M.H., Milstein, V. et al. (1991) Carbamazepine compared with lithium in the treatment of mania. Arch. Gen. Psychiatry, 48, 915–921. 12. Segal, J., Berk, M. and Brook, S. (1998) Risperidone compared with both lithium and haloperidol in mania: a double-blind randomized controlled trial. Clin. Neuropharmacol., 21, 176–180. 13. Berk, M., Ichim, L. and Brook, S. (1999) Olanzapine compared to lithium in mania: a double-blind randomized controlled trial. Int. Clin. Psychopharm., 14, 339–343. 14. Bowden, C.L., Grunze, H., Mullen, J. et al. (2005) A randomized, double-blind, placebo-controlled efficacy and safety study of quetiapine or lithium as monotherapy for mania in bipolar disorder. J. Clin. Psychiat., 66, 111–121.
15. Keck, P.E. Jr, Orsulak, P.J., Cutler, A.J. et al. (2008) Aripiprazole monotherapy in the treatment of acute bipolar I mania: a randomized, double-blind, placebo- and lithium-controlled study. J. Affect. Disord., 108, 36–49. 16. Garfinkel, P.E., Stancer, H.C. and Persad, E. (1980) A comparison of haloperidol, lithium and their combination in the treatment of mania. J. Affect. Disord., 2, 279–288. 17. Johnson, G., Gershon, S., Burdock, E.I. et al. (1976) Comparative effects of lithium and chlorpromazine in the ftreatment of acute manic states. Brit. J. Psychiat., 119, 267–276. 18. Platman, S.R. (1970) A comparison of lithium carbonate and chlorpromazine in mania. Am. J. Psychiatry, 127, 351–353. 19. Prien, R.F., Caffey, E.M. Jr and Klett, C.J. (1972) Comparison of lithium carbonate and chlorpromazine in the treatment of mania: report of the Veterans Affairs and National Institute of Health Collaborative Study Group. Arch. Gen. Psychiatry, 26, 146–153. 20. Shopsin, B., Gershon, S., Thompson, H. et al. (1975) Psychoactive drugs in mania: a controlled comparison of lithium carbonate, chlorpromazine, and haloperidol. Arch. Gen. Psychiatry, 32, 34–42. 21. Spring, G., Schweid, D., Gray, C. et al. (1970) A double-blind comparison of lithium and chlorpromazine in the treatment of manic states. Am. J. Psychiatry, 126, 1306–1310. 22. Takahashi, R., Sakuma, A., Itoh, K. et al. (1975) Comparison of efficacy of lithium carbonate and chlorpromazine in mania: report of collaborative study group on treatment of mania in Japan. Arch. Gen. Psychiatry, 32, 1310–1318. 23. Bowden, C.L. (1995) Predictors of response to divalproex and lithium. Expt. Op. Invest. Drugs, 10, 661–671. 24. McElroy, S.L., Keck, P.E. Jr, Pope, H.G. Jr et al. (1992) Clinical and research implications of the diagnosis of dysphoric or mixed mania or hypomania. Am. J. Psychiatry, 149, 1633–1644. 25. Dunner, D.L. and Fieve, R.R. (1974) Clinical factors in lithium prophylaxis failure. Arch. Gen. Psychiatry, 30, 229–233. 26. Stokes, P.E., Kocsis, J.H. and Orestes, J.A. (1976) Relationship of lithium chloride dose to treatment response in acute mania. Arch. Gen. Psychiatry, 33, 1080–1084. 27. Goldberg, J.F., Garno, J.L., Leon, A.C. et al. (1998) Rapid titration of mood stabilizers predicts remission from mixed or pure mania in bipolar patients. J. Clin. Psychiat., 59, 151–158. 28. McElroy, S.L. and Keck, P.E. Jr (2000) Pharmacological agents for the treatment of acute bipolar mania. Biol. Psychiatry, 48, 539–557. 29. Perlis, R.H., Sachs, G.S., Lafer, B. et al. (2002) Effect of abrupt change from standard to low serum levels of lithium: a re-analysis of double-blind lithium maintenance data. Am. J. Psychiatry, 159, 115–1159. 30. Bowden, C.L., Swann, A.C., Calabrese, J.R. et al. (2006) A randomized, placebo-controlled, multicenter study of divalproex sodium extended release in the treatment of acute mania. J. Clin. Psychiat., 67, 1501–1510. 31. Pope, H.G. Jr, McElroy, S.L., Keck, P.E. Jr et al. (1991) Valproate in the treatment of acute mania: a placebo-controlled study. Arch. Gen. Psychiatry, 48, 62–68.
Acute Mania 32. Brennan, M.J.W., Sandyk, R. and Borsook, D. (1984) Use of sodium valproate in the management of affective disorders: basic and clinical aspects, in Anticonvulsants in Affective Disorders (eds H.M. Emrich, T. Okuma and A.A. Muller), Excerpta Medica, Amsterdam, pp. 56–65. 33. Emrich, H.M., von Zerssen, D. and Kissling, W. (1981) On a possible role of GABA in mania: therapeutic of sodium valproate, in GABA and Benzodiazepine Receptors (eds E. Costa, G. Dicharia and G.L. Gessa), Raven Press, New York, pp. 287–296. 34. McElroy, S.L., Keck, P.E. Jr, Stanton, S.P. et al. (1996) A randomized comparison of divalproex oral loading versus haloperidol in the initial treatment of acute psychotic mania. J. Clin. Psychiat., 57, 142–146. 35. Zajecka, J.M., Weisler, R., Swann, A.C. et al. (2002) A comparison of the efficacy, safety, and tolerability of divalproex sodium and olanzapine in the treatment of bipolar disorder. J. Clin. Psychiat., 63, 1148–1155. 36. Tohen, M., Baker, R.W., Altshuler, L.L. et al. (2002) Olanzapine versus divalproex in the treatment of acute mania. Am. J. Psychiatry, 159, 1011–1017. 37. Muller-Oerlinghausen, B., Retzow, A., Henn, F.A. et al. (2000) Valproate as an adjunct to neuroleptic medication for the treatment of acute episodes of mania: a prospective, randomized, double-blind, placebo-controlled, multicenter study. J. Clin. Psychopharmacol., 20, 195–203. 38. McElroy, S.L., Keck, P.E. Jr, Pope, H.G. Jr et al. (1991) Correlates of antimanic response to valproate. Psychopharmacol. Bull., 27, 127–133. 39. Keck, P.E. Jr, McElroy, S.L., Tugrul, K.C. et al. (1993) Valproate oral loading in the treatment of acute mania. J. Clin. Psychiat., 54, 305–398. 40. Hirschfeld, R.M.A., Allen, M.H., McEvoy, J.P. et al. (1999) Safety and tolerability of oral loading divalproex sodium in acutely manic bipolar patients. J. Clin. Psychiat., 60, 815–818. 41. Allen, M.H., Hirschfeld, R.M.A., Wozniak, P.J. et al. (2006) Linear relationship of valproate serum concentration to response and optimal serum levels for acute mania. Am. J. Psychiatry, 163, 272–275. 42. Weisler, R.H., Kalali, A.H., Ketter, T.A. et al. (2004) A multicenter, randomized, double-blind, placebo-controlled trial of extended release carbamazepine capsules as monotherapy for bipolar patients with manic or mixed episodes. J. Clin. Psychiat., 65, 478–484. 43. Weisler, R.H., Keck, P.E. Jr, Swann, A.C. et al. (2005) Extended release carbamazepine capsules as monotherapy for acute mania in bipolar disorder: a multicenter, randomized, double-blind, placebo-controlled trial. J. Clin. Psychiat., 66, 323–330. 44. Ballenger, J.C. and Post, R.M. (1978) Therapeutic effects of carbamazepine in affective illness: a preliminary report. Comm. Psychopharmacol., 2, 159–175. 45. Grossi, E., Sacchetti, E., Vita, A. et al. (1984) Carbamazepine versus chlorpromazine in mania: a double-blind trial, in Anticonvulsants in Affective Disorders (eds H.M. Emrich, T., Okuma and A.A. Muller), Excerpta Medica, Amsterdam, pp. 177–187.
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46. Okuma, T., Inanaga, K., Otsuki, S. et al. (1979) Comparison of the antimanic efficacy of carbamazepine and chlorpromazine: a double-blind controlled study. Psychopharmacology (Berl.), 66, 211–217. 47. Vasudev, J.M., Goswami, U. and Kohli, K. (2000) Carbamazepine and valproate monotherapy: feasibility, relative safety and efficacy, and therapeutic drug monitoring in manic disorders. Psychopharmacology (Berl.), 150, 15–23. 48. Emrich, H.M. (1991) Studies of oxcarbazepine (Trileptal() in acute mania. Int. J. Psychophysiol., 5, 83–88. 49. Muller, A.A. and Stoll, K.D. (1984) Carbamazepine and oxcarbazepine in the treatment of manic syndromes: studies in Germany, in Anticonvulants in Affective Disorders (eds H.M. Emrich, T. Okuma and A.A. Muller), Excerpta Medica, Amsterdam, pp. 134–137. 50. Wagner, K.D., Kowatch, R.A. and Emslie, G.J. (2006) A double-blind, randomized, placebo-controlled trial of oxcarbazepine in the treatment of bipolar disorder in children and adolescents. Am. J. Psychiatry, 163, 1179–1186. 51. Post, R.M., Uhde, T.W., Roy-Byrne, P.P. et al. (1987) Correlates of antimanic response to carbamazepine. J. Psychiat. Res., 21, 71–83. 52. Greil, W., Kleindienst, N., Erazo, N. et al. (1998) Differential response to lithium and carbamazepine in the prophylaxis of bipolar disorder. J. Clin. Psychopharmacol., 18, 455–460. 53. Post, R.M., Leverich, G.S., Rosoff, A.S. et al. (1990) Carbamazepine prophylaxis in refractory affective disorders: a focus on long-term follow-up. J. Clin. Psychopharmacol., 10, 318–327. 54. Ketter, T.A., Wang, P.W. and Post, R.M. (2000) Carbamazepine and oxcarbazepine, in Textbook of Psychopharmacology, 3rd edn (eds A.F. Schatzberg and C.B. Nemeroff), American Psychiatric Publishing, Inc., Washington, DC, pp. 581–613. 55. Klein, D.F. (1967) Importance of psychiatric diagnosis in prediction of clinical drug effects. Arch. Gen. Psychiatry, 16, 118–126. 56. McIntyre, R.S., Brecher, M., Paulsson, B. et al. (2005) Quetiapine or haloperidol as monotherapy for bipolar mania–a 12-week, double-blind, randomized, parallel-group, placebo-controlled trial. Eur. Neuropsychopharmacol., 15, 573–585. 57. Tohen, M., Goldberg, J.F., Gonzalez-Pinto, A. et al. (2003) A 12-week, double-blind comparison of olanzapine vs. haloperidol in the treatment of acute mania. Arch. Gen. Psychiatry, 60, 1218–1226. 58. Smulevich, A.M., Khanna, S., Eerdekens, M. et al. (2005) Acute and continuation risperidone monotherapy in bipolar mania: a 3-week placebo-controlled trial followed by a 9-week double-blind trial of risperidone and haloperidol. Eur. Neuropsychopharmacol., 15, 75–84. 59. Vieta, E., Bourin, M., Sanchez, R. et al. (2005) Effectiveness of aripiprazole vs. haloperidol in acute bipolar mania: a doubleblind, randomized, 12-week comparative trial. Brit. J. Psychiat., 187, 235–242. 60. Koukopoulos, A., Reginaldi, D. and Laddomada, P. (1980) Course of manic-depressive cycle and changes caused by treatments. Pharmakopsych. Neuro., 13, 156–167.
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61. Tohen, M., Sanger, T.M., McElroy, S.L. et al. (1999) Olanzapine versus placebo in the treatment of acute mania. Am. J. Psychiatry, 156, 702–709. 62. Tohen, M., Jacobs, T.G., Grundy, S.L. et al. (2000) Efficacy of olanzapine in acute bipolar mania: a double-blind, placebocontrolled study. Arch. Gen. Psychiatry, 57, 841–849. 63. Hirschfeld, R.M.A., Keck, P.E. Jr, Kramer, M. et al. (2004) Rapid antimanic effect of risperidone monotherapy: a 3-week multicenter, double-blind, placebo-controlled trial. Am. J. Psychiatry, 161, 1057–1061. 64. Khanna, S., Vieta, E., Lyons, B. et al. (2009) Risperidone in the treatment of acute mania: double-blind, placebo-controlled study. Brit. J. Psychiat., 187, 229–234. 65. Keck, P.E. Jr, Versiani, M., Potkin, S. et al. (2003) Ziprasidone in the treatment of acute bipolar mania: a three-week, placebo-controlled, double-blind, randomized trial. Am. J. Psychiatry, 160, 741–748. 66. Potkin, S., Keck, P.E. Jr, Segal, S. et al. (2005) Ziprasidone in acute bipolar mania: a 21-day randomized, double-blind, placebo-controlled replication trial. J. Clin. Psychopharmacol., 25, 301–310. 67. Keck, P.E. Jr, Marcus, R., Tourkodimitris, S. et al. (2003) A placebo-controlled, double-blind study of the efficacy and safety of aripiprazole in patients with acute bipolar mania. Am. J. Psychiatry, 160, 1651–1658. 68. Sachs, G.S., Sanchez, R., Marcus, R. et al. (2006) Aripiprazole in the treatment of acute manic or mixed episodes in patients with bipolar I disorder: a 3-week placebo controlled study. J. Clin. Psychopharmacol., 20, 536–546. 69. Li, H., Ma, C., Wang, G. et al. (2008) Response and remission rates in Chinese patients with bipolar mania treated for 4 weeks with either quetiapine or lithium: a randomized and double-blind study. Curr. Med. Res. Opin., 24, 1–10. 70. DelBello, M.P., Kowatch, R.A., Adler, C.M. et al. (2006) A double-blind randomized pilot study comparing quetiapine and divalproex for adolescent mania. J. Am. Acad. Child Psy., 45, 305–313. 71. Perlis, R.H., Baker, R.W., Zarate, C.A. Jr et al. (2006) Olanzapine versus risperidone in the treatment of manic or mixed states in bipolar I disorder: a randomized, double-blind trial. J. Clin. Psychiat., 67, 1747–1753. 72. Tohen, M., Chengappa, K.R.N., Suppes, T. et al. (2002) Efficacy of olanzapine in combination with valproate or lithium in the treatment of mania in patients partially nonresponsive to valproate or lithium. Arch. Gen. Psychiatry, 59, 62–69. 73. Sachs, G.S., Grossman, F., Ghaemi, S.N. et al. (2002) Combination mood stabilizer with risperidone or haloperidol for treatment of acute mania: a double-blind, placebo-controlled comparison for efficacy and safety. Am. J. Psychiatry, 159, 1146–1154. 74. Sachs, G.S., Chengappa, K.N.R., Suppes, T. et al. (2004) Quetiapine with lithium or divalproex for the treatment of bipolar mania: a randomized, double-blind, placebo-controlled study. Bipolar Disord., 6, 213–223. 75. Yatham, L.N., Paulsson, B., Mullen, J. et al. (2004) Quetiapine versus placebo in combination with lithium or divalproex for the treatment of bipolar mania. J. Clin. Psychopharmacol., 24, 599–606.
76. Vieta, E., Tjoen, C., McQuade, R.D. et al. (2008) Efficacy of adjunctive aripiprazole to either valproate or lithium in bipolar mania patients partially nonresponsive to valproate/lithium monotherapy: a placebo-controlled study. Am. J. Psychiatry, 165, 1316–1325. 77. DelBello, M.P., Schweirs, M.L., Rosenberg, H.L. et al. (2002) A double-blind, randomized, placebo-controlled study of quetiapine as adjunctive treatment for adolescent mania. J. Am. Acad. Child Psy., 41, 1216–1223. 78. Weisler, R.H., Dunn, J. and English, P. (2004) Ziprasidone adjunctive treatment of acute bipolar mania: a randomized, placebo-controlled trial. Abstracts of the 16th Annual Meeting of the European College of Neuropsychopharmacology, Prague, Czech Republic. 79. Yatham, L.N., Grossman, F., Augustyns, I. et al. (2003) Mood stabilizers plus risperidone or placebo in the treatment of acute mania. International, double-blind, randomized controlled trial. Brit. J. Psychiat., 182, 141–147. 80. Green, A.I., Tohen, M., Patel, J.K. et al. (2000) Clozapine in the treatment of refractory psychotic mania. Am. J. Psychiatry, 157, 982–986. 81. Calabrese, J.R., Kimmel, S.E., Woyshville, M.J. et al. (1996) Clozapine for treatment-refractory mania. Am. J. Psychiatry, 153, 759–764. 82. Baker, R.W., Kinon, B.J., Maguire, G.A. et al. (2003) Effectiveness of rapid initial dose escalation of up to forty milligrams per day of oral olanzapine in acute agitation. J. Clin. Psychopharmacol., 23, 342–348. 83. Vieta, E., Mullen, J., Brecher, M. et al. (2005) Quetiapine monotherapy for mania associated with bipolar disorder: combined analysis of two international, double-blind, randomized, placebo-controlled studies. Curr. Med. Res. Opin., 21, 923–934. 84. Small, J.G., Klapper, M.H., Kellams, J.J. et al. (1988) Electroconvulsive treatment compared with lithium in the management of manic states. Arch. Gen. Psychiatry, 45, 727–732. 85. Mukerjee, S., Sackheim, H.A. and Schnur, D.B. (1994) Electroconvulsive therapy of acute manic episodes: a review of 50 years experience. Am. J. Psychiatry, 151, 169–176. 86. Sikdar, S., Kulhara, P. and Avasthi, A. (1994) Combined chlorpromazine and electroconvulsive therapy in mania. Brit. J. Psychiat., 164, 806–810. 87. Hiremani, R.M., Thirthalli, J., Tharayil, B.S. et al. (2008) Double-blind randomized controlled study comparing short-term efficacy of bifrontal and bitemporal electroconvulsive therapy in acute mania. Bipolar Disord., 10, 701–707. 88. Hirschfeld, R.M.A., Panagides, J., Alphs, L. et al. (2007) Asenapine in acute mania: a randomized, double-blind, placebo- and olanzapine-controlled trial. Abstracts of the 160th Annual Meeting of the American Psychiatric Association. American Psychiatric Publishing, Inc., Washington, DC, p. 333. 89. Vieta, E., Berwaerts, J., Nuamah, I. et al. (2008) Randomized, placebo, active-controlled study of paloperidone extendedrelease (ER) for acute manic and mixed episodes in bipolar I disorder. Eur. Neuropsychopharmacol., 18 (Suppl 4), S369. 90. Cutler, A. (2008) A randomized, double-blind, placebocontrolled, parallel-group, dose-response, multicenter study
Acute Mania
91.
92.
93.
94.
95.
to evaluate the efficacy and safety of three fixed doses of extended-release paloperidone (3, 6, and 12 mg/day) in the treatment of subjects with acute manic and mixed episodes associated with bipolar I disorder. Veritas Medicine, 4 (2), 111–116. Zarate, C.A. Jr, Singh, J.B., Carlson, P.J. et al. (2007) Efficacy of protein kinase C inhibitor (tamoxifen) in the treatment of acute mania: a pilot study. Bipolar Disord., 9, 561–570. Yildiz, A., Guleryuz, S., Ankerst, D.P. et al. (2008) Protein kinase C inhibition in the treatment of mania: a double-blind, placebo-controlled trial of tamoxifen. Arch. Gen. Psychiatry, 65, 255–263. Walton, S.A., Berk, M. and Brook, S. (1996) Superiority of lithium over verapamil in mania: a randomized, controlled single-blind trial. J. Clin. Psychiat., 57, 543–546. Janicak, P.G., Sharma, R.P., Pandey, G. et al. (1998) Verapamil for the treatment of acute mania: a double-blind, placebocontrolled trial. Am. J. Psychiatry, 155, 972–973. Kushner, S.F., Khan, A. and Lane, R. (2006) Topiramate monotherapy in the management of acute mania: results of
96.
97.
98.
99.
|
293
four double-blind placebo-controlled trials. Bipolar Disord., 8, 15–27. Anand, A., Oren, D.A. and Berman, R.M. (1999) Lamotrigine treatment of lithium failure in outpatient mania: a doubleblind, placebo-controlled trial. Abstracts of the 3rd International Conference on Bipolar Disorder. University of Pittsburgh, Pittsburgh, PA. Frye, M.A., Ketter, T.A., Kimbrell, T.A. et al. (2000) A placebocontrolled study of lamotrigine and gabapentin monotherapy for refractory mood disorders. J. Clin. Psychopharmacol., 20, 607–614. Pande, A.C., Crockatt, J.G., Janney, C.A. et al. (2000) Gabapentin in bipolar disorder: a placebo-controlled trial of adjunctive therapy. Bipolar Disord., 2, 249–255. Keck, P.E. Jr and McElroy, S.L. (2007) Pharmacological treatments for bipolar disorder, in A Guide to Treatments That Work, 3rd edn (eds P.E. Nathan and J.M. Gorman), Oxford University Press, New York, NY, pp. 323–350.
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Pharmacological Treatment of Bipolar Depression Allan H. Young1 and Charles B. Nemeroff2 1 2
Department of Psychiatry, Institute of Mental Health, University of British Columbia, Vancouver, BC, Canada Department of Psychiatry and Behavioral Sciences, University of Miami Miller School of Medicine, Miami, FL, USA
Introduction Bipolar disorders are characterized by episodes of mania/ hypomania and depression and are estimated in the population to have a lifetime prevalence of approximately 2% [1,2]. The impact of bipolar disorders has recently been estimated to amount to 2% of all disability-adjusted life years associated with non-communicable disease worldwide [3]. The degree of disability associated with episodes of bipolar depression may be greater than that associated with episodes of bipolar mania [4] and patients with bipolar depression frequently have pronounced psychosocial impairment [5,6]. This is of particular importance given that patients with bipolar disorder are likely to experience depressive symptoms far more frequently than symptoms of mania [7,8]. Furthermore, bipolar depression is a major risk factor for suicide and long-term follow-up studies suggest that predominantly depressed bipolar patients suffer the highest mortality rates from this cause [9]. Effective treatment of depression in bipolar disorders represents a key therapeutic challenge. All treatment should be based on accurate diagnosis but several factors may confound the diagnosis (and thus treatment) of bipolar disorder, including a considerable symptomatic overlap with other psychiatric illnesses; a potentially incomplete medical history of the patient and lack of patient insight or acceptance of diagnosis. Treatment is further complicated by the high prevalence of comorbidities, such as anxiety disorders and substance use disorders. These comorbidities frequently have a detrimental effect on the disease course, including an increase in the number of suicide attempts [10–13]. A combination of these factors can lead to bipolar disorder being under-diagnosed and high rates of misdiagnosis (commonly as unipolar major depressive disorder, anxiety disorder or schizophrenia) have been reported [14]. Inaccurate diagnosis often results in inappropriate treatment being implemented, which may compromise long-term outcomes.
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Diagnostic accuracy may be improved by intensive scrutiny for the presence of manic/hypomanic, psychotic or reverse vegetative symptoms in every patient presenting with depressive symptoms, in establishing whether there is a family history of bipolar disorder, and whether the patient had a prepubertal onset of depression. This chapter focuses on the pharmacological treatment of bipolar depression, although other treatment modalities, both psychological and somatic, exist. For a more extensive discussion and specific treatment recommendations the reader is referred to recent international guidelines [15,16]. Treatments for bipolar 1 and bipolar II depression will be discussed separately.
Treatments for the management of bipolar I depression Lithium In a review of short-term, placebo-controlled, double-blind, cross-over trials that compared the efficacy of lithium with placebo, seven out of eight studies found that lithium was significantly more effective than placebo [17]. Furthermore, approximately half of the patients experienced a relapse of depressive symptoms when lithium was substituted by placebo [17]. However, a more recent double-blind, randomized, placebo-controlled study of quetiapine and lithium as acute monotherapy treatment for bipolar depression found no statistically significant difference between lithium and placebo [18]. The mean serum lithium levels in this study were 0.61 mEq/L and it is unknown if response rates would be greater with higher serum lithium levels. The duration of acute treatment was also 8 weeks, leaving the possibility open of an undetected slower beneficial effect of lithium on bipolar depression. Two early studies examined the efficacy of lithium in the long-term treatment of bipolar disorder. In the first study, 205 patients with bipolar disorder, most recent episode manic, were randomized to lithium or placebo for a period of two years [19]. The number of manic episodes, but not depressive episodes, was significantly lower with lithium
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compared with placebo. In the second smaller study, 44 patients with bipolar disorder, most recent episode depressed, were randomized to lithium, imipramine or placebo for two years [19,20]. In this study, the number of depressive episodes, but not manic episodes, experienced was significantly lower in the lithium group compared with the placebo group. Meta-analyses of trials of lithium in patients with bipolar disorder include further data concerning the use of lithium; importantly they summarize recent studies, which have included lithium as an active comparison to new medications [21,22]. Lithium was shown in these analyses to be more effective than placebo in preventing any new mood episodes. However, although lithium was superior to placebo in preventing manic episodes, this was not clearly shown for depressive episodes [21,22]. Baldessarini and Tondo [23] carried out a pooled analysis of data from 24 studies that investigated the clinical effects of long-term lithium in 360 patients with bipolar disorder who received lithium maintenance treatment since 1970. In the period 1970–1981, the number of recurrences of mania or depression per month was 2.7% compared with 0.5% per month in the period 1982–1996, suggesting that loss of effectiveness has not occurred with lithium as maintenance treatment over time.
Lamotrigine Monotherapy Lamotrigine monotherapy was initially examined in a double-blind, placebo-controlled study for the acute treatment of bipolar I depression [24]. More recently, this study was included in a review of five double-blind, placebocontrolled trials, all of which assessed the efficacy of lamotrigine in the acute treatment of bipolar depression [25]. These five randomized, placebo-controlled trials have also been reviewed by others [26,27]. Although there is a widespread belief that lamotrigine has a beneficial effect on depressive symptoms in the depressed phase of bipolar disorder, the overall pooled effect was modest at best. It is, however, important to note that the advantage of lamotrigine over placebo was greater in the more severely depressed participants. Two longer-term studies compared the effectiveness of lithium and lamotrigine monotherapy over a period of 18 months in 638 patients with bipolar I disorder and recent episodes of mania or depression [28,29]. Bowden et al. demonstrated that lamotrigine was significantly more effective than placebo at prolonging the time to intervention for a depressive episode [28]. This finding is supported by the study by Calabrese et al. that again found that lamotrigine significantly prolonged time to a depressive episode [29]. A pooled analysis of data from these trials showed that lamotrigine, but not lithium, was superior to
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placebo at delaying the time to intervention for a depressive episode [30].
Adjunctive lamotrigine The use of adjunctive lamotrigine as a treatment for bipolar I depression was investigated in the Systematic Treatment Enhancement Programme for Bipolar Disorder (STEP-BD) study. This study was designed to evaluate the rate of recovery (defined as no more than two symptoms meeting Diagnostic and Statistical Manual of Mental Disorders, 4th edition (DSM-IV) threshold criteria for a mood episode and no significant symptoms present for 8 weeks) with open-label lamotrigine, inositol or risperidone as adjuncts to a mood stabilizer for up to 16 weeks in patients (n ¼ 66) with treatment-resistant bipolar I or bipolar II depression. Recovery rates were 23.8% (95% CI ¼ 5.8 to 41.8) with lamotrigine compared with 17.4% (95% CI ¼ 2.4 to 32.4) with inositol and 4.6% (95% CI ¼ 0 to 14.6) for risperidone (no significant between group differences were reported) [31]. In addition, the use of adjunctive lamotrigine was recently evaluated in an eight-week, double-blind, randomized, placebo-controlled trial; the results suggested that lamotrigine in combination with lithium was superior to lithium monotherapy [32]. A comparison of the adjunctive use of lamotrigine and lithium in the long-term treatment of bipolar disorder has been carried out in an open, randomized trial [33]. Patients were randomized to receive lithium (dosed to attain serum levels of 0.5–0.8 mmol/L, n ¼ 78) or lamotrigine (up to 400 mg/day, n ¼ 77) for up to six years, with concomitant pharmacologic therapy allowed for the first six months of the study period. The primary outcome measure was the cumulative probability of the patients only requiring monotherapy at month 6 and continuing on monotherapy after this assessment. No differences were noted between lamotrigine and lithium when used as adjunctive therapy with respect to the primary outcome measure [33].
Divalproex Relatively little evidence exists supporting the use of divalproex in bipolar 1 depression. A small eight-week, doubleblind, placebo-controlled, randomized study that evaluated the clinical efficacy of Divalproex (up to 2500 mg/day) in 25 outpatients with bipolar I depression found that the active treatment was significantly more effective than placebo in improving symptoms of depression [34]. Some further evidence is provided by a very small double-blind, randomized study in which patients with bipolar I depression (n ¼ 9) received divalproex or placebo for six weeks [35]. Divalproex was associated with a significantly greater reduction in MADRS total score, the
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primary efficacy measure, from baseline to Week 6 compared with placebo (p < 0.001; standardized effect size [Cohen d] ¼ 0.81).
Carbamazepine A double-blind study evaluated the acute effects of carbamazepine monotherapy in 35 patients with depression, including 16 patients with bipolar I depression and 8 with bipolar II depression, over a median treatment duration of 45 days. The investigators found that 62% of patients receiving carbamazepine monotherapy (mean dose of 971 mg/day; achieving mean SD blood levels of 9.3 1.9 micrograms/ml; range, 3–12.5 micrograms/ml) experienced a response (mean improvement of 1 point on the Bunney-Hamburg scale) [36].
Quetiapine Monotherapy Evidence for the acute efficacy of quetiapine monotherapy in patients with bipolar I or bipolar II depression is provided by the results of two large, 8-week, randomized, doubleblind, placebo-controlled studies that evaluated quetiapine monotherapy (300 and 600 mg/day) [37,38]. In the first study, effect sizes (based on change in MADRS total score from baseline to Week 8) in patients with bipolar I depression were 0.91 and 1.09 for quetiapine, 300 and 600 mg/day, respectively. In the second study, effect sizes at Week 8 for the bipolar I subgroup were 0.67 and 0.51 for quetiapine, 300 and 600 mg/day, respectively. Importantly, treatment-emergent mania rates did not differ from placebo [37,38]. The efficacy of quetiapine or lithium as acute monotherapy was further evaluated in a double-blind, placebocontrolled study in patients with bipolar I and bipolar II depression. The study consisted of an initial acute phase lasting eight weeks, during which patients were randomized to receive quetiapine 300 mg/day, 600 mg/day, lithium or placebo. This was followed by a continuation phase lasting between 26 and 52 weeks. The primary endpoint of the acute phase of the study was the change from baseline to Week 8 in MADRS total score. In the bipolar I subgroup of patients (n ¼ 487) the mean change in MADRS total score at Week 8 was 14.8 with quetiapine 300 mg/day (p < 0.05 vs. placebo) and 16.5 with quetiapine 600 mg/day (p < 0.05 vs. placebo) compared with 11.2 for placebo [18]. Notably, lithium did not separate from placebo. These findings are consistent with a double-blind, placebo-controlled study of similar design that evaluated the efficacy of quetiapine (300 and 600 mg/day) and paroxetine (20 mg/day) as monotherapy in patients with bipolar I and bipolar II depression [39]. In the bipolar I subgroup (n ¼ 448), quetiapine 600 mg/day significantly
reduced MADRS total score from baseline to Week 8 (16.2, quetiapine 300 mg/day [95% CI ¼ 5.34 to 0.22; p < 0.05]; 16.4, quetiapine 600 mg/day [95% CI ¼ 5.60 to 0.49; p < 0.05] compared with placebo [13.4]). Both of the above studies were sufficiently large (n ¼ 328 and n ¼ 256, respectively) to provide adequate evidence for the short- and long-term use of quetiapine monotherapy for the treatment of bipolar I or II depression [18,39]. These two studies were powered to allow for a combined continuation phase, during which patients who remitted on quetiapine 300 or 600 mg/ day were randomly re-assigned to either continued treatment on quetiapine 300 mg/day or placebo and were studied for an additional 26–52 weeks. Quetiapine significantly increased the time to recurrence of depression compared with placebo (HR 0.48, 95% CI ¼ 0.29 to 0.77) [18]) (HR 0.36, 95% CI ¼ 0.21 to 0.63) [39] in patients with bipolar I or II depression. Analysis of the individual items on the MADRS revealed significant improvement of virtually all of them in the quetiapine group, indicating that the overall effect was not solely secondary to improvement in sleep. The two comparator agents in these studies, lithium and paroxetine, did not separate from placebo.
Adjunctive quetiapine To date, no randomized, controlled trials have yet examined the efficacy of adjunctive quetiapine treatment for acute bipolar depression; however, evidence for long-term efficacy in patients with bipolar I depression is provided by two randomized, double-blind, parallel group studies that investigated the use of quetiapine in combination with lithium or divalproex (Li/DVP) [40,41]. In both studies, a 12- to 36-week open-label stabilization phase was followed by a randomized treatment phase of up to 104 weeks. The primary efficacy endpoint for both studies was the time to recurrence of any mood event (mixed, mania or depression). In one study, quetiapine in combination with Li/DVP was found to be significantly more effective than placebo and Li/DVP in preventing the recurrence of any mood event and in particular a depressive episode [40]. In the other study, quetiapine in combination with Li/DVP was also significantly more effective than placebo and Li/DVP in preventing both the recurrence of any mood event and a depression event [41].
Olanzapine and olanzapine/fluoxetine combination The efficacy of olanzapine/fluoxetine combination (OFC) in comparison with lamotrigine was demonstrated in a seven-week, randomized, double-blind, parallel-group study in patients with bipolar I depression. OFC was associated with significantly greater improvement in CGI-S from baseline to Week 7 compared with lamotrigine
Pharmacological Treatment of Bipolar Depression
(1.43, OFC; 1.18, lamotrigine; p < 0.01). Furthermore, patients had statistically significantly greater improvement in MADRS total score with OFC than lamotrigine at Week 7 (14.91, OFC; 12.92, lamotrigine; p < 0.01) [42]. Tohen et al. [43] carried out a sub-analysis of data from an 8-week, placebo-controlled, randomized study that investigated the efficacy of olanzapine and OFC in patients with bipolar I depression. The aim of the analysis was to compare rates of treatment-emergent mania (defined a priori as YMRS score <15 at baseline and 15 at any subsequent visit) in patients receiving olanzapine or placebo. During the eight-week study, olanzapine and OFC were not associated with a greater risk of treatment-emergent mania compared with placebo [44]. To date, the long-term use of olanzapine or OFC in patients with bipolar depression has not been evaluated in placebo-controlled trials. The only long-term, controlled data for olanzapine plus fluoxetine in bipolar depression derive from a study evaluating the efficacy of OFC. A 25week, randomized, double-blind study compared the efficacy of OFC and lamotrigine in patients with bipolar I depression ([45]; see above). OFC was associated with significantly greater improvements in CGI-S and MADRS total scores than lamotrigine from baseline to Week 25. It is important to note the increased risk for the development of the metabolic syndrome, diabetes and cardiovascular disease incumbent in long-term treatment with olanzapine and other atypical antipsychotics. This is an important consideration in patients with bipolar disorder, a patient population already vulnerable to these major causes of morbidity and mortality.
Antidepressants There is little evidence to support the use of antidepressant monotherapy in patients with bipolar disorder, despite their common use [14]. In support of this, results from the McElroy study that investigated the efficacy of quetiapine and paroxetine for the acute treatment of bipolar depression showed that paroxetine did not significantly improve MADRS total scores at Week 8 from baseline in patients with bipolar depression (14.9, paroxetine; 13.4, placebo; p ¼ 0.313) [39], whereas quetiapine did separate from placebo as discussed above. The adjunctive use of antidepressants is a common approach to treatment of bipolar depression. A systematic review and meta-analysis of five acute, randomized, double-blind controlled trials (n ¼ 779) compared the use of antidepressants or placebo as adjuncts to a mood-stabilizer in patients with bipolar disorder and a current depressive or mixed episode. The Gijsman et al. concluded that antidepressants were a more effective adjunctive therapy than placebo, and moreover, were not associated with a higher incidence of switching to mania [46].
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In some contrast to the Gijsman analysis, the long-term use of adjunctive antidepressants in patients with bipolar I or II depression was evaluated in a large, 26-week, doubleblind, randomized, placebo-controlled study (STEP-BD). The primary outcome was durable recovery, defined as euthymia for at least 8 consecutive weeks. Adjunctive treatment with paroxetine or bupropion did not significantly increase the rate of durable recovery compared with the use of mood-stabilizers alone (23.5 and 27.3%, respectively; p ¼ 0.4). Notably, the rate of treatment-emergent affective switch in the two groups was not significantly different [47].
Imipramine and paroxetine A double-blind, randomized, placebo-controlled study investigated the use of adjunctive antidepressants in patients with bipolar I depression. Nemeroff et al. investigated the efficacy of paroxetine, imipramine or placebo in 117 outpatients stabilized on lithium therapy. Patients were randomized to receive paroxetine (mean dose, 32.6 mg/day), imipramine (mean dose, 166.7 mg/day) or placebo for 10 weeks [48]. Mean changes in HAM-D and CGI-S total score from baseline to Week 10 in the paroxetine and imipramine groups were no different to those in the placebo group. However, in the patients with subtherapeutic plasma lithium concentrations, paroxetine, but not imipramine, was effective. Imipramine, but not paroxetine, was associated with an increased switch rate into mania. Interestingly, in a smaller previous study of 27 patients with bipolar depression treated with lithium or valproate, paroxetine augmentation was equally effective to treatment with the two mood stabilizers [49]. The long-term efficacy of imipramine and lithium for the prevention of affective episodes in patients with bipolar disorder was investigated in a two-year, randomized, placebo-controlled study [20]. Imipramine had no effect on the number of depressive episodes experienced compared with placebo. Furthermore, there was no evidence of a protective effect against episodes of mania with imipramine, with 83, 67 and 12% of patients experiencing a manic episode during the last 20 months of the study with placebo, imipramine and lithium, respectively.
Fluoxetine Evidence for the use of fluoxetine as monotherapy for the acute treatment of bipolar depression is provided by the results of a 6-week, double-blind study that compared the efficacy of fluoxetine and imipramine with placebo [50]. Patients with bipolar depression (n ¼ 89) were randomized to fluoxetine (20–80 mg/day, n ¼ 30), imipramine (75–300 mg/ day, n ¼ 30) or placebo (n ¼ 29) for six weeks, with 22 patients receiving concomitant lithium during the study. Fluoxetine and imipramine were both associated with significant
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improvement in MADRS total score from baseline to Week 6 (p < 0.05 for both treatments) compared with placebo [50]. Furthermore, fluoxetine significantly improved CGI-S score at Week 6 compared with imipramine (p < 0.05).
Sertraline, bupropion and venlafaxine The efficacy of sertraline, bupropion and venlafaxine as adjunctive treatment to mood-stabilizers was investigated in a 10-week, randomized, flexible-dose trial in patients with bipolar I depression. All three antidepressant treatments were associated with comparable levels of acute response (49, 51, and 53% for bupropion, venlafaxine, and sertraline, respectively; defined as a 50% improvement in Inventory of Depressive Symptomatology (IDS) score or a decrease in Clinical Global Impression-Bipolar Disorder [CGI-BP] score of 2) and remission (34, 36, and 41% for venlafaxine, sertraline and bupropion, respectively; defined as either an IDS score 12 or CGI-BP score of 1); however, venlafaxine was associated with a significantly increased risk of switching to hypomania or mania compared with both sertraline and bupropion (29, 9, and 10%, respectively; p ¼ 0.01 venlafaxine vs. sertraline; p < 0.01 venlafaxine vs. bupropion) [51]. However, given that there was no placebo group in this study, it is not possible to determine if switch rates in the sertraline and bupropion groups were similar to what might be expected over the natural course of the disorder. Vieta et al. [52] randomized patients with bipolar I (n ¼ 44) or bipolar II (n ¼ 16) depression in a 6-week trial to augmentation with paroxetine (mean dose 32 mg/day) or venlafaxine (mean dose 179 mg/ day). The response rates were equivalent (43–48%) but the switch rate into mania was 4-fold greater in the venlafaxine group. Open studies suggested both efficacy and low switch rates with bupropion. Sachs et al. [53] reported that bupropion and imipramine exhibited equal efficacy to imipramine in the treatment of bipolar depression with low switch rates with the former agent, and Fogelson et al. [54] noted a greater than 50% switch rate with this agent.
Monamine oxidase inhibitors (MAOIs) Because the phenomenology of bipolar depression closely resembles that of an atypical depression, for example, hypersomnia, fatigue and reverse diurnal mood variation, and because MAOIs are usually effective in the treatment of atypical depression, many clinicians frequently prescribe MAOIs for the treatment refractory bipolar depression. Himmelhoch et al. [55,56] and Thase et al. [57] demonstrated the superiority of tranylcypromine over imipramine in the treatment of bipolar depression. Clearly, more double-blind controlled studies are needed in this area.
Modafinil Evidence from a recently published double-blind, placebocontrolled, randomized study showed that adjunctive modafinil is potentially an efficacious treatment for patients with bipolar I depression who respond inadequately to monotherapy with a mood stabilizer [58]. In this study, patients with bipolar I (n ¼ 64) or bipolar II (n ¼ 21) depression were randomized to receive modafinil (200 mg/day) or placebo in combination with a mood stabilizer for 6 weeks. At study endpoint, significant reductions in IDS score (p ¼ 0.047, effect size 0.47) and the CGI-BP depression severity item (p ¼ 0.009, effect size 0.63) were seen in the modafinil group compared with placebo. Furthermore, response (>50% improvement in IDS total score) and remission (final IDS total score <12) rates were significantly higher in the modafinil group compared with placebo (43.9 vs. 22.7% [p < 0.05] and 39 vs. 18%, [p ¼ 0.033], respectively) [58].
Pramipexole A 6-week, randomized, placebo-controlled trial investigated the efficacy of pramipexole monotherapy (up to 5 mg/ day) in patients with treatment-resistant bipolar I (n ¼ 15) and bipolar II depression (n ¼ 7). The primary endpoint was response to treatment, defined as >50% reduction in HAMD total score. Overall, 67% of patients who received pramipexole responded to treatment compared with 20% of patients who received placebo (p < 0.05). The change in mean HAM-D scores was greater (p ¼ 0.05) for pramipexole (48%) compared with placebo (21%). Pramipexole also significantly improved mean CGI-S score from baseline to Week 6 compared with placebo (2.4 and 0.30, respectively; p ¼ 0.01) [59].
Mifepristone A recent Cochrane systematic review has found some evidence supporting the use of glucocorticoid antagonists in the treatment of mood disorders [60]. Of these, the glucocorticoid receptor antagonist Mifepristone has the best, albeit extremely preliminary, evidence in bipolar depression. Improvements in mood and neurocognitive function were reported in a small proof of concept study in bipolar depression [61], effects that were not replicated in a similar study in schizophrenia [62]. A larger study is currently underway. Mifepristone has relatively persistent effects on cortisol levels in these patients, which raises the possibility of similarly persistent beneficial effects on mood and cognition [63].
Ethyl-eicosapentaenoic acid The efficacy of adjunctive ethyl-eicosapentaenoic acid (EPA) [1 and 2 g/day] was evaluated in a 12-week randomized,
Pharmacological Treatment of Bipolar Depression
double-blind, placebo-controlled study in 65 patients with bipolar I depression. Both doses of adjunctive EPA (combined data) significantly improved both HAM-D (3.3 points, 95% CI ¼ 6.1 to 0.2; p < 0.05; effect size 0.34) and CGI (0.79 points, 95% CI ¼ 1.27 to 0.25; p < 0.05) scores compared with placebo from baseline to the end of the study [64].
Aripiprazole Aripiprazole is classified as an atypical antipsychotic drug because of its efficacy as a monotherapy in schizophrenia and bipolar mania and lack of extrapyramidal side effects. It possesses relatively novel pharmacological properties, including partial agonism at dopamine D2/D3 receptor as well as full agonism at 5HTIA receptors. An analysis of two, identically designed, 8-week, randomized, double-blind, placebo-controlled studies in patients with bipolar I depression found that aripiprazole (flexible dose 5–30 mg/day) demonstrated a rapid onset of action (from Week 1) with significant reductions in MADRS total score compared with placebo. However, this effect was lost in the final two weeks of the trials [65]. Subsequent analysis of data from the two trials suggests that the aripiprazole doses used were not adequately determined in advance leading to high patient withdrawal, which likely contributed to the loss of statistical significance towards the end of the trials [65]. Aripiprazole has demonstrable efficacy as an adjunctive treatment to antidepressants in unipolar depression [66,67].
Pharmacological treatment of bipolar II depression In contrast to the considerable clinical data available regarding potential treatments for bipolar I depression, there is a relative dearth of clinical evidence from studies in patients with bipolar II depression [68]. This lack of clinical evidence may be a consequence of bipolar I disorder being regarded as a more severe form of illness than bipolar II depression, particularly regarding length and severity of individual depressive episodes [69–71]; however, this view may be ill-founded as patients with bipolar II disorder experience a greater frequency of episodes and a longer overall time spent in depression [70,72]. It may also be related to the lack of recognition of this subtype in the community by both patients and clinicians.
Quetiapine The efficacy of quetiapine monotherapy (300 and 600 mg/ day) for the acute treatment of patients with bipolar II depression was evaluated as part of two 8-week, randomized, double-blind, placebo-controlled studies [37,38]. In the
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bipolar II subgroup in the first study (n ¼ 182), quetiapine monotherapy was associated with a statistically significant improvement in mean MADRS total score at most assessments during the study, compared with placebo. However, the difference in MADRS total score was not significant at final assessment (Week 8) with either dose of quetiapine compared with placebo. Effect sizes were 0.39 for quetiapine 600 mg/day and 0.28 for quetiapine 300 mg/day [37]. In the second study, a significant improvement in mean MADRS total score compared with placebo was sustained from Week 1 to final assessment with quetiapine 300 mg/ day (p 0.05) and from Week 3 to final assessment with quetiapine 600 mg/day (p 0.05) in the bipolar II subgroup (n ¼ 152) [38]. A post hoc analysis of pooled data from both studies of bipolar II depression has recently been published. Quetiapine monotherapy significantly improved mean MADRS total score from the first assessment (Week 1) and at each subsequent assessment [73]. At Week 8, mean change from baseline in MADRS total score was 17.1 for quetiapine 300 mg/day (p < 0.01) and 17.9 for quetiapine 600 mg/day (p < 0.01) compared with 13.3 for placebo. Effect sizes were calculated as 0.54 for quetiapine 600 mg/day and 0.45 for quetiapine 300 mg/day. Additional data regarding the use of quetiapine for the acute treatment of bipolar II depression derive from a randomized, placebo-controlled study that evaluated the acute (eight weeks) use of quetiapine monotherapy (300 mg/day and 600 mg/day) in this patient group (n ¼ 252) [39]. At the end of the study the investigators reported a mean change in MADRS total score of 16.5 points for quetiapine 300 mg/ day, 16.3 points for quetiapine 600 mg/day, and 11.53 points for placebo. Differences in mean MADRS total score were significant for quetiapine 300 mg/day vs. placebo (95% CI ¼ 7.93 to 1.67; p < 0.05) and for quetiapine 600 mg/day vs. placebo (95% CI ¼ 8.10 to 1.85; p < 0.05). Evidence for the long-term use of quetiapine monotherapy in the treatment of bipolar II depression derives from the 26–52 week continuation phases of the Young et al. [18] and McElroy et al. [39] studies. Quetiapine significantly increased the time to recurrence of depression compared with placebo during the continuation phases of both studies in patients with bipolar I or bipolar II depression.
Pramipexole A very small six-week, double-blind, placebo-controlled study investigated the efficacy of pramipexole (up to 4.5 mg/day) in patients with bipolar II depression (n ¼ 10). The results of the study revealed a significant treatment effect with pramipexole, as shown by an improvement in total MADRS compared with placebo at Week 6 (p ¼ 0.03, 95% CI ¼ 0.104 to 2.27). Furthermore, response (defined as a >50% decrease in MADRS score from baseline) was
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experienced by 60% of patients in the pramipexole group compared with 9% in the placebo group (p ¼ 0.02) [74].
Antidepressants Another very small, nine-month, randomized, placebo-controlled, cross-over study reported significant improvement in depression severity, measured by HAM-D score and percentage of days impaired (effect sizes 1.07 and 0.85, respectively; p < 0.05), in patients with bipolar II disorder (n ¼ 10) receiving selective serotonin reuptake inhibitor (SSRI) monotherapy compared with placebo [75]. However, this study needs to be replicated in a larger sample before any conclusions regarding the efficacy of SSRIs in patients with bipolar II depression can be drawn.
Rapid cyclers Divalproex and lithium A 20-month, double-blind, parallel-group study, comparing the efficacy of divalproex and lithium for the long-term treatment of rapid-cycling bipolar disorder, has been conducted [76]. Following a 6-month, acute stabilization phase, during which patients received open-label lithium and divalproex in combination, 60 patients were randomized to receive lithium monotherapy (mean dose 1359 mg/day) or divalproex monotherapy (mean dose 1571 mg/day) for up to 20 months. No statistically significant difference between the lithium and divalproex groups was observed for the primary efficacy measure of time to treatment for a mood episode.
Lamotrigine The use of lamotrigine as a maintenance treatment in rapid-cycling bipolar disorder was investigated in a doubleblind, placebo-controlled, prophylaxis study [77]. Patients (n ¼ 324) received lamotrigine or placebo as monotherapy for six months following a preliminary, open-label stabilization phase. The primary efficacy measure was time to additional pharmacotherapy for emerging mood symptoms. No significant difference between the lamotrigine and placebo groups with respect to the primary measure was observed. However, lamotrigine was associated with a significantly greater time to premature discontinuation compared with placebo (p < 0.05). Furthermore, significantly more patients receiving lamotrigine (41%) were stable without relapse for the duration of the study compared with placebo (26%; p < 0.05) [77].
Quetiapine Evidence for the use of quetiapine monotherapy in patients with a rapid cycling disease course has been provided by a
sub-analysis of an eight-week, randomized, double-blind, placebo-controlled study [37]. Quetiapine (600 and 300 mg/ day) provided significantly greater mean reductions from baseline to Week 8 in MADRS total score than placebo (p < 0.001 for both doses) in patients with a rapid cycling disease course [78].
Antidepressants A 10-week, randomized, flexible-dose study evaluating sertraline, bupropion and venlafaxine as adjuncts to mood stabilizers investigated the impact of a patients rapid cycling status on the relative risk of switching into mania or hypomania [51]. In patients without rapid cycling, the risk of switching was no different with the three study medications (p ¼ 0.55); however, in patients with a rapid cycling disease course, bupropion was associated with a significantly lower risk of switching than venlafaxine (p < 0.01).
Miscellaneous High doses of thyroxine have been shown to have efficacy in rapid-cycling bipolar disorder [79]. Open studies suggest the efficacy of clozapine in treatment–refractory rapid cyclers [80,81].
Clinical recommendations From the preceding discussion it is clear that a number of key principles emerge to guide the clinician, although as ever in psychiatry we must retain the right for the individual clinician to exercise their judgement as to the best practice for any particular scenario. However, it is clear that depression is a frequent and damaging part of the lives of patients with bipolar disorder. Clinicians must be aware of this and examine all patients for depression most carefully. Furthermore, awareness of bipolar depression should be highlighted in educational materials both for the patient, family members and health care professionals. A number of evidence based treatments are now available and treatments with good supporting evidence should be prioritized over those with less, or in some cases no, supporting research evidence. The evidence base will be briefly discussed below; however, it is clearly in the interests of all (patients, families and clinicians) to support further work to strengthen the research upon which good clinical practice is based.
Conclusions Bipolar depression is a common and disabling condition with highly significant attendant costs to the patient, their families and society. Increasing evidence is available to support the efficacy of certain pharmacological agents for this mood disorder. Of these, lithium is the most venerable.
Pharmacological Treatment of Bipolar Depression
However, the evidence supporting lithiums use (at least as monotherapy) is not strong and important negative studies have recently been reported. Although antidepressant drugs have long been used in bipolar depression, the evidence of their efficacy is not as robust as we would like, and some recent studies have been negative. However, recent large studies do support the use of some drugs, including lamotrigine and quetiapine. Much further research is needed. Larger trials could examine the efficacy of older agents, such as valproate, as well as newer agents, for example mifepristone and proof of concept studies may usher in newer agents yet. The requirement for efficacious drugs for bipolar depression is unlikely to lessen in the near future and clinicians who treat this disorder should be aware of the current evidence in order to facilitate the best clinical practice.
Financial disclosures Dr. Young has received honoraria from pharmaceutical companies, including AstraZeneca, for lecturing on this topic and has also received grant support from AstraZeneca. Dr Nemeroff serves on the Scientific Advisory Board for the American Foundation for Suicide Prevention; AstraZeneca; NARSAD, PharmaNeuroboost and CeNeRx. He serves on the Board of Directors of American Foundation for Suicide Prevention; George West Mental Health Foundation; NovaDel Pharma, Mt Cook Pharma, Inc. He owns equity or is stock holder in Corcept; Revaax; NovaDel Pharma; CeNeRx, PharmaNeuroboost, Mt Cook Pharma. He is inventor on the following patents: method and devices for transdermal delivery of lithium (US 6,375,990 B1) and method to estimate serotonin and norepinephrine transporter occupancy after drug treatment using patient or animal serum (provisional filing April, 2001).
References 1. Merikangas, K.R., Akiskal, H.S., Angst, J. et al. (2007) Lifetime and 12-month prevalence of bipolar spectrum disorder in the national comorbidity survey replication. Arch. Gen. Psychiatry, 64, 543–552. 2. Perala, J., Suvisaari, J., Saarni, S.I. et al. (2007) Lifetime prevalence of psychotic and bipolar I disorders in a general population. Arch. Gen. Psychiatry, 64, 19–28. 3. Prince, M., Patel, V., Saxena, S. et al. (2007) No health without mental health. Lancet, 370, 859–877. 4. Post, R.M., Denicoff, K.D., Leverich, G.S. et al. (2003) Morbidity in 258 bipolar outpatients followed for 1 year with daily prospective ratings on the NIMH life chart method. J. Clin. Psychiatry, 64, 680–690. 5. Judd, L.L., Akiskal, H.S., Schettler, P.J. et al. (2005) Psychosocial disability in the course of bipolar I and II disorders: a prospective, comparative, longitudinal study. Arch. Gen. Psychiatry, 62, 1322–1330.
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6. Michalak, E.E., Murray, G., Young, A.H. and Lam, R.W. (2008) Burden of bipolar depression: impact of disorder and medications on quality of life. CNS Drugs, 22 (5), 389–406. 7. Judd, L.L., Akiskal, H.S., Schettler, P.J. et al. (2002) The longterm natural history of the weekly symptomatic status of bipolar I disorder. Arch. Gen. Psychiatry, 59, 530–537. 8. Kupka, R.W., Altshuler, L.L., Nolen, W.A. et al. (2007) Three times more days depressed than manic or hypomanic in both bipolar I and bipolar II disorder. Bipolar Disord., 9, 531–535. 9. Angst, J., Angst, F., Gerber-Werder, R. and Gamma, A. (2005) Suicide in 406 mood-disorder patients with and without long-term medication: a 40 to 44 years follow-up. Arch. Suicide Res., 9 (3), 279–300. 10. Vieta, E., Colom, F., Corbella, B. et al. (2001) Clinical correlates of psychiatric comorbidity in bipolar I patients. Bipolar Disord., 3, 253–258. 11. Keller, M.B. (2006) Prevalence and impact of comorbid anxiety and bipolar disorder. J. Clin. Psychiatry, 67 (Suppl. 1), 5–7. 12. Perlis, R.H. (2005) Misdiagnosis of bipolar disorder. Am. J. Manag. Care, 11, S271–S274. 13. Pollack, L.E., Cramer, R.D. and Varner, R.V. (2000) Psychosocial functioning of people with substance abuse and bipolar disorders. Subst. Abus., 21, 193–203. 14. Hirschfeld, R.M., Lewis, L. and Vornik, L.A. (2003) Perceptions and impact of bipolar disorder: how far have we really come? Results of the national depressive and manic-depressive association 2000 survey of individuals with bipolar disorder. J. Clin. Psychiatry, 64, 161–174. 15. Calabrese, J.R., Kasper, S., Johnson, G. et al. (2004) International Consensus Group on bipolar I depression treatment guidelines. J. Clin. Psychiatry, 65, 569–579. 16. Calabrese, J.R., Kasper, S., Johnson, G. et al. (2010) International Consensus Group on bipolar depression treatment guidelines (Updated and Revised). J. Clin. Psychiatry (In Press). 17. Srisurapanont, M., Yatham, L.N. and Zis, A.P. (1995) Treatment of acute bipolar depression: a review of the literature. Can. J. Psychiatry, 40, 533–544. 18. Young, A.H., McElroy, S., Chang, W. et al. (2008) A doubleblind, placebo-controlled study with acute and continuation phase of quetiapine in adults with bipolar depression (EMBOLDEN I) Poster presented at the International Society for Bipolar Disorders, Delhi and Agra, India, 27–30 January, 2008. 19. Prien, R.F., Klett, C.J. and Caffey, E.M. Jr (1974) Lithium prophylaxis in recurrent affective illness. Am. J. Psychiatry, 131, 198–203. 20. Prien, R.F., Klett, C.J. and Caffey, E.M. Jr (1973) Lithium carbonate and imipramine in prevention of affective episodes. A comparison in recurrent affective illness. Arch. Gen. Psychiatry, 29, 420–425. 21. Geddes, J.R., Burgess, S., Hawton, K. et al. (2004) Long-term lithium therapy for bipolar disorder: systematic review and meta-analysis of randomized controlled trials. Am. J. Psychiatry, 161, 217–222. 22. Smith, L.A., Cornelius, V., Warnock, A. et al. (2007) Effectiveness of mood stabilizers and antipsychotics in the maintenance phase of bipolar disorder: a systematic review of randomized controlled trials. Bipolar Disord., 9, 394–412.
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23. Baldessarini, R.J. and Tondo, L. (2000) Does lithium treatment still work? Evidence of stable responses over three decades. Arch. Gen. Psychiatry, 57, 187–190. 24. Calabrese, J.R., Bowden, C.L., Sachs, G.S. et al. (1999) A double-blind placebo-controlled study of lamotrigine monotherapy in outpatients with bipolar I depression. J. Clin. Psychiatry, 60, 79–88. 25. Calabrese, J.R., Huffman, R.F., White, R.L. et al. (2008) Lamotrigine in the acute treatment of bipolar depression: results of five double-blind, placebo-controlled clinical trials. Bipolar Disord., 10, 323–333. 26. Geddes, J., Huffman, R.F., Paksa, W. et al. (2007) Lamotrigine for acute treatment of bipolar depression: individual patient data meta-analysis of 5 randomised, placebo-controlled trials. Bipolar Disord., 9 (s1), 42. 27. Geddes, J., Calabrese, J.R. and Goodwin, G.M. (2009) Lamotrigine for treatment of bipolar depression: independent meta-analysis and meta-regression of individual patient data from five randomised trials. Br. J. Psychiatry., 194, 4–9. 28. Bowden, C.L., Calabrese, J.R., Sachs, G. et al. (2003) A placebocontrolled 18-month trial of lamotrigine and lithium maintenance treatment in recently manic or hypomanic patients with bipolar I disorder. Arch. Gen. Psychiatry, 60, 392–400. 29. Calabrese, J.R., Bowden, C.L., Sachs, G.S. et al. (2003) A placebo-controlled 18-month trial of lamotrigine and lithium maintenance treatment in recently depressed patients with bipolar I disorder. J. Clin. Psychiatry, 64, 1013–1024. 30. Goodwin, G.M., Bowden, C.L., Calabrese, J.R. et al. (2004) A pooled analysis of 2 placebo-controlled 18-month trials of lamotrigine and lithium maintenance in bipolar I disorder. J. Clin. Psychiatry, 65, 432–441. 31. Nierenberg, A.A., Ostacher, M.J., Calabrese, J.R. et al. (2006) Treatment-resistant bipolar depression: a STEP-BD equipoise randomized effectiveness trial of antidepressant augmentation with lamotrigine, inositol, or risperidone. Am. J. Psychiatry, 163, 210–216. 32. van der Loos, M., Nolen, W. and Vieta, E.,on behalf of all members of the LamLit Study Group (2006) Lamotrigine as add-on to lithium in bipolar depression. Poster P268 presented at the Fifth European Stanley Conference on Bipolar Disorder, Barcelona, Spain, October 5–7, 2006. 33. Licht, R.W. (2008) Lamotrigine versus lithium in prophylaxis of bipolar disorder: a randomised study mimicking clinical practice. Bipolar Disord., 10 (Suppl. 1), 27. 34. Davis, L.L., Bartolucci, A. and Petty, F. (2005) Divalproex in the treatment of bipolar depression: a placebo-controlled study. J. Affect. Disord., 85, 259–266. 35. Ghaemi, S.N., Gilmer, W.S., Goldberg, J.F. et al. (2007) Divalproex in the treatment of acute bipolar depression: a preliminary double-blind, randomized, placebo-controlled pilot study. J. Clin. Psychiatry, 68, 1840–1844. 36. Post, R.M., Uhde, T.W., Roy-Byrne, P.P. and Joffe, R.T. (1986) Antidepressant effects of carbamazepine. Am. J. Psychiatry, 143, 29–34. 37. Calabrese, J.R., Keck, P.E. Jr, Macfadden, W. et al. (2005) A randomized, double-blind, placebo-controlled trial of quetiapine in the treatment of bipolar I or II depression. Am. J. Psychiatry, 162, 1351–1360.
38. Thase, M.E., Macfadden, W., Weisler, R.H. et al. (2006) Efficacy of quetiapine monotherapy in bipolar I and II depression: a double-blind, placebo-controlled study (the BOLDER II study). J. Clin. Psychopharmacol., 26, 600–609. 39. McElroy, S., Young, A.H., Carlsson, A. et al. (2008) Doubleblind, randomized, placebo-controlled study of quetiapine and paroxetine in adults with bipolar depression (EMBOLDEN II). Poster presented at the International Society for Bipolar Disorders, Delhi and Agra, India, 27–30 January, 2008. 40. Suppes, T., Liu, S., Paulsson, B. and Brecher, M. (2007) Maintenance treatment in bipolar I disorder with quetiapine concomitant with lithium or divalproex: a North American placebo-controlled, randomized multicenter trial. Poster presented at the 46th Annual Meeting of the American College of Neuropsychopharmacology, Boca Raton, Florida, USA, 9–13 December, 2007. 41. Vieta, E., Eggens, I., Persson, I. et al. (2007) Efficacy and safety of quetiapine in combination with lithium or divalproex as maintenance treatment for bipolar I disorder. Poster presented at the 20th European College of Neuropsychopharmacology Congress, Vienna, Austria, 13–17 October, 2007. 42. Brown, E.B., McElroy, S.L., Keck, P.E. Jr et al. (2006) A 7-week, randomized, double-blind trial of olanzapine/fluoxetine combination versus lamotrigine in the treatment of bipolar I depression. J. Clin. Psychiatry, 67, 1025–1033. 43. Tohen, M., Sanger, T.M., McElroy, S.L. et al. (1999) Olanzapine versus placebo in the treatment of acute mania. Am. J. Psychiatry, 156, 702–709. 44. Keck, P.E. Jr, Corya, S.A., Altshuler, L.L. et al. (2005) Analyses of treatment-emergent mania with olanzapine/fluoxetine combination in the treatment of bipolar depression. J. Clin. Psychiatry, 66, 611–616. 45. Brown, E.B., Dunner, D.L., Adams, D.H. et al. (2006) Olanzapine/fluoxetine combination versus lamotrigine in the longterm treatment of bipolar I depression. Poster presented at the 2nd Biennial Conference of the International Society for Bipolar Disorders, Edinburgh, UK, 2–4 August, 2006. 46. Gijsman, H.J., Geddes, J.R., Rendell, J.M. et al. (2004) Antidepressants for bipolar depression: a systematic review of randomized, controlled trials. Am. J. Psychiatry, 161, 1537–1547. 47. Sachs, G.S., Nierenberg, A., Calabrese, J.R. et al. (2007) Effectiveness of adjunctive antidepressant treatment for bipolar depression. N. Engl. J. Med., 356, 1711–1722. 48. Nemeroff, C.B., Evans, D.L., Gyulai, L. et al. (2001) Doubleblind, placebo-controlled comparison of imipramine and paroxetine in the treatment of bipolar depression. Am. J. Psychiatry, 158, 906–912. 49. Young, L.T., Joffe, R.T., Robb, J.C. et al. (2000) Double-blind comparison of addition of a second mood stabilizer versus an antidepressant to an initial mood stabilizer for treatment of patients with bipolar depression. Am. J. Psychiatry, 157, 124–126. 50. Cohn, J.B., Collins, G., Ashbrook, E. and Wernicke, J.F. (1989) A comparison of fluoxetine imipramine and placebo in patients with bipolar depressive disorder. Int. Clin. Psychopharmacol., 4, 313–322. 51. Post, R.M., Altshuler, L.L., Leverich, G.S. et al. (2006) Mood switch in bipolar depression: comparison of adjunctive venlafaxine, bupropion and sertraline. Br. J. Psychiatry, 189, 124–131.
Pharmacological Treatment of Bipolar Depression 52. Vieta, E., Martinez-Ar an, A., Goikdea, J.M. et al. (2002) A randomized trial comparing paroxetine and venlafaxine in the treatment of bipolar depressed patients taking mood stabilizers. J. Clin. Psychiatry, 63 (6), 508–512. 53. Sachs, G.S., Lafer, B., Stoll, A.L. et al. (1994) A double-blind trial of bupropion versus desipramine for bipolar depression. J. Clin. Psychiatry, 55 (9), 391–393. 54. Fogelson, D.L., Bystritsky, A. and Pasnau, R. (1992) Bupropion in the treatment of bipolar disorders: the same old story? J. Clin. Psychiatry, 53 (12), 443–446. 55. Himmelhoch, J.M., Fuchs, C.Z. and Symons, B.J. (1982) A double-blind study of tranylcypromine treatment of major anergic depression. J. Nerv. Ment. Dis., 170 (10), 628–634. 56. Himmelhoch, J.M., Thase, M.E., Mallinger, A.G. and Houck, P. (1991) Tranylcypromine versus imipramine in anergic bipolar depression. Am. J. Psychiatry, 148 (7), 910–916. 57. Thase, M.E., Mallinger, A.G., McKnight, D. and Himmelhoch, J.M. (1992) Treatment of imipramine-resistant recurrent depression. IV: A double-blind crossover study of tranylcypromine for anergic bipolar depression. Am. J. Psychiatry, 149 (2), 195–198. 58. Frye, M.A., Grunze, H., Suppes, T. et al. (2007) A placebocontrolled evaluation of adjunctive modafinil in the treatment of bipolar depression. Am. J. Psychiatry, 164, 1242–1249. 59. Goldberg, J.F., Burdick, K.E. and Endick, C.J. (2004) Preliminary randomized, double-blind, placebo-controlled trial of pramipexole added to mood stabilizers for treatment-resistant bipolar depression. Am. J. Psychiatry, 161, 564–566. 60. Gallagher, P., Malik, N., Newham, J. et al. (2008) Antiglucocorticoid treatments for mood disorders. Cochrane Database Syst. Rev (1), CD005168. 61. Young, A.H., Gallagher, P., Watson, S. et al. (2004) Improvements in neurocognitive function and mood following adjunctive treatment with mifepristone (RU-486) in bipolar disorder. Neuropsychopharmcology, 29 (8), 1538–1545. 62. Gallagher, P., Watson, S., Smith, M.S. et al. (2005) Effects of adjunctive mifepristone (RU-486) administration on neurocognitive function and symptoms in schizophrenia. Biol. Psychiatry, 57 (2), 155–161. 63. Gallagher, P., Watson, S., Elizabeth Dye, C. et al. (2008) Persistent effects of mifepristone (RU-486) on cortisol levels in bipolar disorder and schizophrenia. J. Psychiatr. Res., 42 (12), 1037–1041. 64. Frangou, S., Lewis, M. and McCrone, P. (2006) Efficacy of ethyl-eicosapentaenoic acid in bipolar depression: randomised double-blind placebo-controlled study. Br. J. Psychiatry, 188, 46–50. 65. Thase, M.E., Jonas, A., Khan, A. et al. (2008) Aripiprazole monotherapy in nonpsychotic bipolar I depression: results of 2 randomized, placebo-controlled studies. J. Clin. Psychopharmacol., 28, 13–20. 66. Simon, J.S. and Nemeroff, C.B. (2005) Ariprazole augmentation of antidepressants for the treatment of partially responding and non-responding patients with major depressive disorder. J. Clin. Psychiat., 66, 1216–1220.
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67. Marcus, R.N., McQuade, R.D., Carson, W.H. et al. (2008) The efficacy and safety of aripiprazole as adjunctive therapy in major depressive disorder: a second multicenter, randomized, double-blind, placebo-controlled study. J. Clin. Psychopharmacol., 28 (2), 156–165. 68. Vieta, E. and Suppes, T. (2008) Bipolar II disorder: arguments for and against a distinct diagnostic entity. Bipolar Disord., 10, 163–178. 69. Coryell, W., Endicott, J., Andreasen, N. and Keller, M. (1985) Bipolar I, bipolar II, and nonbipolar major depression among the relatives of affectively ill probands. Am. J. Psychiatry, 142, 817–821. 70. Vieta, E., Gasto, C., Otero, A. et al. (1997) Differential features between bipolar I and bipolar II disorder. Compr. Psychiatry, 38, 98–101. 71. Benazzi, F. (1999) A comparison of the age of onset of bipolar I and bipolar II outpatients. J. Affect. Disord., 54, 249–253. 72. Judd, L.L., Akiskal, H.S., Schettler, P.J. et al. (2003) The comparative clinical phenotype and long term longitudinal episode course of bipolar I and II: a clinical spectrum or distinct disorders? J. Affect. Disord., 73, 19–32. 73. Suppes, T., Hirschfeld, R.M., Vieta, E. et al. (2008) Quetiapine for the treatment of bipolar II depression: Analysis of data from two randomized, double-blind, placebo-controlled studies. World J. Biol. Psychiatry, 9, 198–211. 74. Zarate, C.A. Jr, Payne, J.L., Singh, J. et al. (2004) Pramipexole for bipolar II depression: a placebo-controlled proof of concept study. Biol. Psychiatry, 56, 54–60. 75. Parker, G., Tully, L., Olley, A. and Hadzi-Pavlovic, D. (2006) SSRIs as mood stabilizers for Bipolar II Disorder? A proof of concept study. J. Affect. Disord., 92, 205–214. 76. Calabrese, J.R., Shelton, M.D., Rapport, D.J. et al. (2005) A 20month, double-blind, maintenance trial of lithium versus divalproex in rapid-cycling bipolar disorder. Am. J. Psychiatry, 162, 2152–2161. 77. Calabrese, J.R., Suppes, T., Bowden, C.L. et al. (2000) A double-blind, placebo-controlled, prophylaxis study of lamotrigine in rapid-cycling bipolar disorder. J. Clin. Psychiatry, 61, 841–850. 78. Vieta, E., Calabrese, J.R., Goikolea, J.M. et al. (2007) Quetiapine monotherapy in the treatment of patients with bipolar I or II depression and a rapid-cycling disease course: a randomized, double-blind, placebo-controlled study. Bipolar Disord., 9, 413–425. 79. Bauer, M.S. and Whybrow, P.C. (1990) Rapid cycling bipolar affective disorder. II. Treatment of refractory rapid cycling with high-dose levothyroxine: a preliminary study. Arch. Gen. Psychiatry, 47 (5), 435–440. 80. McElroy, S.L., Dessain, E.C., Pope, H.G. Jr et al. (1991) Clozapine in the treatment of psychotic mood disorders, schizoaffective disorder, and schizophrenia. J. Clin. Psychiatry, 52 (10), 411–414. 81. Suppes, T., McElroy, S.L., Gilbert, J. et al. (1992) Clozapine in the treatment of dyxphoric mania. Biol. Psychiatry, 32 (3), 270–280.
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Practical Pharmacological Maintenance Treatment of Bipolar Disorder Alan C. Swann Department of Psychiatry and Behavioral Sciences, The University of Texas Health Science Center at Houston, Houston TX, USA
Introduction Bipolar disorder is treatable, but we do not yet have curative treatments or effective measures for primary prevention. Therefore, successful maintenance treatment is the goal in bipolar disorder. Every episode prevented improves the subsequent course of illness [1] and reduces its cost [2]. We will discuss maintenance treatment in terms of the critical assessment and practical application of research findings. Our focus will be on pharmacological treatments, as nonpharmacological treatments are addressed in another chapter, but we will also address factors related to integration of pharmacological and nonpharmacological strategies.
Goals of long-term treatment What should we expect from successful treatment of a severe, life-long illness? Lack of severe symptomatic exacerbations of illness is necessary for successful maintenance treatment. Lack of episodes is, however, not sufficient for successful maintenance or optimization of quality and productivity of life [3]; yet some individuals can have impressive accomplishments and rewards despite recurrent episodes of illness [4]. Subsyndromal symptoms can be harbingers of episodes, or can be problematic in their own right [5]. Cognitive impairment may combine persistent features of bipolar disorder regardless of symptomatic status with state-dependent exacerbations in specific areas, and are potentially useful, but underused, measures of outcome [6]. Comorbidities like substance-use disorders can worsen the course of bipolar disorder and cause serious impairment in their own right [7]. Existence of social supports and rewarding employment can be considered desirable outcomes of treatment, and also can be viewed as part of a treatment strategy since they predict prolonged stability [8]. Table 1 summarizes elements of successful long-term Bipolar Disorder: Clinical and Neurobiological Foundations Edited by Lakshmi N. Yatham and Mario Maj © 2010 John Wiley & Sons, Ltd. ISBN: 978-0-470-72198-8
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treatment. Goals and means for attaining the goals interact and are interdependent. These goals are only partially related to the objectives of most treatment studies.
Adherence to and participation in treatment No matter how strong the evidence supporting a treatment is, it only works if the patient takes it. Promoting responsible participation in treatment is therefore necessary for successful maintenance pharmacotherapy. Proper monitoring of clinical state and pharmacological treatment can provide the basis for a structure, encompassing education, peer support and caregiver support, underlying responsible participation [9]. Patients commonly do not take moodstabilizing medicines [10]. While side effects and weight gain are important components of this, and important health considerations in their own right, the main reasons that patients do not take their medicine have more to do with their attitude towards and understanding of the illness and its treatment [10,11]. Interestingly, the reasons that patients gave for not taking medicine (most strongly related to their understanding of and attitude towards their illness) were quite different from the reasons assumed by their clinicians [11]. This shows how important communication and education are. The association between noncompliance and suicide highlights both the lack of opportunity for medicine to work, and failure of communication [12].
Nature of evidence: relationship to the goals of treatment Goals and outcomes We will be reviewing psychopharmacological data using diverse study designs and outcomes. Most controlled pharmacological trials focus primarily on prevention of episodes [13]. A few studies have addressed treatment effects on subsyndromal symptoms; fewer have addressed effects on cognitive function or socioeconomic outcomes.
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Table 1 Successful long-term treatment. Goal
Some mechanisms
Prevent episodes and symptoms
Primary: pharmacological Secondary: specific nonpharmacological treatments; pharmacological and nonpharmacological treatment of substance use disorders and other associated conditions; education and support of patient, caregivers and other key individuals; structure; optimization of physical health; finding the means to assure availability of treatment; treatment of concurrent illnesses Education of patient and key individuals; social skills learning; development of social networks Control of symptoms and impairments; social networking; education Judicious, yet complete, treatment of episodes and symptoms; healthy habits including exercise and protection of social and activity/sleep rhythms; someday, specific treatments Judicious psychopharmacological choices; comprehensive treatment of other medical problems; healthy habits including exercise and protection of social and activity/sleep rhythms
Enhance social adaptation Enhance occupational function Optimize cognitive function Optimize overall health
Subjects in studies Study results must be viewed in terms of their generalizability to practice. Who were the participants in the study [14,15]? Randomized trials are, by necessity, generally conducted in restricted groups. Table 2 summarizes common subject exclusions in randomized trials. These restrictions are often necessary in order to conduct trials safely and to obtain results that are interpretable. Yet they can influence responses to, and toleration of, the treatments being studied. The manner in which these criteria are applied varies across studies. We must take them into account by combining data from conventional randomized trials with other types of evidence from less restricted groups or treatment studies for the problem leading to exclusion.
Design of treatment studies Certain questions must be asked in evaluating any treatment study. Table 3 summarizes factors pertaining to the
antecedents of a subjects participation in a study: characteristics of the subjects course of illness, the subjects state on entering the study and the subjects recent and past pharmacological and nonpharmacological treatments and responsiveness [13]. To what extent can we generalize this study to our practice? How can these factors affect outcome? Factors to keep in mind include: . Polarity of index episode: There appear to be depressionprone and mania-prone forms of bipolar disorder, with potentially different courses of illness and other clinical characteristics [16]. Depression-prone patients may have a more unstable course of illness [17]. Clinical characteristics of subjects in studies of recently depressed or recently manic subjects may differ, leading to potentially different patterns of treatment response [18]. Placebo responses appeared to differ between recently depressed and recently manic in one of the few pairs of comparable studies where both were investigated [19,20]. A true prophylaxis study would begin at a time when there was no recent index
Table 2 Common exclusions from clinical trials. Exclusion
Rationale
Problem
Concurrent psychiatric diagnoses, especially substance-related
Interactions with treatment drugs; difficulty in determining what is causing symptoms and symptomatic changes; safety
Concurrent medical illness
Pharmacological interactions with study drugs; difficulty in determining causation of symptoms and changes; safety
Severity of illness
Safety; severely ill patients may be less likely to have the capacity to give informed consent
Previous treatment with study drugs
May bias outcome; safety – either because subject does not tolerate drug, or should not be randomized when an effective treatment is known
Most patients with bipolar disorder have a substance use and/or anxiety disorder; these are associated with worse outcomes [7,288] Many patients with bipolar disorder have other medical illnesses, some of which may be more common in bipolar disorder, or related to treatment toxicities [289–291] Questions of generalizability to severely ill patients, who need effective, evidence-based treatment As the number of available treatments increases, the pool and generalizability of the subject pool decreases
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Table 3 Practical design considerations in clinical trials: subject characteristics. Characteristic
Rationale
Course of illness: frequency and dominant polarity [16] Features of index episode [18] What happened before time zero? Treatment and response in index episode [13]
May influence response to specific treatments, characteristics of most likely recurrence, and potential frequency of recurrent episodes May influence effectiveness of treatments and characteristics of recurrence Effects of treatment withdrawals or dose changes before randomization; effects of responses to specific treatments, including enrichment of sample with responders to a specific treatment
episode, removing potential effects of residual symptoms or relapse into episodes that were not fully treated [13]. However, not all patients are able to enter suitable stable periods; those who do might not be amenable to the risks of entering a controlled treatment trial, and relapses/recurrences under these conditions would be less frequent, requiring more subject-years to obtain statistically usable results. . Course of illness: Bipolar disorder can vary widely in terms of the frequency of episodes and the severity of complications, such as substance-use or anxiety disorders. There is some evidence for two basic, possibly heritable, forms of the illness, where one (‘episodic-stable’) has potentially severe episodes, but the episodes are relatively infrequent, prevalence of comorbidities is relatively low and response to lithium may be relatively strong. The other more inherently unstable group may be more prone to frequent episodes, mixed states, complications like substance abuse and lithium resistance [21]. Therefore, number or frequency of previous episodes, or age of onset, can influence responses to treatments. Current data suggest that a history of many previous episodes is associated with poor response to lithium [22–25]; there is little evidence with other treatments. In terms of overall psychosocial impairment, a large number of previous episodes predicts impairment regardless of severity of an individual episode [26], confirming Kraepelins original observation [27]. . Previous responses to treatments: This may overlap with course of illness [21]. As more treatments become available, it is harder to find clinically typical cohorts of patients who are not:(1) atypically refractory to treatment; or (2) so mildly ill that the impact of previous treatments were small enough that they are willing to give them up to enter a randomized clinical trial. Furthermore, most new drugs resemble drugs that are already in use, and that potential subjects may have already responded or nonresponded to, potentially distorting results. This situation is ameliorated by the fact that, even for patients who are technically episode-free, current treatment outcomes still leave a lot to be desired [28].
Relevant properties of the trial itself Again, there is a complementarity between reliability or robustness of outcome measures, and generalizability to practice. General factors to consider include: . Treatment of the index episode: There are two basic alternate design strategies. In one, (‘enriched’ designs) subjects are stabilized on the drug of interest, then randomized to receive that drug or comparators. This strategy is considered less general than the alternative, since it is limited to the subgroup of patients who have responded to a specific treatment, but is closer to clinical practice, since it is certainly more coherent to continue to treat a patient with a drug that was initially effective than to switch to something else [14]. The second is a design where randomization is independent of previous treatment. This design is more general, at least in an abstract way, but is less like clinical practice and is more likely to produce negative or failed studies [13]. . Speed of cross-over to randomized treatment: Withdrawal of a successful or partially successful treatment that is more rapid than two to four weeks is associated with increased likelihood of relapse [29,30]. This appears to hold for lithium and for other mood-stabilizing treatments [31]. . Nature of comparator treatments: Placebo-controlled trials are considered the strongest evidence that a drug works, but their implementation and design are challenging, especially in maintenance studies [32]. Placebocontrolled trials have larger effect sizes and therefore need fewer subject-years to achieve statistically significant results, positive or negative. However, they have disadvantages in terms of generalizability: More severely ill subjects cannot enter placebo-controlled trials and there is published evidence that subjects of placebo-controlled trials differ clinically from subjects in trials with active comparators, and that placebo responders differ clinically and demographically from non-responders [32]. However, studies with active comparators require considerably more subject-years than placebo-controlled trials. . Study duration: A maintenance treatment study needs to be long enough to determine that recurrent episodes
Maintenance Treatment
were actually prevented by the treatments under study. Duration of published studies ranges from a few months to two years. If there is an index episode, six months is arguably inadequate time to distinguish prevention of new episodes from prevention of re-emergence of the index episode [13]. The frequency of relapse/recurrence correlates with previous episode frequency [33]. A true prophylaxis study without an index episode could presumably be conducted for a shorter time, but would require more subjects in order to obtain an adequate number of new episodes for meaningful comparisons between treatments. . Study endpoint: The endpoint of a study can range from the need to add an additional treatment to emergence of a new episode of illness. Furthermore, some studies continue after the primary endpoint, and others do not. This can distort data about relapse. For example, many studies stopped after the first relapse, which was usually manic because of the study design, thereby constraining evidence on effectiveness in preventing depressive relapse [13,34]. Designs based on time to episode or percent remaining will have the further disadvantage that information from subjects who withdrew for other reasons is lost [35]. Combining dropout from intolerance or adverse events with dropout from episodes may provide a measure closer to the true effectiveness of a drug. Table 4 summarizes different study endpoints and manners of expressing study outcomes [13]. They vary in their clinical interpretability:
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. Time until a new episode is a common endpoint. This is certainly highly relevant, but has limitations because, in a recurrent illness, the timing of a single episode may not reflect overall clinical outcome, including frequency of future episodes, over time [36]. As with all episode-based measures, this measure does not account for the substantial symptoms and impairment that can exist in the absence of a full episode. . A variant of this is time to first intervention, which is more sensitive than time to a syndromal episode. Results of studies using this method may have limited generalizability to realistic practice. Bipolar disorder is a lifelong illness. If a drug differs from placebo, as may be the case for lamotrigine, by having a few more weeks or even months before a new treatment is added – but for most patients a new treatment must be added sooner or later – might it be better just to start with two treatments, or to attempt to identify, in advance, indicators of whether or when the second treatment will be needed? . Some studies, but generally not large randomized clinical trials, have used integrated symptom measures, such as number or fraction of days symptomatic. This underscores the importance of subsyndromal symptoms and of clinical effects over time, but may underestimate the impact of severe episodes [37]. This metric has been used more in descriptive longitudinal studies than in prospective treatment evaluations [38]. . Older studies compared percentage of subjects remaining episode-free over a given period. This measure loses
Table 4 Metrics for evaluating and comparing treatments. Method
Advantages
Disadvantages
Examples
Percent episode free
The most stringent
Time to episode
Accessible; provides data on % episode free
No information about how long the average subject remains stable Defining an episode; no information about course after the episode
Time to intervention
Clinically realistic measure of need for further treatments
Lithium [231,292,293]; often a secondary measure Lithium [212]; valproate [212]; aripiprazole [294]; olanzapine [258] Lamotrigine; lithium [19,20]
Integrated severity
May overestimate recurrences; hard to control variance amongst treaters; no information about course after the intervention Misses information about the most severe aspects of the illness
Measure of real symptom severity Naturalistic [37,38] over time; addresses subsyndromal symptoms Reasons for dropout are heterogeneous Reported in most studies, Percent completing the study A rough measure of effectiveness, though rarely the and often based on case-by-case since most dropouts are due primary endpoint decisions to poor clinical response and/or poor tolerability Number needed to treat Estimates the probability that Artificially separates drug and placebo [6] a subject will benefit effects, which clinically are inseparable
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information about how long patients were actually able to remain stable, subsyndromal symptoms, what happened after the first recurrence, and realistic psychosocial impairment. . Finally, rather than, or in addition to, comparing durations of stability or percentages of subjects who remain free of episodes, some more modern studies evaluate the number needed to treat, an estimate based on the relative probability of a subject having a certain outcome [6]. An advantage of this measure is that it is portable across any outcome measure [39]. A problem is that the number needed to treat to obtain benefit versus placebo is misleading, because it assumes that one could actually dissect out the components of improvement due to placebo or active treatment, when treatment with placebo is clinically impossible.
Transition to maintenance treatment One of the most crucial aspects of long-term treatment in bipolar disorder (or any similar illness) is the transition between the acute episode and long-term treatment. Successful acute treatment substantially reduces symptomatic impairment in a matter of weeks, with initial improvement even in the first week. However, functional impairment persists for months or even for years. This transitional period, when symptoms are improved but functional impairment persists, is a critical time for most patients, as during this period there is increased pressure to function and decreased support and monitoring [40]. Documented consequences include the relatively high risk for suicide after depression [41] or arrest following mania [42] during the months after an episode.
Transition to maintenance: pharmacological management Most treatment guidelines, to the extent that they address this aspect of treatment, recommend continuing whatever treatment was effective for the acute episode [43–45]. Therefore, when initial treatments are selected or when treatments are added due to breakthrough symptoms, careful thought must be given to balancing short-term effectiveness with long-term tolerability, safety and practicality. In addition to the primary treatment, this may also hold for important supplementary treatments such as antidepressive or antipsychotic treatments. Strategies described here for the transition to maintenance treatment are also relevant for management of subsyndromal or prodromal symptoms.
After a manic episode Most evidence that rapid discontinuation of successful antimanic treatments is associated with relapse at any time during treatment is from retrospective or uncontrolled
studies [31,46]. One large randomized, placebo-controlled study demonstrated that this was the case for the period after an acute manic episode [47]. Subjects who had entered remission for an acute manic episode with a combination of olanzapine and lithium or valproate were randomized to continue on combined treatment or to have the olanzapine, which had generally been added because of inadequate response, discontinued and replaced by placebo. Subjects with olanzapine discontinued had a more rapid rate of relapse to mania. About half of subjects with olanzapine discontinuation relapsed over the first two to three months of treatment. For the remaining subjects, the survival curve was parallel to that for subjects for whom combined treatment was continued. This suggests that relatively rapid discontinuation of the added olanzapine was associated with rapid, withdrawal-like relapse in about half of the subjects, while the subjects who did not suffer this early relapse had a long-term course that was similar to subjects on combined treatment. These results strongly support the idea that, if a second treatment was needed to resolve a manic episode, this treatment should be continued for at least a few months, and then tapered slowly (if at all). Several continuation treatment studies have addressed continued improvement over 10–12 weeks after a manic episode. Subjects randomized to have risperidone or haloperidol added to lithium or valproate had better outcome 10 weeks later [48]. Of 156 original subjects, 85 entered the continuation study and only 48 finished it. Lithium and quetiapine both maintained effectiveness over a 12-week period; 72/107 subjects on quetiapine and 67/98 subjects on lithium completed the study [49]. In a similar study, lithium and haloperidol maintained effectiveness for 12 weeks [50]. Of the treatments in these studies, risperidone, haloperidol and quetiapine lack placebo-controlled evidence for longerterm efficacy; only lithium has such evidence.
After a depressive episode There is substantial evidence that, in randomized trials, antidepressant treatments do not have prophylactic efficacy in bipolar disorder [51]. However, results of randomized trials pertain to the average subject in a study, and may not apply to individual patients or subgroups. A minority of patients with bipolar disorder appear to require antidepressive treatments, in addition to mood-stabilizing treatments, for resolution of a depressive episode. Altshuler et al. addressed this in a prospective [52] and a retrospective [53] study. About 20% of subjects with bipolar depressive episodes, all receiving mood-stabilizing treatments, did not respond to mood-stabilizing treatments alone, had resolution of their depressive episodes with supplemental antidepressive treatment, and tolerated the treatment for at least 6 weeks. This group of subjects had increased likelihood of depressive relapse if antidepressive treatments
Maintenance Treatment
were discontinued within 6–12 months. It must be kept in mind that these subjects were not randomized to antidepressive treatment but were selected based on treatment response and course of illness. These results suggest strongly that the minority of patients who require antidepressive treatments for acute depressive episodes should have those treatments continued for at least 6–12 months if the treatments are tolerated and their use is consistent with the patients course of illness.
The need to treat residual symptoms Most criteria for improvement, response, or even remission leave a lot of room for subsyndromal symptoms. There is ample evidence that these symptoms must be treated. Subsyndromal symptoms predict relapse [5]. One study found that, with lithium or lamotrigine monotherapy, onset of prodromal symptoms after an episode was delayed for only a week compared to placebo, and predicted relapse into an episode of the original polarity [54]. During the period after recovery from the acute episode, it is important to institute collaborative monitoring of residual and emergent prodromal symptoms [55], and coping strategies for dealing with them [56].
Nonpharmacological considerations Nonpharmacological treatments are discussed in detail elsewhere in this volume. Strategies with key roles in the transition to maintenance include [40]: . First, this is the time when the collaborative, structured treatment relationship, necessary for successful treatment adherence and monitoring, is solidified [9]. . Collaborative monitoring for prodromes of episodes, and developing of pharmacological and nonpharmacological tactics for dealing with them [56,57], should be instituted during this period. Mood charting methods are very useful for this [58]. . This is the best opportunity to establish strategies that are related to education and support of the patient and caregivers. If the family or those close to the patient do not understand the illness and its need for treatment, successful treatment is difficult, if not impossible [59]. Increased burden to family members is related to poor understanding of the illness, more than to severity [60] and predicts poor outcome [61]. . Behavioural and cognitive strategies, either as supplements to pharmacological treatments of primary mood symptoms or as treatments for concurrent conditions, such as anxiety or substance-use disorders [62], can be instituted during this period. . Attention must be paid to adaptive function, including education, work and other aspects of the patients usual life role. This crucial period, when symptoms may be better but functional recovery is incomplete, is generally not the
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time for major life changes if they can be deferred until the patient is truly back on her feet [40]. . Perhaps the most cost-effective approach is caregiver group psychoeducation [63], where a randomized trial (n ¼ 113) showed that patients whose caregivers engaged in 12 psychoeducation group sessions had fewer relapses, and longer time to relapse, for manic or hypomanic episodes. This underscores the importance of educating and supporting caregivers and thereby reducing caregiver burden in bipolar disorder.
When is the transition to maintenance complete? If the patient is fortunate, the transition to maintenance is complete when s/he is able to handle the living and work situation that existed before the episode, without undue stress. This may, therefore, be far from the individuals ideal adaptation. We know of no objective means to determine this. In the future it may be possible to identify and measure state-dependent neurocognitive impairments, thereby identifying the return to pre-episode function [64]. Once this point is reached, the individual is ready to embark on a stage of treatment aimed at maintaining and enhancing mood stability and enhancing adaptive and occupational functioning.
Maintenance treatment: evidence from controlled trials Studies have been designed to evaluate prevention of manic relapse, prevention of depressive relapse and prevention of either. The polarity of the most recent episode has an important impact on outcome [18]. First, there may be depression-prone and mania-prone courses of bipolar disorder, with different clinical and illness-course characteristics [16]. Accordingly, relapses are most commonly in the same direction as the most recent episode [18]. It can therefore be difficult to evaluate efficacy against relapse into the opposite polarity to the index episode, since those relapses may be less common, and they may go undetected in studies that end after the first relapse.
Placebo-controlled monotherapy studies Table 5 summarizes placebo-controlled relapse prevention or maintenance studies, published in the peer-reviewed literature, in which monotherapy with active drug was compared to placebo for at least 12 months. Evidence from this kind of trial is available for only five drugs: lithium, divalproex, olanzapine, aripiprazole and lamotrigine. In almost all cases, the treatment sample was enriched with acute responders to the study drug; in most cases, the index episode was manic. In terms of manic episodes, lithium, divalproex, olanzapine and aripiprazole were effective.
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Table 5 Evidence for prevention of depressive or manic episodes from placebo-controlled monotherapy studies. Drug
Study
N
Mo.
Manic
Depressive
Remarks
Lithium
[292] [293]
16 30
Prevented relapse
No effect Prevented relapse
No index episode Depressive index; enriched
[231] [231] [19]
40 bipolar II 35 bipolar I, 18 bipolar II 205 bipolar I 44 bipolar II 179 bipolar I
24 24 18
Prevented relapse Delayed recurrence
No effect Prevented relapse No effect
[20]
463 bipolar I
18
Delayed recurrence
No effect
Divalproex; lithium
[212]
372 bipolar I
12
Reduced relapse rate
Olanzapine
[258]
341 bipolar I
12
Aripiprazole
[295] [294] [19] [20]
161 bipolar I 24 bipolar I 179 bipolar I 463 bipolar I
6 Up to 24 18 18
No effect in entire sample. Reduced recurrence in enriched subsample Delayed recurrence and reduced rate Delayed recurrence Delayed recurrence No effect No effect
Manic index; enriched Depressive index; enriched Manic index; enriched for lamotrigine Depressive index; enriched for lamotrigine Manic index. Reduced rate for all episodes. Lithium arm not effective Manic index. Enriched
Lamotrigine
Delayed recurrence and reduced rate No effect No effect Delayed recurrence Delayed recurrence
Manic index; enriched Continuation of [295] Enriched; manic index Enriched; depressive index
Duration is in months. Positive effect: delayed time to new episode or reduced incidence of new episodes during study period. Enriched: index episode stabilized on study drug before randomization.
Lithium was effective even in two studies that were enriched for lamotrigine response [19,20]. Lamotrigine was ineffective in reducing manic recurrence in two studies, even though their designs were enriched for initial response to lamotrigine [19,20]. Lithium (in some studies), lamotrigine, divalproex and olanzapine were effective against depressive episodes. It should be noted that two of the negative studies with lithium were enriched for responders to lamotrigine [19,20]. Lithium was most effective against depression in subjects with index depressive episodes, but this may have resulted in part from study designs where early manic relapses occurred first and reduced the available pool of subjects for evaluation of depressive relapse prevention. Lithium, lamotrigine, divalproex and olanzapine were effective in reducing recurrent episodes in general.
Rapid-cycling Lamotrigine delayed the need for additional treatments compared to placebo in a six-month study of patients with rapid-cycling bipolar disorder [65]. Of 324 patients entering the study, 182 could be stabilized adequately, on multiple treatments including lamotrigine, to be randomized to lamotrigine or placebo. Overall, 41% of subjects randomized to lamotrigine versus 26% randomized to placebo were able to complete six months of randomized treatment without needing additional drugs. The effect of lamotrigine was significant in subjects with bipolar II disorder but not in subjects with bipolar I disorder [65].
Monotherapy studies with non-placebo comparators Amongst drugs with placebo-controlled trials, there have also been comparisons to other treatments. Olanzapine response was comparable to valproate for relapse in general in a 47-week study of subjects initially treated for mania with the study drug [66], and was better than lithium for mania and comparable to lithium for depression in a study of 431 recently manic subjects who were initially treated with both lithium and olanzapine and then had one or the other treatment replaced by placebo [67]. Many placebo-controlled studies have the disadvantage of early relapses on placebo due to withdrawal of active treatment. A meta-analysis of mirror-image studies, which do not have this disadvantage, found lithium to reduce relapse by 50% in patients with bipolar disorder [68]. There are several comparisons of lithium and carbamazepine, generally too small to detect any meaningful difference [69,70]. The largest was a prospective, randomized 2.5 year study of 171 subjects. Overall response to the two drugs did not differ significantly, though lithium appeared slightly better overall and significantly better in subjects with a ‘classical’ course [71]. Ironically, the ‘classical’ group (n ¼ 67) was substantially smaller than the ‘nonclassical’ group (n ¼ 104), and patient satisfaction was higher with carbamazepine than with lithium [72]. In a two-year randomized study of previously treatment-na€ıve subjects with at least two past episodes, lithium was slightly more effective in reducing episodes (12/44 with lithium and 21/50
Maintenance Treatment
with carbamazepine) but, after dropouts for intolerance, only 36% of subjects on lithium and 32% on carbamazepine completed the two years [73]. Denicoff et al. compared lithium, carbazepine and the combination in sequential one-year studies, where one year of monotherapy with each drug was followed by a year of combination treatment in 52 subjects [74]. Each drug alone was only modestly effective: on lithium, 31% of subjects had recurrent episodes, while 33% had marked improvement; with carbamazepine, 37% of subjects had recurrences, while 31% had marked improvement; on the combination, 24% had recurrences, while 55% had marked improvement [74]. Because the combination treatment phase came last, the results could have been biased in favour of combination treatment, since the more severely ill or nonresponsive subjects would have already dropped out.
Rapid-cycling Calabrese et al. compared lithium and divalproex in a 20month randomized study of patients with rapid-cycling, after initial stabilization on the combination [75]. Only 60 of the 254 subjects originally entering the study were able to be stabilized enough for randomization, even after combined treatment. Of the subjects who did not complete the stabilization phase, 76% had relapse/recurrence of depression (74% of episodes) or mania/hypomania/mixed (26% of episodes). The 60 subjects who could be randomized had similar response to lithium or divalproex, with roughly half of subjects having recurrent episodes; most recurrences were depression for either drug [75]. In their study of lithium and carbamazepine, Denicoff et al. found the combination to be significantly better than either alone in subjects with histories of rapid-cycling (28% marked improvement with lithium, 19% with carbamazepine and 56% with the combination) [74].
Combination studies Most patients with bipolar disorder eventually need more than one long-term treatment. The usual reasons for this are: (1) even at what is considered an optimal dose, monotherapy is not effective enough, especially for treating subsyndromal symptoms rather than producing mere ‘response’; and (2) that the patient gets some benefit from a drug, but is unable to tolerate what is considered an optimal dose. There is some evidence available in combination studies, but none were designed to answer these two questions. Instead, they are drug withdrawal studies where patients who have entered remission on a combination of a secondgeneration antipsychotic agent and lithium or valproate are randomized to continue on combined treatment or to have the second-generation antipsychotic discontinued. In this
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design, combinations of olanzapine [47] or quetiapine [76] with lithium or valproate were superior to lithium or valproate alone for prevention of new episodes, though the combinations also tended to have a greater side-effect burden, especially weight gain. As noted elsewhere in this chapter, combinations of lithium with carbamazepine appeared more effective than lithium alone in patients with rapid-cycling bipolar disorder [74]. Because lamotrigine may be most effective in depressionprone bipolar disorder, while drugs like lithium and valproate may be more effective in mania-prone illness, combinations of these treatments would appear reasonable. Interactions between lamotrigine and valproate are discussed below. Lamotrigine combined with lithium was well tolerated but appeared to have greater short-term than long-term effectiveness [77]. There are no published structured studies of lamotrigine and valproate, but their mechanisms are complementary [78] and the combination can be used safely if the lamotrigine dose is increased slowly [79]. Despite this paucity of evidence, combined treatments are usually necessary. In selecting combinations, factors are evidence that effects of mechanisms of drugs may be complementary, pharmacokinetic compatibility and toxicity.
Treatments for severe illness without evidence from randomized clinical trials Two treatments, electroconvulsive therapy and clozapine, have not been used in randomized clinical trials, but are considered to be effective treatments in patients who are not responding to more established treatments, or cannot take them.
Electroconvulsive treatment (ECT) When conventional treatments are ineffective or medically unsafe, long-term ECT treatment is sometimes used. Continuation and maintenance ECT have been studied retrospectively, using mirror designs in the same patients or parallel groups designs with comparable subjects not receiving continued ECT. ECT can be given for a few months after the index episode (continuation ECT) or can be given for a prolonged or indefinite period (maintenance ECT). ECT given every 10 days for an average of 10 weeks resulted in 1-year relapse rates of 33%, compared to 95% in a non-ECT comparison group [80]. One year of maintenance ECT, using mirror designs, reduced hospitalizations in 43 patients [81] and reduced time in hospital from 44 to 7% in 22 patients studied for 18 months [82]. Maintenance ECT was reported to be generally well tolerated. It may be underutilized in patients with treatment-refractory bipolar disorder or complicated medical illnesses [83].
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ECT in pregnancy and childbirth ECT is useful when more established treatments may be problematic, such as the first trimester of pregnancy. In general, ECT appears safe during pregnancy, including high-risk pregnancy [84]. A review of 300 reports over 50 years found 4 reports of premature labour, no reports of premature membrane rupture, and a few reports of transient but benign foetal arrythmias [85]. ECT in pregnancy is not free of risk; spontaneous abortion [86] and premature labour [87,88] have been reported.
Clozapine may also be beneficial in impulsivity and related problems. Clozapine reduced aggressive or impulsive aggressive behaviour in schizophrenia, independent of its effects on psychosis [100–102]. Clozapine may also reduce substance abuse [101]. Clozapine has been reported to reduce suicidal behaviour [103,104]. In a large prospective, randomized study of patients with schizophrenia, patients receiving clozapine had less suicidal behaviour than those receiving olanzapine, although other indices of clinical response were similar [105].
Clinical use and tolerability Treatment of mixed or manic states generally requires bilateral ECT [89]. Memory loss can occur during ECT; it is considered to be generally reversible, and to affect retention memory, unlike the usual impairment in acquisition memory associated with depression itself [90]. ECT can apparently be given with most psychotroic drugs if the ECT dose and seizure are monitored carefully, though it may be difficult with some anticonvulsive agents. The combination of ECT and lithium has been reported to cause prolonged seizures or persistent delirium [91]. However, one study of 31 patients given ECT plus lithium found that complications did not differ from those in 135 patients receiving ECT without lithium [92].
Toxicities and side effects Clozapine can cause weight gain, insulin resistance, and increased cholesterol and triglycerides, comparable to or greater than effects of olanzapine [106]. New-onset diabetes mellitus [107] and diabetic ketoacidosis [108] have been reported with clozapine. Clozapine has the potential for severe leucopenia or agranulocytosis in 1–2% of patients, especially during the first 6 months of treatment [109]. Therefore, periodic monitoring of complete blood counts is required for at least the first six months of treatment, with availability linked to peripheral neutrophil counts. The dose must be increased gradually, starting with 12.5–25 mg/day and increasing by 25–50 mg/day to reach the target dose, usually 300–450 mg/day for monotherapy, by about two weeks. Other more frequent side effects, including sialorrhea, antimuscarinic side effects and postural hypotension, have led to discontinuation in about 17% of patients in schizophrenia trials [110]. However, persistence in long-term naturalistic treatment is better than would be expected from a drug with its side-effect profile, probably due to the quality of the clinical response, severity of illness in those treated with it, lack of response to other treatments and, in add-on studies, the relatively low dose requirement [93]. Clozapine lowers the seizure threshold, with about 5% of clinical trial patients reporting seizures. At doses above about 400 mg, an anticonvulsant is often given concomitantly [110]. Pharmacokinetic interactions should be taken into account. Carbamazepine reduces clozapine levels, while valproate does not [111]. Neuroleptic malignant syndrome [112] and tardive dyskinesia [113] have both been reported with clozapine. Therefore, although clozapine is less likely to have these effects than other antipsychotics are, there is no antipsychotic treatment that is completely without risk for tardive dyskinesia or neuroleptic malignant syndrome.
Summary ECT is effective in the acute treatment of bipolar disorder when conventional treatment is not effective or usable. While there is less evidence, it may be effective in maintenance treatment under similar circumstances. It also may be a useful interim treatment, such as during pregnancy. However, long-term cognitive effects of ECT, especially when combined with other treatments, are a potential problem.
Clozapine Effectiveness Clozapine appears to be effective, sometimes as add-on treatment at moderate doses [93], in manic or mixed episodes not responsive to other treatments [94,95]. In two studies of patients refractory to other treatments, including clozapine or electroconvulsive treatment alone, patients tolerated and responded to combined clozapine and ECT [96,97]. The required dose of clozapine under these conditions appeared to be moderate, averaging 150–200 mg in add-on studies [93,96]. There is limited data on longer-term treatment; remissions persisted for three to five years in patients with severe dysphoric mania [94]. Clozapine has been studied for 48 months [98] to five years [94]. In a one-year randomized prospective add-on trial, subjects receiving clozapine had substantial improvement in ratings for general psychopathology, psychosis and mania compared to treatment as usual [99].
Summary In patients not responding to conventional treatments or combinations of them, clozapine can be effective in mania and severe impulsive aggression, sometimes with modest add-on doses of 100–200 mg/day. Clozapine may protect
Maintenance Treatment
against suicidal behaviour, though this effect has only been reported in schizophrenia [105]. Disadvantages include that, unlike ECT, it has little or no known antidepressive effects, and its metabolic effects are amongst the most severe of any psychotropic drug.
Treatment targets other than affective episodes Patients with bipolar disorder can suffer considerable impairment even when they are not having syndromal episodes of illness [3]. A few controlled studies have addressed endpoints other than depressive, manic, or mixed episodes. We will consider three significant problems associated with bipolar disorder: substance use, suicidal behaviour and cognitive impairment. Each of these is examined in detail in other chapters of this book; we will briefly review effects of commonly used maintenance treatments on these outcomes.
Substance/alcohol use Bipolar disorder has a higher prevalence of substance-use disorders than any other non-substance-related Axis I disorder. Substance use is associated with a more unstable course of illness, more suicide and violence, and poorer response to widely-used treatments. Yet, there is surprisingly little evidence that any treatment prevents or reduces substance or alcohol use in bipolar disorder. Unfortunately, individuals with substance use disorders are generally excluded from controlled maintenance trials. Results of
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pharmacological treatment studies for alcohol/substance use disorders in bipolar disorder are summarized in Table 6. Most of these studies were short-term; they suggest temporary additions to ongoing maintenance treatment rather than long-term preventive treatments. In some cases the treatments potentially effective in substance use treatment are also potentially useful for prevention of depressive or manic episodes. There are modestly positive results with anticonvulsants and uniformly negative results with second-generation antipsychotic agents, even when these treatments improved mood symptoms. In treatment of cocaine abuse in patients without bipolar disorder, positive results have been published with topiramate [114] and modafinil [115], with negative studies for olanzapine [116,117], risperidone [118], valproate [117] and carbamazepine [119]. For alcohol use, positive studies have been published with topiramate [120] and (for heavy drinking) valproate [121], an equivocal study with quetiapine [122], and largely negative studies with lithium (reviewed in [123]). In maintenance strategies for substance-related disorders in bipolar disorder, the mood-stabilizing treatment most supported by the overall sparse evidence is valproate. If conventional mood stabilizing treatments are not effective in reducing substance use, adjunctive topiramate may be useful; it has good evidence in either alcohol or cocaine use and should not have negative effects on mood stability. Cognitive behavioural relapse prevention therapies [124], perhaps especially group designs [125,126], are promising nonpharmacological interventions that may reduce substance use and improve adherence to pharmacological treatments. It may be important that nonpharmacological
Table 6 Treatment of substance abuse/dependence in subjects with bipolar disorder. Drug
Design
Duration
Outcome
Remarks
Citicholine [296]
Placebo-controlled, add-on n ¼ 44 Open-label, add-on, n ¼ 15 Open-label, add-on, n ¼ 30 and 32 Open-label add-on, n ¼ 17
12 wk
Reduced cocaine craving and frequency Reduced psychiatric symptoms and cocaine use Reduced psychiatric symptoms and cocaine craving No effect on measures of cocaine use; improved psychiatric symptoms No effect on abstinence; reduced heavy drinking Reduced substance use and improved psychiatric symptoms
Improved cognitive function
Valproate [297] Lamotrigine [298,299] Quetiapine [300]
Valproate [302] Lithium [303]
Quetiapine [298] Naltrexone [304]
Placebo-controlled, n ¼ 59 Placebo-controlled, n ¼ 20 Placebo-controlled add-on, n ¼ 102 Open-label, n ¼ 34
12 wk Up to 36 wk 12 wk
24 wk 6 wk
12 wk 16 wk
Reduced depressive symptoms; no effect on alcohol use Reduced psychiatric symptoms and alcohol use
Reduced cocaine use only in combined study Note Quetiapine abuse potential [301]
Adolescents with manic episodes and alcohol/ marijuana use
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strategies be aimed specifically at substance abuse in the context of bipolar disorder rather than substance use in general [127].
Suicidal behaviour Suicide in bipolar disorder is discussed in depth elsewhere in this book; we will consider aspects related to maintenance psychopharmacological treatment. Bipolar disorder carries a 20–30-fold increase in suicide mortality, regardless of age and gender; even in treated individuals, suicide mortality appears five-fold higher [128,129]. Risk for severe suicidal behaviour is increased with the combination of activation and depression, and is therefore maximal in mixed or activated depressive states [130,131], partially explaining the increased risk with substance-use disorders [130,132], since they are associated with mixed states and impulsivity [133]. Risk of suicide is also increased in patients with poor adherence to treatment [12]. The period of greatest risk is during or directly after depressive or mixed episodes [41].
Treatment effects on suicidal behaviour Suicidal behaviour appears to be reduced during lithium treatment, increasing when treatment is stopped [134,135]. In 32 controlled trials [136] and in longer-term observational studies [137], lithium reduced suicide and all-cause mortality. In patients who discontinued lithium treatment, the increased mortality generally associated with bipolar disorder returned [138]. Several factors complicate the interpretation of this evidence. None of the studies of suicide and treatment in bipolar disorder involved randomized treatments or designs that assured comparable treatment populations. Good response to lithium, and therefore the likelihood of remaining in treatment with lithium, is associated with characteristics that would be expected to confer relatively low risk for suicide: lack of mixed episodes, relatively infrequent episodes, and lack of substance abuse [21,22,25,139–141]. In naturalistic studies comparing two treatments, patients given the treatments may differ since clinicians will base treatment choice on clinical characteristics or previous response. Analyses of effects on suicidal behaviour in randomized clinical trials are complicated by the fact that potentially suicidal subjects are generally excluded from these trials. This important question should be addressed by a prospective, randomized study, designed in a manner where it is safe for a range of subjects to participate, such as the comparison of clozapine and olanzapine in schizophrenia where, other than the randomized treatments, subjects could have a wide range of treatments, including hospitalization [105]. Until such evidence is available, no other treatment has evidence for suicide prevention that is comparable to lithium.
Maintenance strategies for reducing suicide risk Components of a successful programme to minimize the risk for suicidal behaviour, which must be an integrated part of overall treatment, include: 1. vigorous preventive pharmacological mood-stabilizing treatment, especially emphasizing protection against activated depressive states, and combined with the education and support necessary to maximize adherence to treatment; 2. treatment of psychiatric comorbidities, especially substance use and anxiety disorders; 3. a supportive, collaborative treatment structure that includes education and support of caregivers or key individuals in the patients life, and careful and proactive monitoring, including detection and management of prodromal symptoms or of situations known to be problematic in the past [142]. It is noteworthy that, in patients who continued to take lithium but left lithium clinics, suicide mortality increased (though not to the extent of patients who also quit taking lithium [143]), emphasizing the role of structure and support. No strategy can eliminate suicide, but an integrated approach can reduce the risk for suicide and is the kind of approach that is necessary, in general, for the effective treatment of bipolar disorder.
Anxiety disorders Anxiety disorders, including generalized anxiety disorders, panic disorder and obsessive-compulsive disorders, are more prevalent in bipolar disorder than in any other axis I illness, including major depressive disorder; about half of patients with bipolar disorder have met criteria for at least one anxiety disorder [144,145]. Patients with combined bipolar and anxiety disorders, compared to those without anxiety disorder, have a stronger family history of bipolar illness, have earlier onset and are more likely to have histories of substance use disorders and of suicidal behaviour [146]. Young et al. reported that patients with bipolar who had high symptom ratings for anxiety, even if they did not meet criteria for an anxiety disorder, had a worse course of illness with increased suicidality and alcohol use behaviour, with a trend towards poorer response to lithium [147]. Yet, there is little information about treatment of anxiety disorders or anxiety in the context of bipolar disorder.
Treatment considerations The only placebo-controlled trial published to date in treating anxiety disorders in bipolar disorder was a negative trial of risperidone at 0.5–4 mg/day in patients who had generalized anxiety disorder or panic disorder in addition to bipolar disorder [148]. In placebo-controlled studies of depressive episodes in bipolar disorder, olanzapine or olanzepine-fluoxetine combination [149] and valproate [150] markedly reduced anxiety scores. In a single-blind 12-week
Maintenance Treatment
add-on study for patients who were receiving lithium and in remission, olanzapine (average dose about 7.5 mg) and lamotrigine (average dose about 100 mg) similarly reduced anxiety scores [151]. In patients without bipolar disorder, evidence of varying depth supports valproate (panic disorder), lamotrigine, risperidone and olanzapine (post-traumatic stress disorder), risperidone, olanzapine or quetiapine (refractory obsessive compulsive disorder) and many antidepressive agents [152]. In one report, open-label valproate improved symptoms of panic disorder in treatment-refractory patients with mood instability [153]. Antidepressants [154], or antidepressant withdrawal [155], have been reported to cause mood destabilization in patients with anxiety disorders who were not thought to have bipolar disorder. While there have been few reports involving subjects with bipolar disorder [156], cognitive behavioural therapies are effective against anxiety disorders in other subject groups, and their effects persist well beyond the period of treatment [157]. Given the potential for long-term effectiveness, the lack of pharmacokinetic interactions with ongoing treatments, and the lack of mood-destabilizing effects, cognitive behaviour therapy is a potentially attractive treatment for anxiety disorders in patients with bipolar disorder who are already receiving mood-stabilizing treatments.
Maintenance strategies for anxiety disorders or severe anxiety in bipolar disorder The clinician needs to be alert for the presence of anxiety disorders, which appear to be under-recognized [158]. Given the lack of direct evidence from controlled studies, the first pharmacological choice is to use treatments shown to be effective in other contexts that are also effective in bipolar disorder, without potential mood-destabilization. This would include lamotrigine, valproate and several atypical antipsychotics. Antidepressive agents have the most extensive body of supporting data and could be useful in patients with adequate mood-stabilizing treatment, especially if their previous illness course pattern is episodic-stable. Addition of nonpharmacological treatments such as cognitive-behavioural therapy has the potential for long-term effectiveness without complicating the patients pharmacological regime.
Using major treatments This section summarizes practical aspects of the most important maintenance treatments. Many relevant topics, including pharmacology of individual drugs, drug toxicities, pregnancy and weight gain, are treated in more detail elsewhere in this book. It is the purpose of this chapter to summarize information that is most salient in the context of maintenance treatment.
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Lithium Effectiveness Lithium, the first prophylactic treatment with demonstrated effectiveness in randomized trials, is remarkably versatile. It has been reported to reduce recurrences of mania or (possibly a less robust effect) depression [68,159,160] and to have the potential of reducing suicidal behaviour [161] (see above). While there are also negative studies with lithium (see Table 5), some of these were compromised by study design, especially studies in prevention of depressive episodes. Response to lithium appears to run in families [21,162] and to be strongest with an episodic-stable, rather than inherently unstable, course of illness [21,24]. Lithium may be less effective in patients who have had many episodes and who have concurrent substanceuse disorders or other complications of bipolar disorder [8,21–23,25,71]. Naturalistic studies suggest that some patients initially responding to lithium lose their response to lithium monotherapy over the ensuing 5–10 years; this effect is seen most in patients with many previous episodes [23,163]. However, other patients appear to have progressively better response to lithium with time, even after 10–15 years [164,165]. If it is necessary to stop lithium treatment, this should be done as gradually as possible, as multiple studies have shown that the incidence and severity of relapse (usually into the episode type resembling the first or the most recent episode) is worse if discontinuation is more rapid than two to four weeks [29,46]. This may be a general principle across long-term treatments [31]. If lithium is discontinued for any reason, there are reports of less satisfactory response, or nonreponse, when it is reinstated [166]. However, other larger studies suggest that, on average, patients who responded to lithium in the past will respond again, though response may worsen as time off lithium increases [167]. Patients should be encouraged to continue taking lithium if they respond well to it; long-term outcome with controlled lithium withdrawal was poor [168]. Practical pharmacokinetics Lithium is so simple that it is complicated. It has many cellular actions. Pharmacokinetically, a few principles are helpful in understanding its use. It is almost completely absorbed from the GI tract (some slow-release preparations may have reduced absorption if bowel transit time is too fast), reaching peak plasma concentrations in one to three hours [169]. Its half life is roughly 24 hours, so single daily dosing is potentially feasible [170]. It is distributed to all tissues. Concentrations in most tissues are lower than plasma levels becauseofa transmembrane lithium-sodium exchanger [171]. Concentrations in excitable cells, like neurons, are higher than in other tissues, because lithium enters through the voltage dependent sodium channel during electrical
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activity [172]. The concentration of lithium in excitable tissues continues to increase for hours after the plasma level has begun to decline [173], an important consideration with toxicity or overdose. Lithium is not metabolized (one would need a nuclear reactor) and has no appreciable protein binding. It is entirely excreted by the kidney, being filtered in the glomerulus, and partially reabsorbed in the proximal tubule. How much lithium is in the body at a given dose depends almost entirely on the rate of sodium delivery to the proximal tubule, because lithium and sodium compete for reabsorption [174]. Sodium is also reabsorbed in the distal tubule, but lithium basically is not. Increased sodium delivery to the proximal tubule, for instance from increased cardiac output, a proximal-tubule diuretic or increased sodium intake, reduces lithium reabsorption. If the patient is dehydrated or has low sodium stores, perhaps due to diuretic treatment, there is less sodium to compete with lithium, so more lithium is reabsorbed and the lithium level rises. As the lithium level approaches 3 mEq/L, it inhibits the action of aldosterone on the distal tubule, impairing reabsorption of sodium there (where lithium does not compete with sodium) and limiting sodium reabsorption to the proximal tubule where it must compete with increasing lithium concentrations. Therefore, the severity of lithium toxicity quickly accelerates at around this level [175].
Management and monitoring Lithium treatment requires therapeutic structure, and this can be beneficial in bipolar disorder. Suicidal behaviour increased in patients who left lithium clinics but kept taking lithium [143]. The structure inherent in successful lithium treatment promotes education about the illness and monitoring of its course [9,176,177]. Lithium levels can be useful in planning treatment, as well as in assuring safety. One study found that patients maintained on higher lithium levels (0.8–1.0 mEq/L) did better in terms of episodes and residual symptoms than those maintained on a lower level (0.4–0.6 mEq/L), though they also had more side effects [22]. Interpretation of these results, however, is complicated by the fact that subjects on the lower level had a rapid dose reduction at the beginning of the trial, possibly predisposing them to increased symptoms [30]. Another study reported that manic relapses were associated with lower lithium levels than depressive relapses were [178]. However, it must be remembered that lithium levels are state-dependent. Hypomania or mania is associated with increased catecholamine release, cardiac output, renal blood flow and lithium clearance, resulting in lower lithium levels [173,179,180]. If an incipient episode is detected early, the dose of lithium can be increased (if tolerated) and this potential problem can be prevented or reduced.
Toxicities and side effects Lithium has a varied profile of potential side effects that require systematic monitoring of its use. Even so, when used properly, lithium is potentially well tolerated and safe. Guscott and Taylor stressed the importance of education and monitoring, pointing out that many problems with lithium stem from noncompliance: not on the part of patients, but of clinicians [9]. The monitoring that is required for optimum treatment with lithium fosters communication between patient and physician, understanding of the patients illness, and the idea that the patient has responsibility for his health, rather than being the mere recipient of a treatment. This attitude is useful for all treatments, not just lithium. Major potential side effects and practical measures include: . Weight gain: Weight gain with lithium can be substantial, especially if combined with other treatments [181]. Weight gain must be managed prospectively, with a judicious programme of nutrition, activity and monitoring [182]. If necessary, addition of topiramate has been shown to reduce weight in patients receiving lithium or valproate without worsening depression or mania [183]. . Renal effects: Lithium treatment can result in progressive decline in renal function over time, due to interstitial nephropathy, though the average patient may have no longterm decline in renal function beyond normal ageing [184]. This usually insidious phenomenon (sometimes called ‘creatinine creep’) seems to occur in 20% or less of patients taking lithium for many years [185]. Prospective and retrospective studies based on biopsy evidence suggest that this problem is not related to duration of lithium treatment per se but is related to repeated episodes of lithium toxicity and to other drugs or medical conditions that affect the kidney [185–187]. If detected early, it appears to be reversible (or at least not to progress further) if lithium is discontinued; under these circumstances, lithium can be discontinued gradually while alternative treatment is substituted [188]. Sometimes a low dose of lithium can be continued. It is advisable to monitor renal function (at least with a creatinine level) at least yearly in healthy patients, more often if there is pre-existing illness that can affect the kidneys [189]. If creatinine starts to rise, further evaluation is warranted, and consultation with a nephrologist is advisable if creatinine rises above 1.6 mg/dl [189]. The importance of monitoring creatinine levels is underscored by a report that in patients discontinuing lithium with serum creatinine greater than 2.5 mg/dl, deterioration of renal function usually was progressive even after lithium discontinuation, but when creatinine was less than 2.5 mg/dl, renal function subsequently improved [188]. More commonly, lithium can cause a reversible, doserelated diabetes insipidus due to impairment of antidiuretic hormone action [190]. This can usually be managed by dose reduction or by addition of a low dose thiazide diuretic or
Maintenance Treatment
amiloride [191]. Over long periods, this condition may become less reversible, and may predispose to interstitial nephropathy and renal insufficiency by predisposing to episodes of lithium toxicity [186]. Single daily dosing may reduce these effects [170,186]: . Endocrine effects: The most common endocrine side effect of lithium is hypothyroidism, usually manifested first by increased thyroid stimulating hormone levels. Lithium treatment can usually be continued, with addition of thyroid hormone replacement [192]. Hyperparathyroidism can also occur during lithium treatment [193]. . Neurotoxicity: Lithium treatment can be associated with neurotoxicity [194,195], which can be insidious [196], is potentially related to elevated lithium levels [196] and is at least partially reversible [195,196]. It is associated with impaired neuromuscular conduction [194]. Its true incidence is difficult to determine; risk may be increased by combination with antipsychotic agents [197]. . Cardiac: cardiac problems are rare in lithium treatment, but the drug can cause reversible sinus node dysfunction, at toxic or nontoxic levels, in susceptible individuals [198]. This is thought to be a consequence of sodium channel blockade [199]. This effect may be more likely in patients who are also taking carbamazepine [200] or verapamil [201]. Hypothyroidism can also contribute to sinus node impairment with lithium [202]. Lithium has also been reported to cause, or contribute to, QTc prolongation [203]. . Dose-dependent symptomatic side effects [204]: Doserelated side effects should be watched closely for two reasons:(1) they can usually be managed, but, if ignored, can readily lead the patient to stop taking lithium (generally their worst consequence); and (2) they can be early signs that the lithium level is rising or has reached pre-toxic levels. Lithium can cause intention tremor, especially if given in combination with other tremor-inducing drugs such as serotonin reuptake inhibitors or anticonvulsants. If not manageable by dose adjustment of lithium or one of the other drugs, this can usually be ameliorated with betanoradrenergic blocking agents. Lithium can also cause stomach upset, which can be managed by dose adjustment, giving with food, or acid-reducing drugs; or diarrhoea, which can be managed by dose reduction or common antidiarrheal drugs.
Lithium and pregnancy [205] This is an important consideration in planning long-term treatment, since pregnancy is potentially an important part of life for at least half of patients with bipolar disorder. Long-term lithium can have substantial benefits, and pregnancy does not protect against episode recurrence if treatment is discontinued [206]. It is reasonable that a patient and her psychiatrist have clear communication about one of the most important decisions of her life. Lithium exposure
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during the first trimester can be associated with Ebsteins anomaly, an otherwise rare heart defect that requires surgical correction. It is difficult to determine the actual incidence of this effect, since most data are from case-registry studies, which tend to over-report problems [207]. Later in pregnancy, lithium can cause side effects in the foetus, such as polyhydramnios from foetal nephrogenic diabetes insipidus [208]. During pregnancy, lithium clearance is increased due to the mothers increased fluid volume, so lithium levels at the pre-pregnancy dose will be lower. At the time of delivery, because of the rapid drop in fluid volume, the lithium level can rise; therefore, it is recommended that a woman who is taking lithium stop lithium before going into labour (it she is fortunate enough to know this beforehand). Probably because of its lack of protein binding, the concentration of lithium in breast milk is relatively high [209]. Judicious planning in patients who benefit from lithium is therefore necessary. The period directly after childbirth is particularly risky in bipolar disorder; furthermore, ‘postpartum’ depressions often have onset during the third trimester [210].
Summary Lithium is effective for reducing recurrence of manic or depressive episodes in bipolar disorder. Although its effectiveness as a primary treatment may be greatest in patients with an episodic-stable course of illness and positive family history for lithium response [21,211], it is also an valuable secondary treatment. Beyond effects on mood episodes, lithium has beneficial effects on impulsive-aggressive behaviour and suicidal behaviour. The facts that it is not bound to plasma proteins or metabolized by the liver are favourable characteristics for combination treatments. Lithium use requires monitoring and structure, appropriate to using an effective drug to treat a complex illness.
Anticonvulsive treatments Valproate Effectiveness In a six-month, placebo-controlled study, fewer patients on divalproex than on placebo treatment had depressive or total episodes [212,213]. There were no differences in percent of patients having manic episodes or in time to recurrence. This study was unusual in that subjects were not required to be initially treated with valproate, though subjects were stabilized on valproate and/or lithium. In the subjects who were initially stabilized on valproate, time to manic recurrence was significantly longer than that for placebo [212]. Therefore, under usual clinical conditions, divalproex was effective in delaying relapse to mania or depression. In addition, one year of valproate treatment was equivalent to olanzapine in the incidence of recurrence [66].
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There is evidence suggesting that treatment with valproate might be effective in reducing cocaine use or heavy alcohol drinking in bipolar disorder.
Toxicities Valproate has been associated with liver failure [214] and with pancreatitis [215]. Liver failure is rare (one case per several thousand patients) except in infants or in patients with already compromised liver function [214]. Pancreatitis is a rare, idiosyncratic reaction to valproate, usually occurring early in treatment and generally recurring upon rechallenge [216]; a total of 24 cases were reported in the world literature up to 1991 [215]. Pancreatitis may be more likely in patients with risk factors (i.e. severe drinking) and valproate may exacerbate pancreatitis that has other causes. Valproate commonly reduces platelet counts during the acute phase of treatment (by 10% in the average patient); functionally significant thrombocytopenia is rare [217]. In a cohort of young women with seizure disorders, valproate treatment was associated with increased development of polycystic ovarian syndrome [218]. The authors attributed this to insulin resistance caused by weight gain. Results of subsequent studies in patients with bipolar disorder have been mixed [219,220]. Until there is a prospective, longitudinal study that is large enough to account for confounding factors and evaluate predictors of risk, treatment should be based on the patients clinical needs; weight control is important in young women at risk [220]. Pregnancy and childbirth During the first trimester, incidence of neural tube defects is increased (2–3%); this risk is possibly reduced, but certainly not eliminated, by folic acid treatment [221]. Risk is increased with valproate levels of over 70 ug/ml or doses over 1000 mg/day, and by combinations that include enzyme inducers or benzodiazepines [222]. The neural tube closes by day 28, when many women may not realize they are pregnant. Therefore, it is important to address the issue of pregnancy-associated risk proactively, as early in treatment as possible [221,223]. Generally it is recommended that women taking valproate take folic acid supplements, with increased folic acid around the time of conception if pregnancy on valproate is anticipated [224]. It is important, however, not to have a false sense of security because of folic acid treatment. The concentration of valproate in breast milk appears to be low, but this is based on a very small number of cases [209]. Valproate does not significantly affect circulating levels of oral contraceptive hormones [224]. Monitoring Trough valproate levels can be obtained about 12 hours after divalproex treatment. Theoretically, levels should be
obtained about 24 hours after treatment with the extended release form, but because of its smaller diurnal variation, it is adequate to obtain the level at the time most convenient to the patient, being sure to maintain a consistent pattern. Liver function and platelets should be monitored early in treatment. In healthy patients, thereafter it is generally adequate to monitor these parameters once or twice yearly, or when there is a change in drug regimen or medical status. Because pancreatitis is rare and sporadic, there is no utility in monitoring serum amylase routinely [225].
Summary Valproate is potentially effective in a wide range of presentations in bipolar disorder, including mixed states, rapid-cycling and patients with substance abuse. Results of maintenance studies suggest that valproate protects against recurrence under normal clinical circumstances, and the drug is also potentially effective against common complications of bipolar disorder, including substance- and impulsivity-related disorders [226]. Its main disadvantages are potential reproductive effects and weight gain. Lamotrigine Effectiveness Lamotrigine treatment delayed onset of need for additional treatments for depressive episodes in recently depressed [20] or manic [19] patients, and reduced the total incidence of recurrence [227], in two 18-month studies. It similarly delayed onset of need for additional treatment in bipolar II subjects with rapid-cycling in a 6-month study [65]. All of these studies used enrichment designs with the requirement that subjects were stabilized on combined treatments including lamotrigine and then remained stable for at least two weeks on lamotrigine monotherapy. This is a disadvantage since lamotrigine has never been demonstrated to be effective in acute manic episodes [228] or in preventing manic episodes [229], and has only limited supporting evidence in acute depression [230]. Therefore, patients maintained on lamotrigine will generally require initial treatment with other medicines instead of or in addition to lamotrigine, as well as combination treatment with a drug that is more effective for mania prevention. Lamotrigine has practical advantages in long-term preventive treatment of bipolar depressive episodes. It appears to be weight-neutral and rarely causes sedation. No other treatment has evidence for prevention of depressive episodes that is as consistent as that for lamotrigine, since lithium may be less effective in preventing depressive episodes in patients with index mania [231]. Lamotrigine monotherapy may have somewhat limited application in bipolar disorder, given its lack of effectiveness against mania. Recently manic subjects on lamotrigine
Maintenance Treatment
went 20 weeks before needing additional treatment, compared to 12 weeks on placebo or 42 weeks on lithium [19]. Recently depressed patients went 29 weeks on lamotrigine, 24 weeks on lithium or 13 weeks on placebo [20]. In subjects with rapid-cycling, 45% were able to complete 6 months without additional treatments [65]. Therefore, over a period of several months, most subjects needed additional medicine, no matter what monotherapy they had been assigned. It is attractive to consider lamotrigine for bipolar II disorder, where most patients are probably depression-prone [232]. The 18-month studies were in bipolar I subjects, and in the single study with bipolar II depression, effects of lamotrigine did not differ from placebo [233].
Toxicities Lamotrigine is a well-tolerated drug after the first 2 months of treatment. Lamotrigine, like many aromatic anticonvulsants (carbamazepine, barbiturates, diphenylhydantoin), can precipitate hypersensitivity reactions, possibly directed against a complex of the drug and a metabolizing enzyme [234,235]. These reactions can include severe rashes, including Stevens-Johnson syndrome and toxic epidermal necrolysis, as well as other systemic manifestations of hypersensitivity [236]. These reactions are unusual (generally around 0.1%), can be largely prevented by gradual initial dose escalation, and are more common in children or in individuals with known susceptibility to this kind of hypersensitivity (which appears to be genetic). When a person taking lamotrigine develops a rash, it is necessary to determine whether the rash is likely to progress to a severe hypersentivity reaction (these have substantial mortality) or is benign and self-limited (benign rashes outnumber severe hypersensitivity by 100 : 1). Lamotrigine should only be used if the rationale is unusually strong in patients who are at high risk (previous similar reaction to another drug, child/adolescent), and all patients should have careful discussions (and written material) about these hypersensitivity reactions. In clinical trials where the dose was escalated gradually, the rate of severe rash was extremely low [227]. The incidence of rash can be reduced by using gradual dose titration plus a set of dermatological precautions to protect against confounding rashes from other causes [237]. Using lamotrigine with other medicines Medicines that inhibit metabolism of lamotrigine can increase the likelihood of rash by accelerating initial concentrations of lamotrigine. The most widely used example of this in psychiatry is valproate [238]. The combination of valproate and lamotrigine is considered clinically useful because the drugs may have complementary effects on episode prevention that mirror their positive anticonvulsive interaction [78], and appears to be safe if this pharmacoki-
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netic interaction is compensated for [79]. Valproate essentially doubles steady-state lamotrigine levels by preventing its conjugative metabolism (usually the dominate pathway) [239]. Therefore, if lamotrigine is added to the regimen of a patient already taking valproate, the usual dosage schedule should be cut in half (i.e. 12.5 mg daily for 2 weeks, then 25 mg daily, etc.). If valproate is added to lamotrigine, the clinician should allow for the fact that, once the valproate level is above about 70 mcg/ml, the rate of lamotrigine metabolism will be halved. Therefore, a prudent tactic might be to double the dose interval before the first lamotrigine dose after valproate was added, and then continue at half the former dose [240,241]. Enzyme inducers, like carbamazepine, can reduce lamotrigine levels, and it is often recommended that the initial doses of lamotrigine be increased proportionately to compensate for this [241]. However, one should be cautious with this tactic, because enzyme inducers lower the concentration of unmetabolized drug, but they increase the concentrations of the drugenzyme complex that is presumably the target of the allergic reaction [235].
Lamotrigine in pregnancy There is no evidence for elevated rates of foetal malformations with lamotrigine [205]. However, one should not be complacent, because foetal complications are so widespread amongst anticonvulsants and the experience with lamotrigine is still relatively brief [242]. During pregnancy, lamotrigine clearance is increased so an increased dose may be necessary for successful treatment. Lamotrigine in the newborn can reach substantial blood levels and has a low clearance rate, though no problems have been associated with this [243]. Lamotrigine can lower circulating levels of oral contraceptive hormones, but not to the extent of more strongly enzyme-inducing anticonvulsants [242]. Summary Lamotrigine has strong supporting evidence for prevention of depressive episodes in subjects stabilized on lamotrigine [227]. It also has advantages in terms of tolerability, since weight gain and sedation are generally not encountered. It may be especially useful in treatment of depressionprone patients with bipolar disorder, generally as part of treatment combinations. Carbamazepine Effectiveness Carbamazepine has a wealth of experience in naturalistic trials and in comparisons to other treatments, generally lithium, but no long-term placebo-controlled maintenance trials. Evidence for effectiveness of carbamazepine is limited to mania. It may be most effective in patients with
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‘atypical’ features, who actually outnumber their ‘typical’ counterparts [71]. The general view that carbamazepine was especially effective in patients with rapid-cycling was not supported in a prospective 3-year randomized, sequential, counterbalanced comparison with lithium, where neither treatment alone was particularly effective over 12 months but the combination was significantly better [244].
Oxcarbazepine Oxcarbazepine is a congener of carbamazepine. Because its first metabolic step is reductive and does not undergo autoinduction as the corresponding step of carbamazepine metabolism does, oxcarbazepine has the potential for simpler pharmacokinetic interactions and a lower incidence of hypersensitivity reactions. These problems, most importantly the interaction with oral contraceptives (see below) still occur with oxcarbazepine, though possibly at lower rates. There is preliminary evidence for prophylactic effects, but current evidence is not adequate to determine its effectiveness [245]. In a small 12-month add-on study to lithium (total n ¼ 55), there were trends for improvement in depressive (p ¼ 0.085) and total (p ¼ 0.13) mood events [246]; the study was therefore not powered adequately to provide realistic evidence for the efficacy, or lack of efficacy, of oxcarbazepine added to lithium. Toxicities Carbamazepine can precipitate the anticonvulsive hypersensitivity syndrome described above for lamotrigine, possibly with a greater prevalence. The cause of the reaction is hypersensitivity to a complex of carbamazepine with arene oxidase, its initial degradative enzyme [235]. General treatment considerations are as discussed above for lamotrigine. In addition to skin rashes, a common result with carbamazepine is bone marrow suppression and aplastic anaemia [247]. While more insidious, reversible neutropenia can be detected by regular haematological monitoring during the first few weeks of treatment, the severe, more sudden onset of aplastic anaemia cannot, so patients must be educated to recognize potential early manifestations. Carbamazepinealsohashepaticandothertoxicitiesthatare similar to most other antiepileptic drugs [248]. Weight gain can occur with carbamazepine but is less than with valproate or lithium [249]. Neurological side effects, including diplopia, intention tremor and coordination difficulties, are relatively common during dose escalation or if levels are increased by pharmacokinetic interactions with added treatments [250]. Using carbamazepine with other drugs Because it induces cytochrome p450 3A4, carbamazepine lowers levels of most psychotropic drugs, including members of every drug class except lithium [251]. Carba-
mazepine can also lower levels of many other prescribed medicines, including oral contraceptives [252]. It is therefore important (as always) to be aware of all other medicines that a patient is taking, and to communicate regularly with other treating physicians to be sure they know the patient is receiving carbamazepine. These considerations apply equally well to any other enzyme-inducing drugs. Carbamazepine and valproate have a dual interaction [253]. Carbamazepine lowers valproate levels by inducing that portion of valproate metabolism that takes place through microsomal oxidation. This can be readily compensated for by monitoring valproate levels and increasing the dose. In addition, valproate, while it has little effect on circulating levels of carbamazepine, increases levels of an active metabolite, carbamazepine 10,11-epoxide, whose levels are not routinely measured [254]. Therefore, the carbamazepine dose may need to be reduced, based on clinical observation rather than blood levels.
Carbamazepine in pregnancy Carbamazepine, like many other anticonvulsants, is associated with increased incidence of neural tube defects, a problem that occurs during the first month of pregnancy [255]. Drug combinations that include enzyme inducers like carbamazepine may increase the likelihood of these effects over the individual drugs [222]. Summary Carbamazepine can be effective in reducing recurrence of mania, especially in patients who have a complicated course of bipolar disorder including comorbid substance use and an unstable course; predictors of response are complementary to predictors of lithium response [71], so the combination can be more useful than either drug alone in some patients [74,256]. It has never been demonstrated to prevent recurrence of depression. Its greatest use may be as part of treatment combinations (allowing for pharmacokinetic interactions) in mania-prone patients with complicated illness. Treatment guidelines generally consider it a secondline treatment [43,44]. Second-generation antipsychotic agents Effectiveness Aripiprazole, olanzapine, quetiapine, risperidone and ziprasidone all have been shown to be efficacious for treating depressive and/or manic episodes in bipolar disorder [257], and therefore are likely to be used for long-term treatment. Olanzapine [258] and aripiprazole [259] were effective against placebo in long-term prevention of episodes (Table 5). The long-acting injectable form of risperidone was effective for 2 years in a study of 10 patients [260]. Quetiapine plus lithium or valproate appeared more effective than
Maintenance Treatment
lithium or valproate alone in a 2-year study [76], but this study was enriched by a prolonged stabilization period on combination treatment, so it should be regarded as a quetiapine withdrawal study. In a 4-year naturalistic study of 232 patients with bipolar I or II disorder, quetiapine alone was associated with good outcome in 29%, lithium in 46%, valproate in 33% and lithium or valproate plus quetiapine in 78–80%. Rapid cycling subjects had favourable (but not as good as non-rapid cycler) outcomes with olanzapine [261] and favourable (difficult to compare with non-rapid cyclers) with aripiprazole [262]. Secondgeneration antipsychotics are heterogeneous in their toxicities and in their apparent effectiveness against acute depressive episodes [149,263–265]. Therefore one cannot assume that they would be equi-effective in the general prevention of episodes of bipolar disorder. Clozapine differs from other second-generation drugs in its spectrum of effectiveness and the nature of its supporting evidence, and was discussed separately above. While no peer-reviewed placebo-controlled monotherapy studies have been published, placebo-controlled maintenance studies of risperidone (long-acting injectable) and quetiapine, lasting at least 1 year, and a shorter study of adjunctive ziprasidone, have been conducted and the results have been presented in meetings. It is therefore safe to assume that, though toxicities and relative effectiveness against depression, mania and comorbid conditions may vary, second-generation antipsychotics in general can prevent recurrent episodes in bipolar disorder, at least in patients initially responding to these drugs. With long acting, injectable first-generation antipsychotic agents, there is evidence from mirror-design and naturalistic studies that long-acting forms of conventional antipsychotic agents can reduce manic recurrence in bipolar disorder; there is no evidence from randomized, controlled trials [266]. However, these drugs have the potential of increasing depressive symptoms and, possibly, suicidality [267].
Toxicities and side effects The most substantial problems related to second-generation antipsychotics are metabolic effects and effects on the secondary motor system: . Metabolic effects and weight gain: All second-generation antipsychotics can cause excessive weight gain, type II diabetes mellitus, or even new-onset diabetic ketoacidosis [268,269]. However, the incidence varies substantially across drugs. Olanzapine and clozapine have the highest incidence of these problems; quetiapine (note that the incidence may increase as higher doses are used) and risperidone are intermediate, and aripiprazole and ziprasidone have the lowest incidence (although undue complacency is ill-advised). These are potentially effective drugs but the decision to use them, as with all powerful
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medical treatments with significant potential toxicities, should be made judiciously. The key to management is early, proactive education, monitoring and efforts to foster reasonable nutrition and activity [270]. There should be a proactive strategy for controlling weight gain with specific strategies if a patient gains a threshold amount of weight. A first-line approach could be a nonpharmacological programme like Weight-Watchers; a second-line pharmacological approach might include a drug like topiramate [271], which has been shown to reduce weight gain with olanzapine [272], at least does not have mood-destabilizing properties, and can be effective in other concomitant problems in bipolar disorder. In addition to these effects on glucose metabolism and weight, second-generation antipsychotics can be associated with unfavourable lipid effects, including increases in cholesterol and triglycerides [273]. These should therefore be monitored during treatment, and approached using dietary and, if necessary, pharmacological treatments: . Movement disorders: All second-generation antipsychotics can cause acute drug-induced parkinsonism or akathisia; these effects may be more common in risperidone, aripiprazole and ziprasidone and less common in quetiapine [274]. The incidence may be substantially higher in clinical practice than that reported in clinical trials [275]. In addition to these dose-dependent, acute side effects, second-generation antipsychotic treatments can be associated with tardive dyskinesia, other tardive movement disorders like tardive dystonia and neuroleptic malignant syndrome [275]. Incidence varies across individual drugs, but all second-generation drugs, even clozapine [112,113], have convincing reports of tardive dyskinesia and neuroleptic malignant syndrome. Patients need to be aware of these possibilities from the start, so they can collaborate in effective monitoring and treatment.
Second-generation antipsychotics in pregnancy As noted above, effective treatment during and following pregnancy are highly important, and this need has to be balanced with the requirements for a safe pregnancy. There appears to be little evidence for foetal malformations associated with second-generation antipsychotic drugs [276]. Metabolic effects can be significant, including apparent increases in gestational diabetes and in weight of the newborn infant [277]. Gestational diabetes mellitus associated with olanzapine treatment, as with diabetes mellitus outside of pregnancy, can occur in the absence of drug-induced weight gain [278]. Antidepressive agents Antidepressive agents have never been shown to prevent depressive recurrence in bipolar disorder; there are seven negative trials [51]. In addition, mood destabilization appears greater during extended treatment than during
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single episodes [279], and their long-term use has been associated with cycle acceleration [280], loss of initial response [280,281] and the emergence of chronic irritability and dysphoria [282]. In a large prospective study, antidepressive drugs or placebo were added to ongoing moodstabilizing treatment in patients who developed depressive episodes; antidepressants were no more effective than placebo [283]. Yet, antidepressant use is common in bipolar disorder, and some patients appear to benefit. In a naturalistic study, Ghaemi and Goodwin reported that about 20% of outpatients benefited from addition of antidepressive to moodstabilizing treatments [284]. Altshuler et al. conducted retrospective (n ¼ 44) [53] and prospective (n ¼ 84) [52] studies, finding that patients in whom antidepressants were discontinued did worse than those in whom they were continued, with more depressions and without less mood instability. It must be kept in mind, however, that these patients:(1) had depressive episodes that had not responded to mood stabilizing treatments; (2) responded to antidepressants; and (3) tolerated antidepressants without mood instability for at least six weeks before they entered the study group. This produced a relatively rarified sample of less than 20% of the original subjects [52]. Furthermore,
there was no information about the patients course of illness, previous treatment responses or reasons for discontinuing antidepressant treatment. It is possible that patients who discontinued antidepressive treatments may have done so because of emerging problems or the loss of response that has been reported in bipolar disorder [280,281]. Withdrawal of antidepressant treatment can also result in manic episodes [285], even in patients taking moodstabilizing treatments [286]. There is not much information on the frequency, but one chart review found withdrawal mania in 6 of 73 cases [286]. Characteristics of the unstable form of bipolar disorder, or of a mania-prone course, may predict antidepressantrelated problems [287]. These characteristics include histories of substance-use disorders, a recent manic episode, and many previous episodes of illness.
Summary: practical maintenance pharmacological treatment Table 7 summarizes pharmacological drugs supported by evidence in bipolar disorder. Drugs, where evidence has not been published, are shown because they have demonstrated efficacy in other phases of the illness. In terms of the course
Table 7 Summary of maintenance pharmacological treatments. Treatment
Placebo-controlled RCT
Non-placebo or adjunctive RCT
Other uses
Remarks/course
Lithium
Mania (enriched or nonenriched) > Depression Mania (enriched only), Depression Depression (enriched)
General
Suicidality?
General
Substance abuse, anxiety Substance abuse, anxiety
Manic-prone, episodicstable, familial Unstable course?
Valproate Lamotrigine Carbamazepine Olanzapine Aripiprazole Quetiapine
Depression Mania
Antidepressants
Mania, Depression (enriched) Mania (enriched) Mania, Depression (enriched; abstract only) Mania, Depression (enriched; abstract only) Mania, Depression (injectable; abstract only) Only negative
Topiramate
None
Clozapine
None
Open label add on
Electroconvulsive treatment
None
Naturalistic
Ziprasidone Risperidone
Depression-prone Mania-prone, unstable course?
General Mania General
Mania-prone Depression-prone?
General (injectable) Positive continuation study
Anxiety Substance use, impulse-control disorders, weight control Impulsive-aggression; suicide?
Depression-prone, episodic stable course
Refractory mania or behavioural disturbances Refractory episodes, or other treatment not usable
Maintenance Treatment
presentations of bipolar disorder, results can be summarized as: 1 Mania-prone: Lithium, olanzapine, aripiprazole and valproate have the best published evidence, while quetiapine, ziprasidone and long-acting injectable risperidone have unpublished (abstract only) studies. 2 Depression-prone: Lamotrigine, valproate, lithium and olanzapine have the best published evidence, while quetiapine has unpublished (abstract only) evidence. 3 Episodic-stable vs. unstable course: Lithium response is strongest with episodic-stable illness, while valproate and carbamazepine may be effective in unstable illness, but evidence for relationships between response and course of illness is still sparse. For depressive episodes not responding to mood stabilizing treatments, antidepressive treatments may be best tolerated by patients with an episodic-stable course of illness. 4 Comorbidities and problems: a. Suicide: Lithium and clozapine may have antisuicide action (although effective prevention of activated depression and provision of a collaborative treatment structure are the most desirable general strategies); b. Substance use: Evidence supports topiramate and valproate, and cognitive-behavioural relapse prevention treatments; c. Anxiety disorders: Sparse evidence supports lamotrigine, valproate and cognitive-behavioural therapy; d. Weight gain: proactive management; topiramate is probably the best-proven pharmacological option. 5 Combination treatments: drugs with compatible pharmacokinetics and complementary mechanisms: lithium, valproate or lamotrigine with each other or with a secondgeneration antipsychotic, depending on course of illness and side-effect profile; 6 Treatment-refractory patients: clozapine (mania, impulsive-aggressiveness, suicidality); electroconvulsive treatment (depressive, mania, or mixed). Integrated nonpharmacological treatment is, for most patients, a vital part of optimal treatment; psychoeducation groups for caregivers appear to be a highly efficient strategy. In this context, collaborative, prospective monitoring of life events and prodromal or emergent subsyndromal symptoms is a vital part of treatment that can reduce recurrence of illness and provide the patient with the tools for collaborative mastery of the illness.
References 1. Kessing, L.V., Hansen, M.G., Andersen, P.K. and Angst, J. (2004) The predictive effect of episodes on the risk of recurrence in depressive and bipolar disorders – a life-long perspective. Acta Psychiatr. Scand., 109 (5), 339–344. 2. Begley, C.E., Annegers, J.F., Swann, A.C. et al. (2001) The lifetime cost of bipolar disorder in the US: an estimate for new cases in 1998. Pharmacoeconomics, 19 (5 Pt 1), 483–495.
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3. Gitlin, M.J., Swendsen, J., Heller, T. and Hammen, C. (1995) Relapse and impairment in bipolar disorder. Am. J. Psychiatry, 152, 1635–1640. 4. Jamison, K.R., Gerner, R.H., Hammen, C. and Padesky, C. (1980) Clouds and silver linings: positive experiences associated with primary affective disorders. Am. J. Psychiatry, 137 (2), 198–202. 5. Keller, M.B., Lavori, P.W., Kane, J.M. et al. (1992) Subsyndromal symptoms in bipolar disorder. A comparison of standard and low serum levels of lithium. Arch. Gen. Psychiatry, 49 (5), 371–376. 6. Martinez-Aran, A., Vieta, E., Chengappa, K.N. et al. (2008) Reporting outcomes in clinical trials for bipolar disorder: a commentary and suggestions for change. Bipolar Disord., 10 (5), 566–579. 7. Frye, M.A. and Salloum, I.M. (2006) Bipolar disorder and comorbid alcoholism: prevalence rate and treatment considerations. Bipolar Disord., 8 (6), 677–685. 8. Kulhara, P., Basu, D., Mattoo, S.K. et al. (1999) Lithium prophylaxis of recurrent bipolar affective disorder: longterm outcome and its psychosocial correlates. J. Affect. Disord., 54 (1–2), 87–96. 9. Guscott, R. and Taylor, L. (1994) LIthium prophylaxis in recurrent affective illness. Efficacy, effectiveness, and efficiency. Br. J. Psychiatry, 164, 741–746. 10. Joyce, P.R., Doughty, C.J., Wells, J.E. et al. (2004) Affective disorders in the first-degree relatives of bipolar probands: Results from the south island bipolar study. Compr. Psychiatry, 45 (3), 168–174. 11. Pope, M. and Scott, J. (2003) Do clinicians understand why individuals stop taking lithium? J. Affect. Disord., 74 (3), 287–291. 12. Gonzalez-Pinto, A., Mosquera, F., Alonso, M. et al. (2006) Suicidal risk in bipolar I disorder patients and adherence to long-term lithium treatment. Bipolar Disord., 8 (5 Pt 2), 618–624. 13. Greenhouse, J.B., Stangl, D., Kupfer, D.J. and Prien, R.F. (1991) Methodologic issues in maintenance therapy clinical trials. Arch. Gen. Psychiatry, 48, 131–318. 14. Bowden, C.L., Swann, A.C., Calabrese, J.R. et al. (1997) Maintenance clinical trials in bipolar disorder: design implications of the divalproex-lithium-placebo study. Psychopharmacol. Bull., 33 (4), 693–699. 15. Bowden, C.L., Calabrese, J.R., Walin, B.A. et al. (1995) Who enters therapeutic trials? Illness characteristics of patients in clinical drug studies of mania. Psychopharmacol. Bull., 31, 103–109. 16. Quitkin, F.M., Rabkin, J.G. and Prien, R.F. (1986) Bipolar disorder: are there manic-prone and depressive-prone forms? J. Clin. Psychopharmacol., 6 (3), 167–172. 17. Perugi, G., Micheli, C., Akiskal, H.S. et al. (2000) Polarity of the first episode, clinical characteristics, and course of manic depressive illness: a systematic retrospective investigation of 320 bipolar I patients. Compr. Psychiatry, 41 (1), 13–18. 18. Calabrese, J.R., Vieta, E., el Mallakh, R. et al. (2004) Mood state at study entry as predictor of the polarity of relapse in bipolar disorder. Biol. Psychiatry, 56 (12), 957–963.
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|
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19. Bowden, C.L., Calabrese, J.R., Sachs, G. et al. (2003) A placebo-controlled 18-month trial of lamotrigine and lithium maintenance treatment in recently manic or hypomanic patients with bipolar I disorder. Arch. Gen. Psychiatry, 60 (4), 392–400. 20. Calabrese, J.R., Bowden, C.L., Sachs, G. et al. (2003) A placebo-controlled 18-month trial of lamotrigine and lithium maintenance treatment in recently depressed patients with bipolar I disorder. J. Clin. Psychiatry, 64 (9), 1013–1024. 21. Duffy, A., Alda, M., Kutcher, S. et al. (2002) A prospective study of the offspring of bipolar parents responsive and nonresponsive to lithium treatment. J. Clin. Psychiatry, 63 (12), 1171–1178. 22. Gelenberg, A.J., Kane, J.M. and Keller, M.B. (1989) Comparison of standard and low serum levels of lithium for maintenance treatment of bipolar disorders. N. Engl. J. Med., 321, 1489–1493. 23. Maj, M., Pirozzi, R. and Magliano, L. (1996) Late nonresponse to lithium prophylaxis in bipolar patients: prevalence and predictors. J. Affect. Disord., 39 (1), 39–42. 24. Kleindienst, N., Engel, R. and Greil, W. (2005) Which clinical factors predict response to prophylactic lithium? A systematic reviewforbipolardisorders.Bipolar Disord.,7(5),404–417. 25. OConnell, R.A., Mayo, J.A., Flatow, L. et al. (1991) Outcome of bipolar disorder on long-term treatment with lithium. Br. J. Psychiatry, 159, 123–129. 26. Harrow, M., Goldberg, J.F., Grossman, L.S. and Meltzer, H. Y. (1990) Outcome in manic disorders. A naturalistic followup study. Arch. Gen. Psychiatry, 47, 665–671. 27. Kraepelin, E. (1921) Manic-Depressive Illness and Paranoia, E & S Livingstone, Edinburgh, Scotland. 28. Garnham, J., Munro, A., Slaney, C. et al. (2007) Prophylactic treatment response in bipolar disorder: results of a naturalistic observation study. J. Affect. Disord., 104 (1–3), 185–190. 29. Baldessarini, R.J., Tondo, L., Faedda, G.L. et al. (1996) Effects of the rate of discontinuing lithium maintenance treatment in bipolar disorders. J. Clin. Psychiatry, 57, 441–448. 30. Perlis, R.H., Sachs, G.S., Lafer, B. et al. (2002) Effect of abrupt change from standard to low serum levels of lithium: a reanalysis of double-blind lithium maintenance data. Am. J. Psychiatry, 159 (7), 1155–1159. 31. Franks, M.A., Macritchie, K.A., Mahmood, T. and Young, A. H. (2008) Bouncing back: is the bipolar rebound phenomenon peculiar to lithium? A retrospective naturalistic study. J. Psychopharmacol., 22 (4), 452–456. 32. Vieta, E. and Carne, X. (2005) The use of placebo in clinical trials on bipolar disorder: a new approach for an old debate. Psychother. Psychosom., 74 (1), 10–16. 33. Goodnick, P.J., Fieve, R.R., Schlegel, A. and Baxter, N. (1987) Predictors of interepisode symptoms and relapse in affective disorder patients treated with lithium carbonate. Am. J. Psychiatry, 144 (3), 367–369. 34. DerSimonian, R. and Levine, R.J. (1999) Resolving discrepancies between a meta-analysis and a subsequent large controlled trial. JAMA, 282 (7), 664–670. 35. Shapiro, D.R., Quitkin, F.M. and Fleiss, J.L. (1989) Response to maintenance therapy in bipolar illness. Effect of index episode. Arch. Gen. Psychiatry, 46 (5), 401–405.
36. Baethge, C. and Schlattmann, P. (2004) A survival analysis for recurrent events in psychiatric research. Bipolar Disord., 6 (2), 115–121. 37. Post, R.M., Leverich, G.S., Altshuler, L.L. et al. (2003) An overview of recent findings of the Stanley Foundation Bipolar Network (Part I). Bipolar Disord., 5 (5), 310–319. 38. Judd, L.L., Schettler, P.J., Akiskal, H.S. et al. (2003) Longterm symptomatic status of bipolar I vs. bipolar II disorders. Int. J. Neuropsychopharmacol., 6 (2), 127–137. 39. Citrome, L. (2008) Compelling or irrelevant? Using number needed to treat can help decide. Acta Psychiatr. Scand., 117 (6), 412–419. 40. Sachs, G.S. (1996) Bipolar mood disorder: practical strategies for acute and maintenance phase treatment. [Review] [87 refs]. J. Clin. Psychopharmacol., 16 (2 Suppl. 1), 32S–47S. 41. Schweizer, E., Dever, A. and Clary, C. (1988) Suicide upon recovery from depression. A clinical note. J. Nerv. Ment. Dis., 176, 633–636. 42. Quanbeck, C.D., Stone, D.C., Scott, C.L. et al. (2004) Clinical and legal correlates of inmates with bipolar disorder at time of criminal arrest. J. Clin. Psychiatry, 65 (2), 198–203. 43. Suppes, T., Dennehy, E.B., Hirschfeld, R.M. et al. (2005) The Texas implementation of medication algorithms: update to the algorithms for treatment of bipolar I disorder. J. Clin. Psychiatry, 66 (7), 870–886. 44. Yatham, L.N., Kennedy, S.H., ODonovan, C. et al. (2006) Canadian Network for Mood and Anxiety Treatments (CANMAT) guidelines for the management of patients with bipolar disorder: update 2007. Bipolar Disord., 8 (6), 721–739. 45. McAllister-Williams, R.H. (2006) Relapse prevention in bipolar disorder: a critical review of current guidelines. J. Psychopharmacol., 20 (2 Suppl.), 12–16. 46. Faedda, G.L., Tondo, L., Baldessarini, R.J. et al. (1993) Outcome after rapid vs gradual discontinuation of lithium treatment in bipolar disorders. Arch. Gen. Psychiatry, 50, 448–455. 47. Tohen, M., Chengappa, K.N., Suppes, T. et al. (2004) Relapse prevention in bipolar I disorder: 18-month comparison of olanzapine plus mood stabiliser v. mood stabiliser alone. Br. J. Psychiatry, 184, 337–345. 48. Bowden, C.L., Myers, J.E., Grossman, F. and Xie, Y. (2004) Risperidone in combination with mood stabilizers: a 10week continuation phase study in bipolar I disorder. J. Clin. Psychiatry, 65 (5), 707–714. 49. Bowden, C.L., Grunze, H., Mullen, J. et al. (2005) A randomized, double-blind, placebo-controlled efficacy and safety study of quetiapine or lithium as monotherapy for mania in bipolar disorder. J. Clin. Psychiatry, 66 (1), 111–121. 50. McIntyre, R.S., Brecher, M., Paulsson, B. et al. (2005) Quetiapine or haloperidol as monotherapy for bipolar mania – a 12-week, double-blind, randomised, parallel-group, placebo-controlled trial. Eur. Neuropsychopharmacol., 15 (5), 573–585. 51. Ghaemi, S.N., Lenox, M.S. and Baldessarini, R.J. (2001) Effectiveness and safety of long-term antidepressant treatment in bipolar disorder. J. Clin. Psychiatry, 62 (7), 565–569. 52. Altshuler, L., Suppes, T., Black, D. et al. (2003) Impact of antidepressant discontinuation after acute bipolar
Maintenance Treatment
53.
54.
55.
56.
57. 58.
59. 60.
61.
62.
63.
64.
65.
66.
67.
68.
depression remission on rates of depressive relapse at 1-year follow-up. Am. J. Psychiatry, 160 (7), 1252–1262. Altshuler, L., Kiriakos, L., Calcagno, J. et al. (2001) The impact of antidepressant discontinuation versus antidepressant continuation on 1-year risk for relapse of bipolar depression: a retrospective chart review. J. Clin. Psychiatry, 62 (8), 612–616. Frye,M.A.,Yatham,L.N., Calabrese, J.R. etal.(2006)Incidence and time course of subsyndromal symptoms in patients with bipolar I disorder: an evaluation of 2 placebo-controlled maintenance trials. J. Clin. Psychiatry, 67 (11), 1721–1728. Wittchen, H.U., Mhlig, S. and Pezawas, L. (2003) Natural course and burden of bipolar disorders This paper is a revised version of a presentation held at the CINP International Workshop, St Tropez, France, 3–6 September 2001. Int. J. Neuropsychopharmacol., 6 (2), 145–154. Lam, D., Wong, G. and Sham, P. (2001) Prodromes, coping strategies and course of illness in bipolar affective disorder – a naturalistic study. Psychol. Med., 31 (8), 1397–1402. Fava, G.A. and Kellner, R. (1991) Prodromal symptoms in affective disorders. Am. J. Psychiatry, 148, 823–830. Post, R.M., Roy Byrne, P.P. and Uhde, T.W. (1988) Graphic representation of the life course of illness in patients with affective disorder. Am. J. Psychiatry, 145, 844–848. Schou, M. (1986) Lithium treatment: a refresher course. Br. J. Psychiatry, 149, 541–547. Perlick, D., Clarkin, J.F., Sirey, J. et al. (1999) Burden experienced by care-givers of persons with bipolar affective disorder. Br. J. Psychiatry, 175, 56–62. Perlick, D.A., Rosenheck, R.R., Clarkin, J.F. et al. (2001) Impact of family burden and patient symptom status on clinical outcome in bipolar affective disorder. J. Nerv. Ment. Dis., 189 (1), 31–37. Miklowitz, D.J. (2006) A review of evidence-based psychosocial interventions for bipolar disorder. J. Clin. Psychiatry, 67 (Suppl. 11), 28–33. Reinares, M., Colom, F., Sanchez-Moreno, J. et al. (2008) Impact of caregiver group psychoeducation on the course and outcome of bipolar patients in remission: a randomized controlled trial. Bipolar Disord., 10 (4), 511–519. Bora, E., Vahip, S., Akdeniz, F. et al. (2007) The effect of previous psychotic mood episodes on cognitive impairment in euthymic bipolar patients. Bipolar Disord., 9 (5), 468–477. Calabrese, J.R., Suppes, T., Bowden, C.L. et al. (2000) A double-blind, placebo-controlled, prophylaxis study of lamotrigine in rapid-cycling bipolar disorder. Lamictal 614 Study Group. J. Clin. Psychiatry, 61 (11), 841–850. Tohen, M., Ketter, T.A., Zarate, C.A. et al. (2003) Olanzapine versus divalproex sodium for the treatment of acute mania and maintenance of remission: a 47-week study. Am. J. Psychiatry, 160 (7), 1263–1271. Tohen, M., Greil, W., Calabrese, J.R. et al. (2005) Olanzapine versus lithium in the maintenance treatment of bipolar disorder: a 12-month, randomized, double-blind, controlled clinical trial. Am. J. Psychiatry, 162 (7), 1281–1290. Davis, J.M., Janicak, P.G. and Hogan, D.M. (1999) Mood stabilizers in the prevention of recurrent affective
69.
70.
71.
72.
73.
74.
75.
76.
77.
78.
79.
80.
81.
82.
83.
|
325
disorders: a meta-analysis. Acta Psychiatr. Scand., 100 (6), 406–417. Coxhead, N., Silverstone, T. and Cookson, J. (1992) Carbamazepine versus lithium in the prophylaxis of bipolar affective disorder. Acta Psychiatr. Scand., 85 (2), 114–118. Dardennes, R., Even, C., Bange, F. and Heim, A. (1995) Comparison of carbamazepine and lithium in the prophylaxis of bipolar disorders. A meta-analysis. Br. J. Psychiatry, 166 (3), 378–381. Greil, W., Kleindienst, N., Erazo, N. and Muller-Oerlinghausen, B. (1998) Differential response to lithium and carbamazepine in the prophylaxis of bipolar disorder. J. Clin. Psychopharmacol., 18 (6), 455–460. Kleindienst, N. and Greil, W. (2000) Differential efficacy of lithium and carbamazepine in the prophylaxis of bipolar disorder: results of the MAP study. Neuropsychobiology, 42 (Suppl. 1), 2–10. Hartong, E.G., Moleman, P., Hoogduin, C.A. et al. (2003) Prophylactic efficacy of lithium versus carbamazepine in treatment-naive bipolar patients. J. Clin. Psychiatry, 64 (2), 144–151. Denicoff, K.D., Smith-Jackson, E.E., Disney, E.R. et al. (1997) Comparative prophylactic efficacy of lithium, carbamazepine, and the combination in bipolar disorder. J. Clin. Psychiatry, 58 (11), 470–478. Calabrese, J.R., Shelton, M.D., Rapport, D.J. et al. (2005) A 20month, double-blind, maintenance trial of lithium versus divalproex in rapid-cycling bipolar disorder. Am. J. Psychiatry, 162 (11), 2152–2161. Vieta, E., Suppes, T., Eggens, I. et al. (2008) Efficacy and safety of quetiapine in combination with lithium or divalproex for maintenance of patients with bipolar I disorder (international trial 126). J. Affect. Disord., 109 (3), 251–263. Ghaemi, S.N., Schrauwen, E., Klugman, J. et al. (2006) Longterm lamotrigine plus lithium for bipolar disorder: One year outcome. J. Psychiatr. Pract., 12 (5), 300–305. Pisani, F., Oteri, G., Russo, M.F. et al. (1999) The efficacy of valproate-lamotrigine comedication in refractory complex partial seizures: evidence for a pharmacodynamic interaction. Epilepsia, 40 (8), 1141–1146. Faught, E., Morris, G., Jacobson, M. et al. (1999) Adding lamotrigine to valproate: incidence of rash and other adverse effects. Postmarketing Antiepileptic Drug Survey (PADS) Group. Epilepsia, 40 (8), 1135–1140. Petrides, G., Dhossche, D., Fink, M. and Francis, A. (1994) Continuation ECT: relapse prevention in affective disorders. Conv. Ther., 10, 189–194. Brown, E.S., Nejtek, V.A., Perantie, D.C. et al. (2003) Lamotrigine in patients with bipolar disorder and cocaine dependence. J. Clin. Psychiatry, 64 (2), 197–201. Vanelle, J.M., Loo, H., Galinowski, A. et al. (1994) Maintenance ECT in intractable manic-depressive disorders. Conv. Ther, 10 (3), 195–205. Vaidya, N.A., Mahableshwarkar, A.R. and Shahid, R. (2003) Continuation and maintenance ECT in treatment-resistant bipolar disorder. J. ECT, 19 (1), 10–16.
326
|
Chapter 24
84. Walker, R. and Swartz, C.M. (1994) Electroconvulsive therapy during high-risk pregnancy. Gen. Hosp. Psychiatry, 16 (5), 348–353. 85. Miller, L.J. (1994) Use of electroconvulsive therapy during pregnancy. Hosp. Community Psychiatry, 45, 444–450. 86. Echevarria, M.M., Martin, M.J., Sanchez, V.J. and Vazquez, G.T. (1998) Electroconvulsive therapy in the first trimester of pregnancy. J. ECT, 14 (4), 251–254. 87. Polster, D.S. and Wisner, K.L. (1999) ECT-induced premature labor: a case report [letter]. J. Clin. Psychiatry, 60 (1), 53–54. 88. Bhatia, S.C., Baldwin, S.A. and Bhatia, S.K. (1999) Electroconvulsive therapy during the third trimester of pregnancy. J. ECT, 15 (4), 270–274. 89. Small, J.G., Klapper, M.H., Kellams, J.J. et al. (1988) Electroconvulsive treatment compared with lithium in the management of manic states. Arch. Gen. Psychiatry, 45, 727–732. 90. Steif, B.L., Sackeim, H.A., Portnoy, S. et al. (1986) Effects of depression and ECT on anterograde memory. Biol. Psychiatry, 21 (10), 921–930. 91. Selden, N.R., Robbins, T.W. and Everitt, B.J. (1990) Enhanced behavioral conditioning to context and impaired behavioral and neuroendocrine responses to conditioned stimuli following ceruleocortical noradrenergic lesions: support for an attentional hypothesis of central noradrenergic function. J. Neurosci., 10 (2), 531–539. 92. Jha, A.K., Stein, G.S. and Fenwick, P. (1996) Negative interaction between lithium and electroconvulsive therapy – a case-control study. Br. J. Psychiatry, 168 (2), 241–243. 93. Fehr, B.S., Ozcan, M.E. and Suppes, T. (2005) Low doses of clozapine may stabilize treatment-resistant bipolar patients. Eur. Arch. Psychiatry Clin. Neurosci., 255 (1), 10–14. 94. Suppes, T., McElroy, S.L., Gilbert, J. et al. (1992) Clozapine in the treatment of dysphoric mania. Biol. Psychiatry, 32 (3), 270–280. 95. Zarate, C.A. Jr, Tohen, M. and Baldessarini, R.J. (1995) Clozapine in severe mood disorders. J. Clin. Psychiatry, 56, 411–417. 96. Chanpattana, W. (2000) Combined ECT and clozapine in treatment-resistant mania. J. ECT, 16 (2), 204–207. 97. Merette, C., Roy-Gagnon, M.H., Ghazzali, N. et al. (2000) Anticipation in schizophrenia and bipolar disorder controlling for an information bias. Am. J. Med. Genet., 96 (1), 61–68. 98. Ciapparelli, A., Ducci, F., Carmassi, C. et al. (2004) Predictors of response in a sample of treatment-resistant psychotic patients on clozapine. Eur. Arch. Psychiatry Clin. Neurosci., 254 (5), 343–346. 99. Suppes, T., Webb, A., Paul, B. et al. (1999) Clinical outcome in a randomized 1-year trial of clozapine versus treatment as usual for patients with treatment-resistant illness and a history of mania. Am. J. Psychiatry, 156 (8), 1164–1169. 100. Buckley, P., Bartell, J., Donenwirth, K. et al. (1995) Violence and schizophrenia: clozapine as a specific antiaggressive agent. Bull. Am. Acad. Psychiatry Law, 23 (4), 607–611. 101. Volavka, J. (1999) The effects of clozapine on aggression and substance abuse in schizophrenic patients. J. Clin. Psychiatry, 60 (Suppl. 12), 43–46.
102. Rabinowitz, J., Avnon, M. and Rosenberg, V. (1996) Effect of clozapine on physical and verbal aggression. Schizophr. Res., 22 (3), 249–255. 103. Ernst, C.L. and Goldberg, J.F. (2004) Antisuicide properties of psychotropic drugs: a critical review. Harv. Rev. Psychiatry, 12 (1), 14–41. 104. Spivak, B., Roitman, S., Vered, Y. et al. (1998) Diminished suicidal and aggressive behavior, high plasma norepinephrine levels, and serum triglyceride levels in chronic neuroleptic-resistant schizophrenic patients maintained on clozapine. Clin. Neuropharmacol., 21 (4), 245–250. 105. Meltzer, H.Y., Alphs, L., Green, A.I. et al. (2003) Clozapine treatment for suicidality in schizophrenia: International Suicide Prevention Trial (InterSePT). Arch. Gen. Psychiatry, 60 (1), 82–91. 106. Melkersson, K. and Dahl, M.L. (2004) Adverse metabolic effects associated with atypical antipsychotics: literature review and clinical implications. Drugs, 64 (7), 701–723. 107. Citrome, L., Jaffe, A., Levine, J. et al. (2004) Relationship between antipsychotic medication treatment and new cases of diabetes among psychiatric inpatients. Psychiatr. Serv., 55 (9), 1006–1013. 108. Maule, S., Giannella, R., Lanzio, M. and Villari, V. (1999) Diabetic ketoacidosis with clozapine treatment [letter]. Diabetes Nutr. Metab., 12 (2), 187–188. 109. Esposito, D., Rouillon, F. and Limosin, F. (2005) Continuing clozapine treatment despite neutropenia. Eur. J. Clin. Pharmacol., 60 (11), 759–764. 110. Young, C.R., Bowers, M.B. Jr and Mazure, C.M. (1998) Management of the adverse effects of clozapine. Schizophr. Bull., 24 (3), 381–390. 111. Facciola, G., Avenoso, A., Scordo, M.G. et al. (1999) Small effects of valproic acid on the plasma concentrations of clozapine and its major metabolites in patients with schizophrenic or affective disorders. Ther. Drug Monit., 21 (3), 341–345. 112. Hasan, S. and Buckley, P. (1998) Novel antipsychotics and the neuroleptic malignant syndrome: a review and critique. Am. J. Psychiatry, 155 (8), 1113–1116. 113. Ahmed, S., Chengappa, K.N., Naidu, V.R. et al. (1998) Clozapine withdrawal-emergent dystonias and dyskinesias: a case series. J. Clin. Psychiatry, 59 (9), 472–477. 114. Kampman, K.M., Pettinati, H.M., Volpicelli, J.R. et al. (2004) Cocaine dependence severity predicts outcome in outpatient detoxification from cocaine and alcohol. Am. J. Addict., 13 (1), 74–82. 115. Dackis, C.A., Kampman, K.M., Lynch, K.G. et al. (2005) A double-blind, placebo-controlled trial of modafinil for cocaine dependence. Neuropsychopharmacology, 30 (1), 205–211. 116. Kampman, K.M., Pettinati, H., Lynch, K.G. et al. (2003) A pilot trial of olanzapine for the treatment of cocaine dependence. Drug Alcohol. Depend., 70 (3), 265–273. 117. Reid, M.S., Casadonte, P., Baker, S. et al. (2005) A placebocontrolled screening trial of olanzapine, valproate, and coenzyme Q10/L-carnitine for the treatment of cocaine dependence. Addiction, 100 (Suppl. 1), 43–57.
Maintenance Treatment 118. Loebl, T., Angarita, G.A., Pachas, G.N. et al. (2008) A randomized, double-blind, placebo-controlled trial of longacting risperidone in cocaine-dependent men. J. Clin. Psychiatry, 69 (3), 480–486. 119. Montoya, I.D., Levin, F.R., Fudala, P.J. and Gorelick, D.A. (1995) Double-blind comparison of carbamazepine and placebo for treatment of cocaine dependence. Drug Alcohol. Depend., 38 (3), 213–219. 120. Johnson, B.A., Ait-Daoud, N., Bowden, C.L. et al. (2003) Oral topiramate for treatment of alcohol dependence: a randomised controlled trial. Lancet, 361 (9370), 1677–1685. 121. Brady, K.T., Myrick, H., Henderson, S. and Coffey, S.F. (2002) The use of divalproex in alcohol relapse prevention: a pilot study. Drug Alcohol. Depend., 67 (3), 323–330. 122. Kampman, K.M., Pettinati, H.M., Lynch, K.G. et al. (2007) A double-blind, placebo-controlled pilot trial of quetiapine for the treatment of Type A and Type B alcoholism. J. Clin. Psychopharmacol., 27 (4), 344–351. 123. Lejoyeux, M. and Ades, J. (1993) Evaluation of lithium treatment in alcoholism. Alcohol Alcohol., 28 (3), 273–279. Schmitz, J.M., Averill, P., Sayre, S.L. et al. (2002) Cognitive124. Q1 behavioral treatment of bipolar disorder and substance abuse: A preliminary randomized study. Addictive Disorders and Their Treatment, 1, 17–24. 125. Weiss, R.D., Najavits, L.M. and Greenfield, S.F. (1999) A relapse prevention group for patients with bipolar and substance use disorders. J. Subst. Abuse Treat., 16 (1), 47–54. 126. Weiss, R.D., Griffin, M.L., Kolodziej, M.E. et al. (2007) A randomized trial of integrated group therapy versus group drug counseling for patients with bipolar disorder and substance dependence. Am. J. Psychiatry, 164 (1), 100–107. 127. Weiss, R.D., Kolodziej, M.E., Najavits, L.M. et al. (2000) Utilization of psychosocial treatments by patients diagnosed with bipolar disorder and substance dependence. Am. J. Addict., 9 (4), 314–320. 128. Angst, F., Stassen, H.H., Clayton, P.J. and Angst, J. (2002) Mortality of patients with mood disorders: follow-up over 34–38 years. J. Affect. Disord., 68 (2–3), 167–181. 129. Tondo, L., Baldessarini, R.J., Hennen, J. et al. (1998) Lithium treatment and risk of suicidal behavior in bipolar disorder patients. J. Clin. Psychiatry, 59 (8), 405–414. 130. Maser, J.D., Akiskal, H.S., Schettler, P. et al. (2002) Can temperament identify affectively ill patients who engage in lethal or near-lethal suicidal behavior? A 14-year prospective study. Suicide Life Threat. Behav., 32 (1), 10–32. 131. Dilsaver, S.C., Chen, Y.R., Swann, A.C. et al. (1995) Suicidality in patients with pure and depressive mania. Am. J. Psychiatry, 151, 1312–1315. 132. Dalton, E.J., Cate-Carter, T.D., Mundo, E. et al. (2003) Suicide risk in bipolar patients: the role of comorbid substance use disorders. Bipolar Disord., 5 (1), 58–61. 133. Swann, A.C., Dougherty, D.M., Pazzaglia, P.J. et al. (2004) Impulsivity: A link between bipolar disorder and substance abuse. Bipolar Disord., 6, 204–212. 134. Tondo, L., Hennen, J. and Baldessarini, R.J. (2001) Lower suicide risk with long-term lithium treatment in major affective illness: a meta-analysis. Acta Psychiatr. Scand., 104 (3), 163–172.
|
327
135. Tondo, L., Baldessarini, R.J., Hennen, J. et al. (1998) Lithium treatment and risk of suicidal behavior in bipolar disorder patients. J. Clin. Psychiatry, 59 (8), 405–414. 136. Cipriani, A., Pretty, H., Hawton, K. and Geddes, J.R. (2005) Lithium in the prevention of suicidal behavior and all-cause mortality in patients with mood disorders: a systematic review of randomized trials. Am. J. Psychiatry, 162 (10), 1805–1819. 137. Coppen, A., Standish-Barry, H., Bailey, J. et al. (1991) Does lithium reduce the mortality of recurrent mood disorders? J. Affect. Disord., 23 (1), 1–7. 138. Muller-Oerlinghausen, B., Wolf, T., Ahrens, B. et al. (1996) Mortality of patients who dropped out from regular lithium prophylaxis: a collaborative study by the International Group for the Study of Lithium-treated patients (IGSLI). Acta Psychiatr. Scand., 94 (5), 344–347. 139. Bouman, T.K., Niemantsverdriet van, K.J.G., Ormel, J., and Slooff, C.J. (1986) The effectiveness of lithium prophylaxis in bipolar and unipolar depressions and schizo-affective disorders. J. Affect. Disord., 11, 275–280. 140. Gasperini, M., Scherillo, P., Manfredonia, M.G. et al. (1993) A study of relapses in subjects with mood disorder on lithium treatment. Eur. Neuropsychopharmacol., 3 (2), 103–110. 141. Simpson, S.G. and Jamison, K.R. (1999) The risk of suicide in patients with bipolar disorders. [Review] [19 refs]. J. Clin. Psychiatry, 60 (Suppl. 2), 53–56. 142. Sachs, G.S., Yan, L.J., Swann, A.C. and Allen, M.H. (2001) Integration of suicide prevention into outpatient management of bipolar disorder. J. Clin. Psychiatry, 62 (Suppl. 25), 3–11. 143. Kallner, G., Lindelius, R., Petterson, U. et al. (2000) Mortality in 497 patients with affective disorders attending a lithium clinic or after having left it. Dig. Dis. Sci., 33 (1), 8–13. 144. Freeman, M.P., Freeman, S.A. and McElroy, S.L. (2002) The comorbidity of bipolar and anxiety disorders: prevalence, psychobiology, and treatment issues. J. Affect. Disord., 68 (1), 1–23. 145. Chen, Y.W. and Dilsaver, S.C. (1995) Comorbidity for obsessive-compulsive disorder in bipolar and unipolar disorders. Psychiatry Res., 59 (1–2), 57–64. 146. Edmonds, L.K., Mosley, B.J., Admiraal, A.J. et al. (1998) Familial bipolar disorder: preliminary results from the Otago Familial Bipolar Genetic Study. Aust. NZ J. Psychiatry, 32 (6), 823–829. 147. Young, L.T., Cooke, R.G., Robb, J.C. et al. (1993) Anxious and non-anxious bipolar disorder. J. Affect. Disord., 29 (1), 49–52. 148. Sheehan, D.V., McElroy, S.L., Harnett-Sheehan, K. et al. (2008) Randomized, placebo-controlled trial of risperidone for acute treatment of bipolar anxiety. J. Affect. Disord., 115 (3), 376–385. 149. Corya, S.A., Perlis, R.H., Keck, P.E. Jr et al. (2006) A 24-week open-label extension study of olanzapine-fluoxetine combination and olanzapine monotherapy in the treatment of bipolar depression. J. Clin. Psychiatry, 67 (5), 798–806. 150. Davis, L.L., Bartolucci, A. and Petty, F. (2005) Divalproex in the treatment of bipolar depression: a placebo-controlled study. J. Affect. Disord., 85 (3), 259–266. 151. Maina, G., Albert, U., Rosso, G. and Bogetto, F. (2008) Olanzapine or lamotrigine addition to lithium in remitted
328
152.
153.
154.
155.
156.
157.
158.
159.
160.
161.
162.
163.
164.
165.
166.
167.
|
Chapter 24
bipolar disorder patients with anxiety disorder comorbidity: a randomized, single-blind, pilot study. J. Clin. Psychiatry, 69 (4), 609–616. Keck, P.E., Strawn, J.R. and McElroy, S.L. (2006) Pharmacologic Treatment Considerations in Co-Occurring Bipolar and Anxiety Disorders. J. Clin. Psychiatry, 67 (Suppl. 1), 8–15. Baetz, M. and Bowen, R.C. (1998) Efficacy of divalproex sodium in patients with panic disorder and mood instability who have not responded to conventional therapy. Can. J. Psychiatry, 43 (1), 73–77. Levy, D., Kimhi, R., Barak, Y. et al. (1998) Antidepressantassociated mania: a study of anxiety disorders patients. Psychopharmacology (Berl.), 136 (3), 243–246. Khazaal, Y. (2007) Mania after venlafaxine withdrawal in a patient with generalized anxiety disorder. Ann. Pharmacother., 41 (2), 359–360. Coplan, J.D. and Gorman, J.M. (1990) Treatment of anxiety disorder in patients with mood disorders. J. Clin. Psychiatry, 51 (Suppl.), 9–13. Hollon, S.D., Stewart, M.O. and Strunk, D. (2006) Enduring effects for cognitive behavior therapy in the treatment of depression and anxiety. Annu. Rev. Psychol., 57, 285–315. Simon, N.M., Otto, M.W., Weiss, R.D. et al. (2004) Pharmacotherapy for bipolar disorder and comorbid conditions: baseline data from STEP-BD. J. Clin. Psychopharmacol., 24 (5), 512–520. Carney, S.M. and Goodwin, G.M. (2005) Lithium – a continuing story in the treatment of bipolar disorder. Acta Psychiatr. Scand. Suppl. (426), 7–12. Geddes, J.R., Burgess, S., Hawton, K. et al. (2004) Long-term lithium therapy for bipolar disorder: systematic review and meta-analysis of randomized controlled trials. Am. J. Psychiatry, 161 (2), 217–222. Muller-Oerlinghausen, B. (2001) Arguments for the specificity of the antisuicidal effect of lithium. Eur. Arch. Psychiatry Clin. Neurosci., 251 (Suppl. 2), II72–II75. Grof, P., Duffy, A., Cavazzoni, P. et al. (2002) Is response to prophylactic lithium a familial trait? J. Clin. Psychiatry, 63 (10), 942–947. Licht, R.W., Vestergaard, P. and Brodersen, A. (2008) Longterm outcome of patients with bipolar disorder commenced on lithium prophylaxis during hospitalization: a complete 15-year register-based follow-up. Bipolar Disord., 10 (1), 79–86. Maj, M., Pirozzi, R., Magliano, L. and Bartoli, L. (1998) Longterm outcome of lithium prophylaxis in bipolar disorder: a 5-year prospective study of 402 patients at a lithium clinic. Am. J. Psychiatry, 155 (1), 30–35. Goldberg, J.F., Harrow, M. and Leon, A.C. (1996) Lithium treatment of bipolar affective disorders under naturalistic followup conditions. Psychopharmacol. Bull., 32 (1), 47–54. Post, R.M., Leverich, G.S., Altshuler, L. and Mikalauskas, K. (1992) Lithium-discontinuation-induced refractoriness: preliminary observations. Am. J. Psychiatry, 149 (12), 1727–1729. Maj, M., Pirozzi, R. and Magliano, L. (1995) Nonreponse to reinstituted lithium prophylaxis in previously responsive
168.
169.
170.
171.
172.
173.
174.
175.
176.
177.
178.
179.
180.
181.
182.
183.
bipolar patients: prevalence and predictors. Am. J. Psychiatry, 152, 1810–1811. Yazici, O., Kora, K., Polat, A. and Saylan, M. (2004) Controlled lithium discontinuation in bipolar patients with good response to long-term lithium prophylaxis. J. Affect. Disord., 80 (2–3), 269–271. Fyro, B., Petterson, U. and Sedvall, G. (1973) Pharmacokinetics of lithium in manic-depressive patients. Acta Psychiatr. Scand., 49 (3), 237–247. Perry, P.J., Dunner, F.J., Hahn, R.L. et al. (1981) Lithium kinetics in single daily dosing. Acta Psychiatr. Scand., 64 (4), 281–294. Greil, W., Eisenreid, F., Becker, B.F. and Duhm, J. (1977) Interindividual diferences in the Na þ -dependent Li þ countertransport system and in the Li þ distribution across the red cell membrane among lithium-treated patients. Psychopharmacol., 53, 19–26. Janka, Z. and Jones, D.G. (1982) Lithium entry into neural cells via sodium channels: a morphometric approach. Neuroscience, 7 (11), 2849–2857. Swann, A.C., Berman, N., Frazer, A. et al. (1990) Lithium distribution in mania: single-dose pharmacokinetics and sympathoadrenal function. Psychiatry Res., 32, 71–84. Thomsen, K. and Schou, M. (1999) Avoidance of lithium intoxication: advice based on knowledge about the renal lithium clearance under various circumstances. Dig. Dis. Sci., 32 (3), 83–86. Baer, L., Platman, S.R., Kassir, S. and Fieve, R.R. (1971) Mechanisms of renal lithium handling and their relationship to mineralocorticoids: a dissociation between sodium and lithium ions. J. Psychiatr. Res., 8 (2), 91–105. Armond, A.D. (1998) The social and economic effects of manic depressive illness and of its treatment in lithium clinics. [Review] [17 refs]. Occup. Med., 48 (8), 505–509. Fieve, R.R. (1975) The lithium clinic: a new model for the delivery of psychiatric services. Am. J. Psychiatry, 132 (10), 1018–1022. Kleindienst, N., Severus, W.E. and Greil, W. (2007) Are serum lithium levels related to the polarity of recurrence in bipolar disorders? Evidence from a multicenter trial. Int. Clin. Psychopharmacol., 22 (3), 125–131. Greenspan, K., Goodwin, F.K., Bunney, W.E. and Durell, J. (1968) Lithium ion retention and distribution. Patterns during acute mania and normothymia. Arch. Gen. Psychiatry, 19 (6), 664–673. Kukopoulos, A., Minnai, G. and Muller-Oerlinghausen, B. (1985) The influence of mania and depression on the pharmacokinetics of lithium. A longitudinal single-case study. J. Affect. Disord., 8 (2), 159–166. Atmaca, M., Kuloglu, M., Tezcan, E. and Ustundag, B. (2002) Weight gain and serum leptin levels in patients on lithium treatment. Neuropsychobiology, 46 (2), 67–69. Torrent, C., Amann, B., Sanchez-Moreno, J. et al. (2008) Weight gain in bipolar disorder: pharmacological treatment as a contributing factor. Acta Psychiatr. Scand., 118 (1), 4–18. Roy Chengappa, K.N., Schwarzman, L.K., Hulihan, J.F. et al. (2006) Adjunctive topiramate therapy in patients receiving a
Maintenance Treatment
184.
185.
186. 187.
188.
189. 190.
191.
192.
193.
194.
195.
196.
197.
198.
199.
mood stabilizer for bipolar I disorder: a randomized, placebo-controlled trial. J. Clin. Psychiatry, 67 (11), 1698–1706. Fairbanks, L.A., Jorgensen, M.J., Huff, A. et al. (2004) Adolescent impulsivity predicts adult dominance attainment in male vervet monkeys. Am. J. Primatol., 64 (1), 1–17. Lepkifker, E., Sverdlik, A., Iancu, I. et al. (2004) Renal insufficiency in long-term lithium treatment. J. Clin. Psychiatry, 65 (6), 850–856. Walker, R.G. (1993) Lithium nephrotoxicity. Kidney Int. Suppl., 42, S93–S98. Hetmar, O., Povlsen, U.J., Ladefoged, J. and Bolwig, T.G. (1991) Lithium: long-term effects on the kidney. A prospective follow-up study ten years after kidney biopsy. Br. J. Psychiatry, 158, 53–58. Markowitz, G.S., Radhakrishnan, J., Kambham, N. et al. (2000) Lithium nephrotoxicity: a progressive combined glomerular and tubulointerstitial nephropathy. J. Am. Soc. Nephrol., 11 (8), 1439–1448. Gitlin, M. (1999) Lithium and the kidney: an updated review. Drug Saf., 20 (3), 231–243. Erfurth, A., Amann, B. and Grunze, H. (1998) Female genital disorder as adverse symptom of lamotrigine treatment. A serotoninergic effect? Neuropsychobiology, 38 (3), 200–201. Batlle, D.C., von Riotte, A.B., Gaviria, M. and Grupp, M. (1985) Amelioration of polyuria by amiloride in patients receiving long-term lithium therapy. N. Engl. J. Med., 312 (7), 408–414. Fagiolini, A., Kupfer, D.J., Scott, J. et al. (2006) Hypothyroidism in patients with bipolar I disorder treated primarily with lithium. Epidemiol. Psichiatr. Soc., 15 (2), 123–127. Kallner, G. and Petterson, U. (1995) Renal, thyroid and parathyroid function during lithium treatment: laboratory tests in 207 people treated for 1–30 years. Acta Psychiatr. Scand., 91 (1), 48–51. Chang, Y.C., Lin, H.N. and Deng, H.C. (1990) Subclinical lithium neurotoxicity: correlation of neural conduction abnormalities and serum lithium level in manic-depressive patients with lithium treatment. Acta Neurol. Scand., 82 (2), 82–86. Fountoulakis, K.N., Vieta, E., Bouras, C. et al. (2008) A systematic review of existing data on long-term lithium therapy: neuroprotective or neurotoxic? Int. J. Neuropsychopharmacol., 11 (2), 269–287. Lang, E.J. and Davis, S.M. (2002) Lithium neurotoxicity: the development of irreversible neurological impairment despite standard monitoring of serum lithium levels. J. Clin. Neurosci., 9 (3), 308–309. Kessel, J.B., Verghese, C. and Simpson, G.M. (1992) Neurotoxicity related to lithium and neuroleptic combinations? A retrospective review. J. Psychiatr. Neurosci., 17 (1), 28–30. Roose, S.P., Nurnberger, J.I., Dunner, D.L. et al. (1979) Cardiac sinus node dysfunction during lithium treatment. Am. J. Psychiatry, 136 (6), 804–806. Oudit, G.Y., Korley, V., Backx, P.H. and Dorian, P. (2007) Lithium-induced sinus node disease at therapeutic concentrations: linking lithium-induced blockade of sodium channels to impaired pacemaker activity. Can. J. Cardiol., 23 (3), 229–232.
|
329
200. Steckler, T.L. (1994) Lithium- and carbamazepine-associated sinus node dysfunction: nine-year experience in a psychiatric hospital. J. Clin. Psychopharmacol., 14 (5), 336–339. 201. Dubovsky, S.L., Franks, R.D. and Allen, S. (1987) Verapamil: a new antimanic drug with potential interactions with lithium. J. Clin. Psychiatry, 48, 371–372. 202. Numata, T., Abe, H., Terao, T. and Nakashima, Y. (1999) Possible involvement of hypothyroidism as a cause of lithium-induced sinus node dysfunction. Pacing Clin. Electrophysiol., 22 (6 Pt 1), 954–957. 203. Mamiya, K., Sadanaga, T., Sekita, A. et al. (2005) Lithium concentration correlates with QTc in patients with psychosis. J. Electrocardiol., 38 (2), 148–151. 204. Freeman, M.P. and Freeman, S.A. (2006) Lithium: clinical considerations in internal medicine. Am. J. Med., 119 (6), 478–481. 205. Dodd, S. and Berk, M. (2006) The safety of medications for the treatment of bipolar disorder during pregnancy and the puerperium. Curr. Drug Saf., 1 (1), 25–33. 206. Viguera, A.C., Whitfield, T., Baldessarini, R.J. et al. (2007) Risk of recurrence in women with bipolar disorder during pregnancy: prospective study of mood stabilizer discontinuation. Am. J. Psychiatry, 164 (12), 1817–1824. 207. Cohen, L.S., Friedman, J.M., Jefferson, J.W. et al. (1994) A reevaluation of risk of in utero exposure to lithium. JAMA, 271, 146–150. 208. Krause, S., Ebbesen, F. and Lange, A.P. (1990) Polyhydramnios with maternal lithium treatment. Obstet. Gynecol., 75 (3 Pt 2), 504–506. 209. Chaudron, L.H. and Jefferson, J.W. (2000) Mood stabilizers during breastfeeding: a review. J. Clin. Psychiatry, 61 (2), 79–90. 210. Freeman, M.P. and Gelenberg, A.J. (2005) Bipolar disorder in women: reproductive events and treatment considerations. Acta Psychiatr. Scand., 112 (2), 88–96. 211. Avella, J., Wetli, C.V., Wilson, J.C. et al. (2004) Fatal olanzapine-induced hyperglycemic ketoacidosis. Am. J. Forensic Med. Pathol., 25 (2), 172–175. 212. Bowden, C.L., Calabrese, J.R., McElroy, S.L. et al. (2000) A randomized, placebo-controlled 12-month trial of divalproex and lithium in treatment of outpatients with bipolar I disorder. Divalproex Maintenance Study Group [see comments]. Arch. Gen. Psychiatry, 57 (5), 481–489. 213. Gyulai, L., Bowden, C.L., McElroy, S.L. et al. (2003) Maintenance efficacy of divalproex in the prevention of bipolar depression. Neuropsychopharmacology, 28, 1377–1385. 214. Dickinson, R.G., Bassett, M.L., Searle, J. et al. (1985) Valproate hepatotoxicity: a review and report of two instances in adults. Clin. Exp. Neurol., 21 (9), 79–91. 215. Binek, J., Hany, A. and Heer, M. (1991) Valproic-acid-induced pancreatitis. Case report and review of the literature. J. Clin. Gastroenterol., 13 (6), 690–693. 216. Asconape, J.J., Penry, J.K., Dreifuss, F.E. et al. (1993) Valproateassociated pancreatitis. Epilepsia, 34 (1), 177–183. 217. Tohen, M., Castillo, J., Baldessarini, R.J. et al. (1995) Blood dyscrasias with carbamazepine and valproate: A pharmacoepidemiological study of 2,228 patients at risk. Am. J. Psychiatry, 152, 413–418.
330
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218. Isojarvi, J.I., Laatikainen, T.J., Knip, M. et al. (1996) Obesity and endocrine disorders in women taking valproate for epilepsy [see comments]. Ann. Neurol., 39 (5), 579–584. 219. McIntyre, R.S., Mancini, D.A., McCann, S. et al. (2003) Valproate, bipolar disorder and polycystic ovarian syndrome. Bipolar Disord., 5 (1), 28–35. 220. Rasgon, N. (2004) The relationship between polycystic ovary syndrome and antiepileptic drugs: a review of the evidence. J. Clin. Psychopharmacol., 24 (3), 322–334. 221. Dodd, S. and Berk, M. (2004) The pharmacology of bipolar disorder during pregnancy and breastfeeding. Expert Opin. Drug Saf., 3 (3), 221–229. 222. Kaneko, S., Battino, D., Andermann, E. et al. (1999) Congenital malformations due to antiepileptic drugs. Epilepsy Res., 33 (2–3), 145–158. 223. Viguera, A.C., Cohen, L.S., Baldessarini, R.J. and Nonacs, R. (2002) Managing bipolar disorder during pregnancy: weighing the risks and benefits. Can. J. Psychiatry, 47 (5), 426–436. 224. Kennedy, D. and Koren, G. (1998) Valproic acid use in psychiatry: issues in treating women of reproductive age. J. Psychiatry Neurosci., 23 (4), 223–228. 225. Frick, T.W., Speiser, D.E., Bimmler, D. and Largiader, F. (1993) Drug-induced acute pancreatitis: further criticism. Dig. Dis., 11 (2), 113–132. 226. Bowden, C.L. (2003) Valproate. Bipolar Disord., 5 (3), 189–202. 227. Goodwin, G.M., Bowden, C.L., Calabrese, J.R. et al. (2004) A pooled analysis of 2 placebo-controlled 18-month trials of lamotrigine and lithium maintenance in bipolar I disorder. J. Clin. Psychiatry, 65 (3), 432–441. 228. Calabrese, J.R., Shelton, M.D., Rapport, D.J. and Kimmel, S. E. (2002) Bipolar disorders and the effectiveness of novel anticonvulsants. J. Clin. Psychiatry, 63 (Suppl. 3), 5–9. 229. Dossett, E.C., Land, A.J., Gitlin, M.J. and Frye, M.A. (2007) Lack of mania prophylaxis associated with lamotrigine monotherapy in manic-predominant bipolar I disorder. J. Clin. Psychiatry, 68 (6), 973–974. 230. Calabrese, J.R., Huffman, R.F., White, R.L. et al. (2008) Lamotrigine in the acute treatment of bipolar depression: results of five double-blind, placebo-controlled clinical trials. Bipolar Disord., 10 (2), 323–333. 231. Prien, R.F., Klett, C.J. and Caffey, E.M. Jr (1974) Lithium prophylaxis in recurrent affective illness. Am. J. Psychiatry, 131 (2), 198–203. 232. Calabrese, J.R., Shelton, M.D., Bowden, C.L. et al. (2001) Bipolar rapid cycling: focus on depression as its hallmark. J. Clin. Psychiatry, 62 (Suppl. 14), 34–41. 233. Nassir, G.S., Shirzadi, A.A. and Filkowski, M. (2008) Publication bias and the pharmaceutical industry: the case of lamotrigine in bipolar disorder. Medscape J. Med., 10 (9), 211. 234. Mansur, A.T., Pekcan, Y.S. and Goktay, F. (2008) Anticonvulsant hypersensitivity syndrome: clinical and laboratory features. Int. J. Dermatol., 47 (11), 1184–1189. 235. Leeder, J.S. (1998) Mechanisms of idiosyncratic hypersensitivity reactions to antiepileptic drugs. Epilepsia, 39 (Suppl. 7), S8–S16.
236. Rzany, B., Correia, O., Kelly, J.P. et al. (1999) Risk of StevensJohnson syndrome and toxic epidermal necrolysis during first weeks of antiepileptic therapy: a case-control study. Study Group of the International Case Control Study on Severe Cutaneous Adverse Reactions. Lancet, 353 (9171), 2190–2194. 237. Ketter, T.A., Greist, J.H., Graham, J.A. et al. (2006) The effect of dermatologic precautions on the incidence of rash with addition of lamotrigine in the treatment of bipolar I disorder: a randomized trial. J. Clin. Psychiatry, 67 (3), 400–406. 238. Rahman, M. and Haider, N. (2005) Anticonvulsant hypersensitivity syndrome from addition of lamotrigine to divalproex. Am. J. Psychiatry, 162 (5), 1021. 239. Ketter, T.A., Frye, M.A., Cora-Locatelli, G. et al. (1999) Metabolism and excretion of mood stabilizers and new anticonvulsants. Cell. Mol. Neurobiol., 19 (4), 511–532. 240. Ketter, T.A., Frye, M.A., Cora-Locatelli, G. et al. (1999) Metabolism and excretion of mood stabilizers and new anticonvulsants. Cell. Mol. Neurobiol., 19 (4), 511–532. 241. Riva, R., Albani, F., Contin, M. and Baruzzi, A. (1996) Pharmacokinetic interactions between antiepileptic drugs. Clinical considerations. Clin. Pharmacokinet., 31 (6), 470–493. 242. Chang, S.I. and McAuley, J.W. (1998) Pharmacotherapeutic issues for women of childbearing age with epilepsy. Ann. Pharmacother., 32 (7–8), 794–801. 243. Ohman, I., Vitols, S. and Tomson, T. (2000) Lamotrigine in pregnancy: pharmacokinetics during delivery, in the neonate, and during lactation. Epilepsia, 41 (6), 709–713. 244. Greil, W., Ludwig-Mayerhofer, W., Erazo, N. et al. (1997) Lithium versus carbamazepine in the maintenance treatment of bipolar disorders – a randomised study. J. Affect. Disord., 43, 151–161. 245. Vasudev, A., Macritchie, K., Watson, S. et al. (2008) Oxcarbazepine in the maintenance treatment of bipolar disorder. Cochrane Database Syst. Rev (1), CD005171. 246. Vieta, E., Cruz, N., Garcia-Campayo, J. et al. (2008) A doubleblind, randomized, placebo-controlled prophylaxis trial of oxcarbazepine as adjunctive treatment to lithium in the long-term treatment of bipolar I and II disorder. Int. J. Neuropsychopharmacol., 11 (4), 445–452. 247. De Vriese, A.S., Philippe, J., Van Renterghem, D.M. et al. (1995) Carbamazepine hypersensitivity syndrome: report of 4 cases and review of the literature. Medicine (Baltimore), 74 (3), 144–151. 248. Kaufman, K.R. (1999) Carbamazepine, hepatotoxicity, organic solvents, and paints. Seizure, 8 (4), 250–252. 249. Joffe, R.T., Post, R.M. and Uhde, T.W. (1986) Effect of carbamazepine on body weight in affectively ill patients. J. Clin. Psychiatry, 47 (6), 313–314. 250. Akiskal, H.S., Fuller, M.A., Hirschfeld, R.M. et al. (2005) Reassessing carbamazepine in the treatment of bipolar disorder: clinical implications of new data. CNS Spectr., 10 (6), suppl-11. 251. Dresser, G.K., Spence, J.D. and Bailey, D.G. (2000) Pharmacokinetic-pharmacodynamic consequences and clinical relevance of cytochrome P450 3A4 inhibition. Clin. Pharmacokinet., 38 (1), 41–57.
Maintenance Treatment 252. Murialdo, G., Galimberti, C.A., Gianelli, M.V. et al. (1998) Effects of valproate, phenobarbital, and carbamazepine on sex steroid setup in women with epilepsy. Clin. Neuropharmacol., 21 (1), 52–58. 253. Wilder, B.J. (1992) Pharmacokinetics of valproate and carbamazepine. J. Clin. Psychopharmacol., 12 (Suppl.), 64S–68. 254. Chang, S.L. and Levy, R.H. (1986) Inhibitory effect of valproic acid on the disposition of carbamazepine and carbamazepine-10,11-epoxide in the rat. Drug Metab. Dispos., 14 (3), 281–286. 255. Jones, K.L., Lacro, R.V., Johnson, K.A. and Adams, J. (1989) Pattern of malformations in the children of women treated with carbamazepine during pregnancy. N. Engl. J. Med., 320, 1661–1666. 256. Baethge, C., Baldessarini, R.J., Mathiske-Schmidt, K. et al. (2005) Long-term combination therapy versus monotherapy with lithium and carbamazepine in 46 bipolar I patients. J. Clin. Psychiatry, 66 (2), 174–182. 257. Scherk, H., Pajonk, F.G. and Leucht, S. (2007) Second-generation antipsychotic agents in the treatment of acute mania: a systematic review and meta-analysis of randomized controlled trials. Arch. Gen. Psychiatry, 64 (4), 442–455. 258. Tohen, M., Calabrese, J.R., Sachs, G.S. et al. (2006) Randomized, placebo-controlled trial of olanzapine as maintenance therapy in patients with bipolar I disorder responding to acute treatment with olanzapine. Am. J. Psychiatry, 163 (2), 247–256. 259. Keck, P.E. Jr, Calabrese, J.R., McIntyre, R.S. et al. (2007) Aripiprazole monotherapy for maintenance therapy in bipolar I disorder: a 100-week, double-blind study versus placebo. J. Clin. Psychiatry, 68 (10), 1480–1491. 260. Malempati, R.N., Bond, D.J. and Yatham, L.N. (2008) Depot risperidone in the outpatient management of bipolar disorder: a 2-year study of 10 patients. Int. Clin. Psychopharmacol., 23 (2), 88–94. 261. Vieta, E., Calabrese, J.R., Hennen, J. et al. (2004) Comparison of rapid-cycling and non-rapid-cycling bipolar I manic patients during treatment with olanzapine: analysis of pooled data. J. Clin. Psychiatry, 65 (10), 1420–1428. 262. Muzina, D.J., Momah, C., Eudicone, J.M. et al. (2008) Aripiprazole monotherapy in patients with rapid-cycling bipolar I disorder: an analysis from a long-term, double-blind, placebo-controlled study. Int. J. Clin. Pract., 62 (5), 679–687. 263. Calabrese, J.R., Keck, P.E. Jr, Macfadden, W. et al. (2005) A randomized, double-blind, placebo-controlled trial of quetiapine in the treatment of bipolar I or II depression. Am. J. Psychiatry, 162 (7), 1351–1360. 264. Tohen, M., Vieta, E., Calabrese, J. et al. (2003) Efficacy of olanzapine and olanzapine-fluoxetine combination in the treatment of bipolar I depression. Arch. Gen. Psychiatry, 60 (11), 1079–1088. 265. Thase, M.E., Jonas, A., Khan, A. et al. (2008) Aripiprazole monotherapy in nonpsychotic bipolar I depression: results of 2 randomized, placebo-controlled studies. J. Clin. Psychopharmacol., 28 (1), 13–20. 266. El-Mallakh, R.S. (2007) Medication adherence and the use of long-acting antipsychotics in bipolar disorder. J. Psychiatr. Pract., 13 (2), 79–85.
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267. Bond, D.J., Pratoomsri, W. and Yatham, L.N. (2007) Depot antipsychotic medications in bipolar disorder: a review of the literature. Acta Psychiatr. Scand. Suppl. (434), 3–16. 268. McIntyre, R.S., Mancini, D.A., Basile, V.S. et al. (2003) Antipsychotic-induced weight gain: bipolar disorder and leptin. J. Clin. Psychopharmacol., 23 (4), 323–327. 269. Birt, J. (2003) Management of weight gain associated with antipsychotics. Ann. Clin. Psychiatry, 15 (1), 49–58. 270. Poulin, M.J., Chaput, J.P., Simard, V. et al. (2007) Management of antipsychotic-induced weight gain: prospective naturalistic study of the effectiveness of a supervised exercise programme. Aust. NZ J. Psychiatry, 41 (12), 980–989. 271. McIntyre, R.S., Mancini, D.A., McCann, S. et al. (2002) Topiramate versus bupropion SR when added to mood stabilizer therapy for the depressive phase of bipolar disorder: a preliminary single-blind study. Bipolar Disord., 4 (3), 207–213. 272. Vieta, E., Sanchez-Moreno, J., Goikolea, J.M. et al. (2004) Effects on weight and outcome of long-term olanzapinetopiramate combination treatment in bipolar disorder. J. Clin. Psychopharmacol., 24 (4), 374–378. 273. Almeras, N., Despres, J.P., Villeneuve, J. et al. (2004) Development of an atherogenic metabolic risk factor profile associated with the use of atypical antipsychotics. J. Clin. Psychiatry, 65 (4), 557–564. 274. Gao, K., Kemp, D.E., Ganocy, S.J. et al. (2008) Antipsychoticinduced extrapyramidal side effects in bipolar disorder and schizophrenia: a systematic review. J. Clin. Psychopharmacol., 28 (2), 203–209. 275. Ghaemi, S.N., Hsu, D.J., Rosenquist, K.J. et al. (2006) Extrapyramidal side effects with atypical neuroleptics in bipolar disorder. Prog. Neuropsychopharmacol. Biol. Psychiatry, 30 (2), 209–213. 276. McKenna, K., Koren, G., Tetelbaum, M. et al. (2005) Pregnancy outcome of women using atypical antipsychotic drugs: a prospective comparative study. J. Clin. Psychiatry, 66 (4), 444–449. 277. Newham, J.J., Thomas, S.H., Macritchie, K. et al. (2008) Birth weight of infants after maternal exposure to typical and atypical antipsychotics: prospective comparison study. Br. J. Psychiatry, 192 (5), 333–337. 278. Vemuri, M.P. and Rasgon, N.L. (2007) A case of olanzapineinduced gestational diabetes mellitus in the absence of weight gain. J. Clin. Psychiatry, 68 (12), 1989. 279. Post, R.M., Leverich, G.S., Nolen, W.A. et al. (2003) A reevaluation of the role of antidepressants in the treatment of bipolar depression: data from the Stanley Foundation Bipolar Network. Bipolar Disord., 5 (6), 396–406. 280. Fava, G.A. (2003) Can long-term treatment with antidepressant drugs worsen the course of depression? J. Clin. Psychiatry, 64 (2), 123–133. 281. Sharma, V. (2001) Loss of response to antidepressants and subsequent refractoriness: diagnostic issues in a retrospective case series. J. Affect. Disord., 64 (1), 99–106. 282. Ei-Mallakh, R.S. and Karippot, A. (2005) Antidepressantassociated chronic irritable dysphoria (acid) in bipolar disorder: a case series. J. Affect. Disord., 84 (2–3), 267–272.
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283. Goldberg, J.F., Perlis, R.H., Ghaemi, S.N. et al. (2007) Adjunctive antidepressant use and symptomatic recovery among bipolar depressed patients with concomitant manic symptoms: findings from the STEP-BD. Am. J. Psychiatry, 164 (9), 1348–1355. 284. Ghaemi, S.N., Hsu, D.J., Soldani, F. and Goodwin, F.K. (2003) Antidepressants in bipolar disorder: the case for caution. Bipolar Disord., 5 (6), 421–433. 285. Dilsaver, S.C. and Greden, J.F. (1984) Antidepressant withdrawal-induced activation (hypomania and mania): mechanism and theoretical significance. Brain Res., 319 (1), 29–48. 286. Goldstein, T.R., Frye, M.A., Denicoff, K.D. et al. (1999) Antidepressant discontinuation-related mania: critical prospective observation and theoretical implications in bipolar disorder. J. Clin. Psychiatry, 60 (8), 563–567. 287. MacQueen, G.M., Trevor, Y.L., Marriott, M. et al. (2002) Previous mood state predicts response and switch rates in patients with bipolar depression. Acta Psychiatr. Scand., 105 (6), 414–418. 288. Otto, M.W., Simon, N.M., Wisniewski, S.R. et al. (2006) Prospective 12-month course of bipolar disorder in outpatients with and without comorbid anxiety disorders. Br. J. Psychiatry, 189, 20–25. 289. Fenn, H.H., Bauer, M.S., Alshuler, L. et al. (2005) Medical comorbidity and health-related quality of life in bipolar disorder across the adult age span. J. Affect. Disord., 86 (1), 47–60. 290. Simon, G.E., Von, K.M., Saunders, K. et al. (2006) Association between obesity and psychiatric disorders in the US adult population. Arch. Gen. Psychiatry, 63 (7), 824–830. 291. Sicras, A., Rejas, J., Navarro, R. et al. (2008) Metabolic syndrome in bipolar disorder: a cross-sectional assessment of a Health Management Organization database. Bipolar Disord., 10 (5), 607–616. 292. Dunner, D.L., Stallone, F. and Fieve, R.R. (1976) Lithium carbonate and affective disorders. V: a double-blind study of prophylaxis of depression in bipolar illness. Arch. Gen. Psychiatry, 33 (1), 117–120. 293. Fieve, R.R., Kumbaraci, T. and Dunner, D.L. (1976) Lithium prophylaxis of depression in bipolar I, bipolar II, and unipolar patients. Am. J. Psychiatry, 133 (8), 925–929.
294. Keck, P.E. Jr, Calabrese, J.R., McIntyre, R.S. et al. (2007) Aripiprazole monotherapy for maintenance therapy in bipolar I disorder: a 100-week, double-blind study versus placebo. J. Clin. Psychiatry, 68 (10), 1480–1491. 295. Keck, P.E. Jr, Calabrese, J.R., McQuade, R.D. et al. (2006) A randomized, double-blind, placebo-controlled 26-week trial of aripiprazole in recently manic patients with bipolar I disorder. J. Clin. Psychiatry, 67 (4), 626–637. 296. Brown, E.S., Gorman, A.R. and Hynan, L.S. (2007) A randomized, placebo-controlled trial of citicoline add-on therapy in outpatients with bipolar disorder and cocaine dependence. J. Clin. Psychopharmacol., 27 (5), 498–502. 297. Salloum, I.M., Douaihy, A., Cornelius, J.R. et al. (2007) Divalproex utility in bipolar disorder with co-occurring cocaine dependence: a pilot study. Addict. Behav., 32 (2), 410–415. 298. Brown, E.S., Perantie, D.C., Dhanani, N. et al. (2006) Lamotrigine for bipolar disorder and comorbid cocaine dependence: a replication and extension study. J. Affect. Disord., 93 (1–3), 219–222. 299. Brown, E.S., Nejtek, V.A., Perantie, D.C. et al. (2003) Lamotrigine in patients with bipolar disorder and cocaine dependence. J. Clin. Psychiatry, 64 (2), 197–201. 300. Brown, E.S., Nejtek, V.A., Perantie, D.C. and Bobadilla, L. (2002) Quetiapine in bipolar disorder and cocaine dependence. Bipolar Disord., 4 (6), 406–411. 301. Hanley, M.J. and Kenna, G.A. (2008) Quetiapine: treatment for substance abuse and drug of abuse. Am. J. Health Syst. Pharm., 65 (7), 611–618. 302. Salloum, I.M., Cornelius, J.R., Daley, D.C. et al. (2005) Efficacy of valproate maintenance in patients with bipolar disorder and alcoholism: a double-blind placebo-controlled study. Arch. Gen. Psychiatry, 62 (1), 37–45. 303. Geller, B., Cooper, T.B., Sun, K. et al. (1998) Double-blind and placebo-controlled study of lithium for adolescent bipolar disorders with secondary substance dependency. J. Am. Acad. Child Adolesc. Psychiatry, 37 (2), 171–178. 304. Brown, E.S., Beard, L., Dobbs, L. and Rush, A.J. (2006) Naltrexone in patients with bipolar disorder and alcohol dependence. Depress. Anxiety, 23 (8), 492–495.
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Rapid Cycling Bipolar Disorder: Phenomenology and Treatment Joseph F. Goldberg1 and Michael Berk2 1 2
Mount Sinai School of Medicine, New York, NY, USA Barwon Health and the Geelong Clinic, University of Melbourne, Victoria, Australia
The construct of rapid cycling has received considerable attention ever since Dunner and Fieve [1] first coined the term to describe bipolar disorder patients with a poor response to long-term lithium therapy. In its original definition – and as stillreflectedinDSM-IVTR– rapidcyclingpertainedtofouror more distinct episodes of mania or depression in a preceding 12-month period. From that definition, numerous controversies and clinical uncertainties have arisen: is rapid cycling transient (state-like) or persistent (trait-like)? Does it arise early or late in the course of bipolar disorder? Concordant with the staging model, is it a marker of the later and more refractory stageofthe disorder?Is polarity change a necessary component of rapid cycling, or is there more often proneness for a single polarity (e.g. depression) to recur with high frequency? How commonly is rapid cycling a consequence ofantidepressantuse(i.e.iatrogenic)?Howdoesrapidcycling differ from a mixed episode? How important are DSM-IV criteria for defining rapid cycling with respect to the need for duration criteria for defining a full affective episode, or for delineating newepisodes (i.e.frequent relapses within a year) from single episodes that merely wax and wane due to incomplete recovery? What is the boundary between rapid cycling and the mood lability seen in borderline personality disorder? And perhaps most essentially, what treatments are most versus least useful in the presence of rapid cycling? This chapter will attempt to address these and other related questions regarding the phenomenology and treatment of rapid cycling in bipolar disorder, with a focus on issues most relevant to practical diagnosis and management.
Controversies regarding the definition of rapid cycling Although Dunner and Fieve [1] originally defined rapid cycling based on the presence of frequent syndromes per
Bipolar Disorder: Clinical and Neurobiological Foundations Edited by Lakshmi N. Yatham and Mario Maj © 2010 John Wiley & Sons, Ltd. ISBN: 978-0-470-72198-8
year, other investigators have emphasized the clinical importance of mood oscillations per se (rather than frequent syndromes with requisite associated criteria) – thus emphasizing polarity change rather than high recurrence regardless of polarity – as a nosologically valid and clinically relevant construct. Kramlinger and Post (1996) [2] described the phenomenon of mood states that shifted in polarity over the course of weeks to days (‘ultra-rapid cycling’) to distinct mood shifts that occurred within a day (‘ultra-ultra rapid’ or ‘ultradian’ cycling). Problematic with such conceptualizations is their phenomenologic overlap with the World Health Organization (WHO) construct of mixed episodes, which can include the ‘rapid alternation (i.e. within a few hours) of hypomanic, manic and depressive symptoms’ over at least a two-week period [3]. This similarly overlaps with the mood instability that is core to the borderline construct [4]. It can be very difficult to separate out the mood lability of borderline personality organization from that of rapid cycling. This is not helped by high rates of overlapping risk factors such as sexual abuse, nor by the high rates of comorbidity that exist between the two conditions. The clinical imperative to do so is however self evident, due to the divergent treatment approaches implied by a dichotomous diagnosis. Separate from the qualitative symptoms of rapid cycling (i.e. distinct polarity changes as per DSM-IVTR vs. rapid alternations of affective symptoms per ICD-10) lies ongoing debate over the minimally relevant time duration of symptoms to constitute an ‘episode’. Maj and colleagues [5] observed high inter-rater reliability amongst psychiatrists in identifying distinct clinical states involving four or more episodes per year that included relaxed criteria for the duration of episodes. In order to clarify the controversy regarding the diagnosis of rapid cycling, the International Society of Bipolar Disorders commissioned a review of the diagnostic criteria for rapid cycling. The working group concluded that: ‘while episode cycling can be conceptualized as a dimensional phenomenon between the extremes of no cycling and
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continuous ultradian cycling, there is insufficient new evidence to modify the existing DSM-IV definition of rapid cycling in a manner that would be less arbitrary’ [6]. The staging model proposes that bipolar disorder has a characteristic trajectory, from an at-risk phase, through the prodrome, to a first episode, followed by the characteristic cycle of recurrence and relapse, which frequently shows an accelerating pattern, and the subsequent emergence of a phase of treatment resistance in a few individuals. Rapid cycling is considered to be a component of the latter, fourth stage of the disorder [8,67].
Phenomenology There is inconsistent data on the prevalence of rapid cycling in patients with bipolar disorder. An overall prevalence of 16.3%, with a range between 12 and 24% was described in a meta-analysis, which included patients consecutively admitted to an inpatient or outpatient facility without a priori selection of rapid cycling or matching with controls without rapid cycling [9]. Rapid cycling may have increased in prevalence in recent years, particularly in inpatient settings [10]. There are many explanations for this, from sampling bias (studies of patients in specialized centres), increased recognition after the inclusion of rapid cycling in the DSM-IV and the publication of key papers highlighting rapid cycling, or it may reflect a true increased prevalence, due to widespread treatment with antidepressants and greater prevalence of substance use [11]. In 1742 subjects from the National Institute of Mental Health Systematic Treatment Enhancement Programme for Bipolar Disorder (NIMH STEP-BD), the incidence of prospectively-observed rapid cycling (as defined by DSM-IV) over a two-year period was only 5% [12], in contrast to a much higher retrospectively-reported rate (20%) [13]. This raises the question of whether patients may subjectively overestimate the frequency of multiple episodes within a two-year period, perhaps due either to impressionistic recall or by confusing the waxing and waning course of incomplete remissions with the onset of truly new episodes [14]. Individuals with rapid cycling appear to have a younger age of onset than patients without rapid cycling [15,16]. Onset of bipolar disorder in prepuberty or early adolescence may denote a more severe form of illness [17]. Amongst prepubertal and early adolescent children with bipolar disorder, ultradian cycling was reported in 77.4% and ultra-rapid cycling in 9.7% [18]. Childhood physical and sexual abuse is associated with an earlier age of onset of bipolar disorder, rapid cycling and a more severe course of illness in adulthood [19]. Initial polarity of illness appears to be predictive of a propensity to a rapid cycling course [20,21]. Rapid cycling has also been associated with a pattern of illness characterized by a depression-mania-free interval (DMI) course more than a mania-depression-free
interval course [22], perhaps reflecting a greater likelihood for antidepressant exposure when depressive episodes precede manias in bipolar disorder. Probably the most robust and well-replicated finding regarding clinical features related to rapid cycling involves its apparent over-representation amongst women, who comprise about 70% of individuals with rapid cycling [23], although this finding is not consistently replicated. Rapid cycling mood patterns generally do not show high correlations with variation in the menstrual cycle [24,25]. Reports have identified a higher prevalence of rapid cycling in patients with bipolar II than bipolar I disorder [26], in bipolar I than bipolar II disorder [27], or similar rates across both bipolar I and II patients [12]. The presence of rapid cycling has been associated with more extensive illness complexity (e.g. comorbid substance abuse and histories of childhood abuse [27]) and a number of poor outcome states, including more suicide attempts [28,29]. Rapid cycling is also associated with more work impairment, alcohol abuse and greater service utilization [23,30]. Non-adherence is reported as a particular issue in rapid cycling, with rates of non-adherence between 20 and 33% [31–33]. Poor medication adherence may contribute to increased cycling frequency [34]. A further factor in the genesis of rapid cycling is substance abuse, which has been consistently reported as being more common in rapid cycling cohorts [35]. An additional clinical component of rapid cycling involves its potential link with subclinical (grade I or II) hypothyroidism, arising in about half of individuals with rapid cycling bipolar disorder, as originally described in small studies (N 30) by Cowdry et al. [36] and by Bauer and colleagues [37], although this relationship has not been consistently replicated. There has been much speculation, but little evidence, regarding the potential for lithiuminduced hypothyroidism to account for at least some degree of biochemical hypothyroidism associated with rapid cycling. A further point of controversy about rapid cycling involves uncertainty about whether it more often reflects a transient or persistent phenomenon. Over an average 13.7year follow-up period, data from the National Institute of Mental Health (NIMH) Collaborative Depression Study found rapid cycling usually dissipated within two years of its emergence [28]. By contrast, naturalistic follow-up data from a large patient group drawn from bipolar disorder speciality clinics across Italy (n ¼ 109) found that the mean duration of a rapid cycling course was nearly eight years, with the persistence of four or more annual episodes in 40% of patients [22].
Antidepressants and rapid cycling Since initial reports of antidepressant-induced mania and cycle acceleration, there has been growing concern amongst
Rapid Cycling Bipolar Disorder
practitioners that a substantial proportion of bipolar disorder patients could develop cycle acceleration as the direct consequence of excessive or prolonged antidepressant use. Some of the seminal data suggesting that antidepressants can be associated with cycle acceleration come from Wehr et al. [24], who showed reduction in the inter-episode interval with antidepressants, and lengthening with cessation of antidepressants, although it should be noted that this finding was demonstrated using a within-subject on-off-on design in only 10 patients. Retrospective observations by Altshuler and colleagues [38] at the NIMH further suggested that cycle acceleration appeared linked with antidepressant use in 26% of 51 with treatment-refractory bipolar disorder; furthermore, antidepressant-associated cycle acceleration was more common in those who also had a history of acute mania induction by antidepressants. Further suggestive of an association between antidepressant use and cycle acceleration, Ghaemi and colleagues [39] demonstrated an increase in the number of episodes per year with antidepressant treatment. Most modern studies are quick to point out the unresolved and controversial nature of this view, since most of the clinical evidence to support this is based more on case reports or open-label studies rather than controlled studies. Some authors have suggested that antidepressants may be more prone to accelerate cycling frequency in predisposed subgroups, such as women rather than men [40]. Contrary to popular perceptions linking antidepressants with rapid cycling, naturalistic follow-up data from the NIMH Collaborative Depression Study found no association between polarity shifts from depression to mania and tricyclic antidepressant use – in fact, time spent with depression amongst rapid cyclers was longer (not shorter) when lithium was taken without antidepressants – nor was the resolution of rapid cycling associated with the cessation of antidepressants [28]. While it remains uncertain to what extent antidepressants can cause or exacerbate rapid cycling in some bipolar disorder patients, it has never been demonstrated that antidepressants diminish cycling frequency over time in patients with frequent episodes. This point is perhaps best illustrated by recent prospective naturalistic findings from the NIMH-STEP-BD, in which subjects taking antidepressants continued to have multiple episodes over the course of one year, while those not taking antidepressants typically had fewer annual episodes [23]. It is tempting to interpret these data as suggesting that antidepressant use caused the occurrence of multiple episodes, but it is equally plausible that multiple episodes persisted despite the use of antidepressants, or that antidepressants are more often used by clinicians in individuals with the most challenging mood symptoms. Definitive explanations for this finding are limited due to methodology of STEP-BD (i.e. the nonrandomization to treatment and control for potential confounding factors, since patients with highly recurrent depression may
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have been those most likely to receive antidepressants in the first place). Nevertheless, one can observe from these data that if antidepressants were efficacious in rapid cycling, one would not expect to see the persistence of multiple episodes during long-term antidepressant therapy. The necessity for long-term antidepressant trials in bipolar disorder to resolve this and related dilemmas is therefore compelling.
Treatment of rapid cycling General considerations Having confirmed the diagnosis of rapid cycling using a careful clinical history, augmented if possible and appropriate with mood diaries and collateral history, the initial step in management is to exclude known precipitants, particularly thyroid dysfunction and substance use. The latter requires active independent management. A focus on engagement and strengthening the therapeutic alliance plays a significant role in adherence to treatment, which is a disproportionate factor in some individuals with rapid cycling [41]. Adherence is further assisted using programmes addressing the illness using psychoeducation and other group based modalities [42]. The nature of the illness makes continuity of care of particular value in bipolar disorder [43]. Before examining current data from treatment studies of rapid cycling, it is important also to consider the role of nonpharmacologic factors known to influence or perpetuate affective cycling. These include alcohol or other psychoactive drug abuse, chronobiological factors such as sleep deprivation or transcontinental air travel, subclinical hypothyroidism and shift work. Anti-cycling agents are generally regarded as both the safest and most effective biological therapies for rapid cycling, although most long-term studies show that the presence of rapid cycling is usually associated with a poorer response to long-term treatment. It is important to note at the outset that many existing controlled trials also have focused not on the anti-cycling effect of a treatment over at least 12 months (i.e. an anti-rapid cycling effect as would be defined by DSM-IVTR), but rather, the extent to which bipolar disorder patients with a recent or even lifetime past history of rapid cycling show responsiveness to a particular intervention for an acute manic or depressive episode. While such studies are clinically valuable, their findings should not be misconstrued as evidence for the type of longer-term anti-cycling efficacy that is fundamental to treating patients with rapid cycling. It is perhaps salient to conceptualize mood-stabilizers as agents that modulate, in a beneficial manner, the endogenous propensity to cyclicity that is the hallmark of bipolarity. In addition to changes in the polar axis, this core property of mood stabilizers to modulate the endogenous
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cyclical pattern impacts additional cycle parameters, including inter-episode length, episodic amplitude and duration. Reduction in cycle length is an accepted metric of the impact of therapy on cycle change [24,39]. As such, lengthening of the inter-episode interval can be seen as a core impact of efficacious mood stabilizer therapy. This is buttressed by reductions in episode amplitude and duration. Tondo et al. [44] reviewed treatment studies of rapid cycling, and concluded that the presence of rapid cycling was associated with lower effectiveness of all reviewed treatments. Direct comparisons of specific treatments did not show superiority of any individual treatment.
Lithium and divalproex Traditional mood stabilizing agents such as lithium and several specific anticonvulsants have long been considered cornerstone treatments for rapid cycling bipolar disorder. Following early observations to suggest that lithium alone may have more modest prophylactic value in the presence of rapid cycling, attention turned to the possible anticycling efficacy of divalproex and carbamazepine – the two anticonvulsants shown to have acute antimanic efficacy in the late 1970s and 1980s. Posts hypothesis that highly recurrent mood episodes may be analogous to the processes of kindling and behavioural sensitization in epilepsy helped to provide a conceptual and pharmacodynamic rationale for turning to ‘anti-kindling’ agents as a viable alternative strategy to lithium [45]. Indeed, initial open label data with divalproex suggested that a substantial proportion of bipolar disorder patients with rapid cycling could improve in both manic and depressive symptoms, both acutely and during continuation-phase treatment [46], a finding that was quickly incorporated into practice guidelines in the 1990s and early 2000s. Hopes that divalproex might offer superior prevention of relapse than lithium quickly diminished based on the findings of a 20-month, double-blind, randomized comparison of each agent as monotherapy following acute stabilization with a combination of both [31]. During an initial 6-month open-label phase of combination therapy with lithium plus divalproex amongst 254 subjects with rapid cycling, only 60 (24%) stabilized. Treatment-nonresponsive depression was the predominant reason for inadequate mood stabilization during the open-label combination therapy phase, occurring in 73% of the 65 subjects who were deemed nonresponders to lithium plus divalproex. Amongst responders, subsequent randomization to monotherapy for up to 20 months with either lithium (n ¼ 32; mean dose ¼ 1359 mg/day; mean serum [lithium] ¼ 0.92 mEq/L) or divalproex (n ¼ 28; mean dose ¼ 1571 mg/day; mean serum [valproate] ¼ 77 mcg/ml) showed comparable rates of relapse with lithium (56.3%) or divalproex (50.0%). Hence, only a very small minority of individuals with rapid cycling
achieved both acute and continuation phase mood stabilization with either agent as monotherapy, and no particular advantage was evident for one agent relative to the other.
Carbamazepine Early studies with carbamazepine for bipolar mania were conducted by Okuma and colleagues in Japan. In an initial retrospective study of 215 bipolar disorder patients taking lithium or carbamazepine for at least two years, better overall response to either drug was observed amongst non-rapid cycling than rapid cycling subjects; amongst rapid cyclers, response rates were higher with carbamazepine (19/48; 39%) than lithium (11/43; 25%) [47]. A subsequent investigation in rapidly cycling bipolar patients by Denicoff and colleagues [48] found a significantly greater proportion having a moderate to marked response amongst those taking lithium plus carbamazepine (56.3%) than seen in those only taking lithium (28.3%) or only carbamazepine (37.3%).
Lamotrigine Long-term data are available from two randomized monotherapy studies of lamotrigine in bipolar disorder patients with rapid cycling. The first enrolled bipolar I or II disorder subjects with past-year rapid cycling who were currently in any phase of illness (manic, hypomanic, depressed, mixed or euthymic in the preceding 3 months) and involved initial open-label treatment with lamotrigine dosed to a target range of 100–300 mg/day with subsequent randomization of responders to flexibly-dosed lamotrigine monotherapy or placebo [49]. The primary outcome variable of ‘time to additional pharmacotherapy for emerging mood symptoms’ showed no significant difference between drug and placebo (p ¼ 0.177). However, on the secondary outcome measure of time until study discontinuation, survival was significantly longer with lamotrigine (n ¼ 90; mean dose of 288 94 mg/day) than placebo (n ¼ 87) (p ¼ 0.036). This difference was driven primarily by a significant effect in patients with bipolar II disorder; no significant difference was seen amongst those with bipolar I disorder. In addition, the proportion of patients who were stable without relapse for six months was significantly higher overall in patients taking lamotrigine (41.1%) than placebo (26.4%), and specifically in those with bipolar II disorder (45.8% vs. 17.9%, respectively). Another secondary analysis of this trial, using prospective life charting, found that rapid cycling bipolar disorder patients taking lamotrigine were 1.8 times more likely than those taking placebo to achieve euthymia on a weekly basis across a 6-month study period [50]. In addition to the above studies focusing specifically on rapid cycling populations, the two long-term placebocontrolled maintenance studies of lamotrigine in bipolar I disorder enrolled 169 subjects who had four to six episodes
Rapid Cycling Bipolar Disorder
in the preceding year [51]. In an exploratory analysis, the median time to intervention for a relapsing or recurrent mood episode was found to be numerically longer with lamotrigine (123 days) or lithium (146 days) than with placebo (87) days, but this difference was not significant.
Thyroid hormone Suprametabolic doses of thyroid hormone for the treatment of refractory rapid cycling were described in an open case series (n ¼ 11) by Bauer and Whybrow [52], and supported by a handful of additional case reports (e.g. [53,54]). There also exist a number of small, open-label case reports using supraphysiologic thyroxine (e.g. 250–500 mcg/day) for multi-drug-resistant bipolar disorder [55] or other novel manipulations of the thyroid axis (e.g. intrathecal thyrotropin releasing hormone [56]) as a novel antidepressant strategy without risk for provoking cycle acceleration. Although no randomized controlled trials have been reported involving thyroxine or other thyroid perturbations in bipolar disorder patients with rapid cycling, many experts view suprametabolic thyroid hormone as a viable treatment strategy for rapid cycling [57], particularly given the paucity of alternative viable therapeutic options.
Calcium channel blockers Early impressions about the possible anti-manic or anticycling value of L-type phenylalkylamine calcium channel blockers, such as verapamil, have not been proven by larger trials to demonstrate robust utility in bipolar disorder [58]. By contrast, however, the L-type dihydropyridine calcium channel blocker and anticonvulsant [59] nimodipine at relatively high doses (e.g. 330–360 mg/day) has been associated with a reduction in cycling frequency in bipolar disorder patients with refractory rapid cycling [60].
Second-generation antipsychotics Several second-generation antipsychotics (SGA) have been studied in controlled trials to assess their acute or prophyolactic efficacy in the presence versus absence of a rapid cycling history. Vieta and colleagues [61] examined the acute (8-week) antidepressant effects of quetiapine monotherapy dosed at 300 mg/day (n ¼ 42) or 600 mg/day (n ¼ 31) or placebo (n ¼ 35) in a subgroup of bipolar I or II patients with past-year rapid cycling. Significant reductions from baseline depressive symptoms were noted in both active treatment groups, with large effect sizes for subjects taking 300 mg/day (d ¼ 1.1) or 600 mg/day (d ¼ 1.2). Notably, the magnitude of reduction in depressive symptom severity between active drug and placebo was as robust amongst patients with rapid cycling as in those without rapid cycling [32].
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A 47-week randomized comparison of olanzapine or divalproex found poorer long-term improvement in mania symptom severity scores amongst rapid cyclers than non-rapid cyclers, with comparable effects seen in both treatment groups [62]. Other existing studies involving olanzapine in patients with rapid cycling bipolar disorder have demonstrated its short-term antimanic superiority to placebo amongst subjects with a prior history of rapid cycling, separate from the more overarching issue of reducing episode number during prospective long-term follow-up [63]. Drawing on data from a 100-week placebo-controlled trial of aripiprazole monotherapy for maintenance therapy in bipolar I disorder, Muzina and colleagues [64] examined outcomes for the subgroup of 18 subjects with a history of past-year rapid cycling and found a significantly longer time until relapse at week 26 and again at week 100, although the small sample size and post hoc analysis makes this finding preliminary in nature. In a small (N ¼ 28) naturalistic study of clozapine, Suppes and colleagues [65] found greater symptomatic improvement in treatment-resistant bipolar I or schizoaffective subjects for whom rapid cycling was absent rather than present. There is a single six-month open-label trial of adjunctive risperidone in 10 outpatients with rapid cycling bipolar disorder, reporting a significant reduction in mania and depression symptom severity scores from baseline as well as the mean number of episodes during the 6-month followup period (mean SD ¼ 2.0 1.7) as compared to the 6 months preceding study enrolment (5.5 3.7) [66]. At present, there are no published reports focusing on the use of ziprasidone, specifically in patients with rapid cycling bipolar disorder.
Is there a role for antidepressants? Despite growing perception that antidepressants as a class may carry risks for cycle acceleration, there are surprisingly few controlled studies assessing whether short-term antidepressant use may have benefit for the depressed phases of rapid cycling. Furthermore, while there is some evidence to suggest a lower risk for the induction of acute mania with serotonergic than noradrenergic antidepressants [67], there has been little empirical study of whether short-term use of some antidepressants may alleviate depressive symptoms without accelerating cycling frequency. Indeed, given the naturalistic outcome data from the NIMH Collaborative Depression Study, rapid cycling bipolar disorder patients may spend more time with depression when a mood stabilizer is administered without an antidepressant [11,28]. It must be emphasized that no randomized controlled trials have yet prospectively examined short-term outcomes with versus without an antidepressant for acute depression amongst rapidly cycling bipolar disorder patients.
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There are a number of unresolved questions regarding antidepressant use in rapid cycling, which may be worth considering, to help guide clinical decision making and future research efforts. First, it is unknown whether subgroups of rapid cycling patients may be more or less likely to respond favourably (or to destabilize further) with antidepressants. Patients whose depressed phases are of longer duration may differ in this respect from those whose depressions last only for a few weeks at a time. Similarly, some individuals with bipolar disorder have been identified as being prone to change polarity more swiftly and abruptly than others, potentially as a familial trait in highly-dense pedigrees; when such patients also have rapid cycling, antidepressants may induce manic or hypomanic phases in about one-third [68]. A further uncertainty involves the potential differences in risk for mania induction or cycle acceleration amongst specific antidepressants, particularly noradrenergic mixed-agonists agents such as venlafaxine [69]. It is possible that some rapid cycling patients may benefit from at least the short-term use of certain antidepressants, although further empirical study is needed to better determine which characteristics best determine the suitability and candidacy of a given patient.
Electroconvulsive therapy Literature supporting the utility of electroconvulsive therapy (ECT) for treatment of rapid cycling bipolar disorder derives largely from case reports and anecdotal observations [70,71]. The anticonvulsant properties of ECT have long been recognized as contributing to its probable therapeutic mechanism of action, a concept that may be particularly relevant to the treatment of highly recurrent or oscillatory mood states within the framework of the kindling model. At the same time, there exist case reports of the induction or exacerbation of mania or ultra-rapid cycling during ECT [72], and at present there is no consensus on the optimal management of emergent mania during ECT with respect to the continuation versus cessation of ongoing treatments. Some authors have sought to distinguish truly iatrogenic mania from ‘organic euphoric states’ associated with cognitive impairment as a point of consideration for guiding ongoing therapy to treat the former, rather than latter, state [73]. Few contemporary studies have been conducted in bipolar disorder patients with rapid cycling that address issues such as specific ECT technique (e.g. bilateral vs. unilateral nondominant electrode placement, or comparing high-dose versus stimulus dosing of ECT); and there exist only limited data from case reports or small open trials on the use of novel methods of brain stimulation specifically in bipolar disorder patients with rapid cycling (e.g. transcranial magnetic stimulation) [74] or vagal nerve stimulation (VNS) [75,76], although such modalities offer promise for future investigation.
Other novel treatments A two-year open-label trial of chromium has been reported in rapid cycling individuals [77]. Open-label trials need to be interpreted with particular caution, as many individual have periods of a few years of rapid cycling that resolve, and placebo controlled data is essential to draw any conclusions. Omega 3 fatty acids, after showing some promise in bipolar maintenance therapy, failed to demonstrate benefit in a placebo controlled trial of rapid cycling individuals [78].
Chronobiological treatments Based on observations linking rapid cycling with circadian rhythm disturbances, there has arisen a small literature examining manipulations of the sleep-wake cycle as a strategy to reduce cycling frequency in bipolar disorder. Case reports have described successful outcomes using extended bed rest with prolonged darkness (10–14 hours/night), either with [79] or without [80] concurrent daytime light therapy. Light therapy in the absence of a clear seasonal pattern has received only limited study in bipolar disorder patients with rapid cycling, although preliminary data suggest greater value for mid-day rather than early morning or evening exposure, and it does not appear beneficial during periods of hypomania [81].
Psychotherapy Reilly-Harrington and colleagues [82] have been amongst the first to apply cognitive behavioural therapy (CBT) principles to the specific needs of individuals with rapid cycling bipolar disorder. Their recent pilot study of 10 cases treated with adjunctive CBT demonstrated significant improvement in depressive symptoms with sustained benefits over a short-term (two-month) follow-up.
Summary and conclusions Rapid cycling, as defined by four or more distinct mood episodes during the preceding year, is a nonfamilial descriptor of bipolar I or II disorder that arises in an important minority of patients. It may occur at any stage of bipolar disorder and its long-term persistence should not be assumed. Rapid cycling appears more common in women than men, although links with reproductive health and the menstrual cycle have not been consistently demonstrated. Rapid cycling may serve as a marker for illness chronicity and severity, including a potentially increased risk for suicidal behaviour and greater overall illness complexity. There are no standard effective treatments for rapid cycling, although traditional mood stabilizing agents and at least some SGAs likely represent the mainstay of therapy, alongside the normalization of chronobiological elements and
Rapid Cycling Bipolar Disorder
elimination of other environmental factors that can destabilize mood such as psychoactive substance abuse. The utility as well as potential hazards of antidepressants remain controversial, and clinicians should be alert to the potential for long-term antidepressants to accelerate the frequency of affective cycles. A number of novel strategies may have anti-cycling properties for which further research is needed to better inform future evidence-based interventions.
References 1. Dunner, D.L. and Fieve, R.R. (1974) Clinical factors in lithium carbonate prophylaxis failure. Arch. Gen. Psychiatry, 30 (2), 229–233. 2. Kramlinger, K.G. and Post, R.M. (1996) Ultra-rapid and ultradian cycling in bipolar affective illness. Br. J. Psychiatry, 163 (3), 213–323. 3. World Health Organization (2007) International Statistical Classification of Diseases and Related Health Problems (ICD-10). 4. MacKinnon, D.F. and Pies, R. (2006) Affective instability as rapid cycling: theoretical and clinical implications for borderline personality and bipolar spectrum disorders. Bipolar Disord., 8 (1), 1–14. 5. Maj, M., Pirozzi, R., Formicola, A.M. and Tortorella, A. (1999) Reliability and validity of four alternative definitions of rapid-cycling bipolar disorder. Am. J. Psychiatry, 156 (9), 1421–1424. 6. Bauer, M., Beaulieu, S., Dunner, D.L. et al. (2008) Rapid cycling bipolar disorder – diagnostic concepts. Bipolar Disord., 10 (1 Pt 2), 153–162. 7. McGorry, P.D., Hickie, I.B., Yung, A.R. et al. (2006) Clinical staging of psychiatric disorders: a heuristic framework for choosing earlier, safer and more effective interventions. Aust. NZ J. Psychiatry, 40 (8), 616–622. 8. Berk, M., Conus, P., Lucas, N. et al. (2007) Setting the stage: from prodrome to treatment resistance in bipolar disorder. Bipolar Disord., 9 (7), 671–678. 9. Kupka, R.W., Luckenbaugh, D.A., Post, R.M. et al. (2003) Rapid and non-rapid cycling bipolar disorder: a meta-analysis of clinical studies. J. Clin. Psychiatry, 64 (12), 1483–1494. 10. Wolpert, E.A., Goldberg, J.F. and Harrow, M. (1990) Rapid cycling in unipolar and bipolar affective disorders. Am. J. Psychiatry, 147 (6), 725–728. 11. Coryell, W., Endicott, J. and Keller, M. (1992) Rapidly cycling affective disorder. Demographics, diagnosis, family history and course. Arch. Gen. Psychiatry, 49 (2), 126–131. 12. Schneck, C.D., Miklowitz, D.J., Miyahara, S. et al. (2008) The prospective course of rapid-cycling bipolar disorder: findings from the STEP-BD. Am. J. Psychiatry, 165 (3), 370–377. 13. Schneck, C.D., Miklowitz, D.J., Calabrese, J.R. et al. (2004) Phenomenology of rapid-cycling bipolar disorder: data from the first 500 participants in the Systematic Treatment Enhancement Program. Am. J. Psychiatry, 161 (10), 1902–1908. 14. Goldberg, J.F. (2008) Antidepressant prescribing and rapid cycling. Am. J. Psychiatry, 165 (8), 1048–1049.
|
339
15. Fisfalen, M.E., Schulze, T.G., DePaulo, J.R. Jr et al. (2005) Familial variation in episode frequency in bipolar affective disorder. Am. J. Psychiatry, 162 (7), 1266–1272. 16. Carter, T.D., Mundo, E., Parikh, S.V. and Kennedy, J.L. (2003) Early age at onset as a risk factor for poor outcome of bipolar disorder. J. Psychiatr. Res., 37 (4), 297–303. 17. Leboyer, M., Henry, C., Paillere-Martinot, M.L. and Bellivier, F. (2005) Age at onset in bipolar affective disorders: a review. Bipolar Disord., 7 (2), 111–118. 18. Geller, B., Zimerman, B., Williams, M. et al. (2002) DSM-IV mania symptoms in prepubertal and early adolescent bipolar disorder phenotype compared to attention-deficit hyperactive and normal controls. J. Child Adolesc. Psychopharmacol., 12 (1), 11–25. 19. Leverich, G.S., McElroy, S.L., Suppes, T. et al. (2002) Early physical and sexual abuse associated with an adverse course of bipolar illness. Biol. Psychiatry, 51 (4), 288–297. 20. Roy-Byrne, P., Post, R.M., Uhde, T.W. et al. (1985) The longitudinal course of recurrent affective illness: life chart data from research patients at the NIMH. Acta Psychiatr. Scand. Suppl., 317, 1–34. 21. Perugi, G., Micheli, C., Akiskal, H.S. et al. (2000) Polarity of the first episode, clinical characteristics, and course of manicdepressive illness: a systematic retrospective investigation of 320 bipolar I patients. Compr. Psychiatry, 41 (1), 13–18. 22. Koukopoulos, A., Sani, G., Koukopoulos, A.E. et al. (2003) Duration and stability of the rapid cycling course: a longterm personal follow-up of 109 patients. J. Affect. Disord., 73 (1–2), 75–85. 23. Cruz, N., Vieta, E., Comes, M. et al. (2008) Rapid-cycling bipolar I disorder: course and treatment outcome of a large sample across Europe. J. Psychiatr. Res., 42 (13), 1068– 1075. 24. Wehr, T.A., Sack, D.A., Rosenthal, N.E. and Cowdry, R.W. (1988) Rapid cycling affective disorder: contributing factors and treatment responses in 51 patients. Am. J. Psychiatry, 145 (2), 179–184. 25. Leibenluft, E., Ashman, S.B., Feldman-Naim, S. and Yonkers, K. (1999) Lack of relationship between menstrual cycle phase and mood in a sample of women with rapid cycling bipolar disorder. Biol. Psychiatry, 46 (4), 577–580. 26. Calabrese, J.R., Shelton, M.D., Bowden, C.L. et al. (2001) Bipolar rapid cycling: focus on depression as its hallmark. J. Clin. Psychiatry, 62 (Suppl. 14), 34–41. 27. Kupka, R.W., Luckenbaugh, D.A., Post, R.M. et al. (2005) Comparison of rapid-cycling and non-rapid-cycling bipolar disorder based on prospective mood ratings in 539 outpatients. Am. J. Psychiatry, 162 (7), 1273–1280. 28. Coryell, W., Solomon, D., Turvey, C. et al. (2003) The longterm course of rapid-cycling bipolar disorder. Arch. Gen. Psychiatry, 60 (9), 914–920. 29. Azorin, J.M., Kaladjian, A., Adida, M. et al. (2008) Factors associated with rapid cycling in bipolar I manic patients: findings from a French national study. CNS Spectr., 13 (9), 780–787. 30. Rizzo, C.J., Esposito-Smythers, C., Swenson, L. et al. (2007) Factors associated with mental health service utilization among bipolar youth. Bipolar Disord., 9 (8), 839–850.
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|
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31. Calabrese, J.R., Shelton, M.D., Rapport, D.J. et al. (2005) A 20month, double-blind, maintenance trial of lithium versus divalproex in rapid-cycling bipolar disorder. Am. J. Psychiatry, 162 (11), 2152–2161. 32. Calabrese, J.R., Keck, P.E. Jr, Macfadden, W. et al. (2005) A randomized, double-blind, placebo-controlled trial of quetiapine in the treatment of bipolar I or II depression. Am. J. Psychiatry, 162 (7), 1351–1360. 33. Sajatovic, M., Elhaj, O., Youngstrom, E.A. et al. (2007) Treatment adherence in individuals with rapid cycling bipolar disorder: results from a clinical-trial setting. J. Clin. Psychopharmacol., 27 (4), 412–414. 34. Levy, J.M. and Remick, R.A. (1986) Clinical aspects and treatment of rapid cycling mood disorders. Can. J. Psychiatry, 31 (5), 436–441. 35. Strakowski, S.M., DelBello, M.P., Fleck, D.E. et al. (2007) Effects of co-occurring cannabis use disorders on the course of bipolar disorder after a first hospitalization for mania. Arch. Gen. Psychiatry, 64 (1), 57–64. 36. Cowdry, R.W., Wehr, T.A., Zis, A.P. and Goodwin, F.K. (1983) Thyroid abnormalities associated with rapid cycling bipolar illness. Arch. Gen. Psychiatry, 40 (4), 414–420. 37. Bauer, M.S., Whybrow, P.C. and Winokur, A. (1990) Rapid cycling bipolar affective disorder. I. Association with grade I hypothyroidism. Arch. Gen. Psychiatry, 47 (5), 427–432. 38. Altshuler, L.L., Post, R.M., Leverich, G.S. et al. (1995) Antidepressant-induced mania and cycle acceleration: a controversy revisited. Am. J. Psychiatry, 152 (8), 1130–1138. 39. Ghaemi, S.N., Rosenquist, K.J., Ko, J.Y. et al. (2004) Antidepressant treatment in bipolar versus unipolar depression. Am. J. Psychciatry, 161 (1), 163–165. 40. Yildiz, A. and Sachs, G.S. (2003) Do antidepressants induce rapid cycling? A gender-specific question. J. Clin. Psychiatry, 64 (7), 814–818. 41. Berk, M., Berk, L. and Castle, D. (2004) A collaborative approach to the treatment alliance in bipolar disorder. Bipolar Disord., 6 (6), 504–518. 42. Castle, D., Berk, M., Berk, L. et al. (2007) Pilot of group intervention for bipolar disorder. Int. J. Psychiatr. Clin. Pract., 11, 279–284. 43. Ilgen, M.A., Hu, K.U., Moos, R.H. and McKellar, J. (2008) Continuing care after inpatient psychiatric treatment for patients with psychiatric and substance use disorders. Psychiatr. Serve. 59 (9), 982–988. 44. Tondo, L., Hennen, J. and Baldessarini, R.J. (2003) Rapidcycling bipolar disorder: effects of long-term treatments. Acta Psychiatr. Scand., 108, 4–14. 45. Post, R.M., Rubinow, D.R. and Ballenger, J.C. (1986) Conditioning and sensitization in the longitudinal course of affective illness. Br. J. Psychiatry, 149, 191–201. 46. Calabrese, J.R., Markovitz, P.J., Kimmel, S.E. and Wagner, S. C. (1992) Spectrum of efficacy of valproate in 78 rapid-cycling bipolar patients. J. Clin. Psychopharmacol., 12 (Suppl. 1), 53S–56. 47. Okuma, T. (1993) Effects of carbamazepine and lithium on affective disorders. Neuropsychobiology, 27 (3), 138–145. 48. Denicoff, K.D., Smith-Jackson, E.E., Disney, E.R. et al. (1997) Comparative prophylactic efficacy of lithium, carbamaze-
49.
50.
51.
52.
53.
54. 55.
56.
57.
58.
59.
60.
61.
62.
63.
pine, and the combination in bipolar disorder. J. Clin. Psychiatry, 58 (11), 470–478. Calabrese, J.R., Suppes, T., Bowden, C.L. et al. (2000) A double-blind, placebo-controlled, prophylaxis study of lamotrigine in rapid-cycling bipolar disorder. Lamictal 614 Study Group. J. Clin. Psychiatry, 61 (11), 841–850. Goldberg, J.F., Bowden, C.L., Calabrese, J.R. et al. (2008) Sixmonth prospective life charting of mood symptoms with lamotrigine monotherapy versus placebo in rapid cycling bipolar disorder. Biol. Psychiatry, 63 (1), 125–130. Goodwin, G.M., Bowden, C.L., Calabrese, J.R. et al. (2004) A pooled analysis of 2 placebo-controlled 18-month trials of lamotrigine and lithium maintenance in bipolar I disorder. J. Clin. Psychiatry, 65 (3), 432–441. Bauer, M.S. and Whybrow, P.C. (1990) Rapid cycling bipolar affective disorder. II. Treatment of refractory rapid cycling with high-dose levothyroxine: a preliminary study. Arch. Gen. Psychiatry, 47 (5), 435–440. Stancer, H.C. and Persad, E. (1982) Treatment of intractable rapid-cycling manic-depressive disorder with levothyroxine. Clinical observations. Arch. Gen. Psychiatry, 39 (3), 311–312. Leibow, D. (1983) L-thyroxine for rapid-cycling bipolar illness. Am. J. Psychiatry, 140 (9), 1255. Baumgartner, A., Bauer, M. and Hellweg, R. (1994) Treatment of intractable non-rapid cycling bipolar affective disorder with high-dose thyroxine: an open clinical trial. Neuropsychopharmacology, 10 (13), 183–189. Marangell, L.B., George, M.S., Callahan, A.M. et al. (1997) Effects of intrathecal thyrotropin-releasing hormone (protirelin) in refractory depressed patients. Arch. Gen. Psychiatry, 54 (3), 214–222. Keck, P.E. Jr, Perlis, R.D., Otto, M.W. et al. (2004) The expert consensus guidelines: treatment of bipolar disorder 2004. Postgrad. Med. Special Report (December), 1–20. Walton, S., Berk, M. and Brook, S. (1996) Lithium is superior to verapamil in the management of mania; a controlled randomised trial. J. Clin. Psychiat., 57 (11), 543–546. de Falco, F.A., Bartiromo, U., Majello, L. et al. (1992) Calcium antagonist nimodipine in intractable epilepsy. Epilepsia, 33 (2), 343–345. Pazzaglia, P.J., Post, R.M., Ketter, T.A. et al. (1998) Nimodipine monotherapy and carbamazepine augmentation in patients with refractory recurrent affective illness. J. Clin. Psychopharmacol., 18 (5), 404–413. Vieta, E., Calabrese, J.R., Goikolea, J.M. et al. (2007) Quetiapine monotherapy in the treatment of patients with bipolar I or II depression and a rapid-cycling disease course: a randomized, double-blind, placebo-controlled study. Bipolar Disord., 9 (4), 413–425. Suppes, T., Brown, E., Schuh, L.M. et al. (2005) Rapid versus non-rapid cycling as a predictor of response to olanzapine and divalproex sodium for bipolar mania and maintenance of remission: post hoc analyses of 47-week data. J. Affect. Disord., 89 (1–3), 69–77. Sanger, T.M., Tohen, M., Vieta, E. et al. (2003) Olanzapine in the acute treatment of bipolar I disorder with a history of rapid cycling. J. Affect. Disord., 73 (1–2), 155–161.
Rapid Cycling Bipolar Disorder 64. Muzina, D.J., Momah, C., Eudicone, J.M. et al. (2008) Aripiprazole monotherapy in patients with rapid-cycling bipolar I disorder: an analysis from a long-term, doubleblind, placebo-controlled study. Int. J. Clin. Pract., 62 (5), 679–687. 65. Suppes, T., Ozcan, M.E. and Carmody, T. (2004) Response to clozapine of rapid cycling versus non-cycling patients with a history of mania. Bipolar Disord., 6 (4), 329–332. 66. Vieta, E., Gasto, C., Colom, F. et al. (1998) Treatment of refractory rapid cycling bipolar disorder with risperidone. J. Clin. Psychopharmacol., 18 (2), 172–174. 67. Peet, M. (1994) Induction of mania with selective serotonin re-uptake inhibitors and tricyclic antidepressants. Br. J. Psychiatry, 164, 549–550. 68. MacKinnon, D.F., Zandi, P.P., Gershon, E. et al. (2003) Rapid switching of mood in families with multiple cases of bipolar disorder. Arch. Gen. Psychiatry, 60 (9), 921–928. 69. Post, R.M., Altshuler, L.L., Leverich, G.S. et al. (2006) Mood switch in bipolar depression: comparison of adjunctive venlafaxine, bupropion and sertraline. Br. J. Psychiatry, 189, 124–131. 70. Berman, E. and Wolpert, E.A. (1987) Intractible manic-depressive psychosis with rapid cycling in an 18 year-old woman successfully treated with electroconvulsive therapy. J. Nerv. Ment. Dis., 175 (4), 236–239. 71. Kho, K.H. (2002) Treatment of rapid cycling bipolar disorder in the acute and maintenance phase with ECT. J. ECT, 18 (3), 159–161. 72. Zavarotnyy, M., Diemer, J., Patzelt, J. et al. (2009) Occurrence of ultra-rapid cycling during electroconvulsive therapy in bipolar depression. World J. Biol. Psychiatry, 10, 987–990. 73. Devenand, D.P., Sackheim, H.A., Decina, P. and Prudic, J. (1988) The development of mania and organic euphoria during ECT. J. Clin. Psychiatry, 49 (2), 69–71.
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74. Dellosso, B. and Carlo Altamura, A. (2008) Augmentive transcranial magnetic stimulation (TMS) combined with brain navigation in drug-resistant rapid cycling bipolar depression: a case report of acute and maintenance efficacy. World J. Biol. Psychiatry, 10, 673–676. 75. Marangell, L.B., Suppes, T., Zboyan, H.A. et al. (2008) A 1-year pilot study of vagus nerve stimulation in treatmentresistant rapid cycling bipolar disorder. J. Clin. Psychiatry, 69 (2), 183–189. 76. Bajbouj, M., Danker-Hopfe, H., Heuser, I. and Anghelescu, I. (2006) Long-term outcome of vagus nerve stimulation in rapid-cycling bipolar disorder. J. Clin. Psychiatry, 67 (5), 837–838. 77. Amann, B. L., Mergl, R., Vieta, E., et al. (2007) A 2-year, openlabel pilot study of adjunctive chromium in patients with treatment-resistant rapid-cycling bipolar disorder. J. Clin. Psychopharmacol., 27 (1), 104–106. 78. Keck, P.E. Jr., Mintz , J., McElroy, S.L. et al. (2006) Doubleblind, randomized, placebo-controlled trials of ethyl-eicosopentanoate in the treatment of bipolar depression and rapid cycling bipolar disorder. Biol. Psychiatry, 60 (9), 1020–1022. 79. Wirz-Justice, A., Quinto, C., Cajochen, C. et al. (1999) A rapidcycling bipolar patient treated with long nights, bedrest, and light. Biol. Psychiatry, 45 (8), 1075–1077. 80. Wehr, T.A., Turner, E.H., Shimada, J.M. et al. (1998) Treatment of rapidly cycling bipolar patient by using extended bed rest and darkness to stabilize the timing and duration of sleep. Biol. Psychiatry, 43 (11), 822–828. 81. Leibenluft, E., Turner, E.H., Feldman-Naim, S. et al. (1995) Light therapy in patients with rapid cycling bipolar disorder: preliminary results. Psychopharmacol. Bull., 31 (4), 705–710. 82. Reilly-Harrington, N.A., Deckersbaugh, T., Knauz, R. et al. (2007) Cognitive behavioral therapy for rapid-cycling bipolar disorder: a pilot study. J. Psychiatr. Pract., 13 (5), 291–297.
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Management of Bipolar II Disorder Gordon Parker1 and Terence A. Ketter2 1 2
University of New South Wales; Black Dog Institute, Prince of Wales Hospital, Randwick, NSW, Australia Stanford University Hospital and Clinics, Stanford University School of Medicine, Stanford, CA, USA
Introduction Despite the lifetime rate of bipolar II disorder exceeding the bipolar I disorder rate [1], there is little consensus as to how bipolar II disorder should be optimally managed. Most randomized controlled trials as well as guidelines for managing bipolar disorder are limited or weighted towards patients with bipolar I disorder, and extrapolating their use to the management of bipolar II conditions may or may not be valid. This issue requires extension, as management is contingent on any such logic. If bipolar I and II are essentially similar conditions, merely varying by severity, then management nuances might be expected to be similar across the two conditions. However, if bipolar I and II disorders are categorically distinct, then differing treatment modalities are likely to have differing levels of relevance across the two conditions, as occurs for (say) Type I and Type II diabetes. Both of the latter conditions share the generic diagnosis of diabetes but differ importantly with respect to aetiology and management paradigms, with management involving both shared – and facultative – components, and with the latter respecting type-specific characteristics of each condition. Thus, how we model the bipolar disorders and differentiate bipolar I and II conditions, is of fundamental importance. Formal classificatory systems provide limited distinctions. The 10th edition of the International Classification of Diseases (ICD-10) has only one category (bipolar affective disorders), without any constituent bipolar I and II conditions, and with mania distinguished from hypomania principally by severity. ICD-10 states that psychotic features are absent in hypomania, but does not require their presence for mania, and further suggests that hypomania is a state often occurring as patients develop or recover from mania. The 4th edition of the Diagnostic and Statistical Manual of
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Mental Disorders (DSM-IV) essentially differentiates bipolar I and II disorders by the respective presence of manic or hypomanic episodes, and have very similar symptom criteria for diagnosing mania or hypomania. DSM-IV differentiation is limited to differing minimal duration periods (seven days or less if the patient is hospitalized for mania, and four days for hypomania) and with psychotic features and/or hospitalization resulting in allocation of a manic episode. However, neither hospitalization nor psychotic features during a high is a necessary requirement for a DSM-IV diagnosis of mania or bipolar I disorder. Episodes of mood elevation accompanied by marked impairment of occupational or psychosocial function are considered to have sufficient severity to merit deeming as manias. This additional means of meeting the DSM-IV severity criterion has the important limitation of not being adequately operationalized, making the distinction between some manic and hypomanic episodes (and hence between some cases of bipolar I disorder and bipolar II disorder) challenging. A potentially useful categorical model – and one variably used over time – parsimoniously differentiates those two bipolar conditions by the lifetime presence (bipolar I) or absence (bipolar II) of psychotic features during a high, and similarly positioning mania as a psychotic state and hypomania as a non-psychotic state. We have provided some empirical support for such a categorical model. Thus, in a sample of bipolar patients [2], those who had experienced any lifetime psychotic manic state were also likely to have experienced a psychotic episode when depressed. More importantly, no patient experiencing a non-psychotic hypomanic episode had experienced psychotic features when depressed. We therefore suggested that those with a bipolar II condition have oscillating non-psychotic extremes of mood and energy, while those with a bipolar I condition experience the categorical feature of psychosis – at least during highs and, at times, when in a depressive episode. If a valid model, then it might be imagined that there would be substantive differing biological contributions to the differing (psychotic and non-psychotic) conditions, leading to differential management nuances. While
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this chapter is structured with some respect for that model, evaluating the published literature is constrained by the reality that study definitions of those with a bipolar II disorder vary considerably.
An overall management model We argue for a management model that involves – after diagnostic clarification – three key components: medication, education and the development of a wellbeing plan, with the contribution of each varying over time.
Clarifying the diagnosis Most people with a bipolar II condition present to outpatient health facilities (as they do not experience psychotic conditions requiring hospitalization) during a depressive episode or, as a consequence of greater community awareness, to pursue the possibility that they might have a bipolar condition. Longitudinal data (e.g. a history of hypomania in a patient presenting with depression) are commonly more important than cross-sectional data in clarifying the diagnosis, while corroborative witness data (e.g. from a family member) should be sought. In essence, an individual with true bipolar II disorder should have had mood swings emerge at some time (most usually in adolescence), so that the clinician is seeking to identify a trend break. This does not deny that there are some individuals who will describe mood swings going back into childhood but even these patients are likely to describe a distinct worsening in adolescence or later. Early onset is commonly considered to be a marker of more severe illness, but to date definitive evidence of differential onset age in bipolar I and bipolar II disorder is lacking. While it is also true that there are some individuals with true bipolar II disorder that have experienced highs without any depressive episodes, this is rare. Indeed, the DSM-IV definition of bipolar II disorder requires not only at least one hypomanic episode but also at least one major depressive episode. Thus, assessing depressive clinical symptoms can be as important as assessing features of the highs. In essence, most individuals with bipolar II disorder will describe a pattern dominated by melancholic symptoms (e.g. a profound non-reactive and anhedonic mood, impaired concentration, diurnal variation of mood and energy), although they are less likely to report the more characteristic melancholic features of early morning wakening, and appetite and weight loss – and more likely (especially in younger patients) to report converse features of hypersomnia and hyperphagia that are considered associated with atypical depression. The presence of psychotic features (i.e. frank delusions or hallucinations, or distinct over valued ideas) would more suggest a bipolar I disorder.
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Turning to the highs, those with a bipolar II disorder feel more energized and wired, and would be expected to report a set of symptoms noted elsewhere in this book. One key feature that we find clinically useful is to ask about anxiety during any presumptive high. During a pure high, individuals will commonly report anxiety disappearing like snow on a summers day as they become carefree and without anxiety. An important exception is Obsessive Compulsive Disorder (OCD), where those with bipolar II disorder will at best report some lessening of their OCD but rarely its complete disappearance. Also, some highs with mixed features may entail not only symptoms of mood elevation, but also depression and anxiety. A diagnosis of bipolar II should not be made if the individual has only experienced episodes of highs on commencing an antidepressant, on having its dose increased to high levels or on its cessation. Here a diagnosis of the non-DSM term bipolar III is more appropriate, although many such patients have disorders that progress to have subsequent spontaneous mood elevation episodes. While many with bipolar II disorder will report episodes being precipitated by stressors (particularly early in the course of illness), clinicians should search for some intrinsic cyclicity to some or most episodes. Triggers or precipitants vary, ranging from life stressors, to seasons (spring being over-represented) and to stimulant drugs (including highenergy drinks and caffeine, as well as illicit stimulant drugs). Many patients with bipolar II disorder crave and use alcohol and stimulant drugs to precipitate or advance a high, while their resistance to alcohol is seemingly increased – often able to drink considerably more than when euthymic. While DSM-IV requires a minimum of four days for a hypomanic episode, this criterion was not established empirically and has, in fact, been discounted in a number of empirical studies (e.g. [2–4]). If the four-day duration criterion is applied, it runs the risk of rejecting a true diagnosis – as hypomanic episodes can in reality sometimes last a couple of days or less. The latter pattern is particularly common in those who have ultra rapid (within a week) or ultradian (within a day) mood changes. Alternative diagnoses that need to be included or excluded commonly include Attention-Deficit/Hyperactivity Disorder (ADHD), and borderline or sensitivity to rejection personality styles. ADHD is usually marked by ongoing concentration, attention and academic problems in childhood (with or without hyperactivity), while those with a bipolar II disorder will have either not shown such behaviours or have only experienced periods of inattention and concentration problems (along with some features of highs such as insomnia) intermittently in childhood, if at all. Those with a borderline personality style will again tend to show such personality characteristics in an ongoing way, and are more likely to have episodes of irritability and anger in
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relation to stressors (rather than mood elevation), and be less likely to report any intrinsic cyclicity pattern. The personality style of sensitivity to rejection is marked by seemingly having a semi-permeable membrane to external stimuli that impact the individuals self-esteem, with the individual over-reacting positively to praise and over-reacting negatively to any perceived criticism, rejection or abandonment. Here, such reactions appear closely linked to stimuli, do not show any natural cycling pattern, do not have the usual clinical features noted above in relation to depression and highs, and reflect a chronic longstanding pattern rather than an episodic course emerging in adolescence or early adulthood. Another challenging differential diagnosis involves highly creative individuals who, when affected by their creative muse, become energized, experience mood elevation, are clearly more productive, need less sleep without feeling tired and tend to be more talkative. Such individuals will usually only describe highs or pseudo highs when engaged in creative pursuits. It is worth noting, however, that creativity may be enhanced in people with bipolar disorder [5], and that there is temperamental overlap between such individuals with bipolar disorder and highly creative people [6]. While these alternate conditions need to be considered, each is possibly over-represented in those with true bipolar II disorder, rejecting the theoretical principle (rarely evident in operation) of diagnostic parsimony. Finally, secondary bipolar disorder needs to be considered. While a loose concept, this effectively views the bipolar condition as secondary to an antecedent organic cause (e.g. brain tumour) or drug (e.g. steroids).
Providing the diagnosis and addressing its impact Faced with a diagnosis of bipolar II disorder, patients vary in their reaction. For some it is a relief – they have an explanation and can more efficiently pursue management information. Others equate the condition with manic depressive psychosis and are overwhelmed by maniac or related connotations. Many who have comfortably accepted that they have a depressive condition, hold the view that bipolar disorder is more severe and more stigmatizing, and become concerned about implications – especially the extent to which they might be trusted with confidential information or financial responsibilities at work. Irrespective of specific concerns, for most people there is an impact phase where the individual deals (or fails to deal) with new realities – that they have a condition that is not simply depression, that it cannot be cured but more controlled, and that it is going to require extended and often sophisticated management. Denial is common early on, and some individuals never fully adjust to the perceived sense of loss, while others take months or years to make an appropriate adjustment. The managing clinician should consider
how best to assist the individual to proceed through this impact phase as rapidly as possible. The clinician may find it useful to emphasize that it is a bipolar II condition and not that other type – manic depressive psychosis with psychotic episodes (and often requiring hospitalization), so creating a distinction that is appreciated by many patients. Second, noting that, while it cannot be guaranteed that the first, second or even third treatment will be effective, emphasizing that a pluralistic management plan will bring the condition progressively under increasing control is of central importance. The caveat – that the condition may not necessarily rapidly respond – avoids frustration and anger if initial strategies yield suboptimal outcomes. Positioning management as pluralistic rather than just merely relying on medication builds to a partnership model rather than a top down clinician-weighted and drug-loculated model, which is limiting for many patients, making them passive recipients rather than active participants in their treatment. Informing the patient that the condition commonly has a genetic cause has both benefits and limitations. For those who view this information as positive, this commonly reflects an appreciation that it is not a character problem (or a personality disorder as some have had previously diagnosed) and more a hard-wiring issue over which they essentially have had only limited control. An important limitation for some people reflects a stated or unstated concern that they may pass it on to their children. Emphasizing that a genetic cause reflects vulnerability rather than destiny, and drawing parallels with other medical conditions, such as diabetes mellitus that entail genetic vulnerability interacting with precipitating or protective environmental contingencies, may prove worthwhile. While clinicians clearly vary in the messages that they initially convey, these are some that we have found useful raising after giving the diagnosis. First, while bipolar II can be brought under control, the depressive episodes are, in particular, commonly severe and that this reality argues for the importance of close management. Second, it is a common mood disorder (effecting up to 6% of the population) – with the meta-communication being that the individual is not alone. Third, management involves the three key components noted earlier – medication, education and the development of a well-being plan. Fourth – and an attempt to further a positive message –there is an over-representation of people with bipolar disorder in creative fields. The last issue often melds with an early – and subsequently repeated – query from patients that, as highs are often productive and enjoyed, why should they be treated, especially if they are not too severe. The answer usually reflects a lesson that most clinicians have had to learn, and learn again, that the higher an individual goes, the greater the chances of disastrous mood-elevated decisions (e.g. inappropriate financial investments) and rebound severe depressions. Fifth, while there are many studies providing
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group-based data on management options, predicting any individuals response is challenging – with about one-third responding well to their first medication, one-third responding well or moderately well to one or two medications after trialling several other medications, and the remaining one-third commonly requiring multiple medication trials and needing combination medications to maintain their mood state. Sixth, once their mood state has been brought under reasonable control, there is no reason as to why they should forego most future life aspirations or ambitions – with the main caveats being that care is necessary to adhere to treatment and address mood-destabilizing factors such as stress (e.g. sleep deprivation) and exposure to alcohol and drugs, and that female patients require careful review of medication (and possible changes) when they seek to become pregnant. In essence, the clinician should feel comfortable offering a guardedly optimistic prognosis but not one that is simplistic and/or infers that the condition will necessarily be brought under control rapidly. The key message is that, while the condition cannot be cured, it can eventually be controlled.
Medication There are three distinct important clinical objectives for clinicians. First, to achieve mood-stabilization so that individuals remain euthymic (rare) or have minimal mood fluctuations. Second, to treat any breakthrough depressive episodes and, third, to seriously consider treating any breakthrough hypomanic episodes.
Mood-stabilizing medication strategies As noted earlier, in the absence of evidence-based guidelines, there is a tendency for clinicians to use the same strategies recommended for managing bipolar I disorder as for managing those with a bipolar II condition, and this usually positions mood-stabilizing drugs as a high priority strategy. As reviewed by Hadjipavlou and Yatham [7], there are a number of studies that have shown clear support for lithium as a maintenance therapy in bipolar II disorder. However, those authors go on to state that valproate is often considered more effective than Lithium in the treatment of rapid cycling bipolar disorder (albeit without supportive randomized controlled data), before concluding that it remains unclear as to whether those with bipolar II disorder fare better with lithium or valproate. They also note several studies suggesting that lamotrigine can be an important maintenance treatment for those with bipolar II disorder, and particularly those who have rapid cycling course. Other authors (e.g. [8,9]) have prioritized lamotrigine above other mood-stabilizers for managing bipolar II disorder, with that judgement reflecting both its efficacy for depressive symptoms and its generally very good tolerability.
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Hadjipavlou and Yatham [7] also note that combination mood-stabilizers may be required, and that the combination of lithium and lamotrigine is a potentially viable approach (albeit lacking adequate systematic evidence of efficacy), but with the rationale being that lamotrigine tends to yield more robust stabilization from below, providing greater relief of depressive symptoms, while lithium tends to yield more robust stabilization from above, providing greater relief of mood elevation symptoms [10]. Those authors briefly noted the possible role of other mood-stabilizers such as carbamazepine, as well as the anticonvulsants gabapentin and topiramate. However, in the absence of any formal studies and reflecting clinical observation, they suggested that lithium, valproate and lamotrigine have stronger cases for consideration as mood-stabilizers for bipolar II disorder. The atypical antipsychotic drugs are increasingly being positioned as having mood-stabilizing properties for those with bipolar II disorder (as many have been studied extensively for those with bipolar I disorder) and with their possible role reviewed by Fresno and Vieta [11]. However, few studies have been performed with pure bipolar II disorder samples (most studies combining patients with bipolar I and II disorders) and few sub-set analyses limiting consideration to those with a bipolar II condition have been reported. Currently, quetiapine has generated the largest number of studies of atypical antipsychotic drugs, and with such studies providing some support for this drug having mood-stabilizing properties, in both being of some benefit for bipolar II patients during depressive and hypomanic episodes, and in reducing the chance of breakthrough episodes over time. Arguably, the most controversial interventions are the antidepressant drugs and the roles of these agents have been reviewed in relation to bipolar II disorder [12,13]. There is strong dissonance in views between clinicians and those who produce guidelines for managing bipolar disorder in their consideration of antidepressant drugs, although the debate is generally restricted to their potential to assist depressive episodes in those with a bipolar II disorder without risking mood switching, mixed states and more rapid cycling. The first author of this chapter has, however, observed a number of patients with a bipolar II disorder who, when prescribed antidepressant monotherapy (most commonly an SSRI or a dual-action drug such as venlafaxine), have not only reported a reduction in depressive episodes over time but have also reported a change in their pattern of highs. In contrast, the second author of this chapter has observed that therapeutic inefficacy is an alltoo-common problem with antidepressants in patients with bipolar II disorder. Such differential experience may be related to referral bias. For example, in the United States, bipolar II disorder patients experiencing inadequate efficacy or tolerability to standard antidepressants may
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gravitate towards bipolar disorder clinics, while bipolar II disorder patients having better outcomes with standard antidepressants may not need to proceed beyond their initial prescribing family physician or psychiatrists to a subspecialty clinic. In the experience of the first author of this chapter, when an antidepressant-induced change in the pattern of highs is described or acknowledged, it generally involves bipolar II patients noting that highs are less common, less severe and briefer in duration – rather than completely controlled. As a consequence of such observations, a proof of concept study [14] was undertaken. In that study, 10 patients with a diagnosis of bipolar II disorder and who have never previously received any psychotropic medication were enrolled in a nine-month study. Over the first three months, subjects received no medication, and merely completed daily rating measures while being regularly reviewed on the Hamilton Rating Scale for depression and the Young Mania Rating Scale for hypomania severity estimates. In the second three-month period, they were randomly assigned to receive either the SSRI escitalopram or placebo and, for the third three-month period, subjects received the converse (SSRI or placebo) option. Despite the small sample size, there was a reduction in depression severity scores when the subjects were receiving the SSRI and a trend for the number of days depressed to be reduced. While there was a trend for the severity of hypomanic episodes to be reduced in severity, this was not statistically significant. In terms of days ill (whether as a consequence of hypomanic or depressive episodes) subjects reported fewer days ill and also reported significantly higher functioning when receiving the SSRI. When daily rating mood measures were examined for each of the 10 subjects (and as graphed in the report), there were several subjects who showed a clear attenuation or minimization of highs when receiving the SSRI. Over the trial, there was no evidence that exposure to the SSRI increased cycling frequency or was associated with any increase in the number of highs. In contrast, in the experience of the second author of this chapter, bipolar II disorder patients who commonly present with depressive symptoms resistant to standard antidepressants may respond when a mood-stabilizer such as divalproex is added [15], and that bipolar II patients presenting with concurrent depression and hypomania while taking standard antidepressants may respond when an atypical antipsychotic such as quetiapine is added. Clinical experience by the first author suggests that standard antidepressant drugs can have some mood-stabilizing potential in about 30–40% of patients with a bipolar II disorder but that, after weeks or months, there is some poop out of efficacy in about half of those who initially received some benefit. This lack of efficacy can be temporally overcome by increasing the dose of the antidepressant – but again, many patients will describe further poop outs
as the dose is increased to recommended upper limits. Clinical experience by the second author is consistent with this, with patients presenting with bipolar II depression despite antidepressant therapy commonly reporting prior transient responses. While treatment guidelines for those with bipolar II disorder argue that antidepressants are contra-indicated in those with a bipolar disorder – as they increase the chance of highs (switching), or increase the frequency of highs and/or increase the chance of mixed states – it is the first authors experience that such consequences are relatively rare. This view is partially shared by the second author, who commonly encounters inadequate antidepressant efficacy as the main problem with antidepressants in patients with bipolar II disorder, but also encounters a substantial number of bipolar II disorder patients taking antidepressants and presenting with concurrent hypomania and depression.
Medication strategies for managing depressive episodes Individuals with a bipolar II disorder most commonly present for help with a new depressive episode (with or without having previously received any psychotropic medication), or following a breakthrough episode while already on a psychotropic drug regime. However, as noted above, some patients with bipolar II disorder present with concurrent hypomania and depression. As noted earlier, guidelines for managing bipolar depression (essentially in relation to those with a bipolar I condition) argue against use of antidepressant drugs or only introducing them after a mood-stabilizer has been prescribed for a period. Numerous studies have shown that not only are antidepressant drugs widely prescribed by clinicians for those with bipolar II disorder but that they are the most common drug class prescribed when such patients present during a depressive episode. Concerns about increased switching have generated quite varying findings. Leverich et al. [16] reported a study of patients with bipolar I and II disorders and who were receiving an antidepressant drug (bupropion, sertraline or venlafaxine) in addition to a mood-stabilizer. Three findings with possible clinical implications are worth noting. First, the rate of switching was less likely in those with a bipolar II than a bipolar I disorder (18.6% vs. 30.8%). Second, switching was some three times more likely in those receiving the broader action antidepressant venlafaxine than the SSRI sertraline. Third, in the entire combined group of bipolar I disorder and bipolar II disorder patients, switching was approximately twice as common with chronic (one year) treatment (21.8% hypomania and 14.9% mania) compared to acute (10 weeks) treatment (11.4% hypomania and 7.9% mania). However, as this study was not placebo controlled, any judgement as to whether the switch rate exceeded the natural history rate cannot be made.
Management of Bipolar II Disorder
Furthermore, a Cochrane review [17] quantified little support for antidepressant drugs inducing switching (apart from the tricyclic antidepressant class) and concluded that antidepressants are effective in the short-term treatment of bipolar depression. Furthermore, Amsterdam and Shults [18] reported a study of those with bipolar II and bipolar not otherwise specified (NOS) conditions, where depressed subjects received open-label fluoxetine for 8 weeks and responders were subsequently enrolled in an second phase involving double-blind, placebo-substitution continuation therapy with fluoxetine for 6 months. This pilot study indicated that the SSRI fluoxetine appeared to be safe and effective for some patients (and). . .with a low manic switch rate. Large controlled trials are needed to provide an evidence base to inform clinical practice regarding the benefits and risks of antidepressants in patients with bipolar II disorder. As noted above, to date there are limited systematic data regarding the benefits and risks of adding antidepressants to mood-stabilizers in patients with bipolar II disorder. In the largest randomized, double-blind, placebo-controlled pharmacotherapy study to date, 179 bipolar disorder patients (68.6% Type I and 31.4% Type II) taking antidepressants (bupropion or paroxetine) plus mood-stabilizers compared to 187 bipolar disorder patients (67.0% Type I and 33.0% Type II) taking placebo plus mood-stabilizers did no better (similar efficacy) or worse (similar switch rates). The pattern of findings was similar in patients with bipolar I disorder and those with bipolar II disorder [19]. These discouraging adjunctive pharmacotherapy findings were in contrast to more encouraging adjunctive intensive psychotherapy findings from the same group of investigators [20]. Taken together, these studies suggest that controlled head-to-head studies are needed to assess whether adjunctive psychotherapy might yield more benefit than adjunctive antidepressants in patients with bipolar II depression. Despite counter-recommendations from formal guidelines, antidepressants are commonly prescribed – presumably reflecting the reality that episodes of depression in those with a bipolar II disorder are generally severe and debilitating, and can put individuals at a significant risk for suicide, and for psychosocial losses (e.g. jobs or relationships). Equally important, many clinicians judge antidepressants as commonly sufficiently effective, may fail to detect or appreciate the importance of residual depressive symptoms, and either discount or be unaware of attendant risks (of switching and increased propensity to mixed episodes and increased cycling). The first author has little hesitancy in prescribing an antidepressant drug when an individual with bipolar II disorder presents with depression – sometimes as monotherapy and sometimes in conjunction with a mood-stabilizer. The second author will, in most circumstances, prescribe antidepressants along with anti-
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manic agents or perhaps lamotrigine without an antimanic agent, and if a patient presents with depression along with even subsyndromal mood elevation symptoms, will start with an antimanic agent and only add an antidepressant (or lamotrigine) if mood elevation symptoms resolve and depression persists. As with antidepressants, there are only limited controlled data to inform clinical practice with respect to alternative approaches. For example, in randomized controlled bipolar II depression trails, lamotrigine was not significantly better than placebo in one double-blind study [21], but was comparable to lithium in another single-blind study [22]. Similarly, there are only limited controlled [23,24] and uncontrolled [25,26] data regarding the utility of divalproex in bipolar II depression. The management model of the first author assumes a hierarchy to the potency of antidepressant drugs in such situations, with narrow-action SSRIs generally initially trialled. If they fail, dual-action drugs are trialled and, in turn, tricyclic antidepressants and finally monoamine oxidase inhibitors, with the view that broader spectrum drugs are more likely to be required in older bipolar II patients and those whose depressive episodes are more classically melancholic in type (i.e. marked by anhedonia, anergia, mood non-reactivity and psychomotor disturbance). Each antidepressant class (from narrow-action SSRI to broad-action MAOI) is initially trialled alone, and if ineffective or only associated with partial improvement, is augmented with a low-dose atypical antipsychotic for one to two weeks to determine if such combination therapy resolves the depression. If the combination produces a euthymic mood state, an attempt is made to cease the atypical antipsychotic in the following week to see if the antidepressant (with or without any mood-stabilizer) is sufficient to keep the depression at bay. The above approach varies somewhat from that of the second author, who early on discusses with the patient the only (United States) approved treatments for bipolar II depression (quetiapine, as well as the olanzapine-fluoxetine combination), but in view of the tolerability limitations of these treatments will also consider lamotrigine due to its good tolerability, as well as the use of an SSRI or bupropion (most often along with an antimanic agent), particularly if such antidepressants have yielded excellent prior responses in the patient or a first-degree relative. If the depression is resistant to an SSRI, bupropion and/or a SNRI, novel adjunctive agents with at least some controlled evidence of efficacy, such as modafinil or pramipexole, will be considered prior to MAOIs, while tricyclic antidepressants are generally avoided.
Medication strategies for managing hypomania The first and second authors personal view is that not all episodes of hypomania necessarily require adding or
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increasing antimanic medication. Indeed, such presentations may provide opportunities to decrease or even discontinue antidepressant medication. If the hypomanic episode is relatively mild and/or the patient has a history of such episodes being relatively brief, then the patient may have a spontaneous remission or, with training and development of a well-being plan, become able to use non-medication strategies such as psychotherapy, enhanced sleep hygiene (ensuring at least 6 hours sleep), avoiding illicit drugs, limiting alcohol use and overall activity level to stabilize their mood. Medication is, however, appropriate when the high is of such severity that there are distinct attendant risks (e.g. misadventure, disinhibition) or when the patient reports that their highs put them at risk of a significant depressive episode. If the patient is not already in receipt of any medication, then a mood-stabilizer (particularly low dose lithium or valproate) is an option, while the use of a low-dose atypical antipsychotic for a brief period until the ongoing mood-stabilizing regime has been modified can be a useful strategy. The second author has a similar approach.
Education As for any chronic medical or psychiatric condition where control is the objective other than cure, education is fundamental for several reasons. First, it is the right of the patient to be informed about their condition, management options and factors that can influence outcome, and many seek to be educated about causal factors, specific risks (e.g. the use of psychotropic drugs in pregnancy) and treatments on the horizon. The second reason reflects the previously noted dislocation process that follows the impact of receiving a diagnosis of a bipolar disorder. As noted, patients initially may tend to feel controlled by their condition and have great difficulty in either accepting the diagnosis or the need to accept a management plan. The therapeutic aim of education here is to progressively advance the patients sense of mastery over their condition, to ensure that they are not defined by their condition and that they can learn ways to bring it under greater control. Accepting these givens, the task then is to consider how education is best provided. The managing clinician should be expected to provide both general educational components and also – as a consequence of having some understanding of their knowledge, sophistication, psychological mindedness and other relevant factors – be able to address some of the nuances specific to that patient. Such a clinician-provided educational introduction is a priority after the diagnosis has been provided to the patient. Subsequently, there are a large number of both generic and finely focused educational options that individuals tend to find useful. The Internet is clearly a major source of information, but patients need to be informed that much of the material on the Internet is in relation to bipolar I
disorder and with little specific to bipolar II disorder. The Black Dog Institute has developed an 80-minute web-based educational program (blackdoginstitute.org.au) on the bipolar disorders (both bipolar I and bipolar II), which is pluralistic in the domains covered, describing the bipolar disorders, their causes, drug and non-drug treatments, psychological approaches, how carers can support the individual, and how the individual can both survive and come to terms with the condition. Of the 10 professionals who contribute to this site, 5 have lived with a bipolar disorder themselves, so that the presentations provide an amalgam of outside in and inside out views, while the meta-communication of having successful professional people with a bipolar disorder contributing to the Web site provides an empowering optimistic message. Other Web sites provided by professional (e.g. bipolarnews.org) and peer support (e.g. dbsalliance.org) organizations can also provide useful educational information for patients and their families. Some regional research centres regularly provide live educational experiences for patients and their families, some of which are archived on the Internet (e.g. bipolar.org). There are many books that have been written about bipolar disorder for those with the condition, and lists of these books are provided on most bipolar Web sites. Reading evocative accounts of those with bipolar disorder (e.g. [27,28]) can be particularly helpful, although again most written accounts have been provided by those with a bipolar I condition and by people eminent in their own professional field – which causes some patients to read in admiration but with the belief that such management successes merely reflects those individuals extraordinary gifts. A powerful strategy, that allows patients to identify and promote engagement, is their reading the stories of ordinary people who have had to deal with a bipolar disorder for an extended period. Some such stories are provided on Web sites, while this model is being increasingly used to frame self-help publications. Eyers and Parker [29] compiled excerpts from essays written by more than 200 people with a bipolar disorder to capture their wisdom on ways of managing mood swings on a daily basis. One quote from a bipolar contributor is worth noting: The average bipolar sufferer is getting off the train in front of you. We are family members, we are friends and workmates. We tile floors, we drive taxis and we process insurance claims. And some days we are in a knock-down prize fight for our jobs, our partners, our families and our lives. The metaphor for that book was the need for the individual to achieve balance. The term balance draws attention away from the opposing forces of hypomania and depression, and requires the individual to focus on the middle ground – and the treatments and lifestyle choices required to get there. The term balance also addresses the trade-offs that people need to master their bipolar disorder and captures the need for the individual to balance their
Management of Bipolar II Disorder
condition and their personality (e.g. where any natural sense of spontaneity has to be balanced into the need for a certain amount of routine). Furthermore, the metaphor notes how stresses and a range of factors can tip the person off balance and how well-being plans need to have rebalancing strategies. Just like acrobats, people with a bipolar disorder are often precariously balanced on the high wire – with or without a safety net – and ideally they learn to balance in formation with the support of family members and friends. In that particular book, patients communicate strategies that they have found most useful over time and certain lessons emerge. While conceding that the book is biased to those more successful in bringing bipolar disorder under control, there are some messages that inform us about components of a successful management plan. After a period of time, most people take their medication and respect the health practitioner who is looking after them. The contribution of these two factors is viewed almost as a given. However, bipolar patients who have achieved a level of mastery more highly value the contributions that they have learned and introduced themselves that keep their mood states in check. This finding points to the need for individuals with a bipolar II condition to recognize self-management as a singularly distinctive factor – that it is central to bringing the condition under control or into balance, and needs to be encouraged by the managing clinician.
Psychological interventions As reviewed by Manicavasagar [30], there is increasing recognition of the importance of adjunctive psychological interventions. However, there are risks of positioning psychological strategies as either tokenistic strategies or, alternately, as having universal application and, – in their implementation, providing them in unmodified ways and/or in a simplistic painting by numbers strategy. Many clinicians argue that all bipolar patients need adjunctive cognitive behaviour therapy (CBT) or some other adjunctive psychotherapy, as if any such psychotherapeutic modality can be applied as if it has universal application. However, bipolar II disorder is an equal opportunity condition, in the sense that it is not primarily a consequence of temperament or personality style, and many individuals have a perfectly normal personality. If an individual with a bipolar II disorder does not have any trait limitation that argues a priori for CBT (e.g. a dysfunctional attributional style, faulty cognitive schema) then recommending a treatment such as CBT risks being inappropriate. Some would argue against this view and refer to the empirical literature, which is replete with studies demonstrating that adding psychotherapy to medication improves outcomes for individuals with bipolar disorder. However, controlled data also indicate that patient selection is important. For example, Scott and associates [31] found that amongst patients
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with severe recurrent bipolar disorders (94% Type I, 6% Type II), benefit from adjunctive CBT was restricted to patients with fewer than 12 prior episodes. Furthermore, is it the addition of psychotherapy or the provision of a more pluralistic model (i.e. management not being restricted to medication review) that is helpful? Selection of therapies providing specific attention to dysfunctional attitudes (e.g. CBT), family dynamics (e.g. Family Focused Therapy) or relationship and circadian rhythms (e.g. Interpersonal and Social Rhythm Therapy) ought to be based on patient needs and preferences. Arguably, psychoeducation is the most common non-specific component of psychotherapies for bipolar disorder, highlighting the importance of education across the broad range of patients with bipolar disorder. Psychotherapies for bipolar disorder have both specific and non-specific benefits, with the non-specific benefits (e.g. empathy, understanding, support) being substantive. For many patients with a bipolar II disorder, and who see a doctor who merely prescribes medication, that narrow focus and allopathic paradigm is generally viewed as limited, so that any psychotherapeutic engagement (whether provided by the prescribing doctor or by another therapist) advances the patients sense of being heard and understood as an individual human being as well as being an active participant in their care. For those and other reasons, individuals who are recipients of psychotherapy or even participating in peer support groups are more likely to be compliant with medication and adherent to non-drug management strategies. In essence then, any psychotherapeutic ingredient both needs to respect the recognized benefits of non-specific ingredients but also needs to be titrated to address those psychosocial factors that risk exacerbating the underlying condition and unbalancing the individual. Thus, psychological interventions should include self-monitoring of symptoms and mood, need to have an educational emphasis, should address psychosocial factors predisposing or precipitating an episode – and the consequences of an episode – while there can frequently be benefit in the therapist seeking to preempt the collateral damage that can occur with episodes or follow them. While psychotherapy is commonly viewed as an interaction between a therapist and a patient, for managing those with a bipolar II disorder, then psychotherapeutic and counselling strategies can frequently be more cogent, effective and appreciated if relevant other parties (e.g. family members and even employers) are involved at appropriate times. Psychotherapy should also seek to address and preempt stigma and illness consequence events, such as compromised self-esteem, demoralization, suicide risk and relationship issues. As such, a set of tasks overlap with a well-being plan (see below), consideration should be given as to how such a management model is positioned – be it as a psychotherapy,
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as psychoeducation, a well-being plan, counselling or pluralistic common sense – and which discipline is best trained to deliver it well. The psychotherapist needs to recognize that people with bipolar disorder are at high risk of falling from grace and getting into difficulty as a consequence of ignoring advice or of the mood state resulting in them engaging in multiple disinhibited and at-risk behaviours. Recognizing that some patients may need to fail for a period before they learn from their mistakes and begin to achieve mastery is important for any psychotherapist to recognize. Thus, rather than terminate psychotherapy in an individual who appears noncompliant, affording an appropriate degree of leniency during a course of psychotherapy or leaving the door open for the patient to return at a later stage are important nuances for management. However, as bipolar disorder may be progressive as episodes accumulate, and it may be relatively more responsive to interventions early in the course of illness, efforts to engage patients in the treatment alliance early on are particularly important. Manicavasagar [30] has detailed a set of cognitive, behavioural, family focused and interpersonal problem strategies that may be applied to those with a bipolar II condition. The psychotherapist needs. like the patient. to be aware of early warning signs, and to introduce strategies that can minimize precipitating factors and ones that work towards relapse prevention.
Well-being plans Orum [32] has detailed arguments in support of patients with a bipolar II disorder having well-being plans developed, and the potential components of such plans. She argues that such a strategy is underlined by the axiom that knowledge is power. Knowledge refers to the need to be highly aware of early-warning signs and triggers, as well as aspects of the illness itself, while power is required to recognize the potential risks and to know how to neutralize or otherwise take action. She notes that the most used strategies include ensuring adequate sleep, being aware of early-warning signs and triggers, keeping stress at manageable levels, taking appropriate medication and making use of professional support and compassionate support figures. As has been emphasized earlier, most people contributing to a well-being plan benefit from a strong sense of ownership. Orum observes that rather than merely following doctors orders, people with a bipolar II disorder benefit from assuming responsibility for the overall management of their illness, although it can take months or years to finesse into a well-tuned strategy-based system. Orum notes that a well-being plan is more than simply avoiding symptoms or keeping an illness in check, and that it more seeks to raise the level of response to a higher level, protecting against episode risk, reminding or challenging the
individual to take needed steps towards adding value to their life and working towards a more robust sense of self, which buffers against episodes. Orum further observes that it is often more difficult for those with a bipolar II disorder to commit to such a plan as they do not have psychotic manic episodes, suffer the consequences of being viewed as crazy or as needing hospitalization, and therefore may wish to retain their euphoric and enjoyable highs. She notes that the chief desire for most with bipolar disorder is to rid themselves of depressive episodes but, as noted earlier, the argument that allowing highs to develop runs the risk of depression, is usually the most sustaining one for engaging people with a bipolar II disorder to develop and follow a well-being plan. Orum suggests that there is no uniform format for a wellbeing plan, and that it may range from a private decision by an individual to adopt a certain strategy, through to a formal document drawn up by an individual to consult family, friends and health professionals. A primary consideration is what will work best for the individual involved? The individual needs to feel confident that the plan will serve their particular interests and circumstances, both in the short and the long term. The number and quality of the individuals relationships should determine who might be called on in particular circumstances, and clearly influence the likely success of the plan. Motivating the individual to develop a well-being plan commonly involves first exploring the costs and benefits of the illness and conceptualizing a life with fewer episodes, and with the individuals own deliberations shaping the management plan rather than having it imposed in a top down manner by the clinician. Orum argues that a well-being plan should also include some positive psychology strategies, so that individuals seek out pleasurable activities, become more engaged in interesting and absorbing activities, and seek a greater meaning in life – principally through a sense of contribution. Only recently has systematic research in bipolar disorder focused on the potential importance of positive emotions in patients with bipolar disorder [33]. Orum [32] concludes that well-being plans must reflect the preferences and personal style of the individual, be responsive to current needs but foreshadow future ones, and be flexible. While they can either be simple or complicated, developed alone or in conjunction with other people, they should incorporate experiences from the past, identify early-warning signs and triggers, set out action plans for minimizing or preventing future episodes, and include quality of life commitments to advance the individual beyond merely managing episodes.
Summary The pluralistic model outlined here can be implemented in multiple ways and by involving varying practitioners.
Management of Bipolar II Disorder
Such a model entails having the psychiatrist (in conjunction with the family physician) take principal responsibility for medication issues, a psychologist well trained in managing bipolar disorder take responsibility for developing and monitoring a well-being plan, peer support groups provide additional information and assistance for patients and their significant others, and recommending a set of fact sheets and Internet-based resources detailed for education. Patients and their families need to be engaged and active participants in such multimodal efforts in order to optimize outcomes.
Acknowledgement The preparation of this chapter was supported by an NHMRC (Australia) Program Grant, an infrastructure grant from the NSW Department of Health and Bianca Blanch.
References 1. Merikangas, K.R., Akiskal, H.S., Angst, J. et al. (2007) Lifetime and 12-month prevalence of bipolar spectrum disorder in the National Comorbidity Survey Replication. Arch. Gen. Psychiatry, 64, 543–552. 2. Parker, G. (2008) Defining and measuring bipolar II disorder, in Bipolar II Disorder: Modelling, Measuring and Managing (ed. G. Parker), Cambridge University Press, Cambridge, pp. 46–60. 3. Angst, J., Gamma, A., Benazzi, F. et al. (2003) Toward a redefinition of sub-threshold bipolarity: Epidemiology and proposed criteria for Bipolar-II Disorder, minor bipolar disorders and hypomania. J. Affect. Disord., 73, 133–146. 4. Tully, L. and Parker, G. (2007) How low do we go? Is duration of a high integral to the definition of bipolar disorder? Acta Nauropsychiatrica, 19, 38–44. 5. Santosa, C.M., Strong, C.M., Nowakowska, C. et al. (2007) Enhanced creativity in bipolar disorder patients: a controlled study. J. Affect. Disord., 100, 31–39. 6. Nowakowska, C., Strong, C.M., Santosa, C.M. et al. (2005) Temperamental commonalities and differences in euthymic mood disorder patients, creative controls, and healthy controls. J. Affect. Disord., 85, 207–215. 7. Hadjipavlou, G. and Yatham, L.N. (2008) Mood-stabilisers in the treatment of bipolar II disorder, in Bipolar II Disorder: Modelling, Measuring and Managing (ed. G. Parker), Cambridge University Press, Cambridge, pp. 120–132. 8. Goodwin, G.M. (2008) Management commentary, in Bipolar II Disorder: Modelling, Measuring and Managing (ed. G. Parker), Cambridge University Press, Cambridge, pp. 262–264. 9. Post, R.M. (2008) Management commentary, in Bipolar II Disorder: Modelling II, Measuring and Managing (ed. G. Parker), Cambridge University Press, Cambridge, pp. 252–258. 10. Ketter, T.A. and Calabrese, J.R. (2002) Stabilization of mood from below versus above baseline in bipolar disorder: proposal for a new nomenclature. J. Clin. Psychiat., 63, 146–151.
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11. Fresno, D. and Vieta, E. (2008) The use of atypical antipsychotic drugs in bipolar II disorder, in Bipolar II Disorder: Modelling, Measuring and Managing (eds G. Parker), Cambridge University Press, Cambridge, pp. 113–140. 12. Goldberg, J.F. (2008) The role of antidepressants in managing bipolar II disorder, in Bipolar II Disorder: Modelling, Measuring and Managing (ed. G. Parker), Cambridge University Press, Cambridge, pp. 94–106. 13. Parker, G. (2008) The use of SSRIs as mood-stabilisers for bipolar II disorder, in Bipolar II Disorder: Modelling, Measuring and Managing (ed. G. Parker), Cambridge University Press, Cambridge, pp. 107–119. 14. Parker, G., Tully, L., Olley, A. et al. (2006) SSRIs as moodstabilizers for bipolar II disorder? A proof concept study. J. Affect. Disord., 92, 205–214. 15. Ketter, T.A., Wang, P., Nowakowska, C. et al. (2007) Divalproex-extended release monotherapy and adjunctive therapy in bipolar II depression. 7th International Conference on Bipolar Disorder. Pittsburgh, June 7–9, 2007, Bipolar Disorders, 9, p. 58. 16. Leverich, G.S., Altshuler, L.L., Frye, A.A. et al. (2006) Risk of switch in mood polarity to hypomania or mania in patients with bipolar depression during acute and continuation trials of venlafaxine, sertraline, and bupropion as adjuncts to mood-stabilizers. Am. J. Psychiatry, 163, 232–239. 17. Gijsman, H.J., Geddes, J.R., Rendell, J.M. et al. (2004) Antidepressants for bipolar depression: a systematic review of randomized, controlled trials. Am. J. Psychiatry, 161, 1537–1547. 18. Amsterdam, J.D. and Shults, J. (2005) Fluoxetine monotherapy of bipolar type II and bipolar NOS major depression: a double-blind, placebo-substitution, continuation study. Int. Clin. Psychopharm., 20, 257–264. 19. Sachs, G.S., Nierenberg, A.A., Calabrese, J.R. et al. (2007) Effectiveness of adjunctive antidepressant treatment for bipolar depression. N. Engl. J. Med., 356, 1711–1722. 20. Miklowitz, D.J., Otto, M.W., Frank, E. et al. (2007) Intensive psychosocial intervention enhances functioning in patients with bipolar depression: results from a 9-month randomized controlled trial. Am. J. Psychiatry, 164, 1340–1347. 21. Calabrese, J.R., Huffman, R.F., White, R.L. et al. (2008) Lamotrigine in the acute treatment of bipolar depression: results of five double-blind, placebo controlled clinical trials. Bipolar Disord., 10, 323–333. 22. Suppes, T., Marangell, L.B., Bernstein, I.H. et al. (2008) A single blind comparison of lithium and lamotrigine for the treatment of bipolar II depression. J. Affect. Disord, 111, 334–343. 23. Ghaemi, S.N., Gilmer, W.S., Goldberg, J.F. et al. (2007) Divalproex in the treatment of acute bipolar depression: a preliminary double-blind, randomized, placebo-controlled pilot study. J. Clin. Psychiat., 68, 1840–1844. 24. Sachs, G., Altshuler, L.L., Ketter, T. et al. (2001) Divalproex versus placebo for the treatment of bipolar depression. 40th Annual Meeting of the American College of Neuropsychopharmacology. Waikaloa, Hawaii.
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25. Winsberg, M.E., DeGolia, S.G., Strong, C.M. et al. (2001) Divalproex therapy in medication-naive and mood-stabilizernaive bipolar II depression. J. Affect. Disord., 67, 207–212. 26. Wang, P.W., Nowakowska, C., Chandler, R.A., et al. (in press) Divalproex extended-release in acute bipolar II depression. J. Affect. Disord., Corrected proof, Available online 17 November 2009. 27. Jamison, K.R. (1995) An Unquiet Mind: A Memoir of Moods and Madness, Picador, London. 28. Behrman, A. (2002) Electroboy: A Memoir of Mania, Random House Inc., Toronto. 29. Eyers, K. and Parker, G. (2008) Mastering Bipolar Disorder: Techniques for Gaining Balance on the Highwire, Allen & Unwin, Sydney.
30. Manicavasagar, V. (2008) The role of psychological interventions in managing bipolar II disorder, in Bipolar II Disorder: Modelling, Measuring and Managing (ed. G. Parker), Cambridge University Press, Cambridge, pp. 151–176. 31. Scott, J., Paykel, E., Morriss, R. et al. (2006) Cognitive-behavioural therapy for severe and recurrent bipolar disorders: randomized controlled trial. Brit. J. Psychiat., 188, 313–320. 32. Orum, M. (2008) The role of wellbeing plans in managing bipolar II disorder, in Bipolar II Disorder: Modelling, Measuring and Managing (ed. G. Parker), Cambridge University Press, Cambridge, pp. 177–194. 33. Gruber, J., Culver, J.L., Johnson, S.L. et al. (2009) Do positive emotions predict symptomatic change in bipolar disorder? Bipolar Disord., 11:3, 330–336.
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Management of Comorbidity in Bipolar Disorder Ihsan M. Salloum1, Luca Pani2 and Tiffany Cooke3 1
Department of Psychiatry, University of Miami, Miami, FL, USA Istituto Tecnologie Biomediche, Consiglio Nazionale delle Ricerche, Sede di Cagliari-Pula and PharmaNess Scarl, Edificio 5 - Parco Scientifico e Tecnologico della Sardegna - 09010 Pula (Cagliari) 3 Emory University, Rollins School of Public Health, 1518 Clifton Road Northeast Atlanta, GA 30329, USA 2
Introduction Comorbidity is a term originated in general medicine to account for the impact of associated clinical entities, which includes disease states but also non-disease states such as pregnancy, on the management and prognosis of the index disease [1]. Thus, the relevance of comorbidity is related to the potential impact of an associated clinical condition on the efficacy, effectiveness, choice of treatment and the outcome of the index disease. Considering the chronic course of bipolar disorder and the likely need for polypharmacy throughout its treatment, management of comorbidity and presenting psychosocial and pharmacological complexities must constitute an integral part of an individualized treatment plan for these patients. In this chapter, we will briefly review the multiple comorbidities associated with bipolar disorder. We will then focus on the management of psychiatric comorbidities, with special emphasis on the management of substance use disorders, given the frequency and the difficulties encountered n addressing these conditions in bipolar disorder.
Faces of comorbidity in bipolar disorder Comorbidities associated with bipolar disorder often span multiple domain clusters to include other mental health conditions, general health conditions and, at times, significant social problems. Psychiatric disorders comorbidity is usually the rule in patients with bipolar disorder. For instance, studies have reported that most individuals with bipolar disorder have another major psychiatric condition and over one-third of them also meet criteria for a comorbid personality disorder [2]. Substance use disorders and anxiety disorders constitute the vast majority of comorbid psychiatric disorders in patients with bipolar disorder. Studies have consistently reported a high rate of anxiety disorders in this population. The National Comorbidity Bipolar Disorder: Clinical and Neurobiological Foundations Edited by Lakshmi N. Yatham and Mario Maj © 2010 John Wiley & Sons, Ltd. ISBN: 978-0-470-72198-8
Survey estimates that 86.7–92% of patients with bipolar I disorder have a comorbid anxiety disorder (generalized anxiety disorder, social phobia, panic disorder, posttraumatic stress disorder) [3]. The National Comorbidity Survey and its replication study note that 47%–51.6% of bipolar I patients had comorbid social phobia. Lifetime and current prevalence of anxiety disorders in the Systematic Treatment Enhancement Program for Bipolar Disorder (STEP-BD) sample was reported at 51.2 and 30.5%, respectively [4]. Another study of clinical samples reported a rate of up to 71% of anxiety disorders [2]. Of those, almost half (47%) had social phobia, and 39% had post-traumatic stress disorder, while a significant minority (11%) had panic disorder. Another study reported the prevalence of obsessive-compulsive disorder at 30% [5]. While the reported rates may vary amongst studies, the findings of a high prevalence of associated anxiety disorders in bipolar disorder have been consistent [4]. Comorbidity with anxiety disorder is reported to be associated with younger age of onset, and to be more frequent amongst females and amongst patients with bipolar II as compared to bipolar I disorder [6]. The presence of anxiety in the bipolar patient has also been considered as an aspect of the illness, rather than a separate disorder, and viewed as an inborn characteristic of a severe form of bipolar disorder [4,6]. Anxiety disorders appear to confer an added dimension of severity to bipolar illness. Studies have found decreased likelihood of recovery, poorer role functioning and quality of life, less time euthymic and greater likelihood of suicide attempts in bipolar patients with comorbid anxiety [7]. A 12-month prospective study reported that bipolar patients with current comorbid anxiety disorder had fewer days well, a lower likelihood of timely recovery from depression, risk of earlier relapse, lower quality of life and diminished role function during the one-year study period. The presence of multiple anxiety disorders was associated with greater negative impact on quality of life as well. Anxiety disorders were reportedly associated with less response to treatment as well [4,5,8–11]. Non-remitting bipolar patients appear
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more likely to have a history of panic attacks and those with panic attacks may require an increased mean number of medications to achieve symptomatic remission [3]. The negative effect on the comorbid patient appears to be independent of the duration of bipolar disorder [4]. A supplementary study of the STEP-BD, revealed that lifetime comorbidity of anxiety disorder was found to double the probability of a past suicide attempt, and a current comorbidity doubled the odds of current suicidal ideation, which tended to be more severe. Current comorbidity also predicted increased suicide behaviours in the future [3]. Thus, comorbid anxiety disorders in the bipolar patient appear to be associated with poorer prognosis indicated by slower recovery from depression, earlier relapse, decreased chances of recovery, impaired social and occupational functioning, worse quality of life, less periods in a euthymic state, more suicide attempts and lower lithium responsitivity [4,6,12]. Multiple anxiety disorders are associated with increased impairment. Substance use disorder is the other major psychiatric comorbidity with bipolar disorder. Multiple clinical and large population-based epidemiological surveys have repeatedly documented high association between bipolar disorder and substance use disorders [13–15]. The National Epidemiologic Survey on Alcohol and Related Conditions (NESARC) [15] is the largest and most recent epidemiological survey to date of a representative sample of over 42 000 respondents in the United States. Mania and hypomania were associated with very high rates of substance use disorder. Respondents with mania were 14 times more likely to have drug dependence and 6 times more likely to have alcohol dependence over the preceding 12 months. The NESARC study also documented a high lifetime prevalence of mania (range from 8.9–33.4%) and hypomania (range from 3.7–13.4%) in respondents with the various drug use disorders [16]. Nicotine dependence due to cigarette smoking is another major health hazard that is highly prevalent in bipolar disorder. It is estimated that over 68% are current cigarette smokers and over 82% are lifetime smokers. While there is notable variability in the number of cigarettes smoked during the different phases of the disorders (higher in mania and lower in depression), nicotine dependence is the most frequent substance use disorder in this population [17]. The negative impact of associated substance use disorders on the manifestation, course, treatment adherence, hospitalization rate and suicidal behaviour has also been reported extensively [18–21]. Other psychiatric disorders that are comorbid with bipolar disorder include binge eating disorder, polysubstance use disorders and impulse control disorders such as pathological gambling. While recent clinical and epidemiological surveys have confirmed the high rate of associated psychopathology and other general health and salient social problems, development in the management of complex conditions, es-
pecially those that involve chronic course and significant behavioural and psychosocial components still represent clear challenges.
Management issues While traditional, disease-focused, acute care models are very effective in alleviating the most pressing symptoms, they may be inadequate when dealing with complex chronic disease processes. Recovery from an uncomplicated acute illness is usually expected with successful treatment. However, recovery from multiple chronic conditions, such as bipolar disorder and a substance use disorder, or accompanying diabetes, involves a different process of long-term commitment to maintaining stability and of health restoration. It requires a different culture of treatment even by most health professionals, in a manner where the therapy moves from acute symptomatic relief and control of the clinical status to prevention of subsequent and otherwise recurrent new episodes. Treatment for the acute episode in these conditions is usually the initial stabilization period of what is likely to be a lifelong treatment and adaptation process. In addressing comorbidity, there is a need to first identify potential co-occurring conditions, and then draft and implement a treatment plan that addresses the multiple presenting needs on long-term basis. Thus, the presence of multiple interacting conditions requires a shift in the diagnostic process from a purely disease or symptoms/signs focused approach, to a broader paradigm encompassing the health status of the person presenting for care, along with unique contextual factors significantly impacting on the global health status. This is facilitated in psychiatry as there exists a tradition of adopting a biopsychosocial approach to diagnosis and treatment. The need for an early diagnosis and relapse prevention strategy is essential in the management of comorbid bipolar disorders. The presence of multiple chronic conditions raises the crucial issue of long-term recovery and health restoration, which is often inadequately considered in acute care models. Furthermore, comorbid conditions, such as substance abuse and bipolar disorder may have been intertwined over the course of decades (e.g. both disorders staring in young adolescence), therefore disentangling one condition from the other is very difficult. Thus, an integrated model of care, where all presenting problems are addressed in the same setting and by the same treatment provider, have been found to most likely to be successful in attending to the multiple needs of this population. While treating co-occurring anxiety disorders in bipolar disorder have availed of the same setting and provider, as these conditions have been within the preview of traditional psychiatric care, this has not always been the case for the treatment of substance use disorders. When cooccurring disorders also include a substance use disorder,
Management of Comorbidity
then careful attention should be placed on ensuring that adequate attention is also given to the substance use disorder. These patients have been at risk of receiving inadequate substance use treatment when they present to traditional psychiatric settings and inadequate mental health care when they present to addiction treatment settings. While awareness for providing adequate care for both disorders have increased recently, the problem of disjoined treatment and falling through the cracks is still noticeably present in many settings. The provision of integrated care is greatly facilitated when integration efforts occur at multiple levels, from programme financing and treatment access to clinician training to ensure adequate competencies in addressing the multiple health disorders and need at hand, to employing empirically proven effective interventions for comorbid disorders. Another key consideration in the treatment of complex conditions that present with multiple challenges is how to optimize access to the treatment setting and milieu. For example, as there are no confirmatory tests for the diagnosis of bipolar disorder in the context of substance use, longitudinal followups become of crucial importance, not only for the immediate management of the presenting distress, but also for further clarifying the diagnostic picture. It is in our common experience that even when doubting the diagnosis of bipolar disorders comorbid with substance abuse (e.g. in recurrent depression with decrease free interval), if a mood stabilizer is added to the therapy, the pattern of abuse significantly decreases along with the severity of the depressive episodes. Thus, settings and milieus orientated towards enhancing treatment access and treatment adherence, and sustained follow-up are more likely to have a positive impact in the management of these conditions.
Diagnostic considerations Accurate diagnostic formulation represents the first step in the management of these patients. A key issue in the management process is the establishment of the diagnosis of bipolar disorder. Diagnosing bipolar disorder is challenging even without the presence of additional psychopathology. It is estimated that from symptom onset, there is a 10-year lag period to correctly identifying bipolar illness [22]. This may be particularly relevant for the so-called soft-bipolar patients who do not present with the classical mania or hypomania-depression cycle but, rather, long periods of hyperactivity, dysphoria, stress and irritable mood followed by melancholic depressive symptoms comorbid with anxiety disorders and most often with substance abuse. The presence of additional psychopathology further obscures the diagnostic picture. This is especially true with cooccurring substance use disorders [19]. The presence of substance use disorders can significantly interfere with the diagnosis of bipolar disorder by producing symptoms that
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mimic, overlap or obscure the manifestation of bipolar disorder. Substance induced symptoms may also exacerbate the manifestation of bipolar disorder. In the absence of specific diagnostic tests confirmatory of the diagnosis of bipolar disorder, clinical history, anamnesis and ultimately, longitudinal follow-up form the basis for the confirmation of diagnoses. Several questions may be helpful in attempting to untangle the diagnostic picture, such as the following: 1 Are the symptoms present during a state of acute intoxication or withdrawal? It is generally agreed that symptoms occurring during either intoxication or withdrawal are secondary to the involved substance, and the type and expected duration of symptoms produced are dictated by the specific pharmacodynamic and pharmacokinetic profile of the substance involved. While signs and symptoms of bipolar disorder may also be present during these states, establishing the diagnosis during these states is not advisable, unless such diagnosis has been firmly established in the past. 2 Are the symptoms known to result from either the pharmacological effect of intoxication or from the corresponding withdrawal state? It is also important to note the pharmacological properties of the substance involved. For example, intoxication with alcohol or other depressants may produce agitation, irritability and lack of insight along with physical signs of intoxication, such as slurred speech or ataxia. While typical euphoric mania is not expected to be seen during depressant intoxication, symptoms of agitation, lack of insight, irritability and jovial mood seen during an intoxication state may pose a diagnostic challenge. Euphoric mania, on the other hand, is even less expected to be seen during withdrawal from chronic alcohol and other depressants. On the other hand, exacerbation of depressive symptoms and suicidal behaviour, while not pathognomonic of specific psychopathology, are likely to occur in severe alcoholism with associated psychopathology. Depressant withdrawal is also well-known to produce significant anxiety, which may overlap and exacerbate a primary anxiety disorder co-occurring with bipolar disorder. 3 Do the symptoms persist beyond the pharmacokinetic effect of the substance involved with a sufficient level of severity to require treatment? Stimulant intoxication, such as with cocaine, is known to produce a hyperactive, manic and psychotic state, which is expected to last up to 72 hours after cessation of use. Significant symptoms lasting beyond the expected resolution of cocaine- or other substanceinduced symptoms likely requires treatment. While some diagnostic guidelines suggest that symptoms need to persist for a period of 30 days drug-free to consider a primary psychiatric disorder in the context of substance use [23], these guidelines do not take into account the disparate pharmacologic properties of the substances involved, from those with a very short half-life, such as cocaine, to those
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with relatively longer half-life, such as amphetamines or certain depressants. Several studies of alcoholism with comorbid major depression have demonstrated that depressive symptoms of major depressive disorder improve minimally subsequent to the first week or 10 days of cessation of alcohol used [24]. Furthermore, these guidelines are of limited clinical utility in regular clinical practice, where clinicians are pressured to make treatment decisions in a very limited time frame. 4 Is worsening of symptoms disproportional to the amount of the substance used; and is the onset of symptoms not expected to be a known effect of the abused substance? The development of severe and drastic worsening of psychiatric symptoms in the context of a stable pattern of substance abuse, or the onset of symptoms that are not expected to be a known effect of the abused substance, may point towards the presence of primary psychopathology. 5 Is there a past history suggestive of bipolar disorder? Most helpful would be a documented past history of a manic episode during a clear period of protracted abstinence (i.e. three to six months). Other helpful historical information includes early age of onset (i.e. adolescence) of severe depressive disorder, and a family history of bipolar disorder in first degree relatives. The high rate of bipolar disorder subtypes known to lead to misdiagnosis, such as mixed states and rapid cycling, in bipolar disorder with comorbid substance abuse further complicates the diagnostic picture. Chronic continuous cocaine use with unremitting periods of alternating intoxication and withdrawal may overlap with manic symptoms or with rapid cycling or ultra-rapid cycling subtypes.
administer. For example, screening tools for SUDs have been found useful in psychiatric settings such as the Alcohol Use Disorders Identification Test [25] and the Drug Abuse Screening Test [26]. Screening for bipolar disorder in patients with SUDs is an area that needs further development. Broad screening for manic and depressive symptoms may be obtained using the Mood Disorder Questionnaire [27]. High sensitivity and moderate specificity for mood disorders in patients with substance abuse has been reported for the Symptom Checklist (SCL-90) [28]. The use of mania rating scales, such as the Young Mania Rating Scale [29] or the Bech-Rafaelsen Mania Scale [30], may also be helpful. Structured diagnostic interviews may provide a useful model in terms of comprehensiveness to evaluate not only for bipolar disorder, but also for all co-occurring psychopathology. Unfortunately, these instruments are time-intensive for regular clinical practice and their acceptability for use amongst clinicians is limited. The Psychiatric Research Interview for Substance and Mental Disorders for DSM-IV (PRISM) [31] was specifically developed to formulate psychiatric diagnosis within the context of substance use. Screening modules of some structured interviews may be useful to screen for most common psychopathologies [32]. Experiences with comprehensive diagnostic interview for clinical care, such as the Initial Evaluation Form [33], represents important alternatives that could be further refined in clinical settings. This assessment procedure contains both a standardized and narrative component, thus allowing for a comprehensive standard assessment of psychopathology, along with a flexible narrative to accommodate regular clinical care.
The role of systematic screening
General treatment considerations
The reality of clinical care in many settings is characterized by limitations in resources and significant time pressure, which then influence the clinical encounter to be primarily focused on the presenting distress. The risk of not considering associated conditions is that key elements that may impact on the presenting problem are left unaddressed. A common example of this is the failure to identify substance use disorders in patients with severe psychopathology (such as in individuals affected with bipolar disorder or schizophrenia). This failure is then reflected in poor response to treatment caused by a variety of reasons mostly related to the presence of undiagnosed substance abuse. These may range from lack of medication compliance to developing adverse effects because of substance usemedication interaction, to developing social complications related to substance abuse that interferes with the treatment of the primary psychiatric disorder. Thus the use of systematic screening is crucial in the care for these patients, as early diagnosis and treatment predict treatment outcome. There are a number of screening tools that are brief to
As mentioned earlier, an integrated treatment model, as opposed to either a sequential or a parallel care model, is the preferred approach, as both the bipolar disorder and the substance use disorders require maintenance treatment with emphasis on continuity of care, relapse prevention, recovery and health restoration. This would also call for active involvement of the patient, their families/support system and community support including participation in self-help groups, especially those focusing on Dual Diagnosis. Since for both disorders relapses occur even during periods of apparent stability, it is recommended to plan for an ongoing maintenance treatment programme to allow the monitoring of these patients on a regular basis. Furthermore, multiple demographic and clinical-biological factors may also affect the patterns of comorbidity and diagnostic cluster (i.e. anxiety and/or substance use disorders in bipolar patients) and possible response to treatment. For example, males are more likely to display comorbidity of bipolar disorder with alcoholism and/or cocaine addiction. Genotype may also play a role. The
Management of Comorbidity
presence of certain allele haplotypes has shown to confer resistance or responsiveness to some treatments versus others, irrespective of compliance or drug blood levels [34]. Age may also affect the type of drug abused (e.g. designer drugs in early adolescence vs. alcohol in later life.) However, useful treatment algorithms that take into account the individual patients characteristics are still lacking. Effective treatment interventions for comorbid disorders have lagged behind because of the difficulty in conducting trials in this population and because comorbid conditions have traditionally been excluded from clinical trials. Thus few pharmacologic agents have been tested in this population. Similarly, psychosocial interventions targeting this population are also still limited. General treatment-related challenges are particularly salient in the treatment of these complex conditions, especially when substance use comorbidity is present. Attitudinal difficulties in dealing with substance use disorders and psychiatric disorders in general still persist and issues related to stigmatization could manifest at multiple levels involving the health care provider, the family and the patient. Medications and treatment sometimes are unnecessarily withheld or delayed with the rationale that one problem should be cleared before the other condition can be treated, or that the patient is not ready to be treated or that medications are unsafe in the context of substance abuse. Families and patients may be resistant to treatment with medication. Some self-help groups may discourage the use of any medication labelled as mind altering. Furthermore, patients may deny or avoid seeking care for their mental illness, fearing stigmatization. Double stigmatization for having both a substance use disorder and a major psychiatric condition may be encountered. Many patients had confided that they would rather confront the stigma of being a drug addict than the stigma connected with major mental disorder, and they recall this fear as one reason for delaying seeking care. This tendency is sometimes increased by care providers themselves who believe that the disease model objectively implies an acute and partial control of symptoms (e.g. intoxication; medical comorbidities) rather than a continuous integrated approach dealing with a chronic, highly relapsing brain disorder. Poor treatment adherence is another significant challenge in the management of these conditions. Insight into illness and consequent treatment-seeking behaviour and treatment adherence are impaired, especially during the manic state of bipolar disorder. The co-occurrence of substance abuse significantly worsens treatment adherence, which is a key contributing factor to the reported worsening response to treatment and high hospitalization rates for these patients. Studies have clearly reported that patients with residual affective symptoms are significantly more likely to relapse to an affective episode than those with full symptomatic recovery [35]. These findings highlight the
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importance of proper diagnosis of even mild affective disturbances and of optimizing treatment to achieve full symptomatic recovery. Comorbidities in bipolar disorder, for a variety of reasons, interfere with achievement of full recovery. Anxiety symptoms may persist even when aggressively addressed. In addition, the use of serotonin reuptake inhibitors (SSRIs) and other antidepressants to treat anxiety disorders carries the risk of inducing mixed states, rapid mood cycles, hypomania and full blown switch into mania. On the other hand, the widespread use of benzodiazepines carries the risk of dependence and addiction, especially in those with co-occurring substance use disorders, and we have observed worsening of depressive symptoms in dualdiagnosis patients when under chronic (i.e. >6 months) treatment with benzodiazepines. While there are no clear indications that a history of substance abuse alters medication response in bipolar disorder, achieving full symptomatic remission in the context of active heavy drugs or alcohol use is unlikely. Hence, optimizing treatment of bipolar disorder involves optimizing treatment of associated morbidities as well.
Treatment phases Treatment for bipolar disorder and associated comorbidities may be conceptualized in two broad interwoven phases: (1) an acute stabilization phase to address the acute episode or the need for acute treatment of the comorbid disorder (e.g. need for medically supervised detoxification); (2) an ongoing maintenance phase to consolidate recovery, prevent relapse and maximize health restoration and functioning. Acute stabilization often involves stabilization of the acute bipolar state and that of the comorbid condition. The level of intervention intensity and restrictiveness is expected to be proportional to symptom acuity in the stabilization of acute psychopathology and the presence of significant cooccurring substance use disorder imposes an additional level of complexity. Patients with bipolar disorder with comorbid alcoholism and other SUDs presenting for emergency care have significantly higher levels of symptoms compared to those without SUDs [36], and females with the bipolar- SUD comorbidity present with significantly more depressive symptoms [37]. Management of drug withdrawal syndromes during acute stabilization occurs within the context of acute presentation of bipolar disorder, which may range from an acute manic or psychotic state, to disabling depression and imminent suicidal risk, all of which require immediate, high intensity services. Detoxification from alcohol remains the most frequent withdrawal syndrome in need for medical management in this population. Opioid withdrawal syndrome is the second-most likely syndrome that needs medication treatment. While medications to treat stimulant withdrawal, such as cocaine withdrawal, have
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not been firmly established, behavioural treatment, such as protection from suicidal risk may be necessary for some patients, given the high rate of reported suicidal symptoms during cocaine withdrawal [38]. The available reports on the optimal management of psychoactive substance withdrawal in bipolar disorder or other severe psychopathology are limited. The use of objective rating scales and the loading-dose method appear to be useful in the treatment of alcohol withdrawal in the context of severe psychopathology [39]. A symptom-triggered approach guided by the use of rating-scales, such as the use of the Clinical Institute Withdrawal Assessment-revised (CIWA-r) [40] provides a comprehensive assessment of the withdrawal syndrome. Measurement of vital signs (pulse, blood pressure and temperature), routinely used in regular clinical practice to monitor withdrawal syndrome, have been found to be inconsistent. While some items on the CIWA-r, such as anxiety, may overlap with psychiatric symptoms, the advantage of applying a systematic procedure that provides a comprehensive assessment of the withdrawal syndrome, especially when this assessment is integrated with all available information to guide clinical judgement, decreases the likelihood of undertreating the withdrawal syndrome, thus preventing the development of withdrawal complications. The use of assessment scales to guide treatment has been found to reduce the likelihood of either under-, as well as over-use of medication when compared to the standard medical detoxification methods [41]. Furthermore, the use of long-acting medications, such as the benzodiazepine diazepam-loading dose method, takes advantage of the self-tapering properties of these medications, thus minimizing repeated dosing and marked fluctuation in blood levels associated with medications that have shorter acting half-life. This procedure was found effective, with minimum complications in a sample of 125 acutely ill hospitalized patients with severe mood, anxiety and related disorders [39]. Treatment of the opioid withdrawal syndrome can also avail of the use of assessment scales, such as the widely used Short Opiate Withdrawal Scale (SOWS) [42]. With the introduction of buprenorphine, the SOWS also could be used to guide induction of maintenance treatment. While buprenorphine is very effective for the treatment of the opioid withdrawal syndrome, the focus on maintenance treatment also highlights a primary management issue in the treatment of the withdrawal syndrome in these patients. One of the key goals of the treatment of the drug withdrawal syndromes, in addition to preventing complications and alleviating the symptoms and distress of withdrawal, is to introduce the patient to the long-term goal of initiating and maintaining sobriety. The detoxification period has been viewed as a window of opportunity for some patients who become more receptive to addressing their substance use problem during this time. Thus, as for the treatment of
bipolar disorder, where medications are usually initiated to stabilize an acute episode, then continued through maintenance treatment, for those who may benefit from pharmacological treatment for the addictive disorder, appropriate medications should be initiated during this phase. The buprenorphine/naloxone combination is an important medication to consider for maintenance opioid addiction treatment in bipolar disorder for appropriate cases. Thus far, there has been very limited reported experience using this medication in severe psychopathology. Likewise, medications used in alcoholism, such as naltrexone hydrochloride or acamprosate may be better initiated during this period as well. As medication adherence has been shown to predict better short and long outcome, it is crucial that patients and family be educated on recognizing warning signs and return of symptoms. They should also be advised on the importance of maintaining regular visits with their health care provider and on the need to optimize treatment of residual symptoms. Patients are often tempted to discontinue their medications upon alleviation of presenting symptoms. This highlights the importance of an open dialogue with the patient and family/supporting others on the risks, benefits and alternatives of treatment and medication maintenance. While many patients may eventually quit taking their medications, the presence of a strong therapeutic alliance and availability of open dialogue facilitates reengagement and treatment resumption. Maintenance of ongoing treatment of comorbidity in bipolar disorder, while becoming of increasing interest given its frequency and impact, is still an area of substantial unmet needs. Of the two major psychiatric comorbidities in bipolar disorder considered in this chapter, interestingly there have been more trials targeting the comorbid bipolar disorder with associated substance use disorders than those specifically addressing bipolar disorder with comorbid anxiety disorders. Anxiety disorders have been examined as part of secondary outcomes in the treatment of bipolar disorder. Our recent Medline and other electronic database searches completed for this chapter could not identify a single clinical trial specifically focusing on the anxiety disorders co-occurring with bipolar disorder. The negative impact of anxiety disorders on treatment response in bipolar disorder, and more pressingly, the findings of increased association of suicidal behaviour risk with comorbid anxiety, highlights the need for developing effective antianxiety treatment in bipolar disorder.
Treatment guidance for comorbid anxiety disorders The lack of specific guidelines for the treatment of comorbid anxiety disorders, despite its high frequency and impact on bipolar disorder, is noteworthy. For example, the American Psychiatric Association Guidelines for the treatment of
Management of Comorbidity
bipolar disorder include few generic paragraphs on the management of comorbidity in bipolar disorder [43]. The presence of an additional anxiety disorder is generally associated with increased severity, less responsive to treatment and most concerning with increased risk of suicidal behaviour. Guidelines for the treatment of anxiety disorders amongst bipolar disorder is not different from that of addressing the anxiety disorders in the non-comorbid population, with the caveat and cautions of using an SSRI or other antidepressants in the context of bipolar disorder. As mentioned earlier, comorbid anxiety disorders present a unique challenge in the bipolar patient. Most individuals suffering with bipolar disorder (BD) have high rates of comorbid anxiety disorders that require careful evaluation and rationally guided therapeutic choices [44]. Global personal functioning decreases as a consequence of the anxiety, which contributes to produce a significant extent of social impairment both for BD II and BD I patients [45]. Since only a scarce minority of BD II outpatients receives appropriate (i.e. lithium, valproic acid salts, anticonvulsants, or antipsychotics) medication for their primary condition [45] is very unlikely that their comorbid conditions are also assessed and properly treated. Instead, specific treatment(s) for the anxiety accompanying (and sometime anticipating) BD must be addressed carefully, considering that even amongst the geriatric BD population up to 20% of subjects could present anxiety symptoms and signs [46,47]. It is also not uncommon that patients may present with an anxiety related disorder (e.g. panic attack) in late adolescence and then develop full-blown bipolar disorder 10 years later. The serotonergic antidepressants, which represent an effective, often first-line treatment modality for anxiety disorders, can be associated with unfavourable outcomes in bipolar disorder. Antidepressants may trigger manic episodes or increase the likelihood of cycling between episodes [3,48]. A further complicating factor is the dearth of available information regarding treatment guidelines for the bipolar patient with comorbid anxiety [43]. Alternative agents have been used to treat anxiety disorders in the bipolar patient, which are occasionally used as second line for the treatment of non-comorbid anxiety disorders include gabapentin (social phobia, panic), olanzapine and quetiapine (panic, OCD, nonspecific symptoms, PTSD) [3]. In a recent 12-week single-blind observation trial, the addition of either olanzapine or lamotrigine to lithium therapy in 47 BD patients in remission with concurrent anxiety disorder was shown effective in decreasing anxiety [49]. On the other hand, in an 8-week randomized clinical trial, risperidone monotherapy did not differ from placebo in improving anxiety symptoms in patients with BD and comorbid panic disorder or GAD [50]. Contrasting results were obtained with Quetiapine: in the first BOLDER study, HAM-A scores did not improve but one subsequent pooled analysis of BOLDER I and II data showed that
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quetiapine 600 mg/day was effective in reducing HAM-A [51] and it has now been recommended as firstline monotherapy therapy in BD [44]. Due to the complications of pharmacologic treatment of the comorbid patient, the role of psychotherapy should be examined. Unfortunately, there is no data available regarding psychotherapy treatment modalities in patients with bipolar and anxiety disorders; however cognitive behavioural therapy (CBT) has proven to be a useful treatment modality in the individual disorders [3]. Finally, a very preliminary study in 14 BD patients in remission found that mindfulness-based cognitive therapy might have a fast effect on the residual anxiety between episodes [52]. From the above limited information, it is difficult to design clear treatment guidelines for anxiety in bipolar disorder, although the few studies are encouraging in terms of pointing towards carrying out systematic assessment of already available medications and their effect on comorbid anxiety. There continues to be a paucity of information regarding the effectiveness of anxiety treatments for prevention of suicide attempts in the bipolar patient, and if treatment of anxiety symptoms can ameliorate severity of bipolar symptoms. The increased suicide risk in these patients calls for careful consideration of the pharmacologic treatment. Lithium has been found to decrease suicidal behaviour in bipolar disorder when taken as maintenance treatment [12,53–55]. While, as stated earlier, anxious patients may be more resistant to treatment with lithium [53], lithium augmentation with olanzapine or lamotrigine was found helpful. Evaluation of other lithium augmentation strategies may be useful as well.
Treatment of comorbid substance use disorders While this is still an area of unmet treatment needs, more attention has been paid to the treatment of this comorbid condition. Both efforts at developing psychotherapeutic, as well as pharmacotherapies that specifically address comorbid bipolar disorder and addiction, have been published.
Psychotherapy for comorbid substance use disorders Psychotherapy plays an important role in the management of comorbid SUDs in bipolar disorder. Psychotherapy enhances treatment alliance and treatment and medication adherence, crucial elements in preventing relapse. Psychotherapy is also important at developing coping skills and maximizing relapse prevention. It is also important for the recovery and health restoration efforts. While the addiction field presents a rich selection of empirically tested effective therapies, and to a lesser extent, effective therapies are also available for bipolar disorder, specific psychotherapies tailored to comorbid SUD – bipolar disorder are scarce.
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Group counselling Integrated Group Therapy (IGT) has been developed specifically for comorbid bipolar and addictive disorder [56]. In randomized controlled trials, the efficacy of IGT was found superior to standard group drug counselling in significantly decreasing days of substance use during treatment and follow-up [57]. While both the IGT and the standard drug counselling addressed the substance use, the IGT also addressed the bipolar disorder. Thus it appears that counselling for bipolar disorder, in addition to counselling for SUDs, is required in order to improve substance use outcome in this population.
Individual counselling Early Recovery Adherence Therapy (ERAT) is a newlydeveloped, integrated, manual-guided individual therapy specifically designed for comorbid bipolar disorder and alcoholism and other addictions during the early phases of recovery from an acute episode [58]. ERAT addresses both the bipolar and the addictive disorders by integrating principles and techniques derived from effective psychotherapies for bipolar disorder and for addictive disorders. In a randomized pilot-efficacy study, ERAT had shown significant advantage over 12-step Facilitation Therapy in decreasing alcohol use. Interestingly, the ERAT group also had significantly improved depressive symptoms compared to the other group [59].
Pharmacotherapy A limited number of randomized, double-blind, placebocontrolled trials have been published to date, including two trials for comorbid bipolar disorder and alcoholism, and two pilot studies, including one trial in adolescents [60–63]. A number of open-label trials testing several medications for this population have also been published. The anticonvulsant, mood stabilizer, valproate, to date is the only empirically tested medication that showed advantage over placebo in decreasing alcohol use in patients with comorbid bipolar disorder and alcoholism. Salloum and colleagues (2005) [60], in a 6-month, double-blind, placebocontrolled study of valproate added to treatment- as-usual (dual recovery counselling and lithium Carbonate) in bipolar I disorder and alcohol dependence, found that valproate had an advantage over placebo in decreasing heavy drinking, as well as in relapse to sustained heavy drinking and had significantly longer time to relapse compared to the placebo. They also had significant improvement on decreasing the GGT liver enzyme, an objective measure of alcohol use. The two groups were not different on mood outcomes, although the valproate had a trend to remit from mania earlier.
The efficacy of quetiapine as an add-on was recently tested in a 12-week trial of outpatients with bipolar disorder and alcoholism. Most of the sample was in the depressive phase (82%). Quetiapine did not have an advantage over placebo on alcohol use outcome [62] or an advantage over placebo in improving depressive symptoms. The results of this study are interesting as many studies have reported a correlation between improved alcohol use and improved depression. In this study, the positive effect on depression does not seem to influence alcohol use. Quetiapine did not have an advantage over placebo on alcohol outcome in a larger, multi-site, randomized, double-blind and placebocontrolled study [64]. Citicoline was reported to decrease cocaine positive urine in bipolar disorder with cocaine dependence. Citicoline was tested in a 12-week, randomized, placebo-controlled, add-on, proof-of-concept trial in 44 outpatients with a history of mania or hypomania and cocaine dependence. The citicoline group had significant improvement on some aspects of declarative memory and cocaine use. However, the two groups were similar on mood symptoms [63]. Lithium carbonate had an advantage over placebo on positive urine drug screen (mostly marijuana), and improved scores on the global clinical impression in a 6-week double blind placebo controlled pilot study of adolescents with bipolar I or bipolar II disorders [61]. In secondary analyses of a randomized controlled trial, valproate was found to have an advantage over placebo in decreasing cocaine use in subjects with bipolar disorder and alcoholism [65]. Carbamazepine was found to have a trend towards an advantage over placebo on cocaine positive urine in a subgroup of patients who had a history of affective disorder, including bipolar disorder [66]. There are several published open-label pilot studies of a variety of psychotropic medications, such as the atypical antipsychotic medications quetiapine [67], the anticonvulsants divalproex [65,68–70] and lamotrigine [71], and the opioid antagonist approved for alcoholism, naltrexone [72,73]. While results from pilot studies may point to potential promising directions, they are also subject to multiple biases.
The role of medications for substance use disorders Over the past decade there has been a concerted effort at developing and testing pharmacotherapy for addictive disorders. While the usefulness of these compounds has not been tested in bipolar disorder, there are no indications that they are less effective for their indication in this population. These medications have been underutilized in general practice and also in psychiatric population. Currently, there are three approved medications by the US Food and Drug Administration (FDA) for the treatment
Management of Comorbidity
of alcoholism. These are disulfiram, naltrexone hydrochloride, oral and monthly intramuscular formulation and acamprosate. Topiramate, an anticonvulsant not FDA approved for alcoholism, has been found to decrease alcohol use in two well conducted clinical trials [74,75]. While each of these medications has a specific pharmacologic profile that must be tailored to the individual patients health status, they offer a distinct benefit for alleviating alcoholism in bipolar disorder. For example, while disulfiram has an extensive side effect profile, it requires reliable adherence to dietary restrictions, and its use has been discouraged in psychoses because of its inhibition of dopamine beta-hydroxylase. Select patients find its deterrent property very helpful. Naltrexone hydrochloride and acamprosate, on the other hand, have a benign side-effect profile and may be used in a broader spectrum of clinical situations. The long-acting preparation of naltrexone offers the added advantage of enhancing medication adherence. Medications are also available for other addictive disorders, namely nicotine and opioid addictions. Given the exceedingly high rate of nicotine addiction in bipolar disorder, addressing this significant health risk is imperative. A number of treatment options are available, including the different formulations of nicotine replacement therapies (NRT), other pharmacotherapies such as bupropion hydrochloride and the newly introduced selective nicotinic receptors partial agonist compound varenicline and other promising medications [76]. Opioid substitution pharmacotherapy and naltrexone hydrochloride have been available for a long time to treat addiction to opiates; although treatment availability has been limited to specialized addiction treatment settings. The recent introduction of buprenorphine/naloxone for opioid maintenance treatment in office-based settings presents a distinct advantage in opening access to this effective treatment to a broader population, including those with severe psychopathology [77].
Treatment guidance Although there is still a need to develop empirically based pharmacotherapy and psychotherapy for these complex conditions, certain treatment principles have been applied into practice to enhance the care for these conditions. Thus, while there is no substitute to clinical judgement generated by the clinician-patient relationship, the following guidelines should be viewed as general guidance rather than a rigid treatment algorithm. In the management of bipolar disorder with comorbid substance use disorders, and in addition to general treatment principles, such as those found in treatment guidelines for bipolar disorder [44], the following points, based on earlier discussions in this chapter, are found to be helpful in the treatment of this population:
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Issues related to mental health professionals training Ensure mental health professional staffs are knowledgeable, experienced and fully comfortable in caring for patients with comorbid severe psychiatric disorders and severe substance used disorders. A major road block for the optimal care for these patients is the lack of adequate training, mostly resulting from systems issues that have required a separation of services for these two major psychiatric disorders. This may be a more insidious problem than it may appear, especially in certain settings. Not all those who talk recovery are fully trained to handle severe psychopathology. Conversely, stigma and attitudinal issues fuelled by lack of knowledge and comfort may still be found amongst some mental health professionals with limited experience in the treatment of substance use disorders.
Issues related to expectations and attitudes This is another general management principle that is crucial for establishing solid foundations for therapeutic alliance and agreed upon treatment plan. Patients may deny or minimize their substance use and mood disorders or they may have misconceptions regarding the effect of substance use on their psychiatric problems or have very different expectations of treatment or of the expected effect of medications. This misconception may also need to be addressed in the family and in self-help groups, especially as they relate to the use of mood altering drugs. Attitudinal issues may also involve health care providers, such as physicians who may be reluctant to prescribe psychotropic medications in the context of active substance abuse or fear of being manipulated by the patient.
Issues related to the setting The setting fosters an integrated approach in addressing both disorders as reflected in personnel training and expertise, programming and milieu. Emphasize a balanced approach on both medications and psychotherapy. Ensuring easy access and flexibility of the clinical programming, along with, when feasible, including a self-help programme (e.g. dual diagnosis or double trouble groups) are features that have been found helpful in the management of this population.
Issues related to medication management In addition to addressing the diagnostic accuracy as discussed earlier, medication for these patients should include medications with low abuse potential, as vulnerability to develop additional addictions is quite high in this population. Furthermore, to the extent possible, medications with
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low lethality on overdose are preferred when available. Furthermore, dispensing limited amounts of medications, at least during the early phases of treatment and maintaining frequent contact provide the benefit for enhanced therapeutic alliance, and a for more cautious monitoring of the clinical situation and potential problems with the medications. Routine random urine or plasma toxicology screens are recommended and are usually well accepted and in many instances appreciated by the patients as part of their treatment plan. Patient education about the medication effects, side effects and expected response is crucial, including discussing the patients attitude, thoughts and feelings regarding medication. Assuming that the use of substances may make psychotropic medication more acceptable to patients could not be more erroneous. Our experiences taught us that patients with substance use disorders are certainly no different from patients without substance use disorders and often times have very different understandings and expectations of the effect of psychotropic medications,. Thus an open and candid discussion is crucial and may significantly impact on treatment adherence.
Issues related to counselling and psychotherapy Psychotherapy is highly relevant for this complex population to address crucial issues such as dual recovery, and to motivate patients and enhance treatment and medication adherence. While there is a long tradition and availability of rich choices of empirically proven effective therapies for addictive disorders, and to lesser extent for bipolar disorder, the few studies available indicate that this population requires therapies that address both the addiction and the bipolar disorder to have maximum benefit. An interesting finding of available psychotherapy trials for this population is that these patients report significant improvement in their drug use more so when exposed to integrated psychotherapies that address both disorders than when exposed to therapies designed to address substance use without bipolar disorder.
Issues related to specific medications a. Medication used for bipolar disorder that may help with substance abuse: While there are no large multisite studies supporting the use of any particular medication, the available evidence suggests usefulness of the anticonvulsants (especially valproate) for bipolar disorder with alcoholism and possibly with cocaine use disorders as well. While it is unclear what the ideal dose of valproate for alcoholism is, a decrease in alcohol use was found to inversely correlate with valproate blood levels, which was maintained within the recognized range of therapeutic response for bipolar disorder (50–100 mg/mL) [78]. The role of atypical antipsychotics is still unclear.
Two larger studies (one single suite and one multisite) failed to find an advantage of quetiapine over placebo. Other anticonvulsant mood stabilizers (i.e. lamotrigine, carbamazepine and oxcarbazepine) may also have some utility. The same precautions and prescribing information used in general should be implemented when prescribing valproate for bipolar with alcoholism or other substance use disorders. Valproate has been associated with a mild transient elevation of transaminase. Valproate has also been associated with rare hepatotoxic effects, which resulted in fatalities in young children treated for seizure disorders. Because of the potential effect of valproate on the liver, liver function tests must be measured prior to initiating valproate and any active liver disease should be ruled out prior to initiating valproate. A consultation with hepatologist is recommended in certain cases. Although there are no clear guidelines on how frequently liver function tests should be monitored after initiating valproate, routine monitoring within the first six months and yearly thereafter would be helpful. Hepatotoxic reactions to valproate have been described as idiosyncratic, therefore are difficult to predict. A sudden increase in liver function tests and physical signs and symptoms of liver pathology should be closely monitored. b. The use of medications for alcoholism in bipolar disorder: Four medications are approved for the treatment of alcoholism in the United States; these are disulfiram, naltrexone hydrochloride (oral), naltrexone extended release intramuscular injection (Vivetral) and acamprosate. There are no clear guidelines as to when, and what treatment sequence should be followed when deciding to use any of these medications. For example, it is not clear whether these medications should be used only after adequate pharmacotherapy for bipolar disorder have failed to also reduce alcohol use, or medications for alcoholism should be initiated when alcoholism is identified in these patients. This later modality of treatment would be similar if hypertension is identified in these patients, then an antihypertensive medication would be added to the existing treatment regimen. Naltrexone hydrochloride is a pure opiate antagonist that decreases alcohol use and relapse by its effect on the endogenous opiate system and by decreasing the positive reinforcing effects of alcohol ingestion. Oral naltrexone (50 mg/day dose) has been examined by two pilot studies, an add-on study [72] and an open-label randomized assignment study [73] with encouraging findings in both studies. Naltrexone is a safe and effective medication for alcoholism. Naltrexone has been reported to increase liver transaminase at higher dosages. Therefore, liver enzymes should be measured prior to initiating naltrexone and monitored during treatment. Multiple studies conducted with naltrexone (oral and intramuscular, sustained release form) have been found safe in alcohol and opioid dependence in terms
Management of Comorbidity
of liver toxicity. It is crucial to ensure that patients are not dependent on opioid as naltrexone will precipitate a prolonged, and potentially severe opioid withdrawal syndrome. It is also important to advise patients about naltrexones blocking the effect on opioid analgesia. Nausea and anxiety may be an initial, limiting, side effects in few cases. Usual naltrexone dose has been of 50 mg per day. To minimize the chance of developing side effects, naltrexone is usually initiated after two to three days of sobriety and some may start with 25 mg dose for the first few days and increase to 100 mg. To date there have no studies using the intramuscular, sustained release formulation, thus it is unclear how well it will be tolerated in this population. The sustained release formulation has been well tolerated in alcohol dependence without comorbid bipolar disorder and it offers an advantage in terms of medication adherence, as it is a monthly injection. Acamprosate presumably acts by alleviating the negative reinforcing effects of alcohol withdrawal, and is a well tolerated medication with limited adverse effects profile such as itching and soft stools. This medication does not interact with alcohol and is not metabolized by the liver, but excreted through the kidney. While two studies conducted in the United States on alcohol dependence without comorbid bipolar disorder failedto find an advantage of acamprosateover placebo, studies conducted in Europe have reported significant advantage of acamprosate over placebo. Disulfiram is one of the oldest medications in psychiatry available since 1951. Disulfiram is an aversive agent that acts by irreversibly inhibiting aldehyde dehydrogenase leading to the accumulation of the alcohol metabolite acetaldehyde, which causes the Disulfiram-Ethanol reaction. Disulfiram was found useful in non-comorbid alcohol dependent patients when administered under supervised conditions or in certain subgroups. Disulfiram has an extensive side-effect profile, including liver toxicity and neuropathy and is reported to precipitate psychopathology including psychosis or depression. Therefore its use has been contraindicated in severely ill psychiatric patients. Current dose range is between 125 and 250 mg/day. Given new findings of disulfirams effectiveness in cocaine dependence [79], it is unclear whether this medication may have a role in the treatment of the severely ill psychiatric population. c. Medications interactions: While this is a vast field, it is important to keep in mind that bipolar disorder patients with comorbid addictive disorders may be exposed to multiple medications as well as multiple psychoactive substances of abuse and that potential interactions are very high. It is important to keep in mind the general rules of interaction between the major medications that may be used for this population [80]. Medication-medication, or medication-drug interaction may occur at multiple levels (i.e. pharmacokinetics and pharmacodynamic) and the effect may be synergistic, antagonistic or additive. For example, the barbiturate-alcohol interaction on the central nervous
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system is thought of as synergistic. This kind of interaction used to lead to frequent lethal overdosing, when the use of barbiturates was very common. Alcohol-benzodiazepine is thought to be an additive interaction and again it could be lethal on severe overdoses. Pharmacokinetic interactions, such as hepatic enzyme induction or inhibition, can also be significant. For example, while acute alcohol intoxication may cause impaired liver functions and lead to increased blood levels of the medications, chronic alcohol use may lead to hepatic enzyme induction and acceleration of medication metabolism, resulting in lower blood and therapeutic levels of these medication. Other medication can cause hepatic enzyme induction such as barbiturates, non-barbiturate hypnotics, carbamazepine and phenytoin amongst others. Hepatic enzyme inhibition, on the other hand, could be caused by medications such as disulfiram, alcohol intoxication, valproate, serotonin reuptake inhibitors (SSRIs), methadone and naltrexone.
Conclusion Substance abuse and anxiety disorders are the most common comorbidities in bipolar disorder and may have significant impact on its course and treatment. Other psychiatric comorbidities not fully addressed in this chapter, such as additional personality disorders, binge eating disorder, hyperactivity attention deficit disorder and impulse control disorders, just to mention some, also impact on bipolar disorder. Another major comorbidity that needs much attention is the co-occurrence of general physical disorders. The course of comorbid conditions intertwines with that of bipolar disorder with reciprocal negative impact. Caring for multiple comorbid conditions with a chronic course is greatly enhanced by adopting an integrated approach to care and follow-up. Specific, empirically tested, effective interventions are scarce. Treatment of comorbid anxiety disorders relies on general guidelines and present significant challenges for clinician. Treatments for substance use disorders are still in early stages of developing effective interventions (psychotherapy and medications) to improve the outcome of both the addictive and the bipolar disorders. Thus, unmet treatment for comorbidities in bipolar disorder still persists.
References 1. Feinstein, A. (1970) The pre-therapeutic classification of comorbidity in chronic disease. J. Chron. Dis., 23, 455–468. 2. Krishnan, K. and R.R.M.B.C. (2005) Psychiatric and medical comorbidities of bipolar disorder. SO – Psychosom. Med., 67 (1), 1–8. 3. El-Mallakh, R.S. and Hollifield, M. (2008) Comorbid anxiety in bipolar disorder alters treatment and prognosis. Psychiat. Quart., 79 (2), 139–150. 4. Simon, N.M. et al. (2004) Anxiety disorder comorbidity in bipolar disorder patients: data from the first 500
364
5.
6. 7.
8.
9.
10.
11.
12.
13.
14.
15.
16.
17. 18.
19.
20.
|
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participants in the systematic treatment enhancement program for bipolar disorder (STEP-BD). Am. J. Psychiatry, 161 (12), 2222–2229. Otto, M.W. et al. (2006) Prospective 12-month course of bipolar disorder in out-patients with and without comorbid anxiety disorders. Brit. J. Psychiat., 189, 20–25. McIntyre, R.S. et al. (2006) Anxiety disorders and bipolar disorder: a review. Bipolar Disord., 8 (6), 665–676. Cosoff, S.J. and Hafner, R.J. (1988) The prevalence of comorbid anxiety in schizophrenia, schizoaffective disorder and bipolar disorder. Aust. Nz. J. Psychiat., 32 (1), 67–72. McElroy, S.L.M.D. et al. (2001) Axis I psychiatric comorbidity and its relationship to historical illness variables in 288 patients with bipolar disorder. Am. J. Psychiatry, 158 (3), 420–426. Feske, U. et al. (2000) Anxiety as a correlate of response to the acute treatment of bipolar I disorder. Am. J. Psychiatry, 157 (6), 956–962. Frank, E. et al. (2002) Clinical significance of lifetime panic spectrum symptoms in the treatment of patients with bipolar I disorder. Arch. Gen. Psychiatry, 59 (10), 905–911. Henry, C. et al. (2004) Anxiety disorders in 318 bipolar patients: prevalence and impact on illness severity and response to mood stabilizer. SO – Year Book of Psychiatr. Appl. Ment Health, 2004, 268–269. Sharma, V. (2003) Atypical antipsychotics and suicide in mood and anxiety disorders. Bipolar Disord. Supplement, (5 Supplement), (2), 48–52. Regier, D.A. et al. (1990) Comorbidity of mental disorders with alcohol and other drug abuse. Results from the Epidemiologic Catchment Area (ECA) Study. JAMA, 264 2511–2518. Kessler, R.C. et al. (1997) Lifetime co-occurrence of DSM-III-R alcohol abuse and dependence with other psychiatric disorders in the National Comorbidity Survey. Arch. of Gen. Psychiatry, 54 (4), 313–321. Grant, B.F. et al. (2004) Prevalence and co-occurrence of substance use disorders and independent mood and anxiety disorders: results from the national epidemiologic survey on alcohol and related conditions. Arch. Gen. Psychiatry, 61 (8), 807–816. Conway, K.P. et al. (2006) Lifetime comorbidity of DSM-IV mood and anxiety disorders and specific drug use disorders: results from the national epidemiologic survey on alcohol and related conditions. J. Clin. Psychiat., 67 (2), 247–257. Lasser, K. et al. (2000) Smoking and mental illness: a population-based prevalence study. JAMA, 284, 2606–2610. Frye, M.A. and Salloum, I.M. (2006) Bipolar disorder and comorbid alcoholism: prevalence rate and treatment considerations. Bipolar Disord., 8 (6), 677–685. Salloum, I., Douaihy, A. and Williams, L. (2008) Diagnostic and Treatment Considerations: Bipolar Patients with Comorbid Substance Use Disorders. Psychiat. Ann., 38 (11), 716. Kupfer, D.J. et al. (2002) Demographic and clinical characteristics of individuals in a bipolar disorder case registry. J. Clin. Psychiat., 63 (2), 120–125.
21. Weiss, R.D. et al. (2005) Does recovery from substance use disorder matter in patients with bipolar disorder? J. Clin. Psychiat., 66 (6), 730–735; quiz 808–809. 22. Hirschfeld, R.M.A. and Vornik, L.A. (2004) Recognition and diagnosis of bipolar disorder. J. Clin. Psychiat., (65 Suppl 15), 5–9. 23. American Psychiatric Association (2000) DSM-IV-TR: Diagnostic and Statistical Manual of Mental Disorders, 4th edn, Text Revision, American Psychiatric Association, Washington, DC. 24. Salloum, I.M. and Jones, Y.O. (2008) Efficacy of pharmacotherapy for comorbid major depression and substance use disorders: A review. Curr. Psychiatr. Rev., 4 (1), 14–27. 25. Allen, J.P. et al. (1997) A Review of Research on the Alcohol Use Disorders Identification Test (AUDIT). Alcohol. Clin. Exp. Res., 21 (4), 613. 26. Cocco, K.M. and Carey, K.B. (1998) Psychometric properties of the drug abuse screening test in psychiatric outpatients. Psychological Assessment, 10 (4), 408–414. 27. Hirschfeld, R.M. et al. (2000) Development and validation of a screening instrument for bipolar spectrum disorder: the Mood Disorder Questionnaire. Am. J. Psychiatry, 157 (11), 1873–1875. 28. Franken, I.H. and Hendriks, V.M. (2001) Screening and diagnosis of anxiety and mood disorders in substance abuse patients. Am J Addict., 10 (1), 30–39. 29. Young, R.C. et al. (1978) A rating scale for mania: reliability, validity, and sensitivity. Br. J. Psychiatry, 133 429–435. 30. Bech, P. et al. (1979) The bech-rafaelsen mania scale and the hamilton depression scale. Acta Psychiatr. Scan., 59, 420–430. 31. Hasin, D.S. et al. (1996) Psychiatric research interview for substance and mental disorders (PRISM): reliability for substance abusers. Am. J. Psychiatry, 153, 1195–1201. 32. Sheehan, D.V. et al. (2002) The Mini-International Neuropsychiatric Interview (M.I.N.I): The development and validation of a structured diagnostic psychiatric interview for DSM-IV and ICD-10. J. Clin. Psychiat., 59 (Suppl 20), 22–33. 33. Mezzich, J.E. et al. (1981) Developing an efficient clinical information system for a comprehensive psychiatric institute: II. Initial evaluation form. Behavior Research Methods & Instrumentation, 13 (4), 464–478. 34. Murphy, G.M. Jr et al. (2004) Effects of the serotonin transporter gene promoter polymorphism on mirtazapine and paroxetine efficacy and adverse events in geriatric major depression. Arch. Gen. Psychiatry, 61 (11), 1163–1169. 35. Judd, L.L. et al. (2008) Residual symptom recovery from major affective episodes in bipolar disorders and rapid episode relapse/recurrence. Arch. Gen. Psychiatry, 65 (4), 386–394. 36. Salloum, I.M. et al. (2002) Impact of concurrent alcohol misuse on symptom presentation of acute mania at initial evaluation. Bipolar Disord., 4 (6), 418–421. 37. Salloum, I.M. et al. (2001) Characterizing female bipolar alcoholic patients presenting for initial evaluation. Addict. Behav., 26 (3), 341–348. 38. Salloum, I.M. et al. (1996) Disproportionate lethality in psychiatric patients with concurrent alcohol and cocaine abuse [see comments]. Am. J. Psychiatry, 153 (7), 953–955.
Management of Comorbidity 39. Salloum, I.M. et al. (1995) The utility of diazepam loading in the treatment of alcohol withdrawal among psychiatric inpatients. Psychopharmacol. Bull., 31 (2), 305–310. 40. Sullivan, J.T. et al. (1989) Assessment of alcohol withdrawal: the revised clinical institute withdrawal assessment for alcohol scale (CIWA-Ar). Brit. J. Addict., 84 (11), 1353–1357. 41. Saitz, R. et al. (1994) Individualized treatment for alcohol withdrawal. A randomized double-blind controlled trial. JAMA, 272 (7), 519–523. 42. Gossop, M. (1990) The development of a Short Opiate Withdrawal Scale (SOWS). Addict. Behav., 15 (5), 487–490. 43. Association, A.P. (2002) Practice Guidelines for the treatment of patients with bipolar disorder (revision). Am. J. Psychiatry, 159, 1–50. 44. Yatham, L.N. et al. (2009) Canadian Network for Mood and Anxiety Treatments (CANMAT) and International Society for Bipolar Disorders (ISBD) collaborative update of CANMAT guidelines for the management of patients with bipolar disorder: update 2009. Bipolar Disord., 11, 225–255. 45. Merikangas, K.R. et al. (2007) Lifetime and 12-month prevalence of bipolar spectrum disorder in the National Comorbidity Survey replication. Arch. Gen. Psychiatry, 64 (5), 543–552, [erratum appears in Arch. Gen. Psychiatry, 2007 Sep.; 64(9), 1039]. 46. Sajatovic, M., Blow, F.C. and Ignacio, R.V. (2006) Psychiatric comorbidity in older adults with bipolar disorder. Int. J. Geriatr. Psych., 21 (6), 582–587. 47. Goldstein, B.I., Herrmann, N. and Shulman, K.I. (2006) Comorbidity in bipolar disorder among the elderly: results from an epidemiological community sample. Am. J. Psychiatry, 163 (2), 319–321. 48. Post, R.M. et al. (1997) Drug-induced switching in bipolar disorder: Epidemiology and therapeutic implications. CNS Drugs, 8 (5), 352–365. 49. Maina, G. et al. (2008) Olanzapine or lamotrigine addition to lithium in remitted bipolar disorder patients with anxiety disorder comorbidity: a randomized, single-blind, pilot study. J. Clin. Psychiat., 69 (4), 609–616. 50. Sheehan, D.V. et al. (2009) Randomized, placebo-controlled trial of risperidone for acute treatment of bipolar anxiety. J. Affect. Disord., 115 (3), 376–385. 51. Suppes, T. et al. (2008) Quetiapine for the treatment of bipolar II depression: analysis of data from two randomized, doubleblind, placebo-controlled studies. World J. Biol. Psychiatr., 9 (3), 198–211. 52. Williams, J.M.G. et al. (2008) Mindfulness-based Cognitive Therapy (MBCT) in bipolar disorder: preliminary evaluation of immediate effects on between-episode functioning. J. Affect. Disord., 107 (1–3), 275–279. 53. Tondo, L., Hennen, J. and Baldessarini, R.J. (2001) Lower suicide risk with long-term lithium treatment in major affective illness: a meta-analysis. [comment]. Acta Psychiatr. Scand., 104 (3), 163–172. 54. Tondo, L., Ghiani, C. and Albert, M. (2001) Pharmacologic interventions in suicide prevention. J. Clin. Psychiat., 62 (Suppl 25), 51–55.
|
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55. Baldessarini, R.J. and Tondo, L. (2001) Long-term lithium for bipolar disorder. Am. J. Psychiatry, 158 (10), 1740. 56. Weiss, R.D. (2004) Treating patients with bipolar disorder and substance dependence: lessons learned. J. Subst. Abuse. Treat, 27 (4), 307–312. 57. Weiss, R.D. et al. (2007) A randomized trial of integrated group therapy versus group drug counseling for patients with bipolar disorder and substance dependence. Am. J. Psychiatry, 164 (1), 100–107. 58. Salloum, I.M. et al. (2006) Early Recovery Adherence Therapy (ERAT) for Bipolar Alcoholics: An integrated individual counseling approach to enhance treatment adherence. Alcohol. Clin. Exp. Res., 30 (6s1), 161. 59. Salloum, I.M. et al. (2008) Integrating pharmacotherapy and a novel individual counseling for alcoholism with bipolar disorder. Alcohol. Clin. Exp. Res., 32 (6s1), 260A. 60. Salloum, I.M. et al. (2005) Efficacy of valproate maintenance in patients with bipolar disorder and alcoholism: a doubleblind placebo-controlled study. Arch. Gen. Psychiatry, 62 (1), 37–45. 61. Geller, B. et al. (1998) Double-blind and placebo-controlled study of lithium for adolescent bipolar disorders with secondary substance dependency [see comments]. J. Am. Acad. Child Psy., 37 (2), 171–178. 62. Brown, E.S., Garza, M. and Carmody, T.J. (2008) A randomized, double-blind, placebo-controlled add-on trial of quetiapine in outpatients with bipolar disorder and alcohol use disorders. J. Clin. Psychiatry, 69 (5), 701–705. 63. Brown, E.S., Gorman, A.R. and Hynan, L.S. (2007) A randomized, placebo-controlled trial of citicoline add-on therapy in outpatients with bipolar disorder and cocaine dependence. J. Clin. Psychopharmacol., 27 (5), 498–502. 64. Pettinati, H.M. et al. (2008) A double-blind, placebocontrolled study of quetiapine adjunct therapy with traditional mood stabilizers in bipolar i patients with alcohol dependence. Alcohol. Clin. Exp. Res., 32 (s1), 258. 65. Salloum, I.M. et al. (2005) Divalproex reduces cocaine use in patients with bipolar disorder and comorbid alcoholism. Bipolar Disord., 7 (s2), 93. 66. Brady, K.T. et al. (2002) Carbamazepine in the treatment of cocaine dependence: subtyping by affective disorder. Exp. Clin. Psychopharm., 10 (3), 276–285. 67. Brown, E.S. et al. (2002) Quetiapine in bipolar disorder and cocaine dependence. Bipolar Disord. December,4 (6),406–411. 68. Brady, K.T. et al. (1995) Valproate in the treatment of acute bipolar affective episodes complicated by substance abuse: a pilot study. J. Clin. Psychiatry, 56 (3), 118–121. 69. Albanese, M.J., Clodfelter, R.C.J. and Khantzian, E.J. (2000) Divalproex sodium in substance abusers with mood disorder. J. Clin. Psychiat., 61 (12), 916–921. 70. Salloum, I.M. et al. (2007) Divalproex utility in bipolar disorder with co-occurring cocaine dependence: a pilot study. Addict. Behav., 32 (2), 410–415. 71. Brown, E.S. et al. (2006) Lamotrigine for bipolar disorder and comorbid cocaine dependence: a replication and extension study. J. Affect. Disord., 93 (1–3), 219–222. 72. Salloum, I.M., Cornelius, J.R. and Chakravorthy, S. (2003) Combined naltrexone valproate in bipolar alcoholics: a
366
73.
74.
75.
76.
|
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randomized, open-label, pilot study. Bipolar Disord. Supplement, 1, 79–80. Brown, E.S. et al. (2006) Naltrexone in patients with bipolar disorder and alcohol dependence. Depress Anx., 23 (8), 492–495. Johnson, B.A. et al. (2003) Oral topiramate for treatment of alcohol dependence: a randomised controlled trial. Lancet, 361 (9370), 1677–1685. Johnson, B.A., et al. (2007) Topiramate for treating alcohol dependence: a randomized controlled trial. JAMA, 298 (14), 1641–1651. Johnson, B.A. (2006) New weapon to curb smoking: no more excuses to delay treatment. Arch. Intern. Med., 166 (15), 1547–1550.
77. Cowan, A.P. (2007) Buprenorphine: the basic pharmacology revisited. J. Addiction Med., 1 (2), 68–72. 78. Salloum, I.M. et al. (2005) Efficacy of valproate maintenance in patients with bipolar disorder and alcoholism: a doubleblind placebo-controlled study. [see comment]. Arch. Gen. Psychiatry, 62 (1), 37–45. 79. Carroll, K.M. et al. (1998) Treatment of cocaine and alcohol dependence with psychotherapy and disulfiram. Addiction, 93 (5), 713–727. 80. Salloum, I.M. and Cornelius, J.R. (1999) Management of side effects of druges used in treatment of alcoholism and drug abuse, in Practical Management of the Side Effects of Psychotropic Drugs (ed. R. Balon), Marcel Dekker, New York, NY, pp. 169–197.
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Bipolar Disorder and Safety Monitoring for Clinicians: A Review of the Evidence and the Implications Chris J. Bushe1 and Mauricio Tohen2 1 2
Lilly UK, Basingstoke RG24 9NL, UK University of Texas Health Science Centre at San Antonio, San Antonio, TX, USA
Introduction Over the last 10 years there has been far greater attention paid to adverse outcomes associated with the use of psychotropic agents in bipolar disorder. Awareness has developed that for many patients lifelong treatment with antipsychotics and mood stabilizing agents is the norm. Bipolar disorder is also a complex disorder moving through various phases quickly in an individual patient and thus often requiring a combination of psychotropics long term and it is common for an individual subject to receive three psychotropics concurrently, often from different classes of therapeutic agents [1]. Better and longerterm research has also helped clinicians understand the metrics and severity of adverse events that may be associated with the treatment. This has been reflected in the safety aspects relating to monitoring in guidelines [2–4], some of which are specific for bipolar disorder, regulatory change that now encompasses the mandatory requirement for all new licensed compounds to have a risk management plan (RMP) and widespread usage of more generic monitoring guidelines proposed on an evidence base by leading global institutions such as the Maudsley guidelines in UK [5]. Resultantly, clinicians are now recommended to monitor certain parameters and variables on a long-term basis. Whereas many clinicians might view bipolar disorder as requiring similar monitoring to schizophrenia or schizoaffective disorder, there are additional facets to bipolar disorder monitoring that needs to acknowledge that in addition to antipsychotics used in both affective and non-affective disorders, treatments commonly used in the treatment of bipolar disorder such as lithium or anticonvulsant mood stabilizers have distinct safety profiles. A further issue that transcends safety monitoring is the
Bipolar Disorder: Clinical and Neurobiological Foundations Edited by Lakshmi N. Yatham and Mario Maj © 2010 John Wiley & Sons, Ltd. ISBN: 978-0-470-72198-8
unfortunate reality that few patients suffering from bipolar disorder have acceptable levels of healthcare; consequently any monitoring may lead to diagnosis of illnesses that are relatively common in the general population, such as hypertension, hypothyroidism and cancers [6–8]. Many of these relate neither to the illness specifically nor its treatment but are important nonetheless. Safety monitoring on a regular basis can be expected to improve the general physical healthcare of patients with bipolar disorder [9]. In this review, we have not included antidepressants and other pharmacological treatments (benzodiazepines), as these either do not have specific safety monitoring needs or in many cases do not form part of recommended longterm treatment programmes.
Metabolism and bipolar disorder Overview of metabolic issues in bipolar disorder Data describing metabolic and other adverse events has been widely published over the last 10 years but there remains an imprecise distinction between forms of bipolar disorder, schizoaffective disorder and schizophrenia. Consequently much data has been reported from generic cohorts of patients often referred to as severe mental illness (SMI). These data have contributed to our understanding of metabolic and other adverse events and as such have been included in this review. There is sometimes a generic assumption that psychotropic agents have similar safety profiles in all forms of SMI (schizophrenia and bipolar disorder) but we need to be aware that this is a hypothesis that will require confirmation. The prevalence of obesity is increasing in patients with bipolar disorder, at least at the rate such an increase is seen in the general population. Prevalence rates increased from 26% during 1995–2001 to 49% in 2003–2004 in the United States [10] and the country-specific need for comparative data is exampled by the simple but unsurprising 367
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observation that US bipolar patients have greater BMI, and higher rates of obesity and extreme obesity than European patients. There are questions about the clinical value of a diagnosis of metabolic syndrome. For example, in 2005, the ATP 111 diagnostic criteria thresholds were reduced for a diagnosis of metabolic syndrome and resultantly rates can be expected to rise making temporal comparisons complex. There are also at least five different definitions of the metabolic syndrome and in population studies the choice affects the prevalence measured. An example of this is a prospective study in a Belgian naturalistic cohort, where the prevalence of metabolic syndrome varied from 30% using IDF criteria to 16.7% with ATP 111 [1]. An important weakness is also that metabolic syndrome as an entity is not graded and hence there is no uniform means of assessing worsening. Clinicians may also forget that metabolic syndrome is only one of many cardiovascular prediction tools. As a result of increased attention, particularly to the potential metabolic adverse effects of psychotropic agents and awareness that genetic vulnerability and lifestyle factors also may have a significant role in adverse metabolic outcomes, there has been many data reported on metabolic and other physical health parameters. Data has been derived from both shorter-term RCTs and longer non-interventional studies but it is complex to try and separate out the potential role of treatment in adverse metabolic outcomes compared to illness or lifestyle. Evidence is supportive that glucose abnormalities are more prevalent in treatmentna€ıve subjects and far more common also in the well first-degree relatives of these subjects [11] than in relevant control populations. In prospective randomized trials, incident glucose abnormalities can also be measured in placebo cohorts, further defining the independent role the illness has in adverse outcomes [12]. A family history of diabetes can be found in almost a third of bipolar subjects (32%) [1]. Certainly DM is more prevalent in bipolar disorder patients than in the general population and the many risk factors for DM excluding medication play a major role in causation [11]. Thus we need to consider when advising safety monitoring not only what might the adverse effect of the medication be but also what might the adverse effect of the illness and lifestyle be.
How common are metabolic abnormalities in bipolar disorder? There is little doubt that higher rates of all forms of metabolic disorder obesity, diabetes, dyslipidaemia and risk factor constellations such as metabolic syndrome are found in bipolar patients [13] and these factors have strong associations with underlying insulin resistance. However, there is less certainty to what extent an underlying genetic
predisposition, choice of treatment and the illness-related effects (stress and lifestyle alterations) each potentially contribute to this increased risk. It may be appropriate to consider that the diagnosis of bipolar disorder carries with it a significant risk of metabolic disorder with the various other proponents potentially worsening the risk. More recently emerging data suggests that women with bipolar disorder may be particularly at risk for metabolic problems that are underpinned by insulin resistance [13]. Such metabolic dysfunction and obesity is also present in treatmentna€ıve women [13]. Whether metabolic syndrome is the best parameter to assess such dysfunction needs debate. Whereas the CATIE study in chronic schizophrenia patients reported that metabolic syndrome is more common in females (51.6% vs. 36%), similar data in bipolar disorder is currently less convincing [8,13]. To generalize, metabolic abnormalities are highest in schizoaffective patients, then schizophrenia and less often increased in bipolar subjects [1] but greater than in relevant general populations. There are also regional variations leading to necessity to compare data within a country or region. For example, prevalence rates of metabolic syndrome in bipolar patients of 16.7% in Belgium and 30–49% in the United States are reported, whereas rates in schizoaffective patients in the United States reached 40% [13]). A cross-sectional prevalence survey of 560 SMI patients in Kentucky, USA, reported that compared with their general population, the odds ratio of obesity was 2.6 (95% CI; 2–3) [14]. Rates of glucose abnormalities will be determined by many factors, including the precise population being screened, current known prevalence in that cohort and the format of testing utilized. Oral Glucose tolerance Testing is the gold standard investigation and Belgian trials report success in engaging patients in this testing [1] and the utility of doing so. In a cohort of such screened patients without known glucose abnormalities, high hidden rates of DM 6.7% and prediabetic glucose abnormalities of 23.3% were measured, with the majority of patients not overweight. A chart review of inpatients with major psychiatric disorders reported 26% prevalence of glucose abnormalities [15]. Any linkage between weight and metabolic abnormality in bipolar and schizophrenia patients may be more complex than a simple linear link [13,16]. In a Belgian naturalistic sample, of 707 patients with psychosis the risk of metabolic syndrome was significantly higher in the schizoaffective cohort than in bipolar patients (OR 3.5; p < 0.0001). Schizophrenia patients also having a higher rate than bipolar subjects (OR 1.97; p ¼ 0.046). The absolute prevalence of metabolic syndrome was 50% schizoaffective, 27% schizophrenia and 23% bipolar subjects [1] with speculation that brain derived neurotrophic factor gene (BDNF) may play an aetiological role. However, there were no differences in glucose abnormalities; in 28% of schizophrenia and bipolar patients, up to
Bipolar Disorder and Safety Monitoring for Clinicians
40% were schizoaffective. The glucose data are consistent with three retrospective chart reviews also reporting an increased prevalence of diabetes compared to a general population, as reviewed by van Winkel [1]. Many studies have been unable to adjust for all relevant confounders and in particular ethnicity may be important. A recent review on this topic suggested that glucose elevation may be greater in non-white subjects [17]. Future research needs to take account of ethnicity. Obesity is more frequent in bipolar disorder and specifically in females in addition to increased waist circumference, as was shown in STEP-BD (women 31%, men 21%) [18], despite similar frequency of those with BMI >25. The males tended to remain in the BMI 25–30 category, whilst females had propensity to BMI >30. Prevalence rates of metabolic syndrome vary worldwide and consequently it is critical to compare any prevalence figure with the local general population. For example, in Spain the prevalence of metabolic syndrome is 22% but this is 58% higher than for the Spanish general population of 14% [19], and the rate from Turkey of 32% is nearly twice the prevalence in the adult general population of 18% [20].
How much metabolic monitoring and physical health screening is currently undertaken? As recently as 2004 in United Kingdom, there was little evidence that monitoring of lipids was routinely undertaken by psychiatrists. A chart review of 606 SMI inpatients reported that lipids were measured during admission in only 3.5% of patients, leading to the conclusion that diagnosed rates of dyslipidaemia at 1.3% were likely to significantly underestimate the full extent of dyslipidaemia, with a consequence that only 1.3% were treated with statins [21]. Furthermore, only 19% had their weight recorded (giving a prevalence for BMI >25 of 14%) and 41% had glucose testing (giving a prevalence of 6.4% with glucose abnormalities). The study then went on to measure these parameters and reported actual prevalence rates for abnormal glucose of 17%, dyslipidaemia 68% and BMI >25 62%. In 2007, an audit of 2000 UK patients from assertive outreach teams, whom might be expected to have close contact with secondary care, reported that during 2005–2006 there were recorded measurements for blood pressure 26%, obesity 17%, lipids 22% and glucose 28% [22]. This failure to monitor recognized CVD risk factors was mirrored by the low rates of diagnosed DM 6%, hypertension 6% and dyslipidaemia 6%, when the true rates are significantly greater. Further UK data was reported in 2007 from the baseline data prior to initiation of a lifestyle and well-being programme (Wellbeing Support Programme WSP) in 1000 SMI patients from geographically diverse centres [7]. Only 31% had received any form of
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physical health monitoring in the previous year and in some regions this level was as low as 7% [7]. There can be little surprise that when testing was undertaken, rates of measured obesity BMI > 30 49%, hypertension 50% and hyperlipidaemia 71%, were found. Metabolic monitoring is complex and it is too simplistic to measure only components of the metabolic syndrome. There are reasons to be cautious about equating metabolic syndrome and metabolic abnormality. First, metabolic syndrome does seem less prevalent in bipolar disorder than schizophrenia or schizoaffective disorder. Second, metabolic syndrome is not an illness but a constellation of specific variables and there are at least five different definitions. Lastly, metabolic syndrome is a CVD risk predictor but is in fact not the best predictor. The best predictor seems still to be the Framingham criteria. NICE in the United Kingdom furthermore consider that in a population receiving antipsychotics, usage of CVD risk prediction may not be appropriate [23]. Conversely, metabolic syndrome may be a useful tool for psychiatrists whom at least understand its importance and should not be totally discouraged and it was reported that in 2006 survey 56% of EU psychiatrists had diagnosed metabolic syndrome and encouragingly 65% were adjusting their monitoring accordingly [24], but 18% were unaware of the diagnostic criteria. The same survey showed that whereas almost half were very concerned with weight gain or glucose abnormalities, only 22% were similarly concerned over dyslipidaemia.
Monitoring requirements for bipolar patients Who should monitor? The NICE 2009 schizophrenia guidelines recommend that physical health monitoring is undertaken in primary care; however, this does not recognize that patients prefer at least their monitoring to be undertaken in secondary care by their provider and that secondary care is well placed to perform the monitoring. There will be some monitoring that the psychiatrists can and will act upon, for example, lithium levels, but for many abnormal results it is not in the remit of the psychiatrist to manage complex metabolic abnormalities and evaluate any need for statin usage. A further issue is that for an individual patient, they may have various physical health tests done in a variety of disparate places (inpatient, outpatient, hospital A/E, GP, specific screening services for breast cancer). There is no certainty that all these tests are transmitted to a single health care provider such as the GP. It remains a practical issue that without all data in a single place, taking an overview and actioning treatment strategies becomes difficult. A recent UK audit [22] reported that only 17% of assertive outreach teams have a clear
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system for agreeing responsibility for monitoring between primary and secondary care. Further identified issues in this audit included the unavailability of basic equipment (couch, room, blood pressure monitor, etc.) and importantly lack of availability of results of investigations, which were available in only 28% of cases at the next attendance, which when combined with the realization that less than 40% of clinicians felt they had adequate time and knowledge to undertake physical health monitoring, does not bode well.
What monitoring should be undertaken? Overview Bipolar patients are an eclectic mix of ages, diagnostic categories and are in varying states of health. However, it does seem clear that few patients will be receiving a single medication and the norm will be essential polypharmacy. Hence a monitoring programme that addresses both potential drug adverse events and more generic inherent health risks relating to bipolar disorder will need to be only somewhat tailored to specific medication choices. There will be much generic monitoring that all bipolar patients will require. Currently there are no specific published guidelines that advise only on safety monitoring in bipolar disorder, although the International Society for Bipolar Disorders (ISBD) has been developing safety monitoring guidelines. Many guidelines that give guidance on the totality of the management of bipolar disorder include sections on physical health monitoring and broadly speaking recognize its importance. However, there is little agreement over either the specific monitoring or the frequency. We have reviewed the major guidelines [2–4] and take a view that monitoring should be divided into generic (for all bipolar patients regardless of medication and illness phase) and specific for each medication.
Generic bipolar safety monitoring Currently available guidelines are not in total agreement with recommended specific monitoring recommendations. None focus totally on such monitoring and there are three main guidelines from which recommendations can be drawn, National Institute for Health and Clinical excellence (NICE), Canadian Network for mood and Anxiety Treatments (CANMAT) and the American Psychiatric Association (APA) [2–4]. To generalize, the CANMAT guidelines require more monitoring than the others. However, none explicitly recommend long-term monitoring of aspects of bipolar disorder that may be under genetic or lifestyle influence, rather than being potentially treatment-related. For this reason we would propose that there are baseline
and ongoing monitoring aspects that should be undertaken in all bipolar patients. There are some generic safety monitoring that should be undertaken in all patients prior to commencing treatment: History: Full medical and family history (including CVD events, family history (FH) DM and breast cancer), CVD risk factors, ethnicity, illicit drug and alcohol consumption, Baseline Investigations: Waist and hip circumference, weight and height (BMI), blood pressure, glucose, lipid profile, non-fasting triglyceride, full blood count, liver function, renal function. Non-fasting blood samples are acceptable and for triglycerides should be encouraged [94,95]. Additional Baseline Investigations: Breast examination and mammography (>50 years), testicular examination, ECG, thyroid, prolactin, renal and electrolytes and liver function. GammaGT may be specifically useful for early detection of excess alcohol intake. Ongoing Regular Investigations: Waist and weight threemonthly with additional testing in early phase treatment as indicated; glucose and lipids three-monthly and then annually; prolactin three months and then as clinically indicated, blood pressure annually.
Additional safety monitoring according to specific treatment Lithium Dosing and toxicity Lithium is an effective treatment in bipolar disorder [2], but has been associated with a number of adverse events (Table 1). An important aspect is that clinical vigilance is as important as blood monitoring in the prevention of serious lithium toxicity. Each laboratory has a working normal range for a therapeutic lithium level, as there is a narrow therapeutic index. Lithium clinical toxicity can, however, arise with a plasma level within a normal range and if untreated can lead to permanent organ damage and sometimes death and thus should always be treated as a medical emergency. Patients should be aware of the need for adequate hydration and the potential for drug interactions that will increase plasma levels. Dosing is to some degree dependent on the severity and stage of the bipolar illness but also needs to be guided by adverse events and where possible should be the lower end of the therapeutic range. Vulnerable groups are likely to include the elderly, those with medical comorbidities and polypharmacy and those with organic brain syndromes. The predominant risk factor for lithium toxicity is reduced renal excretion. Lithium adverse events: . Renal. Renal impairment is common with NDI on longterm lithium treatment, being reported in 12% of patients after 15 years treatment but up to 54% may have reduced renal concentration [25,26]. Chronic renal disease, including
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Table 1 Adverse events associated with lithium treatment and toxicity. Organ system
Adverse event
Adverse event when lithium toxicity present
Neurological
Tremors, cognitive difficulties
Gastrointestinal Cardiac Metabolic Haematological Renal Endocrine
Nausea, vomiting, diarrhoea, abdominal pain Conduction abnormalities and ECG change Weight gain leucocytosis Nephrogenic diabetes insipidus Thyroid and parathyroid abnormal function
Coarse tremors, drowsiness, lethargy, weakness, ataxia, muscle fasciculation, agitation. Nausea, vomiting, diarrhoea, abdominal pain Syncope, arrhythmias, dizziness
nephropathies, nephritic syndrome and renal failure may have an underestimated prevalence. Risk factors are imprecise but likely to include higher doses over long-term periods, concomitant illness where renal damage is common but asymptomatic (hypertension, DM) and usage of other nephrotoxic drugs. Renal monitoring is thus appropriate in many patients. Discontinuation of lithium may lead to improvement or resolution of renal problems, but this is not always the case [27]. . Thyroid and Parathyroid. Spontaneous hypothyroidism is not uncommon in a general population with an incidence in a 20-year longitudinal study of 0.35% females and 0.06% males and has a strong association with other autoantibody related illness [28]. In longer-term lithium treatment, significantly higher incidence rates have been observed, 2.3% in females and 0.7% in males [29]. Thyroid function tests may transiently alter during initiation of lithium and in acute illness and thus test repetition may be required to confirm any diagnosis. Hyperparathyroidism is 7.5 times more common than in the general population, with a point prevalence of 2.7% in longer-term treatment [30]. The resultant bone resorption and hypercalcaemia may cause symptoms and be associated with renal calculi, osteoporosis and a series of non-specific symptoms (weakness, tiredness, nausea). . Weight. Lithium is associated with some weight gain. Over 52 weeks, observed case data reported a mean weight gain of 3.8 kg compared with 2.1 kg for placebo [31]. The weight gain was greater in those already overweight. A review of this topic reports weight gain of 5 kg over one to two years, up to 4.5–15.6 kg over two years [13]. . Drug interactions with Lithium. Any increase of lithium levels may cause toxicity and there is potential for various classes of drug to increase lithium levels. These include: NSAIDs, selective COX-2 inhibitors, ACE inhibitors, thiazides. For ACE inhibitors there may be a delay before lithium levels increase and additional monitoring for the initial two to three months is prudent. Lithium Monitoring. In addition to the baseline monitoring for all bipolar subjects the following may be appropriate according to NICE bipolar 2006 guidelines:
Polyuria, polydipsia
1 TSH and calcium at baseline and six-monthly. Appropriate tests may be indicated if any pre-existing renal or endocrine disorder is present. Total calcium is adequate, however free calcium levels may be indicated in the presence of altered blood pH. Parathyroid hormone levels can be measured 2 Lithium levels taken at steady-state 12-hours post dose (seven days after last dose increase) and repeated until levels within the monitoring range. The aim should be to maintain serum lithium levels between 0.6 and 0.8 mmol/L in subjects receiving lithium for the first time. Further testing is dependent on many factors but should be done three-monthly. 3 Renal function (urea and creatinine) six-monthly, but more frequently if evidence of impaired renal function.
Carbamazepine Adverse events There are a number of potential adverse events that relate to safety monitoring: . Haematological. Blood dyscrasias are associated with treatment and are listed in Table 2. . Hepatic. Elevations in enzymes are common, as carbamazepine induces hepatic enzymes but rarely translating into clinical symptoms [33]. Acute drug-induced hepatitis has a rapid onset and may not be predicted by LFT monitoring and is an immune-mediated hypersensitivity syndrome with a mixed hepatitic-cholestatic type presentation. . Dermatological. As with lamotrigine, TEN and SJS may occur rarely [34]. . Reduced bone density. There is some evidence from epilepsy studies; however, data in bipolar disorder is unclear. Many bipolar subjects will have multiple other risk factors for BMD loss, including hyperprolactinaemia and lifestyle issues unrelated to carbamazepine . Hyponatraemia. Common [35]. . Reduced contraceptive effects. due to hepatic P450 enzyme induction. Use contraceptives not affected by carbamazepine or higher dosing regimens.
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Table 2 Adverse events associated with carbamazepine treatment and toxicity. Adverse event
Frequency
Implications for monitoring
Leucopenia
10–20% during initial 3 mo. In point prevalence study 977 hospitalized subjects, prevalence 2.1% Rare in general population between 1–15/million. OR 5.9–16.9 Rare Very rare. 21.9 per 100 000 (de Abajo 2004)
Resolves on cessation (mean 6.5 d)
Agranulocytosis and aplastic anaemia Thrombocytopenia Drug induced hepatitis Elevation of liver enzymes SJS and TEN hyponatraemia
Very common Very rare 1.4/10 000 new patients Common. Prevalence 4.8–40%. (Van Amelsvoort 1994). ADH is involved but mechanism unclear.
Recommended monitoring [2] FBC, LFT and U/E 6-monthly.
.
Valproate Adverse events There are a number of potential adverse events that relate to safety monitoring [39,40]: . Haematological. Thrombocytopenia is associated with treatment and is listed in Table 3. Although relatively commonly diagnosed, it is only rare cases that are severe. In 1251 hospitalized subjects, there were no cases of TCP <100 000 [36]. . Hepatic. Elevations in enzymes are common but rarely translating into clinical symptoms [37]. The black box
Unpredictable and rapid onset. Median onset 49 d, resolving after 6 d drug cessation — Severe and rapid onset not predicted by LFT monitoring. Early onset. Resolves on cessation and recurs on rechallenge. ALT > 2–3 times considered drug induced hepatitis 90% cases before 63 d Usually chronic and asymptomatic. No fatal cases. Risk factors include concomitant medications causing hyponatraemia. May progress to symptomatic. Treatment is slow correction.
warning in the USPI, however, does state the need to monitor for relevant symptoms in order to detect symptoms of serious potentially fatal hepatotoxicity. . Dermatological. As with lamotrigine, TEN and SJS may occur rarely [34]. . Reduced bone density. There is some evidence from epilepsy studies; however, data in bipolar disorder is unclear [38]. Many bipolar subjects will have multiple other risk factors for bone mineral density (BMD) loss, including hyperprolactinaemia and lifestyle issues unrelated to carbamazepine. . Endocrine. Valproate may be associated with elevated rates of polycystic ovary syndrome (PCOS), menstrual-
Table 3 Adverse events associated with valproate treatment and toxicity. Adverse event
Frequency
Implications for monitoring
Thrombocytopenia
12% mild/moderate
Blood dyscrasias (coagulopathies, aplastic anaemia, bone marrow suppression) Idiopathic hepatitis Asymptomatic elevations LFT SJS and TEN Weight gain and metabolic PCOS
Very rare
Clinical bleeding only associated with severe TCP <50 000. Associated with higher dose, develop over months and resolve with dose reduction. Reverse on treatment discontinuation
Very rare Very common but hepatic injury rare
— First 3–6 mo. Sometimes later.
Very rare. 0.4/10 000 new patients Common. 11.9% over 47 wk had significant weight gain 10.5% Val, 1.4% other mood stabilizers
90% cases before 63 d Males develop increased lipids and insulin
Pancreatitis Hyperammonaemic encephalopathy
Estimated incidence 2/1044 patient years Rare
Symptoms in 12 mo, median 3 mo. Mostly resolves after drug cessation. Hyperandrogenism common. Fatal unless immediate discontinuation. Develops early – days/weeks.
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cycle abnormalities and hyperandrogenism [13,41]. Menstrual-cycle abnormalities measured in 47% vs. 0% control and 13% non-valproate, with PCOS in 41% [42].
Reccomended monitoring [2] The usage of valproate in women of child-bearing potential is discouraged by NICE, due to teratogenicity risk [2]. Adequate contraception needs to be checked. Additional monitoring over baseline might include in addition to all requirements of the USPI: . Serum measurements to establish therapeutic dose if evidence of ineffectiveess, poor adherence or toxicity; . Baseline hepatic and haematological history; . FBC and LFT after 6 months.
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Table 4 Adverse events and monitoring considerations for antipsychotics. Organ system
Adverse event
Clinical context
Cardiac
QTc prolongation
Metabolic
Weight gain
Endocrine
Hyperprolactinaemia
Risk factor for arrhythmia and sudden death. TdP. CVD risk factor. Postulated worsening of dyslipidaemia and glucose Sexual dysfunction, infertility, amenorrhoea, bone mineral density loss, osteoporosis, postulated role in breast cancer
Lamotrigine The clinical issues lamotrigine, carbamazepine and valproate have all been associated with mucocutaneous syndromes, which are complex to classify [34]. There are a series of such syndromes that clinically overlap but the main syndromes are Stevens-Johnson syndrome (SJS) and Toxic Epidermal Necrolysis (TEN) and are rare, although it is difficult to be precise over rates. For lamotrigine, the risk of serious rash (defined as requiring hospitalization and discontinuation, SJS or TEN) may be 0.1%, although higher rates of 0.3% were previously reported [34,43–45]. Any reduction may relate to a more cautious approach to dosing schedules and awareness of elevated levels when used with Valproate, due to inhibition of its metabolism. The risk per 10 000 subjects, as derived from one study, may equate to 2.5 for lamotrigine, 1.4 for carbamazepine and 0.4 for Valproate [46]. Benign rash is more frequent with lamotrigine with an incidence of 8.3% in a series of clinical trials [43]. Valproate can increase lamotrigine levels via inhibition of hepatic glucuronidation, thus increasing risk of SJS/TEN. Lamotrigine dose should be halved. In a naturalistic cohort (n ¼ 145), no serious rash was reported and 3.5% subjects discontinued due to a benign rash over a mean of 434 days [47]. Monitoring solutions SJS and TEN are both rare and idiosyn-cratic and cannot be predicted.
Antipsychotics and monitoring Antipsychotics are utilized in both the acute treatment and maintenance of bipolar disorder. With both acute and longer-term usage, appropriate monitoring is essential in total accordance with their SPCs (Table 4). All antipsychotics may be associated with weight gain and alterations in metabolic parameters and although some may have a worse profile for weight change, glucose and lipids, metabolic changes are measured in patients taking all antipsychotics including typicals. Predominantly atypical antipsychotics
Table 5 Percentage of SMI patients with recorded measurement in clinical records. Parameter
2005
2006
Blood pressure BMI/Obesity Glucose Lipids
26% 17% 28% 22%
43% 34% 38% 35%
are prescribed with aripiprazole, olanzapine, quetiapine, risperidone and ziprasidone, demonstrating efficacy in RCTs in forms of bipolar illness. Predominantly, the monitoring required covers the areas relating to weight, metabolic changes and prolactin [2], although NICE recommend prolactin monitoring only for risperidone subjects, and monitoring requirements differ between children/adolescents and adults. There is also debate regarding the relative effects of antipsychotics on ECG parameters, such as QTc, and the value of routine screening. However, NICE do recommend routine ECG monitoring for subjects with risk factors for, or existing cardiovascular disease. NICE also recommend, when initiating quetiapine [2], the dose should be titrated gradually in accordance with the SPC. Weight should be measured at least three-monthly, plasma glucose and lipids three-months after treatment initiaition (one month for olanzapine) in all bipolar patients regardless of medication [2].
Metabolic parameters In general terms, much of the metabolic data derives from antipsychotic usage in schizophrenia cohorts and there is an assumption that similar changes will be measured in bipolar disorder. However, NICE utilized many data from schizophrenia cohorts in making their recommendations for monitoring in bipolar disorder [2]. The terminology of metabolic syndrome has crept in the last few years;
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however, few long-term comparative data exist and most are post-hoc analyses from incomplete datasets [48]. Furthermore, metabolic syndrome is not an illness but a constellation of measurements that constitute a CVD risk prediction tool. For this review it should be understood that other CVD risk predictors, such as Framingham criteria, are more accurate. Metabolic syndrome does, however, allow psychiatrists one simple measurement that is perhaps understandable. Comparative data in schizophrenia over one year reports incidence rates of 15.7% for aripiprazole and 27.4% for olanzapine, which in the dataset examined gave prevalence rates of 27.9 and 41.6%. respectively [48]. Metabolic syndrome has been reported in a significant proportion of schizophrenia patients treated with antipsychotics in CATIE, including those sometimes identified as metabolically neutral. In the fasting dataset (primary analysis), at three months there were no significant between-drug differences in the proportion of subjects metabolic syndrome status. Although antipsychotics have recognized associations with weight gain, dyslipidaemia and glucose abnormalities, these are common in treatment-na€ıve schizophrenia patients and almost certainly bipolar subjects as well [11]. The EUFEST study in schizophrenia demonstrated a baseline prevalence of 7% glucose abnormalities, 17% subjects BMI >25 and at least 23% with dyslipidaemia [50]. In CATIE, the numbers of schizophrenia patients gaining more than 7% body weight was 30% olanzapine, 16% quetiapine, 14% risperidone and 7% ziprasidone, and significantly more olanzapine patients discontinued treatment due to changes in weight or metabolic parameters [51]. There are relatively fewer head-to-head studies between atypicals but in a 6-month RCT in a schizophrenia cohort, weight gain of more than 7% was measured in 19% of the olanzapine cohort and 13% of quetiapine subjects (p ¼ ns) [52]. This study reporting weight in a categorical manner also emphasized that 9% of each cohort lost more than 7% of their initial weight. Weight changes reported over short-term trials in bipolar disorder may not be reflective of longer-term usage [53]. During the acute phase, 29.1% of patients gained 7% of baseline weight and 16.1% during the randomized maintenance phase [53]. In a four-week lithium comparator study in acute mania, mean weight gain was 1.85 kg in olanzapine subjects and 0.73 kg in lithium subjects (p ¼ 0.012). However, this was not reflective of the fact that numbers of patients gaining more than 7% weight was 16% olanzapine and 3% lithium [54]. In a four-week placebo controlled study in bipolar mania, olanzapine weight gain was significantly greater than placebo (2.1 vs. 0.45 kg) [55] and in the 6–12-week open-label co-treatment phase with olanzapine and lithium, a mean weight gain of 2.7 kg (with 28% having weight increase >7%) was subsequently followed by mean weight gain of 1.8 kg over 52 weeks of olanzapine treatment [32]. More
olanzapine than lithium patients measured more than 7% weight gain (30% vs. 10%; p < 0.001). In an analysis of 113 bipolar 1 subjects followed for up to a year on olanzapine, almost 80% gained weight. During an initial three-week treatment, the mean weight increase of 2 kg had increased to 6.53 kg after a mean of 29 weeks treatment [56]. The weight of bipolar patients does not increase in a linear manner, which makes short-term trials complex to interpret. Quetiapine, risperidone and aripiprazole are all associated with weight gain [51]. For quetiapine, the mean weight change ranging from 0.9 to 2.6 kg has been reported during mania treatment to 12 weeks, with 12.8 to 39% of patients gaining 7% of baseline weight [58,59]. Weight gain may be less with aripiprazole, with weight gain of 0.5 kg over 6 months in a placebo controlled bipolar study. Mean weight change during mania trials to 12 weeks has ranged from 0.27 to 1.4 kg with 14.6% [60,61] of patients gaining 7% of baseline weight in the only study that reported this. Mean weight change during the treatment of bipolar depression to 8 weeks has ranged from 0.01 to þ 0.08 kg, with 2.9 to 6.7% of patients gaining 7% of baseline weight [62]. In the CATIE schizophrenia study, ziprasidone was the only atypical antipsychotic associated with mean weight loss [51]. There is less weight data on risperidone in bipolar disorder. Mean weight change at 12 weeks is reported in one bipolar study [63] as 1.4 kg. In a five-year naturalistic cohort of risperidone SMI patients, 40% gained more than 7% body weight and mean weight gain was 4.7 11.6 kg [64], with 72% being accumulated by two years. The relative risk profiles for glucose abnormalities from published randomized clinical trials show no significant differences between antipsychotics [65]. However, the US olanzapine label does state that the association between atypical antipsychotics and increases in glucose levels appears to fall on a continuum and olanzapine appears to have a greater association than some other atypical antipsychotics. Importantly, the incidence of glucose abnormalities is the same in placebo as in active comparator cohorts [16,65]. Interpretation of data is complex, in that no single study has glucose as its primary endpoint. Fasting glucose data from the CATIE schizophrenia study reported no glucose differences between cohorts at three and nine months after the initial data, and a mixture of fasting and non-fasting samples in the same patients suggested originally that glucose differences may be present [51,66]. CATIE phase 3 (an openlabel phase) saw the first entry of aripiprazole and there was significantly greater glucose elevation in the aripiprazole cohort than other comparators [67], which was acknowledged by the authors as a chance finding based on evidence provided in the systematic review of glucose data from schizophrenia RCTs [65]. Recent large studies in firstepisode schizophrenia (including CAFE´ and EUFEST) also report no glucose differences [50,52,68]. For QUET XR, one
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schizophrenia clinical study report states that glucose changes were generally higher with QUET XR than PBO over 3 weeks of treatment [69]. For patients with diabetic risk factors, more QUET XR treated patients (10.1%) than PBO (4.4%) experienced a glucose value of 7.0 mmol/L over 3 weeks. The ZODIAC study in schizophrenia reported few cases of DKA in either the ziprasidone or olanzapine cohorts; however, DKA has been reported in temporal association with all utilized atypicals [70]. Dyslipidaemias are complex to interpret for numerous factors. Few data are available in treatment of na€ıve SMI subjects and fasting data is not so readily available [71]. Retrospective database studies often have the largest cohorts but are confounded by lack of data on how many subjects in a given cohort had blood testing. Some studies have suggested patients taking atypicals, such as clozapine and olanzapine, have more blood tests and outside of a prospective evaluation this confounder cannot be fully addressed [72]. A pharmacoepidemiological study in SMI patients with matched case controls reported increased rates of hyperlipidaemia for olanzapine 1.56 OR and Ziprasidone 1.4 OR, but not aripiprazole [73]. During maintenance treatment of bipolar disorder with aripiprazole, no significant differences in mean lipid changes or categorical changes have emerged [74,75]. The CATIE study initially reported increases in cholesterol and triglycerides for olanzapine and quetiapine but not risperidone or ziprasidone. However, later data found that although olanzapine was associated with initial elevations in cholesterol, this had normalized to baseline values by 9–12 months [51,76].
Cancer screening Rather than consider cancer as a single entity in bipolar disorder, it can be considered in individual types. Any screening available to the general population should be made easily available to bipolar patients. Schizophrenia has long been associated with a postulated decreased risk of cancer but research has proved complex and contradictory [84]. There is little research in bipolar disorder and any research amalgamates all bipolar subjects as a single entity. A large UK nested case-control study of 40,000 cancer subjects with schizophrenia or bipolar disorder found no increased risk of cancer in bipolar disorder [77]. A few findings though deserve mention. Schizophrenia patients had a 47% decreased respiratory cancer risk, which differed from bipolar disorder where the rate was the same as the general population. Colon, rectal and gastro oesophageal cancers, although not significantly increased over the general population, did show trends that suggest further research is needed. The odds ratios for these cancers were 0.95 (0.51–1.76), 0.99(0.40–2.43) and 0.98 (0.47–2.05), respectively.
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Cancer rates in SMI patients are likely to underestimate incidence rates, due to lower rates of screening [78].
Prolactin monitoring Hyperprolactinaemia is amongst the most common abnormal laboratory elevations reported in a clinical trial of antipsychotics in schizophrenia and bipolar disorder, but is rarely recognized as such due to incomplete presentation of the data [79]. However. more recent data is now tending to report at least the prevalence of hyperprolactinaemia if not the severity. In an open-label 6–12 week phase utilizing olanzapine in bipolar 1(n ¼ 304) patients, hyperprolactinaemia was measured in 25.6% and weight gain of more than 7% in 29.5%. This contrasted with reported treatment emergent adverse events (TEAE), ranging from 20.4% for dry mouth to 3.9% for insomnia [49]. With an increased awareness of potential long-term adverse events associated with hyperprolactinaemia (bone mineral density loss, fractures, and breast cancer and pituitary tumours) greater attention to prolactin monitoring has been undertaken in the last few years. There has been a tendency to report prolactin as mean cohort values, which does not allow understanding of the precise number of patients developing hyperprolactinaemia [79]. NICE currently recommend prolactin measurements in adult patients treated with risperidone who present with low libido, sexual dysfunction and menstrual abnormalities. How common is hyperprolactinaemia? Bipolar illness has no effect on prolactin levels. Absolute rates of hyperprolactinaemia will be dependent on many factors that include medication choice, gender, age and length of follow-up. Timing in relation to medication may also be relevant, as all D2 blocking drugs will at least temporarily elevate prolactin for a few hours [80]. Naturalistic data may be informative as evidence suggests that prolactin monitoring is not routine and prevalence rates in complete populations screened will reflect previous under-diagnosis. Two recent naturalistic analyses, in which asymptomatic schizophrenia cohorts have been screened for prolactin, both report a prevalence of hyperprolactinaemia of 38% in the United Kingdom and Norway [81,82]. Categorical rates of hyperprolactinaemia from trials in schizophrenia and bipolar disorder show that no antipsychotic is prolactin neutral, and the prevalence is between 33 and 69% [79]. For individual antipsychotics, the prevalence is highest in risperidone treated subjects (72–100%) and amisulpride and are substantially higher than in patients treated with typicals (33% in a UK cohort on depot) [79,81]. In our study (a complete UK cohort of SMI subjects receiving various antipsychotics n ¼ 194), hyperprolactinaemia was measured in 52% females and 26% males consistent with other data [81].
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Measurement of prolactin Many factors in a general population influence a prolactin level. Prolactin is released in a pulsatile manner, with more than 10 peaks/day, but has a defined diurnal rhythm peaking at night. Ideally blood sampling should be undertaken 1 hour after waking before medication in a fasting state; however, the reality is that this not often feasible in outpatients. Factors including stress and poor venepuncture technique may transiently elevate prolactin and if there is doubt as to the aetiology, the sample should be repeated. Dynamic tests of prolactin secretion are rarely helpful. Hyperprolactinaemia is best defined as a prolactin level greater than the local laboratory limits, as these vary. Commonly there are individual normal ranges based on gender and menopausal status. Units of measurement also give some confusion as US data is often presented in ng/ml, whereas most UK and EU data is in mIU/L Traditionally, ng/ml is regarded as conventional and mIU/L as SI units. Other reporting units include ug/l and nmol/l. Conversion rates are also not standardized from ng/ml to miU/L and will vary between 21.2 and 36, dependent on the assay employed. Laboratories should also routinely test for macroprolactin. Dimeric and polymeric forms of prolactin may circulate and although biologically inert with decreased clearance rates, may give rise to spurious hyperprolactinaemia. In the United Kingdom and Ireland, this testing is routine in all samples demonstrating hyperprolactinaemia. Two recent naturalistic studies in SMI cohorts both routinely tested for macroprolactin and found no cases in 400 subjects with a prevalence of hyperprolactinaemia of 38% [81,82]. Macroprolactin is thus unlikely to be a major confounder of diagnosis.
What level of prolactin matters? This is a complex question. If hyperprolactinaemia is associated with clinical symptoms, then that level is relevant for the patient. Although hyperprolactinaemia is associated with menstrual and sexual adverse events, those events may not necessarily be associated with antipsychotic medication. In general terms, levels of less than 1000 mIU/L are associated with decreased libido and infertility, 1000–1600 mIU/L with oligomenorrhea and >2000 mIU/L with amenorrhoea and hypogonadism. Hypogonadism is the driver for bone mineral density loss and fractures. Prolactin levels, that may be associated with longer term adverse events, are even more complex to understand as the reporting of prolactin data is often without the sex hormone data. However, the topic has been reviewed [79] and in cross-sectional prevalence studies in schizophrenia subjects that report bone mineral density loss in association with typicals or risperidone over 8–21 years, the mean cohort values ranged from 908–3024 mIU/L. These levels are common in patients
treated with prolactin elevating antipsychotics [79,81]. The US product labelling for risperidone states that prolactin levels may become elevated and, that is, elevation persists if chronic administration is maintained; however, research is incomplete on this important topic. Risperdione is associated with higher levels of prolactin elevation than other antipsychotics, with the possible exception of amisulpride, which is not licensed in the United States to date [79,81]. Prolactin levels related to breast cancer in bipolar disorder are unknown. Data is supportive of levels as low as 500 mIU/L, relating to an increased risk of breast cancer in the general population [83], but data in bipolar disorder is unknown. Breast cancer is increased in schizophrenia by at least 12%, but a recent UK study reported that breast cancer risk in bipolar patients was the same as the general population [77,84]. Regardless of relationship with prolactin, breast cancer screening should be encouraged in all bipolar subjects. Screening rates are very low compared with the general population for an illness that is very common (lifetime prevalence 1 in 9 and rising) and curable. For many forms of breast cancer diagnosed on screening with mammography and treatment (surgery and chemotherapy), mortality rates do not differ from those in the general population.
Sudden death and ECG monitoring During the last decade, a series of antipsychotics have been withdrawn from usage (thioridazine, droperidol) and others have either failed to be licensed in certain regions (ziprasidone) or had restricted usage (sertindole), due to concerns over their association with QTc prolongation and arrhythmic potential for sudden death. In 2004, Harrigan reported that patients with psychotic disorders treated with thioridazine experienced the greatest QTc prolongation from baseline (30.1 milliseconds) and patients treated with olanzapine experienced the least (1.7 milliseconds). However, no patient had a QTc over 500 milliseconds, which is regarded as the threshold risk level for torsade de pointes [85]. The QTc increase for ziprasidone 15.9 msec compared with quetiapine 5.7 msec, and 3.9 msec risperidone. The CATIE trial in schizophrenia did not report a single case of torsade de pointes in 1493 subjects [51] and the QTc changes were not significantly different between all antipsychotics. The commonest surrogate marker for a pro-arrhythmic state is the QTc interval. However, interpretation is complex as there is considerable variability due to environmental and biological factors. In pragmatic terms, the risk of sudden death is low as a cause of death! In the Zodiac study that used a mortality endpoint and followed 18 000 subjects on ziprasidone or olanzapine for one year, there were only five cases of sudden death [70], with no significant difference between groups. A recent retrospective observational study published in the NEJM, however, draws attention again to the potential risk of sudden death in users of antipsychotics (for any indication) and reports no significant differences
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between patients treated with typical and atypical antipsychotics, but that rates are increased over the general population with adjusted incident rate ratios (IRR) of 1.99 and 2.26, respectively [57,86] and the increased risk was doserelated. Using incidence rates, the potential risk of sudden death is 2.9 events per 1000 patient-years, which is contextualised by a rate of 6.8 events per 1000 patient-years for agranulocytosis associated with clozapine and a death rate for such agranulocytosis of only 0.2 per 1000 person-years. ECG monitoring for all antipsychotics at baseline and repeated afterwards to seek for QTc prolongation is advised by the authors of the NEJM publication [86,87]. Some caveats should be noted though. First, the event rate increased from 0.47 per 1000 patient years in the 30–34 age cohorts up to 4.76 per 1000 patient years in the 70–74 years cohort. Second, only half the cohort had diagnoses of schizophrenia or bipolar disorder, with 48% having major depression or a mood disorder. Lastly, the unadjusted rate of sudden cardiac death was almost twice as high for men than women (2.71 vs. 1.29), which is not explained by the observation that female sex is the common risk factor for TdP [88]. It may be too early to conclude that ECG monitoring should be advised, based on data from predominantly off-label usage either dose or indication. With regards to cardiac safety monitoring, there is debate as to the value of routine QTc measurement. However, a pilot service evaluation reported that routine ECG, though not helpful for QTc diagnostic purposes, did measure a number of potentially important ECG abnormalities [89]. Treatment emergent TdP is usually associated with multiple risk factors [90] with 71% of patients having two or more risk factors, including structural problems and electrolyte disturbances. Awareness of concomitant drugs associated with QT prolongation may be critical. Female sex would also seem to be the most common risk factor for TdP [88].
Recommended monitoring for antipsychotics The monitoring advice in each antipsychotic SPC or drug label should be followed. A number of individual consensus groups or bodies have in addition put forward their suggestions. In addition to the routine ongoing monitoring suggested, specific for antipsychotics: . It has been suggested by a UK consensus group on prolactin to perform [104] prolactin tests at one month in all patients on an antipsychotic. A normal level then requires further prolactin levels only if symptoms relating to hyperprolactinaemia develop or there is a medication change. Abnormal levels require further monitoring and investigation dependent on prolactin level. A FH of breast cancer and a history of breast cancer in the patient should be asked about; . ECG if identified risk factors for QTc prolongation are present [2].
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Thyroid function and bipolar disorder A number of studies have reported that adverse levels of free thyroxine index (FTI) and higher levels of TSH are associated with a slower response and longer remission time [91]; with remission being seen 4 months earlier with normal thyroid function. The association of lithium with thyroid dysfunction is well established. Fagiolini has followed a cohort of bipolar 1 patients given lithium, and over two years of maintenance treatment, thyroid abnormalities were detected in 38% [92]. These patients had more severe depression and longer acute treatment phases. Low thyroid function thus has an adverse effect on bipolar disorder and in particular bipolar depression. Spontaneous hypothyroidism is not uncommon in a general population, with an incidence in a 20-year longitudinal study of 0.35% females and 0.06% males and has a strong associated with other autoantibody related illness [28]. In longer-term lithium treatment, significantly higher incidence rates have been observed, 2.3% in females and 0.7% males [29]. Thyroid function tests may transiently alter during initiation of lithium and in acute illness and thus test repetition may be required to confirm any diagnosis.
Current monitoring guidelines No current guideline devotes itself to bipolar safety monitoring. Many guidelines incorporate some guidance for monitoring the various safety aspects of antipsychotics and vary in the extent of testing suggested [2–4]. In general terms, the metabolic guidance is similar with various baseline tests but differs thereafter in frequency for certain tests. The largest variance is in lipid testing, which ranges from six-monthly to five-yearly. Most guidelines, but not all, specify fasting samples. For anticonvulsants, haematological and LFTs are suggested by all guidelines at baseline, and then generally monthly and finally 6-montly. Similarly for lithium monitoring, there is little variance in the guidance with baseline and longitudinal renal and thyroid monitoring long term. CANMAT guidelines, however, recommend more baseline testing than others (coagulation tests, full biochemical screening). Monitoring becomes complex in bipolar disorder, as patients commonly are taking multiple psychotropic medications. These data derive from naturalistic cohorts and range from 2.9–3.4 psychotropic medications [1]. Monitoring thus becomes more generic as it is likely that medications from multiple classes are being combined and almost all subjects (98%) will be receiving an antipsychotic in many EU countries [1]. Aspects not always covered in monitoring schedules relate more to pragmatics and should opportunities for monitoring be different in different forms of SMI? For example, where should the monitoring be undertaken and by whom? Bipolar patients are more likely to live
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independently than schizophrenia patients, at least in Belgium, and more likely to have a job (32 vs. 10%) [1]. Inappropriate locations and timings for monitoring may be perceived by the patient as either interfering with his ability to work or potentially stigmatizing.
National Screening Committee that evaluates the viability, effectiveness and appropriateness of a screening programme. The authors conclude that such a programme is imperative. despite an absence of current evidence in SMI patients of its cost-effectiveness.
What metabolic tests should be done? Most guidelines on monitoring currently recommend fasting samples for glucose and lipids [2–4]. In SMI patients, obtaining fasting samples is complex and often not feasible. Even in a large study, such as CATIE, less than 50% of intended fasting samples were fasting [51,66]. Guidelines recognize this difficulty and although advising fasting samples if possible acknowledge that non-fasting samples are pragmatically acceptable [93] or make no reference to the precise testing needed [22]. The difficulty of obtaining fasting samples in SMI patients relates predominantly to their outpatient status, cognitive deficits and lifestyle related issues. This is exampled by the need for hospital admission in some studies to ensure fasting status [21]. In a recent 6-month randomized trial in schizophrenia outpatients, despite asking for non-fasting samples, a number of subjects arrived in a fasting state [52]. A clinician cannot be certain a sample is fasting through any biochemical testing and in a trial situation where multiple samples may be measured over a 6-month period, if in an individual subject samples are random and fasting at different time points, this is a confounder that cannot be adjusted for. Such a situation seemed to arise in the CATIE study and led to initial metabolic data that showed different findings when only fasting data was included in analysis. A fasting glucose alone also risks missing post-prandial glucose elevation, which in some patients is the earliest presentation of DM [96]. The sensitivity and specificity of single random and fasting samples differ little [93]. The reality is if a random sample suggests glucose abnormality then fasting samples and more complex testing such as glucose tolerance test (OGTT) can be undertaken if required [93,96]. A diagnosis of DM can be made on random samples alone, in particular if accompanied by clinical symptoms [93,96]. Fasting lipids remain in many cases the ideal sample; however, some recent data has suggested that non-fasting triglycerides may be superior to fasting in prediction of major CVD related events, as subjects are in a non-fasting state most of the day [94,95]. Pragmatism thus suggests that non-fasting samples can be undertaken in subjects with a relevant history regarding food intake which, if abnormal, can then be confirmed with testing in a fasting status. It can be noted that difficulties with obtaining fasting samples may not be applicable in all regions, exampled by the ease of such testing in Belgium. The option of screening for CVD risk factors and DM in an SMI population has been critically appraised by Holt and Peveler [96]. using a set of 19 criteria developed by the UK
Topical debates for years to come 1 Do females require extra monitoring? The data is not finite but the suggestion is there that obesity is greater in bipolar females and this is accompanied by increased visceral fat. Insulin resistance may have a greater role to play than in males and may be present in the treatment na€ıve state. In addition, menstrual abnormalities are more common but the aetiology for these is not totally clear but may involve increased prevalence of PCOS combined with an increased incidence in patients treated with antipsychotics. There is no evidence that increased monitoring will provide. Future research should determine any potential for gender specific medication strategies. 2 Is there a case for routine statin usage in all bipolar patients? The CATIE study demonstrated a great deal of metabolic dysfunction in both undiagnosed and untreated, even when diagnosed [8]. There certainly would be a good case to propose clinical studies in which cohorts routinely received statins and were followed over many years. Data is emerging in SMI subjects that statins can significantly improve severe dyslipidaemias [97]. Many chronic SMI patients have dyslipidaemias and although some evidence is emerging that total cholesterol elevations associated with antipsychotics may not be persistent [76], this should not be confused with the fact that even at baseline lipids are elevated. The olanzapine label states that nonfasting cholesterol did not increase further after 4–6 months in patients who completed 12 months of treatment. In the EUFEST first-episode schizophrenia study, at least 23% of subjects had dyslipidaemia at baseline in a treatment-na€ıve state [50].
Can safety monitoring for CVD risk factors improve? Many factors may be relevant. The awareness of the problem is crucial [22]. A quality improvement programme implemented in the Unitrf Kingdom and audited after one year reported significantly increased rates for screening of each component of the metabolic syndrome (Table 5) [98].
Can wellness programmes in bipolar illness decrease CVD risk? Over the last five years, there have been various lifestyle and weight management programmes for patients with SMI. Mainly these have been either short-term controlled trials or
Bipolar Disorder and Safety Monitoring for Clinicians
longer-term naturalistic programmes. These programmes have provided some evidence of benefit; however, the challenge is retaining the patients longer term [99]. The range of programme types is diverse and ranges from a telephone and postal programme, small group weekly sessions to individual longer-term nursing involvement. The longest running of these programmes in Manchester, UK, is a weekly group modular programme with no printed materials and has reported data at four years with encouraging results, although all subjects were self-referred and hence highly motivated [99]. Weight loss was measured in 94% of the subjects and the mean weight loss at programme exit of 6.2 kg compared favourably with that measured in the general population attending commercial weight management programmes for 12 months, 2.1–3.3 kg [99]. Weight loss correlated only with the number of sessions attended and bipolar patients had similar weight loss to those with schizophrenia. The challenge, however, is that 23% of the subjects dropped out in the first 8 weeks and the numbers attending over the four years consecutively showed extensive attrition. An interesting programme in the United States was the telephone and postal programme, which reported a service evaluation in almost 40 000 participants [100]. Most entrants were female, 84% and over 60% were obese (BMI > 30). Over 6 months, the mean weight loss in those completing this programme was almost 3 kg but only 21% of subjects completed the 6-month programme. Diagnostic categories are unknown in this programme but it can be speculated that this type of model may be intuitively helpful for higher functioning bipolar patients and relevant in that it attracted predominantly obese females [100]. The most frequent described model is the small group setting, such as used by Pendlebury et al., and it can further be speculated that such models provide psychotherapeutic group therapy benefits in addition to weight and lifestyle. The most complex models involve ongoing 1-to-1 interactions with nursing staff and give more attention to other CVD risk factors, in particular exercise. Over a two-year period, the Well-Being Support Programme (WSP) in 1000 UK SMI patients retained 80% of patients and achieved encouraging results. Significant reductions in CVD risk factors and marked increase in physical activity levels were maintained over the two-year programme [9]. Evidence is also emerging that these programmes may also improve metabolic parameters. Menza et al. reported a reduction in glycosylated haemoglobin over one year from 5.35–5.11 % (n ¼ 31; p ¼ 0.001) [101]. Mauri et al. reported significant reductions in fasting insulin levels, insulin resistance and improvement in insulin sensitivity in an olanzapine case series of 49 subjects predominantly with bipolar disorder, who were randomized to a psycho-educational programme for weight loss for either 12 or 24 weeks [102]. A review of the literature is supportive that there are no adverse effects from these programmes and the regular
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utilization may lead to patient benefits. Recent data is also supportive that such interventions are acceptable and may be effective in acutely unwell inpatients [103].
Implications for future monitoring and clinical research Until psychiatry fully moves to the medical model and provides relevant endpoint data (mortality, CVD events and reduction in new cases of DM) it is speculative as to the cost-effectiveness of safety monitoring that we can consider as multiple screening programmes. Future clinical research and audit should determine necessity, frequency and cost-effectiveness of screening the SMI population. This will also answer the question as to who should screen and take initial action. Screening itself is of little value without subsequent action. Does secondary care have the clinical acumen and facilities to provide such screening? Within the overall bipolar cohorts it needs to be determined if there are specific groups at elevated risks who would benefit from more intensive or a different safety monitoring programme. Some research suggests that women with bipolar disorder have multiple reasons to have greater insulin resistance [13].
Summary The increasing attention given to the safety monitoring of bipolar patients and the rapid understanding of our knowledge of the physical health issues in these subjects, combined with the observation that such safety monitoring encompasses more than the monitoring of and minimization of treatment-emergent adverse events, should lead to the implementation of safety monitoring as a standard component of bipolar care. Further steps are needed to establish the primary providers of safety monitoring and there should be recognition that these may be countryspecific, reflecting different patterns of health care. The observation that there is genetic comorbidity with illnesses such as DM may help research efforts to identify genetic targets for prevention and treatment strategies of bipolar disorder through the next decade. Future research should also establish whether we are correct for safety monitoring to consider bipolar disorder as a single entity.
Declaration of interest CB is an employee of Eli-Lilly.
Disclosure MT is a former employee of Eli Lilly & Co. (1997–2008) and spouse current employee and stockholder.
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References 1. van Winkel, R., De Hert, M., Van Eyck, D. et al. (2008) Peuskens. Prevalence of diabetes and the metabolic syndrome in a sample of patients with bipolar disorder. J. Bipolar Disord., 10 (2), 342. 2. National Institute for Health, Clinical Excellence (NICE) (2006) Bipolar disorder. The management of bipolar disorder in adults, children and adolescents, in primary and secondary care. NICE clinical guideline 38 [cited 2009 March 14]; Available from: www.nice.org.uk/CG038. 3. American Psychiatric Association (2002) Practice guideline for the treatment of patients with bipolar disorder (revision). Am. J. Psychiatry, 159, 1–50. 4. Yatham, L.N., Kennedy, S.H., ODonovan, C. et al. (2006). Canadian Network for Mood and Anxiety Treatments (CANMAT) guidelines for the management of patients with bipolar disorder: update 2007. Bipolar Disord., 8, 721–739. 5. Guideline on risk management systems for medicinal products for human use. CHMP. http://www.emea.europa. eu/pdfs/human/euleg/9626805en.pdf (accessed 19 July 2009). 6. Dalton, S.O., Mellemkjaer, L., Thomassen, L. et al. (2005) Risk for cancer in a cohort of patients hospitalized for schizophrenia in Denmark, 1969–1993. Schizophr. Res., 75 (2–3), 315–324. 7. Smith, S., Yeomans, D., Bushe, C.J. et al. (2007) A well-being programme in severe mental illness. Baseline findings in a UK cohort. Int. J. Clin. Pract., 61 (12), 1971–1978. 8. McEvoy, J., Meyer, M., Goff, D. et al. (2005) Prevalence of the metabolic syndrome in patients with schizophrenia: baseline results from the Clinical Antipsychotic Trials of Intervention Effectiveness (CATIE) schizophrenia trial and comparison with national estimates from NHANES III. Schizophr. Res., 80, 19–32. 9. Smith, S., Yeomans, D., Bushe, C.J. et al. (2007) A well-being programme in severe mental illness. Reducing risk for physical ill-health: a post-programme service evaluation at 2 years. Eur. Psychiatry, 22, 413–418. 10. Fagiolini, A., Frank, E., Scott, J.A. et al. (2005) Metabolic syndrome in bipolar disorder: findings from the Bipolar Disorder Center for Pennsylvanians. Bipolar Disord., 7 (5), 424–430. 11. Bushe, C. (2009) Glucose abnormalities in Schizophrenia, Bipolar and Major Depressive disorders, in Metabolic Effects of Psychotropic Drugs, 26 (eds J. Thakore and B.E. Leonard), Karger, pp. 47–65. 12. Bushe, C.J. and Leonard, B.E. (2007) Blood glucose and schizophrenia: a systematic review of prospective randomized clinical trials. J. Clin. Psychiatry, 68, 1682–1690. 13. Vemuri, M., Stemmle, P., Jiang, B. et al. (2009) Insulin resistance in bipolar women; effects of mood-stabilising drugs, in Metabolic Effects of Psychotropic Drugs, 26 (eds J. Thakore B.E., Leonard), Karger, pp. 12–24. 14. Susce, M.T., Villanueva, N., Diaz, F.J. et al. (2005) Obesity and associated complications in patients with severe mental illnesses: a cross-sectional survey. J. Clin. Psychiatry, 66 (2), 167–173.
15. Regenold, W.T., Thapar, R.K., Marano, C. et al. (2002) J Increased prevalence of type 2 diabetes mellitus among psychiatric inpatients with bipolar I affective and schizoaffective disorders independent of psychotropic drug use. Affect. Disord., 70 (1), 19–26; Erratum in: J Affect Disord. 2003; Feb 73 (3) 301–302. 16. Bushe, C. and Leonard, B. (2004) Association between atypical antipsychotic agents and type 2 diabetes: review of prospective clinical data. Br. J. Psychiatry, 47 (Suppl.), S87–S93. 17. Ormerod, S., McDowell, S.E., Coleman, J.J. and Ferner, R.E. (2008) Ethnic differences in the risks of adverse reactions to drugs used in the treatment of psychoses and depression: a systematic review and meta-analysis. Drug Saf., 31 (7), 597–607. 18. Wang, P.W., Sachs, G.S., Zarate, C.A. et al. (2006) Overweight and obesity in bipolar disorders. J. Psychiatr. Res., 40 (8), 762–764. 19. Garcia-Portilla, M.P., Saiz, P.A., Benabarre, A. et al. (2008) The prevalence of metabolic syndrome in patients with bipolar disorder. Affect. Disord., 106 (1–2), 197–201. 20. Yumru, M., Savas, H.A., Kurt, E. et al. (2007) Atypical antipsychotics related metabolic syndrome in bipolar patients. J. Affect. Disord., 98 (3), 247–252. 21. Paton, C., Esop, R., Young, C. and Taylor, D. (2004) Obesity, dyslipidaemias and smoking in an inpatient population treated with antipsychotic drugs. Acta Psychiatr. Scand., 110, 299–305. 22. Barnes, T.R., Paton, C., Cavanagh, M.R. et al. (2007) UK Prescribing Observatory for Mental Health. A UK audit of screening for the metabolic side effects of antipsychotics in community patients. Schizophr. Bull., 33 (6), 1397–1403. 23. National Institute for Health, Clinical Excellence (2008) Lipid Modification: Cardiovascular Risk Assessment and the Modification of Blood Lipids for the Primary and Secondary Prevention of Cardiovascular Disease. NICE Clinical Guideline 67, National Institute for Health and Clinical Excellence, London. 24. Bauer, M., Lecrubier, Y. and Suppes, T. (2008) Awareness of metabolic concerns in patients with bipolar disorder: a survey of European psychiatrists. Eur. Psychiatry, 23 (3), 169–177. 25. Bendz, H., Aurell, M., Balldin, J. et al. (1994) Kidney damage in long-term lithium patients: a cross-sectional study of patients with 15 years or more on lithium. Nephrol. Dial Transplant, 9, 1250–1254. 26. Boton, R., Gaviria, M. and Batlle, D.C. (1987) Prevalence, pathogenesis, and treatment of renal dysfunction associated with chronic lithium therapy. Am. J. Kidney Dis., 10, 329–345. 27. Thompson, C.J., France, A.J. and Baylis, P.H. (1997) Persistent nephrogenic diabetes insipidus following lithium therapy. Scott. Med. J., 42, 16–17. 28. Vanderpump, M.P., Tunbridge, W.M., French, J.M. et al. (1995) The incidence of thyroid disorders in the community: a twenty-year follow-up of the Whickham Survey. Clin. Endocrinol. (Oxf.), 43, 55–68.
Bipolar Disorder and Safety Monitoring for Clinicians 29. Johnston, A.M. and Eagles, J.M. (1999) Lithium-associated clinical hypothyroidism. Prevalence and risk factors. Br. J. Psychiatry, 175, 336–339. 30. Bendz, H., Sjodin, I., Toss, G. and Berglund, K. (1996) Hyperparathyroidism and long-term lithium therapy–a cross-sectional study and the effect of lithium withdrawal. J. Intern. Med., 240, 357–365. 31. Sachs, G., Bowden, C., Calabrese, J.R. et al. (2006) Effects of lamotrigine and lithium on body weight during maintenance treatment of bipolar I disorder. Bipolar Disord., 8, 175–181. 32. Tohen, M., Greil, W., Calabrese, J.R. et al. (2005) Olanzapine versus lithium in the maintenance treatment of bipolar disorder: a 12-month, randomized, double-blind, controlled clinical trial. Am. J. Psychiatry, 162 (7), 1281–1290. 33. Callaghan, N., Majeed, T., OConnell, A. and Oliveira, D.B. (1994) A comparative study of serum F protein and other liver function tests as an index of hepatocellular damage in epileptic patients. Acta Neurol. Scand., 89, 237–241. 34. Wolf, R., Matz, H., Marcos, B. and Orion, E. (2005) Drug rash with eosinophilia and systemic symptoms vs toxic epidermal necrolysis: the dilemma of classification. Clin. Dermatol., 23, 311–314. 35. Dong, X., Leppik, I.E., White, J. and Rarick, J. (2005) Hyponatremia from oxcarbazepine and carbamazepine. Neurology, 65, 1976–1978. 36. Tohen, M., Castillo, J., Baldessarini, R.J. et al. (1995) Blood dyscrasias with carbamazepine and valproate: a pharmacoepidemiological study of 2,228 patients at risk. Am. J. Psychiatry, 152, 413–418. 37. Powell-Jackson, P.R., Tredger, J.M. and Williams, R. (1984) Hepatotoxicity to sodium valproate: a review. Gut., 25, 673–681. 38. Petty, S.J., OBrien, T.J. and Wark, J.D. (2007) Anti-epileptic medication and bone health. Osteoporos Int., 18, 129–142. 39. Bowden, C.L., Calabrese, J.R., McElroy, S.L. et al. (2000) A randomized, placebo-controlled 12-month trial of divalproex and lithium in treatment of outpatients with bipolar I disorder. Divalproex Maintenance Study Group. Arch. Gen. Psychiatry, 57, 481–489. 40. Tohen, M., Ketter, T.A., Zarate, C.A. et al. (2003) Olanzapine versus divalproex sodium for the treatment of acute mania and maintenance of remission: a 47-week study. Am. J. Psychiatry, 160, 1263–1271. 41. Joffe, H., Cohen, L.S., Suppes, T. et al. (2006) Valproate is associated with new-onset oligoamenorrhea with hyperandrogenism in women with bipolar disorder. Biol. Psychiatry, 59 (11), 1078–1086. 42. ODonovan, C., Kusumakar, V., Graves, G.R. and Bird, D.C. (2002) Menstrual abnormalities and polycystic ovary syndrome in women taking valproate for bipolar mood disorder. J. Clin. Psychiatry, 63 (4), 322–330. 43. Calabrese, J.R., Sullivan, J.R., Bowden, C.L. et al. (2002) Rash in multicenter trials of lamotrigine in mood disorders: clinical relevance and management. J. Clin. Psychiatry, 63, 1012–1019. 44. Bowden, C.L., Asnis, G.M., Ginsberg, L.D. et al. (2004) Safety and tolerability of lamotrigine for bipolar disorder. Drug Saf., 27, 173–218.
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45. Guberman, A.H., Besag, F.M., Brodie, M.J. et al. (1999) Lamotrigine-associated rash: risk/benefit considerations in adults and children. Epilepsia, 40, 985–991. 46. Mockenhaupt, M., Messenheimer, J., Tennis, P. and Schlingmann, J. (2005) Risk of Stevens-Johnson syndrome and toxic epidermal necrolysis in new users of antiepileptics. Neurology, 64, 1134–1138. 47. Ketter, T.A., Brooks, J.O., Hoblyn, J.C. et al. (2008) Effectiveness of lamotrigine in bipolar disorder in a clinical setting. J. Psychiatr. Res., 43 (1), 13–23. 48. LItalien, G.J., Casey, D.E., Kan, H.J. et al. (2007) Comparison of metabolic syndrome incidence among schizophrenia patients treated with aripiprazole versus olanzapine or placebo. J. Clin. Psychiatry, 68 (10), 1510–1516. 49. Tohen, M., Sutton, V.K., Calabrese, J.R. et al. (2009) Maintenance of response following stabilization of mixed index episodes with olanzapine monotherapy in a randomized, double-blind, placebo-controlled study of bipolar 1 disorder. J. Affect. Disord., 116 (1–2), 43–50. 50. Kahn, R.S., Fleischhacker, W.W., Boter, H. et al. (2008) Effectiveness of antipsychotic drugs in first-episode schizophrenia and schizophreniform disorder: an open randomised clinical trial. Lancet, 371, 1085–1097. 51. Lieberman, J.A., Stroup, T.S., McEvoy, J.P. et al. (2005) Effectiveness of antipsychotic drugs in patients with chronic schizophrenia. N. Engl. J. Med., 353 (12), 1209–1223. 52. Bushe, C., Sniadecki, J., Bradley, A. and Poole Hoffmann, V. (2009) Comparison of metabolic and prolactin variables from a six-month randomised trial of olanzapine and quetiapine in schizophrenia. J. Psychopharmacol., Feb 24. [Epub ahead of print]. PMID: 19240085. 53. Tohen, M. et al. (2006) Randomized, Placebo-Controlled Trial of Olanzapine as Maintenance Therapy in Patients With Bipolar I Disorder Responding to Acute Treatment With Olanzapine. 54. Niufan, G., Tohen, M., Qiuqing, A. et al. (2008) Olanzapine versus lithium in the acute treatment of bipolar mania: a double-blind, randomized, controlled trial. J. Affect. Disord., 105 (1–3), 101–108. 55. Tohen, M. et al. (2000) Efficacy of olanzapine in acute bipolar mania. a double blind placebo controlled study. Arch. Gen. Psychiatry, 57, 841–849. 56. Hennen, J., Perlis, R.H., Sachs, G. et al. (2004) Weight gain during treatment of bipolar I patients with olanzapine. J. Clin. Psychiatry, 65 (12), 1679–1687. 57. Schneeweiss, S. and Avorn, J. (2009) Antipsychotic agents and sudden cardiac death--how should we manage the risk? N. Engl. J. Med., 360 (3), 294–296. 58. Bowden, C.L. et al. (2005) A Randomised, double blind, placebo controlled efficacy and safety study of quetiapine or lithium as monotherapy for mania in bipolar disorder. J. Clin. Psychiatry, 66, 111–121. 59. McIntyre, R.S. et al. (2005) Quetiapine or haloperidol as monotherapy for bipolar mania–a 12-week, double blind, randomised, parallel group, placebo controlled trial. Eur. Neuropsychopharmacol., 15, 573–585. 60. Vieta, E. et al. (2005) Effectiveness of aripiprazole versus haloperidol in acute bipolar mania. Double blind,
382
61.
62.
63.
64.
65.
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randomised, comparative 12 week trial. B. J. Psych., 187, 235–242. Keck, P.E. et al. (2009) Aripiprazole monotherapy in the treatment of acute bipolar i mania: a randomized, doubleblind, placebo and lithium controlled study. J. Affect. Disord., 112 (1–3), 36–49. Thase, M.E. et al. (2008) Aripiprazole monotherapy in nonpsychotic bipolar I depression results of 2 randomized, placebo-controlled studies. J. Clin. Psychopharmacol., 28, 13–20. Smulevich, A.B. et al. (2005) Acute and continuation risperidone monotherapy in bipolar mania: a 3-week placebocontrolled trial followed by a 9-week double-blind trial of risperidone and haloperidol. Eur. Neuropsychopharmacol., 15, 75–84. Neovius, M., Eberhard, J., Lindstr€ om, E. and Levander, S. (2007) Weight development in patients treated with risperidone: a 5-year naturalistic study. Acta Psychiatr. Scand., 115 (4), 277–285. Bushe, C.J. and Leonard, B.E. (2007) Blood glucose and schizophrenia: a systematic review of prospective randomized clinical trials. J. Clin. Psychiatry, 68 (11), 1682–1690. Meyer, J.M., Davis, V.G., Goff, D.C. et al. (2008) Change in metabolic syndrome parameters with antipsychotic treatment in the CATIE Schizophrenia Trial: prospective data from phase 1. Schizophr. Res., 101, 273–286. Stroup, T.S., Lieberman, J.A., McEvoy, J.P. et al. (2009) CATIE Investigators Results of phase 3 of the CATIE schizophrenia trial. Schizophr. Res., 107 (1), 1–12. McEvoy, J.P., Lieberman, J.A., Perkins, D.O. et al. (2007) Efficacy and tolerability of olanzapine, quetiapine and risperidone in the treatment of early psychosis: A randomised, double blind 52 week comparison. Am. J. Psychiatry, 164, 1050–1060. Clinical study D144CC00004 (Nov 2007) A Multicenter, Double-blind, Randomized, Parallel-group, Placebo controlled, Phase III Study of the Efficacy and Safety of Quetiapine Fumarate Sustained-release as Monotherapy in Adult Patients with Acute Bipolar Mania. Strom, B., Faich, G., Eng, S. et al. (2008) Comparative moratility associated with ziprasidone vs olanzapine in real-world use: the ziprasidone observational study of cardiac outcomes (ZODIAC). Schizophr. Res., 98, 160–161. doi: 10.1016/j.schres.2007.12.377 Bushe, C. and Paton, C. (2005) The potential impact of antipsychotics on lipids in schizophrenia: is there enough evidence to confirm a link? J. Psychopharmacol., 19 (6 Suppl), 76–83. Taylor, D., Young, C., Esop, R. et al. (2004) Testing for diabetes in hospitalised patients prescribed antipsychotic drugs. Br. J. Psychiatry, 185, 152–156. Olfson, M., Marcus, S.C., Corey-Lisle, P. et al. (2006) Hyperlipidemia following treatment with antipsychotic medications. Am. J. Psychiatry, 163 (10), 1821–1825. Keck, P.E. et al. (2006) A randomised double blind placebo controlled 26 week trial of aripiprazole in recently manic patients with bipolar 1 disorder. J. Clin. Psychiatry, 67, 626–637.
75. Keck, P.E. et al. (2007) Aripiprazole monotherapy for maintenance treatment in bipolar disorder: a 100 week double blind study versus placebo. J. Clin. Psychiatry, 68, 1480–1491. 76. Daumit, G.L., Goff, D.C., Meyer, J.M. et al. (2008) Antipsychotic effects on estimated 10-year coronary heart disease risk in the CATIE schizophrenia study. Schizophr. Res., 105, 175–187. 77. Hippisley-Cox, J., Vinogradova, Y., Coupland, C. and Parker, C. (2007) Risk of malignancy in patients with schizophrenia or bipolar disorder: nested case-control study. Arch. Gen. Psychiatry, 64 (12), 1368–1376. 78. Werneke, U., Horn, O., Maryon-Davis, A. et al. (2006) Uptake of screening for breast cancer in patients with mental health problems. J. Epidemiol. Community Health, 60 (7), 600–605. 79. Bushe, C., Shaw, M. and Peveler, R. (2008) A review of the association between antipsychotics and hyperprolactinaemia. J. Psychopharm., 22 (2 Suppl), 46–55. 80. Turrone, P., Kapur, S., Seeman, M.V. and Flint, A.J. (2002) Elevation of prolactin levels by atypical antipsychotics. Am. J. Psychiatry, 159 (1), 133–135. 81. Bushe, C. and Shaw, M. (2007) Prevalence of hyperprolactinaemia in a naturalistic cohort of schizophrenia and bipolar outpatients during treatment with typical and atypical antipsychotics. J. Psychopharmacol., 21 (7), 768–773. 82. Johnsen, E., Kroken, R.A., Abaza, M. et al. (2008) Antipsychotic-induced hyperprolactinemia: a cross-sectional survey. J. Clin. Psychopharmacol., 28 (6), 686–690. 83. Tworoger, S.S. and Hankinson, S.E. (2006) Prolactin and breast cancer risk. Cancer Lett., 243, 160–169. 84. Catts, V.S., Catts, S.V., OToole, B.I. and Frost, A.D. (2008) Cancer incidence in patients with schizophrenia and their first-degree relatives – a meta-analysis. Acta Psychiatr. Scand., 117 (5), 323–336. 85. Harrigan, E.P., Miceli, J.J., Anziano, R. et al. (2004) A randomized evaluation of the effects of six antipsychotic agents on QTc, in the absence and presence of metabolic inhibition. J. Clin. Psychopharmacol., 24 (1), 62–69. 86. Ray, W.A., Chung, C.P., Murray, K.T. et al. (2009) Atypical antipsychotic drugs and the risk of sudden cardiac death. N. Engl. J. Med., 360 (3), 225–235. 87. Schneeweiss, S. and Avorn, J. (2009) Antipsychotic agents and sudden cardiac death--how should we manage the risk? N. Engl. J. Med., 360 (3), 294–296. 88. Seeman, M.V. (2008) Prevention inherent in services for women with schizophrenia. Can. J. Psychiatry, 53 (5), 332–341. 89. Bushe, C., ONeil, J., Wood, C. et al. (2007) Physical health monitoring in a scottish cohort of schizophrenia patients – The role of ECG & blood pressure monitoring. Presented at 62nd Annual Convention of the Society of Biological Psychiatry. San Diego May 2007. 90. Justo, D., Prokhorov, V., Heller, K. and Zeltser, D. (2005) Torsade de pointes induced by psychotropic drugs and the prevalence of its risk factors. Acta Psychiatr. Scand., 111 (3), 171–176. 91. Cole, D.P., Thase, M.E., Mallinger, A.G. et al. (2002) Slower treatment response in bipolar depression predicted by lower pretreatment thyroid function. Am. J. Psychiatry, 159, 116–121.
Bipolar Disorder and Safety Monitoring for Clinicians 92. Fagioline, A., Kupfer, D.J., Scott, J. et al. (2006) Hypothyroidism in patients with bipolar 1 disorder treated primarily with lithium. Epidemiol. Psychiatr. Soc., 15, 123–127. 93. Gough, S. and Peveler, R. (2004) Diabetes and its prevention: pragmatic solutions for people with schizophrenia. Br. J. Psychiatry, 47 (Suppl.), S106–S111. 94. Nordestgaard, B.G., Benn, M., Schnohr, P. and TybjaergHansen, A. (2007) Nonfasting triglycerides and risk of myocardial infarction, ischemic heart disease, and death in men and women. JAMA, 298 (3), 299–308. 95. Bansal, S., Buring, J.E., Rifai, N. et al. (2007) Fasting compared with nonfasting triglycerides and risk of cardiovascular events in women. JAMA, 298 (3), 309–316. 96. Holt, R.I.G. (2009) Screening for diabetes and cardiovascular risk factors in people with serious mental illness, in Metabolic Effects of Psychotropic Drugs, 26 (eds J. Thakore and B.E. Leonard), Karger, pp. 66–81. 97. Hanssens, L., De Hert, M., Kalnicka, D. et al. (2007) Pharmacological treatment of severe dyslipidaemia in patients with schizophrenia. Int. Clin. Psychopharmacol., 22 (1), 43–49. 98. Barnes, T.R., Paton, C., Hancock, E. et al. (2008) UK prescribing observatory for mental health. Screening for the metabolic syndrome in community psychiatric patients prescribed antipsychotics: a quality improvement programme. Acta Psychiatr. Scand., 118 (1), 26–33.
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99. Pendlebury, J., Bushe, C.J., Wildgust, H.J. and Holt, R.I. (2007) Long-term maintenance of weight loss in patients with severe mental illness through a behavioural treatment programme in the UK. Acta Psychiatr. Scand., 115 (4), 286–294. 100. Poole Hoffmann, V., Bushe, C., Meyers, A.L. et al. (2008) A wellness intervention program for patients with mental illness: self-reported outcomes. Prim Care Companion J. Clin. Psychiatry, 10 (4), 329–331. 101. Menza, M., Vreeland, B., Minsky, S. et al. (2004) Managing atypical antipsychotic-associated weight gain: 12-month data on a multimodal weight control program. J. Clin. Psychiatry, 65, 471–477. 102. Mauri, M., Castrogiovanni, S., Simoncini, M. et al. (2006) Effects of an educational intervention on weight gain in patients treated with antipsychotics. J. Clin. Psychopharmacol., 26 (5), 462–466. 103. Bushe, C.J., McNamara, D., Haley, C. et al. (2008) Weight management in a cohort of Irish inpatients with serious mental illness (SMI) using a modular behavioural programme. A preliminary service evaluation. BMC Psychiatry, 8, 76. 104. Peveler, R.C., Branford, D., Citrome, L. et al. (2008) Antipsychotics and hyperprolactinaemia: clinical recommendations. J. Psychopharmacol., 22 (2 Suppl), 98–103.
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Somatic Treatments for Bipolar Disorder: ECT, VNS and TMS Mark S. George1,2 1 2
Radiology and Neurosciences Medical University of South Carolina, Charleston, SC USA Ralph H. Johnson VA Medical Centre, Charleston, SC
Introduction to the technologies There are now entire journals devoted to the field of brain stimulation [1], and books devoted to each of the individual techniques [2] as well as in-depth overviews [3]. The interested reader is referred to these. This chapter will focus on a quick and precise introduction to each treatment, with a focus on emerging clinical applications in bipolar disorder (BD). One of the recurring themes within each of the techniques is the currently inadequate understanding of the translational neurobiological effects of the use parameters of electrical stimulation. These are the electrical pulse width, current direction, intensity, frequency, duty cycle and the overall dose as well as dosing scheme. The future of the promising field of brain stimulation will undoubtedly involve better clinical application of the knowledge gained about appropriate use parameters from preclinical cellular and non-human animal studies and human imaging studies.
Electroconvulsive therapy (ECT) The essential ingredient of electroconvulsive therapy (ECT) is the induction of a seizure within specific regions in the brain, likely involving the prefrontal cortex, orbitofrontal cortex and the connections to limbic structures. In 1960, Cronholm and Ottosson established in their classic study that it was the seizure activity that produced the therapeutic response with ECT and not just the electrical activity [4]. They did this by randomly administering an anticonvulsant (lidocaine) to some of the patients. Those that received the lidocaine displayed less seizure activity, required more electrical stimulation and did not respond as well. Clearly, in regards to ECT, the seizure produces the therapeutic effect. However, Sackeim and colleagues showed Bipolar Disorder: Clinical and Neurobiological Foundations Edited by Lakshmi N. Yatham and Mario Maj © 2010 John Wiley & Sons, Ltd. ISBN: 978-0-470-72198-8
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that a generalized seizure, while necessary for the therapeutic effects of ECT, is also insufficient if it is induced in the wrong regions of the brain. For instance, ECT-induced seizures over the parietal cortex do not result in an antidepressant effect [5]. Thus, for ECT to work, there has to be a seizure induced in key mood-regulating circuits involving the prefrontal cortex. Modern ECT, at least in the United States and other industrialized nations, is administered with brief anaesthesia, muscle relaxants and supplemental oxygen. With modern ECT, electricity (alternating current) is stored and released through the ECT device. The electrical pulse from the device is commonly a brief pulse (milliseconds). More recent work with ultrabrief pulse has reduced the width of this signal even further, to where it now approaches chronaxie, that is the minimum width needed to cause an action potential in a nerve [6]. Right unilateral ultrabrief ECT is a new method that is rapidly gaining acceptance, as it has similar efficacy to brief pulse ECT but has reduced cognitive side effects. The current is passed through electrodes on the scalp, inducing a seizure. With ECT, sufficient stimulation is needed to produce an effect, but too much energy used to induce a seizure can increase the rate of adverse events. One variable that presents a greater problem with ECT is resistance. The scalp and particularly the skull impede the flow of electricity to the brain. As mentioned above, the placement of the electrodes on the head has a significant effect on the outcome, both in terms of efficacy and side effects. The two most commonly used positions are bilateral and unilateral. Bilateral is more widely used, presumably due to increased efficacy. However, bilateral ECT is also associated with greater cognitive side effects. Sackeim et al. showed that unilateral ECT requires greater electrical stimulation to have similar efficacy, but can still have less side effects [7]. ECT has several important clinical roles in the treatment and management of BD. It is the most effective acute antidepressant for patients with BD, while also being an effective antimanic treatment.
Somatic Treatments
With respect to treating the depressive phase of BD, most studies suggest that ECT is less effective in treating depressed bipolar as compared to unipolar patients, but that it is still more effective than any other treatment. For example, Medda and colleagues treated 130 depressive patients (17 with Major Depression (UP), 67 with bipolar disorder II (BP II) and 46 with bipolar disorder I (BP I)) with bilateral ECT, on a twice-a-week schedule [8]. The patients were assessed before (baseline) and a week after the ECT course (final score), using the Hamilton Rating Scale for Depression (HAM-D), Young Mania Rating Scale (YMRS), Brief Psychiatric Rating Scale (BPRS) and the Clinical Global Improvement (CGI) scale. All three groups (UP, BP II, BP I) showed a significant improvement after the ECT course. Concerning depressive symptomatology, the remission rate (HAM-D <8) was respectively 70% for UP, 57% for BP II and 65% for BP I. The best results were achieved by UP patients, while the BP I group showed the worst results, with a lower remission rate and higher scores in YMRS and BPRS psychotic cluster at the final evaluation. ECT is thus a viable option for the treatment of both unipolar and bipolar depressive patients resistant to pharmacological treatment. BP I patients tended to exhibit residual manic and psychotic symptomatology. In contrast, Bailine and colleagues recently found there was no difference in antidepressant response between BP and UP depressed patients [9]. Patients referred for ECT with both UP and BP depressions were included in a multisite collaborative, double-masked, randomized controlled trial of three electrode placements – right unilateral, bifrontal or bitemporal – in a permutated block randomization scheme. Of 220 patients, 170 patients (77.3%) were classified as UP and 50 (22.7%) as BP depression in the intent-to-treat sample. The remission and response rates and numbers of ECT for both groups were equivalent. This study suggested that both UP and BP depressions remit with ECT. Polarity is not a factor in the response rate. In addition, in this sample ECT did not precipitate mania in depressed patients nor have a quicker onset of action. However, most studies do suggest that patients with bipolar depression tend to show more rapid clinical improvement with ECT than do patients with unipolar depression [10]. ECT can also be used to treat the manic phase of BD, with effective and rapid success. Several recent studies suggest ECT may also be effective with mixed states [11]. One of the main drawbacks of ECT is the relatively high relapse rate after a successful course, even with maintenance medications [12]. For example, a recent study found that 6 months after achieving remission with ECT, only 46% were still remitted even if they took medications or had continuation ECT. This high and relatively rapid relapse rate makes the use of ECT in the chronic management of BD a challenge.
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Vagus nerve stimulation (VNS) The idea of stimulating the vagus nerve in order to modify central brain activity has been pursued for over 100 years. However, it was not until the mid-1980s that methods became available to efficiently stimulate the vagus in man and animals.
Description of method Although one can stimulate the vagus in several different ways, even transcutaneously, for all intents and purposes, vagus nerve stimulation in the modern literature refers to a technique where a surgeon or researcher wraps a unidirectional wire around the vagus nerve in the neck. This wire is then connected to a subcutaneous, battery operated, generator which is implanted in the left chest wall and intermittently sends an electrical current through the wire and thus through the nerve, which then conveys the impulse up into the brainstem [13]. VNS implantation is usually an outpatient procedure in the United States, typically preformed by neurosurgeons. The battery in the device generates an intermittent electrical stimulation that is delivered to the vagus nerve. Clinicians following the patient control the frequency and intensity of the stimulation. Adjustments to the stimulation parameters are transmitted from a computer to the VNS device by a handheld infrared wand placed over the device. The wire connecting around the nerve is directional, and this unidirectional feature likely helps minimize efferent side effects. However, it is likely that at least some patients have had the leads reversed, without noticeable harm. The vagus nerve is actually a large nerve bundle, composed of different sized nerves (both unmyelinated and myelinated). The vagus nerve is thus a complex structure and the current form of VNS is imprecise with respect to activating discrete nerves within the bundle. Microsurgical techniques might theoretically allow for more focal VNS.
Putative mechanisms of action To refresh, the vagus nerve (tenth cranial nerve) emerges from the brain at the medulla. It is the longest cranial nerve extending intothechestandabdominalcavity.Vagus comes from the Latin word for wandering, and this nerve is remarkably complex, both in where it comes from, and the variety of information it passes to and from the brain to the viscera. Traditionally, the vagus nerve has been conceptualized as modulating the parasympathetic tone of the internal organs (efferent functions). However, 80% of the signals travelling through the vagus nerve actually go from the organs back into the brain (afferent) [14]. In 1938, Bailey and Bremer [15] stimulated the vagus nerve of cats and reported that this synchronized the
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electrical activity in the orbital cortex. In 1949, Paul MacLean and Karl Pribram carried out similar studies with anesthetized monkeys. Using an electroencephalogram (EEG), they found VNS generated slow waves over the lateral frontal cortex. The afferent fibres travelling in the vagus terminate in the Nucleus of the Solitary Tract (NTS) and then many travel through the Locus Coeruleus (LC). They eventually terminate in the orbitofrontal cortex and the insula, in somatotopically defined regions. Simplistically, many of the vagus afferents connect transynaptically to areas of the limbic brain that regulate emotion. It is no surprise then that when we grieve we have the perception of having a broken heart, or feeling like there are butterflies on our stomach when we are nervous or anxious. This misplacement concerning the source of the sensory signal likely occurs because the vagus cardiac fibres terminate in brain regions where the limbic system and gut sensations overlap. Jake Zabara, in the mid-1980s, was perhaps the first to demonstrate convincingly the therapeutic benefits of VNS, although many had been considering this avenue before Zabara [16]. Zabara discovered in a canine model of epilepsy (strychnine-induced) that repetitive electrical stimulation of the vagus nerve was able to acutely terminate a motor seizure. Importantly, he also found that the anticonvulsant benefits could outlast the period of stimulation by a factor of four. Constant stimulation was not required for enduring anticonvulsive effects.
Safety The adverse events associated with VNS fall into two categories – those associated with the complications of the surgery and those resulting from the side effects of stimulation. The risks associated with surgery are minimal [17]. Wound infections are infrequent (<3%) and managed with antibiotics. Pain at the surgical site almost always resolves within two weeks. Rarely left vocal cord paresis persists after surgery (<1 in 1000), but usually resolves slowly over the ensuing weeks. Temporary asystole during the initial testing of the device is a rare but serious surgical complication. In approximately 1 out of 1000 cases, asystole has been reported in the operating room during initial lead testing. It may be a result of aberrant electrical stimulation resulting from poor haemostatic control. That is, blood in the surgical field causes arcing of the current and the cardiac branch gets depolarized. Fortunately, no deaths have been reported, as normal cardiac rhythm has always been restored. Postoperatively, these patients have been able to safely use VNS. More importantly and surprisingly, given the known efferent VNS effects, no cardiac events have been reported when the device is turned on for the first time after surgery. The most common side effects associated with stimulation are hoarseness, dyspnoea and cough. They are dose
dependent and correlate with stimulation intensity and can be minimized with reductions in the stimulation parameters. Interestingly, most side effects decrease with time. Hoarseness or voice alteration is the most persistent problem. Between 30 and 60% continue to experience this side effect during times of stimulation, although for reasons that are unclear this also diminishes over months to years. One would speculate that VNS might induce a parasympathetic response. However, this has been aggressively monitored and has not been an issue. Because of the cost and invasive nature of VNS, there have been no human studies in healthy adults. However, studies in patients with epilepsy or depression implanted with VNS have revealed that VNS causes discrete changes in limbic structures, including the cingulate gyrus, the hippocampus and the insula [18–22]. The specific network activated depends on the choice of the use parameters, suggesting that with more extensive knowledge one could direct the VNS signal within groups of patients or even individually. These regional changes evolve over time and vary with clinical response. In addition, VNS produces interesting improvements in cognition, perhaps linked to its noradrenaline activity [23]. CSF studies have found changes in serotonin and noradrenaline metabolites. The animal studies to date have been more extensive, although progress in this area was slowed by the lack of small portable generators. Now that these are available for rats, VNS studies have shown the importance of the LC in the signal propagation, and have also revealed longterm changes in raphe firing, unlike serotonin acting medications.
Clinical studies The first self-contained devices were implanted in humans in 1988 in patients with intractable, medically unresponsive epilepsy. Results were positive in two large acute double-blind controlled studies of VNS in patients with treatment-resistant epilepsy [24,25]. Low dose stimulation (intensity, number of pulses per day) served as the control in comparison to high stimulation. In this difficult to treat population, seizure frequency decreased 28–31% in the high stimulation group compared to baseline, while only dropping 11–15% in the low stimulation group. Unfortunately, few patients are able to stop their anticonvulsant medications, although many are able to reduce the number of daily medications. This is clinically important in childhood epilepsy, as many children experience deleterious cognitive side effects from the anticonvulsants. Long-term follow-up studies have shown that the time course to respond to VNS is gradual, with continued improvement up to one year and then stabilization of effect. There appears to be no tolerance to VNS. The patient with the longest exposure to VNS has had the system operating
Somatic Treatments
for 20 years. VNS has assumed a small but significant role in epilepsy practice for those patients who have tried and failed two anticonvulsants. VNS became available for use in Europe in 1994 and was given an FDA indication for epilepsy in the United States in 1997. In 1997, the author (MSG), along with John Rush, Harold Sackeim and later Lauren Marangell, began an initial pilot study of VNS for patients with treatment resistant depression. Several lines of evidence suggested that VNS might be helpful in patients with depression, including anecdotal reports of mood improvement in VNS implanted epilepsy patients and functional imaging studies demonstrating that VNS increased activity in several regions of the brain thought to be involved with depression [26]. This open-label study with 59 patients with treatment resistant depression demonstrated good results – 30% response rate and 15% remission rate at 10 weeks [27]. Even more encouraging were the extended results [28]. Patients continued to improve long after the acute phase of the trial. Patients were clinically better at one year than they were at three months. This pattern is unusual in the treatment of depression, especially in a difficult to treat cohort with prior tolerance to antidepressants. A recent European trial found slightly better results, but with the same side effects and time course of response [29]. A pivotal multi-centred, randomized, double-blinded trial of VNS was not as encouraging. In this trial, active VNS failed to statistically separate from sham treatment [30,31]. The response rates for the acute treatment of treatment-resistant depression were 15% for active treatment and 10% for sham treatment. A parallel but nonrandomized group was also studied and compared to those patients who received VNS in the pivotal trial above [32]. Thus one group received the addition of VNS and the other received treatment as usual. They were followed for 12 months, during which time both groups received similar treatment (medications or ECT) except for the VNS difference. At the end point the response rates were significantly different: 27% for the VNS group and 13% for the treatment as usual group. The FDA considered all these studies when evaluating VNS for depression. They were most impressed with the long-term enduring benefits for this difficult to treat population. In 2005 they approved VNS for patients with chronic or recurrent depression, either unipolar or bipolar, with a history of failing to respond to at least four antidepressant trials. Because VNS is FDA approved for TRD in the absence of Class I evidence of efficacy, insurance companies have resisted reimbursing the implant. Thus, currently VNS is not making a large clinical impact and the field awaits a much-needed prospective randomized controlled trial, which unfortunately has not been started due to financial concerns on the part of the manufacturer.
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Importantly for all of these VNS depression studies, bipolar depression patients were included, and there were no differences in outcome between bipolar patients and unipolar patients. However, BD was not studied uniquely. In contrast, there has been one small study directly addressing VNS in bipolar patients. Marangell and colleagues treated nine outpatients with a DSM-IV-TR diagnosis of treatment-resistant rapid-cycling bipolar disorder (RCBD) for 40 weeks with open-label VNS [33]. Patients recorded their depression and mania mood symptoms on a daily basis throughout the study using the National Institute of Mental Health prospective life charting methodology and daily mood ratings. Patients were assessed every two weeks during the two-month baseline period before device activation, every two weeks for the remaining 40 weeks of the study, and at the end of the study with the 24-item HAM-D (HAM-D-24), the 10-item Montgomery-Asberg Depression Rating Scale (MADRS), the YMRS), the CGI scale, the Global Assessment of Functioning (GAF) scale and the 30-item Inventory of Depressive Symptomatology Self-Report (IDS-SR-30). Any adverse events or device complications were also recorded at each visit. The prospective life charts were analysed by calculating the area under the curve. Over the 12-month study period, VNS was associated with a 38% mean improvement in overall illness as compared to baseline, as well as significant reductions in symptoms as measured by the HAM-D-24, MADRS, CGI and GAF rating scales. Common adverse events were voice alteration during stimulation and hoarseness. These long-term open-label data suggest that VNS may be an efficacious and well-tolerated treatment option for treatment-resistant rapid-cycling bipolar patients. There are several other potential VNS clinical applications, reasoning from the known role of the vagus, including obesity, craving, pain and anxiety. Small sample size trials all suggest potential efficacy in these domains but randomized controlled trials are needed and none of these diseases are FDA approved for using VNS.
Transcranial magnetic stimulation (TMS) Transcranial magnetic stimulation (TMS) involves inducing an electrical current within the brain using pulsating magnetic fields that are generated outside the brain near the scalp [2,34,35]. TMS is not simply applying a static or constant magnetic field to the brain. By 1820 scientists had discovered that passing an electric current though a wire induces a magnetic field. In 1832, Michael Faraday demonstrated that the inverse was also true – passing a wire through a magnetic field generates an electrical current [36]. Thus a changing magnetic field can generate electrical current in nearby wires, nerves or muscles. A static magnet will not generate a current. For most TMS applications, it likely is the electricity induced from the pulsating magnet,
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and not the magnetic field itself, which produces neurobiological effects. In 1959, Kolin and his colleagues demonstrated that a fluctuating magnetic field could stimulate a peripheral frog muscle in preparation [37]. However, it was not until 1985 that the modern era of TMS started. That year, Anthony Baker in Sheffield, England described the use of a noninvasive magnetic device resembling modern TMS instruments [38]. The device was slow to recharge and quick to overheat, but it was able to stimulate spinal cord roots, and also superficial human cortex. TMS requires a unit to store and deliver a charge (called a capacitor), and an electromagnetic coil (typically round in the shape of a doughnut or two round coils side by side and connected in a figure eight). A system can be cumbersome (resembling a small refrigerator), although some haveshown that the entire system could be made portable and weigh less than 20 lbs. The devices are regulated by the FDA for general safety and most machines have FDA approval for sale in the United States. They are also then regulated with respect to the ability to advertise their therapeutic use in a particular disorder. In the United States, a device manufactured by Neuronetics was approved by the FDA in 2008 for treating depression [39]. The essential feature is using electricity to generate a rapidly changing magnetic field, which in turn produces an electrical impulse in the brain. A typical TMS device produces a fairly powerful magnetic field (1.5–3 Tesla), but only very briefly (milliseconds). Early TMS devices only emitted a single, brief pulse. Modern devices can generate a rapid succession of pulses, called repetitive TMS (rTMS). These devices are used for behavioural research or clinical treatments and can discharge on and off for several minutes. For example, the typical treatment for depression is a 20–40 minute session, five days a week for four to six weeks. To keep the patient still and the device correctly placed, the patient reclines in a chair and the device is held securely against their head while they are awake and alert without needing anaesthesia. The TMS coil generates a magnetic field impulse that can only reach the outer layers of the cortex. The main effect of the impulse only penetrates 2–3 cm below the device; however, a deeper device has been invented and is in early clinical trials. When the TMS device produces a pulse over the motor cortex, descending fibres discharge and volley of electrochemical activity descends through connected fibres into the spinal cord and out to the peripheral nerve, where it can ultimately cause a muscle to twitch. The minimum amount of energy needed to produce morement of the thumb (abductor pollicis brevis) is called the motor threshold (MT). Because this is so easy to generate, and varies widely across individuals, the MT is used as a measure of general cortical excitability and most TMS studies (both research and clinical) report the TMS intensity as a function of individual
MT (and not as an absolute physical value). Although this convention has helped in making TMS safer, it is severely insufficient, in that it is referenced only to each machine, and thus is not a universal number. Future work is focusing on more universal, constant, measures of the magnetic field delivered. In general with TMS, a stronger, more intense pulse results in more activation of the CNS tissue, and a wider area of activation. The circumstance with frequency is more complex. In general, frequencies of less than 1 per second (<1 Hz) are inhibitory [40]. This may be because low frequency TMS more selectively stimulates the inhibitory GABA neurons, or this frequency is Long-term depression (LTD)-like. Conversely, higher frequency stimulation is behaviourally excitatory. However, high frequency TMS over some brain regions can temporarily block or knock out the function of that part of the brain. A handheld device is being developed and studied as a treatment to interrupt migraine headaches (Neuralieve, Inc.). The device delivers a single large pulse. When the patient experiences the aura phase of an impending headache, they hold the device to the back of their head and direct the pulse towards the occipital cortex.
Putative mechanisms of action TMS can produce different brain effects, depending on the brain region being stimulated, the frequency of stimulation, the use parameters (intensity, frequency, duty train) and whether the brain region is engaged or resting. Thus, it is difficult to review a single mechanism of action for TMS. However, in general, a single pulse of TMS over a cortical region like the motor cortex causes large neurons to depolarize. That is, the powerful transient magnetic field induces current to flow in neurons in superficial cortex (induced current). Both modelling and simple testing have shown that the fibres that are most likely to depolarize are those that are perpendicular to the coil, and are bending within the gyrus [41–43]. Some lower TMS intensities do not cause large neuron depolarization, but can still affect resting membrane potentials and thus alter brain activity and behaviour. The most striking positive phenomena that TMS can produce are motor twitches (thumb, hand, arm or leg movement) when applied over motor cortex, or phosphenes when TMS is placed over the occiput. To date, TMS cannot produce acute memories, thoughts, or sensations or percepts apart from the scalp sensation of the coil. Repeated TMS (rTMS) can produce measurable effects lasting for minutes to hours after the train. In general, rTMS at frequencies greater than 1 Hz are excitatory, and less than 1 Hz inhibitory. One particular TMS sequence builds directly from the neurobiological studies of Long-term potentiation (LTP) and LTD, and is called theta burst, as it has short bursts of TMS at theta frequencies [44].
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TMS over some cortical regions can produce a transient disruption of behaviour. This is most striking when the coil is placed over Brocas area and one can produce a transient expressive aphasia [45]. Much interest involves whether TMS can produce shortterm or even longer-term changes in plasticity. Simple studies in motor and visual systems clearly indicate the potential for this approach, which is now being applied in studies of post-stroke recovery and other forms of rehabilitation. Coupling TMS with electrophysiological measures allows one to use TMS as a measure of motor cortex excitability, and then measure how behaviour, medications or other interventions might change excitability. Several groups are using this TMS excitability tool to investigate new CNS-active compounds [46,47]. For example, some anticonvulsants and mood stabilizers like lamotrigine, can inhibit the motor cortex, and thus cause an increase in the TMS MT [48–50]. The TMS MEP can thus serve as a potential biomarker of the cortical effects of the compound. Coupling TMS with imaging (PET, SPECT, fMRI or BOLD fMRI) allows one to directly stimulate circuits and then image the resultant changes [51]. In a series of studies germane to BD, Li and colleagues at the Medical University of South Carolina (MUSC) have performed TMS within the fMRI scanner in healthy adults who are either taking a single oral dose of placebo, valproic acid or lamotrigine. Over motor cortex, both lamotrigine and valproic acid caused a reduction in the TMS-induced BOLD signal [48–50]. In contrast, when the TMS coil was placed over the prefrontal cortex, valproic acid as expected caused a reduction in the TMS-induced signal. However, paradoxically lamotrigine caused an increase in the TMS-induced prefrontal BOLD signal. These exciting data may be linked to the differential clinical effects seen between valproic acid and lamotrigine (with lamotrigine having a larger antidepressant effect in BD than does valproic acid). Whether or not these findings link to differential clinical efficacy, they demonstrate that TMS may have regionally specific and varying effects, depending on which medications patients are taking. With respect to the neuropsychiatric uses of TMS for depression or pain, at a molecular level, TMS is known to have similar effects as those seen with ECT, for example, increased monoamine turnover, increased Brain-Derived Neurotrophic Factor (BDNF), and normalization of the hypothalamic-pituitary-adrenal (HPA) axis. The initial use of daily prefrontal TMS to treat depression was based on the theory that in depression there was imbalanced relationship between prefrontal cortex and deeper limbic regions involved in mood regulation (insula, cingulate gyrus, amygdala and hippocampus) [52]. There is only limited direct support that this is occurring, although recent work by Maier and colleagues directly supports the
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critical role of medial prefrontal cortex in mitigating and reversing chronic learned helplessness. Stimulatory fibres from the prefrontal cortex are critical in this model [53–55].
Safety In general, TMS is regarded as safe and without enduring side effects. There have been no reported lasting neurologic, cognitive or cardiovascular sequelae. However, TMS can alter brain function and is a relatively new technology so vigilance is required. The interested reader should read the results from an international conference on TMS safety [56]. Inducing a seizure is the primary safety concern with TMS. There have been less than 20 reported seizures induced with TMS, with a sample size of several thousand. The risk is less than one half of one percent. Most of these patients were healthy volunteers without a history of epilepsy. Fortunately, there are no reports that the individuals affected experienced recurrence. Also, all of the seizures occurred during TMS administration, when the patient was sitting down and near an investigator. Also, all of the seizures were self-limited without needing medications or other interventions. Published safety tables concerning the proper intensity, frequency and number of stimuli help minimize the numbers of seizures. Of the reported cases, the majority were receiving TMS to the motor cortex – the most epileptogenic region of the cortex. In addition, most (but not all) were receiving trains of stimulation outside of suggested limits. These cases suggest that TMS-induced seizures will remain a small but significant adverse event, even in patients without histories of seizures and even when TMS is used within suggested guidelines. Headaches are the most common complaint after TMS. Repeated analysis of neurocognitive functioning of TMS patients has not found any enduring negative effects from the procedure. After a session, patients or subjects are able to drive home and return to work. The TMS procedure itself causes some scalp pain, which is almost always worse during the first few sessions and then largely disappears [57,58].
Research uses Space does not permit a thorough overview of TMS research uses, other than to highlight the active areas. TMS can be used as a measure of cortical excitability, and has been used to investigate medication effects, emotional states, plasticity in learning and stroke recovery, sleep, and in a host of disease states. TMS can be combined with brain imaging to directly stimulate circuits and image the resultant changes. When precisely applied over critical brain regions, TMS can help causally determine whether a brain region is involved in a behaviour, and how information flows through the brain during a task. There is much excitement,
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but little hard evidence, that TMS might be used to actually augment task performance, memory formation or recovery from injury.
Clinical studies in BD Largely because of its non-invasiveness, TMS has been investigated in almost all neuropsychiatric conditions. Until only recently, there has not been a TMS industry to promote or perform this work and thus much of the clinical work has been single site and non-industry funded, with relatively small sample sizes. Depression has been the most widely studied condition with TMS. Three initial studies from Europe used TMS over the vertex as a potential antidepressant [59–61]. In the United States, George, Wassermann and Post performed initial safety studies in healthy controls, an open study, and then a double blind controlled trial of TMS for two weeks [62–64]. This work has now dramatically grown, but without much change in many of the initial treatment choices (coil location, frequency, dosing). There have now been several meta-analyses of the procedure [65]. A recent meta-analysis of repetitive TMS for depression examined 25 published sham-controlled studies [66]. The authors concluded that left prefrontal TMS provided statistical superiority over sham treatment for patients with depression. However, they concluded that the clinical benefits are marginal in the majority of reports and there is still considerable uncertainty concerning the optimal stimulation parameters. Those clinical features, which appear to be associated with greater response, include younger age, lack of refractoriness to antidepressants and no psychotic features. The largest multi-site trial to date, which resulted in FDA approval, was by Neuronetics. They sponsored a double blind, multisite study of 301 medication-free patients with unipolar major depression. Patients were randomized to active TMS or sham treatment, which they received for four to six weeks [39]. There was some controversy about the results of the trial. Before conducting the experiment, the company chose the MADRS as the primary outcome (and did not tell investigators) while using the HAM-D as the entry criteria. Unfortunately, at six weeks, the MADRS for the active treatment group was not quite statistically different from the control group: p ¼ 0.058. The HAM-D scores, considered secondary outcome measures, were indeed superior for those in the active treatment group. The company argued, successfully for the publication, that they should exclude six subjects with entry MADRS scores that were very low and could not reflect clinical improvement. Thus, the manuscript was published as a positive trial but the FDA initially rejected the application, and only agreed for approval after reviewing response data on subgroups [67,68]. Because there was
such a large effect seen in those who were less treatmentresistant, the FDA labelling is for the treatment of MDD in adult patients who have failed to achieve satisfactory improvement from one prior antidepressant treatment at or above the minimal effective dose and duration in the current episode. Note that in clinical practice, only about one in four antidepressant treatment trials meets criteria for minimal dose and duration, so this translates to patients with a moderate level of treatment resistance [69–71]. Most recently, the NIH has funded a large multisite trial in depression, which was recently completed. Using a new sham technique [72,73], these researchers created an effective sham with no differences in side effects, and effective blinding of patients, raters, and to a substantial degree, TMS treaters. The study revealed a statistically significant difference in remission rates between sham and real TMS, with remission rates larger than seen with medications in similar treatment-resistant medication trials [74]. Nahas and colleagues performed one of the first TMS studies in bipolar depression [75]. We recruited and enrolled 23 depressed BD patients (12 BPI depressed state, 9 BPII depressed state, 2 BPI mixed state). Patients were randomly assigned to receive either daily left prefrontal rTMS (5 Hz, 110% MT, 8 sec on, 22 sec off, over 20 min, 1600 stimuli per session) or placebo each weekday morning for two weeks. Patients could remain on mood stabilizers but not antidepressants. Blinded HAM-D and YMRS were obtained weekly. There were no significant adverse events and no induction of mania. We failed to find a statistically significant difference between the two groups in the number of antidepressant responders (>50% decline in HAM-D or HAM-D <10–4 active and 4 sham) or the mean HAM-D change from baseline over the two weeks. Active rTMS, compared with sham rTMS, produced a trend but not statistically significant greater improvement in daily subjective mood ratings post-treatment. We concluded that daily left prefrontal rTMS appeared safe in depressed BD subjects, and the risk of inducing mania in BD subjects on medications was small. We failed to find a statistically significant TMS clinical antidepressant effect greater than sham or even a mathematical difference upon which to complete the power and effect size needed in a larger clinical trial. This study was published in 2003 but conducted in 2000–2001. With the knowledge gleaned over the past 10 years, it appears clear that this trial was underdosed, both in terms of the number of weeks needed for treatment (many studies now treat for four to six weeks), and the number of stimuli/day, which has increased from the 1600 stimuli/session in this trial to 6000 stimuli/session in recent trials. In a recent effectiveness trial, which admitted both unipolar and bipolar depressed patients, bipolar patients also responded. It thus appears that TMS may work to treat bipolar depression, but there are no class I data of
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efficacy exclusively in bipolar depression (Hadley, in press, JECT). TMS has also been studied as a treatment for mania. Grisaru and colleagues enrolled 16 inpatients admitted in a manic phase, and randomized them to either right or left prefrontal TMS as adjunctive treatment on top of treatment as usual [76]. Patients were treated with TMS delivered at 20 Hz, 2-sec duration per train, 20 trains per day for 10 treatment days (800 stimuli/day, 8000 total dose). They found that right prefrontal TMS was associated with better outcomes in terms of reduction in mania symptoms. Unfortunately, there was no sham or control condition, and the two groups were unequal in terms of baseline illness, with the left-sided group appearing slightly more treatment-resistant and ill. The group tested these data for replication in a different design with right prefrontal stimulation compared to sham, and they found no difference. They wondered if the left prefrontal TMS, which has antidepressant effects, had actually had an elevating or mania worsening effect [77]. Thus there is no film evidence of TMS being useful as an antimanic treatment. Clinically when bipolar depressed patients have developed mania or hypomania during a TMS treatment course, clinicians have stopped the TMS and used other antimanic therapies. Xia and colleagues recently reviewed the published literature regarding treatment-emergent mania/hypomania (TEM) associated with repetitive TMS (rTMS) treatment of depression [78]. They found that 10/53 randomized controlled trials on rTMS treatment of depression specifically addressed TEM. The pooled TEM rate is 0.84% for the active treatment group and 0.73% for the sham group, which was not statistically significantly different. Along with case reports, a total of 13 cases of TEM associated with rTMS treatment of depression have been published. Most of these patients were diagnosed with bipolar disorder and the majority of patients experiencing TEM took medication concurrent with rTMS. The parameters of rTMS used in these cases were scattered over the spectrum of major parameters explored in previous studies. Most train durations and intervals were within the published safety guidelines of the field. The severity of manic symptoms varied significantly, but all cases responded to treatment that included a decrease or discontinuation of antidepressant or rTMS treatment or use of an anti-manic medication. This review suggested that rTMS treatment for bipolar and unipolar depression might carry a slight risk of TEM, but the published literature reveals this is not statistically higher than that associated with sham treatment.
ECT is a lifesaver and has both acute antidepressant and antimanic effects. ECT is unique in that it can treat both phases of the illness, and if treatment emergent hypomania occurs when treating BD depression with ECT, more ECT sessions can improve the mania as well. BD depressed patients, compared to unipolar patients, tend to have a quicker onset of response to ECT and require fewer treatments in a course. VNS has shown some evidence of improving the long-term outcome of treatment-resistant patients with BD. However, there is no class I evidence of efficacy in using VNS for BD depression. The study in rapid cycling BD used an historical control and was thus not a prospective trial. Similarly, there is no class I evidence that TMS can treat BD depression, although there are open-label case series. The work to date shows that there is potential for the brain stimulation methods to assume an ever-expanding role in the management and treatment of bipolar disorder. As more research emerges about the underlying problems with regional brain circuits in bipolar disorder, clinical researchers can continue to investigate how to apply the growing number of brain stimulation treatments to this important disorder.
Overall conclusions about brain stimulation methods for BD
References
The brain stimulation methods are increasingly playing a role in the management and treatment of bipolar disorder.
Acknowledgement Dr George is currently funded through grants from the NIH (NIMH, NIDA, NINDS), the VA system, and the US Department of Defence.
Conflicts Dr George reports no equity or other direct financial investment in any device or pharmaceutical firm. Within the past three years he has: served as a paid consultant to: Glaxo-Smith-Kline, Jazz Pharmaceuticals, Cyberonics, Neuropace, received research grants from: Glaxo-Smith-Kline, Jazz Pharmaceuticals, Brainsway, served as an unpaid consultant to: Brainsonix, Brainsway, Neuronetics, NeoStim, been the editor-in-chief of a journal published by Elsevier entitled Brain Stimulation. MUSC holds patents in the area of combining TMS with functional brain imaging. The total compensation from any company in a single year has been less than $10 000. The total combined compensation from all consulting activities is less than 10% of his university salary.
1. Sackeim, H.A. and George, M.S. (2008) Brain Stimulation – basic, translational and clinical research in neuromodulation: Why a new journal? Brain Stimulation, 1 (1), 4–6.
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2. George, M.S. and Belmaker, R.H. (2006) TMS in Clinical Psychiatry, American Psychiatric Press, Washington, DC. 3. Higgins, E.S. and George, M.S. (2008) Brain Stimulation Therapies for Clinicians, American Psychiatric Press, Washington. 4. Cronholm, B. and Ottoson, J.-O. (1963) Ultrabrief stimulus technique in electroconvulsive therapy. II. Comparative studies of therapeutic effects and memory disturbances in treatment of endogenous depression with the Elther ES electroshock apparatus and Siemens Konvulsator III. J. Nerv. Ment. Dis., 137, 268–276. 5. Sackeim, H.A., Prudic, J., Devanand, D.P. et al. (1993) Effects of stimulus intensity and electrode placement on the efficacy and cognitive effects of electroconvulsive therapy. N. Engl. J. Med., 328, 839–846. 6. Sackeim, H.A., Prudic, J., Nobler, M.S. et al. (2008) Effects of pulse width and electrode placement on the efficacy and cognitive effects of electroconvulsive therapy. Brain Stimulation, 1 (2), 71–83. 7. Sackeim, H.A., Prudic, J., Devanand, D.P. et al. (2000) A prospective, randomized, double-blind comparison of bilateral and right unilateral electroconvulsive therapy at different stimulus intensities. Arch. Gen. Psychiatry, 57 (5), 425–434. 8. Medda, P., Perugi, G., Zanello, S. et al. (2009) Response to ECT in bipolar I, bipolar II and unipolar depression. J. Affect. Disord., 118 (1–3), 55–59. 9. Bailine, S., Fink, M., Knapp, R. et al. (2009) Electroconvulsive therapy is equally effective in unipolar and bipolar depression. Acta Psychiatr. Scand. Epub ahead of print, Nov. 5. 10. Sienaert, P., Vansteelandt, K., Demyttenaere, K. and Peuskens, J. (2009) Ultra-brief pulse ECT in bipolar and unipolar depressive disorder: differences in speed of response. Bipolar Disord., 11 (4), 418–424. 11. Valenti, M., Benabarre, A., Garcia-Amador, M. et al. (2008) Electroconvulsive therapy in the treatment of mixed states in bipolar disorder. Eur. Psychiatry, 23 (1), 53–56. 12. Kellner, C.H., Knapp, R.G., Petrides, G. et al. (2006) Continuation electroconvulsive therapy vs pharmacotherapy for relapse prevention in major depression: a multisite study from the Consortium for Research in Electroconvulsive Therapy (CORE). [see comment]. Arch. Gen. Psychiatry, 63 (12), 1337–1344. 13. George, M.S., Nahas, Z., Borckardt, J.J. et al. (2007) Vagus Nerve Stimulation for the Treatment of Depression and other Neuropsychiatric Disorders. Expert Rev. Neurother., 7 (1), 63–74. 14. Foley, J.O. and DuBois, F. (1937) Quantitative studies of the vagus nerve in the cat. The ratio of sensory and motor studies. J. Comp. Neurol., 67, 49–67. 15. Bailey, P. and Bremer, F. (1938) A sensory cortical representation of the vagus nerve. J. Neurophys., 1 (5) 405–412. 16. Groves, D.A. and Brown, V.J. (2005) Vagal nerve stimulation: a review of its applications and potential mechanisms that mediate its clinical effects. Neurosci. Biobehav. R., 29 (3), 493–500. 17. OReardon, J.P., Cristancho, P. and Peshek, A.D. (2006) Vagus nerve stimulation (VNS) and treatment of depression: to the brainstem and beyond. Psychiatry, 3 (5), 54–63.
18. Conway, C.R., Sheline, Y.I., Chibnall, J.T. et al. (2006) Cerebral blood flow changes during vagus nerve stimulation for depression. Psychiatry Res., 146 (2), 179–184. 19. Mu, Q., Bohning, D.E., Nahas, Z. et al. (2004) Acute vagus nerve stimulation using different pulse widths produces varying brain effects. Biol. Psychiatry, 55 (8), 816–825. 20. Chae, J.H., Nahas, Z., Lomarev, M. et al. (2003) A review of functional neuroimaging studies of vagus nerve stimulation (VNS). J. Psychiatr. Res., 37 (6), 443–455. 21. Lomarev, M., Denslow, S., Nahas, Z. et al. (2002) Vagus nerve stimulation (VNS) synchronized BOLD fMRI suggests that VNS in depressed adults has frequency/dose dependent effects. J. Psychiatr. Res., 36 (4), 219–227. 22. Bohning, D.E., Lomarev, M.P., Denslow, S. et al. (2001) Feasibility of vagus nerve stimulation-synchronized blood oxygenation level-dependent functional MRI. Invest. Radiol., 36 (8), 470–479. 23. Clark, K.B., Naritoku, D.K., Smith, D.C. et al. (1999) Enhanced recognition memory following vagus nerve stimulation in human subjects. Nat. Neurosci., 2, 94–98. 24. Ben-Menachem, E., Manon-Espaillat, R., Ristanovic, R. et al. (1994) Vagus nerve stimulation for treatment of partial seizures: 1. A controlled study of effect on seizures. First international vagus nerve stimulation study group. Epilepsia, 35 (3), 616–626. 25. Handforth, A., DeGiorgio, C.M., Schachter, S.C. et al. (1998) Vagus nerve stimulation therapy for partial-onset seizures: a randomized active-control trial. Neurology, 51 (1), 48–55. 26. Henry, T.R., Bakay, R.A., Votaw, J.R. et al. (1998) Brain blood flow alterations induced by therapeutic vagus nerve stimulation in partial epilepsy: I. Acute effects at high and low levels of stimulation. Epilepsia, 39 (9), 983–990. 27. Rush, A.J., George, M.S., Sackeim, H.A. et al. (2000) Vagus nerve stimulation (VNS) for treatment-resistant depressions: a multicenter study. Biol. Psychiatry, 47 (4), 276–286. 28. Nahas, Z., Marangell, L.B., Husain, M.M. et al. (2005) Twoyear outcome of vagus nerve stimulation (VNS) for treatment of major depressive episodes. J. Clin. Psychiatry, 66 (9), 1097–1104. 29. Schlaepfer, T.E., Frick, C., Zobel, A. et al. (2008) Vagus nerve stimulation for depression: efficacy and safety in a European study. Psychol. Med., 38 (5), 651–661. 30. Rush, A.J., Sackeim, H.A., Marangell, L.B. et al. (2005) Effects of 12 months of vagus nerve stimulation in treatment-resistant depression: a naturalistic study. Biol. Psychiatry, 58 (5), 355–363. 31. Rush, A.J., Marangell, L.B., Sackeim, H.A. et al. (2005) Vagus nerve stimulation for treatment-resistant depression: a randomized, controlled acute phase trial. Biol. Psychiatry, 58 (5), 347–354. 32. George, M.S., Rush, A.J., Marangell, L.B. et al. (2005) A oneyear comparison of vagus nerve stimulation with treatment as usual for treatment-resistant depression. Biol. Psychiatry, 58 (5), 364–373. 33. Marangell, L.B., Suppes, T., Zboyan, H.A. et al. (2008) A 1-year pilot study of vagus nerve stimulation in treatmentresistant rapid-cycling bipolar disorder. J. Clin. Psychiatry, 69 (2), 183–189.
Somatic Treatments 34. Padberg, F. and George, M.S. (2009) Repetitive transcranial magnetic stimulation of the prefrontal cortex in depression. Exp. Neurol., 219 (1), 2–13. 35. George, M.S. and Aston-Jones, G. (2010) Noninvasive techniques for probing neurocircuitry and treating illness: vagus nerve stimulation (VNS), transcranial magnetic stimulation (TMS) and transcranial direct current stimulation (tDCS). Neuropsychopharmacology, 35 (1), 301–316. 36. Faraday, M. (1965) Effects on the production of electricity from magnetism (1831), in Michael Faraday (ed. L.P. Williams), Basic Books, New York, pp. 531. 37. Kolin, A., Brill, N.Q. and Broberg, P.J. (1959) Stimulation of irritable tissues by means of an alternating magnetic field. Proc. Soc. Exp. Biol. Med., 102, 251–253. 38. Barker, A.T., Jalinous, R. and Freeston, I.L. (1985) Noninvasive magnetic stimulation of human motor cortex. Lancet, 1 (8437), 1106–1107. 39. OReardon, J.P., Solvason, H.B., Janicak, P.G. et al. (2007) Efficacy and safety of transcranial magentic stimulation in the acute treatment of major depression: a multisite randomzied controlled trial. Biol. Psychiatry, 62, 1208–1216. 40. Hoffman, R.E. and Cavus, I. (2002) Slow transcranial magnetic stimulation, long-term depotentiation, and brain hyperexcitability disorders. Am. J. Psychiatry, 159 (7), 1093–1102. 41. Cracco, R.Q., Amassian, V.E. and Maccabee, P.J. (1987) Physiological basis of the motor effects of cortical stimulation. I. Transcranial electrical stimulation. J. Clin. Neurophysiol., 4, 221–222. 42. Amassian, V.E., Eberle, L., Maccabee, P.J. and Cracco, R.Q. (1992) Modelling magnetic coil excitation of human cerebral cortex with a peripheral nerve immersed in a brain-shaped volume conductor: the significance of fiber bending in excitation. Electroencephalo. Clin. Neuro., 85, 291–301. 43. Herbsman, T., Forster, L., Molnar, C. et al. (2009) Motor threshold in transcranial magnetic stimulation: the impact of white matter fiber orientation and skull-to-cortex distance. Hum. Brain. Mapp., 30 (7), 2044–2055. 44. Di Lazzaro, V., Pilato, F., Saturno, E. et al. (2005) Theta-burst repetitive transcranial magnetic stimulation suppresses specific excitatory circuits in the human motor cortex. J. Physiol., 565 (Pt 3), 945–950. 45. Epstein, C.M., Lah, J.J., Meador, K. et al. (1996) Optimum stimulus parameters for lateralized suppression of speech with magnetic brain stimulation. Neurology, 47, 1590–1593. 46. Ziemann, U. and Hallett, M. (2000) Basic Neurophysiological Studies with TMS, in Transcranial Magnetic Stimulation in Neuropsychiatry, 1st edn (eds M.S. Georgeand R.H. Belmaker), American Psychiatric Press, Washington, DC, pp. 45–98. 47. Ziemann, U. (2003) Pharmacology of TMS. EEG Clin. Neurophys, 56 (Supplement), 226–231. 48. Large, C.H., Daniel, E.D., Li, X. and George, M.S. (2009) Neural network dysfunction in bipolar depression: clues from the efficacy of lamotrigine. Biochem. Soc. Trans., 37 (Pt 5), 1080–1084. 49. Li, X., Teneback, C.C., Nahas, Z. et al. (2004) Interleaved transcranial magnetic stimulation/functional MRI confirms
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that lamotrigine inhibits cortical excitability in healthy young men. Neuropsychopharmacology, 29 (7), 1395–1407. Li, X., Ricci, R., Large, C.H. et al. (2009) Lamotrigine and valproic acid have different effects on motorcortical neuronal excitability. J. Neural. Transm. (Vienna, Austria: 1996), 116 (4), 423–429. George, M.S., Bohning, D.E., Li, X. et al. (2007) Neuroimaging of rTMS effects on the brain, in Transcranial Brain Stimulation in Mental Disorders (eds M. Marcolin F., Padberg), Karger, Berlin. George, M.S., Ketter, T.A. and Post, R.M. (1994) Prefrontal cortex dysfunction in clinical depression. Depression, 2 (2), 59–72. Amat, J., Baratta, M.V., Paul, E. et al. (2005) Medial prefrontal cortex determines how stressor controllability affects behavior and dorsal raphe nucleus. Nat. Neurosci., 8 (3), 365–371. Bland, S.T., Schmid, M.J., Watkins, L.R. and Maier, S.F. (2004) Prefrontal cortex serotonin, stress, and morphine-induced nucleus accumbens dopamine. Neuroreport, 15 (17), 2637–2641. Maier, S. (1984) Learned helplessness and animal models of depression. Prog. Neuropsychopharmacol. Biol. Psychiatry, 8 (3), 435–446. Rossi, S., Hallett, M., Rossini, P.M. and Pascual-Leone, A. (2009) Safety, ethical considerations, and application guidelines for the use of transcranial magnetic stimulation in clinical practice and research. Clin. Neurophys., 120 (12), 2009–2039. Borckardt, J.J., Smith, A.R., Hutcheson, K. et al. (2006) Reducing pain and unpleasantness during repetitive transcranial magnetic stimulation. J. ECT, 22 (4), 259–264. Anderson, B.S., Kavanagh, K., Borckardt, J.J. et al. (2009) Decreasing procedural pain over time of left prefrontal rtms for depression: Initial results from the open-label phase of a multisite trial (OPT-TMS). Brain Stimulation, 2 (2), 88–92. Hoflich, G., Kasper, S., Hufnagel, A. et al. (1993) Application of transcranial magnetic stimulation in the treatment of drug-resistant major depression. Hum. Psychopharm., 8, 361–365. Kolbinger, H.M., Hoflich, G., Hufnagel, A. et al. (1995) Transcranial Magnetic Stimulation (TMS) in the treatment of major depression – a pilot study. Hum. Psychopharm., 10, 305–310. Grisaru, N., Yarovslavsky, U., Abarbanel, J. et al. (1994) Transcranial magnetic stimulation in depression and schizophrenia. Eur. Neuropsychopharm., 4, 287–288. George, M.S., Wassermann, E.M., Kimbrell, T.A. et al. (1997) Mood improvement following daily left prefrontal repetitive transcranial magnetic stimulation in patients with depression: a placebo-controlled crossover trial. Am. J. Psychiatry, 154 (12), 1752–1756. George, M.S., Wassermann, E.M., Williams, W.A. et al. (1996) Changes in mood and hormone levels after rapid-rate transcranial magnetic stimulation (rTMS) of the prefrontal cortex. J. Neuropsychiatry Clin. Neurosci., 8 (2), 172–180. George, M.S., Wassermann, E.M., Williams, W.A. et al. (1995) Daily repetitive transcranial magnetic stimulation (rTMS) improves mood in depression. Neuroreport, 6 (14), 1853–1856.
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65. Ridding, M.C. and Rothwell, J.C. (2007) Is there a future for therapeutic use of transcranial magnetic stimulation? Nat. Rev. Neurosci., 8 (7), 559–567. 66. Mitchell, P.B. and Loo, C.K. (2006) Transcranial magnetic stimulation for depression. Aust. Nz. J. Psychiat., 40 (5), 406–413. 67. Lisanby, S.H., Husain, M.M., Rosenquist, P.B. et al. (2009) Daily left prefrontal repetitive transcranial magnetic stimulation in the acute treatment of major depression: clinical predictors of outcome in a multisite, randomized controlled clinical trial. Neuropsychopharmacology, 34 (2), 522–534. 68. Avery, D.H., Isenberg, K.E., Sampson, S.M. et al. (2008) Transcranial magnetic stimulation in the acute treatment of major depressive disorder: clinical response in an open-label extension trial. J. Clin. Psychiat., 69 (3), 441–451. 69. Oquendo, M.A., Baca-Garcia, E., Kartachov, A. et al. (2003) A computer algorithm for calculating the adequacy of antidepressant treatment in unipolar and bipolar depression. J. Clin. Psychiat., 64 (7), 825–833. 70. Dew, R.E., Kramer, S.I. and McCall, W.V. (2005) Adequacy of antidepressant treatment by psychiatric residents: the antidepressant treatment history form as a possible assessment tool. Acad. Psychiatry, 29 (3), 283–288. 71. Joo, J.H., Solano, F.X., Mulsant, B.H. et al. (2005) Predictors of adequacy of depression management in the primary care setting. Psychiatr. Serv. (Washington, DC), 56 (12), 1524–1528.
72. Borckardt, J.J., Linder, K.J., Ricci, R. et al. (2008) Focal Electrically Administered Therapy (FEAT): Device parameter effects on stimulus perception in humans. J. ECT, 25 (2), 91–98. 73. Arana, A.B., Borckardt, J.J., Ricci, R. et al. (2008) Focal Electrical Stimulation as a Sham Control for rTMS: Does it truly mimic the cutaneous sensation and pain of active prefrontal rTMS? Brain Stimulation, 1 (1), 44–51. 74. George, M.S., Lisanby, S.H., Averg, D. et al. (2010) Daily left Prefrontal transcranial magnetic stimulation therapy for major depressive disorder: a sham-controlled randomized trial. Arch. Gen. Psychiat. 75. Nahas, Z., Kozel, F.A., Li, X. et al. (2003) Left prefrontal transcranial magnetic stimulation (TMS) treatment of depression in bipolar affective disorder: a pilot study of acute safety and efficacy. Bipolar Disord., 5 (1), 40–47. 76. Grisaru, N., Chudakov, B., Yaroslavsky, Y. and Belmaker, R.H. (1998) TMS in mania: a controlled study. Am. J. Psych., 155 (11), 1608–1610. 77. Kaptsan, A., Yaroslavsky, Y., Applebaum, J. et al. (2003) Right prefrontal TMS versus sham treatment of mania: a controlled study. Bipolar Disord., 5 (1), 36–39. 78. Xia, G., Gajwani, P., Muzina, D.J. et al. (2008) Treatmentemergent mania in unipolar and bipolar depression: focus on repetitive transcranial magnetic stimulation. Int. J. Neuropsychopharmacol., 11 (1), 119–130.
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Novel Therapeutic Strategies for Bipolar Disorder Rodrigo Machado-Vieira1, Husseini K. Manji2 and Carlos A. Zarate Jr1 1 2
Experimental Therapeutics, Mood and Anxiety Disorders Research Program, NIMH-NIH, Bethesda, Maryland, USA Johnson & Johnson Pharmaceuticals Group, Titusville, NJ, USA
Introduction Bipolar disorder (BPD) is a chronic and complex disorder comprising diverse behavioural, cognitive, hedonic and motoric changes over the lifetime. Despite the existence of several treatment options, current drugs for BPD are not effective for a significant number of patients. In particular, treatments for the depressive and maintenance phases of BPD are still far from optimal. Few agents have proved to be effective in these conditions, which increases the amount of time that vulnerable individuals experience depression. High rates of residual symptoms, functional impairment, episode relapses and psychosocial disability are challenges that need to be addressed by the next generation of improved treatments. While patients who receive available therapeutics for acute manic episodes tend to have a better outcome, there is still a considerable lack of efficacy and tolerability associated with their use [1,2]. Recent large-scale studies funded by the National Institute of Mental Health (NIMH) explored the effectiveness of standard treatments for BPD and observed that, after 26 weeks, the use of adjunctive antidepressants during the depressive phase of BPD was as effective as using only mood-stabilizers [3,4]. Indeed, no drug has been developed specifically for the treatment of BPD based on its neurobiology or on a specific mechanism of action for achieving therapeutic effects. High rates of dropout, placebo effects and difficulty in recruiting patients are some of the problems that have limited our ability to develop faster-acting and more effective treatments for BPD. A review of the antipsychotics and anticonvulsants currently used to treat BPD is not the focus of this chapter, and these are discussed elsewhere. Instead, the goal of this chapter is to review the efficacy and safety of novel therapies for BPD that are worthy of future investigation, mostly based on preclinical and initial proof of concept clinical Bipolar Disorder: Clinical and Neurobiological Foundations Edited by Lakshmi N. Yatham and Mario Maj © 2010 John Wiley & Sons, Ltd. ISBN: 978-0-470-72198-8
studies. These include medications that act on: (1) the dynorphin opioid neuropeptide system; (2) the purinergic system; (3) the cholinergic system (muscarinic and nicotinic systems); (4) the melatonin and serotonergic [5-hydroxytryptamine receptor 2C (5-HT2C)] system; (5) the glutamatergic system; and (6) the hypothalamic-pituitary adrenal (HPA) axis. In addition, diverse intracellular pathways and targets merit further attention, including: (7) glycogen synthase kinase-3 (GSK-3) protein; (8) protein kinase C (PKC); (9) the arachidonic acid (AA) cascade; and (10) other candidates. Here we describe studies evaluating potential new treatments for BPD encompassing the systems described above, and based on clinical and preclinical findings. These targets were identified using several criteria. Specifically: (a) studies of these agents showing that they had antimanic effects in humans, or beneficial effects on irritability, hyperactivity, or mood; (b) studies of agents showing antidepressant properties in bipolar depression; and (c) studies of agents with antidepressant-like properties in animal models, ‘antimanic-like’ properties in animal models or antipsychoticlike properties in either humans or animal models of psychosis (e.g. prepulse inhibition). It should be noted that the extrapolation of animal studies to humans in the absence of reliable and valid animal models of BPD must be interpreted with caution.
The dynorphin opioid neuropeptide system The dynorphin opioid neuropeptide system is known to regulate mood, cognition, motor and endocrine functions. The three well-defined types of opioid receptors – m, k and d – are thought to be involved in mood disorders. In individuals with BPD, significant decreases of 37–38% in pro-dynorphin mRNA expression levels in the amygdalohippocampal area have been described, as has parvicellular division of the accessory basal area [5]. Selective kappa opiate antagonists have been proposed as a treatment for psychosis [6]. The activation of kappa opiate 395
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receptors appears to be depressogenic in both animals and humans [7,8]. In contrast, blocking these receptors using the kappa opioid antagonist MCL-144B resulted in antidepressant-like effects in the forced swim test (FST) [9,10], raising the possibility that kappa opiate agonists could have antimanic effects. It should be noted, however, that activating these receptors may induce psychotomimetic and dysphoric effects [11,12], as well as risk for addictive behaviour. So far, no selective kappa agonist has been tested in humans. In animals, the highly selective full kappa opioid receptor agonist Salvinorin-A (Salvia divinorum) was found to induce depressive-like behaviour involving reduced extracellular concentrations of dopamine (but not serotonin) in the nucleus accumbens [8]. Also, the analgesic pentazocine (Talwin) exerted a partial agonistic effect at the kappa receptors in the brain, and has recently been tested adjunctively in ten BPD inpatients presenting with a manic episode. In this uncontrolled study, patients received two 50-mg doses of pentazocine two hours apart. Symptoms of mania were reduced one hour after each dose (>44% after the first dose and 41% after the second dose) without inducing depression [13]. No significant adverse events, including psychotomimetic effects, were observed. Although kappa opioid receptors have been associated with induction of depression in healthy volunteers, future controlled proof of concept studies may clarify their relevance in the pathophysiology and treatment of BPD.
The purinergic system Purines play a key role in energy metabolism and regulate neurotransmission (adenosine triphosphate and adenosine). Adenosine is a widespread neuromodulator that acts mostly through adenosine 1 and 2A receptors. In 1949, John Cade injected lithium urate into guinea pigs, and noted that it calmed them, thus suggesting that it could have sedative effects in BPD subjects with mania [14]. Later, Anumonye and colleagues described that remission in mania was associated with an increased excretion of uric acid [15]. Subsequently, it was hypothesized that dysfunction of the purinergic system was directly involved in the neurobiological basis of bipolar mania and possibly in the mechanism of action of lithium [16]. Relatedly, the use of adenosine antagonists such as caffeine has been associated with irritability, anxiety and insomnia, which may trigger manic episodes in individuals with BPD [17]. In contrast, adenosine agonists appear to have sedative, anticonvulsant, anti-aggressive and antipsychotic properties in animals [18]. Recent genetic and clinical studies have reinforced the role of purinergic dysfunction in the pathophysiology of BPD [19–21]. For instance, the purinergic modulator allopurinol, which has been used for many years to treat gout, appears to be an effective antimanic agent in individuals
with mania and hyperuricemia [22]. Recently, two large, double blind, placebo-controlled studies showed that allopurinol as an add-on treatment to antimanic/mood-stabilizer therapies resulted in significant antimanic effects. In the first study, 82 subjects were randomized to either blinded allopurinol (300 mg/day) or placebo added to lithium plus haloperidol for 8 weeks. Posthoc comparisons showed significant improvement as early as Day 7 on the Young Mania Rating Scale (YMRS), and the difference between the two groups was also significant at the endpoint (eight weeks) [23]. The second study was a four-week, double-blind, placebo-controlled study involving 180 subjects with acute bipolar mania. This study compared allopurinol (600 mg/day), dipyridamole (200 mg/day) and placebo added to lithium and also found that allopurinol treatment resulted in significant antimanic effects compared to placebo [21]. Further large controlled studies with more selective modulators targeting the purinergic system are necessary to determine what specific purinergic targets are relevant to antimanic effects.
The cholinergic system Muscarinic system Several decades ago, Janowsky and colleagues first postulated that dysfunctions of the cholinergic-adrenergic balance, especially enhanced cholinergic activity, could be associated with the pathophysiology of mood disorders [24]. Relatedly, tricyclic antidepressants (TCA) were believed to induce their antidepressant effects via their anticholinergic properties. Early work by Kasper and colleagues (1981) investigated the antidepressant properties of the anticholinergic drug biperiden in 10 inpatients presenting with a severe depressive episode [25]. In preclinical studies, rats bred selectively for enhanced muscarinic receptor sensitivity showed diverse depressivelike behaviours, such as lethargy, despair and anhedonia [26]. In human studies, neuroendocrine and pupillary responses to cholinergic activity are increased in depression [27,28] and blunted in manic subjects, with normalization of pupillary responses after administration of lithium or valproate [29]. In addition, a PET study showed decreased muscarinic type 2 receptor binding in the anterior cingulate cortex of subjects with BPD [30]. Notably, a small controlled trial with physostigmine, a short-acting cholinesterase inhibitor, found rapid but not sustained improvement of manic symptoms after the first of multiple injections of physostigmine [31,32]. Other trials testing the long-acting cholinesterase inhibitor donepezil (5–10 mg/day) as an adjunctive treatment to mood stabilizers showed that it had rapid and significant antimanic effects in more than half of patients with treatment-resistant BPD who were experiencing a manic episode [33]. However, a recent 6-week, double-blind placebo-controlled trial showed no
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significant improvement using the same dose in a small sample (n ¼ 12) [34]. Recently, Furey and Drevets (2006) evaluated the potential role of the antimuscarinic drug scopolamine hydrobromide in two double-blind trials of patients with unipolar and bipolar depression. Significant antidepressant effects were observed in both studies, and were apparent after 3–5 days. Patients received a 15-minute intravenous infusion of a saline placebo and 3 doses of scopolamine hydrobromide (2.0, 3.0 and 4.0 ug/kg). A second study involved 7 sessions with a 15-minute intravenous infusion of a placebo saline solution or scopolamine hydrobromide (4.0 ug/kg) [35]. In both studies, a significant decrease in Montgomery-Asberg Depression Rating Scale (MADRS) scores was observed in patients treated with scopolamine versus those treated with placebo at study endpoint. Only one patient experienced euphoria while on scopolamine, in contrast to previous hypotheses predicting that euphoria would complicate any evaluation of antidepressant effects associated with this class of agents [36]; no increase in YMRS scores was observed. The key limitation of currently available anticholinergic agents in the treatment of bipolar depression is their sideeffect profile, which could be minimized with the development of new selective compounds. These promising initial results suggest that further controlled short- and long-term studies are warranted to evaluate the long-term efficacy, safety and tolerability of these compounds in the treatment of BPD. It should be noted, however, that a study investigating the association between 19 cholinergic genes and BPD found no association between the two [37].
The nicotinic acetylcholine receptor (nAChR) system The nAChR system is a well-characterized neurotransmitter system. A potential role for nicotinic receptors in the therapeutics of mood disorders has been suggested. Nicotine and its analogues have mood-elevating (hedonic) properties and antidepressant-like effects and, in animal models, their withdrawal leads to anhedonic states [38–41]. Similarly, the high-affinity nAChR agonist cytisine had antidepressant-like properties in male C57BL/6J mice [42]. However, it still remains controversial whether the antidepressant-like effect of nAChR modulation is induced by activation, desensitization or inhibition of central nAChRs. In a recent study, the effects of non-selective and selective nicotinic agonists and antagonists were compared in two different tests for antidepressant effects in mice: the tail suspension test (TST) and the FST [43]. The study found that blockade of nAChRs with mecamylamine, or selective antagonism of a4b2, or a7 nAChRs with dihydro-betaerythroidine or methyllycaconitine (MLA, an a7-selective antagonist), respectively, had antidepressant-like effects that were not confounded by motor stimulation. At the
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doses tested, none of the nAChR agonists (nicotine, RJR2403 (an a4b2-selective agonist), PNU-282987 (an a7-selective agonist)) displayed antidepressant-like profiles. Thus it appears that antagonism of central a4b2 and/or a7 nAChRs induced antidepressant-like effects in mice. In humans, an increase in mRNA levels of a7 (located at chromosome 15a13-14) and a7-like genes was found in the postmortem prefrontal cortex (PFC) of BPD subjects compared to patients with schizophrenia and healthy controls [44]. A small four-week, double-blind, placebo-controlled clinical study of transdermal nicotine (3.5–7.0 mg/day) induced significant antidepressant effects only at Day 8, with no difference to placebo at endpoint. The study reported few side effects, although nicotine treatment can often cause side effects such as sympathomimetic actions and nausea. Because these unwanted side effects are probably mediated through peripheral nicotinic receptors, studies of specific nicotinic modulators are underway. Regarding nicotinic antagonists, mecamylamine attenuated both ephedrine- and quinpirole-induced hyperactivity in rats [41,45]. Mecamylamine (1 mg/kg) also significantly decreased immobility time in the FST and TST without altering baseline locomotor activity. These effects appear to depend on both b2 and a7 subunits of the NAChR, as mice lacking these subunits showed no evidence of antidepressant-like properties [46]. Mood-stabilizing effects were also observed in clinical studies of mecamylamine (2.5–7.5 mg/day) in two BPD subjects comorbid with Tourette’s syndrome [47], whose manic symptoms returned after mecamylamine treatment ceased. A recent small, 8-week, double-blind, placebo-controlled study similarly found that mecamylamine (2.5–7.5 mg/day) had antidepressant and mood-stabilizing properties in children and adolescents with Tourette’s syndrome comorbid with other psychiatric disorders [48]. Because the subjects in these studies had comorbid diagnoses, and because neither study directly evaluated BPD, the generalizability of these findings is limited. However, the potential efficacy of these agents in BPD is worthy of further investigation, as is an assessment of the likelihood of abuse and/or withdrawal symptoms associated with their use. Further studies are also needed to clarify whether the antidepressant-like effects of nAChR modulation is induced by activation, desensitization or antagonism of central nAChRs.
The melatonin and serotonin (5-HT2C receptor) systems The pineal hormone melatonin induces its biological effects mostly through G protein–coupled melatonin receptors (MT1 and MT2), which are particularly expressed in the brain. The presence of disrupted sleep-wake rhythms and the cyclical nature and course of BPD suggest that dysfunction of the circadian system may underlie at least some
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portion of its pathophysiology. A significant association of the d 502–505 polymorphism in GPR50 (H9, melatoninrelated receptor) and susceptibility to BPD was found in a Scottish population, but this was not replicated in a Swedish sample [49,50]. Supersensitivity to melatonin suppression by light has been reported in patients with BPD, as well as in the non-affected offspring of probands with BPD and in monozygotic twins discordant for BPD, although not all studies have replicated this finding [51–54]. Low doses of the mood stabilizers lithium and valproate have both been shown to decrease melatonin light sensitivity, but not its overall synthesis in healthy volunteers [55,56]. In addition, levels and the timing of melatonin secretion appear to be altered in BPD and in patients with seasonal affective disorder [57]. There are no controlled studies using melatonin in patients with BPD, and case reports describe conflicting findings [58,59]. However, recent studies have explored the use of agomelatine, a potent, non-selective agonist of melatonin MT1 and MT2 receptors in BPD. A recent review concluded that agomelatine is efficacious and well-tolerated in patients with major depressive disorder (MDD) [60]. It is extensively metabolized via cytochrome P450 isoenyzmes 1A1, 1A2 and 2C9 to metabolites with less activity than the parent drug. Like lithium, agomelatine resynchronizes a disrupted circadian rhythm and has circadian phase-advancement properties [61–63]. In several large, multi-centre, multinational, placebo-controlled, short-term studies of MDD [64–66], agomelatine was found to be a clinically effective and well-tolerated antidepressant. Agomelatine is also effective in animal models of depression (e.g. the FST, chronic mild stress test and learned helplessness model) and anxiety [67–69]. However, agomelatine is also a 5-HT2C antagonist and increases both norepinephrine and dopamine levels [59]. Chronic agomelatine increases cell proliferation and neurogenesis in the ventral dentate gyrus [70]. With regards to BPD, a recent trial evaluated 21 patients with BPD-I experiencing a depressive episode who received agomelatine (25 mg/day) for 6 weeks. Results showed that 81% of patients met criteria for marked improvement at the study endpoint, and 47% responded as early as the first week of treatment [71]. No dropouts were observed. An extension phase involving 11 patients followed for 46 weeks who received agomelatine in combination with lithium or valpromide found that three lithium-treated patients had manic or hypomanic episodes, but only one of these was treatment-related; six patients had serious adverse events.
The glutamatergic system Glutamate is the main excitatory synaptic neurotransmitter in the brain. It mediates neurotransmission across excitatory synapses, and modulates several physiological brain functions such as synaptic plasticity, learning and
memory [72–75]. Excessive concentrations of glutamate are directly involved in the dysregulation of brain neuroplasticity and cellular resilience observed in patients with BPD. Emerging data also indicate a critical role for glutamate in both acute and long-term processes involved in the mode of action of currently available mood stabilizers and antidepressants. Consequently, several glutamatergic modulators have been investigated in an attempt to regulate these abnormal concentrations, and several glutamatergic compounds have been tested in proof-of-concept studies in patients with severe mood disorders [76,77]. These glutamatergic modulators, reviewed below, target either the glutamate receptors [N-methyl-D-aspartate (NMDA), a-amino-3-hydroxyl-5-methyl-4-isoxazole-propionate (AMPA) and metabotropic] directly or glutamate before its release into the extracellular space.
Riluzole Riluzole (2-amino-6-trifluoromethoxy benzothiazole) is a blood-brain-penetrant glutamatergic modulator with neuroprotective and anticonvulsant properties. Riluzole is the only drug approved by the FDA for the treatment of the degenerative motor-neuron disease amyotrophic lateral sclerosis (ALS). It is an inhibitor of glutamate release and enhancer of AMPA trafficking by increasing membrane insertion of AMPA subunits glutamate receptor type 1 (GluR1) and glutamate receptor type 2 (GluR2). Riluzole also increases glutamate reuptake and stimulates neurotrophic factor synthesis [78,79]. In open-label studies for treatment-resistant bipolar and unipolar depression, riluzole showed significant antidepressant effects and was well-tolerated [80]. A similar improvement in mood symtpoms was also observed in a 6-week, open-label study that used riluzole (100–200 mg per day) in conjunction with lithium in 14 patients with BPD experiencing a depressive episode [81]. In addition to its antidepressant effects, mice pretreated with 10 mg/kg riluzole (but not 3 mg/kg) had moderately reduced amphetamine-induced hyperlocomotion, but not MK-801-induced hyperlocomotion [82]; this suggests that riluzole might also have ‘antimanic-like’ properties, but further studies are necessary to clarify this issue. Memantine Memantine is approved for the treatment of Alzheimer’s disease. It is a fairly selective noncompetitive NMDA antagonist with both anticonvulsant and neuroprotective properties, and blocks the NMDA receptor-associated ion channel, thus preventing pathological concentrations of glutamate and excitotoxicity secondary to an extended channel opening [83,84]. In preclinical studies, memantine appears to have antidepressant-like effects when used alone or synergistically
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with imipramine in the FST in rats [85,86]. However, a double-blind, placebo-controlled clinical trial of patients with MDD found no significant antidepressant effects [87], though it is possible that higher doses of memantine, augmentation strategies or its use in different populations (e.g. in BPD) might yield positive results. For example, a recent controlled study found that memantine had antidepressant properties in patients with MDD and comorbid alcohol dependence [88]. However, there was no placebo control in this study. One report of two patients with bipolar depression found that memantine at doses of 10–20 mg/day improved depressive symptoms and cognitive performance when added to current mood stabilizers [89]. Further studies are necessary to address its potential role in bipolar depression, particularly because it may be associated with potent side effects; memantine at high doses has been reported to induce seizures in kindled rats [90].
Ketamine Ketamine has a high affinity for the NMDA receptor, with slow, open-channel blocking/unblocking kinetics and a specific type of channel closure (called ‘trapping block’). It simultaneously promotes a significant presynaptic release of glutamate by increasing firing rate of glutamatergic neurons after disinhibiting GABAergic inputs [91], and some of these properties are believed to be involved in its antidepressant effects. Preclinical studies found that ketamine has both antidepressant and anxiolytic effects in animal models [92–96]. These animal studies suggest that ketamine’s antidepressant effects occur in part by enhancing AMPA throughput [94]. One clinical trial found significant improvement in depressive symptoms within 72 hours of ketamine infusion in 7 subjects with treatment-resistant MDD [97]. Another randomized, double-blind, placebo-controlled, cross-over study found a fast (within 2 hours), robust, and relatively sustained antidepressant effect (lasting one to two weeks) after a single intravenous subanesthetic dose of ketamine (0.5 mg/kg for 40 min) in patients with treatment-resistant MDD [77]. More than 70% of patients met criteria for response (50% improvement) at 24 hours after infusion and 35% showed a sustained response after one week. Because of the intrinsic tendency of ketamine to produce cognitive deficits and psychotomimetic effects, its use is currently limited to research settings. Recent studies that used ketamine as an experimental tool found that anterior cingulate cortical activity in response to fearful faces [98] and positive family history of alcohol dependence [99] both predicted the initial antidepressant response to ketamine, but that brain-derived neurotrophic factor (BDNF) levels did not [100]. Such research is expected to generate insights into the bio-signatures of tested compounds that are associated with rapid antidepressant response. In addition, trials assessing the efficacy of more subtype selective NMDA antagonists
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are underway, which may determine whether these antidepressant effects can occur safely without causing ketamine’s undesirable side effects.
NMDA receptor antagonists Three subgroups of glutamatergic ion channels have been identified on the basis of their pharmacological ability to bind different synthetic ligands: NMDA, AMPA and kainate receptors. NMDA receptor antagonists have antidepressant-like effects in diverse paradigms [76,85,101–105]. Dizocilpine (MK-801), a channel blocker, and CGP 37849, an NMDA receptor antagonist, have shown antidepressantlike effects alone or in combination with standard antidepressants in different studies [102,104,106–108]. D-cycloserine, a NMDA receptor agonist and antibiotic used to treat tuberculosis, is a partial agonist of the glycine recognition site of the NMDA receptor. In terms of potential antimanic properties, only preclinical data have been published. D-Cycloserine was found to inhibit the hypermobility induced by methamphetamine but not that induced by apomorphine [109] and to decrease aggressiveness in the resident-intruder test [110]. In humans, D-cycloserine showed no efficacy in treatment-resistant depression, but is currently being tested in bipolar depression. AMPA potentiators AMPA receptors are ionotropic receptors mediating the fast components of excitatory neurotransmission that play a major role in learning and memory. Diverse classes of compounds regulate AMPA receptors by binding to their allosteric sites and are termed AMPA receptor positive modulators or AMPA receptor potentiators (ARPs). ARPs modulate AMPA receptors indirectly by decreasing the receptor desensitization rate and/or deactivation in the presence of an agonist (e.g. AMPA and glutamate (see [111] for a review)). In contrast to the receptor activation by agonists, ARPs decrease receptor desensitization and/or deactivation rates in the presence of an agonist (see [112,113] for review). AMPAkines, a subclass of AMPA potentiators, are small benzamide compounds that produce positive allosteric effects in the AMPA receptors. These compounds include benzoyliperidines (e.g. CX-516), benzothiazides (e.g. cyclothiazide), pyrrolidones (piracetam, aniracetam) and birylpropylsulfonamides (e.g. LY392098). These agents exert significant antidepressant effects in pre-clinical models of depression (reviewed in [111,114]), as well as clinical studies. For instance, one study found that the AMPAkine Ampalex induced antidepressant effects in the first week of treatment, while fluoxetine showed similar effects only after 2 weeks of treatment [115]. Because AMPA potentiators appear to have antidepressant-like properties, it is possible that AMPA receptor
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antagonists could display antimanic effects. The first group of selective AMPA receptor antagonists to be characterized was the quinoxalinedone derivatives such as 2,3-dioxo-6nitro-1,2,3,4- tetrahydrobenzo[f]quinoxaline-7-sulfonamide, which acts at the AMPA receptor recognition site. In contrast, recent AMPA antagonists, such GYKI 52466, block AMPA receptors on the receptor-channel complex via an allosteric site [116]. Currently, the GYKI 52466 analogue talampanel (GYKI 53773; LY 300164) is undergoing phase II clinical trials in ALS. Talampanel has anticonvulsant effects and was well-tolerated in previous clinical trials; sedation was the only notable side effect, and it was observed with initial dosing (reviewed by [117]). Other similar agents include the competitive AMPA receptor antagonist NS1209, which showed good CNS bioavailability and was well tolerated in phase I/II clinical trials. In rats, its anticonvulsant effects were faster and more complete than that of diazepam [118]. It is currently being tested in treatmentrefractory epilepsy (reviewed in [117,119]). Interestingly, these effects of some AMPA potentiators may involve regulation of cell proliferation [120]. Correspondingly, AMPA receptor trafficking (including receptor insertion, internalization and delivery to synaptic sites), which is thought to be involved in the antidepressant effects of ARPs, plays a critical role in regulating activity-dependent regulation of synaptic strength, as well as various forms of neural and behavioural plasticity [121].
Metabotropic glutamate receptors (mGluRs) and glutamate-glutamine cycling The mGluRs comprise eight receptor subtypes (mGluR1 to GluR8) classified into three groups on the basis of their sequence homology, coupling to second messenger systems, and agonist selectivity. Group I mGluRs (mGluR1 and mGluR5) are coupled to the phospholipase C signal transduction pathway. Group II (mGluR2 and mGluR3) and III (mGluR4 and mGluR6 to mGluR8) receptors are both coupled in an inhibitory manner to the adenylyl cyclase signal transduction pathway, which is generally involved in the regulation of the release of glutamate or other neurotransmitters such as g-aminobutyric acid (GABA), based on synaptic localization [122]. Group I mGluRs The Group I mGluR5 antagonists 2-methyl-6-[phenylethynyl]pyridine and [(2-methyl-1,3-thiazol-4-yl)ethynyl]pyridine have antidepressant-like effects in the modified FST and TST in rodents [123,124]. Also, 2-methyl- 6-[phenylethynyl]pyridine treatment was recently found to increase hippocampal mRNA levels [125]. Similarly, the mGluR1 antagonist [3-ethyl-2-methyl-quinolin-6-yl]-(4-methyoxy-cyclohexyl)methanone methanesulfonate had antidepressant-like
effects in the same tests [126]. The mode of antidepressant-like activity for mGluR1 or mGluR5 antagonists is uncertain; it also remains unclear whether mGluR5 antagonists are safe for clinical use. Studies conducted with the non-benzodiazepine anxiolytic fenobam, a potent and selective mGluR5 antagonist, were discontinued because of psychostimulant effects [127]. More recently, the mGluR5-positive allosteric modulator 3-cyano-N-(1,3-diphenyl-1Hpyrazol-5-yl)benzamide was found to be brain penetrant, and to reverse amphetamine-induced locomotor activity and amphetamine-induced deficits in prepulse inhibition in rats. Both models were thought to be sensitive to antipsychotic treatment, suggesting they are potentially useful in the treatment of mania [128]. Relatedly, riluzole (reviewed above) and lamotrigine, an anticonvulsant used to treat BPD, both significantly enhance the surface expression of GluR1 and GluR2 in a time- and dose-dependent manner in cultured hippocampal neurons [129]. In contrast, lithium and valproate reduced surface expression of GluR1 and GluR2 [130]. Taken together, these findings suggest that downregulation of GluR1/2 surface/subunit levels is involved in the antimanic effects of lithium and valproate, while BPD agents that have a predominantly antidepressant profile, such as lamotrigine and riluzole, involve upregulation of these AMPA subunits as a target for their therapeutic effects.
Group II mGluR2 and mGluR2/3 Group II mGluR2 and mGluR2/3 are negatively linked to the adenylyl cyclase signal transduction pathway and limit glutamate release, especially under excessive glutamate levels in the synapse; these receptors also modulate glutamatergic transmission by postsynaptic mechanisms. Group II mGluRs agonists (e.g. LY341495) dose-dependently decreased the immobility time of rodents in the FST and TST [131]. Moreover, the group II mGluR antagonist MGS- 0039 has been reported to be effective in the learned helplessness model of depression [132] and to increase cell proliferation in the adult mouse hippocampus [133]. Interestingly, activation of AMPA receptors has been shown to be responsible at least in part for the antidepressant-like activity of group II mGluR antagonists; the AMPA antagonist 2,3-dioxo-6-nitro-1,2,3,4- tetrahydrobenzo[f]quinoxaline-7-sulfonamide blocked the antidepressant-like activity of MGS-0039 in the TST in mice [134]. Group III mGluRs Pilc and colleagues demonstrated that a selective group III mGluR agonist ([1S,3R,4S]-1-aminocyclopentane-1,3,4-tricarboxylic acid) and a mGluR8 agonist ([RS]-4-phosphonophenylglycine) had antidepressant-like effects in the FST in rats [135]. Palucha and colleagues (2004) similarly reported
Novel Therapeutic Strategies
the antidepressant-like effects of group III mGluR agonists in the behavioural despair test, and Cryan and colleagues (2003) showed that mGluR7 knockout had antidepressantlike effects in mice that underwent the FST and TST [136,137]. No group III mGluR agonists have been tested clinically. Although there have been no studies with these compounds in animal models of mania, the mGluR5 antagonists and group II mGluR antagonists seem to be very promising compounds, with considerable potential antidepressantlike activity.
HPA axis A hyperactive HPA axis has been associated with the pathophysiology of mood disorders. For instance, depressive symptoms occur in more than 50% of patients with Cushing’s syndrome or under treatment with exogenous corticosteroids. Hypercortisolemia may be central to the etiopathogenesis of both the depressive symptoms and the neurocognitive deficits observed in BPD. This major ‘stress pathway’ starts in the hypothalamic lateral ventricular nucleus, which stimulates the production of the adrenocorticotropin-releasing hormone (ACTH) in the pituitary, by releasing corticotropin-releasing factor (CRF). Sequentially, ACTH induces the production of glucocorticoids such as cortisol. A hyperactive HPA axis activates the CRF pathway and induces glucocorticoid hypersecretion, potentially leading to injury and atrophy on hippocampal neurons (which express high levels of glucocorticoid receptors (GRs)) [138,139]. Glucocorticoids were shown to decrease the expression of BDNF in the hippocampus, which may explain the inhibitory effects induced by corticosteroids at the neuroplasticity pathways. Recent data also indicate that two polymorphisms in FKBP5, a co-chaperone of the glucocorticoid receptor, were strongly associated with response to antidepressant therapy (reviewed in [140]). The antiglucocorticoid agents studied in the treatment of depression include both glucocorticoid synthesis inhibitors (aminoglutethimide, ketoconazole and metyrapone) and GR antagonists (mifepristone, hydrocortisone, dexamethasone and dehydroepiandrosterone (DHEA)) and CRF antagonists [141–144].
GR antagonists The antidepressants imipramine and phenelzine have been reported to have differential effects on corticosteroid receptor gene expression in mouse brain, suggesting that this effect might be relevant to antidepressant response [145]. In addition, glucocorticoid receptor antagonism was found to augment fluoxetine-induced down-regulation of the serotonin transporter [146], which would lead to greater availability of extracellular serotonin. In a mouse model of
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depression, the glucocorticoid receptor antagonist RU43044 was shown to have antidepressant-like effects, which were hypothesized to occur via inhibition of enhanced prefrontal dopaminergic neurotransmission [147]. In humans, the non-selective GR antagonist mifepristone (RU–486) possesses antidepressant and antipsychotic effects in psychotic depression [143]. In a six-week trial of 20 patients with bipolar depression, mifepristone (600 mg/day) improved depressive symptoms compared to placebo, as well as cognitive functioning, especially spatial memory [148]. However, two recent, large, phase III studies failed to find significant antipsychotic or antidepressant effects with mifepristone [149]. If mifepristone is ultimately found to have beneficial effects in BPD, its clinical use would be limited to acute depressive episodes; long-term treatment would have significant side effects, including the potential for adrenal insufficiency and hepatic injury [150]. In addition, mifepristone has significant antiprogesterone effects, and its chronic use could lead to fatigue, hot flashes, gynaecomastia/breast tenderness and endometrial hyperplasia [151].
Glucocorticoid synthesis inhibitors Treatment with glucocorticoid synthesis inhibitors (GSI) such as ketoconazole and metyrapone appears to significantly improve depressive symptoms in clinical and preclinical studies (reviewed in [144]). In a double–blind, randomized, placebo-controlled trial, metyrapone was effective as an adjunctive treatment in depression, accelerating the onset of antidepressant action [152]. Ketoconazole (up to 800 mg/day) was given as an add-on therapy to six depressed patients with a diagnosis of treatment-resistant BPD [153]. Reduced depressive symptoms were observed in three patients who received a dose of at least 400 mg/day, with no development of manic symptoms. Ketoconazole also reduced cortisol levels in individuals with BPD and depression, but these preliminary results need replication. Furthermore, the toxicity risk and drug interactions associated with ketoconazole use rule out its possible continuous use in mood disorders. Several classes of CRF 1R inhibitors have been identified (see [154,155] for a review). In preclinical studies, CRF 1 antagonists diminished CRF-induced ACTH release as well as CRF-induced cyclic adenosine monophosphate production. In an open-label study, R-121919 decreased anxiety and depressive symptoms in patients with MDD [156]. Antalarmin, a pyrrolopyrimidine compound, significantly reduced CRF-stimulated ACTH release as well as the pituitary-adrenal, sympathetic and adrenal medullary responses to stress in oral doses of 20 mg/kg in primates. It also reversed stress-induced inhibition of exploratory and sexual behaviours [157]. In mice, antalarmin (10 mg/kg)
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and fluoxetine (10 mg/kg) significantly improved measures of physical state, weight gain and emotional response in the chronic stress model [158]. This compound also decreased swim-stress-induced ACTH response, but showed no antidepressant-like effects in the FST [159]. The CRF inhibitor CP-154,526 also had antidepressant-like properties in the learned helplessness model. Like antalarmin, it has significant brain-barrier penetrability and decreases synthesis of CRF in the paraventricular nucleus [160,161]. Similarly, SSR125543A, a 2-aminothiazole derivative that displays a high affinity for human CRF R1 receptors, was able to reverse chronic mild stress-induced suppression of neurogenesis, also improving depressive-like symptoms and reducing aggressive behaviour in three different animal models [162–164].
CRF antagonists Many of the behavioural effects observed in animals after central administration of CRH mimic symptoms of depression in humans including behavioural despair, disrupted sleep patterns and decreased food consumption. Stress also elicits this response and is reversed by a specific CRH receptor antagonist [165]. Antidepressants in vitro modulate GR mRNA expression, GR protein levels and GR function [166]. Although there is strong preclinical evidence to support the efficacy of CRF antagonists in MDD, some initial clinical studies indicate that this is so far not the case. A recent, six-week, randomized, placebo-controlled trial of CP-316,311 (a selective CRH1 antagonist) failed to show efficacy in the treatment of MDD [167]. More studies are needed to definitively determine the relevance of this target in antidepressant efficacy.
Intracellular pathways and targets worthy of further study in BPD
effects. At present, no blood brain barrier-penetrant GSKselective inhibitor is available for human use; proof-ofprinciple studies with selective GSK inhibitors are needed to define the relevance of this target in BPD.
PKC signalling cascade PKC has a heterogeneous distribution in the brain, presents diverse isoforms and plays an important role in regulating neuronal excitability, neurotransmitter release and longterm alterations in gene expression and plasticity. Diverse data support the potential involvement of PKC and its substrates in the pathophysiology and therapeutics of BPD [171–176]. PKC is regulated by lithium and valproate, and a recent clinical trial provided further evidence for the involvement of this system in BPD. Although well-known for its anti-oestrogenic properties, tamoxifen is also a potent PKC inhibitor, especially at high concentrations, and has been shown to reduce amphetamine-induced hyperactivity in the OFT [177]. Clinically, a single-blind study of individuals with BPD found that tamoxifen had significant antimanic effects in five of seven BPD subjects [178]. This initial finding was confirmed in a recent, double-blind, placebocontrolled study. Tamoxifen showed significant antimanic effects at doses as high as 140 mg/day, as early as Day 5, and during the three weeks of the trial [179]. The antimanic effects of tamoxifen were not due to sedation, and no increased risk of depression was observed. Other studies have also confirmed the relevance of PKC inhibition in antimanic agents [180]. Indeed, it is possible that some of the antimanic effects seen with tamoxifen are attributable to oestrogen receptor antagonism ([181]). In addition, other drugs tested in BPD, such as omega-3 fatty acids and verapamil, also inhibit PKC activity. Overall, large controlled studies with selective PKC inhibitors in acute bipolar mania are warranted.
Glycogen synthase kinase-3 (GSK-3) GSK-3 is a serine/threonine kinase that is normally highly active in cells and is deactivated by signals originating from numerous signalling pathways (e.g. the Wnt pathway, the phosphoinositide 3-kinase pathway, protein kinase A and PKC). In general, increased activity of GSK-3 is proapoptotic, whereas inhibiting GSK-3 attenuates or prevents apoptosis. Lithium has neurotrophic and neuroprotective properties in rodent and in vitro models, and these effects may in part be due to inhibition of GSK-3 (reviewed in [168]). Mice overexpressing a constitutively active form of GSK-3b in the brain had enhanced locomotor activity as well as decreased habituation in the open field test (OFT). Also, the GSK-3 inhibitor AR-A014418 had significant antidepressant-like effects in the FST and attenuated D-amphetamine-induced hyperlocomotion [169,170], thus suggesting that this class of compounds has relevant antimanic and antidepressant
AA cascade Increasing evidence implicates the AA signalling pathway in BPD. AA functions as a key intermediary of second messenger pathways within the brain. This action results in the release of AA from the cellular membrane and cyclooxygenase (COX)-mediated production of eicosanoid metabolites, such as prostaglandins and thromboxanes. Administration of the nonselective COX inhibitors indomethacin and piroxicam in rats prevented amphetamine-stimulated locomotor activity, and blocked cocaine sensitization (both of which are rodent models of mania). Also, chronic lithium and valproate treatment in rats selectively decreases the turnover rate in brain phospholipids of AA, which are believed to be hyperactive in mania [182]. In addition, lithium downregulates the gene expression and protein levels of an AA-specific phospholipase as well as protein levels of
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COX-2. Similarly, valproate decreases turnover of AA, protein levels of COX-1 and COX-2 and frontal cortex COX-2 mRNA [183]. COX-2 also protects against neurotoxicity promoted by excessive concentrations of glutamate. Clinical trials have investigated the utility of celecoxib, a COX-2 inhibitor. A recent six-week, double blind, placebocontrolled trial of celecoxib (400 mg/day) found that it had superior antidepressant effects when used in conjunction with ongoing mood stabilizer treatment, but only during the first week of treatment [184]. Another study found that celecoxib (400 mg/day) showed significant antidepressant effects compared to placebo when used as an add-on to reboxetine [185]. However, the extent of celecoxib’s ability to penetrate the blood brain barrier remains unclear. In addition, it is also presently unclear whether directly targeting COX-2 is worthwhile, because selective COX-2 inhibitors may be associated with an increased risk of adverse cardiovascular outcomes [186].
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presently being studied in the treatment of neuropsychiatric disorders and neurodegenerative diseases. A previous animal study had suggested that RG2133, the prodrug of RG2417, had antidepressant-like effects. Repligen has initiated a phase IIb trial with 150 patients to test the utility of uridine RG2417 in the treatment of bipolar depressive episodes. Indeed, this follows promising, preliminary phase IIa results in the treatment of bipolar depression. In that previous, multicentre study, RG2417 administered twice daily was found to be more effective than placebo (unpublished findings). Over the 6-week treatment period, patients receiving uridine RG2417 experienced a statistically significant improvement in depression rating scale scores compared to those patients receiving placebo, as assessed by the MADRS (p ¼ 0.03). This study was conducted under a development agreement with the Stanley Medical Research Institute (study ID # NCT00322764; study details are available at: http://www.medicalnewstoday.com/articles/ 88213.php).
Other drug targets being investigated in BPD Multiple targets: modafinil Modafinil is approved by the FDA as a wakefulness-promoting agent for the treatment of excessive daytime sleepiness in narcolepsy [187]. The exact mechanism of action of modafinil is not well-known, but the drug is believed to target multiple systems, including glutamate, GABA, hypocretin and, to a smaller extent, the dopaminergic and noradrenergic systems. In mood disorders, modafinil appears to have therapeutic effects. A 6-week, randomized, double-blind, placebo-controlled study of modafinil (mean dose, 177 mg/day) in subjects with bipolar I or II depression who were receiving a mood-stabilizer with or without an antidepressant (n ¼ 87), modafinil significantly improved depressive symptoms versus placebo from Week 2 to endpoint [188]. No manic switches were reported. In another study, Frye and colleagues (unpublished data reported by [189]) compared the adjunctive use of modafinil (100 or 200 mg for 3 weeks) to placebo in BPD subjects with residual depressive symptoms, fatigue or both. Modafinil was significantly more effective than placebo on diverse measures, including the baseline-to-endpoint change on the Inventory for Depressive Symptoms, percentage response rate, remission rate and clinical global impression improvement. However, two recent case reports described a manic/hypomanic switch with this compound in patients with bipolar depression [190,191], and two other cases of modafinil-induced irritability and aggression in BPD patients have been reported [192].
Oxidative stress: N-acetyl cysteine (NAC) Increasing evidence has shown that BPD is associated with altered oxidative stress parameters [193,194]. Glutathione is the main antioxidant substrate in all tissues, and its production is rate-limited by its precursor, cysteine; notably, glutathione level changes have been described in BPD [195,196]. NAC would thus increase glutathione levels, leading to postulated benefits in BPD because of its antioxidant properties. A recent study by Berk and colleagues reported that NAC was indeed effective in the treatment of BPD [197], and the authors hypothesized that NAC’s efficacy might be due to its effects on oxidative stress. In this randomized, doubleblind, multicentre, placebo-controlled study, 75 patients with BPD were treated with NAC (1 g twice daily) during the maintenance phase; NAC was added to ongoing treatment over 24 weeks, followed by a four-week washout phase. The investigators observed that NAC significantly improved MADRS and most secondary scale scores by endpoint. Improvement was seen in the Global Assessment of Functioning (GAF) scale and the Social and Occupational Functioning Assessment Scale (SOFAS) at weeks, and the MADRS at 20 weeks. The benefits obtained were lost shortly after discontinuing the study medication. There were no significant differences in side effects compared to placebo; side effects numerically greater than placebo were headaches (18% NAC, 8% placebo), heartburn (16% NAC, 8% placebo) and increased joint pain (16% NAC, 8% placebo).
Multiple targets: uridine RG2417 Uridine RG2417 (Repligen corporation) – a biological compound critical for the synthesis of DNA and RNA – is
Bcl-2 The anti-apoptotic protein Bcl-2 and its family of proteins are well-known major modulators of cell survival and
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apoptosis [198–200]. Additional studies have confirmed that these proteins play critical roles in calcium homoeostasis [201], mitochondrial and endoplasmic reticulum (ER) function [201,202], neurogenesis [203], neuronal morphogenesis [204–206] and synaptic plasticity [207,208]. Research has indicated that the pharmacological enhancement of Bcl-2 expression/levels may have substantial value as therapeutics for mood disorders, because it would counteract the potentially deleterious effects of stress-induced neuronal endangerment. In preclinical studies, Bcl-2 heterozygous mutant mice demonstrated behaviours modelling two facets of mania: increased reward seeking and amphetamine sensitization, and this sensitization was attenuated by chronic lithium pretreatment [209]. Furthermore, lithium has been shown to increase Bcl-2 levels in neurons and lymphoblasts, as well as down-regulate increased calcium levels in lymphoblasts from individuals with BPD who also have Bcl-2 polymorphisms (Machado-Vieira et al., unpublished data). Indeed, it is possible that lithium’s antidepressant potentiating effects are due to its ability to robustly up-regulate Bcl-2. Similarly, pramipexole, a synthetic aminothiazole derivative dopamine D(2) agonist currently approved by the FDA for the treatment of Parkinson’s Disease, up-regulates Bcl-2 levels in several brain areas [210]. This compound also exerted antidepressant effects in two small, double-blind, placebo-controlled studies in bipolar depression. Goldberg and colleagues randomized 22 patients with bipolar depression to receive pramipexole (1.0–2.5 mg/day) plus a mood stabilizer, or placebo plus a mood stabilizer [211]. Pramipexole was well-tolerated, and more patients in the pramipexole group achieved a 50% reduction from their baseline Hamilton Depression Rating Scale (HAM-D) scores after 6 weeks. Another study of 21 patients with BPD II found that 60% of patients receiving pramipexole (1.0–3.0 mg/day) plus a mood stabilizer achieved antidepressant response (50% improvement in MADRS) compared with 9% in the placebo plus mood stabilizer group [212]. The switch rates into mania and hypomania were not significantly higher than in the placebo group. Future studies are warranted to assess whether selective Bcl-2 enhancers without dopaminergic effects are also effective in treating bipolar depression.
Bioenergetics: creatine Creatine has a key role in brain energy homoeostasis and its dysfunction has been implicated in BPD. Thus, creatine supplementation may modify brain high-energy phosphate metabolism in subjects with BPD. An open-label study consisting of 10 treatment-resistant depressed patients (2 of whom had BPD) found that 3–5 mg/day of creatine monohydrate added to ongoing treatment significantly improved
depressive symptoms in patients with MDD, but the two patients with BPD developed transient hypomanic/manic symptoms [213]. Further studies are necessary to clarify the role of creatine in treating BPD.
Conclusion As this paper has reviewed, a number of targets/compounds could result in putative novel treatments for BPD. These include the dynorphin opioid neuropeptide system, the purinergic system, the cholinergic system (muscarinic and nicotinic systems), the melatonin and serotonin [5-hydroxytryptamine receptor 2C (5-HT2C)] system, the glutamatergic system and the HPA axis. In addition, the GSK intracellular signalling cascade, the AA cascade, PKC, Bcl-2 and the oxidative stress system all merit further study. As detailed above, several drugs not in routine clinical use are being used and studied in the treatment of BPD. These treatments are currently available (with the exception of uridine RG2417) but are not anticonvulsants, antipsychotics or conventional antidepressants. The drugs reviewed here include pentazocine, allopurinol, physostigmine, donepezil, mecamylamine, modafinil, pramipexole, N-acetyl cysteine, scopolamine, agomelatine, riluzole, memantine, ketamine, AMPA potentiators, mifepristone, celecoxib, creatine and uridine RG2417, amongst others. It is important to emphasize that none of these drugs are FDA-approved for the treatment of mood disorders. In addition, most of the evidence presented here comes from case reports, case series or proof-of-concept studies, some with very small sample sizes. Thus, generalizability of such preliminary findings to current clinical practice patterns would be premature. A better understanding of the neurobiological underpinnings of BPD, informed by preclinical and clinical research, will be essential for the future development of targeted therapies that are more effective, act more rapidly and are better tolerated than currently available treatments. Improved criteria for establishing target validation for further development in BPD have been proposed [175,214]. These include: (1) corroboration of a target at the protein and functional level; (2) observation with chemically dissimilar but clinically effective agents; (3) occurrence at a dose/ plasma level and time frame consistent with clinical therapeutic effect; (4) localization to brain regions implicated in the neurobiology of the disorder under consideration; (5) when known, relevance to known pathophysiology; and (6) when possible, link to human genetic findings. We believe the findings reviewed above can guide promising future directions in drug development for BPD. Overall, further study of these and similar drugs may lead to a better understanding of relevant drug targets and their clinical utility as therapeutics for this devastating illness.
Novel Therapeutic Strategies
Acknowledgements Funding for this work was supported by the Intramural Research Program of the National Institute of Mental Health (NIMH) and a NARSAD Award (CAZ). Ioline Henter provided outstanding editorial assistance. A patent application for the use of ketamine in depression has been submitted listing Drs Zarate and Manji amongst the inventors. Drs Zarate and Manji have assigned their rights on the patent to the US government. Dr Manji is now an employee of Johnson & Johnson Pharmaceutical Research and Development.
References 1. Gitlin, M. (2006) Treatment-resistant bipolar disorder. Mol. Psychiatry, 11, 227–240. 2. Judd, L.L., Akiskal, H.S., Schettler, P.J. et al. (2002) The longterm natural history of the weekly symptomatic status of bipolar I disorder. Arch. Gen. Psychiatry, 59, 530–537. 3. Sachs, G.S., Nierenberg, A.A., Calabrese, J.R. et al. (2007) Effectiveness of adjunctive antidepressant treatment for bipolar depression. N. Engl. J. Med., 356, 1711–1722. 4. Trivedi, M.H., Rush, A.J., Wisniewski, S.R. et al. (2006) Evaluation of outcomes with citalopram for depression using measurement-based care in STAR D: implications for clinical practice. Am. J. Psychiatry, 163, 28–40. 5. Hurd, Y.L. (2002) Subjects with major depression or bipolar disorder show reduction of prodynorphin mRNA expression in discrete nuclei of the amygdaloid complex. Mol. Psychiatry, 7, 75–81. 6. Roth, B.L., Baner, K., Westkaemper, R. et al. (2002) Salvinorin A: a potent naturally occurring nonnitrogenous kappa opioid selective agonist. Proc. Natl. Acad. Sci. USA, 99, 11934–11939. 7. Barber, A. and Gottschlich, R. (1997) Novel developments with selective, non-peptidic kappa-opioid receptor agonists. Expert Opin. Investig. Drugs, 6, 1351–1368. 8. Carlezon, W.A. Jr, Beguin, C., DiNieri, J.A. et al. (2006) Depressive-like effects of the kappa-opioid receptor agonist salvinorin A on behavior and neurochemistry in rats. J. Pharmacol. Exp. Ther., 316, 440–447. 9. Mague, S.D., Pliakas, A.M., Todtenkopf, M.S. et al. (2003) Antidepressant-like effects of kappa-opioid receptor antagonists in the forced swim test in rats. J. Pharmacol. Exp. Ther., 305, 323–330. 10. Reindl, J.D., Rowan, K., Carey, A.N. et al. (2008) Antidepressant-like effects of the novel kappa opioid antagonist MCL-144B in the forced-swim test. Pharmacology, 81, 229–235. 11. Rimoy, G.H., Wright, D.M., Bhaskar, N.K. et al. (1994) The cardiovascular and central nervous system effects in the human of U-62066E. A selective opioid receptor agonist. Eur. J. Clin. Pharmacol., 46, 203–207. 12. Walsh, S.L., Strain, E.C., Abreu, M.E. et al. (2001) Enadoline, a selective kappa opioid agonist: comparison with butorphanol and hydromorphone in humans. Psychopharmacology (Berl.), 157, 151–162.
|
405
13. Cohen, B.M. and Murphy, B. (2008) The effects of pentazocine, a kappa agonist, in patients with mania. Int. J. Neuropsychopharmacol., 11, 243–247. 14. Cade, J.F.J. (1949) Lithium salts in the treatment of psychotic excitement. Med. J. Australia, 2, 349–352. 15. Anumonye, A., Reading, H.W., Knight, F. et al. (1968) Uricacid metabolism in manic-depressive illness and during lithium therapy. Lancet, 1, 1290–1293. 16. Machado-Vieira, R., Lara, D.R., Souza, D.O. et al. (2002) Purinergic dysfunction in mania: an integrative model. Med. Hypotheses, 58, 297–304. 17. Ogawa, N. and Ueki, H. (2003) Secondary mania caused by caffeine. Gen. Hosp. Psychiatry, 25, 138–139. 18. Lara, D.R., Dall’Igna, O.P., Ghisolfi, E.S. et al. (2006) Involvement of adenosine in the neurobiology of schizophrenia and its therapeutic implications. Prog. Neuropsychopharmacol. Biol. Psychiatry, 30, 617–629. 19. Barden, N., Harvey, M., Gagne, B. et al. (2006) Analysis of single nucleotide polymorphisms in genes in the chromosome 12Q24.31 region points to P2RX7 as a susceptibility gene to bipolar affective disorder. Am. J. Med. Genet. B Neuropsychiatr. Genet., 141B, 374–382. 20. Lucae, S., Salyakina, D., Barden, N. et al. (2006) P2RX7, a gene coding for a purinergic ligand-gated ion channel, is associated with major depressive disorder. Hum. Mol. Genet., 15, 2438–2445. 21. Machado-Vieira, R., Soares, J.C., Lara, D.R. et al. (2008) A double-blind, randomized, placebo-controlled 4-week study on the efficacy and safety of the purinergic agents allopurinol and dipyridamole adjunctive to lithium in acute bipolar mania. J. Clin. Psychiatry, 69, 1237–1245. 22. Machado-Vieira, R., Lara, D.R., Souza, D.O. et al. (2001) Therapeutic efficacy of allopurinol in mania associated with hyperuricemia. J. Clin. Psychopharmacol., 21, 621–622. 23. Akhondzadeh, S., Milajerdi, M.R., Amini, H. et al. (2006) Allopurinol as an adjunct to lithium and haloperidol for treatment of patients with acute mania: a double-blind, randomized, placebo-controlled trial. Bipolar Disord., 8, 485–489. 24. Janowsky, D.S., el-Yousef, M.K., Davis, J.M. et al. (1972) A cholinergic-adrenergic hypothesis of mania and depression. Lancet, 2, 632–635. 25. Kasper, S., Moises, H.W. and Beckmann, H. (1981) The anticholinergic biperiden in depressive disorders. Pharmacopsychiatria, 14, 195–198. 26. Overstreet, D.H. (1993) The Flinders sensitive line rats: a genetic animal model of depression. Neurosci. Biobehav. Rev., 17, 51–68. 27. Dilsaver, S.C. (1986) Cholinergic-monoaminergic interaction in the pathophysiology of the affective disorders? Int. Clin. Psychopharmacol., 1, 181–198. 28. Dilsaver, S.C. (1986) Pharmacologic induction of cholinergic system up-regulation and supersensitivity in affective disorders research. J. Clin. Psychopharmacol., 6, 65–74. 29. Sokolski, K.N. and DeMet, E.M. (2000) Cholinergic sensitivity predicts severity of mania. Psychiatry Res., 95, 195–200. 30. Cannon, D.M., Carson, R.E., Nugent, A.C. et al. (2006) Reduced muscarinic type 2 receptor binding in subjects with bipolar disorder. Arch. Gen. Psychiatry, 63, 741–747.
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31. Davis, K.L., Berger, P.A., Hollister, L.E. et al. (1978) Physostigmine in mania. Arch. Gen. Psychiatry, 35, 119–122. 32. Khouzam, H.R. and Kissmeyer, P.M. (1996) Physostigmine temporarily and dramatically reversing acute mania. Gen. Hosp. Psychiatry, 18, 203–204. 33. Burt, T., Sachs, G.S. and Demopulos, C. (1999) Donepezil in treatment-resistant bipolar disorder. Biol. Psychiatry, 45, 959–964. 34. Eden Evins, A., Demopulos, C., Nierenberg, A. et al. (2006) A double-blind, placebo-controlled trial of adjunctive donepezil in treatment-resistant mania. Bipolar Disord., 8, 75–80. 35. Furey, M.L. and Drevets, W.C. (2006) Antidepressant efficacy of the antimuscarinic drug scopolamine: a randomized, placebo-controlled clinical trial. Arch. Gen. Psychiatry, 63, 1121–1129. 36. Jellinek, T. (1977) Mood elevating effect of trihexyphenidyl and biperiden in individuals taking antipsychotic medication. Dis. Nerv. Syst., 38, 353–355. 37. Shi, J., Hattori, E., Zou, H. et al. (2007) No evidence for association between 19 cholinergic genes and bipolar disorder. Am. J. Med. Genet. B Neuropsychiatr. Genet., 144B, 715–723. 38. Epping-Jordan, M.P., Watkins, S.S., Koob, G.F. et al. (1998) Dramatic decreases in brain reward function during nicotine withdrawal. Nature, 393, 76–79. 39. Ferguson, S.M., Brodkin, J.D., Lloyd, G.K. et al. (2000) Antidepressant-like effects of the subtype-selective nicotinic acetylcholine receptor agonist, SIB-1508Y, in the learned helplessness rat model of depression. Psychopharmacology (Berl.), 152, 295–303. 40. Semba, J., Mataki, C., Yamada, S. et al. (1998) Antidepressantlike effects of chronic nicotine on learned helplessness paradigm in rats. Biol. Psychiatry, 43, 389–391. 41. Tizabi, Y., Overstreet, D.H., Rezvani, A.H. et al. (1999) Antidepressant effects of nicotine in an animal model of depression. Psychopharmacology (Berl.), 142, 193–199. 42. Mineur, Y.S., Somenzi, O. and Picciotto, M.R. (2007) Cytisine, a partial agonist of high-affinity nicotinic acetylcholine receptors, has antidepressant-like properties in male C57BL/6J mice. Neuropharmacology, 52, 1256–1262. 43. Andreasen, J.T., Olsen, G.M., Wiborg, O. et al. (2008) Antidepressant-like effects of nicotinic acetylcholine receptor antagonists, but not agonists, in the mouse forced swim and mouse tail suspension tests. J. Psychopharmacol., 23, 797–804. 44. De Luca, V., Likhodi, O., Van Tol, H.H. et al. (2006) Regulation of alpha7-nicotinic receptor subunit and alpha7-like gene expression in the prefrontal cortex of patients with bipolar disorder and schizophrenia. Acta Psychiatr. Scand, 114, 211–215. 45. Miller, D.K. and Segert, I.L. (2005) Mecamylamine attenuates ephedrine-induced hyperactivity in rats. Pharmacol. Biochem. Behav., 81, 165–169. 46. Rabenstein, R.L., Caldarone, B.J. and Picciotto, M.R. (2006) The nicotinic antagonist mecamylamine has antidepressant-like effects in wild-type but not beta2- or alpha7nicotinic acetylcholine receptor subunit knockout mice. Psychopharmacology (Berl.), 189, 395–401.
47. Shytle, R.D., Silver, A.A. and Sanberg, P.R. (2000) Comorbid bipolar disorder in Tourette’s syndrome responds to the nicotinic receptor antagonist mecamylamine (Inversine). Biol. Psychiatry, 48, 1028–1031. 48. Shytle, R.D., Silver, A.A., Lukas, R.J. et al. (2002) Nicotinic acetylcholine receptors as targets for antidepressants. Mol. Psychiatry, 7, 525–535. 49. Alaerts, M., Venken, T., Lenaerts, A.S. et al. (2006) Lack of association of an insertion/deletion polymorphism in the G protein-coupled receptor 50 with bipolar disorder in a Northern Swedish population. Psychiatr. Genet., 16, 235–236. 50. Thomson, P.A., Wray, N.R., Thomson, A.M. et al. (2005) Sexspecific association between bipolar affective disorder in women and GPR50, an X-linked orphan G protein-coupled receptor. Mol. Psychiatry, 10, 470–478. 51. Hallam, K.T., Olver, J.S. and Norman, T.R. (2005) Melatonin sensitivity to light in monozygotic twins discordant for bipolar I disorder. Aust. N. Z. J. Psychiatry, 39, 947. 52. Lewy, A.J., Nurnberger, J.I. Jr, Wehr, T.A. et al. (1985) Supersensitivity to light: possible trait marker for manicdepressive illness. Am. J. Psychiatry, 142, 725–727. 53. Lewy, A.J., Wehr, T.A., Goodwin, F.K. et al. (1981) Manicdepressive patients may be supersensitive to light. Lancet, 1, 383–384. 54. Nurnberger, J.I. Jr, Adkins, S., Lahiri, D.K. et al. (2000) Melatonin suppression by light in euthymic bipolar and unipolar patients. Arch. Gen. Psychiatry, 57, 572–579. 55. Hallam, K.T., Olver, J.S., Horgan, J.E. et al. (2005) Low doses of lithium carbonate reduce melatonin light sensitivity in healthy volunteers. Int. J. Neuropsychopharmacol., 8, 255–259. 56. Hallam, K.T., Olver, J.S. and Norman, T.R. (2005) Effect of sodium valproate on nocturnal melatonin sensitivity to light in healthy volunteers. Neuropsychopharmacology, 30, 1400–1404. 57. Srinivasan, V., Smits, M., Spence, W. et al. (2006) Melatonin in mood disorders. World J. Biol. Psychiatry, 7, 138–151. 58. Bersani, G. and Garavini, A. (2000) Melatonin add-on in manic patients with treatment resistant insomnia. Prog. Neuropsychopharmacol. Biol. Psychiatry, 24, 185–191. 59. Van Oekelen, D., Luyten, W.H. and Leysen, J.E. (2003) 5-HT2A and 5-HT2C receptors and their atypical regulation properties. Life Sci., 72, 2429–2449. 60. Dolder, C.R., Nelson, M. and Snider, M. (2008) Agomelatine treatment for major depressive disorder. Ann. Pharmacol. Ther., 42, 1822–1831. 61. Armstrong, S.M., McNulty, O.M., Guardiola-Lemaitre, B. et al. (1993) Successful use of S20098 and melatonin in an animal model of delayed sleep-phase syndrome (DSPS). Pharmacol. Biochem. Behav., 46, 45–49. 62. Nagayama, H. (1996) Chronic administration of imipramine and lithium changes the phase-angle relationship between the activity and core body temperature circadian rhythms in rats. Chronobiol. Int., 13, 251–259. 63. Redman, J.R. and Francis, A.J. (1998) Entrainment of rat circadian rhythms by the melatonin agonist S-20098 requires intact suprachiasmatic nuclei but not the pineal. J. Biol. Rhythms, 13, 39–51.
Novel Therapeutic Strategies 64. Kennedy, S.H. and Emsley, R. (2006) Placebo-controlled trial of agomelatine in the treatment of major depressive disorder. Eur. Neuropsychopharmacol., 16, 93–100. 65. Loo, H., Hale, A. and D’Haenen, H. (2002) Determination of the dose of agomelatine, a melatoninergic agonist and selective 5-HT(2C) antagonist, in the treatment of major depressive disorder: a placebo-controlled dose range study. Int. Clin. Psychopharmacol., 17, 239–247. 66. Montgomery, S.A. and Kasper, S. (2007) Severe depression and antidepressants: focus on a pooled analysis of placebocontrolled studies on agomelatine. Int. Clin. Psychopharmacol., 22, 283–291. 67. Bertaina-Anglade, V., la Rochelle, C.D., Boyer, P.A. et al. (2006) Antidepressant-like effects of agomelatine (S 20098) in the learned helplessness model. Behav. Pharmacol., 17, 703–713. 68. Millan, M.J., Brocco, M., Gobert, A. et al. (2005) Anxiolytic properties of agomelatine, an antidepressant with melatoninergic and serotonergic properties: role of 5-HT2C receptor blockade. Psychopharmacology (Berl.), 177, 448–458. 69. Papp, M., Gruca, P., Boyer, P.A. et al. (2003) Effect of agomelatine in the chronic mild stress model of depression in the rat. Neuropsychopharmacology, 28, 694–703. 70. Banasr, M., Soumier, A., Hery, M. et al. (2006) Agomelatine, a new antidepressant, induces regional changes in hippocampal neurogenesis. Biol. Psychiatry, 59, 1087–1096. 71. Calabrese, J.R., Guelfi, J.D. and Perdrizet-Chevallier, C. (2007) Agomelatine adjunctive therapy for acute bipolar depression: preliminary open data. Bipolar Disord., 9, 628–635. 72. Bannerman, D.M., Good, M.A., Butcher, S.P. et al. (1995) Distinct components of spatial learning revealed by prior training and NMDA receptor blockade. Nature, 378, 182–186. 73. Collingridge, G.L. (1994) Long-term potentiation. A question of reliability. Nature, 371, 652–653. 74. Collingridge, G.L. and Bliss, T.V. (1995) Memories of NMDA receptors and LTP. Trends Neurosci., 18, 54–56. 75. Watkins, J. and Collingridge, G. (1994) Phenylglycine derivatives as antagonists of metabotropic glutamate receptors. Trends Pharmacol. Sci., 15, 333–342. 76. Zarate, C.A., Quiroz, J., Payne, J. et al. (2002) Modulators of the glutamatergic system: implications for the development of improved therapeutics in mood disorders. Psychopharmacol. Bull., 36, 35–83. 77. Zarate, C.A. Jr, Singh, J.B., Carlson, P.J. et al. (2006) A randomized trial of an N-methyl-D-aspartate antagonist in treatment-resistant major depression. Arch. Gen. Psychiatry, 63, 856–864. 78. Frizzo, M.E., Dall’Onder, L.P., Dalcin, K.B. et al. (2004) Riluzole enhances glutamate uptake in rat astrocyte cultures. Cell Mol. Neurobiol., 24, 123–128. 79. Mizuta, I., Ohta, M., Ohta, K. et al. (2001) Riluzole stimulates nerve growth factor, brain-derived neurotrophic factor and glial cell line-derived neurotrophic factor synthesis in cultured mouse astrocytes. Neurosci. Lett., 310, 117–120. 80. Zarate, C.A. Jr, Payne, J.L., Quiroz, J. et al. (2004) An openlabel trial of riluzole in patients with treatment-resistant major depression. Am. J. Psychiatry, 161, 171–174.
|
407
81. Zarate, C.A. Jr, Quiroz, J.A., Singh, J.B. et al. (2005) An openlabel trial of the glutamate-modulating agent riluzole in combination with lithium for the treatment of bipolar depression. Biol. Psychiatry, 57, 430–432. 82. Lourenco Da Silva, A., Hoffmann, A., Dietrich, M.O. et al. (2003) Effect of riluzole on MK-801 and amphetamineinduced hyperlocomotion. Neuropsychobiology, 48, 27–30. 83. Chen, H.S. and Lipton, S.A. (1997) Mechanism of memantine block of NMDA-activated channels in rat retinal ganglion cells: uncompetitive antagonism. J. Physiol., 499 (Pt 1), 27–46. 84. Chen, H.S., Wang, Y.F., Rayudu, P.V. et al. (1998) Neuroprotective concentrations of the N-methyl-D-aspartate open-channel blocker memantine are effective without cytoplasmic vacuolation following post-ischemic administration and do not block maze learning or long-term potentiation. Neuroscience, 86, 1121–1132. 85. Moryl, E., Danysz, W. and Quack, G. (1993) Potential antidepressive properties of amantadine, memantine and bifemelane. Pharmacol. Toxicol., 72, 394–397. 86. Rogoz, Z., Skuza, G. and Danysz, W. (2002) Synergistic effect of uncompetitive NMDA receptor antagonists and antidepressant drugs in the forced swimming test in rats. Neuropharmacology, 42, 1024–1030. 87. Zarate, C.A. Jr, Singh, J.B., Quiroz, J.A. et al. (2006) A double-blind, placebo-controlled study of memantine in the treatment of major depression. Am. J. Psychiatry, 163, 153–155. 88. Muhonen, L.H., Lonnqvist, J., Juva, K. et al. (2008) Doubleblind, randomized comparison of memantine and escitalopram for the treatment of major depressive disorder comorbid with alcohol dependence. J. Clin. Psychiatry, 69, 392–399. 89. Teng, C.T. and Demetrio, F.N. (2006) Memantine may acutely improve cognition and have a mood stabilizing effect in treatment-resistant bipolar disorder. Rev. Bras. Psiquiatr., 28, 252–254. 90. Loscher, W. and Honack, D. (1990) High doses of memantine (1-amino-3,5-dimethyladamantane) induce seizures in kindled but not in non-kindled rats. Naunyn. Schmiedebergs Arch. Pharmacol., 341, 476–481. 91. Moghaddam, B., Adams, B., Verma, A. et al. (1997) Activation of glutamatergic neurotransmission by ketamine: a novel step in the pathway from NMDA receptor blockade to dopaminergic and cognitive disruptions associated with the prefrontal cortex. J. Neurosci., 17, 2921–2927. 92. Aguado, L., San Antonio, A., Perez, L. et al. (1994) Effects of the NMDA receptor antagonist ketamine on flavor memory: conditioned aversion, latent inhibition, and habituation of neophobia. Behav. Neural. Biol., 61, 271–281. 93. Garcia, L.S., Comim, C.M., Valvassori, S.S. et al. (2008) Acute administration of ketamine induces antidepressant-like effects in the forced swimming test and increases BDNF levels in the rat hippocampus. Prog. Neuropsychopharmacol. Biol. Psychiatry, 32, 140–144. 94. Maeng, S., Zarate, C.A. Jr, Du, J. et al. (2008) Cellular mechanisms underlying the antidepressant effects of ketamine: role of alpha-amino-3-hydroxy-5-methylisoxazole4-propionic acid receptors. Biol. Psychiatry, 63, 349–352.
408
|
Chapter 30
95. Mickley, G.A., Schaldach, M.A., Snyder, K.J. et al. (1998) Ketamine blocks a conditioned taste aversion (CTA) in neonatal rats. Physiol. Behav., 64, 381–390. 96. Silvestre, J.S., Nadal, R., Pallares, M. et al. (1997) Acute effects of ketamine in the holeboard, the elevated-plus maze, and the social interaction test in Wistar rats. Depress Anxiety, 5, 29–33. 97. Berman, R.M., Cappiello, A., Anand, A. et al. (2000) Antidepressant effects of ketamine in depressed patients. Biol. Psychiatry, 47, 351–354. 98. Salvadore, G., Cornwell, B.R., Colon-Rosario, V. et al. (2009) Increased anterior cingulate cortical activity in response to fearful faces: A neurophysiological biomarker that predicts rapid antidepressant response to ketamine. Biol. Psychiatry, 65, 289–295. 99. Phelps, L.E., Brutsche, N., Moral, J.R. et al. (2000) Family history of alcohol dependence and initial antidepressant response to an N-methyl-D-aspartate antagonist. Biol. Psychiatry, 65, 181–184. 100. Machado-Vieira, R., Yuan, P., Brutsche, N. et al. (2009) Brain derived neurotrophic factor and initial antidepressant response to an N-methyl-D-aspartate antagonist. J. Clin. Psychiatry, 70, 1662–1666. 101. Maeng, S. and Zarate, C.A. Jr (2007) The role of glutamate in mood disorders: results from the ketamine in major depression study and the presumed cellular mechanism underlying its antidepressant effects. Curr. Psychiatry Rep., 9, 467–474. 102. Papp, M. and Moryl, E. (1993) New evidence for the antidepressant activity of MK-801, a non-competitive antagonist of NMDA receptors. Pol. J. Pharmacol., 45, 549–553. 103. Przegalinski, E., Tatarczynska, E., Deren-Wesolek, A. et al. (1997) Antidepressant-like effects of a partial agonist at strychnine-insensitive glycine receptors and a competitive NMDA receptor antagonist. Neuropharmacology, 36, 31–37. 104. Trullas, R. and Skolnick, P. (1990) Functional antagonists at the NMDA receptor complex exhibit antidepressant actions. Eur. J. Pharmacol., 185, 1–10. 105. Zarate, C.A. Jr, Du, J., Quiroz, J. et al. (2003) Regulation of cellular plasticity cascades in the pathophysiology and treatment of mood disorders: role of the glutamatergic system. Ann. N. Y. Acad. Sci., 1003, 273–291. 106. Meloni, D., Gambarana, C., De Montis, M.G. et al. (1993) Dizocilpine antagonizes the effect of chronic imipramine on learned helplessness in rats. Pharmacol. Biochem. Behav., 46, 423–426. 107. Padovan, C.M. and Guimaraes, F.S. (2004) Antidepressantlike effects of NMDA-receptor antagonist injected into the dorsal hippocampus of rats. Pharmacol. Biochem. Behav., 77, 15–19. 108. Skolnick, P., Miller, R., Young, A. et al. (1992) Chronic treatment with 1-aminocyclopropanecarboxylic acid desensitizes behavioral responses to compounds acting at the N-methyl-D-aspartate receptor complex. Psychopharmacology (Berl.), 107, 489–496. 109. Dall’Olio, R., Rimondini, R. and Gandolfi, O. (1994) The NMDA positive modulator D-cycloserine inhibits dopamine-mediated behaviors in the rat. Neuropharmacology, 33, 55–59.
110. McAllister, K.H. (1994) d-cycloserine enhances social behavior in individually-housed mice in the resident-intruder test. Psychopharmacology (Berl.), 116, 317–325. 111. Black, M.D. (2005) Therapeutic potential of positive AMPA modulators and their relationship to AMPA receptor subunits. A review of preclinical data. Psychopharmacology (Berl.), 179, 154–163. 112. Bleakman, D. and Lodge, D. (1998) Neuropharmacology of AMPA and kainate receptors. Neuropharmacology, 37, 1187–1204. 113. Borges, K. and Dingledine, R. (1998) AMPA receptors: molecular and functional diversity. Prog. Brain Res., 116, 153–170. 114. Miu, P., Jarvie, K.R., Radhakrishnan, V. et al. (2001) Novel AMPA receptor potentiators LY392098 and LY404187: effects on recombinant human AMPA receptors in vitro. Neuropharmacology, 40, 976–983. 115. Knapp, R.J., Goldenberg, R., Shuck, C. et al. (2002) Antidepressant activity of memory-enhancing drugs in the reduction of submissive behavior model. Eur. J. Pharmacol., 440, 27–35. 116. Donevan, S.D. and Rogawski, M.A. (1993) GYKI 52466, a 2,3-benzodiazepine, is a highly selective, noncompetitive antagonist of AMPA/kainate receptor responses. Neuron., 10, 51–59. 117. Rogawski, M.A. (2006) Diverse mechanisms of antiepileptic drugs in the development pipeline. Epilepsy Res., 69, 273–294. 118. Pitkanen, A., Mathiesen, C., Ronn, L.C. et al. (2007) Effect of novel AMPA antagonist, NS1209, on status epilepticus. An experimental study in rat. Epilepsy Res., 74, 45–54. 119. Nielsen, E.O., Varming, T., Mathiesen, C. et al. (1999) SPD 502: a water-soluble and in vivo long-lasting AMPA antagonist with neuroprotective activity. J. Pharmacol. Exp. Ther., 289, 1492–1501. 120. Bai, F., Bergeron, M. and Nelson, D.L. (2003) Chronic AMPA receptor potentiator (LY451646) treatment increases cell proliferation in adult rat hippocampus. Neuropharmacology, 44, 1013–1021. 121. Sanacora, G., Zarate, C.A., Krystal, J.H. et al. (2008) Targeting the glutamatergic system to develop novel, improved therapeutics for mood disorders. Nat. Rev. Drug Discov., 7, 426–437. 122. Conn, P.J. and Pin, J.P. (1997) Pharmacology and functions of metabotropic glutamate receptors. Annu. Rev. Pharmacol. Toxicol., 37, 205–237. 123. Li, X., Need, A.B., Baez, M. et al. (2006) Metabotropic glutamate 5 receptor antagonism is associated with antidepressant-like effects in mice. J. Pharmacol. Exp. Ther., 319, 254–259. 124. Wieronska, J.M., Szewczyk, B., Branski, P. et al. (2002) Antidepressant-like effect of MPEP, a potent, selective and systemically active mGlu5 receptor antagonist in the olfactory bulbectomized rats. Amino Acids, 23, 213–216. 125. Legutko, B., Szewczyk, B., Pomierny-Chamiolo, L. et al. (2006) Effect of MPEP treatment on brain-derived neurotrophic factor gene expression. Pharmacol. Rep., 58, 427–430. 126. Belozertseva, I.V., Kos, T., Popik, P. et al. (2007) Antidepressant-like effects of mGluR1 and mGluR5 antagonists in the
Novel Therapeutic Strategies
127.
128.
129.
130.
131.
132.
133.
134.
135.
136.
137.
138.
139.
rat forced swim and the mouse tail suspension tests. Eur. Neuropsychopharmacol., 17, 172–179. Porter, R.H., Jaeschke, G., Spooren, W. et al. (2005) Fenobam: a clinically validated nonbenzodiazepine anxiolytic is a potent, selective, and noncompetitive mGlu5 receptor antagonist with inverse agonist activity. J. Pharmacol. Exp. Ther., 315, 711–721. Kinney, G.G., O’Brien, J.A., Lemaire, W. et al. (2005) A novel selective positive allosteric modulator of metabotropic glutamate receptor subtype 5 has in vivo activity and antipsychotic-like effects in rat behavioral models. J. Pharmacol. Exp. Ther., 313, 199–206. Du, J., Suzuki, K., Wei, Y. et al. (2007) The anticonvulsants lamotrigine, riluzole, and valproate differentially regulate AMPA receptor membrane localization: relationship to clinical effects in mood disorders. Neuropsychopharmacology, 32, 793–802. Du, J., Gray, N.A., Falke, C.A. et al. (2004) Modulation of synaptic plasticity by antimanic agents: the role of AMPA glutamate receptor subunit 1 synaptic expression. J. Neurosci., 24, 6578–6589. Chaki, S., Hirota, S., Funakoshi, T. et al. (2003) Anxiolyticlike and antidepressant-like activities of MCL0129 (1-[(S)-2(4-fluorophenyl)-2-(4-isopropylpiperadin-1-yl)ethyl]-4-[4(2-met hoxynaphthalen-1-yl)butyl]piperazine), a novel and potent nonpeptide antagonist of the melanocortin-4 receptor. J. Pharmacol. Exp. Ther., 304, 818–826. Yoshimizu, T., Shimazaki, T., Ito, A. et al. (2006) An mGluR2/3 antagonist, MGS0039, exerts antidepressant and anxiolytic effects in behavioral models in rats. Psychopharmacology (Berl.), 186, 587–593. Yoshimizu, T. and Chaki, S. (2004) Increased cell proliferation in the adult mouse hippocampus following chronic administration of group II metabotropic glutamate receptor antagonist, MGS0039. Biochem. Biophys Res. Commun., 315, 493–496. Karasawa, J., Shimazaki, T., Kawashima, N. et al. (2005) AMPA receptor stimulation mediates the antidepressantlike effect of a group II metabotropic glutamate receptor antagonist. Brain Res., 1042, 92–98. Gasparini, F., Bruno, V., Battaglia, G. et al. (1999) (R,S)-4phosphonophenylglycine, a potent and selective group III metabotropic glutamate receptor agonist, is anticonvulsive and neuroprotective in vivo. J. Pharmacol. Exp. Ther., 289, 1678–1687. Cryan, J.F., Kelly, P.H., Neijt, H.C. et al. (2003) Antidepressant and anxiolytic-like effects in mice lacking the group III metabotropic glutamate receptor mGluR7. Eur. J. Neurosci., 17, 2409–2417. Palucha, A., Tatarczynska, E., Branski, P. et al. (2004) Group III mGlu receptor agonists produce anxiolytic- and antidepressant-like effects after central administration in rats. Neuropharmacology, 46, 151–159. Brown, E.S., Frol, A., Bobadilla, L. et al. (2003) Effect of lamotrigine on mood and cognition in patients receiving chronic exogenous corticosteroids. Psychosomatics, 44, 204–208. Duman, R.S. and Monteggia, L.M. (2006) A neurotrophic model for stress-related mood disorders. Biol. Psychiatry, 59, 1116–1127.
|
409
140. Kirchheiner, J., Lorch, R., Lebedeva, E. et al. (2008) Genetic variants in FKBP affecting response to antidepressant drug treatment. Pharmacogenomics, 9, 841–846. 141. Arana, G.W. (1991) Dexamethasone suppression test in the diagnosis of depression. JAMA, 265, 2253–2254. 142. Arana, G.W., Santos, A.B., Laraia, M.T. et al. (1995) Dexamethasone for the treatment of depression: a randomized, placebo-controlled, double-blind trial. Am. J. Psychiatry, 152, 265–267. 143. Belanoff, J.K., Rothschild, A.J., Cassidy, F. et al. (2002) An open label trial of C-1073 (mifepristone) for psychotic major depression. Biol. Psychiatry, 52, 386–392. 144. Quiroz, J.A., Singh, J., Gould, T.D. et al. (2004) Emerging experimental therapeutics for bipolar disorder: clues from the molecular pathophysiology. Mol. Psychiatry, 9, 756–776. 145. Heydendael, W. and Jacobson, L. (2008) Differential effects of imipramine and phenelzine on corticosteroid receptor gene expression in mouse brain: potential relevance to antidepressant response. Brain Res., 1238, 93–107. 146. Johnson, D.A., Ingram, C.D., Grant, E.J. et al. (2008) Glucocorticoid receptor antagonism augments fluoxetineinduced downregulation of the 5-HT transporter. Neuropsychopharmacology, 34, 399–409. 147. Ago, Y., Arikawa, S., Yata, M. et al. (2008) Antidepressantlike effects of the glucocorticoid receptor antagonist RU-43044 are associated with changes in prefrontal dopamine in mouse models of depression. Neuropharmacology, 55, 1355–1363. 148. Young, A.H., Gallagher, P., Watson, S. et al. (2004) Improvements in neurocognitive function and mood following adjunctive treatment with mifepristone (RU-486) in bipolar disorder. Neuropsychopharmacology, 29, 1538–1545. 149. Carroll, B.J. and Rubin, R.T. (2008) Mifepristone in psychotic depression? Biol. Psychiatry, 63, e3. 150. Rothschild, A.J. (2003) Challenges in the treatment of depression with psychotic features. Biol. Psychiatry, 53, 680–690. 151. Grunberg, S.M., Weiss, M.H., Russell, C.A. et al. (2006) Longterm administration of mifepristone (RU486): clinical tolerance during extended treatment of meningioma. Cancer Invest., 24, 727–733. 152. Jahn, H., Schick, M., Kiefer, F. et al. (2004) Metyrapone as additive treatment in major depression: a double-blind and placebo-controlled trial. Arch. Gen. Psychiatry, 61, 1235–1244. 153. Brown, E.S., Bobadilla, L. and Rush, A.J. (2001) Ketoconazole in bipolar patients with depressive symptoms: a case series and literature review. Bipolar Disord., 3, 23–29. 154. Holmes, A., Heilig, M., Rupniak, N.M. et al. (2003) Neuropeptide systems as novel therapeutic targets for depression and anxiety disorders. Trends Pharmacol. Sci., 24, 580–588. 155. Saunders, J. and Williams, J. (2003) Antagonists of the corticotropin releasing factor receptor. Prog. Med. Chem., 41, 195–247. 156. Zobel, A.W., Nickel, T., Kunzel, H.E. et al. (2000) Effects of the high-affinity corticotropin-releasing hormone receptor 1 antagonist R121919 in major depression: the first 20 patients treated. J. Psychiatr. Res., 34, 171–181.
410
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157. Habib, K.E., Weld, K.P., Rice, K.C. et al. (2000) Oral administration of a corticotropin-releasing hormone receptor antagonist significantly attenuates behavioral, neuroendocrine, and autonomic responses to stress in primates. Proc. Natl. Acad. Sci. USA, 97, 6079–6084. 158. Ducottet, C., Griebel, G. and Belzung, C. (2003) Effects of the selective nonpeptide corticotropin-releasing factor receptor 1 antagonist antalarmin in the chronic mild stress model of depression in mice. Prog. Neuropsychopharmacol. Biol. Psychiatry, 27, 625–631. 159. Jutkiewicz, E.M., Wood, S.K., Houshyar, H. et al. (2005) The effects of CRF antagonists, antalarmin, CP154,526, LWH234, and R121919, in the forced swim test and on swim-induced increases in adrenocorticotropin in rats. Psychopharmacology (Berl.), 180, 215–223. 160. Mansbach, R.S., Brooks, E.N. and Chen, Y.L. (1997) Antidepressant-like effects of CP-154,526, a selective CRF1 receptor antagonist. Eur. J. Pharmacol., 323, 21–26. 161. Seymour, P.A., Schmidt, A.W. and Schulz, D.W. (2003) The pharmacology of CP-154,526, a non-peptide antagonist of the CRH1 receptor: a review. CNS Drug Rev., 9, 57–96. 162. Alonso, R., Griebel, G., Pavone, G. et al. (2004) Blockade of CRF(1) or V(1b) receptors reverses stress-induced suppression of neurogenesis in a mouse model of depression. Mol. Psychiatry, 9, 278–286, 24. 163. Farrokhi, C., Blanchard, D.C., Griebel, G. et al. (2004) Effects of the CRF1 antagonist SSR125543A on aggressive behaviors in hamsters. Pharmacol. Biochem. Behav., 77, 465–469. 164. Griebel, G., Simiand, J., Steinberg, R. et al. (2002) 4-(2Chloro-4-methoxy-5-methylphenyl)-N-[(1S)-2-cyclopropyl1-(3-fluoro-4-methylphenyl)ethyl]5-methyl-N-(2-propynyl)1, 3-thiazol-2-amine hydrochloride (SSR125543A), a potent and selective corticotrophin-releasing factor(1) receptor antagonist. II. Characterization in rodent models of stressrelated disorders. J. Pharmacol. Exp. Ther., 301, 333–345. 165. Berridge, C.W. and Dunn, A.J. (1987) A corticotropin-releasing factor antagonist reverses the stress-induced changes of exploratory behavior in mice. Horm. Behav., 21, 393–401. 166. Carvalho, L.A. and Pariante, C.M. (2008) In vitro modulation of the glucocorticoid receptor by antidepressants. Stress, 11, 411–424. 167. Binneman, B., Fletner, D., Kolluri, S. et al. (2008) A 6-week randomized, placebo-controlled trial of CP-316,311 (a selective CRH1 antagonist in the treatment of major depression. Am. J. Psychiatry, 165, 617–620. 168. Gould, T.D. and Manji, H.K. (2005) Glycogen synthase kinase-3: a putative molecular target for lithium mimetic drugs. Neuropsychopharmacology, 30, 1223–1237. 169. Gould, T.D., Einat, H., Bhat, R. et al. (2004) AR-A014418, a selective GSK-3 inhibitor, produces antidepressant-like effects in the forced swim test. Int. J. Neuropsychopharmacol., 7, 387–390. 170. Gould, T.D., Picchini, A.M., Einat, H. et al. (2006) Targeting glycogen synthase kinase-3 in the CNS: implications for the
171.
172.
173.
174.
175.
176.
177.
178.
179.
180.
181. 182.
183.
184.
185.
development of new treatments for mood disorders. Curr. Drug Targets, 7, 1399–1409. Chen, G., Manji, H.K., Hawver, D.B. et al. (1994) Chronic sodium valproate selectively decreases protein kinase C alpha and epsilon in vitro. J. Neurochem., 63, 2361–2364. Friedman, E., Hoau Yan, W., Levinson, D. et al. (1993) Altered platelet protein kinase C activity in bipolar affective disorder, manic episode. Biol. Psychiatry, 33, 520–525. Hahn, C.G. and Friedman, E. (1999) Abnormalities in protein kinase C signaling and the pathophysiology of bipolar disorder. Bipolar Disord., 1, 81–86. Manji, H.K., Etcheberrigaray, R., Chen, G. et al. (1993) Lithium decreases membrane-associated protein kinase C in hippocampus: selectivity for the alpha isozyme. J. Neurochem., 61, 2303–2310. Manji, H.K. and Lenox, R.H. (1999) Ziskind-Somerfeld Research Award. Protein kinase C signaling in the brain: molecular transduction of mood stabilization in the treatment of manic-depressive illness. Biol. Psychiatry, 46, 1328–1351. Young, L.T., Wang, J.F., Woods, C.M. et al. (1999) Platelet protein kinase C alpha levels in drug-free and lithiumtreated subjects with bipolar disorder. Neuropsychobiology, 40, 63–66. Einat, H., Yuan, P., Szabo, S.T. et al. (2007) Protein kinase C inhibition by tamoxifen antagonizes manic-like behavior in rats: implications for the development of novel therapeutics for bipolar disorder. Neuropsychobiology, 55, 123–131. Bebchuk, J.M., Arfken, C.L. Dolan-Manji, S. et al. (2000) A preliminary investigation of a protein kinase C inhibitor in the treatment of acute mania. Arch. Gen. Psychiatry, 57, 95–97. Zarate, C.A. Jr, Singh, J.B., Carlson, P.J. et al. (2007) Efficacy of a protein kinase C inhibitor (tamoxifen) in the treatment of acute mania: a pilot study. Bipolar Disord., 9, 561–570. Kulkarni, J., Garland, K.A., Scaffidi, A. et al. (2006) A pilot study of hormone modulation as a new treatment for mania in women with bipolar affective disorder. Psychoneuroendocrinology, 31, 543–547. Goldstein, J.A. (1986) Danazol and the rapid-cycling patient. J. Clin. Psychiatry, 47, 153–154. Rapoport, S.I. and Bosetti, F. (2002) Do lithium and anticonvulsants target the brain arachidonic acid cascade in bipolar disorder? Arch. Gen. Psychiatry, 59, 592–596. Rao, J.S., Bazinet, R.P., Rapoport, S.I. et al. (2007) Chronic treatment of rats with sodium valproate downregulates frontal cortex NF-kappaB DNA binding activity and COX-2 mRNA. Bipolar Disord., 9, 513–520. Nery, F.G., Monkul, E.S., Hatch, J.P. et al. (2008) Celecoxib as an adjunct in the treatment of depressive or mixed episodes of bipolar disorder: a double-blind, randomized, placebocontrolled study. Hum. Psychopharmacol., 23, 87–94. Muller, N., Schwarz, M.J., Dehning, S. et al. (2006) The cyclooxygenase-2 inhibitor celecoxib has therapeutic effects in major depression: results of a double-blind, randomized, placebo controlled, add-on pilot study to reboxetine. Mol. Psychiatry, 11, 680–684.
Novel Therapeutic Strategies 186. Velentgas, P., West, W., Cannuscio, C.C. et al. (2006) Cardiovascular risk of selective cyclooxygenase-2 inhibitors and other non-aspirin non-steroidal anti-inflammatory medications. Pharmacoepidemiol. Drug Saf., 15, 641–652. 187. Littner, M., Johnson, S.F., McCall, W.V. et al. (2001) Practice parameters for the treatment of narcolepsy: an update for 2000. Sleep, 24, 451–466. 188. Frye, M.A., Grunze, H., Suppes, T. et al. (2007) A placebocontrolled evaluation of adjunctive modafinil in the treatment of bipolar depression. Am. J. Psychiatry, 164, 1242–1249. 189. Post, R.M., Altshuler, L.L., Frye, M.A. et al. (2006) New findings from the Bipolar Collaborative Network: clinical implications for therapeutics. Curr. Psychiatry Rep., 8, 489–497. 190. Plante, D.T. (2008) Treatment-emergent hypomania or mania with modafinil. Am. J. Psychiatry, 165, 134–135. 191. Wolf, J., Fiedler, U., Anghelescu, I. et al. (2006) Manic switch in a patient with treatment-resistant bipolar depression treated with modafinil. J. Clin. Psychiatry, 67, 1817. 192. Ranjan, S. and Chandra, P.S. (2005) Modafinil-induced irritability and aggression? A report of 2 bipolar patients. J. Clin. Psychopharmacol., 25, 628–629. 193. Machado-Vieira, R., Andreazza, A.C., Viale, C.I. et al. (2007) Oxidative stress parameters in unmedicated and treated bipolar subjects during initial manic episode: a possible role for lithium antioxidant effects. Neurosci. Lett., 421, 33–36. 194. Ng, F., Berk, M., Dean, O. et al. (2008) Oxidative stress in psychiatric disorders: evidence base and therapeutic implications. Int. J. Neuropsychopharmacol., 11, 851–876. 195. Andreazza, A.C., Cassini, C., Rosa, A.R. et al. (2007) Serum S100B and antioxidant enzymes in bipolar patients. J. Psychiatr. Res., 41, 523–529. 196. Kuloglu, M., Ustundag, B., Atmaca, M. et al. (2002) Lipid peroxidation and antioxidant enzyme levels in patients with schizophrenia and bipolar disorder. Cell Biochem. Funct., 20, 171–175. 197. Berk, M., Copolov, D.L., Dean, O. et al. (2008) N-acetyl cysteine for depressive symptoms in bipolar disorder–a double-blind randomized placebo-controlled trial. Biol. Psychiatry, 64, 468–475. 198. Manji, H.K. and Chen, G. (2002) PKC, MAP kinases and the bcl-2 family of proteins as long-term targets for mood stabilizers. Mol. Psychiatry, 7 (Suppl 1), S46–S56. 199. Chen, G. and Manji, H.K. (2006) The extracellular signalregulated kinase pathway: an emerging promising target for mood stabilizers. Curr. Opin. Psychiatry, 19, 313–323.
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200. Shaltiel, G., Chen, G. and Manji, H.K. (2007) Neurotrophic signaling cascades in the pathophysiology and treatment of bipolar disorder. Curr. Opin. Pharmacol., 7, 22–26. 201. Hetz, C. and Glimcher, L. (2008) The daily job of night killers: alternative roles of the BCL-2 family in organelle physiology. Trends Cell Biol., 18, 38–44. 202. Youle, R.J. and Strasser, A. (2008) The BCL-2 protein family: opposing activities that mediate cell death. Nat. Rev. Mol. Cell Biol., 9, 47–59. 203. Kuhn, H.G., Biebl, M., Wilhelm, D. et al. (2005) Increased generation of granule cells in adult Bcl-2-overexpressing mice: a role for cell death during continued hippocampal neurogenesis. Eur. J. Neurosci., 22, 1907–1915. 204. Chen, D.F., Schneider, G.E., Martinou, J.C. et al. (1997) Bcl-2 promotes regeneration of severed axons in mammalian CNS. Nature, 385, 434–439. 205. Yuan, P.X., Huang, L.D., Jiang, Y.M. et al. (2001) The mood stabilizer valproic acid activates mitogen-activated protein kinases and promotes neurite growth. J. Biol. Chem., 276, 31674–31683. 206. Hao, Y., Creson, T., Zhang, L. et al. (2004) Mood stabilizer valproate promotes ERK pathway-dependent cortical neuronal growth and neurogenesis. J. Neurosci., 24, 6590–6599. 207. Jonas, E. (2006) BCL-xL regulates synaptic plasticity. Mol. Interv., 6, 208–222. 208. Mattson, M.P. (2007) Calcium and neurodegeneration. Aging Cell, 6, 337–350. 209. Lien, R., Flaisher-Grinberg, S., Cleary, C. et al. (2008) Behavioral effects of Bcl-2 deficiency: implications for affective disorders. Pharmacol. Rep., 60, 490–498. 210. Takata, K., Kitamura, Y., Kakimura, J. et al. (2000) Increase of bcl-2 protein in neuronal dendritic processes of cerebral cortex and hippocampus by the antiparkinsonian drugs, talipexole and pramipexole. Brain Res., 872, 236–241. 211. Goldberg, J.F., Burdick, K.E. and Endick, C.J. (2004) Preliminary randomized, double-blind, placebo-controlled trial of pramipexole added to mood stabilizers for treatmentresistant bipolar depression. Am. J. Psychiatry, 161, 564–566. 212. Zarate, C.A. Jr, Payne, J.L., Singh, J. et al. (2004) Pramipexole for bipolar II depression: a placebo-controlled proof of concept study. Biol. Psychiatry, 56, 54–60. 213. Roitman, S., Green, T., Osher, Y. et al. (2007) Creatine monohydrate in resistant depression: a preliminary study. Bipolar Disord., 9, 754–758. 214. Coyle, J.T. and Duman, R.S. (2003) Finding the intacellular signaling pathways affected by mood disorder treatments. Neuron., 38, 157–160.
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Psychoeducation as a Core Element of Psychological Approaches for Bipolar Disorders Francesc Colom1 and Lesley Berk2 1 2
Bipolar Disorders Program, IDIBAPS-CIBERSAM, Hospital Clinic Barcelona, Catalonia, Spain ORYGEN Research Centre and Department Clinical & Biomedical Sciences, University of Melbourne, Victoria, Australia
Psychoeducation in bipolar disorders: state of the art Recognition of the right of patients to be informed about their illness, and that health beliefs and behaviour influence the course of illness, led to the development of psychological approaches based on psychoeducation to augment medical treatment. Positive results of psychoeducation have been demonstrated in illnesses ranging from diabetes, asthma and cancer to schizophrenia [1–4]. Psychological interventions based on psychoeducation and those that include psychoeducation as a vital component, have proved helpful in improving outcomes in bipolar disorder [5,6]. Bipolar disorder is a biological illness that deserves proper pharmacological treatment. It is also a chronic illness with pervasive behavioural, cognitive and emotional symptoms that may be triggered by personal and environmental factors. Impairment in occupational and social functioning is prevalent, even between episodes. Suicide risk is still a common complication of bipolar disorders, with rates ranging between 15 and 25%. Despite advances in pharmacological treatment, this biological illness has psychosocial consequences both for the patient and the family [7]. These factors together with the huge gap existing between treatment efficacy and effectiveness and adherence problems, pointed to an urgent need to complement the available treatments for bipolar disorders with some clinically-based psychological approaches. Central to this integrated treatment approach has been the recognition that people with bipolar disorder need to be informed about their illness, treatment and illness management strategies, as well as ways of integrating this often stigmatized disorder into their lives. Psychoeducation is a core element of all adjunctive psychological interventions that have proven efficacy in improving outcomes in bipolar disorder, despite the different theoretical models Bipolar Disorder: Clinical and Neurobiological Foundations Edited by Lakshmi N. Yatham and Mario Maj © 2010 John Wiley & Sons, Ltd. ISBN: 978-0-470-72198-8
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and strategies emphasized in some of these approaches (e.g. Cognitive Behavioural Therapy (CBT), Family Focused Therapy (FFT, Interpersonal and Social Rhythm Therapy and Collaborative Care (ISRTCC) approaches) [8]. In this chapter we examine what is meant by psychoeducation and how this has been applied to bipolar disorder and evaluated in randomized controlled trials. We explore the essential ingredients of psychoeducation, and some practical consideration when implementing it with specific reference to the Barcelona model of group psychoeducation, which has demonstrated sustained positive outcomes [9].
What is psychoeducation? ‘Psychoeducation’ has been used as a broad term denoting the active and often didactic presentation of information about an illness and ways to treat or manage it [10]. Over 20 years ago, Goldman [11] viewed psychoeducation as an ‘. . . education or training’ aimed at enhancing ‘treatment and rehabilitation’. Goals included ‘enhancing the persons acceptance of his illness, promoting active cooperation with treatment and rehabilitation, and strengthening the coping skills that compensate for deficiencies by the disorders’ ([11]: p. 666). As an adjunctive treatment for bipolar disorder, psychoeducation interventions go far beyond information. Of course, psychoeducative interventions provide information and knowledge about the disorder as a key element, but the mere transmission of information about the illness does not appear to have any therapeutic effect [12]. Psychoeducation is rather an information-based behavioural training aimed at assisting the person to adjust their lifestyle to cope with bipolar disorder to improve outcomes, including enhancement of illness awareness, treatment adherence, early detection of relapse and avoidance of potentially harmful factors such as illegal drugs and sleep deprivation. Hence, psychoeducation is an intervention that involves good medical practice and seeks to empower the patient with tools that allow him or her to be more active in his or her own therapy process. Optimally, this involves a change of
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paradigm from the excessively personal psychiatric or psychological involvement, typical of the one-on-one therapistpatient paradigm (based especially on the inspiration and charisma of the therapist), to a therapeutic team approach [13]. Psychoeducation can be conducted in different settings involving individuals or groups. Individual patient psychoeducation in bipolar disorder has been used as a standalone adjunctive psychosocial intervention when health behaviour targets are very specific, for example to teach people to respond to early warning signs [14], or as a dominant component of more complex interventions based on different theoretical models (e.g. CBT and ISRTCC). In the delivery of psychoeducation, many interventions actively use the social milieu. People are considered to exist within a social context that influences their perceptions, attitudes and behaviour. For this reason, and that it is costeffective, psychoeducation is sometimes conducted with patients in group format where mutual support and acceptance reinforces the use of positive health behaviour, as in the Barcelona group psychoeducation model [15] and a recent study by Castle and colleagues [16]. Psychoeducation can be aimed at caregivers, as they could be crucial in reinforcing the patients positive behaviour towards the illness. This approach views the individual as interacting in a dynamic ecological system, and recognizes that the illness affects more than the patient alone [10]. The burden of illness extends to the family [17]. There is evidence that stressful events inside the family environment are often related to exacerbations of bipolar disorder; expressed emotion has been described as an important predictor of relapse. Thus, bipolar disorder affects family relationships, and family relationships affect bipolar disorder [18]. The Barcelona group works with separate groups of patients and caregivers, but other outstanding groups, include them together in the same session (Miklowitz and colleagues) or run multifamily education sessions ([19]).
Growth of evidence-based psychoeducational approaches The ancestors of psychoeducation are found in the so-called ‘lithium clinics’, which appeared both in Europe – mainly in the Netherlands – and in the United States in the 1970s. Lithium clinics were typically composed of a team of psychiatrists and nurses – rarely psychologists – who provided both pharmacological care and patient education, mostly in group format. The efficacy of this integrated treatment was described in reports, but unfortunately the studies lacked appropriate comparative methodology. Another remarkable initial effort that deserves attention are the studies by Peet and Harvey [20] that were able to show some changes in patients attitudes towards lithium but, unfortunately, gave no clinical outcome measures. The
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brief psychoeducational studies by Eduard van Gent [21] showed an initial, positive effect on stigma and self-esteem and later, a significant decrease of adherence problems and hospitalizations amongst psychoeducated patients in the 3-year follow-up study of this group intervention [22]. An early randomized family-based psychoeducation intervention for inpatients with mood disorders and schizophrenia (that included 21 patients with bipolar disorder), found an improvement in symptoms, functioning and family attitudes after 18 months [23]. However, a randomized controlled trial of a group intervention for partners of people with bipolar disorder did not find such positive results. While knowledge amongst partners improved, patients were not involved in the intervention and initially showed an increase in anxiety levels [24]. In time, evidence from a number of major randomized controlled trials largely supported what initially was only guessed, although somewhat hoped, by the scientific community: Education-based programmes as an add-on prophylactic tool in bipolar disorders had indisputable merit, and could be applied in individual, group and family contexts.
Studies of individual psychological interventions The first highly structured manualized psychological intervention for bipolar disorders tested with a well-designed randomized controlled study was a very simple and userfriendly psychoeducation intervention [14]. 69 bipolar patients who had experienced a relapse within the previous 12 months were randomized to receive either standard care alone, or in addition to 7 to 12 individual treatment sessions, aimed at teaching them to identify early symptoms of relapse and to seek prompt treatment from their health care providers. The additional treatment sessions were associated with a significant increase in time to first manic relapse (25th percentile, 65 vs. 17 weeks; p ¼ 0.008), as well as a 30% decrease in the number of manic episodes over 18 months (p ¼ 0.013). However, time to first depressive relapse and number of depressive relapses were unaffected. Overall, social functioning and employment over 18 months were significantly improved with the additional treatment sessions. Thus, teaching patients to recognize the early symptoms of manic relapse yielded important clinical gains. An approach that combines education about the illness and its management with a major emphasis on cognitive restructuring and behaviour activation skills is CBT. Lam and colleagues [25] reported the usefulness of an educational-focused cognitive therapy for prevention of relapses. This intervention showed its efficacy at the one year follow-up but, unfortunately, most of the effect disappeared with the passing of time, as shown by the limited efficacy reported at the two-year follow-up [26].
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Another study looking at the efficacy of individual CBT in bipolar disorder was the large effectiveness trial by Scott and colleagues [27], also conducted in the United Kingdom. CBT was tested with 253 unstable and difficult-to-treat bipolar patients, and showed no effect on the final outcome measures. The honesty of the authors in publishing one of the few negative trials on psychotherapy is commendable, and may assist in refining our understanding of how to match treatments to certain patient variables. The number of episodes prior to entering the study, combined with other baseline severity variables, seemed to be a powerful moderator of response to CBT. Specifically, those patients who had had a larger number of episodes, acute symptoms and comorbidity at study entry actually worsened with psychological treatment. The study by Ball and colleagues [28] points to some effect on improving behavioural self-control, but no significant effect on relapse was reported. Data coming from the STEPBD study [29] also suggest the modest efficacy of CBT – with this intervention being the only one that did not separate from standard collaborative care. Interpersonal Social Rhythm Therapy (IPSRT) contains a general psychoeducation component and is a bipolar-tailored reformulation of former Interpersonal Therapy (IPT), originally developed by Klerman and Weissman in the 1980s. Originally, IPT targeted unipolar depression and focused specifically on social interactions as a core problem area. Its bipolar reformulation extends this focus to emphasize lifestyle regularity and the modification of habits. The main advantage of this intervention is that it was designed from the beginning to be easily assessed, which has enhanced research on this matter. The Pittsburgh group [30] showed the positive effect of IPSRT on decreased time to recurrence, in non-stable bipolar patients, once medical comorbidity and marital status were controlled.
Studies of group psychological interventions In 2003, the Barcelona group published the first randomized clinical trial on the efficacy of group psychoeducation. Colom et al. [15] enrolled 120 bipolar patients – type I or II – who had been euthymic for at least 6 months (YMRS < 6, HDRS,8). Patients were randomly assigned to receiving 21 sessions of group psychoeducation or 21 sessions of nonspecific group meetings during a period of six months as an add-on to naturalistic pharmacological treatment. At the two-year follow-up, 55 subjects (92%) in the control group fulfilled criteria for recurrence versus 40 patients (67%) in the psychoeducation group (p < 0.001), whilst the total number of recurrences and of depressive episodes was significantly lower for psychoeducated patients. As for time to recurrence, the survival analysis showed an advantage of psychoeducation for time to any recurrence (log rank ¼ 13.453, df ¼ 1, p < 0.0002), time to depressive recurrence
(log rank ¼ 15.473, df ¼ 1, p < 0.0001), time to mixed recurrence (log rank ¼ 7.95, df ¼ 1, p < 0.05) and time to manic or hypomanic recurrence (log rank ¼ 7.79, df ¼ 1, p < 0.006). Another interesting outcome had to do with hospitalizations; although no difference was found regarding the number of patients who required hospitalization, there was a significant difference concerning the number of hospitalizations per patient at the two-year follow-up (0.304 for the psychoeducated patients vs. 0.780, U ¼ 2.14, p < 0.05). Thus, psychoeducation appeared to prevent the constant rehospitalization of the most severe subset of patients, a phenomenon usually known as the ‘revolving door’ phenomenon. Group psychoeducation has shown its efficacy even in those complex patients fulfilling criteria for a comorbid personality disorder [31]. This is particularly interesting if we consider the poor outcome of comorbid bipolar patients and the complexity of treating this group of patients. Integrated care, including psychoeducational contents, has also been shown to be effective for bipolar patients with substance dependence [32]. Any maintenance treatment should, by definition, be effective in the long term. It would be unthinkable, for instance, to consider lithium, anticonvulsants or other mood-stabilizers as maintenance treatment with efficacy data limited to a 12 or 18 months follow-up (and, unfortunately, this is the case for most of the mentioned compounds, but this would deserve another chapter). Similarly, if we claim that family or patient psychoeducation should be considered as maintenance tools, we should have data on their long-term prophylactic efficacy. Criticisms of the usefulness of psychological interventions based on their supposed time-limited efficacy are not rare. Many authors stress the need for booster sessions, but this would affect feasability and cost-efficacy issues. Maybe because psychoeducation should be considered a training more than anything else, group psychoeducation is the first psychotherapeutic intervention for bipolar disorders that shows long-term efficacy. At the five-year followup [9], psychoeducated patients showed a longer-time to recurrence (log rank ¼ 9.953, P < 00 202) and less recurrences than non-psychoeducated patients (3.86 vs. 8.37, F ¼ 23.6, p < 0.0001). Psychoeducated patients spent much less time acutely ill than non-psychoeducated patients. This was mainly due to the dramatic differences in time spent in depression (364 days vs. 399, t ¼ 5.387, p < 0.0001). Interestingly, the number of days depressed was reported to be a strong predictor of recurrences in the STEP-BD data [33]. Apart from the evident clinical benefits, cost-efficacy issues need to be considered. A recent study has shown that group psychoeducation saves health resources and expenses, particularly those related to hospitalizations [34]. Another group psychological intervention for bipolar disorder (the MAPS study) has recently been evaluated by researchers at the University of Melbourne in Australia [16].
Psychoeducation as a Core Element
This RCT involved a naturalistic sample (n ¼ 84), all of whom received their usual pharmacological treatment, and compared the impact on relapse of an intervention consisting of 12 group sessions and 3 booster sessions, combined with regular telephone follow-up, to a control group who received telephonic follow-up. The intervention focused on providing psychoeducation and included introductory skills training in certain CBT skills. The positive 12-month relapse outcomes will be reported in the near future. The usefulness of care packages containing psychoeducation as a core element has also been shown. The Life-Goals Programme, developed by Bauer and colleagues [35] is a team-based intervention originally designed to test the ‘real world’ efficacy – or effectiveness – of a specific programme of care for bipolar disorders. This programme consists of patient psychoeducation to improve self-management skills, clear clinical practice guidelines and the use of a nurse care coordinator working in collaboration with a supervizing psychiatrist to enhance continuity of care and information flow [35]. When compared to usual care in a 3year study, the Life Goals Programme showed a significant reduction in time spent acutely ill (a 14% reduction in time spent in an episode of illness), including a 23% reduction in weeks manic and a nonsignificant 11% reduction in weeks depressed. Mean three-year intervention costs were $61 398 compared with $64 379 in costs for usual care. The authors did not report any significant effect of the treatment regarding hospitalizations [36]. The Systematic Care Programme designed by Simon and colleagues [37] is another multi-component long-term intervention that focuses on combining intensive systematic care follow-up with the Life Goals Programme. Throughout the 24-month follow-up period, the mean mania severity ratings were lower in the intervention group. Unfortunately, there was no significant difference in the depression ratings between the two treatment groups. Regarding the costs of the intervention, it should be underlined that patients in the intervention group had more medication management visits, and consumed more atypical antipsychotic medications than the usual care group, but neither of these differences was statistically significant at the 5% level. The direct costs of the intervention programme were approximately $500 during the first year and $300 during the second year. The total costs in the intervention group were $1251 (95% confidence interval, $55–$2446) higher than those in the usual care group.
Studies of family/caregiver psychological interventions The study by the Colorado group [38] tested the efficacy of a family-focused therapy (FFT) that included three components: psychoeducation about bipolar disorder, communication enhancement training and problem-solving skills
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training. This study involved 101 bipolar patients who were stabilized on maintenance drug therapy and were randomized to receive either 21 sessions of manual-based familyfocused psychoeducational treatment (n ¼ 31) or two family education sessions and follow-up crisis management (n ¼ 70), both treatments delivered over a nine-month period. After one year of follow-up, patients assigned to the longer psychosocial treatment had fewer depressive relapses, longer times to relapse and significantly lower non-adherence rates than patients assigned to the shorter intervention. No difference was reported concerning manic relapses. At the two-year follow-up, the results were sustained and even improved, as shown by the increased mood benefits evident amongst amongst the patients receiving FFT. The Colorado group keeps on providing some of the most relevant studies in the field of family therapy in bipolar disorders. ‘Multifamily psychoeducational group therapy’ has also been evaluated in a randomized controlled trial [39]. This psychoeducation is generally conducted by two trained therapists over six sessions [39]. It involves groups of four to six people with bipolar disorder and their family members. In this approach participants are provided with psychoeducation and ways of coping with common problems and are encouraged to share experiences of the illness and to work collaboratively. Miller et al. [39] compared this approach to problem centred systems therapy of the family and pharmacotherapy alone in 92 acutely ill people with bipolar I disorder (3/4 of whom were manic) over 28 months. No difference was found between the three groups in terms of the number of people in each group who recovered or time to recovery of an episode. There were no significant differences in number of episodes per year between the different treatments, except when they considered people with bipolar disorder in families that were high in conflict or low in problem-solving ability at baseline. Patients in these more dysfunctional families, who received either type of family therapy, experienced nearly half the number of depressive episodes and fewer depressive symptoms than the patients in the pharmacotherapy alone group [19]. A third report from this study [40] found a significant difference in the proportion of participants requiring hospitalization in favour of multifamily psychoeducational group therapy compared to TAU, or the other family intervention. In the Netherlands, another version of multifamily group psychoeducation was evaluated in a waiting-list controlled study of 52 family member-patient dyads to assess the impact of this six session intervention on EE levels compared to TAU [41]. They found that with post-intervention (i.e. at three months), there was a significant drop in EE levels in the group that received the intervention compared to the control group and both people with bipolar disorder and carers felt appreciated and supported [41]. Thus, multifamily family group psychoeducation interventions may be a promising area for future study, specifically as a brief
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adjunctive intervention for dysfunctional families affected by bipolar disorder. Other authors [42] have recently reported the efficacy of a family psychoeducation programme focused on the group education of caregivers (the patients did not receive any kind of psychological intervention). This psychoeducational family intervention [17] consists of 12 90-minute group sessions for patients caregivers, and roughly follows the content in the model of psychoeducation groups for consumers [15,43], but with an additional emphasis on coping strategies for caregivers. At the one-year follow-up, patients whose caregivers had received psychoeducation showed a dramatic improvement in time-to-first recurrence and prevention of manic/hypomanic episodes, but not in depressive episodes. Importantly, this approach has also been shown to reduce subjective carer burden and maladaptive control attributions [17]. Any efficacious treatment may have drawbacks and limitations. Despite the evidence in support of psychological interventions for bipolar disorder, there are limitations. The first limitation, while obvious, is important: psychoeducation does not work in monotherapy, which means that it should always be considered as an add-on to pharmacotherapy. For many of these studies, no replication has been performed yet, and this limits their validity. In some of the randomized controlled treatment trials, a homogenous, well-defined sample was selected to test the efficacy of the intervention and this may limit the generalizability of the results [44]. In addition, efficacy of psychoeducational interventions with patients with a higher number of previous manic episodes may be limited due to neuropsychological impairment. We do not yet have much information on what type of psychological approach is most suitable for which subgroups of people affected by bipolar disorder, or on the ‘side-effects’ of these interventions. In addition, family/caregiver based therapies are not always practical: about 40–60% of bipolar patients, depending on the cultural context, are not residing with their family. Nevertheless, given the fact that family/caregivers are affected by the illness and can influence outcomes in bipolar disorder, family/caregiver interventions need to be considered when appropriate. Finally, another limitation is that generally, psychoeducation-based interventions are not effective in treating acute episodes, but in preventing them. Overall, these randomized controlled trials of individual, group and family/caregiver interventions involving psychoeducation, have transformed the traditional medical treatment of bipolar disorder. They have highlighted that actively informing patients and often caregivers/families and training them in helpful ways to deal with bipolar disorder is an essential part of good medical treatment. The next step is the translation of effective treatments into everyday clinical practise.
An interesting development in evidence-based psychological approaches is the establishment of increasingly more sophisticated Internet-based psychosocial treatment alternatives used in a wide variety of illnesses [45]. For example, a brief CBT intervention and information-based Internet intervention for depression showed significant positive results over 12 months, compared to the placebo controlled condition [46]. Currently there are a few Web-based interventions being tested in bipolar disorder. These include a RCT comparing psychoeducation to CBT [47], another comparing a relapse prevention psychoeducation model to attentional control [48] and a peer support psychoeducation study for people newly diagnosed with bipolar disorder [49]. The idea of Internet interventions is to enable patients to easily access treatment interventions in the privacy and convenience of their own homes, to overcome distance, time and cost restraints, and the perceived stigma sometimes connected to participating in face-to-face interventions.
Ingredients of psychoeducation There are a number of core psychoeducation ingredients that have been applied with different emphasis in many of psychosocial interventions. The main areas covered in psychoeducation for bipolar disorder include illness awareness, treatment adherence, early warning signs identification, avoidance of substance misuse and regulation of habits. In the Barcelona group psychoeducation model that demonstrated the prophylactic effects of psychoeducation [9], these ‘big five’ ingredients were chosen on the basis of clinical experience and needs identified by both patients and clinicians in the everyday management or treatment of bipolar disorder.
Illness awareness More than a half of bipolar patients have serious problems accepting the illness and many patients engage in denial, which is probably the main problem when it comes to treatment adherence. The association between lack of insight and neuropsychological impairment has been solidly reported, but social stigma and myths surrounding bipolar disorder and psychiatric conditions in general, make this diagnosis highly likely to be rejected by our patients. In the Barcelona psychoeducation model, we found that ‘Illness awareness’ needs to be addressed first, as it introduces concepts that will later be absolutely necessary during the group programme. Patients generally adjust themselves relatively fast to the medical model of illness, which may have the advantage of helping them to deal with stigma and guilt, and thereby enhance acceptance and treatment adherence. As the general population is usually unaware of the origin and nature of psychiatric disorders, the first
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sessions are usually quite ‘open’, allowing the group facilitators time to learn about participants illness models and prejudices. The facilitators can use this information to help the participant engage in the intervention and later, to assist them to deal with guilt and barriers to effective illness management. Approaches that emphasize an entirely patient-centred focus may do the patient a disservice if they do not inform them of the medical model, as this knowledge could facilitate positive outcomes.
Adherence enhancement Improving treatment adherence must be one of the main objectives of any psychological intervention in bipolar disorders, as this is a very common and damaging problem. Almost 50% of bipolar patients stop taking medication without indication from their psychiatrists, even during euthymia [50]. It is well-known that adherence problems are the most common cause of relapse amongst bipolar patients, but the reasons for this behaviour are quite unspecific and patient-dependent, although substance and personality comorbidities play a major role. The risk of hospitalization is four times higher amongst patients who do not fully comply with their maintenance treatment. In the sessions devoted to improving treatment adherence, it may be useful to cover all the different types of nonadherence (intermittent adherence, late adherence, partial adherence and so on). During the sessions the therapist should cover the following 10 points: 1 Inform the patient about the different types of psychotropic medications for bipolar disorder; 2 Review brand names of psychotropic medications. Explain the difference between brand name and generic name; 3 Stress the idea that pharmacological treatment is highly individualized; 4 Learn about the purpose of each medication and how a drug may have more than one purpose; 5 Learn about common side effects of medications; 6 Discuss strategies to deal with side effects; 7 Learn about the importance of monitoring serum levels, especially in the case of lithium, but also valproate and carbamazepine; 8 Learn to identify the signs of severe toxicity with lithium and other drugs; 9 Inform the patient about drug-drug and drug-food interactions; 10 Inform the patient about appropriate administration of their medication (e.g. dose, when to take it.); During this part of the psychoeducative programme, it may also be helpful to discuss the pitfalls and inefficacy of alternative therapies for bipolar disorder, given that bipolar patients are especially prone to seek this sort of ‘help’. According to a recently published US-based study [51], more
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than half the patients reported using alternative remedies such as prayer/spiritual healing, meditation or herbs (50%). Patients on anticonvulsants or atypical antipsychotics were more likely to use these alternative remedies. Therefore, it is worth explaining the scientific method to our patients, so they can learn the distinction between a fact and an opinion and eventually be informed about what a randomized clinical trial is. This is helpful when explaining what is meant by ‘non-tested’ treatments, and most importantly, the difference between tested and non-tested psychotherapies. Specific attention should also be paid to the teratogenic effects of medication. The main message to get across to the patient is that medications may be harmful for the foetus. It is important to inform them that mania or depression can cause damage by disrupting healthy habits, which are badly needed during pregnancy, and they need to be aware of the increased risk of postpartum episodes. If the patient learns that there is a delicate balance between benefits and risks of medication during pregnancy, and this is personalized, then he or she can be in a better position to decide what to do if this situation comes up in the future. The efficacy of psychoeducation in improving adherence has been proven. For instance, patients who were on lithium and received psychoeducation had more stable lithium serum levels than those who did not receive psychoeducation, [52]. This does not mean that psychoeducation works exclusively through adherence enhancement, as shown by the fact that even adherent patients can benefit from psychoeducation [43].
Avoidance of substance misuse The largest study on co-occurrence of bipolar disorders and substance use disorders was conducted as part of the National Epidemiologic Survey on Alcohol and Related Conditions (NESARC) [53], and assessed more than 40 000 people in the United States. According to this study, there was a lifetime prevalence of co-occurring alcohol use disorders reaching almost 60% for bipolar I patients, and a 38% lifetime prevalence of any drug use disorder, a finding that is supported in general by all the existing literature. According to the Epidemiologic Catchment Area data, nearly half of bipolar II patients would be expected to have a comorbid substance use disorder. Thus, the risk for a bipolar patient to suffer a substance related problem is six-fold higher than that of the general population. Substance use is associated with a poorer outcome, including increased episodes of depression, increased adherence problems and delayed symptomatic recovery. Data coming from the Systematic Treatment Enhancement Programme for Bipolar Disorder (STEP-BP) suggest that substance related disorders are strongly associated with an increased number of hospitalizations. Suicide attempts are also more frequent amongst patients with this comorbidity.
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Many patients do not meet the criteria for substance abuse or dependence, even though they consume alcohol or other substances with a certain assiduity, and the mere consumption of alcohol, cannabis and other toxics, even without reaching abuse quantities, can act as a trigger for new episodes. A study of 148 people with bipolar I and II disorders found that more frequent consumption of low levels of alcohol was associated with greater number of illness episodes, emergency department visits and severity of symptoms [54]. The levels of alcohol consumption fell within the low risk guidelines for alcohol use. This suggests that in order to prevent the negative effects of alcohol consumption, people with bipolar disorder may need to consume less alcohol than is recommended in the guidelines, or even to abstain completely, and more research needs to be done in this area. Although patients with severe comorbid substance abuse or dependence may need a specific programme that tackles dual pathology, it is very useful to target the regular use of substances with psychotropic effects. In other words, the idea is to prevent substance consumption in order to control a potential triggering factor. To achieve this objective, it may be useful not only to focus on alcohol and street drugs but also on apparently harmless substances such as caffeine, as many patients may drink coffee or other stimulant drinks in order to compensate their subsyndromal or syndromal depressive condition or to get ‘higher’, which obviously implies a risk, especially because of its impact on the quality of sleep. In the group psychoeducation approach by Colom et al. (Colom and Vieta, 2003a; Colom and Vieta, 2003b), the importance of avoiding substance use to improve prognosis is re-iterated throughout the programme (such as causes and triggers, course and outcome, alternative treatments, early intervention, symptoms management, lifestyle regularity, etc.), although there is only one session specifically devoted to the topic. Amongst the psychological interventions that specifically target the comorbidity of substance use and bipolar disorders, it is worth mentioning Integrated Group Therapy (IGT), a highly-structured group treatment consisting of 20 weekly group sessions. The core principle guiding the treatment is that the same kinds of thoughts and behaviours that facilitate recovery from substance-related disorders will also be helpful in achieving affective stability. Unfortunately, the evidence does not seem to support this last point, as IGT has shown its usefulness in decreasing the days of substance use and other measures regarding the severity of the substance disorder, but not in improving the outcome of bipolar disorder [32]. Interestingly, the Life Goals Programme [35] was as effective in people with comorbid substance use compared to those without this comorbidity, suggesting that a long-term mix of collaborative care and psychoeducation may assist people with these co-occurring conditions [55].
Early warning signs detection Training in detecting and responding to early warning signs has been reported to be efficacious in the prevention of mania but not depression [14]. In this study there was an increase of antidepressant use in the intervention group that might have resulted from an increase in people seeking medical treatment due to a greater recognition of the warning signs of depression. The main intervention strategy in Perrys study was to get early medical help once prodromes were recognized. Possibly, additional behavioural and cognitive ways of coping with warning signs of depression (e.g. maintaining some level of activity when feeling lethargic, putting negative thinking into perspective, keeping to routines as much as possible, exercising, not sleeping during the day) would have been helpful to prevent depressive relapse [13,56]. Similarly, besides the importance of contacting their clinician early, when people experience warning signs of mania, they could also be informed about other practical preventative strategies (e.g. limiting their activities and avoiding stimulating substances) [13]. A recent meta-analysis, involving several interventions that included attention to early warning signs training- [57], showed how this component might be crucial in the prevention of any episodes and, specially, in the prevention of hospitalizations. A further development of the study by Perry et al. [14], aimed at testing its effectiveness and including a focus on the recognition and careful development of a number of coping strategies for dealing with warning signs of depression, mixed episodes, is expected to appear in the next few years [58].
Encouraging healthy habits Regular habits and stress management are extremely important in bipolar disorder and constitute the foundational ingredient of IPSRT. Moreover, developing regular habits and routines by means of IPSRT is efficacious in preventing recurrence of episodes in bipolar patients [30]. Psychoeducation tries to encourage patients towards healthy habits, but a tailored intervention such as IPSRT is needed to improve this aspect in more depth. There are two major concerns regarding lifestyle that should be covered during a psychoeducation group. Sleeping and social-rhythm disruptions have mood-destabilizing effects [59]: 1 Sleeping habits/circadian rhythms. Sleep duration is a key factor in predicting manic and depressive symptoms. There is robust evidence that sleep deprivation can induce manic symptoms amongst non-depressed bipolar individuals. Increasing the duration of night sleep may have some effect on treating manic symptoms. Whilst total sleep deprivation has been reported to be associated with remission in unipolar depression; its use in bipolar disorder is much more controversial. The general advice in psychoeducation
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is to sleep between seven and nine hours, avoid daytime sleep, and use sleep both as an indicator of relapse and as a helper to deal with oncoming episodes (by reducing or augmenting the number of hours asleep within a reasonable frame). 2 Many bipolar patients tend to organize their time rather erratically. Regular schedules and better structuring of activities should be one of the key points in any individual intervention with a bipolar patient. In group psychoeducation, it is possible to get across the importance of these aspects, presenting them as information, but there is not enough time to work on techniques such as recording activities, which are usually useful for bipolar patients. It is important for the patient to keep a proper balance between a schedule that helps to maintain his or her euthymia, and one that favours social adjustment and quality of life. To achieve this, the individual needs of each patient must be considered so the schedule is personalized, something that goes far beyond what can be offered in a psychoeducation group.
Practical considerations when implementing a psychoeducation group Group psychoeducation is a simple and common-sensebased intervention that is extremely easy to implement in most clinical settings that provide care for bipolar patients. Some aspects involved in the practical application of group psychoeducation need to be considered: a. Group size: The optimal size of a psychoeducation group is between 8 and 12 patients. It is possible to work with fewer than eight participants, but this can reduce the wealth of the patients contributions and opportunities to interact. Working with more patients will be complex for the therapists and interfere with group processes. This may result in poor adherence to the psychoeducation. Because the dropout rate is around 25%, it may be useful to start the group with around 15 patients, which ends up being reduced to 10–12 after the first four or five sessions. b. Group participants: Patients should be euthymic at the beginning of the group programme. The original study [15] used very narrow criteria (YMRS, 6, HDRS < 8 during at least 6 months) to define euthymia, but in routine clinical practice it may be enough that the patient is not acutely ill and is considered reasonably stable by the clinician. Ideally, groups should be balanced with regard to gender. Regarding age, the group should ideally be homogeneous enough to generate a feeling of belonging and allow for modelling, but heterogeneous enough to enable patients to learn from each other. If possible, bipolar subtypes should also be balanced, otherwise the likelihood of bipolar type II patients adhering to the group will be quite low, as they will not feel at ease with several terms (forced hospitalization, psychotic symptoms and so on). This may induce denial and disengagement.
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c. Therapist training: Ideally, the group should be directed by more than one therapist. The therapist must have considerable clinical experience with bipolar patients, training in social skills, experience in group management and a specific brief training in bipolar psychoeducation [13]. As long as they have this experience and training, the therapist can be either a psychiatrist, a psychologist or a psychiatric nurse.
Conclusions There has been considerable growth in evidence-based adjunctive psychoeducation treatments for bipolar disorder. The evidence to date suggests that there is increasingly effective help for people and families affected by bipolar disorder, and there are interesting studies in progress. This research needs to be applied in everyday clinical situations. The Barcelona teams group psychoeducation model is supported by robust evidence and is not complicated to implement. In the future, attention needs to be focused on replicating both consumer and carer group psychoeducation in different settings establish the extent of its generalizability, so its potential to assist people and families affected by bipolar disorder can be realized.
References 1. Olmsted, M.P., Daneman, D., Rydall, A.C. et al. (2002) The effects of psychoeducation on disturbed eating attitudes and behaviour in young women with type 1 diabetes mellitus. Int. J. Eat. Disorder., 32, 230–239. 2. Durna, Z. and Ozcan, S., (2003) Evaluation of self-management education for asthmatic patients. J. Asthma, 40, 631–643. 3. Bultz, B.D., Speca, M., Brasher, P.M. et al. (2000) A randomized controlled trial of a brief psychoeducational support group for partners of early stage breast cancer patients. Psychooncology, 9, 303–313. 4. Pekkala, E. and Merinder, L., (2004) Psychoeducation for Schizophrenia (Cochrane Review). The Cochrane Library, Issue 1, John Wiley and Sons, Ltd, Chichester. 5. Benyon, S., Soares-Weiser, K., Woolacott, N. et al. (2008) Psychosocial interventions for the prevention of relapse in bipolar disorder: a systematic review of controlled trials. Brit. J. Psychiat., 192, 5–11. 6. Scott, J., Colom, F. and Vieta, E., (2007) A meta-analysis of relapse rates with adjunctive psychological therapies compared to usual psychiatric treatment for bipolar disorders. Int. J. Neuropsychopharmacol., 10, 123–129. 7. Reinares, M., Vieta, E., Colom, F. et al. (2006) What really matters to bipolar patients caregivers: sources of family burden. J. Affect. Disord., 94, 157–163. 8. Colom, F. and Lam, D., (2005) Psychoeducation: improving outcomes in bipolar disorder. Eur. Psychiatry, 20, 359–364. 9. Colom, F., Vieta, E., S anchez-Moreno, J. et al. (2009) Group psychoeducation for stabilised bipolar disorders: 5-year outcome of a randomised clinical trial. Br. J. Psychiatry.,
420
10.
11. 12.
13. 14.
15.
16.
17.
18.
19.
20.
21.
22.
23.
24. 25.
26.
|
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194 (3), 260–265; Erratum in: Br J Psychiatry. 2009 Jun;194 (6):571. Lukens, E.P. and McFarlane, W.R., (2004) Psychoeducation as evidence based practice: Considerations for practice, research and policy. Brief Treat and Crisis Interv, 4 (3), 205–225. Goldman, C.R., (1988) Toward a definition of psychoeducation. Hosp. Community Psych., 39, 666–668. Miklowitz, D., Goodwin, G.M., Bauer, M.S. and Geddes, J.R. (2008) Common and specific elements of psychosocial treatments for bipolar disorder: A survey of clinicians participating in randomized trials. Journal of Psychiatric Practice, 14 (2), 77–85. Colom, F. and Vieta, E., (2006) Psychoeducation Manual for Bipolar Disorder, Cambridge University Press, Cambridge. Perry, A., Tarrier, N., Morris, R. et al. (1999) Randomised controlled trial of efficacy of teaching patients with bipolar disorder to identify early symptoms of relapse and obtain treatment. Br. Med. J., 318, 149–153. Colom, F., Vieta, E., Martinez-Aran, A. et al. (2003) A randomized trial on the efficacy of group psychoeducation in the prophylaxis of recurrences in bipolar patients whose disease is in remission. Arch. Gen. Psychiatry, 60, 402–407. Castle, D., Berk, M., Berk, L. et al. (2007) Pilot of a group intervention for bipolar disorder. International Journal of Psychiatry in Clinical Practice, 11, 279–284. Reinares, M., Vieta, E., Colom, F. et al. (2004) Impact of a psychoeducational family intervention on caregivers of stabilized bipolar patients. Psychother. Psychosom., 73, 312–319. Reinares, M., Colom, F., Martınez-Ar an, A. et al. (2002) Therapeutic interventions focused on the family of bipolar patients. Psychother. Psychosom., 71, 2–10. Miller, I.W., Keitner, G.I., Ryan, C.E. et al. (2008) Family treatment for bipolar disorder: Family impairment by treatment interactions. J. Clin. Psychiat., 69 (5), 732–740. Peet, M. and Harvey, N.S., (1991) Lithium maintenance: A standard education program for patients. Brit. J. Psychiat., 158, 197–200. van Gent, E.M., Vida, S.L. and Zwart, F.M., (1988) Group therapy in addition to lithium therapy in patients with bipolar disorders. Acta Psych Belg, 88, 405–418. Van Gent, E.M., (2000) Une etude suivie de 3 ans de therapies de groupe additives au traitement au lithium./A three year follow-up of two lithium psycho-education group programmes. LEncephale, 26 (2), 76–79. Clarkin, J.F., Carpenter, D., Hull, J. et al. (1998) Effects of psychoeducational intervention for married patients with bipolar disorder and their spouses. Psychiatr. Serv., 49, 531–533. Van Gent, E.M. and Zwart, F.M., (1991) Psychoeduation of partners of bipolar manic patients. J. Affect. Disord., 21, 15–18. Lam, D.H., Watkins, E.R., Hayward, P. et al. (2003) A randomized controlled study of cognitive therapy for relapse prevention for bipolar affective disorder: outcome of the first year. Arch Gen Psychiatry., 60 (2), 145–152. Lam, D.H., Hayward, P., Watkins, E.R. et al. (2005) Relapse prevention in patients with bipolar disorder: cognitive therapy outcome after 2 years. Am J Psychiatry., 162 (2), 324–329.
27. Scott, J., Paykel, E., Morriss, R. et al. (2006) Cognitivebehavioural therapy for severe and recurrent bipolar disorders: a randomized controlled trial. Brit. J. Psychiat., 188, 313–320. 28. Ball, J.R., Mitchell, P.B., Corry, J.C. et al. (2006) A randomized controlled trial of cognitive therapy for bipolar disorder: focus on long-term change. J. Clin. Psychiat., 67, 277–286. 29. Miklowitz, D.J., Otto, M.W., Frank, E. et al. (2007) Psychosocial treatments for bipolar depression: a 1-year randomized trial from the Systematic Treatment Enhancement Program. Arch. Gen. Psychiatry, 64, 419–426. 30. Frank, E., Kupfer, D.J., Thase, M.E. et al. (2005) Two-year outcomes for interpersonal and social rhythm therapy in individuals with bipolar I disorder. Arch. Gen. Psychiatry, 62, 996–1004. 31. Colom, F., Vieta, E., S anchez-Moreno, J. et al. (2004) Psychoeducation in bipolar patients with comorbid personality disorders. Bipolar. Disord., 6 (4), 294–298. 32. Weiss, R.D., Griffin, M.L., Kolodziej, M.E. et al. (2007) A randomized trial of integrated group therapy versus group drug counselling for patients with bipolar disorder and substance dependence. Am. J. Psychiatry, 164, 100–107. 33. Perlis, R.H., Ostacher, M.J., Patel, J.K. et al. (2006) Predictors of recurrence in bipolar disorder: primary outcomes from the Systematic Treatment Enhancement Program for Bipolar Disorder (STEP-BD). Am. J. Psychiatry., 163 (2), 217–224. 34. Scott, J., Colom, F., Popova, E. et al. (2009) Long-term mental health resource utilization and cost of care following group psychoeducation or unstructured group support for bipolar disorders: a cost-benefit analysis. J. Clin Psychiatry., 70 (3), 378–386. 35. Bauer, M.S., McBride, L., Williford, W.O. et al. (2006) Collaborative care for bipolar disorder: Part I. Intervention and implementation in a randomized effectiveness trial. Psychiatr. Serv., 57 (7), 927–936. 36. Bauer, M.S., McBride, L., Williford, W.O. et al. (2006) Collaborative care for bipolar disorder: Part II. Impact on clinical outcome, function, and costs. Psychiatr. Serv., 57, 937–945. 37. Simon, G.E., Ludman, E.J., Bauer, M.S. et al. (2006) Long-term effectiveness and cost of a systematic care management program for bipolar disorder. Arch. Gen. Psychiatry, 63, 500–508. 38. Miklowitz, D.J., George, E.L., Richards, J.A. et al. (2003) A randomized study of family-focused psychoeducation and pharmacotherapy in the outpatient management of bipolar disorder. Arch. Gen. Psychiatry, 60, 904–912. 39. Miller, I.W., Solomon, D.A., Ryan, C.E. and Keitner, G.I., (2004) Does adjunctive family therapy enhance recovery from bipolar I mood episodes? J. Affect. Disord., 82, 431–436. 40. Solomon, D.A., Keitner, G.I., Ryan, C.E. et al. (2008) Preventing recurrence of bipolar I mood episodes and hospitalizations: family psychotherapy plus pharmacotherapy versus pharmacotherapy alone. Bipolar Disord., 10 (7), 798–805. 41. Honig, A., Hofman, A., Rozendaal, N. and Dingemans, P., (1997) Psychoeducation in bipolar disorder: effect on expressed emotion. Psychiatry Res., 72, 17–22.
Psychoeducation as a Core Element 42. Reinares, M., Colom, F., Sanchez-Moreno, J. et al. (2008) Impact of caregiver group psychoeducation on the course and outcome of bipolar patients in remission: a randomised controlled trail. Bipolar Disord., 10, 511–519. 43. Colom, F., Vieta, E., Reinares, M. et al. (2003) Psychoeducation efficacy in bipolar disorders: beyond compliance enhancement. J. Clin. Psychiat., 64, 1101–1105. 44. Scott, J. and Colom, F., (2008) Gaps and limitations of psychological interventions for bipolar disorders. Psychother. Psychosom., 77, 4–11. 45. Strecher, V., (2007) Internet methods for delivering behavioural and health-related interventions (eHealth). Ann Rev Clin Psychol, 3, 53–76. 46. MacKinnon, A., Griffiths, K.M. and Christensen, H., (2008) Comparative randomised trial of online cognitive–behavioural therapy and an information website for depression: 12-month outcomes. Brit. J. Psychiat., 192, 130–134. 47. Lauder, S., Berk, M., Castle, D. et al. (2008) www.moodswings: the highs and lows of an online intervention for bipolar disorder: preliminary findings. Aust. NZ J. Psychiat., 42 (Suppl. 3), A83–A84. 48. Barnes, C., Harvey, R., Mitchell, R. et al. (2007) Evaluation of an online relapse prevention program for bipolar disorder: an overview of the aims and methodology of a randomised controlled trial. Dis Manag Health Outc, 15 (4), 215–224. 49. Proudfoot, J., Parker, G.B., Jayawant, A. et al. (2008) Bipolar disorder: psycho-education for patients with new diagnoses. Aust. NZ J. Psychiat., 42 (Suppl. 1), A106. 50. Colom, F., Vieta, E., Martınez-Ar an, A. et al. (2000) Clinical factors associated to treatment non-compliance in euthymic bipolar patients. J. Clin. Psychiat., 61, 549–554. 51. Kilbourne, A.M., Copeland, L.A., Zeber, J.E. et al. (2007) Determinants of complementary and alternative medicine
52.
53.
54.
55.
56.
57.
58.
59.
|
421
use by patients with bipolar disorder. Psychopharmacol Bull., 40 (3), 104–115. Colom, F., Vieta, E., S anchez-Moreno, J. et al. (2005) Stabilizing the stabilizer: group psychoeducation enhances the stability of serum lithium levels. Bipolar Disord., 7 (Suppl. 5), 32–36. Grant, B.F., Hasin, D.S., Stinson, F.S. et al. (2005) Prevalence, correlates, comorbidity, and comparative disability of DSMIV generalized anxiety disorder in the USA: results from the National Epidemiologic Survey on Alcohol and Related Conditions. Psychol. Med., 35, 1747–1759. Goldstein, B.I., Velyvis, V.P. and Parikh, S.V., (2006) The association between moderate alcohol use and illness severity in bipolar disorder: a preliminary report. J. Clin. Psychiat., 67 (1), 102–106. Kilbourne, A.M., Biswas, K., Pirragli, P.A. et al. (2009) Is the collaborative chronic care model effective for patients with bipolar disorder and co-occurring conditions? J. Affect. Disord., 112, 256–261. Lam, D., Wong, G. and Sham, P., (2001) Prodromes, coping strategies and course of illness in bipolar affective disorder – a naturalistic study. Psychol. Med., 31, 1398–1402. Morriss, R.K., Faizal, M.A., Jones, A.P. et al. (2007) Interventions for helping people recognise early signs of recurrence in bipolar disorder. Cochrane Database Syst. Rev, (1). Lobban, F., Gamble, C., Kinderman, P. et al. (2007) Enhanced relapse prevention for bipolar disorder – ERP trial. A cluster randomised controlled trial to assess the feasibility of training care coordinators to offer enhanced relapse prevention for bipolar disorder. BMC Psychiatry, 7, 6. Malkoff-Schwartz, S., Frank, E., Anderson, B. et al. (1998) Stressful life events and social rhythm disruption in the onset of manic and depressive bipolar episodes: A preliminary investigation. Arch. Gen. Psychiatry, 55, 702–707.
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Cognitive-Behavioural Therapy for Bipolar Disorder Sagar V. Parikh1 and Jan Scott2 1 2
University Health Network (UHN); University of Toronto, Toronto Western Hospital, Toronto, On, Canada Psychological Treatments Research, Institute of Neuroscience, Newcastle University, Newcastle-upon-Tyne, UK
The foundation of treatment for bipolar disorder (BD) is pharmacotherapy, but it has long been recognized that most individuals either achieve only partial symptom control with medication or struggle to adjust to the consequences of developing a ‘life course illness’. The functions of psychosocial interventions for BD may be broadly conceptualized in three distinct categories, with considerable overlap. The first role is to provide basic education about the illness, including its symptoms, course, treatments and sequelae, both treated and untreated. Inherent in that basic, ‘psychoeducation’ is an attempt to enhance acceptance of treatments, including lifestyle regimens, self-monitoring of symptoms, and adherence to medications and psychotherapy. A second role for psychosocial interventions is to provide symptom relief and prevent relapse. Finally, a third role for psychosocial interventions is to provide understanding and healing for immediate crises, such as disruptions in relationships and work, and to address the emotional scars resulting from episodes of illness. Thus, evaluation of the added value of providing any psychosocial intervention involves considering how it addresses each of these roles. Developing a psychosocial treatment for BD is surely more complex than for other psychiatric disorders, given the plethora of acute clinical presentations that formally manifest as manic, mixed or depressive episodes and the fact that comorbidity with other Axis 1 or II disorders is the rule rather the exception [1,2]. Further complicating the design and delivery of psychotherapy are the differing treatment targets for acute episodes and the maintenance phase. As very few medications are robust in all phases of BD, so too are the psychotherapies. A final critical limitation of psychotherapy involves the difficulty in delineating
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a psychological model for BD with its various phases; in the absence of a model capable of spanning all types of episodes and maintenance, it must be anticipated that psychotherapy itself will be limited in impact. This chapter begins with a summary of the major treatment manuals of cognitive-behavioural therapy (CBT) for BD in adults, highlighting the specific therapeutic manoeuvres and contrasting the broader goals of each book. Next, some unresolved issues relating to the theoretical underpinnings of the CBT model in BD are highlighted, followed by a detailed summary of the major treatment trials of CBT conducted in the past decade. Finally, a more precise role for CBT is delineated, with consideration of costs, ease of dissemination and future directions for research.
Overview of key CBT manuals for bipolar disorder The most extensively evaluated psychotherapy in psychiatry is CBT, so it is natural that it has been applied to BD as well. Three major manuals of CBT for adults with BD have been published, of which only one has been used extensively in studies [3–5]. One patient manual on CBT (further explaining the concepts discussed in therapy and also providing frequently used handouts) has been published [6] and one manual has been published on the use of CBT in first-episode BD [7]. However, the latter tends to address gaps in other manuals that may be specifically related to first-episode presentations and to the developmental needs of young adults. As such, this section will focus on only one the three core manuals. The first limitation is that all three manuals, and almost all published studies, deal with BD in the maintenance phase. Application of CBT during acute mania is not recommended, and data on the utility of CBT during acute bipolar depression is only now beginning to emerge. Two of the manuals [3,4] are more explicitly designed to be brief, with a judicious blend of cognitive and behavioural techniques
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Table 1 Treatment outlines of three major manuals for CBT for BD in adults. Lams CBT programme
Bascos CBT programme
Newmans CBT programme
Stage 1 (sessions 1–4): Introduction to diathesis-stress model, review symptom history, self-monitoring, generate list of goals. Stage 2 (sessions 5–16): introduction to activity scheduling, thought monitoring, thought challenging, challenging dysfunctional assumptions, behavioural experiments, identification of early warning signs, medication adherence (costs-benefit analysis). Stage 3 (sessions 17–20): review of cognitive behavioural techniques, self-management issues, other issues related to interpersonal relationships and stigma.
Stage 1 (sessions 1–7): Psychoeducation overview of CBT, Bipolar Disorder, Meds, Symptomatology.
Part 1 (Chapter 2): Introduction to Bipolar Disorder, therapy homework, cognitive traits and their assessment.
Stage 2 (sessions 8–11): Cognitive tools biased thinking, analysis of negative automatic thoughts, cognitive changes in depression, mania.
Part 2 (Chapters 3 and 4): Recognizing warning signs and consequences, thought records, activity scheduling; self and family reports, increasing mastery and pleasure.
Stage 3 (sessions 12–13): Behavioural tools - behavioural aspects of depression and mania.
Part 3 (Chapter 5): Medications challenges and strategies.
Stage 4 (sessions 14–20): Psychosocial problems - problem assessment, development, and resolution.
Part 4 (Chapters 6 and 7): Interpersonal and psychological issues interventions and strategies; stigma, self-blame and disclosure.
that are implemented in 15–20 sessions. The Newman manual utilizes a longer treatment time to put greater emphasis on classical cognitive therapy elements, particularly schemas (a patients belief system or persistent way of thinking, also called a cognitive trait). Recalling the three primary roles for bipolar psychotherapy – psychoeducation, symptom control including relapse prevention, and problemsolving/healing – one can approach CBT to BD by choosing a manual that suits the goals of the therapist and patient. Table 1 summarizes key treatment aspects of each manual. The first published manual, by Basco and Rush, is the most explicit of the three in providing detailed psychoeducation. Clearly designed to be delivered in the maintenance phase of the illness, this manual utilizes very explicit goals and specific learning objectives, described in detail for each of 20 sessions. The first seven of these sessions involve topics such as illness definition, self monitoring, overview of medication and compliance, fulfilling the mandate of providing psychoeducation. The next four sessions deal with cognitive changes in depression and mania, with full invocation of automatic thought records. Following this cognitive therapy primer, sessions 12 and 13 address behavioural strategies during depression and mania. The final seven sessions are devoted to identification and resolution of psychosocial problems using the CBT skills taught in earlier sessions. The clarity and detail of the session descriptions and the overall manual lend themselves to clearer implementation and evaluation. Only one research study has been published using this manual, from our group [8], and is discussed later in this chapter.
The second major manual, titled Cognitive Therapy for Bipolar Disorder [4], explicitly labels the purpose of the treatment as ‘prophylactic psychotherapy in conjunction with medication’. Consistent with its title, the first five sessions largely employ a classical cognitive approach, with emphasis on orientation to CBT, agenda setting, self monitoring and goal setting. Psychoeducational components are embedded in the introduction, but constitute a smaller emphasis than with the Basco and Rush approach. Sessions 6–16 incorporate some behavioural approaches, including activity scheduling and behavioural experiments, but greatest emphasis is placed on thought monitoring, thought challenging and exploration of dysfunctional assumptions. A traditional psychoeducational approach is returned to with discussion of medication compliance and sessions on development of an early warning symptoms list, in order to conduct a relapse drill of manoeuvres to be employed at first signs of symptoms. The final sessions 17–20 review CBT principles, prepare the patient for termination, and explore stigma and interpersonal issues. This manual has been used in two major studies (discussed later), one involving Lam et al.s original validation study [9], and a second Psychoeducation versus CBT study done by our group ([10]; Parikh et al., submitted, 2009). The most recently-published manual from Newman and colleagues [5] positions itself as a more discussion-orientated monograph, rather than a session by session manual. It avoids specifying to the therapist specific topics for each session, but the CBT intervention may be understood as covering four distinct parts, with principles organized into
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book chapters. Also, the book does include a sample case where core elements of psychoeducation and CBT skills are acquired within the first 15 sessions, followed by various sessions for crises, for couples therapy, and for relapse prevention, ending at close to 50 sessions. The first part covers introduction to therapy and to BD over a few sessions, while the second part – perhaps representing five sessions – teaches many of the core tools of CBT, including thought records and behavioural techniques. A third section rather briefly reviews medication challenges and strategies, and the final part extensively reviews interpersonal relationships, shame and stigma. This manual was integral to the CBT approach utilized in STEP-BD, which include a large RCT of various psychotherapies in acute bipolar depression (discussed later in chapter). Returning to our original framework for bipolar psychotherapy – psychoeducational, symptom control including relapse prevention and problem-solving/healing – we can see that all three manuals offer significant attention to each component. Clearly the Basco and Rush book emphasizes psychoeducation the most, while the Newman et al. monograph emphasizes issues of broader psychological concern. No one manual thus can been seen as superior; however, one could attempt to choose one which most clearly aligns with the stage of illness of the patients. Individuals early in the course of illness likely would benefit from a more explicit psychoeducational emphasis, while veterans of the disorder might prefer exploration of deeper issues of stigma and loss. From the perspective of the reader, a therapist new to CBT would benefit from the explicit guidance provided by the first two manuals; experienced therapists who may be more inclined to work on interpersonal issues and the sequelae of BD may prefer to rely on the Newman approach.
Theoretical underpinnings for a model of CBT for bipolar disorder One of the obvious critiques of the currently available manuals is that many of the techniques outlined overlap considerably with generic techniques or even specific components (such as self-regulation) that are a feature of other psychological therapies used in BD. Also, highlighting key targets for a psychological intervention for all-comers is only one half of an empirical approach – the other critical component is the theoretical underpinning that dictates the clinical conceptualization. Historically, the strength of CBT has been that the therapy model is clearly derived from a unique patient formulation that highlights both transdiagnostic cognitive dysfunction (e.g. over-general processing style; dysfunctional beliefs relating to perfectionism or control) as well as disorder-specific or idiosyncratic personal beliefs that make the individual at risk of episodes of a particular mental disorder, for example, the cognitive model of depression highlights the role of core beliefs about
the self related to lovability. It is hypothesized that these increase risk of depression at times of break-up of significant relationships, thus targeting and modifying these beliefs is an important ‘relapse prevention’ strategy. Alternatively, the model of anxiety incorporates the individuals tendency to predict negative future outcomes allied to their underestimation of their own ability to cope with uncertainty and their under-estimation that others would help them. These theoretical underpinnings aid the therapist in producing a coherent individualized formulation of the problem that is acceptable to the patient and provides a rationale for the interventions used at each stage in therapy (in CBT automatic thoughts are tackled first, then cross-situational themes in these thoughts are used to identify themes that give clues to the individuals likely underlying belief system and core schema). In severe mental disorders, all psychological models acknowledge the interaction between biological vulnerability and psycho-social stressors. The bipolar CBT model suggests that the physiological predisposition for BD interacts with life events and coping abilities that are moderated by cognitive ‘styles’ that confer vulnerability. Thus genetic predisposition for bipolar episodes may be catalysed by negative or positive events that are filtered through the individuals cognitive ‘schemas’. These schemas are reflected in the content and structure of the automatic thoughts and maladaptive assumptions that characterize mood episodes [9,11]. Since empirical support is robust for the CBT model of depression [12–14], this has been incorporated as a major component of a model for BD. However, no manual has, as yet, been able to provide a coherent description of the belief system that would lead an individual to become manic on some occasions or depressed on others. Furthermore, attempts to do this tend only to provide a model for elated mania – which is actually less frequent than dysphoric mania as a presentation. For example, Scott [15] noted that Becks original cognitive model of mania was the mirror image of his model of depression, hypothesizing a ‘positive cognitive triad’, where the self was seen as lovable and powerful and the future was overly optimistic. Such hyper-positive thinking was buttressed by cognitive distortions, which provide biased confirmation of this hyper-positive cognitive triad. This offers an accurate observation of mood state specific schemas but tells nothing of the apparent evolution and links between events and underlying vulnerability beliefs. If an individual is at risk of depression and mania, their mood specific underlying beliefs and schemata seem to be represented as polar opposite concepts (e.g. manic self ¼ ‘Im terrific’; depressed self ¼ ‘Im a failure’) that prove to be difficult, if not impossible for the bipolar patient to reconcile when euthymic. We then have to explain differential activation of these beliefs or a set of overarching beliefs (e.g. one of the few possibilities is ‘I am different’) that can be
Cognitive-Behavioural Therapy
activated by depression-inducing or mania-inducing life events. At this stage, CBT for BD may appear to take on the quality of addressing two sets of mood specific opposing schemas and underlying beliefs, leaving little attention to periods of normal mood states (and thus suggesting a need for a CBT model of euthymic BD). An alternative possibility that has been explored through a post-hoc analysis of treatment trial participants by Lam and colleagues [16] is that high levels of trait perfectionism and excessive striving for achievement may confer increased vulnerability to experience mood relapse. This builds on the work of Sheri Johnson [17], who demonstrated increase in hypomanic symptoms in those at risk of BD who engage in goal-directed behaviour. This model has intuitive appeal as it links psychological manifestations with underlying neural activity in the reward system. However, the hypothesis that those with evolving manic episodes have enhanced levels of self-esteem and increased confidence conflicts with evidence. In fact, if self-esteem and confidence are measured implicitly, the ratings are more similar than different in many instances to those evolving a depressive episode [18]. In addition, the extant research evidence suggests that many bipolar patients experience negative thoughts and beliefs, some of whom continue to think negatively even after their depression remits. Johnson and Tran [19] review the evidence for both negative and hyperpositive schemata relevant to BD and suggest this apparent conflict may be reconciled in that it is possible that bipolar patients may be overly influenced by environmental feedback. At best, current models may explain the presentation of hypomania. The limited data available explain only why some individuals who experience the early symptoms of a (hypo)manic prodrome do or do not experience escalation into an episode. Thus, a manic episode may be better characterized by a biologic shift, followed by a number of psychological and behavioural changes. While the modification of idiosyncratic dispositional (I dont need sleep because I am a special person) or illness attributions (Lack of sleep is a sign I may be developing an illness episode) may prevent some of the problems occurring in BDs, they also suggest the cognitive interventions play a secondary role to all the other required self-management strategies, for example, regulation of sleep patterns, avoidance of certain life-events, recognition of and early intervention when first prodromal symptoms appear [20]. The three manuals focus heavily on these psychoeducation principles and also incorporate behavioural activation strategies and problem solving skills for depression (e.g. activity scheduling) as well as time-delay and stimulus control strategies for hypomania/mania. The sections on cognitive interventions, however, will no doubt need further revision over time. These above comments do not suggest CBT lacks a viable role, but highlight that, without a more robust theoretical cognitive framework, CBT in BD is currently a generic,
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non-specific psychoeducation intervention that incorporates some cognitive and behavioural techniques, not a specific empirically driven approach based on a cognitive formulation and primarily focused on cognitive style and processing, which would be the expected therapy model, for example in unipolar depression and/or anxiety disorders. Having noted this, there are several large-scale RCTs that illuminate our understanding of the strengths and weakness of current CBT approaches used in clinical practice. We now review these studies by examining CBT versus usual treatment or control conditions and then comparing CBT to other psychological therapies.
Review of CBT trials Since 2000, one important pilot study and three major published randomized controlled trials of CBT (one of which generated separate outcome papers at 12 and 30 months) have been published. Studies involving CBT as one arm of multiple psychosocial interventions are considered separately later in this chapter. Here, CBT is used, although some prefer to use CT to signify cognitive therapy; in fact, all the bipolar CBT or CT manuals include behavioural techniques, and so CBT and CT are interchangeable. Scott et al. [21] conducted a pilot study of cognitive therapy comparing 21 outpatient bipolar patients who received up to 25 individual sessions of cognitive behavioural therapy over a 6-month period to 21 waiting-list controls. Outcomes targeted were relapse rates, depressive and manic symptoms, psycho-social functioning and general psychopathology. At 6 months, the CBT intervention subjects showed improvements compared with controls. At 18 months after baseline (i.e. 12 months after terminating treatment), those who received CBT showed a 60% reduction in relapse rates and fewer hospitalizations compared to their own reported relapses and hospitalizations prior to commencing treatment. This pilot study provided further support for conducting a full RCT. Lam et al. [22] randomized 103 euthymic patients with bipolar I disorder to either individual CBT (n ¼ 51) or treatment-as-usual (n ¼ 52). The CBT intervention consisted of 18 sessions of CBT over six months followed by two booster sessions over the following six months. Primary outcomes were number of episodes, number of days in episodes, social functioning, coping strategies and dysfunctional attitudes. Results of this study showed important effects at the end of year one that diminished subsequently. During the 12-month initial study period (which includes the additional time in CBT for those allocated to therapy), the CBT group had fewer bipolar relapses, fewer days in episodes and fewer admissions. The intervention group also had higher social functioning and better coping skills at the 12-month mark.
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Lam et al. [23] reported 30-month data (reported as a 6-month intervention period and a 24-month follow-up period) of the original 2003 study. Overall, the CBT intervention group still had better outcomes in terms of time to relapse, but the effect over the 30 months was almost entirely due to the benefits conferred over the first year; from month 12–30, there were almost no differences between CBT and control. Furthermore, the improvements in social functioning and coping skills at month 12 were not seen at later assessments. Given the initial effects of reducing relapse and time in episode, CBT was recommended, with a suggestion that ongoing maintenance CBT might be effective in maintaining the benefits seen in year one. Given the early promise of CBT, Scott and colleagues [24] sought to explore the utility of the treatment to a broader cohort of bipolar patients in a pragmatic effectiveness trial. They recruited 253 subjects from general adult psychiatry services across five UK cities with virtually no exclusion criteria. It was found that the participants were about twice as likely to have serious comorbidity or higher bipolar severity, than the seven major preceding psychosocial studies in BD. Furthermore, unlike any of the other studies reviewed in this chapter, bipolar patients were recruited in all phases of the illness, with approximately one-third in a depressive episode (and a very small sub-group with mild hypomania). In their RCT, 126 subjects were assigned to treatment as usual (TAU), while 127 were assigned to receive 20 sessions of individual CBT. Over one-quarter of the intervention group attended fewer than 13 sessions, and 40% did not achieve the stated goals of CBT, reflecting the challenge of treatment engagement and adherence in a more ill sample. Primary outcomes included time to recurrence of an episode, with an additional outcome a comparison of the weekly mood symptom ratings from the LIFE instrument. Results of the 18-month study showed no differences in recurrences or average mood ratings between CBT and TAU. However a post-hoc analysis revealed that those with 1–5 or 6–12 prior episodes showed outcomes similar to or better than the outcomes achieved in other CBT efficacy trials. The authors highlighted that in the general NHS system in the United Kingdom, this group represent only 20% of recruits to their pragmatic trial. The authors concluded that their findings did not support the use of CBT to prevent recurrence for unselected BD population being treated in United Kingdom general psychiatry services, except possibly in those with fewer episodes. The introduction of ‘3rd generation’ CBT models, for example, schema-focused and cognitive analytic therapies, for other common mental disorders has again influenced thinking on approaches to BD. Ball et al. [25] conducted a randomized controlled trial comparing 20 weekly sessions of schema therapy (CBT with emotive techniques; n ¼ 25) versus a control group who received usual treatment (n ¼ 27). Outcomes included relapse rates, dysfunctional
attitudes, psychosocial functioning, hopelessness, self-control and medication adherence. At the end of the 6-month treatment period, the CBT group had modestly lower depressive symptoms. All subjects were assessed every three months for an additional year, with the CBT group experiencing non-significant trends in a greater time to relapse, lower mania scores (YMRS) and improved behavioural self-control. Given the relatively small number of subjects as well as its modest findings, the study suggests the value of CBT as an acute intervention but echoed the Lam et al. [22] study in showing the loss of impact of CBT after acute treatment ceased. These results are in contrast to the results of CBT trials for unipolar depression and anxiety disorders, which have shown long-term and enduring effects from CBT.
Summary of CBT trials with ‘treatmentas-usual’ controls While the results of initial studies in CBT for BD were generally positive, the results have often been modest; some did not show maintenance of gains over longer follow-up intervals (e.g. [26]), while others did not show any gains over control groups (e.g. [24]). In addition, there have not always been associated changes in the central mechanism of action underlying this therapeutic strategy – namely changes in underlying dysfunction beliefs [8]. Given that the central and distinguishing focus of CBT is its emphasis on ameliorating dysfunctional thoughts, the modestly positive clinical outcomes and modest effects on dysfunctional attitudes suggest that CBT is of limited value to the average bipolar patient. The role of CBT versus other therapies then merits deeper exploration.
Summary of comparative studies Three key studies have now examined the comparative benefits of different psychosocial interventions. In the largest study of psychosocial intervention in the acute phase of illness, Miklowitz and colleagues [27] involved multiple sites from the Systematic Treatment Enhancement Programme for Bipolar Disorder (STEP-BD; [28]) This programme enrolled over 4361 bipolar subjects in a variety of studies, some open and some RCTs. From this large sample, 15 sites contributed 293 subjects to a study of acute psychosocial intervention. Adding to the complexity was that 236 of these subjects were also enrolled simultaneously to a RCT of mood-stabilizer plus either antidepressant or placebo for bipolar depression. The remaining 57 subjects (293 minus 236) were not eligible for the antidepressant study, but were treated openly with pharmacotherapy according to common treatment guidelines. Psychosocial treatment options included Interpersonal and Social Rhythm Therapy (IPSRT), Family-Focused
Cognitive-Behavioural Therapy
Therapy (FFT) and CBT. However, assignment of the psychosocial treatment was further complicated by the fact that some members did not have family members available (n ¼ 134, or almost half of the 293 subjects). Furthermore, for practical reasons, few sites could offer treatment in all three modalities. Therefore, the study was designed so that at any one site, only two intensive psychosocial treatments would be offered. Thus, 10 sites offered CBT, 9 provided FFT, while 11 offered IPSRT. All 15 sites offered the control condition, which was three individual sessions of ‘Collaborative Care (CC)’. CC was described as containing elements of providing ‘a brief version of the most common psychosocial strategies shown to offer benefit for bipolar disorder’ [27]. Thus, it is worth noting that CC is not a specific brief intervention for bipolar depression, but a more general brief psychosocial manoeuvre. As such, it would be reasonable to view the CC control condition as a type of enhanced TAU, rather than a depression specific intervention. The CC was contrasted to up to 30 sessions of the intensive psychosocial interventions given over a nine-month period, with a total study period of 12 months (including the nine-month treatment time). Primary outcomes were time to recovery and the proportion of patients classified as well during each of the 12 study months. Major findings of the study were that all three intensive interventions, versus the CC control, were able to achieve higher recovery rates by year end and also shorten time to recovery. Functional outcomes were also better with intensive psychotherapy [27]. No differences were seen between the three intensive treatments. The authors concluded that intensive psychosocial intervention was more beneficial than brief intervention for bipolar depression, but acknowledged that cost effectiveness merited further study. It is critical to emphasize that out of all of the studies reviewed here, this is the only one that explicitly targeted BD in the depressed phase, rather than in the maintenance phase. Finally, Parikh and colleagues have conducted two RCTs, which involve psychoeducation (PE) in comparison to CBT in the maintenance phase. In the first study [8], 79 subjects were randomized to receive individual interventions, either PE (n ¼ 39) or PE plus additional CBT (n ¼ 40). The same manual [3] was used to deliver both the PE (the first 7 PE sessions) and the PE plus CBT treatment (the same first 7 PE sessions plus 13 additional CBT sessions). There were no differences in the primary outcome of relapses over a one-year period, but on the measure of number of days of depressed mood (of any severity, not necessarily in a full depressive episode), there was an advantage to CBT. Parikh and colleagues second comparative PE versus CBT study (currently under review) was also a study in the maintenance phase. However, it was designed more explicitly as an effectiveness study, with broad entry criteria, multiple sites and sensitivity to cost and efficiency of treatment delivery. As we have seen, various psychosocial
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interventions have demonstrated efficacy, but differ in intensity, cost and ease of dissemination. Such differences may provide more direction for public health recommendations of which treatments to recommend. A total of 204 participants (ages 18–64) with either BD type I or II participated from four Canadian academic centres. Participants were assigned to receive either 20 individual sessions of CBT (n ¼ 95) or 6 sessions of group PE (n ¼ 109). Primary outcome of symptom course and morbidity was assessed prospectively over 78 weeks using the Longitudinal Interval Follow-up Evaluation, which yields depression and mania symptom burden scores for each week. Additional outcomes included time to relapse. Both treatments had similar outcomes with respect to reduction of symptom burden and the likelihood of relapse. Approximately 8% of subjects dropped out prior to receiving PE, while 64% were treatment completers; rates were similar for CBT (6% and 66%, respectively). Psychoeducation costs $160 per subject compared to CBT at $1200 per subject. Despite longer treatment duration and individualized treatment, CBT did not show a significantly greater clinical benefit compared to group PE. From a public health perspective, if we assume both active treatments achieve better outcomes than would have been achieved with TAU alone (it is not always possible given the constraints and costs of clinical RCTs to have this three-group design; although technically this is useful so that we know how much better the recruits to the new treatment did compared to usual treatment as well as compared to each other), then the similar efficacy but lower cost and potential ease of dissemination suggest that the use of group psychoeducation intervention (alongside medication) may be a preferable recommended intervention in a stepped care model [29], with CBT offered on a more selective basis by CBT therapists with specific expertise in BD.
CBT for BD: the proper role and possible future role We began this chapter by acknowledging the limitations of pharmacotherapy. These limitations have spurred great interest in CBT for BD, given CBTs enviable track record across multiple other mood and anxiety disorders. In spite of a weakness in the scientific underpinnings for a model for CBT, a number of relevant interventions and manoeuvres have been developed to target key factors in BD, including, education about BD, medication and general treatment adherence, early detection of prodromal mood symptoms, disruptions in circadian rhythms, communication styles and interpersonal stress, coping with stigma, reducing expressed emotion, stress and problem solving, correcting maladaptive thoughts and beliefs, as well as addressing substance use. In fact, as also shown elsewhere in this book, multiple other psychosocial interventions also
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address many of the same targets, and use only mildly differing strategies to foster change. The net findings of these interventions are clearly positive, if modest [30]. The encouraging aspect of CBT for BD is that it allows an individual trained in CBT to use many of the same tools for BD. In particular, unipolar and bipolar patients have many similar symptoms during acute depressive episodes, and the same cognitive and behavioural strategies so clearly effective in Major Depressive Disorder are clearly applicable to Bipolar Depression. This is vital, as depressive symptoms are the greatest symptom burden in BD. Furthermore, CBT techniques have been successfully adopted in help with addictive disorders (which are commonly comorbid with BD), and now there is preliminary evidence of such approach being useful for bipolar patients with addictions [31]. But to improve CBTs efficacy, researchers will need to further elaborate the cognitive model and have to expand to a range of cognitive and behavioural targets to cope with bipolar manic and depressive relapse as well as new schemas or underlying beliefs. New underlying core beliefs, or more accurately, bipolar related schemas, will need to be discovered and specifically targeted for intervention. Possible areas for further exploration include: excessive pursuit of perfectionism or high achievement; schemas highlighting unusual fragility of self-concept; internalized stigma; and goal-directed behaviours. Mapping psychological models of such constructs onto a neuroscience-based framework is also necessary if we are to evolve a robust model; understanding where these constructs lie neuroanatomically, how they are biologically mediated, and how biological as well as psychological manoeuvres serve to alter symptom expression and ultimately patient functioning, represent an exciting area for future mindbrain research [14]. Finally, we cannot ignore the issue of cost and ease of dissemination of CBT. The experience of the UK National Health Service (NHS) is instructive here. Briefly, CBT for unipolar depression was identified as efficacious and costeffective; this then led to the creation of ‘low cost’ CBT Therapists attached to Primary Care practices so that CBT could be easily and cheaply employed. Most recently, the NHS has reviewed the efficacy of computer and Internet delivered CBT for depression and anxiety disorders, and extended a mandate for such interventions to be widely available, often by ‘prescription’ by the patients general practitioner. Computer-based or Internet delivered CBT for BD will need to be developed and delivered. As has been observed with anxiety disorders in particular [32], such computer or Internet interventions work best with active encouragement and facilitation by a therapist, rather than as a full substitute for a live therapist. From a societal perspective, the ease of dissemination also depends on the cost and ease of training individuals to deliver that treatment in a competent and consistent manner. For example, Lam et al.
demonstrated that when expert therapists used CBT with euthymic BD subjects, the intervention was costeffective [23]. In the PE versus CBT study, we used psychiatric nurses to deliver group psychoeducation, who were trained with short workshops, but needed Masters level therapists experienced in CBT to train for the Bipolar CBT intervention – a more costly treatment provider. Furthermore, individual therapy for CBT has both cost and capacity constraints, inviting the exploration of Group CBT for BD. Successful expansion of CBT in BD then will require evolution of improved techniques and targets, as well as attention to costs and modes of delivery [33].
References 1. Huxley, N.A., Parikh, S.V. and Baldessarini, R.J. (2000) Effectiveness of psychosocial treatments in bipolar disorder: state of the evidence. Harvard Rev. Psychiat., 8 (3), 126–140. 2. Scott, J. and Colom, F. (2005) Psychosocial treatments for bipolar disorders. Psychiat. Clin. N. Am., 28, 371–384. 3. Basco, M.R. and Rush, A.J. (1996) Cognitive-behavioural Therapy for Bipolar Disorder, Guilford Press, New York. 4. Lam, D.H., Jones, S.H., Hayward, P. and Bright, J.A. (1999) Cognitive Therapy for Bipolar Disorder, John Wiley & Sons, Ltd, Chichester, UK. 5. Newman, C.F., Leahy, R.L., Beck, A.T. et al. (2002) Bipolar Disorder: A Cognitive Therapy Approach, American Psychological Association, Washington DC. 6. Scott, J. (2003) Overcoming Mood Swings: A CBT Approach to Managing Manic Depression, Constable Robinson, London. 7. Macneil, C.A., Hasty, M.K., Conus, P. et al. (2009) Bipolar Disorder in Young People: A Psychological Intervention Manual, Cambridge University Press, Cambridge, UK. 8. Zaretsky, A., Lancee, W., Miller, C. et al. (2008) Is cognitivebehavioural therapy more effective than psychoeducation in bipolar disorder? Can. J. Psychiat., 53 (8), 441–448. 9. Lam, D.H., Bright, J., Jones, S. et al. (2000) Cognitive therapy for bipolar disorder – A pilot study of relapse prevention. Cognitive Ther. Res., 24, 503–520. 10. Parikh, S.V., Velyvis, V., Yatham, L.N. et al. (2007) Coping Styles in the prodomes of mania. Bipolar Disord., 9, 589–595. 11. Leahy, R.L. and Beck, A.T. (1988) Cognitive therapy of depression and mania, in Depression and Mania (eds R. Cancro and R. Georgotas), Elsevier, New York, pp. 517–537. 12. Beck, A.T., Rush, A.J., Shaw, B.F. and Emergy, G. (1979) Cognitive Therapy of Depression, The Guilford Press, New York. 13. Clark, D.A., Beck, A.T. and Alford, B.A. (1999) Scientific Foundations of Cognitive Theory and Therapy of Depression, John Wiley & Sons, Inc., Hoboken, NJ, US. 14. Beck, A.T. (2008) The evolution of the cognitive model of depression and its neurobiological correlates. Am. J. Psychiatry, 165, 969–977. 15. Scott, J. (2001) Cognitive therapy as an adjunct to medication in bipolar disorder. Brit. J. Psychiat., 41, S164–S168.
Cognitive-Behavioural Therapy 16. Lam, D.H., Wright, K. and Smith, N. (2004) Dynsfunctional assumptions in bipolar disorder. J. Affect. Disord., 79, 193–199. 17. Johnson, S.L. (2005) Mania and dysregulation in goal pursuit: a review. Clin. Psychol. Rev., 25 (2), 241–262. 18. Mansell, W. and Scott, J. (2006) Dysfunctional beliefs in bipolar disorders, in Psychology of Bipolar Disorders: New Developments and Research Strategies (eds S. Jones and R. Bentall), Oxford University Press, Oxford, UK. 19. Johnson, S.L. and Tran, T. (2007) Bipolar disorder: What can psychotherapists learn from the cognitive research? J. Clin. Psychol., 63 (5), 425–432. 20. Scott, J. (2004) Bipolar disorders, in The Handbook of EvidenceBased Psychotherapy: A Guide for Research and Practice (eds C. Freeman and R. Power) John Wiley & Sons, Ltd, Chichester, UK, pp. 301–314. 21. Scott, J., Garland, A. and Moorhead, S. (2001) A pilot study of cognitive therapy in bipolar disorder. Psychol. Med., 31 (3), 459–467. 22. Lam, D.H., Watkins, E.R., Hayward, P. et al. (2003) A randomized controlled study of cognitive therapy for relapse prevention for bipolar affective disorder: Outcome for the first year. Arch. Gen. Psychiatry, 60 (2), 145–152. 23. Lam, D.H., McCrone, P., Wright, K. and Kerr, N. (2005) Costeffectiveness of relapse-prevention cognitive therapy for bipolar disorder: 30-month study. Brit. J. Psychiat., 186, 500–506. 24. Scott, J., Paykel, E., Morriss, R. et al. (2006) Cognitive behavioural therapy for severe and recurrent bipolar disorders. Brit. J. Psychiat., 188, 313–320. 25. Ball, J.R., Mitchell, P.B., Corry, J.C. et al. (2006) A randomized controlled trial of cognitive therapy for bipolar disor-
26.
27.
28.
29.
30.
31.
32.
33.
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der: focus on long-term change. J. Clin. Psychiat., 67, 277–286. Lam, D.H., Hayward, P., Watkins, E.R. et al. (2005) Relapse prevention in patients with bipolar disorder: Cognitive therapy outcome after 2 years. Am. J. Psychiatry, 162, 324–329. Miklowitz, D.J., Otto, M.W., Frank, E. et al. (2007) Psychosocial treatments for bipolar depression: a 1-year randomized trial from the Systematic Treatment Enhancement Program. Arch. Gen. Psychiatry, 64 (4), 419–426. Sachs, G.S., Thase, M.E., Otto, M.W. et al. (2003) Rationale, design, and methods of the systematic treatment enhancement program for bipolar disorder (STEP-BD). Biol. Psychiatry, 53, 1028–1042. Parikh, S.V. and Kennedy, S.H. (2004) Integration of patient, provider, and systems treatment approaches in bipolar disorder, in Mood Disorders: A Handbook of Science and Practice (ed. M. Power), John Wiley & Sons, Ltd, London, pp. 247–257. Miklowitz, D.J. (2008) Adjunctive psychotherapy for bipolar disorder: state of the evidence. Am. J. Psychiatry, 165, 1408–1419. Weiss, R.D., Griffin, M.L., Greenfield, S.F. et al. (2000) Group therapy for patients with bipolar disorder and substance dependence: results of a pilot study. J. Clin. Psychiat., 61, 361–367. Spek, V., Cuijpers, P., Nyklicek, I. et al. (2007) Internet-based cognitive behaviour therapy for symptoms of depression and anxiety: a meta-analysis. Psychol. Med., 37, 319–328. Miklowitz, D. and Scott, J. (2009) Psychotherapies for bipolar disorders: Cost-effectiveness, mediating mechanisms and future research needs. Bipolar Disord., 11 (Suppl. 2), 110–122.
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Interpersonal and Social Rhythm Therapy for Bipolar Disorder Holly A. Swartz1, Ellen Frank2,3, Laura E. Zajac4 and David J. Kupfer5 1,2,5
Department of Psychiatry, University of Pittsburgh School of Medicine, Western Psychiatric Institute and Clinic, Pittsburgh PA, USA 3,4 Department of Psychology, University of Pittsburgh, Pittsburgh PA, USA
Introduction Pharmacotherapy continues to be the mainstay of treatment for bipolar disorder. Nevertheless, for individuals suffering from bipolar disorder, treatment with pharmacotherapy alone is associated with incomplete remission [1], substantial risk for recurrence [2] and persistent impairments in functioning [3]. Psychotherapies that address psychosocial difficulties and enhance illness management (i.e. medication adherence, detection of warning signs of relapse) may play an important role in bridging the gap between symptom improvement brought about by medications and a full recovery from illness. Indeed, a growing body of research suggests that, when compared to treatment with pharmacotherapy alone, treatment with the combination of medication and a bipolar-specific psychotherapy results in better outcomes for patients [4]. Current expert treatment guidelines recommend the combination of psychotherapy and medication for the acute management of bipolar depression and during the maintenance phase of the disorder [5]. Thus, psychotherapy is considered an integral component of treatment for individuals suffering from bipolar disorder. In this chapter, we will describe Interpersonal and Social Rhythm Therapy (IPSRT, a bipolarspecific psychotherapy).
Overview of interpersonal and social rhythm therapy IPSRT, developed by Ellen Frank and colleagues at the University of Pittsburgh [6], evolved as a response to the observation that pharmacotherapy, although essential to
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the treatment of bipolar disorder, is often not enough for patients suffering from the disorder. Studies of maintenance treatment with mood-stabilizers alone demonstrate unacceptably high rates of recurrence over a two to three-year period [7,8], and persistence of residual psychosocial difficulties despite syndromal recovery [9]. IPSRT was designed to address these clinical dilemmas. It is a tool to facilitate a full recovery from illness and promote long-term wellness. IPSRT, built on the principles of interpersonal psychotherapy (IPT for unipolar depression [10]) and theories of circadian rhythm biology [11], has the tripartite goals of supporting medication adherence, minimizing the impact of disruptive life events on social rhythms and addressing interpersonal difficulties as they arise in the context of a mood disorder. In a broader sense, IPSRT strives to dampen the most extreme oscillations of mood and energy by helping patients to manage provocative social and environmental factors more effectively. IPSRT integrates psychoeducational, interpersonal, and behavioural strategies in order to reduce symptoms, improve functioning and prevent recurrence of episodes.
Theoretical background The framework of IPSRT rests on three related theoretical constructs: (1) the ‘instability model’ of bipolar disorder proposed by Goodwin and Jamison [1]; (2) theories regarding the function of social and environmental cues in promoting/disrupting circadian rhythm integrity [11,12]; and (3) the principles of IPT conceptualized by Klerman and Weissman [10]. We discuss the theoretical underpinnings of each component below.
Instability model In their instability model, Goodwin and Jamison define three interconnected pathways to episode recurrence:
Interpersonal and Social Rhythm Therapy
taxing life events, medication non-compliance and social rhythm disruption [1]. Each pathway potentially leads a stable patient towards an episode of depression or mania. Their model suggests that individuals with bipolar disorder are fundamentally (biologically) vulnerable to disruptions in circadian rhythms, a hypothesis that is supported by direct evidence implicating the genes that control the circadian rhythm system in the genesis of mood disorders [13], as well indirect evidence such as data suggesting that treatments that are currently employed to treat mood disorders may act by resetting the biological clock [14]. Psychosocial stressors, in turn, interact with this biologic vulnerability to cause symptoms. For instance, stressful life events (such as the birth of a child) disrupt social rhythms, which causes disturbances in circadian integrity which, in turn, may lead to recurrence. Alternately, problematic interpersonal relationships or irregular work schedules contribute to non-adherence to a medication regimen which, again, may lead to recurrence. Conversely, a patient’s ambivalent feelings about medications or intolerable side effects may lead a patient to skip doses or discontinue medication. As medication is decreased, symptoms and rhythm irregularities emerge. As a direct consequence of this model, one would assume that helping patients learn to take their medication regularly, lead more orderly lives and resolve interpersonal problems more effectively, would promote circadian integrity and minimize risk of recurrence. IPSRT focuses on all three of these pathways in an effort to stabilize mood
€ rers Zeitgebers and Zeitsto Related to the model elaborated by Goodwin and Jamison (above), circadian rhythm researchers have identified reciprocal relationships amongst circadian rhythms, sleepwake cycles and mood. It is well-documented, for instance, that sleep reduction can lead to mania in bipolar subjects [15,16]. Furthermore, sleep deprivation has significant (if transient) antidepressant effects in both unipolar and bipolar depressed subjects [17–20]. Ehlers and colleagues [11], attempting to bridge the biological and psychosocial models of depression, hypothesized that there are specific social cues that entrain biological cycles (Zeitgebers) and others that disrupt them (Zeitst€ orers). Social Zeitgebers are defined as personal relationships, social demands or tasks that entrain biological rhythms (e.g. meeting school age children at the bus stop at 3 p.m. each day). They further hypothesized that losing a social Zeitgeber (e.g. summer vacation with the attendant loss of the school bus pick-up) could trigger an episode by causing the dysregulation of biological rhythms [12]. Another example of a social Zeitgeber is a regular job. Losing a job that may have previously determined sleep/wake times, rest periods and meal times represents a lost Zeitgeber. In an individual
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with the genetic predisposition to bipolar disorder the physiologic and chronobiological disturbances produced by losing the social cues for sleep and meal times could be as important in the genesis of an episode as the psychological distress generated by the event. In contrast to Zeitgebers, Zeitst€ orers are defined as physical, chemical or psychosocial events that disturb the biological clock. For instance, travel across time zones represents a prototypical Zeitst€ orer. The abrupt change in the timing of light exposure, rest times and sleep schedule can produce a range of symptoms from mild ‘jet lag’ to a full-blown affective episode in predisposed individuals. Other examples of potential Zeitst€ orers include newborn babies, marital separations, work deadlines (especially those that require an individual to stay at work into the night, missing meals and sleep) and rotating shift work. Each of these disruptions has the potential to significantly alter an individual’s circadian and sleep-wake rhythms and, in turn, provoke an affective episode. IPSRT was built on the idea that helping patients to regulate social rhythms (modulate Zeitgebers and Zeitst€ orers) may help vulnerable individuals reduce the risk of developing mood symptoms.
Interpersonal psychotherapy IPT was developed by Klerman and colleagues as a treatment for unipolar depression [10]. Built on the tenets of social psychology and the observations of interpersonal theorists such as Harry Stack Sullivan, IPT focuses on the link between mood and interpersonal life events. IPT postulates that psychosocial and interpersonal factors are associated with the onset and maintenance of mood episodes in individuals biologically predisposed to affective disorders, and that symptoms of mood disorders interfere with the interpersonal coping skills of the afflicted individuals. In IPSRT, therapists use IPT strategies both to resolve interpersonal difficulties and to lessen the impact of stressful interpersonal events on daily routines.
Treatment strategies A hybrid model Built on these overlapping paradigms, IPSRT fuses three distinct interventions – psychoeducation, social rhythm therapy and IPT – into a single psychosocial treatment. IPSRT helps patients optimize daily schedules, resolve interpersonal difficulties and understand their illness in order to achieve symptom remission and improve interpersonal functioning. By intervening in these potential pathways to recurrence, IPSRT ultimately strives to prevent new episodes of illness in a highly vulnerable population. Each
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treatment intervention (psychoeducation, social rhythm therapy and IPT) will be described separately. In practice, however, these strategies are administered flexibly and fluidly, without distinct boundaries between modalities. During the course of a single session, the therapist moves seamlessly amongst the techniques, according to the particular needs of the patient. Thus, the IPSRT represents a true integration of these disparate approaches. Table 1 summarizes these three strategies and the treatment techniques associated with them.
Psychoeducation Psychoeducation subsumes a heterogeneous group of interventions that are deployed in the service of treating a wide variety of disorders. Virtually all bipolar-specific psychotherapies incorporate psychoeducation – albeit to varying degrees. Psychoeducation is also an integral part of standard IPT (see discussion below). In IPSRT, psychoeducation focuses on: (a) the illness and its consequences; (b) medications and their side effects; and (c) prodromal symptoms/detection of early warning symptoms. Patients receive information from the therapist about the symptoms
and course of bipolar disorder, the impact of the illness on vocational and social functioning and the medications used to treat bipolar disorder. In the course of IPSRT, patients are encouraged to become ‘experts’ in bipolar disorder so that they can collaborate more effectively in the management of their illness. In the instance of a physician-clinician treatment team, the non-physician therapist must also develop familiarity with the major classes of medications used to treat the disorder and their side effects so that they can help their patient recognize medication-related problems and collaborate with the physician to manage them. Therapists are encouraged to work collaboratively with the patient to understand and remedy sources of nonadherence – including management of side effects – that interfere with optimal quality of life. In order to encourage early identification of prodromal symptoms, the therapist reviews with the patient prior episodes of depression and mania. Jointly, the therapist and patient identify characteristic behaviours or symptoms that may herald the onset of an episode, and agree to routinely assess the patient for these harbingers of exacerbation.
Table 1 IPSRT treatment strategies. Strategy
Techniques
Psychoeducation
Provide education regarding: . medications and their side effects . course and symptoms of bipolar disorder Teach patients to recognize: . early warning signs of recurrence . prodromal symptoms Encourage patient to: . become ‘expert’ on their illness . collaboratively manage illness with therapist and psychiatrist
Social Rhythm Therapy
Balance stimulation and stability
Amy is a 31-year-old single female with a 10-year history of bipolar disorder. Recent plasma levels of her current primary mood stabilizer, sodium divalproex, were perplexingly low. In IPSRT, the therapist reviewed with Amy the parameters of therapeutic blood levels and then pointed out that the most recent blood tests fell below the therapeutic range. The therapist gently asked her if she had any insight into her uncharacteristically low blood levels. Amy burst into tears, revealing that her boyfriend had threatened to leave her because of a 30-pound-weight gain over the past year, which he attributed to sodium divalproex. The therapist acknowledged that weight gain can be a troubling side effect of many of the
Complete Social Rhythm Metric . monitor frequency/intensity of social interactions . monitor daily mood Search for specific triggers of rhythm disruption Gradually regularize social rhythms Interpersonal Psychotherapy
Clinical vignette 1
Conduct in-depth psychiatric evaluation Link mood to life events Establish interpersonal case formulation (focus on one or two problem areas): . grief . role transition . role dispute . interpersonal deficits Grieve the lost ‘healthy self’
medications used to treat bipolar disorder. Together they reviewed Amy’s currently prescribed medications which, in addition to the divalproex, included olanzapine and citalopram. Given the complex medication regimen currently prescribed for Amy, the therapist suggested that weight gain may not be solely attributable to the divalproex. They discussed other options, besides abruptly discontinuing her medication, such as consulting with her psychiatrist to discuss alternatives and pursuing an exercise regimen. In addition to helping Amy understand the importance of raising this issue specifically with her psychiatrist, the therapist discussed with Amy how her weight gain had affected her relationship. They reviewed the importance of educating her boyfriend about her medications, explored other areas of conflict in the relationship, and discussed the negative impact of the weight gain on Amy’s sex life with her boyfriend (related to her shame about her changing body).
Interpersonal and Social Rhythm Therapy
Social rhythm therapy Social Rhythm Therapy is based on the theory that stable daily rhythms lead to enhanced stability of mood. This component of treatment focuses on developing strategies to promote regular, rhythm-entraining, social Zeitgebers and manage the negative impact of disrupting Zeist€ orers. Each week patients are asked to complete an instrument, the Social Rhythm Metric (SRM), that helps them optimize their daily rhythms. This five-item self-report form ask patients to record daily activities (i.e. out of bed, first contact with another person, start work/school/volunteer/family care, dinner, to bed) [21], whether each occurred alone or with others present, and whether or not they involved significant amounts of social stimulation (i.e. quiet vs. interactive). Patients are also asked to rate their moods each day. In the beginning stages of treatment, the patient is asked to complete the SRM weekly. The first three to four weeks of SRMs are used to establish the patient’s baseline social rhythms. The therapist and patient jointly review the SRMs, identifying both stable and unstable daily rhythms. For instance, is the patient going to bed at a reasonable hour during the week but then staying out late on the weekends? Does the patient’s mood dip on days when she or he skips meals? By examining the SRMs, the therapist and patient can begin to identify behaviours that negatively influence the patient’s rhythm stability. Once baseline SRMs are collected and patterns of regularity/irregularity identified, the therapist and patient begin working towards rhythm stability through graded, sequential lifestyle changes. The therapist and patient identify short-term, intermediate and long-term goals to gradually bring social rhythms into a tighter, less variable range. For example, a short-term goal may be going to bed at a fixed time for a period of 1 week. In order to achieve that goal, the patient may need to make changes in his or her social behaviours (e.g. curtailing late-night social activities) and health-related behaviours (e.g. working with the psychiatrist to move all sedating medications to bedtime). Intermediate goals may include sleeping eight hours a night with no naps during the day or decreasing the number of hours spent at work. In order to accomplish these goals, the patient will build on short-terms gains but also institute some new social cues (such as signing up for afternoon classes to decreasing napping). The therapist emphasizes the importance of establishing a regular schedule, even if the schedule most comfortable to the patient is phase shifted. For instance, many patients with bipolar disorder prefer to establish regular routines that include a late night bedtime (e.g. 2 a.m.) and a later awakening time (e.g. 10 a.m.). The therapist helps the patient understand that virtually any regular schedule is acceptable, as long as the patient is able to meet his or her social obligations and is able to sleep for an adequate duration in a single time block (for most individuals, seven to eight hours). Long-term goals may consist of
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encouraging the patient to find a job which allows her or him to keep a more regular schedule (e.g. a job in a movie theatre that does not begin until noon). In an effort to regulate rhythms, the therapist will also monitor the frequency and intensity of social interactions and identify connections between mood and activity level. If a patient is depressed, the therapist may encourage the patient to participate in more stimulating activities; if hypomanic, the patient will be encouraged to minimize over-simulation. During the course of treatment, the therapist continues to review SRMs. The weekly SRM provides the therapist with the opportunity to review progress towards identified social rhythm goals and address impediments to change. In addition, the SRM is used to help the patient self-monitor for evidence of an exacerbation of the mood disorder. When a patient begins to slip into an episode of mania or depression, changes in sleep and activity levels may be detected on the SRM before the patient is aware of a shift in mood. Thus, the SRM is used both as a measure of therapeutic change and an ancillary mechanism for monitoring symptoms. Clinical vignette 2 Bob is a 52-year-old married man with bipolar disorder who began treatment with IPSRT because of a six-month history of depression that was unreponsive to sequential trials of mood-stablizers plus antidepressants. At one time a successful businessman, several devastating manic episodes had left him bankrupt and estranged from his family. After completing three weeks of SRMs, it became apparent that Bob consistently reversed his days and nights, spent hours on the Internet from midnight to 5 a.m. and slept routinely during the daytime. He was also very isolated, with few social contacts. Bob acknowledged that he felt lonely and disconnected from ‘the rest of the world’. The therapist helped the patient see that his sleep schedule was contributing to his isolation and perhaps his depression. Together they worked out a plan to gradually shift his ‘to bed’ time from 6 a.m. to 2 a.m. over a period of several weeks. Bob agreed to participate in some regular activities during daytime hours such as a daily walk to buy the newspaper at a neighbourhood store and at least one phone call to a friend or relative around the conventional dinner hour. Although the process was slow, the patient noted some improvement in his mood as he began the process of reconnecting with his social network. The social rhythm therapy component of IPSRT helped provide opportunities for social interactions; IPT strategies were then used to help Bob develop new skills to manage these interactions.
Interpersonal psychotherapy IPT is described in published manuals [22,23]. We review the techniques and framework of IPT in this chapter as the structure of IPSRT is derived from that of IPT. The initial phase of IPT (and IPSRT) begins with an in-depth psychiatric evaluation. The therapist conceptualizes the patient’s
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‘problem’ as a medical illness characterized by specific symptoms linked to biological processes, equating bipolar disorder with medical illnesses such as diabetes or heart disease. The therapist educates the patient, making direct statements about diagnosis, heritability of the disorder and treatment options. This approach, in addition to assuring an accurate diagnosis, relieves the patient of the guilt associated with this syndrome. During the initial phase of treatment, the therapist also gives the patient the sick role [24], a role that encourages the patient to actively participate in treatment, helps them accept that symptoms are manifestations of a medical condition and relieves the patient of unmanageable social obligations. The therapist conceptualizes the sick role as a temporary status for the patient, who is expected to work in treatment toward resuming the healthy role. During the initial phase, the therapist conducts the interpersonal inventory, a systematic exploration of the important individuals in the patient’s past and present life. When inquiring about these significant relationships, the therapist explores the quality of the relationships, including the fulfilling and unsatisfying aspects of the relationships. In addition, the therapist investigates seemingly important relationships the patient does not mention. A good understanding of the patient’s interpersonal difficulties will then allow the therapist to see connections between interpersonal events and symptom exacerbation. The centrepiece of IPT is the interpersonal case formulation [25], a summary statement that reiterates the patient’s diagnosis and links it to one (or at most two) interpersonal problem areas. In the formulation, the therapist explicitly links the onset and maintenance of the mood episode to a specific interpersonal problem area. A salient problem area is chosen based on information collected during the psychiatric interview and interpersonal inventory. In IPT, there are four possible interpersonal problem areas: grief, role transition, interpersonal role dispute and interpersonal deficits. In IPSRT, a fifth problem area (grief for the lost healthy self) is added. These IPT problem areas are discussed below, with a specific focus on their relevance in the treatment of bipolar disorder: Grief: The patient and therapist will choose grief or complicated bereavement as the focal problem area when the current affective episode is linked to the death of an important person in the patient’s life. Treatment focuses on facilitation of the mourning process. The therapist reviews in detail the relationship with the deceased person, encourages the expression of previously suppressed affect in order to facilitate catharsis and helps the patient recognize distorted (either overly positive or overly negative) memories of their relationship with the deceased. In IPT, the problem area of grief is selected only when an important person in the patient’s life has died.
Role Transition: A role transition is defined as a change in one’s social role. Examples of a role change include starting a new job, becoming a parent, graduating from college, and so on. Role transitions are also defined as the focus of treatment when one adopts a new role, such as moving from health to sickness, from full-time parent to ‘empty nester’, from living comfortably in one geographical location to having to master a new city with new social connections and demands. Although role transitions are a normal part of the human experience, for individuals who are vulnerable to mood disorders, these changes may provoke an episode. Patients with bipolar disorders are especially vulnerable to change, even in the face of relatively minor perturbations in their environment [26]. IPT strategies for addressing a role transition include helping the patient develop more realistic views of both the old and new roles (patients tend to idealize the old role and devalue the new one) and acquiring new interpersonal skills to master the new role. It is important to keep in mind that bipolar illness itself may bring about role transitions. For instance, mania-driven, inappropriate behaviour may lead to job loss; depression-associated social isolation may lead to failed relationships. Paradoxically, the process of achieving mood stability may represent a role transition for many patients. In particular, many patients miss the pleasurable hypomanic episodes associated with more variable mood states. It is important that the therapist help the patient mourn the loss of these episodes, identify their negative consequences and help the patient find pleasures associated with newfound mood stability. Grief for the Lost Healthy Self: Individuals with bipolar disorder almost always experience the symbolic loss of the person they would have become were they not afflicted with bipolar disorder. In IPSRT, this is referred to as grieving the lost healthy self. Considered a special type of role transition, grieving the lost healthy self involves encouraging patients to talk about limits placed on their life by the illness, lost hopes and missed opportunities. After mourning these losses, the patient is helped to recognize his or her strengths (rather than focusing on the losses) and gently encouraged to set new, realistic goals. Interpersonal Role Dispute: An interpersonal role dispute occurs when nonreciprocal expectations are present in intimate relationships. The goals of treatment include identification of the dispute, alteration of role expectations and communication patterns, and development of a change plan. Therapeutic strategies include role play, investigation of realistic options and communication analysis. Role disputes are common sequelae of bipolar disorder. Irritability associated with both depression and mania can contribute to the erosion of close interpersonal relationships. Similarly, protracted social withdrawal
Interpersonal and Social Rhythm Therapy
associated with bipolar depressions can destroy close relationships. Friends and family members may be perplexed and ultimately vexed by the patient’s wild swings in mood and energy states, leading to misunderstandings and ultimately entrenched role disputes. Interpersonal Deficits: Patients with interpersonal deficits have long histories of unsuccessful relationships. Typically, the therapist is not able to identify a clear interpersonal event associated with episode onset. Thus, this problem area is used as a ‘default’ category, applied only when the three other categories do not capture the patient’s circumstances. Patients with long-standing bipolar disorder, who have destroyed virtually all close relationships, may be best characterized as experiencing interpersonal deficits. This problem area is the least well conceptualized of the four and is associated with poorer outcomes [22]. Although built on the principles of IPT, IPSRT differs from IPT in several respects [27]. First, IPT focuses on the links between life events and mood. In IPSRT, life events are viewed not only as sources of mood dysregulation but also as potential triggers of rhythm disruption. Thus, IPSRT addresses interpersonal problems using both IPT strategies and behavioural strategies designed to regulate the social rhythm disruptions associated with the interpersonal problem. In addition, IPT for unipolar depression is a therapy of interpersonal change. The therapist actively encourages the depressed patient to take interpersonal risks and make relatively large changes in their interpersonal circumstances in a brief period of time. By contrast, patients who suffer from bipolar disorder may destabilize in the face of relatively minor change [26], and are likely to deteriorate in the setting of very stimulating shifts in their interpersonal lives. Therefore, in IPSRT, the therapist helps the patient adapt to change and find a healthy balance between spontaneity and stability. Changes are made gradually, and both therapist and patient remain alert to signs of clinical deterioration in the face of change. Clinical vignette 3 Clara is a 27-year-old single white female physician who graduated from medical school but experienced a psychotic mania during her first year of surgical training. After recovering from the manic episode, she transferred to a less stressful residency in pathology. She was able to complete her pathology residency but became severely depressed as she attempted to find a job post-residency. In therapy, Clara focused initially on the IPSRT-specific strategy of mourning for the lost healthy self. She discussed her early career aspirations, including plans to become a trauma surgeon. She felt defeated by her illness, choosing pathology because ‘I had no other options’. Clara and the therapist also explored the toll that the illness had taken on relationships, leaving Clara feeling incapable of sustaining a relationship or confiding in others about her illness.
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Through the mourning process, Clara came to accept the limitations of her illness, while recognizing that there were still many options open to her. The next part of treatment helped Clara make the transition from a pathology resident to a working physician. The therapist helped Clara explore the importance of finding a career that was intellectually challenging but not too pressured. They also discussed the importance of selecting a job that enabled her to maintain a regular schedule. After exploring several options, Clara decided that she did not wish to pursue an academic career in pathology, but should consider a less timeintensive job in the pharmaceutical industry. Clara’s mood improved as she began to pursue new career options that were compatible with both her illness and her modified career aspirations.
Integrating the components IPSRT is organized into three discrete treatment phases (initial, intermediate and maintenance phases). Within each phase, the components of IPSRT are administered variably, in order to accommodate the specific needs of each patient. The relative emphasis of psychoeducation, social rhythm therapy and IPT strategies will vary according to the phase of treatment and the acuity of the patient’s symptoms. Initial phase The initial phase of IPSRT consists of gathering a psychiatric history, providing psychoeducation about bipolar disorder, carrying out the interpersonal inventory and introducing the patient to the SRM. During this phase, all patients are evaluated by a psychiatrist (if the therapist is not a physician) to optimize pharmacotherapy. Patients may enter IPSRT when they are euthymic, subsyndromal or fully symptomatic. Thus, the duration of the initial phase varies considerably, ranging from two weeks to two months. During this time, the patient is seen weekly by the therapist and as often as needed by the psychiatrist in order to stabilize medications. The first step of the initial phase involves gathering a thorough medical and psychiatric history. In the course of conducting the history, the therapist listens carefully for description of disrupted daily routines or interpersonal relationships that may have preceded current or previous mood episodes. By carefully reviewing these events, the therapist develops an understanding of specific episode triggers and begins to conceptualize possible vulnerabilities in the patient’s interpersonal life. The therapist uses this information to introduce the IPSRT paradigm to the patient, illustrating the connections amongst interpersonal events, social rhythms and episode onset with examples from the patient’s own life. In the initial phase, the therapist also instructs the patient to begin completing the SRM. Therapists explain the form and initiate a discussion around the practicalities of its implementation (‘When would be a good time for you to
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fill in the form each day?’ ‘Where will you keep it so that you don’t lose it?’). If patients have difficulty completing the form, therapists may ask them to start with a simpler task such as filling in time to bed and time out of bed only in order initiate the process of SRM monitoring. SRMs are collected in weekly sessions to define trends in the patient daily rhythms, and patients are encouraged to begin to pay attention to connections between patterns of daily activities and mood. No effort, however, is made in the initial phase to modify these rhythms unless there are clinically pressing concerns such as wildly erratic sleep times. The final component of the initial phase is the interpersonal case formulation. The case formulation links the current mood episode to one (or at most, two) of the five IPT problem areas and sets the interpersonal agenda for the next phase of treatment [25]. If the patient is manic or hypomanic during the initial phase, it may be difficult to complete the interpersonal inventory and establish a case formulation until medications have been initiated and some degree of symptom control has been established. In some instances, therefore, the initial phase of treatment may focus on psychoeducation and containment until the patient is able to engage fully in the therapy enterprise.
Intermediate phase The intermediate phase follows from the interpersonal case formulation and SRM goals. Therapy focuses on resolving the chosen interpersonal problem(s), identifying and meeting intermediate and long-term SRM goals and optimizing pharmacotherapy (in consultation with a psychiatrist). In addition, therapist and patient continue to closely monitor symptoms and side effects, using standardized rating scales such as the 25-item, modified version of the Hamilton Depression Rating Scale [28] and the Bech-Rafaelsen Mania Scale [29] to track shifts in mood states. The intermediate phase typically lasts for several months, and sessions are conducted weekly. During the intermediate phase, SRMs are reviewed weekly, searching for evidence of rhythm dysregularity. The therapist and patient jointly attempt to understand sources of rhythm instability, which may include emergent bipolar symptoms (e.g. later sleep times driven by an evolving hypomania), interpersonal events (e.g. very irregular meal and sleep times stemming from the chaos of caring for three children under the age of 6) or their combination. The therapist helps the patient find ways to regulate their rhythms by setting clear, graduated, SRM goals, and then using the SRMs to track progress over time. An important issue that typically arises during the middle phase of treatment is the balance between stability and spontaneity. Many patients suffering from bipolar disorder are accustomed to hectic variations in mood and energy states. The prodigious efforts of the therapist to curb the
variablity in their mood and activities are not always welcomed by the patient. In fact, many patients believe they will find regularity boring and unappealing. If sensitive to this issue, the therapist can help the patient determine how much stability is required to lessen the risk of recurrence, while encouraging the patient to seek some degree of ‘safe’ spontaneity in other areas of his or her life. For instance, if a patient’s work schedule has variable demands (e.g. big projects followed by lulls in activity), the therapist may encourage the patient to avoid rhythm-disrupting projects during the spring and summer when the patient is historically at risk for manic episodes, instead shifting them to the fall and winter months when the patient is more likely to tolerate less structured social rhythms. Alternately, using IPT strategies such as grieving for the lost healthy self or managing the role transition from variable mood states to euthymia, the therapist can help the patient understand and mourn the lost highs while learning to value greater stability in mood and, ultimately, functioning. During the intermediate phase of therapy, as in life, patients invariably experience changes in life circumstances that lead to changes in routine. For instance, patients may begin new jobs, start new relationships, move to a new apartment or resume classes. The therapist helps the patient work through these changes in a manner that minimizes disruptions to daily rhythms. For instance, the therapist may encourage a patient in a new relationship to speak with their new partner about the importance of routines, helping the patient establish new patterns that do not deviate substantially from old ones. Patients starting new jobs are encouraged to shift their schedules gradually in order to minimize abrupt changes in daily habits and degree of activity. IPSRT uses social rhythm therapy techniques to protect rhythm integrity and IPT techniques to explore and manage the interpersonal consequences of these events. During the intermediate phase of IPSRT, the therapist uses the IPT strategies, such as communication analysis, role play and decision analysis to resolve the interpersonal problem identified in the case formulation. These IPT strategies are described in the IPT manual [22]. In addition to helping the patient see connections between the problem area and mood, the therapist explores the impact of the interpersonal problem area on social rhythm stability and medication adherence. For instance, if the selected problem area is a role dispute with a spouse, the therapist will ask the patient about the marital conflict over the past week. If the patient reveals that his wife now insists that he drop the children off at school early in the mornings (this had previously been the wife’s responsibility), the therapist will explore both the impact of the new schedule on the patient’s daily rhythms (Will he have to get up earlier? Should he go to bed earlier? Will this interfere with his morning dose of lithium?), as well as the interpersonal meaning of the event (How does the patient feel about the new arrangements?
Interpersonal and Social Rhythm Therapy
How did the couple make this decision?). The relative emphasis and sequencing of the techniques are determined by the clinical judgment of the therapist.
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contributed substantially to her symptoms. Thus, the therapist moved rapidly to help Doreen enlist assistance from her extended family. Doreen’s mother and several sisters each agreed to stay with Doreen one night per week in order to provide her with some relief
Maintenance phase The maintenance phase is designed to consolidate treatment gains, optimize interpersonal functioning in the absence of syndromal illness and prevent recurrence. Treatment frequency is tapered to bi-weekly for two months and then monthly. This phase of treatment has been studied for two years in research protocols [30], although in clinical practice, some patients may stay in maintenance psychotherapy indefinitely. Crisis intervention is provided on an as-needed basis in this phase of treatment. Because bipolar disorder is a chronic illness, some might argue that combination treatment (i.e. medication plus psychotherapy) is indicated indefinitely. In other cases, a patient may demonstrate appreciable improvement in multiple domains and may feel comfortable transitioning to maintenance medication without psychotherapy. In the absence of data to guide this choice, the decision to end maintenance treatment is necessarily an individual decision. When maintenance psychotherapy ends, we recommend a very gradual process of termination, over four to six-monthly sessions. The termination stage should be a period of treatment reflection and encouragement. The therapist reviews the patient’s progress and identifies areas in which additional improvement is needed. The therapist underscores the fact that the patient has acquired both new interpersonal skills and a new understanding of the importance of maintaining regular social rhythms, reinforcing the importance of practising these skills in order to perpetuate therapeutic gains. In this final phase, it is also important to identify additional resources for the patient in the event that symptoms worsen. Virtually all patients with bipolar I disorder will continue maintenance medication indefinitely and should be referred to a psychiatrist for follow-up.
from nighttime feedings as well as assistance with other household responsibilities. Doreen restarted lithium and olanzapine and immediately began to feel better. As Doreen’s mood began to stabilize, it became clear that the interpersonal problem area most salient to Doreen’s current mood episode was a role dispute with Roger, her boyfriend of 2 years. Roger, the father of Doreen’s two youngest children, was unemployed and had a history of drug use. He denied current drug use, but Doreen said, ‘I’m not so sure’. Roger was very suspicious of doctors and medications, routinely disparaging Doreen’s efforts to enter treatment and actively discouraging her from taking medications. In fact, he routinely took her medications from the cabinet, perhaps selling them on the street claiming, ‘you don’t need these’. He did not contribute financially to the household, and instead often demanded money from Doreen. The intermediate phase of treatment focused on helping Doreen set some limits with Roger. She had no wish to end the relationship; however, she admitted that she had trouble getting her needs met in the relationship. Therefore, her therapist began to help Doreen identify and articulate what she wanted from Roger. The therapist suggested that they first work on the conflict over Doreen seeking treatment for bipolar disorder. Doreen asked for some educational materials to give Roger in the hope that he would eventually ‘come around’, but also decided to hide her medications in a new, secure location so that he would be unable to take them from her. Because Roger often showed up unannounced in the middle of the night, contributing to Doreen’s erratic social rhythms, they also worked towards helping Roger understand that he was only welcome to ‘show up’ if it was before 10 p.m. Initially, Roger was enraged by these limits and disappeared for 2 weeks. When he returned, however, he was conciliatory, and Doreen felt empowered by her capacity to ‘stand firm’ with him. She then decided that she would refuse to give any more money to Roger unless he did some things around the house to help her out (fix a broken door, etc.), which helped her feel more competent in the management of both her household and her relationship.
Clinical vignette 4 Doreen is a 34 year old, single female, mother of four, with a history of two prior hospitalizations for suicide attempts during mixed states. Doreen entered IPSRT during a mixed state episode following the birth of her fourth child. She had stopped her moodstabilizers during the pregnancy and had not yet resumed them, despite instructions from her psychiatrist to restart them immedi-
Doreen’s mood stabilized after four months of treatment, and she graduated to the maintenance phase, which focused on helping her tolerate medication side effects, develop more effective ways to manage her hectic schedule at home and manage disputes with Roger. Given her multiple psychosocial problems and history of stopping medications precipitously, the therapist felt it important that Doreen continue psychotherapy indefinitely.
ately after delivery (Doreen did not plan to breastfeed). The initial phase of treatment emphasized psychoeducation, including the importance of following the psychiatrist’s recommendations in order to prevent another hospitalization (the patient was not currently suicidal). It was immediately apparent that Doreen’s erratic sleep schedule, driven by the needs of her newborn infant,
IPSRT for adolescents Adolescents with bipolar disorder show impaired school, family and social functioning and seem to be more impaired than adolescents with other psychiatric disorders [31].
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Unfortunately, there has been little research on therapies for adolescents with bipolar disorder. Since adolescence is characterized by major biological, psychological and social role changes along with frequently dysregulated sleep and social routines, all of which are especially harmful for adolescents with bipolar disorder and are addressed in IPSRT, an adaptation of the treatment for adolescents is an especially promising intervention [32]. IPSRT-A is currently being developed and tested at the University of Washington. The adaptations to IPSRT include increased parent involvement (especially during the education phase of treatment), interpersonal interventions specific to adolescents and based on IPT-A (e.g. an emphasis on interpersonal disputes with parents), changes to the SRM in order to make it more salient to an adolescent population (shorter and including school and homework categories) and a greater emphasis on psychoeducation [32].
Research findings Several recent studies have examined the efficacy of IPSRT. The first study, Maintenance Therapies in Bipolar Disorder (MTBD) compared IPSRT to an intensive clinical management (ICM) approach in patients with bipolar I disorder. Another trial, the Systematic Treatment Enhancement Program for Bipolar Disorder (STEP-BD), compared several intensive psychotherapies (including IPSRT) to a clinical management approach amongst patients with bipolar disorder who were currently depressed. A third, smaller, study examined the feasibility of using IPSRT as a monotherapy for bipolar II depression. The MTBD study, conducted at the University of Pittsburgh, was the first test of IPSRT as a treatment for bipolar disorder [30]. In MTBD, acutely ill patients meeting criteria
for bipolar I disorder (N ¼ 175) were treated with medication and randomly assigned to either IPSRT or ICM. In order to enter the protocol, subjects were required to meet the Schedule for Affective Disorders and Schizophrenia criteria [33] or the Research Diagnostic Criteria [34] for bipolar I with a score of 15 or greater on the 24-item Hamilton Scale for Depression [28,35] or the Bech-Rafaelson Mania Scale [29]. Exclusion criteria included pregnancy, chronic alcohol and drug abuse, rapid cycling (defined as 4 or more affective episodes in 1 year), or an unstable comorbid medical condition. In addition, individuals meeting criteria for antisocial and borderline personality disorder or schizophrenia were excluded from the study. Once stabilized (defined as four weeks of symptom scores averaging 7 on the 24-item version of the Hamilton Depression Rating Scale (HRSD) and 7 on the Bech-Rafaelsen Mania Scale while on a stable medication regimen), patients were reassigned to either IPSRT or ICM (in conjunction with the medication regimen that led to stabilization) for 2 years of monthly maintenance treatment. The maintenance phase of treatment consisted of three months of bi-weekly sessions followed by 21 months of monthly session. Thus, four treatment sequences were included in the study: IPSRT followed by IPSRT (n ¼ 22); IPSRT followed by ICM (n ¼ 27); ICM followed by ICM (n ¼ 19) and ICM followed by IPSRT (n ¼ 25). See Figure 1 for a schematic depiction of the MTBD study design. Although used as a comparison condition in MTBD, ICM is an important psychotherapeutic intervention in it its own right. It should not be mistaken for an inactive control. Influenced by the medical model of clinical management, ICM focuses on fostering support, promoting treatment adherence, assessing symptoms and providing psychoeducation. Thus, ICM incorporates many general psychotherapeutic strategies that contribute to the successful management of bipolar
Maintenance Therapies in Bipolar Disorder Study Design RANDOM ASSIGNMENT TO ACUTE PHASE
Intensive Clinical Management visits and protocol pharmacotherapy
RANDOM ASSIGNMENT TO MAINTENANCE
IPSRT and protocol pharmacotherapy
• Acute treatment weekly until HRSD & BechRafaelsen average <7 over four weeks
• Patient and
family attend psychoeducational workshop
Intensive Clinical Management visits and protocol pharmacotherapy
IPSRT and protocol pharmacotherapy
RANDOM ASSIGNMENT TO MAINTENANCE
Intensive Clinical Management visits and protocol pharmacotherapy
IPSRT and protocol pharmacotherapy
Maintenance treatment bi-weekly (x twelve weeks) followed by monthly (x two years) visits. Frequency of visits increased temporarily if patient experiences new episode.
Fig. 1 Maintenance therapies in bipolar disorder: study design.
Interpersonal and Social Rhythm Therapy Table 2 Intensive clinical management. Elements of Intensive Clinical Management (ICM) 1. 2. 3. 4. 5. 6. 7.
Education about Bipolar Disorder Education about medications used to treat Bipolar Disorder Education about basic sleep hygiene Careful review of side effects Medical and behaviour management of side effects Non-specific support Education regarding early warning signs of impending episodes and use of rescue medication 8. 24-h on call service
illness. See Table 2 for a summary of ICM techniques. In contrast to IPSRT, therapists providing ICM were proscribed from discussing interpersonal stressors and social rhythm stability. In MTBD, all therapists were trained to reliably administer both IPSRT and ICM. In MTBD, all patients received pharmacotherapy according to a specified algorithm (available from the authors). Unless contraindicated, pharmacotherapy began with lithium. Neuroleptics, additional mood stabilizers, benzodiazepines and antidepressants were added in step-wise fashion, guided by weekly symptom scores. Once stable, attempts were made to withdraw all medications except for the primary mood-stabilizer (or combination of mood stabilizers, in some cases). If patients could not tolerate a reduction of medications (i.e. of an antidepressant or antipsychotic), they were permitted to remain on the combination that kept them well. Once reassigned to the maintenance phase of the study, medication was not changed unless a recurrence was declared (except for five days of ‘rescue’ medications, such as lorazepam administered under specified conditions for subsyndromal hypomanic symptoms). The first published report from the MTBD protocol examined the relative impact of ICM and IPSRT on stability of daily routines [36]. This analysis included 38 subjects (18 receiving IPSRT and 20 receiving ICM) followed in the acute phase of treatment for up to 52 weeks. As measured by an expanded version of the SRM [37], a random regression analysis illustrated that individuals who received IPSRT achieved greater stability in their social rhythms when compared to ICM treatment over a similar time period (chi square ¼ 3.96; p ¼ 0.047). The two groups did not differ on levels of symptomatology over 52 weeks (measured by the HRSD and the Bech-Rafaelson; chi square ¼ 0.12; p ¼ 0.73). These analyses demonstrate that IPSRT effectively enhances stability of daily routines. We have also reported on the effects of episode polarity on time to stabilization in the acute phase of the study [38,39]. We first reported on differential time to stabilization amongst subjects treated for depression
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(n ¼ 22), mania (n ¼ 8) or a mixed state (n ¼ 12) during the acute phase of the study [39], finding significant differences amongst groups (chi square ¼ 14.80, p ¼ 0.0006). Subsequent analyses of a larger sample (n ¼ 151) demonstrated longer median times to stabilization in depressed and mixed/cycling subjects: 11.0 weeks for subjects treated for mania, 24.0 weeks for subjects treated for depression and 40.3 weeks for subjects treated for mixed/cycling episodes. Between-group comparisons of survival analyses (time to stabilization) were significantly different (for all, p < 0.05). In the earlier report, although no specific treatment effects were found, amongst depressed subjects, those who received IPSRT had a median time to remission of 22 weeks, versus 40 weeks in subjects assigned to ICM. Although not statistically significant, this finding suggests that IPSRT may selectively hasten recovery from a depressive episode. We also reported the two-year outcomes of the acute and maintenance phases of the MTBD trial [30]. After controlling for age, sex, marital status, index episode polarity, medical burden, history of anxiety disorder, history of alcohol or substance abuse, and baseline HRSD and BechRafaelson Mania scores, we found that participants assigned to IPSRT in the acute treatment phase survived significantly longer without a new affective episode during the 2-year maintenance phase (p ¼ 0.01; hazard ratio (HR) ¼ 0.35), irrespective of maintenance treatment assignment. Participants in IPSRT also had significantly higher regularity of daily routines at the end of acute treatment (p < 0.001). Furthermore, ability to increase regularity of daily routines during acute treatment was significantly related to reduced likelihood of recurrence during the maintenance phase (p ¼ 0.05), demonstrating that social rhythm stabilization mediated positive outcomes [30]. The results of this study suggest that IPSRT may be most effective if it is initiated immediately following an acute episode of illness. Perhaps an acute episode motivates patients to be more open to making the difficult lifestyle changes necessary to achieve social rhythm stability. Interestingly, IPSRT did not benefit all participants who received it during the acute phase. Specifically, participants with a greater number of medical problems who received acute IPSRT recurred more quickly than participants with fewer medical problems in the same condition (p ¼ 0.006, HR ¼ 1.39). Participants who had poor medical health actually had better outcomes when assigned to the ICM group during the acute phase. The explanation for these effects may be found in the content of IPSRT and ICM. In ICM, therapists focused on the patient’s somatic complaints. For patients with a greater medical burden, this may have led to better medical management and a greater focus on problem solving and coping with their multiple illnesses. On the other hand, patients with multiple medical problems in the IPSRT condition would not have discussed somatic
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concerns and instead focused on social rhythm stability and improving interpersonal relationships. An analysis of occupational functioning found that participants assigned to IPSRT in the acute phase demonstrated significantly more rapid improvement in occupational functioning than did participants assigned to ICM (Cohen’s d ¼ 0.68; p ¼ 0.001) [40]. The treatment’s effects on occupational functioning were independent of effects on time to recurrence, since occupational functioning explained only a small part of the variance in time to recurrence (R2 ¼ 0.056). We also observed a gender effect, with women assigned to IPSRT showing more rapid improvement in occupational functioning during the acute treatment phase when compared with men in the same condition (F ¼ 3.06, df ¼ 3, 104, p ¼ 0.032). The STEP-BD was a multicentre study of the course and outcome of bipolar disorder [41]. Across 13 sites, 293 depressed participants with either bipolar I or II disorder who agreed to a psychosocial intervention were randomly assigned to one of three intensive psychotherapies consisting of up to 30 50-minute sessions over 9 months (IPSRT [N ¼ 62], Family Focused Therapy [FFT; N ¼ 26] or Cognitive Behavioural Therapy [CBT; N ¼ 75]) or to a control condition, Comprehensive Care (CC; N ¼ 130), which consisted of three 50-minute sessions of psychoeducation. All psychosocial treatments were administered in combination with standardized medication algorithms. Participants were followed for 1 year and classified as to whether they had 8 consecutive weeks of recovery of both depressive and manic symptoms. All analyses were by intent-to-treat. Rates of study attrition did not differ across the intensive psychotherapy (36%) and CC conditions (31%). Thirty-one percent of this sample (90/293) met criteria for bipolar II disorder. All participants received combination treatment (i.e. medication plus psychotherapy or CC). Patients receiving intensive psychotherapy had significantly higher year-end recovery rates (64 vs. 52%) and shorter times to recovery than patients in CC HR ¼ 1.47; 95% CI ¼ 1.08–2.00; p ¼ 0.013). Patients in intensive psychotherapy were 1.58 times (SE ¼ 0.15) more likely to be clinically well during any study month than those in CC (p ¼ 0.002). In analyses of the effects of type of intensive treatment on time to recovery, a main effect of treatment group was found (log-rank x2(3) ¼ 8.02, p ¼ 0.046). Within the 1year time frame, 65% (40/62) of the IPSRT patients recovered (HR ¼ 1.48) in comparison to 51.5% (67/130) of the CC patients. Considering only those who recovered, median time to recovery was 127.5 76.8 days for IPSRT and 146 80.0 days for CC [42]. Patients receiving intensive psychotherapy also had better total functioning, relationship functioning and life satisfaction scores over 9 months compared to those assigned to CC, even after covarying for pretreatment functioning and concurrent depression scores [43].
IPSRT as monotherapy We conducted a proof of concept study designed to evaluate the feasibility of using IPSRT as a monotherapy for depression in patients with bipolar II disorder. At study entry, all participants met DSM-IV criteria for BP II disorder, currently depressed, with HRSD scores 15 and Young Mania Rating Scale (YMRS) scores 10. Participants were not included if they were currently receiving treatment with psychoactive medications, had active substance abuse problems, or had a diagnosis of borderline or antisocial personality disorder. 17 participants enrolled in the trial. Participants received weekly 45-minute sessions of IPSRT psychotherapy for 12 weeks. Participants also received eight additional weeks of follow-up IPSRT sessions, and non-responders received supplementary lamotrigine. Fifty-nine percent of participants (10/17) completed the study. One participant was enrolled in the study but did not attend any therapy sessions, another participant was hospitalized early in the study for acute suicidal ideation and five participants dropped out after having had at least one study visit. By visit 12, 41% (n ¼ 7) had responded to IPSRT (defined as at least a 50% reduction in depression scores and YMRS scores remaining 10). Participants showed significant improvements over time in both depression (HRSD25 scores decreased; F(1,15) ¼ 13.27, p ¼ 0.002) and overall illness severity (CGI scores decreased; F(1,14) ¼ 4.87, p ¼ 0.045) [44]. The study demonstrated the feasibility of treating depression in patients with bipolar II with IPSRT alone. Because of the small sample size, the authors were unable to find statistically significant differences between responders and nonresponders, but the overall response rate suggests that IPSRT alone can lead to substantial clinical gains in at least a subset of patients with bipolar II disorder.
Conclusion The current research suggests that IPSRT successfully promotes rhythm stability, and when used as an acute treatment leads to decreased likelihood of affective episode recurrence, increased occupational functioning, and quality of life when compared to clinical management interventions. Research also suggests that IPSRT may work well as a monotherapy for a subset of patients with bipolar II depression. Certain subsets of patients with bipolar disorder seem to benefit more from IPSRT, including patients with few medical problems, patients being treated in the acute phase of their illness and female patients. For bipolar disorder, the adage, ‘one size doesn’t fit all’ seems particularly apt. Further research is needed to sort out when IPSRT contributes significantly to improvements in symptoms and functioning, and when adjunctive clinical management will suffice.
Interpersonal and Social Rhythm Therapy
Our quest to find better treatments for patients suffering from bipolar disorder led to the development and testing of IPSRT. It provides yet another option for the treatment of bipolar disorder, helping some patients to achieve a fuller and more stable recovery than would have been possible with medications alone.
16.
17.
Acknowledgement
18.
Supported by the National Institute of Mental Health, Grants MH-29618, MH-30915 and MH-64518.
19.
References 1. Goodwin, F. and Jamison, K. (1990) Manic-Depressive Illness, Oxford University Press, New York. 2. Gitlin, M.J., Swendsen, J., Heller, T.L. and Hammen, C. (1995) Relapse and impairment in bipolar disorder. Am. J. Psychiatry, 152 (11), 1635–1640. 3. Coryell, W., Scheftner, W., Keller, M., Endicott, J. et al. (1993) The enduring psychosocial consequences of mania and depression. Am. J. Psychiatry, 150 (5), 720–727. 4. Miklowitz, D.J. (2008) Adjunctive psychotherapy for bipolar disorder: state of the evidence. Am. J. Psychiatry, 165 (11), 1408–1419. 5. American Psychiatric Association (2002) Practice guidline for the treatment of patients with bipolar disorder (Revision). Am. J. Psychiatry, 159 (suppl.), 1–50. 6. Frank, E. (2005) Treating Bipolar Disorder: A Clinician’s Guide to Interpersonal and Social Rhythm Therapy, Guilford Press, New York, NY. 7. Gelenberg, A.J., Kane, J.M., Keller, M.B. et al. (1989) Comparison of standard and low serum levels of lithium for maintenance treatment of bipolar disorder. N. Engl. J. Med., 321 (22), 1489–1493. 8. Markar, H. and Mander, A. (1989) Efficacy of lithium prophylaxis in clinical practice. Brit. J. Psychiat., 155, 496–500. 9. Goldberg, J.F., Harrow, M. and Grossman, L.S. (1995) Course and outcome in bipolar affective disorder: A longitudinal follow-up study. Am. J. Psychiatry, 152 (3), 379–384. 10. Klerman, G.L., Weissman, M.M., Rounsaville, B.J. and Chevron, E.S. (1984) Interpersonal Psychotherapy of Depression, New York, Basic Books. 11. Ehlers, C.L., Frank, E. and Kupfer, D.J. (1988) Social zeitgebers and biological rhythms. Arch. Gen. Psychiatry, 45 (10), 948–952. 12. Ehlers, C.L., Kupfer, D.J., Frank, E. and Monk, T.H. (1993) Biological rhythms and depression: The role of zeitgebers and zeitstorers. Depression, 1, 285–293. 13. Benedetti, F., Serretti, A., Colombo, C. et al. (2003) Influence of CLOCK gene polymorphism on circadian mood fluctuation and illness recurrence in bipolar depression. Am. J. Med. Genet. Part B, 123B (1), 23–26. 14. McClung, C.A. (2007) Circadian genes, rhythms and the biology of mood disorders. Pharmacol. Ther., 114 (2), 222–232. 15. Leibenluft, E., Albert, P.S., Rosenthal, N.E. and Wehr, T.A. (1996) Relationship between sleep and mood in patients with
20.
21.
22.
23.
24. 25.
26.
27.
28.
29.
30.
31.
|
441
rapid-cycling bipolar disorder. Psychiatry Res., 63 (2–3), 161–168. Wehr, T.A., Sack, D.A. and Rosenthal, N.E. (1987) Sleep reduction as a final common pathway in the genesis of mania. Am. J. Psychiatry, 144 (2), 201–204. Barbini, B., Colombo, C., Benedetti, F. et al. (1998) The unipolar-bipolar dichotomy and the response to sleep deprivation. Psychiatry Res., 79 (1), 43–50. Leibenluft, E., Moul, D.E., Schwartz, P.J. et al. (1993) A clinical trial of sleep deprivation in combination with antidepressant medication. Psychiatry Res., 46 (3), 213–227. Leibenluft, E. and Suppes, T. (1999) Treating bipolar illness: Focus on treatment algorithms and management of the sleepwake cycle. Am. J. Psychiatry, 156 (12), 1976–1979. Benedetti, F., Barbini, B., Fulgosi, M.C. et al. (2005) Combined total sleep deprivation and light therapy in the treatment of drug-resistant bipolar depression: acute response and long-term remission rates. J. Clin. Psychiat., 66 (12), 1535–1540. Ashman, S.B., Monk, T.H., Kupfer, D.J. et al. (1999) Relationship between social rhythms and mood in patients with rapid cycling bipolar disorder. Psychiatry Res., 86 (1), 1–8. Weissman, M.M., Markowitz, J.C. and Klerman, G.L. (2000) Comprehensive Guide to Interpersonal Psychotherapy, Basic Books, New York, NY. Weissman, M.M., Markowitz, J.C. and Klerman, G.L. (2007) Clinician’s Quick Guide to Interpersonal Psychotherapy, Oxford University Press, New York. Parsons, T. (1951) Illness and the role of the physician: a sociological perspective. Am. J. Orthopsychiat., 21, 452–460. Markowitz, J.C. and Swartz, H.A. (2007) Case formulation in interpersonal psychotherapy of depression, in Handbook of Psychotherapy Case Formulation, 2nd edn (ed. T.E. Eels), Gulford Press, New York. Frank, E., Swartz, H.A., Mallinger, A.G. et al. (1999) Adjunctive psychotherapy for bipolar disorder: effects of changing treatment modality. J. Abnorm. Psychol., 108 (4), 579–587. Swartz, H.A., Markowitz, J.C. and Frank, E. (2002) Interpersonal psychotherapy for unipolar and bipolar disorders, in Treating Chronic and Severe Mental Disorders: A Handbook of Empirically Supported Interventions (ed. S.G. Hofmann and M. Tompson), Guilford Press, New York, pp. 131–158. Thase, M.E., Carpenter, L., Kupfer, D.J. and Frank, E.F. (1991) Clinical significance of reversed vegetative subtypes of recurrent major depression. Psychopharmacol. Bull., 27 (1), 17–22. Bech, P., Bolwig, T.G., Kramp, P. and Rafaelsen, O.J. (1979) The Bech-Rafaelsen Mania Scale and the Hamilton Depression Scale: Evaluation of homogeneity and inter-observer reliability. Acta Psychiatr. Scand., 59 (4), 420–430. Frank, E., Kupfer, D.J., Thase, M.E. et al. (2005) Two-year outcomes for interpersonal and social rhythm therapy in individuals with bipolar I disorder. Arch. Gen. Psychiatry, 62 (9), 996–1004. Lewinsohn, P.M., Klein, D.N. and Seeley, J.R. (1995) Bipolar disorders in a community sample of older adolescents:
442
32.
33.
34.
35. 36.
37.
38.
|
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prevalence, phenomenology, comorbidity, and course. J. Am. Acad. Child Psy., 34 (4), 454–463. Hlastala, S.A. and Frank, E. (2006) Adapting interpersonal and social rhythm therapy to the developmental needs of adolescents with bipolar disorder. Dev. Psychopathol., 18 (4), 1267–1288. Spitzer, R.L. and Endicott, J. (1978) Use of the Research Diagnostic Criteria and the Schedule for Affective Disorders and Schizophrenia to study affective disorders. Arch. Gen. Psychiatry, 35 (7), 837–844. Endicott, J., Spitzer, R.L. and Winokur, G. (1977) Research diagnostic criteria: rationale and reliability. Arch. Gen. Psychiatry, 34 (10), 1229–1235. Hamilton, M. (1960) A rating scale for depression. J. Neurol. Neurosurg. Psychiatry, 25, 56–62. Frank, E., Hlastala, S., Ritenour, A., Houck, P. et al. (1997) Inducing lifestyle regularity in recovering bipolar disorder patients: Results from the maintenance therapies in bipolar disorder protocol. Biol. Psychiatry, 41 (12), 1165–1173. Monk, T.H., Kupfer, D.J., Frank, E. and Ritenour, A.M. (1991) The Social Rhythm Metric (SRM): Measuring daily social rhythms over 12 weeks. Psychiatry Res., 36 (2), 195–207. Kupfer, D.J., Frank, E., Grochocinski, V.J. et al. (2000) Stabilization in the treatment of mania, depression, and mixed states. Acta Neuropsychiatr., 12 (3), 110–114.
39. Hlastala, S.A., Frank, E., Mallinger, A.G. et al. (1997) Bipolar depression: An underestimated treatment challenge. Depress Anx., 5, 73–83. 40. Frank, E., Soreca, I., Swartz, H.A. et al. (2008) The role of interpersonal and social rhythm therapy in improving occupational functioning in patients with bipolar I disorder. Am. J. Psychiatry, 165 (12), 1559–1565. 41. Sachs, G.S., Thase, M.E., Otto, M.W. et al. (2003) Rationale, design, and methods of the Systematic Treatment Enhancement Program for bipolar disorder. Biol. Psychiatry, 53 (11), 1028–1042. 42. Miklowitz, D.J., Otto, M.W., Frank, E. et al. (2007) Psychosocial treatments for bipolar depression: A 1-Year randomized trial from the Systematic Treatment Enhancement Program. Arch. Gen. Psychiatry, 64, 419–427. 43. Miklowitz, D.J., Otto, M.W., Frank, E. et al. (2007) Intensive psychosocial intervention enhances functioning in patients with bipolar depression: results from a 9-month randomized controlled trial. Am. J. Psychiatry, 164 (9), 1340–1347. 44. Swartz, H.A., Frank, E., Frankel, D.R. et al. (2009) Psychotherapy as monotherapy for the treatment of bipolar II depression: A proof of concept study. Bipolar Disord., 11, 89–94.
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Family Therapy Approaches to Bipolar Disorder David J. Miklowitz Division of Child and Adolescent Psychiatry, UCLA Semel Institute for Neuroscience and Human Behavior, UCLA School of Medicine, Los Angeles, CA, USA
Introduction Increasingly, family-oriented psychoeducational interventions are being used as adjuncts to somatic therapies in the treatment of major psychiatric and medical conditions [1,2]. Substantial progress has been made in the application of family psychoeducation to bipolar disorder (BD). The purpose of this chapter is to review the current state of knowledge regarding family and marital interventions for BD, with an emphasis on randomized clinical trials. The clinical issues addressed in family treatment are discussed, and a brief case study is offered. The application of family-based treatments to special subpopulations of patients – notably patients with comorbid substance abuse or youth at risk for BD – is described. Finally, views on future research directions are offered.
Theoretical background Early approaches Family approaches to BD can be traced back to at least 1954 [3]. Early approaches viewed BD as a disorder of object relations. Cohen et al. [3] described families of manicdepressive patients as being set apart from their surrounding social milieu by socioeconomic circumstances or psychiatric disorders in the family; as being unusually sensitive to conformity pressures; and leaning on the child who later developed the illness to raise the family’s social prestige through achievement. Relationships within the family were described as conflictual, disrespectful, rigid and emotionally inaccessible. Mayo and colleagues [4,5] described manic-depressive families as maintaining rigid interpersonal boundaries within the family and fluid boundaries with respect to the outside world. These theories gained little traction, in part because they did not distinguish family dynamics that accompanied episodes of the disorder (and occurred in reaction to existing symptoms) from those that preceded the disorder’s onset. Bipolar Disorder: Clinical and Neurobiological Foundations Edited by Lakshmi N. Yatham and Mario Maj © 2010 John Wiley & Sons, Ltd. ISBN: 978-0-470-72198-8
A separate literature examined the health or dysfunction of bipolar marriages. Several early studies observed high rates of divorce and separation [6,7] and that, when marriages did not fail, the healthy spouse often stayed only out of a sense of duty. Targum et al. [8] found that 53% of well spouses (vs. 5% of patient partners) claimed they would not have originally married had they known more about manicdepressive disorder before marrying. Davenport et al. [9] described manic-depressive couples as being enmeshed and highly interdependent, but also as keeping emotional expression to a minimum as a way of protecting against recurrences of the patient’s disorder. In contrast, other studies found that marriages of manic-depressive patients were no different from normal marriages when the patient was asymptomatic [10,11]. Although few definitive conclusions can be drawn from these early studies, they did point to the importance of considering the family or marital context when understanding the symptomatic fluctuations and functional consequences of BD. Even as early as 1972, some prescient observers noted that the goals of lithium therapy could be furthered by including the family or partner in treatment [12]. If nothing else, BD creates havoc and emotional pain for family members, to the point where they develop health and mood problems themselves [13]. The compromised emotional state of some caregivers can have a negative influence on the patient’s course of illness. On the flip side, a spouse or parent who develops an understanding of the nature, course, triggers and treatment of the disorder may help create a milieu which helps protect the patient against recurrences.
Expressed emotion research The more recent progress of family approaches to bipolar disorder has been influenced by the research on expressed emotion (EE), a construct well-studied in schizophrenia and major depressive disorder [14]. EE refers to the expression of critical attitudes, hostility or emotional overinvolvement (overprotectiveness, inordinate self-sacrifice) amongst the caregivers of patients with major psychiatric disorders [15]. Families are classified as high-EE if one or more 443
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caregivers expresses six or more critical comments or shows high levels of hostility or over-involvement when discussing the history of the patient’s disorder with a clinical interviewer. The significance of EE is a prognostic one: patients who have been recently ill and who recover in high-EE households are at two to three times greater risk of relapse in the next year than patients who recover in low-EE (less critical or overprotective) households. Several studies of EE have been conducted in BD, and all indicate that patients in families with high EE attitudes have higher rates of relapse and more severe mood symptoms over nine month to two year periods than patients in families with low-EE attitudes [16–21]. Some, but not all studies have found a stronger impact of caregiver EE on patients’ depressive outcomes than on manic outcomes [17,22]. One study found an effect of EE on the course of childhood-onset BD [21]. The mediational pathways that link caregiver EE with patient relapses is a matter of some debate. Some studies indicate that high-EE caregivers are more likely to attribute the negative behaviours of patients to internal, controllable and personal factors, whereas low-EE caregivers attribute negative patient behaviours to external, uncontrollable or universal factors [23,24]. Families with high-EE are often locked into negatively escalating cycles of communication, in which criticism and counter-criticism amongst family members becomes highly reciprocally dependent [25,26]. There are probably differences between patients in high and low EE families in neural activation patterns as well. College students with histories of depression are less able to recruit the dorsolateral prefrontal cortex when hearing audiotaped criticisms from their parents, compared with college students with no depression history [27]. There are multiple pathways to high-EE caregiver attitudes, and different pathways linking these attitudes with patient relapses. The simplest pathway – a reactive model, in which patients in high-EE families are simply more symptomatic to begin with than patients in low-EE families – does not appear to be consistent with the data [23]. Differences in patients’ symptoms are observed longitudinally, rather than cross-sectionally. Relatives’ EE attitudes may occur in reaction to patients’ subsyndromal symptoms, but EE attitudes have their own prognostic utility independent of patients’ clinical states [28]. For bipolar disorder, the implications of EE research are several-fold: (1) modifying the emotionally-charged environment of the family or marital relationship during a postmanic or post-depressive recovery period may hasten the patient’s recovery and delay recurrence; (2) caregivers may benefit from psychoeducation orientated towards distinguishing what behaviours are controllable (e.g. wilful oppositionality) and not controllable (i.e. illness-driven) by the patient; and (3) families of BD patients often need assistance in communicating and solving problems effectively
during the post-episode period. These implications are addressed in one model of integrated treatment for BD: family-focused treatment (FFT).
Family-focused treatment FFT was developed in our laboratories at the University of California, Los Angeles (1983–1988; [29] and later at the University of Colorado, Boulder (1988-present; [30]. FFT has been conducted with parent/offspring pairs, spousal pairings, siblings, grandparent/grandchild pairings and adult children of parents with BD. It is usually initiated once the patient begins recovering from an acute episode of bipolar disorder. Derived from the behavioural family treatment of schizophrenia [31], FFT consists of three stages: psychoeducation about the nature, aetiology, treatment and selfmanagement of BD; communication enhancement training, in which patients and caregivers rehearse effective speaking and listening skills (e.g. how to give praise and constructive criticism, how to listen actively); and problem-solving skills training, in which patients and caregivers define problems, generate and evaluate solutions and implement solutions to specific conflicts in the family. The treatment is given in 21 sessions (12 weekly, 6 biweekly, 3 monthly) over nine months, and is often supplemented with booster sessions after formal treatment ends. FFT is considered adjunctive to pharmacotherapy, not a substitute for it. Its objectives are listed in Table 1 below.
Psychoeducation Psychoeducation, conducted in the first 7–10 sessions of FFT, gives patients and their caregivers (typically parents, spouses or siblings) concrete, didactic information about the symptoms, differential diagnosis, comorbidity, course, treatment and self-management of BD. Handouts and
Table 1 Objectives of Family-Focused Treatment (FFT). Assist the patient and relatives in: . Integrating the experiences associated with mood episodes in bipolar disorder . Accepting the notion of a vulnerability to future episodes . Accepting the need for mood-stabilizing medication for symptom control . Distinguishing between the patient’s personality and his/her bipolar disorder . Recognizing and learning to cope with stressful life events that trigger recurrences of bipolar disorder . Reestablishing functional relationships after a mood episode Note. From Miklowitz DJ. (2008) Bipolar Disorder: A Family-Focused Treatment Approach, 2nd Ed. Copyright 2008 by The Guilford Press [30]. Adapted with permission.
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self-guided homework (e.g. keeping a daily mood and sleep chart) accompany these topics. First, the clinician reviews the symptoms of BD and distinguishes them from symptoms of anxiety, psychosis, substance abuse or, in the case of teens, disruptive behaviour disorders. The clinician explains the interactive roles of genetic and biological vulnerability, stress and coping in the disorder’s onset, the role of risk factors (i.e. disruptions in sleep/wake rhythms, suddenly discontinuing medications, substance misuse, escalating family conflicts) and protective factors (i.e. consistency with medications and pharmacotherapy visits, stable sleep/wake patterns, structured, low conflict family routines). The impact of the disorder on family functioning is discussed. Care is taken to avoid any implication of blame of parents or spouses, and therapists clarify that many of the patient’s behaviours are driven by a biologically- and genetically-based mood illness rather than wilful intention. A key component of psychoeducation is the relapse drill, or the planning during periods of stability for emergency intervention (medical or behavioural) when the patient’s moods start to deteriorate or when he/she becomes suicidal. Families recall previous periods of mood instability and identify sequences consisting of triggers, early warning signs of relapse and palliative measures. A prevention plan is developed, which may include any combination of no suicide/no harm contracts, strategies to notify the physician, reducing stress triggers at home or stabilizing sleep/ wake rhythms. The plan is typed up and presented for the participants’ signature in the next session. Psychoeducation ends with a discussion of a handout titled How the Family Can Help. For teens, special emphasis is placed on keeping regular family routines (e.g. mealtimes, bed times). During psychoeducation and other phases of FFT, clinicians provide emotional support for parents and clinical referrals as appropriate (including pharmacotherapy). They teach parents to identify and cope with triggers for their own mood cycling (including high-intensity interactions with the bipolar family member) and emphasize communication strategies (see below) to help preserve marital relationships and relations with the affected and nonaffected offspring.
Communication enhancement training CET (sessions 10–15) is designed to reduce unproductive interactions amongst family members and improve the quality of exchanges. It is guided by the assumption that aversive communication reflects distress in the family’s attempts to cope with BD. It uses a role-playing format to teach patient’s and their family members four skills: expressing positive feelings, active listening, making positive requests for changes in each others’ behaviours and constructive negative feedback. The clinician offers handouts listing the components of each skill (e.g. for active
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listening: making eye contact, paraphrasing) and models each for the family. Then participants practice the skills with each other, with coaching and shaping by the clinician. Communication training is done less formally with adolescents than adults, capitalizing as much as possible on spontaneous interactions. Homework assignments, in which the participants record their efforts to use each skill, facilitate generalization to the home setting.
Problem solving Problem solving (sessions 16–21), in which families are taught to identify specific areas of disagreement, generate and evaluate solutions and implement solutions, focuses on behaviour management strategies the caregivers can employ without interfering with the bipolar patient’s desire for independence. Participants list their most pressing problems and define each one (e.g. an adolescent does not get to school on time and conflict ensues). Then, family members generate two to three solution choices and evaluate the pros and cons of each. Next, the patient and family members conjointly choose a best option or set of options and develop an implementation plan. Families practise problem solving between sessions using a self-guided homework sheet and report on their attempts in the next session. Towards the end of FFT, sessions can be tapered to trimonthly (months 10–24). Maintenance sessions revisit the seven objectives of FFT: has the family gained an understanding of the cyclic nature of the disorder? Is consistency of medication treatment in place? Has the family developed, and where necessary, implemented a relapse prevention plan? Are escalating verbal conflicts being held in check? These sessions usually involve problem solving and rehearsal of communication skills.
Case example Nadia was a 17-year-old girl of Eastern European heritage, who lived with her mother, father, grandmother and two younger brothers. She was diagnosed with bipolar I disorder after a suicide attempt. She had frequent outbursts of rage that caused significant conflict in her family, such that her parents described the household as a war zone. All family members agreed that Nadia’s rages created huge problems for the family, but they disagreed on the causes of those rage attacks. Nadia, for her part, felt they were triggered by the highly critical, hostile or aggravating interactions she had with her brothers and parents. Her brothers used highly choice words to explain her behaviour. In the third FFT session, the clinicians encouraged Nadia, her parents and her brothers to identify the triggers, prodromal signs and potential palliative strategies for her rage reactions (her grandmother was unavailable). Her reactions were often precipitated by family arguments or multiple
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requests from parents that confused her and she could not prioritize. She developed a stress thermometer which clarified the stages of her negative escalation. Nadia and her family members were then encouraged to use a variety of emotional self-regulation techniques at the beginning of Nadia’s rage escalation, including: disclosing to one another that something isn’t feeling right; using calming self-talk when we feel the heat rising; mindful breathing; eating something (when she suffered from low blood sugar, which was frequent); exiting the situation (e.g. going outside to cool down); or isolating oneself. With repeated practice, Nadia found that she could control her outbursts with her parents, but she was still repeatedly provoked by her two younger brothers. When their interactions degenerated into back and forth yelling matches, Nadia was especially likely to have a meltdown that led to self-cutting or other self-injurious behaviours. The communication enhancement module involved her brothers and focused on active listening (paraphrasing the statements of another family member, asking clarifying questions, nodding one’s head to show engagement, even when one disagrees). These skills became especially important in helping Nadia and her brothers to slow down their interactions. Being able to limit negative interchanges to a maximum of three volleys also helped to derail this predictable sequence. In the final segment of FFT, Nadia and her parents worked on problem-solving to maximize her chances of making a successful adjustment to life in college. Problem-solving sessions included how to manage her medications (i.e. fulfiling her medication prescriptions and
remembering to take her pills without reminders), getting herself out of bed in the morning without continual intervention by her parents and completing household tasks. Although she still had rage reactions and occasional suicidal thoughts by the end of treatment, Nadia and her parents both reported that these episodes were becoming fewer and farther between, did not last as long and were not as destructive. She reported fewer suicidal thoughts and improved mood. A conversation between Nadia and her doctor led to a reduction in her atypical antipsychotic dosage, which made it easier for her to get up in the morning.
Empirical studies of FFT There have been two open and four published randomized controlled trials of FFT (Table 2). In the first [32], conducted at the University of Colorado, acutely ill patients (N ¼ 101; 82 hospitalized) were randomly assigned at discharge to FFT and pharmacotherapy or a psychoeducational control condition called crisis management (CM) and pharmacotherapy. FFT was given in 21 sessions over 9 months and consisted of psychoeducation (didactic strategies for managing illness episodes as a family, including relapse prevention planning), communication skills training and problem-solving skills training. Patients in CM received 2 sessions of psychoeducation and crisis intervention sessions over 9 months. Patients in FFT were three times more likely to survive the full two-year follow-up without relapsing (52% vs. 17%) and had longer periods of stability without relapse (73.5 weeks vs. 53.2 weeks) than patients in CM. FFT
Table 2 Summary of findings in family-focused treatment studies. Study
Sample
Clinical state at entry
Comparison group
Key findings
Miklowitz et al. [29]
23
Miklowitz et al., 2003 [32]
101
Manic episode in prior 3 mo Depressed or manic episode in prior 3 mo
FFT, 11% relapse rate over 9 mo; Comparison, 61% FFT, 52% survival rate over 2 yr vs. 17% in crisis management
Rea et al., 2003 [33]
53
Treatment as Usual (matched controls) Crisis Management (2 psychoeducation sessions) Individual therapy
Miklowitz et al., 2003 [39]
30
Miklowitz et al., 2007 [36,37]
293
Acute depressive episode
Miklowitz et al., 2008 [34]
58 teens
Acutely or subsyndromally ill
Manic episode in prior 3 mo Depressed or manic episode in prior 3 mo
Crisis management (matched controls)
Collaborative care (3 psychoeducation sesions) 3 psychoeducation sessions
FFT, 36% rehospitalization over 2 yr; Comparison, 60% Combination of FFT and interpersonal therapy associated with longer delays prior to relapse and less severe depression over 1 yr FFT, 77% depression recovery rate; Collaborative care, 52% Adolescents in FFT recovered from depression 7 wk faster than adolescents in brief psychoeducation
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was also associated with lower depression and mania severity scores over 2 years. A trial at UCLA examined FFT and pharmacotherapy when compared to an equally intensive (21 session) individual therapy and pharmacotherapy [33]. All patients began in a hospitalized manic episode and were randomly assigned to treatments just after hospital discharge. Patients in the individual therapy received 21 sessions of psychoeducation, relapse prevention planning, medication adherence monitoring and support against the stigma of bipolar illness. Patients did not differ in rates or timing of relapse or rehospitalization during the first year of treatment. However, in a two-year post-treatment follow-up, patients in FFT showed lower rates of rehospitalization (12%) and symptomatic relapse (28%) than patients in individual therapy (60 and 60%, respectively). Moreover, when patients in FFT did relapse, they were less likely to require rehospitalization (55%) than patients in individual treatment (88%) (33). FFT has also been investigated in one open trial and one randomized trial of adolescent patients. In the open trial [21], 20 adolescents (mean age 15) received 21 sessions of FFT and pharmacotherapy and were followed over two years. Adolescents showed improvements in depression, mania and total problem behaviour scores over two years. The randomized trial [34], conducted over two sites, allocated 58 adolescents with bipolar spectrum disorder to FFT and pharmacotherapy or a three-session psychoeducational control condition called enhanced care (EC) and pharmacotherapy. Over two years, patients in FFT had shorter times to recovery from their initial depressive episodes, less time in states of depression and more time in remission; and a less severe trajectory of depressive symptoms [34].
The STEP-BD program The Systematic Treatment Enhancement Program for Bipolar Disorder (STEP-BD [35]) was a large-scale effort examining selected treatments for bipolar disorder across multiple US sites. One innovative aspect of the programme was a randomized trial in which acutely depressed bipolar patients (N ¼ 293) were assigned randomly to a medication algorithm and one of four psychosocial treatments: up to 30 sessions of FFT, interpersonal and social rhythm therapy (IPSRT), or cognitive-behavioural therapy (CBT) or a threesession individual psychoeducational treatment called collaborative care (CC). Over on one year, being in any of the three forms of intensive psychotherapy was associated with a higher recovery rate from depression (105/163, or 64.4%) than being in CC (67/130, or 51.5%; hazard ratio ¼ 1.47) [36]. Patients in intensive therapy were also 1.58 times more likely to remain well during any given month of the 12-month study than patients in CC. Rates of recovery for the specific modalities were: FFT, 77% (20/26), IPSRT,
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65% (40/62) recovered and CBT, 60% (45/75) recovered. In the CC condition, 51.5% recovered. Finally, patients in intensive therapy showed greater improvements in overall functioning (notably, relationship functioning and life satisfaction) than patients in CC [37]. Interestingly, STEP-BD found no difference in time to recovery between the two medication strategies tested for bipolar depression: mood-stabilizers plus adjunctive antidepressants or mood-stabilizers plus placebo [38]. Instead, adding psychotherapy to mood-stabilizers appeared to speed recovery by as much as 110 days (169 days vs. 279 days) during the study year [36]. The results of STEP-BD suggest that bipolar patients with acute depression require more intensive psychotherapy than is typically offered in community mental health centres. Possibly, the common ingredients of intensive treatments – such as teaching coping strategies to manage mood, intervening early with prodromal symptoms, enhancing patients’ consistency with mood-stabilizing medications and working towards resolution of key interpersonal or family problems – contribute to more rapid recoveries. The three intensive therapies appeared to be equally effective and each outperformed CC, although the study was statistically underpowered to compare each treatment with each other.
Conclusions from empirical studies FFT is effective in stabilizing bipolar mood (particularly depressive) symptoms and delaying recurrences and rehospitalizations. It also appears to benefit family relationship functioning. The findings hold true, whether adults or adolescents with bipolar disorder are sampled. Patients who receive ongoing family treatment may be more likely to consistently take medications than patients who receive briefer treatments. However, not all patients have family members who are either accessible or wish to be involved in treatment. The rate of family accessibility is higher amongst patients in childhood, adolescence or young adulthood than amongst patients who are middle-aged and are highly recurrent. FFT should be considered whenever patients have access to family members and especially when levels of criticism, hostility or overinvolvement characterize family or marital relationships.
Multifamily group approaches FFT is only one way of approaching the family relationships associated with BD. In fact, FFT has been criticized because of its focus on working with one family at a time instead of treating several families simultaneously. Other approaches have offered psychoeducation in multifamily groups, either with or without patients present. Miller and associates [40,41] randomly assigned 92 acutely ill bipolar I patients to pharmacotherapy alone or
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pharmacotherapy with 12 sessions of single-family problem-centred therapy or six sessions of multifamily group psychoeducation. Both treatment models included psychoeducation and problem-solving, using the McMaster family therapy approach. No group differences emerged in time to recovery or relapse, suggesting that neither of these family therapy strategies improved upon the outcomes observed in pharmacotherapy alone. However, a post-hoc analysis revealed that patients from families with high conflict or low problem-solving who received either form of family therapy had half as many depressive episodes per year, and spent less time in depressive episodes than patients from high conflict or low problem-solving families who received pharmacotherapy alone. Fristad and associates [42,43] conducted an 18-month waiting-list control study of a multifamily psychoeducation group with 175 school-aged bipolar (70%) and unipolar depressed (30%) children. The groups included didactic information, stress management, communication skills and coping with mood escalation. Over one year, children whose families participated in the groups had greater improvement in mood symptoms than children whose families were assigned to the waiting-list. Benefits of the groups extended to parents’ ability to advocate for the health needs of their children [43]. Studies of multifamily psychoeducation groups in schizophrenia typically do not involve patients [44]. Only one study, conducted at the University of Barcelona, Spain, has examined multifamily groups without patients [45]. Participants were 113 caregivers who lived with bipolar I and II patients; the patients were euthymic, currently undergoing pharmacotherapy and free of other axis I disorders (a somewhat rarified group). Caregivers were allocated to 12 weeks of group psychoeducation or no group psychoeducation. Caregiver groups focused on early detection of prodromes, medication adherence and effective communication and problem-solving. Over 1 year, patients whose relatives attended the groups had longer survival times prior to hypomanic or manic recurrences than patients in the no-treatment control condition, but did not differ on time to depressive or mixed episodes. It is notable that the relatives-only groups had effects on mania but not depression, whereas studies of individualized family therapy have found stronger effects on depression than mania. Possibly, caregivers become skilled at identifying the early warning signs of manic recurrences when undergoing group psychoeducation. What family therapy format do families choose, when given the choice? Only one study has addressed this issue amongst BD patients. The Veterans Administration Hospital in Denver, CO [46] recruited patients with bipolar disorder, schizophrenia or schizoaffective disorder and gave families three treatment options: individualized FFT (21 sessions); peer-led multifamily educational groups that
did not involve patients (12 sessions); brief (3 session) family psychoeducation or no family treatment. Of 133 referrals to the family programme, 58 (43.6%) chose no treatment. Of the remaining 75, 42 (56.0%) chose FFT, 28 (37.3%) requested peer-led multifamily groups and 5 (6.7%) opted for brief family treatment. The family members of bipolar patients were significantly more likely than the family members of schizophrenic or schizoaffective patients to choose individualized family therapy. Thus, although individualized family therapy is lengthier and costlier, it is also a format preferred by a majority of families coping with BD.
Cognitive-behavioural family models Two other family treatment models deserve mention, although neither has been evaluated in randomized trials. Both models are orientated towards bipolar youth. One, an adaptation of dialectical behaviour therapy, engages bipolar adolescents in weekly sessions of individual therapy and family skills training (up to 36 sessions), with a focus on the skills of mindful acceptance, distress tolerance, emotion regulation and interpersonal effectiveness. In a one-year open trial, 10 BD adolescents showed significant improvement from pre- to post-treatment in suicidality, non-suicidal self-injurious behaviour, depressive symptoms and emotional dysregulation [47]. West and associates [48] examined the three-year outcomes of 34 bipolar children (mean age 11) who participated in a 12-session child and family-focused cognitive-behaviour therapy programme. The model combined sessions of family psychoeducation with individual cognitivebehavioural skills training. Reductions from pre- to post-treatment were observed in mania, aggression, psychosis, depression and global-functioning scores, and gains were maintained over three years [48,49].
Conclusions Collectively, these studies suggest the importance of including caregivers in the treatment of bipolar patients. Of course, in the real world of mental health service delivery, families may or may not choose to become participants in treatment, or clinicians may not feel expert enough in family interventions to offer this modality. Nonetheless, the findings consistently indicate that combining family psychoeducation with pharmacotherapy has broad effects on patients’ symptoms (time to recovery, time to recurrence, symptom severity) and psychosocial functioning.
Mediating mechanisms Amongst the many unanswered questions about family therapy, concerns its mechanisms of action. When patients undergo treatment with their family members, what
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changes the patient’s ability to cope effectively in the family milieu, the caregivers’ ability to respond in a supportive manner to the patient or the ability of multiple family members to regulate their emotions when in conflict? Do patients become more consistent with medication regimens? Can the effectiveness of FFT and other family modalities be explained by whether or not family members learn to identify patients’ prodromal symptoms and implement early intervention strategies? The adoption of such skills would be a practical explanation for the results of the Rea et al. [33] study, which found that patients in FFT were less likely to relapse or be rehospitalized than patients in individual therapy; moreover, when patients in FFT did relapse, they were less likely to need hospitalization than those in individual therapy who relapsed. Possibly, family members become skilful at recognizing symptoms and requesting medication changes for the patients before episodes spin out of control. The more substantial effects of family treatments on depressive symptoms, however, argue against this hypothesis. Depressive recurrences have a less abrupt and definable prodrome than manic recurrences, often developing slowly and on top of pre-existing dysthymic states. Depressive recurrences are much harder to prevent with simple medication alterations than manic recurrences. What variables mediate the prevention of depressive versus manic symptoms? A partial answer comes from the study of Simoneau et al. [50], who analysed pretreatment to post-treatment data on family interactions (as assessed in a laboratory setting) amongst patients who received FFT or two sessions of family psychoeducation (crisis management). Changes in family interactions mediated the relationship between treatment group and one-year depression outcomes: patients from families who adopted positive communication and problem-solving skills (active listening, paraphrasing others’ statements, offering positive solutions to problems) had more significant improvements in depressive symptoms over one year than patients whose families did not gain in positive communication. These gains in communication skills were greater in FFT than in the control condition. Patients who showed gains in nonverbal behaviour when interacting with relatives (e.g. eye contact, affiliative gesturing) after participating in FFT were particularly likely to show stabilization of depressive symptoms. The design of the study did not allow us to disentangle whether improvements in patients’ or relatives’ interactional behaviour preceded or followed improvements in patients’ depression levels. A separate pathway was observed between participating in FFT, being more consistent with mood stabilizing medications, and the stabilization of manic symptoms [32]. This result is consistent with the observation that mood stabilizers have stronger effects on mania stabilization than on
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depression stabilization [51]. Possibly educating spouses or parents about the necessity of ongoing pharmacological adherence maximizes the chances that patients stay consistent with these regimens. As a result, patients become more fully protected when triggers for mania (e.g. stressors that disrupt sleep/wake cycles; [52]) present themselves. Different conclusions have been drawn about mediators of the effects of multifamily psychoeducation groups on the course of paediatric mood symptoms [43]. Parents who received multifamily psychoeducation groups report increases in their knowledge about paediatric mood disorders compared to parents in a waiting-list condition over 1 year. Moreover, these improvements in knowledge were related to the quality of mental health services obtained by parents for their children with mood disorders. The higher quality of mental health services associated with multifamily group participation was associated with lower mood symptom severity scores for the child. Parents who learn about bipolar disorder in a group setting may share information with other parents about services that have been helpful to their child, which may make other parents better consumers of services for their family. Thus, the mechanisms that explain the success of multifamily groups may differ from those that explain the success of individualized family therapy.
Moderators of treatment effects Moderators are variables that help explain the conditions under which a treatment is more and less effective [53]. There is converging evidence that the degree of EE, conflict or problem-solving ability moderates the effectiveness of family interventions [22,41,54]. Patients whose families are higher in EE and more impaired appear to benefit more, at least in terms of depressive symptoms, than those whose families are lower in EE and higher in problem-solving. The pattern of findings suggests the importance of assessing family functioning prior to embarking on a full course of family treatment, at least by questionnaire (e.g. the Family Adaptability and Cohesion Scale [55] or the Perceived Criticism Scale [56]), but preferably through a combination of observational and self-report measures. Another potential moderator of the effects of family treatment is likely to be the patient’s comorbidity with substance or alcohol abuse disorders. Although FFT is not viewed as a primary treatment for substance abuse, it can be used to further the goals of chemical dependency treatments. Moreover, many bipolar patients refuse chemical dependency treatment, and family intervention may bridge an important gap in services for such patients. Goldstein, Goldstein and Miklowitz [57] have developed a manual for FFT for adolescent bipolar patients who are also substance or alcohol abusers. This manual describes procedures such as: engaging adolescents and parents in
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a fact-driven discussion regarding the bidirectional relationship between bipolar disorder and substance abuse and the risk-benefit balance of substance use in their family, specifically; addressing substance use in parents, such that the teen recovers in a substance-free home; using behaviour modification for substance-related behaviours (e.g. rewards for substance free days, consequences for slippage); encouraging family members and adolescents to communicate openly about substance use and related behaviours, and for parents to take a non-punitive stance; modelling and role-playing of the interpersonal skills required to refuse substances from peers; and problem-solving about risk factors for continued use. Problem-solving may include steps such as: identifying high-risk situations (people, places, situations, feelings) that contribute to substance craving; developing strategies to avoid these situations; maximizing pleasurable activities that do not involve substances; and coping with substance withdrawal. The effectiveness of the modified treatment for bipolar adolescents with substance abuse or dependence is being evaluated in an open trial at the Western Psychiatric Institute and Clinic in Pittsburgh, PA.
Directions for future research Research on family therapy for bipolar disorder needs to address three distinct issues: dissemination, neural mechanisms, and preventative applications. Studies of dissemination should clarify the most generalizable forms of family intervention that will maximize effectiveness and decrease costs. Briefer family interventions – for example, the seven-session psychoeducation module of FFT – may be adequate in some circumstances. It is clear, however, that cheaper does not mean better: many families complain that a 21-session treatment barely scratches the surface. Psychoeducational treatments reduced to two to three sessions have not been found to work as well as psychosocial treatments containing 12 or more sessions [58]. Future studies of the effectiveness of family therapy need to consider neural mechanisms of change as well as behavioural mechanisms. Studies have found that bipolar adults and youth show increased amygdala activation and decreased prefrontal cortical activation (notably, the dorsolateral prefrontal cortex and the ventrolateral prefrontal cortex) on fMRI (e.g. [59,60]) during affective challenge tasks, such as judging the emotions displayed by faces. Studies that examine changes in these behavioural and neural markers of emotional dysregulation may yield clues as to why family treatment, and more broadly, psychotherapy in general, has a positive impact on the course of BD. These studies must be designed to use emotion challenge tasks that mirror the skills being taught in psychosocial treatment, such as the ability to self-regulate one’s emotions when in conflict with family members.
Family interventions may have a role in the initial prevention of the disorder. People who develop BD often present with subsyndromal but impairing mood swings before the illness becomes syndromal [61,62]. Conversion from these subsyndromal states to fully syndromal BD I or II disorder has been reported in 25% of youth over an 18-month period, and the risk increases when a first-degree relative has BD [63]. Neural markers such as changes in amygdalar volume or activation of amygdalar/prefrontal circuitry may help to identify genetically vulnerable youth who are at risk for conversion to BD I or II. We have initiated a study of FFT for high risk youth, which focuses on skills relevant to managing the prodromal stages of BD – mood monitoring, reducing family conflict and improving problem-solving, and working toward stabilization of daily routines and sleep/wake cycles [62]. It is possible that this briefer version of FFT could delay the onset of BD amongst at-risk youth, or at least minimizing its severity once manifest. More generally, psychosocial treatments orientated towards coping with mood dysregulation and enhancing the buffering effects of contextual factors may reduce the neurotoxic effects of early episodes. If active intervention is initiated before the illness becomes highly recurrent, we may be able to reduce its long-term functional consequences.
References 1. Heru, A.M. (2006) Family psychiatry: from research to practice. Am. J. Psychiatry, 163, 962–968. 2. Pitschel-Walz, G., Leucht, S., B€ auml, J. et al. (2001) The effect of family interventions on relapse and rehospitalization in schizophrenia: A meta-analysis. Schizophrenia Bull., 27, 73–92. 3. Cohen, M., Baker, G., Cohen, R.A. et al. (1954) An intensive study of 12 cases of manic-depressive psychosis. Psychiatry, 17, 103–137. 4. Mayo, J.A. (1979) Marital therapy with manic-depressive patients treated with lithium. Compr. Psychiat., 20, 419–426. 5. Mayo, J.A., O’Connell, R.A. and O’Brien, J.D. (1979) Families of manic-depressive patients: effect of treatment. Am. J. Psychiatry, 136, 1535–1539. 6. Brodie, H.K.H. and Leff, M.J. (1971) Bipolar depression: A comparative study of patient characteristics. Am. J. Psychiatry, 127, 1086–1090. 7. Carlson, G.A., Kotin, J., Davenport, Y.B. and Adland, M. (1974) Follow-up of 53 bipolar manic-depressive patients. Brit. J. Psychiat., 124, 134–139. 8. Targum, S.D., Dibble, E.D., Davenport, Y.B. and Gershon, E.S. (1981) The family attitudes questionnaire: Patients and spouses’ views of bipolar illness. Arch. Gen. Psychiatry, 38, 562–568. 9. Davenport, Y.B., Ebert, M.H., Adland, M.L. and Goodwin, F.K. (1977) Couples group therapy as adjunct to lithium maintenance of the manic patient. Am. J. Orthopsychiat., 47, 495–502.
Family Therapy Approaches 10. Frank, E., Targum, S.D., Gershon, E.S. et al. (1981) A comparison of nonpatient and bipolar patient-well spouse couples. Am. J. Psychiatry, 138, 764–767. 11. Hirschfeld, R.M.A. and Klerman, G.L. (1979) Personality attributes and affective disorders. Am. J. Psychiatry, 136, 67–70. 12. Fitzgerald, R.G. (1972) Mania as a message: treatment with family therapy and lithium carbonate. Am. J. Psychother., 26, 547–555. 13. Perlick, D.A., Hohenstein, J.M., Clarkin, J.F. et al. (2005) Use of mental health and primary care services by caregivers of patients with bipolar disorder: a preliminary study. Bipolar Disord., 7, 126–135. 14. Butzlaff, R.L. and Hooley, J.M. (1998) Expressed emotion and psychiatric relapse: A meta-analysis. Arch. Gen. Psychiatry, 55, 547–552. 15. Vaughn, C.E. and Leff, J.P. (1976) The influence of family and social factors on the course of psychiatric illness: a comparison of schizophrenia and depressed neurotic patients. Brit. J. Psychiat., 129, 125–137. 16. Miklowitz, D.J., Goldstein, M.J., Nuechterlein, K.H. et al. (1988) Family factors and the course of bipolar affective disorder. Arch. Gen. Psychiatry, 45, 225–231. 17. Yan, L.J., Hammen, C., Cohen, A.N. et al. (2004) Expressed emotion versus relationship quality variables in the prediction of recurrence in bipolar patients. J. Affect. Disord., 83, 199–206. 18. Miklowitz, D.J., Simoneau, T.L., George, E.L. et al. (2000) Family-focused treatment of bipolar disorder: 1-year effects of a psychoeducational program in conjunction with pharmacotherapy. Biol. Psychiatry, 48, 582–592. 19. O’Connell, R.A., Mayo, J.A., Flatow, L. et al. (1991) Outcome of bipolar disorder on long-term treatment with lithium. Brit. J. Psychiat., 159, 132–229. 20. Priebe, S., Wildgrube, C. and Muller-Oerlinghausen, B. (1989) Lithium prophylaxis and expressed emotion. Brit. J. Psychiat., 154, 396–399. 21. Miklowitz, D.J., Biuckians, A. and Richards, J.A. (2006) Earlyonset bipolar disorder: a family treatment perspective. Dev. Psychopathol., 18, 1247–1265. 22. Kim, E.Y. and Miklowitz, D.J. (2004) Expressed emotion as a predictor of outcome among bipolar patients undergoing family therapy. J. Affect. Disord., 82, 343–352. 23. Hooley, J.M. and Gotlib, I.H. (2000) A diathesis-stress conceptualization of expressed emotion and clinical outcome. Appl. Prev. Psychol., 9, 131–151. 24. Wendel, J.S., Miklowitz, D.J., Richards, J.A. and George, E.L. (2000) Expressed emotion and attributions in the relatives of bipolar patients: An analysis of problem-solving interactions. J. Abnorm. Psychol., 109, 792–796. 25. Simoneau, T.L., Miklowitz, D.J. and Saleem, R. (1998) Expressed emotion and interactional patterns in the families of bipolar patients. J. Abnorm. Psychol., 107, 497–507. 26. Hahlweg, K., Goldstein, M.J., Nuechterlein, K.H. et al. (1989) Expressed emotion and patient-relative interaction in families of recent-onset schizophrenics. J. Consult. Clin. Psych., 57, 11–18. 27. Hooley, J.M., Gruber, S.A., Scott, L.A. et al. (2005) Activation in dorsolateral prefrontal cortex in response to maternal
28.
29.
30.
31.
32.
33.
34.
35.
36.
37.
38.
39.
40.
41.
42.
43.
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criticism and praise in recovered depressed and healthy control participants. Biol. Psychiatry, 57, 809–812. Miklowitz, D.J. (2007) The role of the family in the course and treatment of bipolar disorder. Curr. Dir. Psychol. Sci., 16, 192–196. Miklowitz, D.J. and Goldstein, M.J. (1990) Behavioral family treatment for patients with bipolar affective disorder. Behav. Modif., 14, 457–489. Miklowitz, D.J. (2008) Bipolar Disorder: A FamilyFocused Treatment Approach, 2nd edn, Guilford Press, New York, NY. Falloon, I.R.H., Boyd, J.L. and McGill, C.W. (1984) Family Care of Schizophrenia: A Problem-Solving Approach to the Treatment of Mental Illness, Guilford Press, New York. Miklowitz, D.J., George, E.L., Richards, J.A. et al. (2003) A randomized study of family-focused psychoeducation and pharmacotherapy in the outpatient management of bipolar disorder. Arch. Gen. Psychiatry, 60, 904–912. Rea, M.M., Tompson, M., Miklowitz, D.J. et al. (2003) Family focused treatment vs. individual treatment for bipolar disorder: results of a randomized clinical trial. J. Consult. Clin. Psych., 71, 482–492. Miklowitz, D.J., Axelson, D.A., Birmaher, B. et al. (2008) Family-focused treatment for adolescents with bipolar disorder: results of a 2-year randomized trial. Arch. Gen. Psychiatry, 65, 1053–1061. Sachs, G.S., Thase, M.E., Otto, M.W. et al. (2003) Rationale, design, and methods of the systematic treatment enhancement program for bipolar disorder (STEP-BD). Biol. Psychiatry, 53, 1028–1042. Miklowitz, D.J., Otto, M.W., Frank, E. et al. (2007) Psychosocial treatments for bipolar depression: a 1-year randomized trial from the Systematic Treatment Enhancement Program. Arch. Gen. Psychiatry, 64, 419–427. Miklowitz, D.J., Otto, M.W., Frank, E. et al. (2007) Intensive psychosocial intervention enhances functioning in patients with bipolar depression: results from a 9-month randomized controlled trial. Am. J. Psychiatry, 164, 1–8. Sachs, G.S., Nierenberg, A.A., Calabrese, J.R. et al. (2007) Effectiveness of adjunctive antidepressant treatment for bipolar depression. N. Engl. J. Med., 356, 1711–1722. Miklowitz, D.J., Richards, J.A., George, E.L. et al. (2003) Integrated family and individual therapy for bipolar disorder: results of a treatment development study. J. Clin. Psychiat., 64, 182–191. Miller, I.W., Solomon, D.A., Ryan, C.E. and Keitner, G.I. (2004) Does adjunctive family therapy enhance recovery from bipolar I mood episodes? J. Affect. Disord., 82, 431–436. Miller, I.W., Keitner, G.I., Ryan, C.E. et al. (2008) Family treatment for bipolar disorder: family impairment by treatment interactions. J. Clin. Psychiat., 69, 732–740. Fristad, M.A. (2006) Psychoeducational treatment for schoolaged children with bipolar disorder. Dev. Psychopathol., 18, 1289–1306. Mendenhall, A.N., Fristad, M.A. and Early, T. (2009) Factors influencing service utilization and mood symptom severity in children with mood disorders: Effects of Multi-Family Psychoeducation Groups (MFPG). J. Consult. Clin. Psych., 77, 463–473.
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44. McFarlane, W.R., Lukens, E., Link, B. et al. (1995) Multiplefamily groups and psychoeducation in the treatment of schizophrenia. Arch. Gen. Psychiatry, 52, 679–687. 45. Reinares, M., Colom, F., S anchez-Moreno, J. et al. (2008) Impact of caregiver group psychoeducation on the course and outcome of bipolar patients in remission: a randomized controlled trial. Bipolar Disord., 10, 511–519. 46. Dausch, B.M. (2008) Family psychoeducation for veterans with serious mental illness: overview and use of telemedicine. Paper presented at Veterans Administration Best Practices joint MIRECC Annual Conference: Transforming Mental Health Care: Promoting Recovery and Integrated Care; Alexandria, VA. 47. Goldstein, T.R., Axelson, D.A., Birmaher, B. and Brent, D.A. (2007) Dialectical behavior therapy for adolescents with bipolar disorder: a 1-year open trial. J. Am. Acad. Child. Psy., 46, 820–830. 48. West, A.E., Henry, D.B. and Pavuluri, M.N. (2007) Maintenance model of integrated psychosocial treatment in pediatric bipolar disorder: A pilot feasibility study. J. Am. Acad. Child. Psy., 46, 205–212. 49. Pavuluri, M.N., Graczyk, P.A., Henry, D.B. et al. (2004) Child and family-focused cognitive behavioral therapy for pediatric bipolar disorder: development and preliminary results. J. Am. Acad. Child. Psy., 43, 528–537. 50. Simoneau, T.L., Miklowitz, D.J., Richards, J.A. et al. (1999) Bipolar disorder and family communication: Effects of a psychoeducational treatment program. J. Abnorm. Psychol., 108, 588–597. 51. Thase, M.E. (2006) Bipolar depression: Diagnostic and treatment challenges. Dev. Psychopathol., 18, 1213–1230. 52. Malkoff-Schwartz, S., Frank, E., Anderson, B. et al. (1998) Stressful life events and social rhythm disruption in the onset of manic and depressive bipolar episodes: A preliminary investigation. Arch. Gen. Psychiatry, 55, 702–707.
53. Kraemer, H.C., Wilson, T., Fairburn, C.G. and Agras, W.S. (2002) Mediators and moderators of treatment effects in randomized clinical trials. Arch. Gen. Psychiatry, 59, 877–883. 54. Miklowitz, D.J., Axelson, D.A., George, E.L. et al. (2009) Expressed emotion moderates the effects of family-focused treatment for bipolar adolescents. J. Am. Acad. Child. Psy., 48, 643–651. 55. Olson, D.H. and Gorall, D.M. (2006) FACES-IV and the Circumplex Model, Life Innovations, Roseville, MN. 56. Hooley, J.M. and Parker, H.A. (2006) Measuring expressed emotion: an evaluation of the shortcuts. J. Fam. Psychol., 20, 386–396. 57. Goldstein, B.I., Goldstein, T.R. and Miklowitz, D.J. (2008) Integrating a Substance Use Disorder (SUD) Perspective into Family-Focused Therapy of Adolescents with Bipolar Disorder (FFT-A). Unpublished Manual. 58. Miklowitz, D.J. (2008) Adjunctive psychotherapy for bipolar disorder: state of the evidence. Am. J. Psychiatry, 165, 1408–1419. 59. Rich, B.A., Vinton, D.T., Roberson-Nay, R. et al. (2006) Limbic hyperactivation during processing of neutral facial expressions in children with bipolar disorder. Proc. Natl. Acad. Sci. USA, 103, 8900–8905. 60. Yurgelun-Todd, D.A., Gruber, S.A. et al. (2000) fMRI during affect discrimination in bipolar affective disorder. Bipolar Disord., 2 (3 Pt 2), 237–248. 61. Chang, K., Steiner, H. and Ketter, T. (2003) Studies of offspring of parents with bipolar disorder. Am. J. Med. Genet. C: Seminars in Medical Genetics, 123, 26–35. 62. Miklowitz, D.J. and Chang, K.D. (2006) Prevention of bipolar disorder in at-risk children: theoretical assumptions and empirical foundations. Dev. Psychopathol., 20, 881–897. 63. Birmaher, B., Axelson, D., Strober, M. et al. (2006) Clinical course of children and adolescents with bipolar spectrum disorders. Arch. Gen. Psychiatry, 63, 175–183.
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Collaborative Care for Bipolar Disorder Amy M. Kilbourne1, David E. Goodrich2 and Mark S. Bauer3 1
University of Michigan; VA National Serious Mental Illness Treatment Research and Evaluation Center, Ann Arbor, MI, USA 2 VA National Serious Mental Illness Treatment Research and Evaluation Center, Ann Arbor, MI, USA 3 Center for Organization, Leadership, and Management Research, Boston VA Healthcare System, Boston, MA, USA
Bipolar disorder is a complex and chronic condition where the quality of care and subsequent patient outcomes remain suboptimal, despite the existence of clinical practice guidelines. Psychiatric treatment of bipolar disorder is complicated by the fact that patients vary with respect to the uniqueness of their symptoms, life circumstances and comorbid psychiatric issues [1]. Moreover, patients with serious mental illnesses such as bipolar disorder, are more likely to experience a substantial burden of general medical comorbidities than the general population, due in part to the organizational and professional separation of mental and physical care [2]. In recent years, treatment models, such as the Chronic Care Model (CCM) [3] have proved effective in helping clinicians improve the coordination of patient care for chronic health conditions, such as depression or diabetes and thereby reducing disparities in health outcomes. This chapter reviews the current knowledge of integrated medical and psychiatric care for patients with bipolar disorder in community settings. We then propose a collaborative treatment model entitled Life Goals Collaborative Care (LGCC), which seeks to improve the quality of health care for patients with bipolar disorder by: (1) improving coordinated care management; (2) empowering patients to take an active role in self-management of mental and physical risk factors; and (3) providing decision support to clinicians that insures patients receive guideline concordant care. Collaborative care models, such as the LGCC, provide policy makers and clinicians with a tool to simultaneously make quality improvements in organizational and patientlevel processes of care. These improvements can be implemented in a flexible and cost-effective manner that allows for contextual factors relating to clinic size, resources and patient characteristics.
Bipolar Disorder: Clinical and Neurobiological Foundations Edited by Lakshmi N. Yatham and Mario Maj © 2010 John Wiley & Sons, Ltd. ISBN: 978-0-470-72198-8
Integrated care for bipolar disorder: current evidence Bipolar disorder is a costly, significant public health problem Bipolar disorder is a chronic condition with a 1–6.4% lifetime prevalence [4,5] that is associated with significant personal and societal costs [6–8]. This illness is one of the top 10 causes of disability in the United States [9], is associated with increased risk of suicide, homelessness and incarceration, and is one of the most expensive mental disorders [7,10]. Persons with bipolar disorder are often burdened by co-occurring conditions, including substance use disorders, anxiety and suicidal thoughts [11]. Much of the health care costs in patients with bipolar disorder have been attributed to coexisting comorbidities [12,13]. From an overall public health perspective, the cost of bipolar disorder care involves not only assessment of mental health costs, but assessment of overall medical costs [8,13,14]. Patients with bipolar disorder often incur the most health care costs of any mental illness, and costs from general medical conditions can be up to 40% higher than mental health care costs amongst these patients [15].
Medical comorbidity in bipolar disorder poses a unique and significant public health problem The substantial burden of general medical conditions has been documented in patients with serious mental illness [16,17]. However, recent evidence suggests that the burden of medical comorbidities and their adverse outcomes are especially pronounced for individuals with bipolar disorder [14,16,18]. The prevalence of recognized medical conditions in patients with bipolar disorder exceeds national averages, notably hypertension (25%), hyperlipidaemia (22%), obesity (12%), type 2 diabetes (17%), as well as infectious diseases including hepatitis C (6%) [16,19,20]. Current research suggests that individuals with bipolar disorder may be experiencing medical comorbidity at a younger age (four to seven years younger) 453
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than their nonpsychiatric counterparts [16]. Some of the most common medical comorbidities (e.g. diabetes, hypertension, hyperlipidaemia) may significantly increase mortality risk as well [18]. Patients with bipolar spectrum disorders (e.g. bipolar II) have an equal risk for medical comorbidities as patients with bipolar I disorder [14,16,20] and a similar risk to schizophrenia. Hence, there is growing concern that the potential years of life lost in bipolar disorder is attributed to increased medical comorbidity [14]. Without adequate treatment, a 25-year-old person with bipolar disorder can expect to lose 14 years of effective major activity and 9 years of life [6,21].
Medical conditions uniquely impact patients with bipolar disorder Bipolar disorder presents a unique challenge, apart from other chronic, serious mental illnesses (e.g. schizophrenia), because of its cyclical nature (i.e. alternating episodes of mania and depression), which can lead to long periods where the patient has little or no contact with friends or providers (i.e. during a manic episode) [22,23]. Lack of contact can lead to poor adherence, job loss, social instability and increased risk of medical comorbidity. Manic and premanic episodes can increase the risk of infectious diseases (e.g. hepatitis C) through sexual indiscretions or unstable social behaviour [24,25]. In contrast, current episodes of depression in bipolar disorder can decrease motivation to seek medical care when needed [23,26] and increase the risk of cardiovascular disease (CVD) through sedentary lifestyle, poor dietary habits and subsequent weight gain [14,27,28]. Therefore, efforts to improve quality of care for patients with bipolar disorder cannot be successful without an understanding of how different episodes impact these patients. Patients with bipolar disorder as opposed to patients with schizophrenia are also more likely to be exposed to different classes of psychotropic medications [29,30], notably anticonvulsants, antidepressants and atypical antipsychotics, all of which have side effects that can lead to adverse health outcomes, such as thyroid or kidney disease (e.g. lithium) [29,30], bone density loss (e.g. anticonvulsants) [31] and metabolic syndrome (e.g. atypical antipsychotic medications) [32].
Medical conditions in patients with bipolar disorder are undertreated Given the tendency for individuals with bipolar disorder to be higher functioning than those with other serious mental illnesses, they are more likely to be active members of society. Hence, undertreated medical conditions can lead to adverse outcomes on a societal level (e.g. increased risk of diabetes, cardiovascular conditions) and can lead to increased economic costs due to missed work or poor
functioning [14]. Evidence suggests that medical comorbidity amongst patients with mental disorders, including bipolar disorder, is under-detected and inadequately treated. General medical care for patients with mental disorders has remained suboptimal, in particular for CVD [33], diabetes [34] and preventative services [35]. CVD is the leading cause of morbidity and mortality amongst patients with bipolar disorder [18]. Chronic medical conditions in patients with bipolar and other mental disorders are often missed, because the patients are primarily managed in the mental health setting, and their medical illnesses may be overlooked [36,37]. Despite the existence of evidence-based treatments for this condition [38,39], quality of care and subsequent outcomes for individuals with bipolar disorder remain suboptimal [40–42]. Only half of the patients receive adequate outpatient care and only a third received adequate psychotropic drug level and safety monitoring [43]. Inadequate access to and quality of care for bipolar disorder leads to adverse outcomes, including preventable hospitalizations [7], emergency room use [6] and mortality [21,44]. Hence, reasons for poor quality may be attributed to underdetection of medical conditions in psychiatric facilities that a general internist would typically screen for [37,45] or lack of time mental health practitioners have to care for these conditions [37]. Therefore, treatment models that improve outcomes by addressing these gaps in quality of care need to be implemented for patients with bipolar disorder.
Bridging the divide: treatment models to integrate patient care The CCM is an ideal framework to coordinate medical and psychiatric care The greater recognition of medical risk factors associated with bipolar disorder and the cyclical nature of this illness suggest the need to improve coordination and continuity of care between general medical and mental health providers [14]. However, our medical care systems continue to operate across a chasm without much direct interaction [46]. Multi-component treatment models combine the use of non-physician staff (i.e. care managers) to enhance communication between providers and patient selfmanagement skills, systematic incorporation of evidencebased guidelines and use of population-based data in monitoring quality and outcomes of care foster improved coordination of care and ultimately patient outcomes [3,47,48]. The Wagner CCM [3,48] is one of the most widely adopted frameworks that shares these features. The CCM is considered one of the most effective treatment models because of its focus on organizational change, patient activation strategies and, unlike disease management models [49], facilitated coordination of care across existing providers
Collaborative Care
(e.g. primary care providers, mental health specialists). Hence, the CCM transforms health care delivery from its current focus on acute care to one that delivers effective care for chronic conditions. The advantage of the CCM is that it is a versatile, manual based treatment model (i.e. requiring limited training to implement by existing staff). It is also more cost-efficient than existing medical-psychiatric integrated care models, which chiefly rely on hiring new teams of personnel at each facility [50]. The manual-based framework of the CCM facilitates its customization and adaptability to different settings and patient severity levels, because personnel from a variety of backgrounds (e.g. RNs, MSWs) can be trained in its implementation [48], and because of its emphasis on guideline implementation, patient self-management support via a care manager and regular tracking of patients via a registry that does not require a sophisticated information system [51].
Chronic (collaborative) care models are not adapted to needs of patients with bipolar disorder To date, the CCM has only been recently adapted to coordinate medical and psychiatric care for patients with mental disorders in one, small randomized controlled trial [52,53]. However, two CCM-based interventions have been tailored to improve coordination of care for patients with bipolar disorder [54,55], both of which focus on improving psychiatric care exclusively, and are not designed to coordinate medical care. The CCM requires further testing to address medical comorbidity within the context of the different episodes in bipolar disorder. Other treatment models available to coordinate care for patients with mental disorders include Assertive Community Treatment (ACT) [56,57] and intensive case management (ICM) models [50,58,59]. However, ACT and ICM are primarily designed to address substance use disorders amongst patients with chronic mental disorders such as schizophrenia, and are not designed for managing the vast majority of patients with bipolar disorder, many of whom are able to function more independently. Moreover, high start-up costs from hiring additional personnel preclude the dissemination of ACT and ICM models into routine care and their adaptation to general medical settings. Alternatively, CCM-based models have been shown to be cost-effective when applied to managing unipolar depression and other chronic medical illnesses [60,61]. While other approaches to improving medical care for patients with mental disorders exist, such as the training of psychiatrists in general medical care [62], psychiatrists often lack the time, resources and incentives to treat their patients medical conditions [36]. In contrast, the CCM, which involves a care manager who coordinates care across existing providers, may be cost-efficient and hence, sustainable in routine care.
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The CCM can be adapted to community mental health settings The CCM is a desirable framework for improving care across medical and psychiatric conditions, because it can be implemented at a population-based or health plan level. Treatment models that operate at the health plan level are desirable, because health plans often encompass multiple medical and psychiatric provider organizations, often in the form of mental health carve outs. Between 50 and 70% of the insured population (e.g. commercial and Medicaid) is covered under mental health carve outs, making this arrangement the predominant form of organizing and financing mental health services in the United States [63,64]. Unlike closed, staff-model health systems, which can provide medical and psychiatric care under the same entity (e.g. Veterans Administration, Kaiser Permanente), networkmodel plans, because of their dispersed nature, often cannot afford to hire general medical clinicians for each mental health clinic [65]. This makes implementing the CCM at the plan level paramount if coordinated care is to be sustainable. Moreover, implementing treatment models, such as the CCM at the health plan level as opposed to individual clinics, is more likely to be sustainable, because the health plan can take advantage of large practice networks to leverage resources and maximize efficiencies across disperse medical and psychiatric providers [2,47]. In contrast, establishing CCM functions (e.g. care managers) at individual practices is not sustainable in the long-term because, again, individual clinics are often too small to bear the cost of hiring additional personnel. Implementing the CCM at the health plan level also minimizes disruption in delivery of care across existing practices [65]. Plan-level care management, despite the concern that it might be too impersonal, has been shown to be effective in improving depression care via telephone disease management [61,65,66]. Patients with serious mental illness are more likely to value improved communication and coordination of care between medical and psychiatric providers rather than co-location of services [67]. Given the need to: (1) adapt the CCM to the unique characteristics of bipolar disorder; and (2) implement treatment models that coordinate care in mental health carve-outs, we propose a collaborative care model for bipolar disorder that addresses these critical needs.
A collaborative care model for bipolar disorder First generation collaborative care models for bipolar disorder The manual-based framework of the CCM facilitates its customization and adaptability to different settings and
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patient severity levels; because personnel from a variety of backgrounds (e.g. RNs, MSWs) can be trained in its implementation, and because of its emphasis on guideline implementation, patient self-management support via a care manager and regular tracking of patients via a registry that does not require a sophisticated information system. Thus, Bauer and colleagues adapted the CCM model into a treatment model specific to bipolar disorder that focused both on improving psychosocial function [68] and coordinating care. The original Life Goals CCM model [54,69] incorporated the four key components of the Wagner CCM [3]: selfmanagement; delivery system design (care management); clinical information systems (care management- Registry); and decision support (guidelines dissemination). This preliminary version of Life Goals was tested in two separate multisite randomized controlled trials (RCT), targeted psychosocial outcomes and improved bipolar symptom management. The original Life Goals CCM was designed and tested as an effectiveness model, in which subjects and procedures resembled real-world populations and settings. Bauer and colleagues [54,69–71] conducted the > RCT of the Life Goals versus usual care across 11 VA sites. The RCT (n ¼ 306) demonstrated that compared to usual care, the LGCC model reduced the number of patient weeks in affective episode (6.2 weeks, p ¼ 0.041), improved overall function ( þ 30%; p ¼ 0.003) and improved mental health-related quality of life (37.6 vs. 34.1; p ¼ 0.01). The Life Goals was cost-neutral while achieving a net reduction of 6.2 weeks in affective episode. More recently, Kilbourne and colleagues [52,53] extended the adaptation of the CCM to bipolar patients by testing the Life Goals intervention programme with a modified curriculum to address both medical and psychiatric outcomes in older bipolar patients (i.e. >50 years old). In this small RCT (n ¼ 58), participants were recruited from a large VA mental health facility and randomized to the enhanced Life Goals programme or to usual care. Participants in the intervention group received four self-management sessions over four consecutive weeks, followed by 6 months of care management support via monthly phone calls with a care manager, while providers received decision support. Intervention group participants showed significantly greater improvements in the physical-health related quality life component of the SF-12 (þ 0.8 vs. 0.6 p ¼ 0.040) and trends showing greater improvements (non-significant) in mental health-related quality of life on the SF-12, mean-change in self-management efficacy [72] and bipolar symptoms measured by the Internal State Scale [73]. In summary, three recently published independent randomized controlled trials, totalling over 750 subjects with a substantial proportion of minority and comorbidly ill patients [52,53,70,74], found that collaborative care for bipolar disorder improve patient outcomes and recovery, including symptoms, functioning and quality of life, when compared to usual care.
Addressing the complexity of bipolar care: a LGCC model Following the seminal work on adapting the CCM to an integrated model of care for bipolar disorder, Kilbourne and colleagues [52,53] developed an enhanced Life Goals treatment programme that addresses the psychiatric and medical concerns of clinicians treating bipolar patients in the real world [75]. The new patient treatment manual includes additional modules dealing with psychological comorbidities, such as anxiety disorders, suicide and substance abuse, as well as managing medical risk factors (e.g. sleep, nutrition, exercise, medical decision making). The original four components adapted from the Wagner CCM have been paired down to a basic model of three core elements. The new LGCCs core elements include patient Self-Management, enhanced access via Care Management provided by a Health Specialist (e.g. R.N. or MSW) contacts and information systems, as well as enhanced Decision Support (evidence-based guidelines) (Figure 1). The goal of LGCC is to help patients with bipolar and other mental disorders achieve personal wellness goals through application of the three core treatment elements that simultaneously promote healthy lifestyles and bipolar symptom management. Like its Life Goals predecessor, the LGCC is a manual-based brief intervention based on principles of the CCM [3], social cognitive Theory [76] and motivational enhancement counselling [77], and combines best practices in patient selfmanagement [78,79] education and collaborative care.
Self-management support Self-management is a concept and skill that the Health Specialist helps cultivate with patients, either in a group or individual format. As in the original CCM [3], selfmanagement support refers to the education of consumers on how to play an active role in their own care. Selfmanagement includes raising awareness of steps to manage mental and physical health conditions, activating consumer motivation for change, developing skills and knowledge to manage health condition(s), increasing self-confidence to sustain and adhere to changes and following up with consumers about goal progress. The LGCC model calls for Health Specialists to develop patient self-management in two phases. Phase 1 calls for Health Specialists to deliver a minimum of four weekly selfmanagement lessons of 90–120 minutes in duration, based on the Life Goals CCM self-management programme originally developed by Bauer and colleagues (See Table 2 for content) [54,68–71]. The Life Goals lessons cover psychoeducation content aimed to: (1) increase knowledge of bipolar disorder; (2) engage patients in active discussions of coping strategies for manic and depressive symptoms; (3) build self-efficacy to maintain long-term changes without support; and (4) educate patients how to more
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Care coordination
Fig. 1 Life Goals Collaborative Care Model for Bipolar Disorder (Bauer et al. 2006; Simon et al. 2006; Kilbourne et al. 2008).
effectively engage providers for collaborative decision making. During Phase 2, Health Specialists aim to reinforce selfmanagement lessons through at least six brief monthly contacts. To maximize patient engagement in the treatment process and thereby increase adoption of programme skills, Health Specialists utilize Motivational Enhancement counselling [77] that is evocative, respectful of patient autonomy and patient-centred. The psychoeducational content of the Life Goals programme draws upon recent behavioural change evidence on the application of social cognitive theory, self-management and motivational communication strategies to address symptom management and problem solving/decision skills (Tables 3 and 4). Since some patients might miss group sessions, the self-management lessons are designed so that missing one to two lessons is acceptable, because the session content overlaps across sessions and
because they are scripted so that they can be made up via a one-on-one visit or phone call [80]. Self-management is most efficiently delivered in group sessions, and this is the preferred format as consumers can have active discussions and learn from each other. However, these sessions can also be delivered via one-on-one contacts using the accompanying workbook Overcoming Bipolar Disorder: A Comprehensive Workbook for Managing Your Symptoms & Achieving Your Life Goals [75]. Table 2 also showcases options for adapting LGCC to routine practice. The LGCC protocol also allows for providers to augment Life Goals self-management approach with adjunctive psychosocial treatments, in light of recent evidence suggesting that the efficacy of these treatments is greater when specific therapies are matched according to whether the patient is in a manic or depressive episode and the outcomes desired [1].
Table 1 Core elements of LGCC Model. LGCC domain
Core elements
Options for adaptation
Self Management
.
Bipolar Disorder facts Setting personal goals . Active discussions of symptom coping strategies . Provider engagement and communication tips
.
.
.
Care Management
Decision Support
Ongoing patient contacts to reinforce lessons from self-management . Provider contacts (cues) . Crisis management . Registry tracking . Community resources Simplified Guidelines: . General psychiatric care . Metabolic and toxicology monitoring .
Handling missed sessions (visit, phone) Frequency of self-management lessons (4 or more) . Group vs. one-on-one sessions . Family involvement . Cultural tailoring . Crisis intervention protocols
.
Provider communication preferences
Link to existing services Pocket reminders . Outline of guidelines . Mode of delivery (e.g. senior clinician, in-service presentations, Health Specialist) . .
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Table 2 Examples of adapted LGCC features customized for bipolar disorder by episodic stage. Episodic stage
General medical providers (PCPs)
Mental health provider
Health specialist
Pre-manic phase
Guidelines on understanding and addressing warning signs of manic phase (e.g. adherence lapses, unstable social behaviour, indiscretion) PCP contacts HS if patient appears at risk for manic phase
Treatment for mania
Referral to psychiatric support
Manic/post-manic phase Depressive phase
HS contacts providers to offer support, assist in patient follow-up Recognizing suicidal ideation
Post-depressive phase (e.g. euthymic)
Metabolic syndrome, obesity screening
Crisis management, hospitalization Referral to psychiatric support Referral to substance use treatment if needed
Psychotic episode
Mood stabilizer toxicity monitoring Substance use disorder screening Mood stabilizer toxicity monitoring PCP training in addressing psychosis
Psychosis treatment
Follows up with patient more aggressively Refer to MHS Suicide prevention; ongoing support Ongoing support
Referral to MHS
PCP ¼ primary care provider; MHS ¼ mental health specialist; HS ¼ Health Specialist.
Care management The key element of care management is performed by a Health Specialist to encourage and support a collaborative relationship between consumers and their providers. Life Goals care management combines the CCM components of delivery system design and clinical information systems. Delivery system design refers to building the capacity to support collaborative care and patient self-management by
implementing practices that provide better coordination between all members of a consumers care team. The Health Specialist practises care management by educating consumers on how to come prepared for medical visits with providers, monitoring both consumer treatment adherence and response, and providing feedback to providers about patient progress so that any needed changes in a consumers management plan can be made in a timely manner. For
Table 3 Theoretical constructs informing the content and delivery of the LGCC Model. Social cognitive theory constructs
Topics adapted for self-management for chronic conditions
.
Establishing relevance
.
.
Self-monitoring habits and symptoms Setting goals Turning goals into habits Problem-solving around barriers
.
Addressing lapses and relapses Working with behavioural cues
.
.
.
Developing a social support system
.
. . .
.
. . .
.
.
Psycho-education about self-management and chronic health conditions (physical and mental health) Symptom management Making an action plan Feedback and problem solving Making treatment decisions (understanding medications) Working with and informing health care professionals Advance Directives (for example, psychosis or hospitalization for CVD) Healthy eating, exercise, and sleep Suicide, substance abuse, anxiety
Motivational enhancement counselling strategies .
Patient-centred communication
Elicit intrinsic motivation * Values clarification * Open-ended questions * Establish importance and self-efficacy * Affirm positive steps . Roll with resistance .
Explore ambivalence Use reflective listening * Weigh pros and cons . Avoid didactic format * Ask evocative questions to engage group/individual expertise * Ask permission to share information * *
Collaborative Care
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Table 4 Self-management programme addressing medical treatment in bipolar disorder*. Session
Topics taken from the Life Goals Programme
Topics added to LGCC
Session 1: orientation
Establish therapeutic relationship; bipolar symptoms and psychosis; causes of bipolar disorder; prevalence, stigma, substance abuse
Session 2: mania
Recognize manic symptoms; personal mania symptom profile; identify triggers of mania (for example, substance abuse); active discussion of cost benefits of coping strategies
Session 3: depression
Recognize depressive symptoms; personal depressive symptom profile; identify triggers of coping strategies; association between substance abuse and suicide risk
Session 4: treatment adherence and setting long-term goals for bipolar disorder and CVD-related risk management
Provider engagement focused on collaborative treatment; medications; psychosocial therapies; personal care plan; treatment adherence
Causes of CVD risk factors amongst persons with bipolar disorder; impact of bipolar symptoms on functioning and role with physical health; common treatments for CVD-related conditions and importance of treatment adherence Medical consequences of mania; behavioural consequences of manic symptoms related to CVD risk (for example, binge eating); active discussions: benefits of coping with manic symptoms in the context of CVD risk; setting diet and exercise goals Medical consequences of depression; behavioural consequences of depressive symptoms (overeating, sedentary lifestyle); active discussions: benefits of coping with depressive symptoms in the context of CVD risk; maintaining diet and exercise goals (exercise regimens, walking, portion control, and reduced fat intake) Tips to promote healthy habits (sleep, diet, and exercise); provider engagement: facilitating communication with general medical providers (for example, setting goals for blood pressure and cholesterol, listing personal concerns, and discussing possible medication side effects); contingency planning to overcome relapses from personal wellness goals
Table adapted with permission from Psychiatric Services, 59: 760–768. (Copyright 2008) American Psychiatric Association.
example, the Health Specialist contacts patients to set up the group sessions. After the completion of these sessions, Health Specialists follow up with patients on a monthly basis over the phone to reinforce self-management lessons and check on their overall clinical and treatment status. Additional phone calls will be made to follow up in the event of a hospitalization or emergency room visit, and/or if patients missed appointments and to encourage rescheduling. Through these calls, the Health Specialist can routinely ask about side effects, adherence and other bipolar disorderrelated treatment concerns, and provide crisis counselling and referral (e.g. during manic episodes) when needed. The Health Specialist practises care management by educating consumers on how to come prepared for medical visits with providers, monitoring both consumer treatment adherence and response, and providing feedback to providers about patient progress so that any needed changes in a consumers management plan can be made in a timely manner. Care management also includes facilitating consumerprovider communication by relaying pertinent bipolar symptom issues or medical problems to providers. The Health Specialists serve as a liaison between the patients and providers, and are primarily responsible for contacting
the patients provider if the patient has an urgent concern during a telephone follow-up call (e.g. risk of manic episode). The LGCC care management component is designed to supplement existing services at the site. Specifically, the Health Specialists contacts supplement what the clinician is already providing for the patient, by facilitating access to treatment and following up between visits and contacting clinicians or the mobile crisis team in the event of an acute episode or suicidal ideation. The LGCC manual outlines protocols for the Health Specialist to clarify contact procedures with clinicians based on site policies, including providers preferred mode of communication (e.g. e-mail, phone) and guidelines for triaging concerns patients may express over the phone (e.g. routine, urgent and emergent). The third component of LGCC care management is the use of clinical information systems to monitor and track a patients symptoms and health outcomes over time. The Health Specialists use an electronic registry to record information on patients clinical and functional status in a standardized fashion for tracking patient contact. Registries are specific databases containing information on a cohort of patients who are being followed and managed, and are designed to provide timely and accurate information about
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patient health status and care progress [51]. The LGCC registry is based on a Microsoft (MS) Access file format used by the Robert Wood Johnson Depression in Primary Care Program [51]. Health Specialists can use the registry to track: (1) care received at recent visits (e.g. medications, visits); (2) patient telephone contacts, with summaries of discussion of symptoms, side effects, adherence and other issues; (3) provider communication, including prompts to send secure e-mail or faxed reminders to providers regarding needed follow-up; (4) whether patient concerns were addressed by providers; and (5) upcoming appointments and whether they were attended by patients. One master file includes general information on each patient, including contact numbers. A separate series of files is also created for each individual patient and will allow the Care Managers to record each contact. This information is then accessible and allows for more timely updates and feedback for providers, regardless of whether a clinic or network has a centralized electronic medical record system.
Decision support The LGCC element of decision support aims to improve providers knowledge and skills about evidence-based care for persons with bipolar disorder. LGCC Health Specialists build a decision support system by facilitating access to bipolar disorder treatment information. The Health Specialist acts as an informationist, listening to the needs of providers, and then locating and distributing the requested information. For example, Health Specialists might provide information or references on specific health topics related to bipolar disorder for providers, depending on the providers needs and interests. As an informationist, the Health Specialists can also disseminate resources to support adherence to clinical practice guidelines [39,81] in the form of pocket cards, flow sheets, electronic media, and so on, for bipolar, including medical care clinical practice guidelines for cardiovascular and diabetes risk factor evaluation and psychotropic drug toxicity monitoring [38].
Conclusion The LGCC can potentially improve the quality of care for patients with bipolar disorder, because it involves organizational changes in health care delivery that promote improved health care coordination and collaboration [54,55]. These changes may benefit patients with bipolar disorder, because many of them function effectively enough to not require ongoing ICM. Still, the increased risk of medical comorbidity in bipolar disorder warrants improved coordination of care from multiple providers (e.g. psychiatrists and primary care providers) [14]. To date, only three randomized controlled trials based on the CCM have been implemented for bipolar disorder [52,53,70,74] and only one
of them focused on management of medical conditions. CCM-based models for managing medical care for patients with chronic mental illnesses need to be tested, as existing strategies [50,59], because the implementation of primary care teams in mental health clinics are too costly for network-model health plans. A number of large multisite trials are currently testing the LGCC model in a variety of settings, including VA mental health clinics and community-based mental health organizations. It is hoped that these trials will not only provide greater insight into the specific aspects of the LGCC model that provide benefit to patients and health care organizations, but also shed light on ways to disseminate the programme to diverse contexts without losing programme fidelity or effectiveness.
References 1. Miklowitz, D.J. (2008) Adjunctive psychotherapy for bipolar disorder: state of the evidence. Am. J. Psychiatry, 165, 1408–1419. 2. Horvitz-Lennon, M., Kilbourne, A.M. and Pincus, H.A. (2006) From silos to bridges: meeting the general health care needs of adults with severe mental illnesses. Health Affairs (Millwood), 25, 659–669. 3. Wagner, E.H., Austin, B.T. and Von Korff, M. (1996) Organizing care for patients with chronic illness. Milbank Q., 74, 511–544. 4. Judd, L.L. and Akiskal, H.S. (2003) The prevalence and disability of bipolar spectrum disorders in the US population: re-analysis of the ECA database taking into account subthreshold cases. J. Affect. Disord., 73, 123–131. 5. Robins, L.N. and Regier, D.A. (1991) Psychiatric Disorders in America. The Epidemiologic Catchment Area Study, The Free Press, New York, NY. 6. Bauer, M., Unutzer, J., Pincus, H.A. et al. (2002) Bipolar disorder. Ment. Health Serv. Res., 4, 225–229. 7. Bauer, M.S., Kirk, G.F., Gavin, C. et al. (2001) Determinants of functional outcome and healthcare costs in bipolar disorder: a high-intensity follow-up study. J. Affect. Disord., 65, 231–241. 8. Bryant-Comstock, L., Stender, M. and Devercelli, G. (2002) Health care utilization and costs among privately insured patients with bipolar I disorder. Bipolar Disord., 4, 398–405. 9. Murray, C.J. and Lopez, A.D. (1997) Global mortality, disability, and the contribution of risk factors: Global Burden of Disease Study. Lancet, 349, 1436–1442. 10. Hawton, K., Sutton, L., Haw, C. et al. (2005) Suicide and attempted suicide in bipolar disorder: a systematic review of risk factors. J. Clin. Psychiat., 66, 693–704. 11. Merikangas, K.R., Akiskal, H.S., Angst, J. et al. (2007) Lifetime and 12-month prevalence of bipolar spectrum disorder in the National Comorbidity Survey replication. Arch. Gen. Psychiatry, 64, 543–552. 12. Bartels, S.J., Forester, B., Miles, K.M. et al. (2000) Mental health service use by elderly patients with bipolar disorder and unipolar major depression. Am. J. Geriatr. Psychiatry, 8, 160–166.
Collaborative Care 13. Peele, P.B., Xu, Y. and Kupfer, D.J. (2003) Insurance expenditures on bipolar disorder: clinical and parity implications. Am. J. Psychiatry, 160, 1286–1290. 14. Kupfer, D.J. (2005) The increasing medical burden in bipolar disorder. JAMA, 293, 2528–2530. 15. Simon, G.E. and Unutzer, J. (1999) Health care utilization and costs among patients treated for bipolar disorder in an insured population. Psychiatr. Serv., 50, 1303–1308. 16. Kilbourne, A.M., Cornelius, J.R., Han, X. et al. (2004) Burden of general medical conditions among individuals with bipolar disorder. Bipolar Disord., 6, 368–373. 17. Sokal, J., Messias, E., Dickerson, F.B. et al. (2004) Comorbidity of medical illnesses among adults with serious mental illness who are receiving community psychiatric services. J. Nerv Ment. Dis., 192, 421–427. 18. Roshanaei-Moghaddam, B. and Katon, W. (2009) Premature mortality from general medical illnesses among persons with bipolar disorder: a review. Psychiatr. Serv., 60, 147–156. 19. Angst, F., Stassen, H.H., Clayton, P.J. et al. (2002) Mortality of patients with mood disorders: follow-up over 34–38 years. J. Affect. Disord., 68, 167–181. 20. McElroy, S.L. (2004) Diagnosing and treating comorbid (complicated) bipolar disorder. J. Clin. Psychiat., 65 (Suppl. 15), 35–44. 21. Department of Health, Education, and Welfare Medical Practice Project (1979) A State-of-the-Science Report for the Office of the Assistant Secretary for the U.S. Department of Health, Education, and Welfare. Baltimore, MD, Policy Research. 22. Baldessarini, R.J. (2002) Treatment research in bipolar disorder: issues and recommendations. CNS Drugs, 16, 721–729. 23. Keck, P.E. Jr, McElroy, S.L., Strakowski, S.M. et al. (1997) Compliance with maintenance treatment in bipolar disorder. Psychopharmacol. Bull., 33, 87–91. 24. el-Serag, H.B., Kunik, M., Richardson, P. et al. (2002) Psychiatric disorders among veterans with hepatitis C infection. Gastroenterology, 123, 476–482. 25. Rosenberg, S.D., Goodman, L.A., Osher, F.C. et al. (2001) Prevalence of HIV, hepatitis B, and hepatitis C in people with severe mental illness. Am. J. Public Health, 91, 31–37. 26. Kilbourne, A.M., Reynolds, C.F. 3rd, Good, C.B. et al. (2005) How does depression influence diabetes medication adherence in older patients? Am. J. Geriatr. Psychiatry, 13, 202–210. 27. Fagiolini, A., Kupfer, D.J., Houck, P.R. et al. (2003) Obesity as a correlate of outcome in patients with bipolar I disorder. Am. J. Psychiatry, 160, 112–117. 28. McElroy, S.L., Kotwal, R., Malhotra, S. et al. (2004) Are mood disorders and obesity related? A review for the mental health professional. J. Clin. Psychiat., 65, 634–651, quiz 730. 29. Caykoylu, A., Capoglu, I., Unuvar, N. et al. (2002) Thyroid abnormalities in lithium-treated patients with bipolar affective disorder. J. Int. Med. Res., 30, 80–84. 30. Masand, P.S. and Gupta, S. (2002) Long-term side effects of newer-generation antidepressants: SSRIS, venlafaxine, nefazodone, bupropion, and mirtazapine. Ann. Clin. Psychiatry, 14, 175–182.
|
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31. Misra, M., Papakostas, G.I. and Klibanski, A. (2004) Effects of psychiatric disorders and psychotropic medications on prolactin and bone metabolism. J. Clin. Psychiat., 65, 1607–1618. 32. Newcomer, J.W. (2007) Metabolic considerations in the use of antipsychotic medications: a review of recent evidence. J. Clin. Psychiat., 68 (Suppl. 1), 20–27. 33. Druss, B.G., Bradford, D.W., Rosenheck, R.A. et al. (2000) Mental disorders and use of cardiovascular procedures after myocardial infarction. JAMA, 283, 506–511. 34. Desai, M.M., Rosenheck, R.A., Druss, B.G. et al. (2002) Mental disorders and quality of diabetes care in the veterans health administration. Am. J. Psychiatry, 159, 1584–1590. 35. Druss, B.G., Rosenheck, R.A., Desai, M.M. et al. (2002) Quality of preventive medical care for patients with mental disorders. Med. Care, 40, 129–136. 36. Druss, B.G. and Rosenheck, R.A. (2000) Locus of mental health treatment in an integrated service system. Psychiatr. Serv., 51, 890–892. 37. Faulkner, L.R., Bloom, J.D., Bray, J.D. et al. (1986) Medical services in community mental health programs. Hosp. Community Psychiatry, 37, 1045–1047. 38. American Diabetes Association, American Psychiatric Association, American Association of Clinical Endocrinologists et al. (2004) Consensus development conference on antipsychotic drugs and obesity and diabetes. Diabetes Care, 27, 596–601. 39. American Psychiatric Association (2002) Practice guideline for the treatment of patients with bipolar disorder (revision). Am. J. Psychiatry, 159, 1–50. 40. Bradford, D.W., Kim, M.M., Braxton, L.E. et al. (2008) Access to medical care among persons with psychotic and major affective disorders. Psychiatr. Serv., 59, 847–852. 41. Busch, A.B., Huskamp, H.A. and Landrum, M.B. (2007) Quality of care in a Medicaid population with bipolar I disorder. Psychiatr. Serv., 58, 848–854. 42. Kessler, R.C., Merikangas, K.R. and Wang, P.S. (2007) Prevalence, comorbidity, and service utilization for mood disorders in the United States at the beginning of the twenty-first century. Annu. Rev. Clin. Psychol., 3, 137–158. 43. Kilbourne, A.M., Bauer, M.S., Han, X. et al. (2005) Racial differences in the treatment of veterans with bipolar disorder. Psychiatr. Serv., 56, 1549–1555. 44. Bauer, M.S., McBride, L., Shea, N. et al. (1997) Impact of an easy-access VA clinic-based program for patients with bipolar disorder. Psychiatr. Serv., 48, 491–496. 45. Koran, L.M., Sox, H.C. Jr, Marton, K.I. et al. (1989) Medical evaluation of psychiatric patients. I. Results in a state mental health system. Arch. Gen. Psychiatry, 46, 733–740. 46. Pincus, H.A. (2003) The future of behavioral health and primary care: drowning in the mainstream or left on the bank? Psychosomatics, 44, 1–11. 47. Kilbourne, A.M., Schulberg, H.C., Post, E.P. et al. (2004) Translating evidence-based depression management services to community-based primary care practices. Milbank Q., 82, 631–659. 48. Wagner, E.H., Austin, B.T., Davis, C. et al. (2001) Improving chronic illness care: translating evidence into action. Health Affairs (Millwood), 20, 64–78.
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49. Casalino, L.P. (2005) Disease management and the organization of physician practice. JAMA, 293, 485–488. 50. Druss, B.G., Rohrbaugh, R.M., Levinson, C.M. et al. (2001) Integrated medical care for patients with serious psychiatric illness: a randomized trial. Arch. Gen. Psychiatry, 58, 861–868. 51. Kilbourne, A.M., McGinnis, G.F., Belnap, B.H. et al. (2006) The role of clinical information technology in depression care management. Adm. Policy Ment. Health, 33, 54–64. 52. Kilbourne, A.M., Post, E.P., Nossek, A. et al. (2008) Improving medical and psychiatric outcomes among individuals with bipolar disorder: a randomized controlled trial. Psychiatr. Serv., 59, 760–768. 53. Kilbourne, A.M., Post, E.P., Nossek, A. et al. (2008) Service delivery in older patients with bipolar disorder: a review and development of a medical care model. Bipolar Disord., 10, 672–683. 54. Bauer, M.S., Williford, W.O., Dawson, E.E. et al. (2001) Principles of effectiveness trials and their implementation in VA Cooperative Study #430: Reducing the efficacyeffectiveness gap in bipolar disorder. J. Affect. Disord., 67, 61–78. 55. Simon, G.E., Ludman, E., Unutzer, J. et al. (2002) Design and implementation of a randomized trial evaluating systematic care for bipolar disorder. Bipolar Disord., 4, 226–236. 56. Drake, R.E., McHugo, G.J., Clark, R.E. et al. (1998) Assertive community treatment for patients with co-occurring severe mental illness and substance use disorder: a clinical trial. Am. J. Orthopsychiat., 68, 201–215. 57. Torrey, W.C., Drake, R.E., Dixon, L. et al. (2001) Implementing evidence-based practices for persons with severe mental illnesses. Psychiatr. Serv., 52, 45–50. 58. Burns, T., Creed, F., Fahy, T. et al. (1999) Intensive versus standard case management for severe psychotic illness: a randomised trial. UK 700 Group. Lancet, 353, 2185–2189. 59. Quinlivan, R., Hough, R., Crowell, A. et al. (1995) Service utilization and costs of care for severely mentally ill clients in an intensive case management program. Psychiatr. Serv., 46, 365–371. 60. Lave, J.R., Frank, R.G., Schulberg, H.C. et al. (1998) Costeffectiveness of treatments for major depression in primary care practice. Arch. Gen. Psychiatry, 55, 645–651. 61. Simon, G.E., VonKorff, M., Rutter, C. et al. (2000) Randomised trial of monitoring, feedback, and management of care by telephone to improve treatment of depression in primary care. BMJ, 320, 550–554. 62. Golomb, B.A., Pyne, J.M., Wright, B. et al. (2000) The role of psychiatrists in primary care of patients with severe mental illness. Psychiatr. Serv., 51, 766–773. 63. Findlay, S. (1999) Managed behavioral health care in 1999: an industry at a crossroads. Health Affairs (Millwood), 18, 116–124. 64. Frank, R.G., Huskamp, H.A. and Pincus, H.A. (2003) Aligning incentives in the treatment of depression in primary care with evidence-based practice. Psychiatr. Serv., 54, 682–687. 65. Bazelton Center for Mental Health Law (2004) Get It Together: How to integrate physical and mental health care for people with serious mental disorders. Washington, D.C.
66. Katon, W., Von Korff, M., Lin, E. et al. (1999) Stepped collaborative care for primary care patients with persistent symptoms of depression: a randomized trial. Arch. Gen. Psychiatry, 56, 1109–1115. 67. Daumit, G.L., Pratt, L.A., Crum, R.M. et al. (2002) Characteristics of primary care visits for individuals with severe mental illness in a national sample. Gen. Hosp. Psychiat., 24, 391–395. 68. Bauer, M.S. and McBride, L. (2003) Structured Group Psychotherapy for Bipolar Disorder: The Life Goals Program, 2nd edn, Springer Publishing Co., New York, NY. 69. Bauer, M.S. (2001) The collaborative practice model for bipolar disorder: design and implementation in a multi-site randomized controlled trial. Bipolar Disord., 3, 233–244. 70. Bauer, M.S., McBride, L., Williford, W.O. et al. (2006) Collaborative care for bipolar disorder: Part II. Impact on clinical outcome, function, and costs. Psychiatr. Serv., 57, 937–945. 71. Bauer, M.S., McBride, L., Williford, W.O. et al. (2006) Collaborative care for bipolar disorder: Part I. Intervention and implementation in a randomized effectiveness trial. Psychiatr. Serv., 57, 927–936. 72. Lorig, K.R., Sobel, D.S., Ritter, P.L. et al. (2001) Effect of a selfmanagement program on patients with chronic disease. Eff. Clin. Pract., 4, 256–262. 73. Bauer, M.S., Vojta, C., Kinosian, B. et al. (2000) The Internal State Scale: replication of its discriminating abilities in a multisite, public sector sample. Bipolar Disord., 2, 340–346. 74. Simon, G.E., Ludman, E.J., Bauer, M.S. et al. (2006) Long-term effectiveness and cost of a systematic care program for bipolar disorder. Arch. Gen. Psychiatry, 63, 500–508. 75. Bauer, M.S., Kilbourne, A.M., Greenwald, D.E. et al. (2008) Overcoming Bipolar Disorder: A Comprehensive Workbook for Managing Your Symptoms & Achieving Your Life Goals, New Harbinger Publications, Inc., Oakland, CA. 76. Bandura, A. (1996) Social Foundations of thought and Action: A Social Cognitive Theory, Prentice Hall, Englewood Cliffs, NJ. 77. Rollnick, S., Miller, W.R. and Butler, C.C. (2008) Motivational Interviewing in Health Care: Helping Patients Change Behavior, The Guilford Press, New York. 78. Lorig, K.R., Sobel, D.S., Ritter, P.L. et al. (2001) Effect of a selfmanagement program on patients with chronic disease. Eff. Clin. Pract., 4, 256–262. 79. Pearson, M.L., Mattke, S., Shaw, R. et al. (November 2007) Patient Self-Management Support Programs: An Evaluation. Final Contract Report (Prepared by RAND Health under contract No. 282-00-0005) Rockville, MD, Agency for Healthcare Research and Quality, AHRQ Publication No. 08-0011. 80. Duan, N., Braslow, J.T., Weisz, J.R. et al. (2001) Fidelity, adherence, and robustness of interventions. Psychiatr. Serv., 52, 413. 81. Suppes, T., Dennehy, E.B., Hirschfeld, R.M. et al. (2005) The Texas implementation of medication algorithms: update to the algorithms for treatment of bipolar I disorder. J. Clin. Psychiat., 66, 870–886.
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Bipolar Disorder in Women Benicio N. Frey1, Karine A. Macritchie2, Claudio N. Soares1 and Meir Steiner1 1
Department of Psychiatry and Behavioural Neurosciences, McMaster University and Womens Health Concerns Clinic, St. Josephs Healthcare, Hamilton, ON, Canada 2 Institute of Mental Health, Department of Psychiatry, University of British Columbia, Vancouver, BC, Canada
Introduction The course of bipolar illness in women generally differs from that in men, with a greater risk of chronic depressive symptoms, mixed episodes and rapid cycling disorder. Moreover, women with bipolar disorder may face difficult treatment decisions with potential impact on their own welfare and that of their children, in addition to overall emotional and physical challenges of pregnancy, childbirth and new motherhood. This chapter includes a summary of the course of bipolar illness in women and a description of the interplay between the illness and the stages of their reproductive life. Also, the nature and management of reproductive health issues in bipolar disorder including pregnancy, the puerperium and the menopause are critically reviewed.
Bipolar I and II and rapid cycling disorder in women The prevalence of bipolar I disorder is equal between men and women [1] but differences have been well-documented regarding clinical presentation and symptoms clustering. Amongst bipolar I sufferers, women are over-represented in the group who experience dysphoric rather than euphoric mania [2]. Women are at greater risk of depressive episodes, mixed states and sub-syndromal symptoms than of pure mania [3,4]. Bipolar II disorder, which often presents with more chronic depressive symptoms [5], occurs more frequently in women than in men [6,7]. Illness onset may be later in women than in men (see [8] for review), but women with bipolar disorder also face longer periods of unrecognized and therefore untreated (or inappropriately treated) illness [6,9,10]. Rapid cycling disorder is thought to be more prevalent in women [9], although some studies have questioned this
Bipolar Disorder: Clinical and Neurobiological Foundations Edited by Lakshmi N. Yatham and Mario Maj © 2010 John Wiley & Sons, Ltd. ISBN: 978-0-470-72198-8
observation [11]. Rapid cycling is associated with bipolar II disorder and with hypothyroidism [12], both of which are more common in women. Interestingly, in the recent French Epiman study of patients with bipolar I mania, no gender difference was found in the prevalence of rapid cycling disorder [13]. The increased incidence of rapid cycling in women may reflect poorer response to treatment. Women may also be more vulnerable to antidepressant associated cycling in comparison to men [14]. It is also possible that due to diagnostic delay, women received antidepressant treatment without mood stabilization for longer periods, leading to an increase in their risk of rapid cycling [9].
Suicide Unlike in the general population, completed suicide rates between men and women with bipolar disorder are comparable. Tondo et al. [15] reviewed reports of suicide in bipolar subjects over 56 years. Osby et al. [16] conducted a study on mortality outcomes in over 15 000 bipolar patients. In both studies, the average standardized mortality ratios for suicide in bipolar men and women were similar, or higher in women [17]. Puerperal psychosis may be one of the contributing factors to increased risk of suicide amongst bipolar women. In the United Kingdom, The Confidential Enquiries into Maternal Deaths between 1997 and 1999 [18] found that in more than a quarter of cases, mothers died by suicide, making it the leading cause of maternal mortality. This study revealed that most women who died suffered from an abrupt onset of a psychotic illness in the days following childbirth [19].
Psychiatric and medical comorbidity in women with bipolar disorder Medical and psychiatric comorbid conditions are more common in women. Physical comorbidities, notably thyroid disorders [7,20,21], migraine [21] and obesity (see [8] for review) occur more frequently in bipolar women than in
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their male counterparts. Weight gain in the first year of lithium treatment may be a predictor of subclinical hypothyroidism, a side effect more prevalent in women than in men [22]. Higher rates of post-traumatic stress disorder and bulimia in bipolar women have also been reported [7]. Bipolar disorder is associated with high rates of alcohol and substance abuse: the risk for bipolar women appears to be 4 to 7 times greater than that of the general female population [23,24]. Substance abuse is similarly higher in bipolar women than in womenin the general population [23]. In summary, women with bipolar disorder are more likely to suffer from depressive and mixed episodes and are at greater risk of rapid-cycling disorder than men. Comorbid conditions are more prevalent amongst bipolar women and their risk of suicide is comparable if not greater than that of men, with the puerperal period being a time of significant greater risk.
The reproductive life cycle in women with bipolar disorder Menarche, the puerperium and the menopause are associated with an increased risk of affective disturbance in women with bipolar disorder [25]. In this section, we first discuss the interplay between the stages of a womans reproductive life and the course of bipolar disorder; in addition, current avenues of research regarding underlying neuroendocrine mechanisms are outlined. Finally, we address important points regarding the clinical management of perinatal and menopausal issues in this population.
Menarche and the menstrual cycle The prevalence of depression in women is twice that of men, a difference that is most evident during reproductive years [26]. Women carry a heavier depressive burden, not only with respect to the episodes they experience in bipolar I disorder but also the chronicity of the depressive symptoms associated with bipolar II disorder. The difference in bipolar II disorder prevalence is evident in the years following puberty [27], which is consistent with overall observations about gender differences in affective disorders [28,29].
Mood changes related to menstrual phases The premenstrual and menstrual phases of the cycle are associated with increased rates of hospitalization and suicide in women with primary affective illnesses (see [30] for brief review). In one study, two-thirds of women with bipolar I disorder reported pre-menstrual mood changes: a minority reported depressive symptoms whereas the majority described anger, irritability and mood lability [21]. Premenstrual syndrome is a condition with minor mood changes and physical symptoms, such as breast tenderness
and abdominal bloating [31]. Premenstrual dysphoric disorder (PMDD) is a much more severe condition, associated with distressing emotional and behavioural symptoms. Although its prevalence (3–9% of reproductive-aged women) has been systematically documented, PMDD still is described under research diagnostic criteria in the DSM-IV [32]. Symptoms are confined to the luteal phase of the menstrual cycle and are of sufficient severity to cause psychosocial impairment. Mood symptoms include depression, irritability, anxiety and mood swings. Other somatic and psychological symptoms may occur, such as sleep and appetite disturbances, concentration difficulties, fatigue, headache, bloating and breast tenderness. PMDD appears to be associated with abnormalities of the serotonin system, a system that interacts closely with gonadal hormones (see [33] for review). Angst et al. [34] reported an association between perimenstrual psychological symptoms and formal mood and anxiety disorders, including brief depression, depression and dysthymia, but not bipolar II disorder. In bipolar disorder, PMDD may be difficult to distinguish from a premenstrual exacerbation of the underlying affective disorder. Managing symptoms of PMDD in the context of bipolar disorder may be problematic; after all, SSRI antidepressants – with proven efficacy and wide use for the management of PMDD – may exacerbate manic symptoms. Steiner et al. [35] studied the effects of lithium on severe premenstrual tension, but found that this treatment was of no significant clinical value. Jacobsen [36], on the other hand, reported that three of eight women with premenstrual syndrome responded to low doses of valproate. The effect of the menstrual phase on mood in women with rapid-cycling bipolar disorder is uncertain: the putative association between rapid cycling disorder and pre-menstrual depressive symptoms has not been confirmed in prospectively conducted studies (e.g. [37,38]).
Hormonal contraception and exogenous sex steroids The effect of hormonal contraception on mood in healthy women remains unclear, as studies vary with respect to doses and preparations of oestrogens and progesterone used, methodology and study population. Interestingly, a recent review concluded that although most women on oral hormonal contraception experience a reduction in mood changes across their menstrual cycle, there may be a subgroup of women who experience negative mood symptoms associated with hormone use [39]. This subgroup would have a higher prevalence of premenstrual mood symptoms, a past history of depression prior to hormonal contraceptive treatment and a history of pregnancy-related mood symptoms. Progesterone-only contraceptive preparations have also been linked with depression, with higher depressive
Bipolar Disorder in Women
scores being observed amongst women who opted for discontinuing trials of Norplant (levonorgestrel) and Depo-provera (medroxyprogesterone acetate) [40,41]. Whether sex steroids have an iatrogenic or therapeutic role in bipolar disorder is not clear. One naturalistic study reported continuous circular bipolar disorder in a third of perimenopausal women [42]. Oestrogen augmentation of antidepressant treatment was associated with the onset of rapid cycling in a woman with a severe, treatmentresistant depression [43]; in another case, rapid-cycling was abolished when oestrogens and progesterones were administered [44]. Price and Giannini [45] described the successful treatment of a depressed woman with oestrogen and imipramine. In a study of the menstrual cycle in bipolar women, those taking oral hormonal contraception did not report significant mood changes across the menstrual cycle when compared to those not receiving hormones [46]. A recent placebo-controlled pilot study on the anti-oestrogen tamoxifen reported a significant anti-manic effect [47]. The aetiological and therapeutic contributions of sex steroids for the exacerbation and/or treatment of affective symptoms require further systematic investigation.
Pregnancy For women with bipolar disorder, pregnancy is not protective against episode recurrence. In a prospective observational study, 71% of bipolar women suffered recurrence during pregnancy: most episodes were mixed or depressive in character [48]. Puerperal psychosis occurs after 25–50% of deliveries in bipolar mothers, a much higher than expected rate compared to the general population [19]. What mechanisms underlie this complex relationship between reproductive events and affective symptoms? The potential interactions between the hypothalamic-pituitaryadrenal (HPA) and the hypothalamic-pituitary-gonadal (HPG) axes and female affective dysregulation are promising areas of interest [49]. Preliminary evidence indicates that even before their illness is recognized, women with bipolar disorder may be at increased risk of HPG dysfunction. Delayed menarche, early menopause, irregular cycles and oligomenorrhoea may be more prevalent in bipolar women compared to healthy women or women with unipolar depression [50]. Dysrhythmic luteinizing hormone pulsatility has been described in premenopausal depressed women [51]. There are reports of low oestradiol in the follicular phase in women with major depressive disorder ([52]). One small pilot study of bipolar depressed women found a non-significant reduction in oestradiol levels [46]. With regard to the HPA axis, hypersecretion of cortisol occurs in depressed and manic phases of bipolar disorders [53,54]. During euthymic periods, abnormalities of the HPA axis can be documented with the use of dexameth-
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asone/CRH testing [55]. The role of the thyroid system has also been investigated (see [56] for review). Further studies are still required to better explore potential gender differences in the functioning of these systems in bipolar patients. Both fluctuating gonadal and adrenal steroids have a large spectrum of neuromodulatory actions including the genomic transcription of elements in most major neurotransmitter systems. It has been speculated that large shifts in gonadal hormone levels that occur at puberty, in pregnancy and in the puerperium may adversely affect neurotransmitter systems. Important changes may also occur throughout the menstrual cycle and during the menopausal transition. Since neuroendocrine systems are responsive to physiological and psychological stress, the interaction between hormonal and neurotransmitter systems may be altered in women with bipolar disorders; if so, the precise nature of a heightened vulnerability to affective recurrence remains to be clarified (see [33] for review).
The management of the pregnancy of a bipolar women The management of pregnancy in a mother with bipolar disorder requires careful planning. Women and their partners may have questions regarding the heritability of this psychiatric illness, their fertility status and the existing evidence of reproductive safety/toxicity of current mood stabilizing medications available. Moreover, the puerperium constitutes a period of significant increase risk for relapse. Lastly, there are questions and concerns about neonates experiencing adverse effects from maternal medication withdrawal or toxicity at the time of birth, or from exposure to medication through the breast milk.
Pre-pregnancy planning Women with bipolar disorder should be informed and reminded of the necessity of pre-conceptual counselling and planning for pregnancy. Sadly, women with chronic mental illness undergo more induced abortions than do their healthy counterparts and are more likely to be exposed to high risk sexual practices [57]. Family planning and other sexual health services should be an integrated part of their programme of care. The effectiveness of contraceptive agents – oestrogen and progesterone, or progesterone only formulations – may be reduced by medications that induce hepatic P450 3A4 enzyme activity, such as carbamazepine and topiramate. Oral contraceptives with higher doses of ethinylestradiol may be considered, if no other form of contraception is available. Preliminary evidence suggests that lamotrigine plasma concentration may be significantly decreased with the use of combined oral contraception, possibly due to the oestrogen component. Theoretically, adverse symptoms
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may occur during the pill-free period and on stopping contraceptive treatment. Lamotrigine may reduce the levels of progestogens, but the clinical significance of this remains unclear (see [58] for recent review). It is not uncommon to hear reports of bipolar women being discouraged to conceive by health professionals and by family members. In a group of women seeking advice on pregnancy at a perinatal psychiatry programme, more than half of questionnaire respondents reported that they had been advised against pregnancy by doctors or a family member [59]. After receiving information offered by the programme, 63% of the group chose pursue pregnancy. This study highlighted the importance of correct information and counselling. For those who chose not to attempt pregnancy, their decision was most often based on the adverse effects of medication on foetal development or the fear of illness recurrence. Clearly, education of and support for family members, including the patients partner, is also imperative. The association of bipolar disorder with fertility status is not clearly established; one study found that fertility rates were reduced before and after the onset of illness in both male and female subjects with bipolar disorder [60]. Women may suffer from sub-fertility due to psychotropic-induced polycystic ovarian syndrome or hyperprolactinaemia, factors which may also increase the risk of osteoporosis [61,62].
General considerations in the treatment of pregnant women with bipolar disorder Ideally, a woman with bipolar disorder should plan her pregnancy so that decisions regarding treatment may be addressed properly. Pharmacological and non-pharmacological treatment options during pregnancy, labour and in the puerperium should be discussed. Consultation and on-going collaboration with patients obstetrician is highly recommended. Practical steps to ease the womans psychosocial burden during her pregnancy and after the birth of her child should be implemented. A realistic challenge, however, derives from the fact that in the general population, more than half of pregnancies are unplanned [63]. Thus, it is not uncommon that a patient with bipolar disorder presents to her psychiatrist after documenting her pregnancy and, quite often, after an abrupt treatment discontinuation. The management of bipolar disorder during pregnancy comprises the individualized assessment of the risks and the benefits of treatment. The risks to the foetus associated with the exposure to psychotropic agents should be carefully considered in combination with the potential risks to the mother and the foetus associated with the exposure to an untreated or recurrent mood illness. It is clear that there is a significant risk of recurrence associated with treatment discontinuation early in pregnancy. In the study by Viguera and colleagues [48], those who
discontinued mood-stabilizer treatment had a two-fold increased risk of recurrence and the median time to recurrence was four times shorter than for those continuing treatment. Furthermore, the number of weeks of illness during pregnancy was five times greater. Almost half of the episodes occurred in the first trimester. Rapid discontinuation of treatment was associated with a dramatically shorter period to recurrence compared to gradual discontinuation: episodes occurred after a period eleven times shorter. Special care should be taken with lithium withdrawal, as this may in itself precipitate recurrence [64,65]. Maternal illness during pregnancy confers substantial perinatal risk to the child. Bonari et al. [66], in their review of the literature on untreated unipolar depression in pregnancy, found an association between untreated depression and pre-term delivery, growth retardation, pre-eclampsia and spontaneous abortion. Prenatal unipolar depression is associated with abnormal foetal physiology, with reduced foetal movements and with abnormal foetal heart rate responsiveness. Adler et al. [67] examined the effects of depression and anxiety during pregnancy: depression and anxiety symptoms were associated with obstetric complications, somatic complaints, pre-term labour and higher need for pain relief in labour. Lack of psychosocial resources, as well as poor emotional and practical support, are reported to increase the likelihood of small for gestational age neonates [68]. Although the direct impact of bipolar affective episodes in pregnancy is under-investigated, women suffering depression or mania may engage in self-neglecting or risk-taking behaviour, they may sleep poorly, be poorly compliant with antenatal care programmes, have poor decision-making capacity and receive inadequate nutrition [66]. They may also increase the use of psychoactive substances for selfmedication purposes: Zuckerman et al. [69] reported an association between depressive symptoms in pregnancy and the use of cigarettes, alcohol and cocaine. All bipolar women, particularly those who decide against psychotropic maintenance treatment during pregnancy, should be closely monitored for recurrence of affective symptoms, suicidal intent, deteriorating social functioning and substance abuse.
Pharmacological treatment during pregnancy A womans decision to take medication during pregnancy depends largely on the harmful potential of the medication in question, the stage of her pregnancy and her individual risk of affective recurrence upon withdrawing treatment. Women may be best advised to remain on treatment in certain circumstances, such as history of multiple recurrent episodes after treatment discontinuation, severe or difficult to treat illness or history of self-harm. The management of a recurrent episode during pregnancy may involve exposure to more medications or higher doses than regular,
Bipolar Disorder in Women
maintenance treatment. Those who have managed to remain well without medication for significant periods of time in the past may as well be able to come off treatment during part of the pregnancy or throughout the gestational period. The foetus is exposed to maternally-ingested psychotropics in several ways, including placental transfer and ingestion of amniotic fluid. Somatic teratogenicity and organ dysgenesis are not the only concerns when prescribing in pregnancy. Others potential risks include intrauterine foetal death, impaired foetal growth, neonatal toxicity and withdrawal symptoms. Recently, longer-term effects of exposure on behaviour, cognitive and emotional regulatory function have become evident. Long-term metabolic effects remain to be investigated.
Teratogenicity, intrauterine growth effects and neurobehavioural sequelae Accumulating data on the harmful effects of psychotropic agents are available from birth registries and cohort studies. Most registries are now prospective in design, and include data both on pregnancies in which treatment has been used, and treatment in which it has been withheld [70]. Some case control studies also exist, but randomized controlled trials of agents in pregnancy are not considered to be ethical. In many cases, especially in those of relatively new agents, the risk/benefit ratio of a medication is not yet established. The risk of rare but important adverse effects may take some years to emerge and may require the study of a very large number of cases and controls. Thus, the safety profile of a given agent may change as more information becomes available: advice on both old and new psychotropic medications may alter over time. Of note, the US Food and Drugs Administration has not licensed any psychotropic agents for use during pregnancy. In some countries, information and advice is available from national specialist centres. Published guidelines exist on prescribing psychotropic medication in pregnancy, such as the American College of Obstetricians and Gynecologists [71] and the National Institute of Clinical Excellence in England and Wales [72]. Specific guidelines for women with bipolar disorder are also available [72,73]. However, reproductive safety data is continually updated, and so the most upto-date expert advice should be sought. A summary of key issues to be considered in prescribing mood stabilizers during pregnancy is presented below. Readers are referred to the guidelines cited above for more detailed guidance on patient management and to the practical overview of adverse effects of psychotropic use in pregnancy by Wieck [74]. Lithium use in the first trimester has been associated with congenital abnormalities, particularly those of the cardiovascular system, including Ebsteins anomaly. Ebsteins anomaly is a condition where the tricuspid valve is
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displaced into the right ventricle, which is dysplastic: other cardiac malformations may also be present [75]. In the general population, it occurs at a rate of between 1 per 20, 000 live births [74] and 1 in 200 000 [75]. The condition is a serious one, requiring corrective surgery and associated with high mortality. Morphogenesis of the heart chambers is in process in the fourth week of pregnancy and the tricuspid valve is developed in the third month [76], soon after the pregnancy is discovered. Heart defects in the general population occur at a rate of 8 in 1000 of live births [74]. The risk ratio for all cardiac malformations following lithium exposure is estimated to be between 1.2 and 7.7 [77]. Currently, rates of Ebsteins anomaly are estimated at between 1 in 1000 and 1 in 2000 neonates exposed to lithium in the first trimester [77], but further studies are required to clarify the risk data on these important issues (see [74] for review). Lithium-exposed infants have been reported to weigh significantly more than control subjects [78]. Despite the evidence of potential teratogenic risks associated with Lithium exposure, the absolute risk remains low and treatment maintenance should be carefully considered for patients with more severe, chronic conditions. Much of the existing data on the exposure to anticonvulsants and its obstetric and neonatal outcomes derives from women with epilepsy. Overall, the major malformation rates associated with valproate use are significantly higher than those of carbamazepine and lamotrigine. The malformation rate is also increased when multiple medications are administered, particularly when valproate is used [79]. The structural development of the central nervous system occurs very early in pregnancy: the neural tube closes by the end of the fourth week [80]. The rate of neural tube abnormalities in the general population of the United States is 1 in 1000 [80]. Valproate exposure in pregnancy has been reported to increase the rate to 1/50–1/100 [81]. The risk of neural tube defects with valproate may be dose-related [82], and a foetal valproate syndrome with stereotypical craniofacial features has been described [83]. Other congenital malformations may occur separately or as part of the syndrome: these include cardiac, urogenital, skeletal and skin-muscle abnormalities (see [84] for review). There is evidence that the use of valproate during pregnancy may be associated with a significant reduction in the childs cognitive functioning. For instance, recent work reported that 22% of children with in utero exposure to valproate had an exceptionally low verbal IQ compared with the expected 2% in the general population children [85]. In utero exposure to valproate has been implicated in autistic spectrum disorder [86]. Recent guidelines [71,72] recommend that valproate should be avoided in pregnancy. In view of its link with polycystic ovary syndrome and the high incidence of unplanned pregnancy in adolescent girls,
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NICE [72] recommend that its use should also be avoided in girls who are under 18 years of age. First trimester exposure to carbamazepine is associated with a 1% risk of spina bifida [87], compared to the rate of 1 in 1000 in the general population. Elevated risks of craniofacial abnormalities and microcephaly [88], cleft palate and abnormalities of the urinary tract and cardiovascular system [89] have also been reported. Carbamazepine may cause vitamin K deficiency in the infant, requiring vitamin K administration in the neonatal period [90]. It is recommended that exposure to carbamazepine, especially in the first trimester of pregnancy, should be avoided [71,72]. Folic acid supplements are thought to reduce the incidence of neural tube defects [91]. Larger doses of folic acid (5 mg/day) are recommended for cases considered to be at high risk for neural tube defects (See [72]). This may be extended to women on anticonvulsants with folate antagonism. A Hungarian study of case-control congenital abnormality data found evidence to support folic acid supplementation between 5 and 12 weeks from the last menstrual period: it decreased but did not eliminate the risk of neural tube defects resulting from first trimester anticonvulsant exposure [92]. Supplements should be taken from three months prior to conception until 12 weeks of gestation [72,74]. Recently, there have been reports of an increase in the relative risk of oral clefts [70] with the use of lamotrigine in pregnancy. The risk of congenital malformations with this medication is reported to be increased at doses higher than 200 mg/day and when used in combination with valproate [79]. However, the ACOG guidelines [71] refer to the growing reproductive safety profile of lamotrigine in comparison to other mood-stabilizing agents. In contrast, NICE [72] recommend that lamotrigine should not be routinely used in pregnancy for the treatment of bipolar disorder, given the risks listed above and the limited evidence for its efficacy in bipolar disorder. As a general recommendation, women exposed to lithium or to anticonvulsants in early pregnancy should be offered careful screening for foetal anomalies, including high resolution ultrasound examination. Previous studies and reviews have tentatively suggested an overall increased risk of malformations associated with the use of older antipsychotics [93,94]. In a recent prospective, matched-case control study of 151 women exposed to atypical antipsychotics, the only significant difference in pregnancy outcome was with respect to low birth weight and more therapeutic abortions [95]. However, data on individual antipsychotic medications remain limited [72]. Olanzapine has been associated with weight gain, gestational glucose intolerance and diabetes and pre-eclampsia (see [73]). Preliminary data suggests that some antipsychotics may be associated with increased infant birth weight [96].
A more detailed review of antidepressant medications in pregnancy is beyond the scope of this review; overall, most experts in reproductive and perinatal psychiatry believe that exposure to SSRIs during pregnancy poses a small, manageable risk for adverse obstetric and neonatal outcomes; nonetheless, spontaneous abortion, pre-term delivery, low birth weight, respiratory distress and persistent pulmonary hypertension have been reported after prenatal exposure to some SSRI agents [72,97]. Paroxetine exposure in the first trimester of pregnancy may increase the risk of congenital malformations, especially the risk of atrial and ventricular septal defects [98]. The recent ACOG guidelines [71] recommend that paroxetine is avoided in pregnancy, and that foetal echocardiography should be considered in cases of exposure in early pregnancy. Although tricyclic antidepressants are thought to be presently the lowest known risk in pregnancy (see [99] for brief review), SSRIs are less likely to be associated with switching to mania: for this reason, it has been recommended that SSRIs (but not paroxetine) are used for women with bipolar disorder [72].
Pharmacokinetic changes during pregnancy Physiological changes that occur in pregnancy potentially alter maternal serum concentrations of psychotropic medications. In particular, a larger volume of distribution with increased body fat, plasma volume and total body water may result in decreased serum concentrations for a given dose. Decreased protein binding capacity increases serum free drug concentrations. Increased hepatic metabolism of certain psychotropic agents may occur, and dose adjustment in pregnancy may be required ([84]). Renal clearance increases during pregnancy with glomerular filtration rates. If a woman is receiving lithium during pregnancy, the dose may need to be increased as renal clearance increases during pregnancy [100] (see [73] for further guidance on managing lithium in pregnancy and the postpartum period). Great care is required with lithium and several other potentially toxic agents when pre-pregnancy pharmacokinetics resume speedily in the postpartum period. Neonatal toxicity and withdrawal symptoms The neonate may suffer symptoms of maternal drug withdrawal, toxicity or both. However, neonatal symptoms may be of some other, non-pharmacological aetiology, hence a comprehensive clinical assessment is essential [101]. Symptoms and signs of lithium toxicity include low APGAR scores, lethargy, hypotonia, apnoea, respiratory distress syndrome, cyanosis and bradycardia in the newborn [102]. The risk of lithium toxicity may be reduced if the serum lithium level is lowered to less than 0.3 mEq/l for at
Bipolar Disorder in Women
least 24–48 hours before parturition [103]. Other neonatal toxic effects include goitre with hypothyroidism, cardiac arrhythmias, cardiomegaly, nephrogenic diabetes and liver dysfunction [104]. The effects of in utero exposure to anticonvulsants may manifest in sedation; some neonates may develop hyperexcitability as a sign of withdrawal [105]. Foetal distress during labour and neonatal distress has also been reported following maternal treatment with valproate [106]. There are a small number of reports of valproate toxicity in the neonate with hepatic or haematological effects [104]. Carbamazepine exposure may lead to transient cholestatic hepatitis and reduced cord blood vitamin D levels [104]. Neonatal abnormalities following maternal treatment with risperidone have been described, with some symptoms consistent with a withdrawal syndrome [107]. Neonates exposed to tricyclics, selective serotonin reuptake inhibitors (SSRIs) and serotonin-norepinephrine reuptake inhibitors (SNRIs) antidepressants during gestation are also at increased risk of neonatal withdrawal syndrome; most of these symptoms are, however, transient and should not guide physicians to reduce the use/dose of antidepressants amongst high risk mothers prior to delivery (see [99] for review).
Electroconvulsive therapy Several guidelines recommend electroconvulsive therapy (ECT) as a primary treatment for severe acute episodes of bipolar disorder during pregnancy [72,108]. NICE [72] recommend this treatment only when the physical health of the mother or her child is at risk. There are no controlled trials comparing the efficacy and safety of ECT with any other treatments for bipolar affective episodes in pregnancy. Its associated risks and complications are described in case reports in the literature. Miller [109] reviewed 300 case reports over 49 years: complications occurred in 28 cases. Miscarriage, vaginal bleeding and premature birth have occurred in cases where ECT was administered in the first trimester [110]. There are also reports of pre-term labour, utero-placental insufficiency, placental abruption and transient, self-limited disturbances in foetal cardiac rhythm and uterine contractions [111,112]. Pregnant women also face an enhanced risk of regurgitation and aspiration of gastric contents and compression of the aorta and inferior cava [111]. Thus, when considering the use of ECT, these risks should be discussed with the patient and balanced against the risks of the illness itself and the risk of alternative drug treatments. There are practical safety measures that should be undertaken in administering an anaesthetic and ECT to a pregnant patient: these are outlined by Rabheru [111]. ECT may be especially effective for post-natal psychosis (see below).
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Psychotherapeutic, psychoeducation and psychosocial interventions Psychotherapy, psychosocial interventions and psycho-education, if used efficaciously, could reduce the requirement for pharmacological treatment during pregnancy. However, few studies specifically address these interventions for pregnant women with affective disorders. Preliminary data from one open trial suggest that interpersonal psychotherapy is an effective treatment for antepartum depression [113], and data from a controlled trial support its use in postnatal depression [114]. Similarly, one controlled trial exists in support of cognitive behavioural therapy in postnatal depression [115]. Psychotherapy in bipolar disorder is discussed in more detail in a different section of this book. To date, there are no randomized controlled trials that specifically examine psychotherapy alone as a treatment for bipolar disorder, either in the context of an acute episode or as maintenance treatment. For a woman with bipolar disorder, pregnancy may bring concerns regarding the future, the effects of her illness on her child, her medication, the progress of her pregnancy, interpersonal difficulties and psychosocial burdens: these women may well benefit from psychological and practical support in these circumstances. Family-focused treatment aiming to educate the patient and their family about bipolar disorder and to improve communication and problemsolving may also prove helpful.
The postpartum in women with bipolar disorder It has long been recognized that the postpartum is a period of heightened risk for relapse, especially in women with bipolar disorder. The rates of recurrence of a given mood episode range between 25 and 50% but this rate can increase up to 65–70% when considering women with previous history of postpartum episodes [116]. Some studies have suggested that the risk of having a postpartum episode is higher in women with bipolar disorder, as compared to women with schizophrenia or major depressive (unipolar) disorder. No other time in life poses a higher risk than the postpartum period. Whereas the reasons why such risk may be particularly higher in bipolar disorder are unknown, it is imperative for the clinician to investigate a potential diagnosis of bipolar disorder in women with postpartum depression or psychosis. Similarly, postpartum women with bipolar disorder must be carefully monitored during the puerperium. The presence of mood symptoms during pregnancy is one of the strongest predictors of a subsequent postpartum episode and some preliminary studies have suggested that genetic vulnerability and the abrupt decrease in ovarian hormones may be implicated [19,117].
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Postpartum psychosis occurs after about 10–20% of deliveries in women with bipolar disorder [118,119], which is 100–200 times higher than the risk observed in the general population. It is considered a medical emergency because it is associated with significant cognitive impairment and higher risk for infanticide and suicide. This is illustrated in a study conducted in the United Kingdom, showing that suicide accounted for 10% of maternal deaths between 1994 and 1996, the largest cause of postpartum deaths during the study period [120]. Thus, postpartum psychosis requires immediate intervention and possible hospital admission in order to guarantee the safety for the mother and the infant. As the symptoms subside with appropriate treatment, the contact with the baby can be restored under 24-hour supervision until the risk for infanticide is considered no more existent. Importantly, a number of studies demonstrated that postpartum prophylaxis with mood stabilizers reduces the risk for a postpartum episode, although the optimal time to begin the prophylaxis has not been clearly defined [48]. Maternal postpartum depression or psychosis are associated with increased family disruption and adverse effects on infant development, including postnatal complications, increased newborn cortisol and catecholamine levels and higher rates of admission to neonatal intensive care units. Discontinuation or change in treatment regimen during the postpartum period may increase the risk for relapse and the presence of other risk factors, such as history and severity of previous postpartum episodes should be taken into account. When the risk for relapse is considered high and the treatment regimen is considered incompatible with breastfeeding, bottle-feeding can be a safe alternative for both mother and baby. There is a general consensus amongst experts suggesting the mothers health should take priority over the feeding method of the infant. Given that sleep disruption is one of the major factors associated with mood symptoms, it may be useful for a bipolar mother who is breastfeeding to ask for another person to bottle-feed the baby during the night and resume breastfeeding in the next morning. The advantages of breastfeeding to infants and mothers are well established, thus the decision to recommend or not breastfeeding should also consider the benefits and the risks of medication exposure. The majority of medications have been detected in the breast milk, albeit usually at significant lower levels than levels detected in the mother plasma, and available evidence suggest that for most of the psychotropics studied breast milk and infant serum levels are highly variable and are difficult to predict [121,122]. Therefore, measuring serum levels in the infant is usually not recommended. Infants of mothers that use psychotropic medications should be monitored and breastfeeding should be immediately stopped in case a nursing infant displays adverse symptoms potentially related to medication exposure. As a general rule, the use of the lowest effective dosage and limiting the
number of medications can minimize the infants exposure. When necessary, higher dosage of a single medication is preferable over use of multiple medications. The selection of the treatment should also consider history of previous medication efficacy and available safety information. The American Academy of Pediatrics [123] classifies most psychotropic medications as drugs for which the effect on nursing infants is unknown but may be of concern, especially because follow-up studies assessing long-term effects of psychotropics on neurodevelopment in exposed infants are lacking. The use of lithium during breastfeeding is contraindicated and the use of valproic acid and carbamazepine are considered compatible with breastfeeding. Table 1 depicts a list of psychotropic drugs according to the classification from the American Academy of Pediatrics [123] and the Lactation Risk Category [124].
Menopause and menopausal transition Although a number of community-based, longitudinal studies have demonstrated that the transition to menopause is a period of higher risk for new onset and recurrent depression, there is very little information about the impact of menopausal transition on the course of bipolar disorder. Some studies found that women are more likely than men to develop bipolar disorder between 45 and 49 years old, which coincides with the time when most women are approaching menopause [9]. Thus, some women may be particularly vulnerable to develop bipolar disorder during a period of intense hormonal fluctuation, as observed during the menopausal transition. Other studies suggested that this period may be associated with intense emotional instability for those suffering from bipolar disorder. For instance, Kukopulos et al. [42] found that 33% of women with bipolar disorder became continuous circular during menopausal transition. This is consistent with two studies that investigated peri- and postmenopausal women with bipolar disorder, showing that about 20–50% of bipolar women experienced intense affective disturbances (depression, mania, irritability or agitated anxiety) during the menopausal transition [21,25]. One of these studies also found that women using hormone replacement therapy (HRT) were less likely to report mood worsening than those not on HRT [25], suggesting that hypothesis linking intense hormone fluctuations to mood instability [125] may be also true for bipolar disorder. A recent longitudinal study conducted with 47 women between 45 and 55 years old enroled in the systematic treatment enhancement programme for bipolar disorder (STEP-BD) found that during the 17 14 months of follow-up, 68% of peri-menopausal women experienced a major depressive episode, while 23% experienced mood elevation [127]. Interestingly, the frequency of depressive episodes was increased during the peri-menopausal years
Bipolar Disorder in Women Table 1 Psychotropic medications in pregnancy and breastfeeding. Medications
Pregnancy risk categorya
American academy of pediatrics ratingb
Lactation risk categoryc
Lithium carbonate
D
L4
Valproic Acid Carbamazepine Lamotrigine Aripiprazole Clozapine
D D C C B
Olanzapine Quetiapine
C C
Risperidone Ziprasidone
C C
Haloperidol
C
Chlorpromazine
C
Fluphenazine Loxapine Perphenazine
C C C
Pimozide Thioridazine Trifluoperazine
C C C
Fluoxetine
C
Contraindicated Compatible Compatible Unknown N/A Unknown, of concern N/A Unknown, of concern N/A Unknown, of concern Unknown, of concern Unknown, of concern N/A N/A Unknown, of concern N/A N/A Unknown, of concern Unknown, of concern
Fluvoxamine
C
Sertraline
C
Citalopram Escitalopram
C C
Paroxetine
D
Bupropion
B
Mirtazapine Nefazodone Duloxetine Trazodone
C C C C
Venlafaxine Zolpidem Zaleplon
C B C
Unknown, of concern Unknown, of concern N/A N/A Unknown, of concern Unknown, of concern N/A N/A N/A Unknown, of concern N/A N/A Unknown, of concern
L2 L2 L3 L3 L3 L2 L4 L3 L4
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Medications
Pregnancy risk categorya
American academy of pediatrics ratingb
Lactation risk categoryc
Eszopiclone Alprazolam
C D
N/A L3
Chlordiazepoxide Clonazepam Diazepam
D D D
Lorazepam
D
Oxazepam Estazolam Flurazepam Triazolam Temazepam
D X X X X
N/A Unknown, of concern N/A N/A Unknown, of concern Unknown, of concern N/A N/A N/A N/A Unknown, of concern
L3 L3 L3, L4 if used chronically L3 L3 L3 L3 L3 L3
a
L2 L3 L3 L4 N/A L4 L4 N/A L2 in older infants, L3 if used in neonatal period L2 L2 L3 L3 in older infants L2 L3 L3 L4 N/A L2 L3 L3 L2
FDA categories: A ¼ controlled studies show no risk; B ¼ no evidence of risk in humans; C ¼ risk cannot be ruled out; D ¼ positive evidence of risk; X ¼ contraindicated in pregnancy [126]. b American Academy of Pediatrics [123]. c Lactation risk categories: L1 ¼ safest; L2 ¼ safer; L3 ¼ moderately safe; L4 ¼ possibly hazardous; L5 ¼ contraindicated [124].
as compared to their self-reported pre-menopausal years. No differences between pre- and peri-menopausal years were observed in terms of frequency of mood elevations, suggesting that menopausal transition may confer a higher risk for depression but not mania/hypomania for women with bipolar disorder. Lastly, Robertson Blackmore et al. [128] assessed 109 women with bipolar disorder and history of postpartum psychosis and found that 5 out of 17 (29%) of those who were post-menopausal developed a major affective episode during menopausal transition. In sum, accumulating evidence suggests that the intense hormonal variation observed during the transition to menopause may be associated with increased risk for a major mood episode, especially depression, in women with bipolar disorder. Here it is worth mentioning that most studies are small and retrospective. Large prospective studies are necessary to better explore this potential association. In addition, current diagnostic classifications do not investigate the relationship between major mood episodes and womens milestones such as menstrual cycle, pregnancy and menopause, which may difficult their clinical characterization and adequate management [129].
Conclusions (continued )
The course of bipolar illness in women differs from that observed in men, with a greater risk of chronic depressive
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symptoms, mixed episodes and rapid cycling disorder. Bipolar II disorder, which is marked by the presence of major depressive episodes, is also more frequent in women. Furthermore, comorbid medical and psychiatric conditions, such as thyroid disease, migraines, obesity, anxiety and eating disorders occur more frequently in bipolar women than men. However, although such gender differences have been recognized, little is known about the underlying mechanisms that contribute to gender differences in bipolar disorder and whether these differences ultimately influence response to treatment. There is accumulating evidence showing that menarche, postpartum and menopausal transition are associated with an increased risk of affective disturbances in women with bipolar disorder but its aetiology is unclear. The relationship between HPG, HPA dysfunction and affective episodes is a promising hypothesis that warrants further investigation. Oestrogen and progesterone are known to regulate monoamine neurotransmission [130,131] and intracellular signalling systems involved with neuronal plasticity and survival [132]. Futures studies are warranted to determine whether the cross-link between sex hormones and intracellular pathways are relevant in the clinical presentation of bipolar disorder in women. The concept that pregnancy exerts a protective effect against recurrence of affective episodes has been clearly refuted in recent studies. A substantial proportion of bipolar women may experience a relapse during pregnancy, with the risk of relapse being reduced with mood-stabilizing treatment. The management of bipolar illness in pregnancy is of utmost importance and the risk of exposure to an untreated, recurrent maternal illness to mother and child should be weighed against potential risks due to foetal exposure to pharmacological agents. Women with affective disorders should receive special supervision in pregnancy. All bipolar women, particularly those who decide against psychotropic maintenance treatment during pregnancy, should be closely monitored for recurrence of affective symptoms, suicidal intent and deteriorating social functioning. Bipolar patients should be particularly encouraged to comply with their programme of antenatal care. In treating an affective episode during pregnancy, the clinician should consider pharmacological, psychotherapeutic, psycho-educative interventions and practical measures. The decision to continue or interrupt pharmacological treatment during pregnancy is not risk free. Most importantly, information on reproductive safety and obstetric and neonatal outcomes are constantly updated, particularly for newer agents. The postpartum is a period of particular risk for onset and recurrence of major mood and psychotic episodes in women with bipolar disorder. Postpartum episodes are often abrupt and typically occur within the first week after delivery. Although it has been postulated that the abrupt
decrease of sex hormones trigger postpartum episodes, the exact underlying mechanisms are still to be determined. Women with postpartum episodes must be closely monitored due to higher risk of suicide and infanticide. In addition, the risks/benefits of prophylactic and therapeutic agents should be individualized in order to optimize the health of the mother and decrease as much as possible the newborn exposure to potential effects of medication. Lastly, the few studies that investigated the course of bipolar disorder during transition to menopause suggest that this period may be associated with higher risk for depressive episodes, which is consistent with existing data on unipolar disorder [133]. However, most studies are small and of retrospective nature. A particular challenge derives from the lack of information on womens reproductive status in current semi-structured diagnostic interviews. The development of new DSM-IV-based instruments that include aspects pertaining womens reproductive life (e.g. pre-menstrual exacerbation of mood symptoms, onset or recurrence of symptoms during pregnancy and peri-menopause) is long overdue.
References 1. Goodwin, F.K. and Jamison, K.R. (eds) (2007) Epidemiology; subsection Gender, Chapter 8, in ManicDepressive Illness, Oxford University Press, New York, p. 181. 2. McElroy, S.L., Keck, P.E. Jr, Pope, H.G. Jr et al. (1992) Clinical and research implications of the diagnosis of dysphoric or mixed mania or hypomania. Am. J. Psychiatry, 149, 1633–1644. 3. Angst, J. (1978) The course of affective disorders II. Typology of bipolar manic-depressive illness. Arch. Psychiat. Nerven., 226, 65–73. 4. Suppes, T., Mintz, J., McElroy, S.L. et al. (2005) Mixed hypomania in 908 patients with bipolar disorder evaluated prospectively in the Stanley Foundation Bipolar Treatment Network: a sex-specific phenomenon. Arch. Gen. Psychiatry, 62, 1089–1096. 5. Judd, J.L., Akiskal, H.S., Schettler, P.J. et al. (2003) A prospective investigation of the natural history of the long-term weekly symptomatic status of bipolar II disorder. Arch. Gen. Psychiatry, 60, 261–269. 6. Viguera, A.C., Baldessarini, R.J. and Tondo, L. (2001) Response to lithium maintenance treatment in bipolar disorders: comparison of women and men. Bipolar Disord., 3, 245–252. 7. Baldassano, C.F., Marangell, L.B., Gyulai, L. et al. (2005) Gender differences in bipolar disorder: retrospective data from the first 500 STEP-500 BD participants. Bipolar Disord., 7, 465–470. 8. Arnold, L.M. (2003) Gender differences in bipolar disorder. Psychiat. Clin. N. Am., 26, 595–620. 9. Leibenluft, E. (1996) Women with bipolar illness: clinical and research issues. Am. J. Psychiatry, 153, 163–173.
Bipolar Disorder in Women 10. McElroy, S.L. (2004) Bipolar disorders: special diagnostic and treatment considerations in women. CNS Spectrums, 9 (8 Suppl. 7), 5–18. 11. Tondo, L. and Baldessarini, R.J. (1998) Rapid cycling in women and men with bipolar manic-depressive disorders. Am. J. Psychiatry, 155, 1434–1436. 12. Bauer, M.S., Whybrow, P.C. and Winokur, A. (1990) Rapid cycling bipolar affective disorder. I. Association with grade I hypothyroidism. Arch. Gen. Psychiatry, 47, 427–432. 13. Azorin, J.M., Kaladjian, A., Adida, M. et al. (2008) Factors associated with rapid cycling in bipolar I manic patients: findings from a French national study. CNS Spectrums, 13, 80–87. 14. Yildiz, A. and Sachs, G.S. (2003) Do antidepressants induce rapid cycling? A gender-specific association. J. Clin. Psychiat., 64, 814–818. 15. Tondo, L., Isacsson, G. and Baldessarini, R.J. (2003) Suicidal behavior in bipolar disorder: risk and prevention. CNS Drugs, 17, 491–511. 16. Osby, U., Brandt, L., Correia, N. et al. (2005) Excess mortality in bipolar and unipolar disorder. Paper presented to the annual meeting of the American Psychiatric Association, Atlanta, Cited by Goodwin and Jamison (2008). 17. Goodwin, F.K. and Jamison, K.R. (eds) (2007) Suicide, Chapter 8, in Manic-Depressive Illness, Oxford University Press, New York, p. 251. 18. Lewis, G. and Drife, J. (2001) Why Mothers Die 1997–1999:The fifth report of the Confidential Enquiries into Maternal Deaths in the United Kingdom Publisher: Royal College of Obstetricans and Gynaecologists Press. 19. Jones, I. and Craddock, N. (2005) Bipolar disorder and childbirth: the importance of recognizing risk. Brit. J. Psychiat., 186, 453–454. 20. Kupka, R.W., Nolen, W.A., Post, R.M. et al. (2002) High rate of autoimmune thyroiditis in bipolar disorder: lack of association with lithium exposure. Biol. Psychiatry, 51, 305–311. 21. Blehar, M.C., DePaulo, J.R. Jr, Gershon, E.S. et al. (1998) Women with bipolar disorder: findings from the NIMH Genetics Initiative sample. Psychopharmacol. Bull., 34, 239–243. 22. Henry, C. (2002) Lithium side-effects and predictors of hypothyroidism in patients with bipolar disorder: sex differences. J. Psychiatr. Neurosci., 27, 104–107. 23. Hendrick, V., Althshuler, L.L., Gitlin, M.J. et al. (2000) Gender and bipolar illness. J. Clin. Psychiat., 61, 393–396. 24. Frye, M.A., Altshuler, L.L., McElroy, S.L. et al. (2003) Gender differences in prevalence, risk and clinical correlates of alcoholism comorbidity in bipolar disorder. Am. J. Psychiatry, 60, 883–889. 25. Freeman, M.P., Smith, K.W., Freeman, S.A. et al. (2002) The impact of reproductive events on the course of bipolar disorder in women. J. Clin. Psychiat., 63, 284–287. 26. Weissman, M.M. and Olfson, M. (1995) Depression in women: implications for health care research. Science, 269, 799–801. 27. Wittchen, H.-U., Nelson, C.B. and Lachner, G. (1998) Prevalence of mental disorders and psychosocial impairments in adolescents and young adults. Psychol. Med., 28, 109–126.
|
473
28. Kessler, R.C. and Walters, E.E. (1998) Epidemiology of DSM-III-R major depression and minor depression amongst adolescents in the National Comorbidity Survey. Depress Anxiety, 7, 3–14. 29. Lewinsohn, P.M., Rhode, P. and Seeley, J.R. (1998) Major depressive disorder in older adolescents: prevalence, risk factors and clinical implications. Clin. Psychol. Rev., 18, 765–794. 30. Diamond, S.B., Rubinstein, A.A., Dunner, D.L. et al. (1976) Menstrual problems in women with affective illness. Compr. Psychiat., 17, 541–548. 31. World Health Organization (1996) Mental, behavioural and developmental disorders, in Tenth Revision of the International Classification of Diseases (ICD-10), World Health Organization, Geneva. 32. American Psychiatric Association (1994) DSM-IV: Diagnostic and Statistical Manual of Mental Disorders, 4th edn, American Psychiatric Association, Washington DC, pp. 717–718. 33. Steiner, M., Dunn, E. and Born, L. (2003) Hormones and mood: from menarche to menopause and beyond. J. Affect. Disord., 74, 67–83. 34. Angst, J., Sellaro, R., Merikangas, K.R. et al. (2001) The epidemiology of perimenstrual psychological symptoms. Acta Psychiatr. Scand., 104, 110–116. 35. Steiner, M., Haskett, R.F., Osmun, J.N. et al. (1980) Treatment of premenstrual tension with lithium carbonate. Acta Psychiatr. Scand., 61, 96–102. 36. Jacobsen, F.M. (1993) Low-dose valproate: a new treatment for cyclothymia, mild rapid cycling disorders and premenstrual syndrome. J. Clin. Psychiat., 54, 229–234. 37. Leibenluft, E., Ashman, S.B., Feldman-Naim, S. et al. (1999) Lack of relationship between menstrual cycle phase and mood in a sample of women with rapid cycling bipolar disorder. Biol. Psychiatry, 46, 577–580. 38. Shivakumar, G., Bernstein, I.H., Suppes, T. et al. (2008) Are bipolar mood symptoms affected by the phase of the menstrual cycle? J. Womens Health, 17, 473–478. 39. Oinonen, K.A. and Mazmanian, D. (2002) To what extent do oral contraceptives influence mood and affect? J. Affect. Disord., 70, 229–240. 40. Westhoff, C., Truman, C., Kalmuss, D. et al. (1998) Depressive symptoms and Norplant contraceptive implants. Contraception, 57, 241–245. 41. Westhoff, C., Truman, C., Kalmuss, D. et al. (1998) Depressive symptoms and Depo-Provera. Contraception, 57, 237–240. 42. Kukopulos, A., Reginaldi, D., Laddomada, P. et al. (1980) Course of the manic-depressive cycle and changes caused by treatment. Pharmakopsych. Neuro., 13, 156–167. 43. Oppenheim, G. (1984) A case of rapid mood cycling with estrogen: implications for therapy. J. Clin. Psychiat., 45, 34–35. 44. Chouinard, G., Steinberg, S. and Steiner, W. (1987) Estrogenprogesterone combination: another mood stabilizer? Am. J. Psychiatry, 144, 826. 45. Price, W.A. and Giannini, A.J. (1985) Antidepressant effects of estrogen. J. Clin. Psychiat., 46, 506.
474
|
Chapter 36
46. Rasgon, N., Bauer, M., Glenn, T. et al. (2003) Menstrual cycle related mood changes in women with bipolar disorder. Bipolar Disord., 5, 48–52. 47. Kulkarni, J., Garland, K.A., Scaffidi, A., Headey, B., et al. (2006) A pilot study of hormone modulation as a new treatment for mania in women with bipolar affective disorder. Psychoneuroendocrinology, 31, 543–547. 48. Viguera, A.C., Whitfield, T., Baldessarini, R.J. et al. (2007) Risk of recurrence in women with bipolar disorder during pregnancy: prospective study of mood stabilizer discontinuation. Am. J. Psychiatry, 164, 1817–1824. 49. Dorn, L.D. and Chrousos, G.P. (1997) The neurobiology of stress: understanding regulation of affect during female biological transitions. Semin. Reprod. Endocrinol., 15, 19–35. 50. Joffe, H., Kim, D.R., Foris, J.M. et al. (2006) Menstrual dysfunction prior to onset of psychiatric illness is reported more commonly by women with bipolar disorder than by women with unipolar depression and healthy controls. J. Clin. Psychiat., 67, 297–304. 51. Meller, W., Grambsch, P., Bingham, C. et al. (2001) Hypothalamic-pituitary-gonadal axis dysregulation in depressed women. Psychoneuroendcrinology, 26, 253–259. 52. Young, E. and Korzun, A. (2002) The hypothalamicpituitary-gonadal axis in mood disorders. Endocrin. Metab. Clin., 31, 63–78. 53. Linowski, P., Vanc Cauter, E., Kerkhofs, M. et al. (1988) Neuroendocrine rhythms in uni- and bipolar depressions. Neurophysiol. Clin., 18, 141–151. 54. Cervantes, P., Gelber, S., Kin, F. et al. (2001) Circadian secretion of cortisol in bipolar disorder. J. Psychiatr. Neurosci., 26, 411–416. 55. Watson, S., Gallagher, P., Ritchie, J.C. et al. (2004) Hypothalamic-pituitary-adrenal axis function in patients with bipolar disorder. Brit. J. Psychiat., 84, 496–502. 56. Bauer, M., Goetz, T., Glenn, T. et al. (2008) The thyroid-brain interaction in thyroid disorders and mood disorders. J. Neuroendocrinol., 20, 1101–1114. 57. Coverdale, J.H., Turbott, S.H. and Roberts, H. (1997) Family planning needs and STD risk behaviours of female psychiatric out-patients. Brit. J. Psychiat., 171, 69–72. 58. Sabers, A. (2008) Pharmacokinetic interactions between contraceptives and antiepileptic drugs. Seizure, 17, 141–144. 59. Viguera, A.C., Cohen, L.S., Bouffard, S. et al. (2002) Reproductive decisions by women with bipolar disorder after prepregnancy psychiatric consultation. Am. J. Psychiatry, 159, 2102–2104. 60. Baron, M., Risch, N. and Mendlewicz, J. (1982) Differential fertility in bipolar affective illness. J. Affect. Disord., 4, 103–112. 61. Haddad, P.M. and Wieck, A. (2004) Antipsychotic-induced hyperprolactinaemia. Mechanisms, clinical features and management. Drugs, 20, 2291–2314. 62. Joffe, H. (2007) Reproductive biology and psychotropic treatments in premenopausal women with bipolar disorder. J. Clin. Psychiat., 68 (Suppl. 9), 10–15. 63. Forest, J.D. (1994) Epidemiology of unintended pregnancy and contraceptive use. Am. J. Obstet. Gynecol., 170 (5 Pt 2), 1485–1489.
64. Mander, A.J. (1986) Is there a lithium withdrawal syndrome? Brit. J. Psychiat., 149, 498–501. 65. Suppes, T., Baldessarini, R.J., Faedda, G.L. et al. (1991) Risk of recurrence following discontinuation of lithium treatment in bipolar disorder. Arch. Gen. Psychiatry, 48, 1082–1088. 66. Bonari, L., Pinto, N., Ahn, E. et al. (2004) Perinatal risks of untreated depression during pregnancy. Can. J. Psychiat., 49, 726–735. 67. Adler, J., Fink, N., Bitzher, J. et al. (2007) Depression and anxiety during pregnancy: a risk factor for obstetric, fetal and neonatal outcome? A critical review of the literature. J. Matern. Fetal Neonatal Med., 20, 189–209. 68. Dejin-Karlsson, E., Hanson, B.S., Ostergren, P.O. et al. (2000) Association of a lack of psychosocial resources and the risk of giving birth to small for gestational age infants: a stress hypothesis. Brit. J. Obstet. Gynaec., 107, 89–100. 69. Zuckerman, B., Amaro, H., Bauchner, H. et al. (1989) Depressive symptoms during pregnancy: relationship to poor health behaviors. Am. J. Obstet. Gynecol., 160, 1107–1111. 70. Viguera, A.C., Koukopoulos, A., Muzina, D.J. et al. (2007) Teratogenicity and anticonvulsants: lessons from neurology to psychiatry. J. Clin. Psychiat., 68 (Suppl. 9), 29–33. 71. American College of Obstetricians and Gynecologists Committee on Practice Bulletins-Obstetrics (2008) ACOG Practice Bulletin: Clinical management guidelines for obstetrician-gynecologists number 92, April 2008. Use of psychiatric medications during pregnancy and lactation. Obstet. Gynecol., 111, 1001–1020. 72. National Institute for Health and Clinical Excellence (2007) Antenatal and postnatal mental health: clinical management and service guidance. London, http://guidance. nice.org.uk/CG45/niceguidance/pdf/English. 73. Yonkers, K.A., Wisner, K.L., Stowe, Z. et al. (2004) Management of bipolar disorder during pregnancy and the postpartum period. Am. J. Psychiatry, 161, 608–620. 74. Wieck, A. (2004) Teratogenic syndromes, in Adverse Syndromes and Psychiatric Drugs: A Clinical Guide (eds P. M. Haddad, S. Dursonand W. Deakin), Oxford University Press, Oxford. 75. Attenhofer Jost, C.H., Connolly, H.M., Dearani, J.A. et al. (2007) Ebsteins anomaly. Circulation, 115, 277–285. 76. Larsen, W.J. (2001) Development of the Heart, Chapter 7, in Human Embryology, 3rd edn (eds L.S. Sherman, S.S. Postter and W.J. Scott), Churchill Livingston Inc., pp. 79–112. 77. Cohen, L.S., Friedman, J.M., Jefferson, J.W. et al. (1994) A re-evaluation of risk of in utero exposure to lithium. JAMA, 271, 146–150. 78. Jacobson, S.J., Jones, K., Johnson, K. et al. (1992) Prospective multicentre study of pregnancy outcome after lithium exposure during first trimester. Lancet, 339 (8792), 530–533. 79. Morrow, J., Russell, A., Guthrie, E. et al. (2006) Malformation risks of antiepileptic drugs in pregnancy: a prospective study from the UK Epilepsy and Pregnancy Register. J. Neurol. Neurosurg. Psychiatry, 77, 193–198. 80. Larsen, W.J. (2001) The Fourth Week, Chapter 4, in Human Embryology, 3rd edn (eds L.S. Sherman, S.S., Postterand W.J. Scott), Churchill Livingston Inc., pp. 79–112.
Bipolar Disorder in Women 81. Lindhout, D. and Schmidt, D. (1986) In-utero exposure to valproate and neural tube defects. Lancet, 1 (8494), 1392–1393. 82. Omtzigt, J.G., Los, F.J., Grobbee, D.E. et al. (1992) The risk of spina bifida aperta after first-trimester exposure to valproate in a prenatal cohort. Neurology, 42 (4 Suppl. 5), 119–125. 83. DiLiberti, J.H., Farndon, P.A., Dennis, N.R. et al. (1984) The fetal valproate syndrome. Am. J. Med. Genet., 19, 473–481. 84. Newport, J.D., Fisher, A., Graybeal, S. et al. (2004) Psychopharmacology during pregnancy and lactation, Chapter 64, in The American Psychiatric Publishing Textbook of Psychopharmacology, 3rd edn (eds et al.), American Psychiatric Publishing Inc., Washington DC, London, England, pp. 1109–1146. 85. Adab, N., Kini, U., Vinten, J. et al. (2004) The longer term outcome of children born to mothers with epilepsy. J. Neurol. Neurosurg. Psychiatry, 75, 1575–1583. 86. Rasalam, A., Hailey, H., Williams, J. et al. (2005) Characteristics of fetal anticonvulsant syndrome associated with autistic disorder. Dev. Med. Child Neurol., 47, 551–555. 87. Rosa, F.W. (1991) Spina bifida in infants of women treated with carbamazepine during pregnancy. N. Engl. J. Med., 324, 674–667. 88. Jones, J.K., Lacro, R., Johnson, K. et al. (1989) Pattern of malformations in the children of women treated with carbamazepine during pregnancy. N. Engl. J. Med., 320, 1661–1666. 89. Matalon, S., Schechtman, S., Goldzweig, G. et al. (2002) The teratogenic effect of carbamazepine: a meta-analysis of 1255 exposures. Reprod. Toxicol., 16, 9–17. 90. Cornelissen, M., Steegers-Theunissen, R., Kollee, L. et al. (1993) Supplementation of vitamin K in pregnant women receiving anticonvulsant therapy prevents neonatal vitamin K deficiency. Am. J. Obstet. Gynecol., 168, 884–888. 91. Lumley, J., Watson, L., Watson, M. et al. (2001) Periconceptional supplementation with folate and/or multivitamins for preventing neural tube defects. Cochrane Database Syst. Rev (2), CD001056. 92. Kjaer, D., Horvath-Puho´, E., Christensen, J. et al. (2008) Antiepileptic drug use, folic acid supplementation, and congenital abnormalities: a population-based case-control study. Brit. J. Obstet. Gynaec., 115, 98–103. 93. Slone, D., Siskind, V., Heinonen, O.P. et al. (1977) Antenatal exposure to the phenothiazines in relation to congenital malformations, perinatal mortality rate, birth weight, and intelligence quotient score. Am. J. Obstet. Gynecol., 128, 486–488. 94. Altshuler, L.L., Cohen, L., Szuba, M.P. et al. (1996) Pharmacologic management of psychiatric illness during pregnancy: dilemmas and guidelines. Am. J. Psychiatry, 153, 592–606. 95. McKenna, K., Koren, G., Tetelbaum, M. et al. (2005) Pregnancy outcome of women using atypical antipsychotic drugs: a prospective comparative study. J. Clin. Psychiat., 66, 444–449. 96. Newham, J.J., Thomas, S.H., MacRitchie, K. et al. (2008) Birth weight of infants after maternal exposure to typical and
97.
98.
99.
100.
101.
102.
103.
104.
105.
106.
107.
108.
109. 110.
111. 112.
113.
|
475
atypical antipsychotics: prospective comparison study. Brit. J. Psychiat., 192, 333–337. Einarson, T.R. and Einarson, A. (2005) Newer antidepressants in pregnancy and rates of major malformations: a meta-analysis of prospective comparative studies. Pharmacoepidemiol. Drug Saf., 14, 823–827. National Teratology Information Service (NTIS) (2005) Use of Paroxetine in Pregnancy, NTIS, Regional Drug and Therapeutics Centre, Newcastle upon Tyne. ter Horst, P.G., Jansman, F.G., van Lingen, R.A. et al. (2008) Pharmacological Aspects of Neonatal Antidepressant Withdrawal. Obstet. Gynecol. Surv., 63, 267–279. Schou, M., Amdisen, A. and Steenstrup, O.R. (1973) Lithium and pregnancy. II: hazards to women given lithium during pregnancy and delivery. Br. Med. J. 2, 137–138. Haddad, P.M., Pal, B.R., Clarke, P. et al. (2008) Neonatal symptoms following maternal paroxetine treatment: serotonin toxicity or paroxetine discontinuation syndrome? J. Psychopharmacol., 19, 554–557. Kozma, C. (2005) Neonatal toxicity and transient neurodevelopmental deficits following prenatal exposure to lithium: Another clinical report and a review of the literature. Am. J. Med. Genet., 132, 441–444. Newport, D.J., Viguera, A.C., Beach, A.J. et al. (2005) Lithium placental passage and obstetrical outcome: implications for clinical management during late pregnancy. Am. J. Psychiatry, 162, 2162–2170. Diav-Citrin, O. and Koren, G. (2007) Direct toxicity to the fetus, Chapter 8, in Medication Safety in Pregnancy and Breastfeeding (ed. G. Koren), McGraw Hill, pp. 85–119. Koch, S., Gopfert-Geyer, I., Hauser, I. et al. (1985) Neonatal behaviour disturbances in infants of epileptic women treated during pregnancy. Prog. Clin. Biol. Res., 163B, 453–461. J€ ager-Roman, E., Diechi, A. and Jakob, S. (1986) Fetal growth, major malformations and minor anomalies in infants born to women receiving valproic acid. J. Pediatr., 108, 997–1004. Coppola, D., Russo, L.J., Kwarta, R.F. Jr et al. (2007) Evaluating the postmarketing experience of risperidone use during pregnancy: pregnancy and neonatal outcomes. Drug Safety, 30, 247–264. American Psychiatric Association Practice Guidelines (2002) Treatment of Patients with Bipolar Disorder, 2nd edn, http://www.psychiatryonline.com/pracGuide/ pracGuideTopic_8.aspx. Miller, L.J. (1994) Use of electroconvulsive therapy during pregnancy. Hosp. Community Psychiatry, 45, 444–450. Morena, M.E., Munoz, J.M., Valderrabanos, J.S. et al. (1998) Electroconvulsive therapy in first trimester of pregnancy. J. ECT, 4, 251–254. Rabheru, K. (2001) The use of electroconvulsive therapy in special patient populations. Can. J. Psychiat., 46, 710–719. National Institute for Health and Clinical Excellence (2003) Electroconvulsive therapy. London, http://www.nice.org. uk/Guidance/TA59/Guidance/pdf/English. Spinelli, M.G. (1997) Interpersonal psychotherapy for depressed antepartum women: a pilot study. Am. J. Psychiatry, 154, 1028–1030.
476
|
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114. OHara, M.W., Stuart, S., Gorman, L.L. et al. (2000) Efficacy of interpersonal psychotherapy for postpartum depression. Arch. Gen. Psychiatry, 57, 1039–1045. 115. Appleby, L., Warner, R., Whitton, A. et al. (1997) A controlled study of fluoxetine and cognitive-behavioural counseling in the treatment of postnatal depression. Br. Med. J., 314, 932–936. 116. Barnes, C. and Mitchell, P. (2005) Considerations in the management of bipolar disorder in women. Aust. NZ J. Psychiat., 39, 662–673. 117. Jones, I., Lendon, C., Coyle, N. et al. (2001) Molecular genetic approaches to puerperal psychosis. Prog. Brain Res., 133, 321–331. 118. Kendell, R.E., Chalmers, J.C. and Platz, C. (1987) Epidemiology of puerperal psychoses. Br. J. Psychiatry, 150, 662–673. 119. Brockington, I.F., Cernik, K.F., Schofield, E.M. et al. (1981) Puerperal psychosis. Phenomena and diagnosis. Arch. Gen. Psychiatry, 38, 829–833. 120. Department of Health, Scottish Home and Health Department (1998). Department of Health and Social Security. Why mothers die: report on confidential enquiries into maternal deaths in the United Kingdom, 1994–1996, London: Stationery Office. 121. Viguera, A.C., Newport, D.J., Ritchie, J. et al. (2007) Lithium in breast milk and nursing infants: clinical implications. Am. J. Psychiatry, 164, 342–345. 122. Newport, D.J., Pennell, P.B., Calamaras, M.R. et al. (2008) Lamotrigine in breast milk and nursing infants: determination of exposure. Pediatrics, 122, e223–e231. 123. American Academy of Pediatrics (2001) Transfer of drugs and other chemicals into human milk. Pediatrics, 108, 776–789. 124. Hale, T.W. (2004) Medications in Mothers Milk. Amarillo (TX): Pharmasoft Publishing.
125. Soares, C.N. (2007) Menopausal transition and depression: who is at risk and how to treat it? Expert Rev. Neurother., 7, 1285–1293. 126. Briggs, G.G., Freeman, R.K. and Yaffe, S. J. (2005) Drugs in pregnancy and lactation. 7th ed. Philadelphia (PA): Lippincott Williams & Wilkins. 127. Marsh, W.K., Templeton, A., Ketter, T.A. and Rasgon, N.L. (2008) Increased frequency of depressive episodes during the menopausal transition in women with bipolar disorder: preliminary report. J. Psychiatr. Res., 42, 247–251. 128. Robertson Blackmore, E., Craddock, N., Walters, J. and Jones, I. (2008) Is the perimenopause a time of increased risk of recurrence in women with a history of bipolar affective postpartum psychosis? A case series. Arch. Womens Ment. Health, 11, 75–78. 129. Soares, C.N. and Zitek, B. (2008) Reproductive hormone sensitivity and risk for depression across the female life cycle: a continuum of vulnerability? J. Psychiatr. Neurosci., 33, 331–343. 130. Deecher, D., Andree, T.H., Sloan, D. and Schechter, L.E. (2008) From menarche to menopause: exploring the underlying biology of depression in women experiencing hormonal changes. Psychoneuroendocrinology, 33, 3–17. 131. McEwen, B.S. (2001) Invited review: Estrogens effects on the brain: multiple sites and molecular mechanisms. J. Appl. Physiol., 91, 2785–2801. 132. Morrison, J.H., Brinton, R.D., Schmidt, P.J. and Gore, A.C. (2006) Estrogen, menopause, and the aging brain: how basic neuroscience can inform hormone therapy in women. J. Neurosci., 26, 10332–10348. 133. Frey, B.N., Lord, C. and Soares, C.N. (2008) Depression during menopausal transition: a review of treatment strategies and pathophysiological correlates. Menopause Int. 14 (3), 123–128.
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Phenomenology and Treatment of Bipolar I Disorder in Children: A Critical Review Gabrielle A. Carlson1 and Elizabeth B. Weller2 1 2
Child and Adolescent Psychiatry, Stony Brook University School of Medicine, Stony Brook, NY, USA Deceased. [Sadly, Elizabeth B. Weller died during preparation of the manuscript]
Introduction Is bipolar I disorder in children continuous with adult bipolar I disorder? This is important, especially insofar as treatment in youth has been extrapolated from treatment in adults. Conversely, what is the outcome of children who have possible manic symptoms and what kinds of interventions are needed to improve those outcomes? These are the bottom-line questions that clinical research needs to address. Unfortunately, we do not as yet have answers. This chapter will focus on bipolar I disorder and mania rather than the broader bipolar spectrum because there are specific criteria for mania, depression and bipolar I. We will also address children, for the most part, because it is children (those younger than age 13) in whom the diagnosis of bipolar disorder is contentious.
The ‘bipolar controversy’ Bipolar I disorder in children has generated a storm of controversy amongst researchers, practitioners and the general public [1]. Although under-diagnosis of bipolar I disorder has been a prominent focus in adult as well as child and adolescent psychiatry, inappropriate diagnosis is also of concern. For example, there is an apparent increase in rates of diagnosed bipolar disorder in youth, such as a 40-fold increase for outpatient claims for children [2] and an increase in discharge diagnoses from 1.4/10 000 to 7.3/ 10 000 in 9–13 year olds using the National Hospital Discharge survey [3]. On the other hand, the psychopharmacology clinic at Massachusetts General Hospital, which has used the same assessment approach for the past 15 years, reported rates of bipolar disorder in their clinic of 16%, relatively unchanged over that time [4]. While this clinic probably diagnoses bipolar disorder more broadly
Bipolar Disorder: Clinical and Neurobiological Foundations Edited by Lakshmi N. Yatham and Mario Maj © 2010 John Wiley & Sons, Ltd. ISBN: 978-0-470-72198-8
than many, their lack of recorded increase in rates of bipolar disorder suggests that consistently diagnosed disorder is not increasing. In addition, the diagnosis as given in the community is highly unstable with almost 30% of children receiving the diagnosis only one time over one year of treatment follow-up [5]. In another study, one-third of children psychiatrically hospitalized for explosive outbursts were given a diagnosis of bipolar disorder in the community but fewer than 10% were found to have the diagnosis [6]. Nor is this problem of over-diagnosis unique to children. In adults, 30% of 700 patients given a DSM IV diagnosis of bipolar disorder did not have the diagnosis when reassessed using the SCID. This over-diagnosis contrasted to the diagnosis being missed in 13% of patients [7]. There has been one community study of children that provides rates of bipolar I disorder. The Great Smoky Mountain Study found no cases of strictly defined bipolar I disorder in 9–13 year olds [8]. We have arrived at the ‘bipolar controversy’ for several reasons. First, unlike ICD, DSM has been largely symptomdriven rather than incorporating illness course into its criteria. That is, obtaining a history has been secondary to establishing individual symptom criteria [9]. Second, the assessment instruments developed to ascertain symptoms are not consistent in how they define episodes of concurrent manic symptoms. Third, child-diagnostic instruments have worked from the ‘top down’ in that they were developed from adult interviews and applied to children rather than being developed from ‘the bottom up’ and starting with a population of children. Therefore, there was little reckoning with the fact that children’s cognitive, language and emotion regulation development need consideration. This is especially evident with the concept of an episode as ‘a change from one’s usual self’ where developmental shifts may preclude a ‘usual self’. A change is much clearer when an episode of mania or depression occurs in an adolescent or adult. Children with well-demarcated periods of abnormal mood and associated behaviour are sufficiently uncommon that clinicians have inferred episodes from relatively
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brief periods of marked behavioural dyscontrol, often in the context of explosive angry outbursts or of silliness that seem excessive and situationally inappropriate. This affective oscillation, which occurs many times a day, is called ultradian cycling [10]. However, mood states that are both transient and display a high degree of reactivity and volatility are often linked to some provocation or frustration, and only rarely come from ‘out of the blue’. Likewise, ‘elation’ may be precipitated by some exciting or highlystimulating event and is therefore not qualitatively inappropriate, though its expression may be excessive for the context. If these moods occur concurrent with other manic symptoms for a sustained period, they can represent a real change from one’s premorbid ‘self’, and characterize a period of mania. However, if one describes the onset of a manic episode as the first appearance of severe tantrums and hyperactivity in early childhood, they are difficult to distinguish from difficult temperaments and other developmental disorders that present in substantial numbers of children very early in life [11]. The conceptual issue awaiting clarification is whether the aforementioned marked behavioural dyscontrol amongst children derives from the same perturbation that drives bipolar disorder symptoms amongst post-pubertal individuals; or rather it characterizes the emotional reactivity that accompanies deficits of executive function that cuts across conditions. In fact, the number of modifications necessary to make a diagnosis of bipolar disorder in children attests to the fact that unmodified DSM IV criteria, with a relatively acute onset of co-occurring elation/irritability with other manic symptoms that has a finite duration and return to preexisting baseline, is uncommon. Lack of consensus on these definitional terms makes it difficult to extrapolate from one sample to the next, one country to the next and from one era to the next. On the other hand, while the degree to which young children have what many have called ‘classic’ manic depression (i.e. a condition with clear episode onset and offset) remains unclear, what is clear is that children selected with severe manic-like symptoms (regardless of how these are defined) are a significantly impaired, highly comorbid group of children. There are three general interview approaches that different research groups in the United States have adopted and although all claim to adhere to DSM IV, they are by no means interchangeable. The Massachusetts General Hospital approach [12] defines mania by extremely severe ‘irritability’ or affective aggression (with or without expansive mood), and with symptoms, basically, of ADHD. Neither developmental level nor corroboration beyond parent historian is required. With that approach, onset at ages two or three are common and offsets may not occur for many years if at all.
The Washington University version of the K-SADS uses what are called developmental modifications of DSM criteria [13]. There are two important issues that preclude easy interpretation of results where that instrument has been used. First, information is not gathered with episodes in mind but only with onset and offset of specific symptoms. It is thus difficult to reconstruct episodes with clear onset and offset. Similarly, although reliability may be obtained with people trained on the interview, there is by no means agreement across institutions on whether the developmental modifications are valid. For instance, children may have difficulties with the concept of elation; increased self-esteem requires an ability to self-assess that has yet to be studied normatively; other developmental and contextual factors may moderate the long-term significance of these characteristics, which parents endorse as ‘meeting the criteria’. Silliness and bravado, which some feel are childhood manifestations of euphoria and grandiosity may also be seen in children with other forms of psychopathology and developmental delays, such as ADHD, pervasive developmental disorders (PDD or social skills deficits [14]. In ADHD and other conditions with impaired executive function, deficient inhibitory control (‘risky behaviour’) is evident in cognition (i.e. distractibility, poor sustained attention), behaviour (e.g. restlessness, overactivity, difficulty keeping conduct in conformity with situational constraints) and emotion (e.g. undermodulated emotional displays) [15]. Deficient impulse control occurs in mania but arises, at least conceptually, from a heightened drive towards pleasurable pursuits, and risky conduct is a ‘downstream’ effect. The third approach has divided bipolar disorder into a classical ‘narrow phenotype’ and another condition called ‘severe mood dysregulation’ (SMD) [16]. The ‘narrow phenotype’ interprets the DSM IV criteria as emphasizing episodes with a clear onset and offset. Within those episodes, symptom definitions are probably similar to those used by other investigators, though that has not been specifically studied. However, SMD is contrasted with episodic irritability/elation and other manic symptoms and is defined by severe, chronic irritability with extreme reactivity to negative stimuli, and symptoms of hyperarousal. Up to 80% of children with SMD meet DSM-IV-TR criteria for both ADHD and oppositional defiant disorder and many have co-occurring anxiety [17]. Rates of SMD appear to be far more common than BP I disorder and was found in 3.3% of respondents in the Great Smoky Mountains study [18]. None of the assessments examine learning or language disorders, mild PDD or specifically describe whether or not exposure to stress or trauma should modify the diagnosis.
Clinical phenomenology Four cases have been described in prior publications that illustrate clinical phenomenology and issues of diagnosis
Bipolar I Disorder in Children: A Critical Review
better than itemizing lists of symptoms with percentages. The reader is encouraged to read the fuller descriptions elsewhere. Two cases are part of a study examining differences in diagnostic approaches between the United States and the United Kingdom [19]. Nicola, the first example, has bipolar I disorder most clearly. She was considered previously fairly well adjusted and over a several week period, developed obvious symptoms of mania. These were evident to her parents, who were horrified at the complete personality change, and also evident to the examiner, and even people sitting next to her in a waiting room, because she was provocatively dressed, elated, spoke rapidly and loudly, was clearly intrusive, hyperactive and grandiose. There was excellent consensus between clinicians in both countries, and when submitted to a panel of different researchers in the United States (unpublished data), there was no disagreement. By contrast, the second girl, Lynda, age 11, had a long history of partially treated ADHD and defiant behaviour. She became increasingly aggressive with protracted temper outbursts when her wishes were thwarted. She was in trouble academically and with peers, and engaged in forbidden activities such as smoking and visiting pornographic Web sites. Parents but not teachers complained of the more manic-like features. In school, she was inattentive and oppositional, and during her interview, she complained of sadness and anger. US clinicians interpreted her increased aggression and antisocial behaviour as the onset of an episode of mania. UK clinicians diagnosed her as having the ICD 10 condition of hyperkinetic conduct disorder [19]. Submitted to a panel of four expert bipolar clinical researchers in the United States (unpublished), two felt she had mania, and two felt she had SMD and possible depression. A third youngster [20], Eric, was 10. He also had a history of ADHD and extreme reactions to being told ‘no’, or being frustrated in any way. He had been managed somewhat on stimulant medication until third grade when his behaviour gradually seemed to deteriorate and his aggressive outbursts intensified. This was considered the onset of a manic episode in part because he had a grandmother with bipolar disorder and symptoms were reinterpreted in that light. His treating physician stopped his ADHD medication and the child’s ADHD symptoms and overall behaviour went from bad to worse. His parents capitulated to his whims in trying to keep peace, making him quite cocky in what he thought he could get from them. Under the circumstances, symptom criteria (severe irritability plus worse ADHD symptoms and possible grandiosity) might be said to indicate a manic episode. However, several mood stabilizers, atypical antipsychotics and their combination were of no help. The last boy, Seth, also age 10, was complicated. He had severe, chronic rages that began in preschool years. He had language delays and learning disabilities and was exposed to much family disruption. It was difficult to get an
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accurate history from his mother who was overwhelmed by his difficult behaviour. This boy was so explosive and unmanageable that he required psychiatric hospitalization. He, too, had been treated for bipolar disorder with atypical antipsychotics. These had caused a 40 lb weight gain. Anticonvulsants did not ameliorate symptoms, and low doses of clonidine, atomoxetine and lamotrigine did not help either and were stopped. During Seth’s hospitalization, he was treated with stimulant medication for ADHD, which had been previously avoided. This reduced his hyperactivity and excessive talking and interrupting. Behaviour modification reduced his noncompliance somewhat and his mother was also taught to set limits and pick her battles more effectively. Attention was paid to his learning and language issues. Seth gradually improved. However, several weeks later, he seemed to become not only irritable and aggressive again, he also became more pointedly hyperactive, writing many love letters to his favourite teacher, elated, grandiose, and more resistant to bedtime. Re-interview of parent and teachers clarified that these symptoms had, in fact, occurred before, and independent of medication or clear precipitants. The diagnosis of mania was made over and above his ADHD, learning and language disorders. In each of these four cases, information elicited from structured interview of the parent attested to meeting symptom criteria for mania – irritability, hyperactivity, excessive talking, difficulty with sleep, poor insight, and behaviours that could be interpreted as being grandiose, hypersexual, intrusive and expansive. Left to individual interpretation is the question of whether the ‘distinct period’, a necessary criterion for DSM IV, should be interpreted as a clearly defined onset, as evidenced with Nicola and Seth, or whether the difficulties encountered by Eric and Lynda in third and fourth grade represented the beginnings of a distinct period of mania versus a deterioration of their inadequately treated ADHD. Distinguishing the background comorbidities of ADHD and oppositional behaviours from symptoms of mania is both difficult and inconsistently resolved between investigators and clinicians. The interviews used to study mood disorders in children do not examine developmental disorders. DSM IV, in its atheoretical stance, has been interpreted as discounting situations that might better explain symptoms than meeting criteria literally. Finally, the graduate students trained to administer the interviews in large-scale studies have not been trained to understand how well parents understand the intent of the symptom questions, since training tapes do not wrestle with such complexities. For these reasons, combining information from studies published on bipolar disorder in children is unlikely to be very meaningful, since it is unclear the degree to which samples of children are describing the same condition.
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Comorbidities
Course
True comorbidity occurs only when the comorbid condition is present, even when the episode of mania or depression has fully subsided. Not all assessment instruments or investigators clarify whether the comorbidity is present when the child is euthymic. In addition, most studies of bipolar disorder in youth do not distinguish lifetime versus current comorbidity. That is, if a child had separation anxiety at age seven, even though his mania did not begin until age 14, he is still listed as having a comorbid anxiety disorder because data are collected for ‘lifetime’. However, it is concurrent comorbidity that complicates diagnosis and requires treatment; hence, where possible, a distinction between whether a condition is lifetime or concurrent, and whether it has been assessed during a euthymic period needs to be stated. In adults, manic depression/bipolar disorder often occurs in people with prior other psychopathological conditions such as anxiety disorders, substance abuse, personality disorders, and, in about 20% of cases, attention deficit hyperactivity disorder. However, about one-third of patients have no other prior conditions [21]. Children like Seth, who meet criteria for bipolar disorder, nearly always present with co-occurring conditions. What is different is that children like Nicola are rare and when they occur, are generally peripubertal. It is likely the relative absence of such ‘classic’ cases has made many people sceptical about childhood bipolar disorder. In three of the four vignettes presented, symptoms of ADHD were present along with symptoms of oppositional defiant disorder and even conduct disorder. That is, not only were the children hyperactive, impulsive and distractible, they were also defiant, aggressive and irritable. It is easy to see why ADHD is the most common comorbid diagnosis amongst children for whom bipolar disorder is a consideration, with published rates of up to 90% amongst pre-adolescent youth and 50% amongst those with adolescent-onset mania/bipolar disorder. Other externalizing disorders, such as oppositional defiant and conduct disorder, are reported to be as prevalent as 79% [14]. This combination of externalizing disorders and bipolar disorder appears to run in families, and is associated with significant functional morbidity [22]. Other important comorbidities include anxiety disorders (generalized, separation and social anxiety disorders) and in adolescents, substance abuse disorders. There is some evidence that, in a number of cases, anxiety symptoms may intensify during episodes of depression and mania, resolving when mood symptoms are effectively treated. PDD, including autism and autism spectrum disorders, have been inconsistently ascertained. Where investigators have looked for such conditions, they are relatively common, with rates ranging from 20–60%, depending on how the PDD is defined [14].
The natural history of a disorder is one of its defining characteristics. Outcome studies on adults with bipolar I disorder reveal a relapsing and remitting course with considerable functional impairment [23]. Median episode length, depending on the study, is three to six months for cyclical episodes, and mixed episodes being about 50% longer. Even with lithium prophylaxis, recurrence rates are high – up to 50% by one year and 91% by five years. Very long-term follow-up finds good or improved outcomes in 43–56% of patients, and poor outcomes in 20–25%. Stated in terms of recurrence but with good intermorbid functioning, rates are about 41%. Many patients have recurrences with incomplete remissions (34%) and several studies report chronicity rates of around 16%. Stability of the diagnosis of bipolar disorder in adults varies depending on the study, too. The percent of patients retaining this diagnosis from one assessment to the next, has been found to range from 49–91% (median ¼ 70.0%, interquartile range ¼ 50–83%) [24]. There are two published, naturalistic follow-up studies, which specifically address children with bipolar disorder. One [25] selected children (ages 9–13) diagnosed with mania using the WASH U K-SADS. The second, the Course and Outcome of Bipolar Youth study [26] (COBY) includes both children and adolescents. Unlike the first study, where children had current mania, the COBY study sample could have had lifetime or current mania. In these children, age of onset was dated from first MOOD episode, which means their depressive episode could have been in childhood and their manic episode in adolescence. It is unclear how important the age of onset of MANIA is in understanding outcome. Duration of episode (or time to remission), when remission is defined as eight weeks of either no symptoms or subthreshold symptoms, is quite different in children from that seen in adults. In Geller’s sample of children with mania [25], who had a mean age at intake of 11 years, the duration of the index manic episode is measured in years [3.6 (2.5)] rather than months. The COBY study [26], where the mean age was 13, reported a median episode duration of 78 weeks. In this sample, 31% of subjects had an index manic episode, 27% had a mixed episode, 7% had hypomania and the rest were depressed. Thus, the 78 weeks included depressive as well as manic, mixed and hypomanic episodes. However, as mentioned, episodes may have been defined differently. In both of the above studies, recovery from the index episode occurred in 80–90% of cases; relapse rates were between 60 and 70%. It is not clear if return to baseline is part of the recovery definition. Subthreshold symptoms of mania, depression and/or comorbid symptoms may have remained after criteria for mania (or depression) were no
Bipolar I Disorder in Children: A Critical Review
longer met. Not surprisingly, there is considerable functional impairment, though whether this was from partially remitted mood symptoms or enduring comorbidities is unclear. Also absent from published studies in youth to date are data describing the frequency of good versus poor outcomes, or whether episodes are occurring with full remission or only partial remission between full episodes. Risk factors for longer episode duration include nonadherence with pharmacologic treatment, rapid cycling, psychotic symptoms, earlier age of onset, low SES, comorbid anxiety, ADHD and/or disruptive behaviour disorders and what Geller and colleagues have called ‘maternal warmth’ [26–28]. Examining the one to five year outcome of the four children described above (information unpublished) is indicative of why it is likely the results in children vary within samples and are so different from adult samples. Nicola and Seth have had defined episodes. Nicola’s acute manic episode duration was 13 weeks. She responded to lithium and risperidone, but she subsequently had a depressive episode, probably attenuated by medication. She was in complete remission for three years before her next depressive episode at 21 years of age and had finished college with some occasional mild mood symptoms but good intermorbid function. Seth, who had a convincing manic episode that lasted three weeks, observed by professionals, had his ADHD medication stopped and was vigorously treated first with lithium and then an atypical antipsychotic. He continued to have some oppositional defiant behaviour, and problems with executive function, which have required him to continue his education in a special school placement and resume stimulant medication. Nevertheless, his manic symptoms subsided and have not recurred over the 24-month follow-up. He remains on OROS methylphenidate, lithium and risperidone. Lynda and Eric had protracted behaviour problems the exacerbations of which could be called episodes but these were not as clearly defined as they were in the first two children, and probably had alternative explanations. Lynda’s behaviours ultimately required several hospitalizations. Each time she appeared to respond to a different medication regimen and within the inpatient unit structure, she improved. However, Lynda’s symptoms recurred when returned home where there was a great deal of conflict. Finally, it became apparent that out of home placement was necessary for a variety of reasons. She was sent to live with a relative where she lived for several years, treated for ADHD and depression. At age 18, she is about to start college, though it is uncertain how she will function without the kind of structure she had for the past several years. Eric’s ‘episode’ began when he was increasingly overwhelmed with academic demands and worsened when his stimulant medication was discontinued. He responded partially to treatment for ADHD, a different school placement,
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and parents improved management of his outbursts. Nevertheless, his major difficulty occurs when his ADHD medication ceases to work and although his parents are able to manage his outbursts more effectively, he remains a difficult child for whom other medications have either been ineffective or caused unacceptable side effects. In the latter two cases, an understanding of history, context and phenomenology is necessary to clarify diagnosis. Depending on how one interprets symptoms, mania criteria could be met. However, these phenocopies are likely to increase the heterogeneity of bipolar samples.
Differential diagnosis The cases presented illustrate why children with severe ADHD and oppositional defiant disorder are the ones most often confused with mania. When symptoms like euphoria, grandiosity and even irritability and aggression represent a change from a stable baseline of function, it is easier to make the diagnosis of mania than when a child has been chronically afflicted with these behaviours since preschool years. Seth exemplifies a child with the background ‘noise’ of ADHD and wilful, destructive behaviour. When those behaviours were treated, it was easier to distinguish an episode of mania, which was somewhat different in its manifestation. The clearer mania symptoms and behaviours are, the easier the differential diagnosis. Unfortunately, there is often no easy way to do this outside of careful follow-up. Some clinicians feel that a poor response to stimulant medication is of diagnostic value. However, systematic study of that issue has not revealed it to be useful diagnostically [29,30]. A second difficult diagnostic issue is the development of conduct disorder in older children with ADHD. Children with conduct disorder often are very irritable and oppositional, stay out late in defiance of their parents, engage in early sexual behaviour and drugs, and are hedonistic in their self-interest, caring little for the rights of others. In the US and UK child mania study [19], this clinical presentation, as exemplified to some extent by Lynda, caused the most cross-national difference in diagnostic practice. A third difficult diagnostic distinction occurs between an agitated, anxious depression and a mixed episode of mania. In adult psychiatry, the trend has been to err on the side of making a diagnosis of bipolar disorder and avoid the use of medications to treat the depression and anxiety for fear of exacerbating mania [31]. While data may not support the use of antidepressant treatment in known bipolar adults experiencing depression [32], the question of how to treat diagnostically ambiguous cases in children is currently unanswerable for lack of data. Substance abuse and schizophrenia pose important differential diagnoses in teens, but are less pertinent for children.
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Offspring studies Estimates from recent adult twin studies suggest that genetic influences explain approximately 60–93% of the variance in bipolar disorder, while shared and unique environmental factors account for 30–40% and 10–21%, respectively [33]. However, there are no ‘narrow phenotype’ twin studies of early onset bipolar disorder. Rates of BP I in offspring of parents with BP I range from 2–6% [34], though they can be as high as 38% if one includes the bipolar spectrum, and parents are from tertiary care clinics rather than the community [35]. These rates are significantly higher than in offspring of non-psychiatrically ill parents (where rates are negligible). This leads to very high relative risks compared to a normal control sample. However, within the sample of offspring, rates of bipolar disorder are considerably lower than rates of other psychopathology. For instance, in the BIOS study [34], rates of BP I were 2.1%, BP II were 1.2% and BP NOS were 7.2%. Even if all of the children with bipolar disorder not otherwise specified convert to bipolar I or II disorder, the rates of anxiety disorders (25.8%), disruptive behaviour disorders (19%) and ADHD (24.5%) are still much higher. Of course, more offspring may develop mood disorders in general and bipolar disorder in particular as they age. So far, the data would suggest that an assortment of symptoms can be harbingers of future bipolar disorder [36]. In addition, high risk children with subthreshold psychopathology that cuts across different symptom groups are also at risk for bipolar disorder, but their rates of developing other problems is equally high [37]. From a clinician’s standpoint then, the need to respond therapeutically to symptomatic children at risk is clear. The question of how to respond is less clear. Studies of early onset bipolar disorder have found elevated rates of bipolar disorder amongst relatives of children with narrow-phenotype bipolar disorder as compared to later-onset cases [38]. On the other hand, there does not appear to be an increased risk for bipolar disorder within families of children with SMD [39], suggesting that children with chronic problems with emotion regulation and narrow phenotype early-onset BD may be aetiologically distinct. Studies from the Massachusetts General Hospital research group have found evidence that symptoms of affective dysregulation and attention problems co-segregate in certain families [22]. While some argue that this symptom profile represents a particularly virulent form of early-onset bipolar disorder, the nosological status of these individuals is not accepted by everyone in the field. Family histories of the four children previously presented, although somewhat consistent with data described, illustrate that a family history of mood disorder, while helpful and important, is not diagnostic. For instance, Nicola’s parents had both been treated for depression but there was no known history of bipolar disorder in her
family. Lynda had a history in her family of cyclothymia, depression and ADHD. Seth’s mother had experienced a postpartum depression, and his father had substance abuse disorder and numerous learning disabilities. Finally, Eric’s maternal grandmother had bipolar I disorder, which was treated successfully with ECT. His father had a childhood history of ADHD and had been in recovery from alcohol and cocaine abuse for 10 years.
Assessment With regard to mania and bipolar I disorder, the 2007 American Academy of Child and Adolescent Psychiatry (AACAP) Practice Parameter makes a number of treatment recommendations [40]. Simply put, these suggest screening patients for current and past mania and bipolar depression, using DSM IV TR criteria, examining for comorbidities, and using caution when diagnosing preschool children. However, the cases previously described give witness to the fact that considerable time and effort are necessary in making a diagnosis of bipolar disorder in children. Evaluation procedures go well beyond rote application of DSM-IV-TR criteria for mania and depression. Assessment requires interviews with both caregiver(s) and child. Caregivers should be interviewed first regardless of the child’s age, as they are likely to provide the most reliable historical information. These interviews should include an overview of current symptoms, developmental history, ascertainment of other psychiatric emotional, behavioural and developmental disorders, and longitudinal course of manic and depressive symptoms. While the parent interview is necessary for a coherent history, the child interview is critical for eliciting important information regarding manic and depressive symptoms, environmental factors contributing to mood variability, as well as features of other conditions that may be confused, or co-occur, with mania, including PDD, language, or thought disorder, psychosis, anxiety, suicidal behaviour, physical/ sexual abuse and illicit substance use. Where the child’s information is at variance with caregivers, the child and the parent should be asked to explain the difference. Since mania is not subtle, it should be observable. If there is another informant, that person should be asked to corroborate the mania symptoms and insure that both informants are describing the same phenomenon. Similarly, if a parent describes mania and the child has not, it is often useful to ask the child how s/he explains the parent’s description. The converse is true, too. The structured and semi-structured diagnostic interviews used in research settings to elicit symptoms of bipolar disorder and other childhood conditions may also be useful in clinical settings to confirm a diagnosis. However, clinical judgement is required to determine whether a respondent is under- or over-reporting symptoms, misinterpreting
Bipolar I Disorder in Children: A Critical Review
developmentally appropriate behaviours, or misunderstanding questions about clinical behaviours. To this end, it is critical that clinicians probe beyond affirmative responses to elicit examples of specific behaviours, as well as the context in which behaviours are occurring. Rating scales have been developed to measure the severity of mania. Only one, the Child Mania Rating Scale [41] was developed for children. Others, for example the Young Mania Rating Scale [42], the Parent Young Mania Rating Scale and the General Behaviour Inventory are adult measures that have been applied to children [43]. None of the large outpatient research studies have required collateral information (e.g. teacher input) systematically to determine whether mania can be documented to occur cross-situationally, or to corroborate parent information. Where that has been done, as with other conditions, the rate of agreement is quite low [44]. In the case of full-fledged mania, it is difficult to explain how a child may appear asymptomatic in school, day in and day out, and reserve his or her manic symptoms only for home. Other diagnoses must be considered. In the absence of parent/teacher agreement, rates of diagnosed bipolar disorder are much lower than when there is agreement [45]. Additional assessments, including neuropsychological testing, speech and language evaluations and medical records, can also be extremely helpful in identifying developmental, cognitive and medical factors that may contribute to emotional dysregulation, as well as complicate episodes of mania and depression. Family history of mood disorder, bipolar and unipolar, and other psychiatric disorders (including common disorders of childhood such as oppositional defiant disorder, ADHD, learning disabilities and PDD) must be assessed as part of the parent interview. If there is a positive family history of bipolar disorder, it is important to probe for details regarding clinical presentation, comorbid conditions and response to treatment of the family member’s disorder.
Treatment As in adults, treatment requires a combination of psychosocial and psychopharmacologic approaches.
Psychosocial treatment Psychosocial interventions in youth and adults have several components, including teaching families about bipolar disorder, helping them to recognize future episodes before they progress too far, encouraging treatment adherence and addressing environmental stressors that act as possible precipitants to further episodes. There are four models of psychosocial treatment studied in children and adolescents with early-onset bipolar disorder. These include multifamily and individual family psychoeducation [46], family-
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focused therapy for adolescents [47], child and familyfocused CBT for younger children [48] and collaborative problem solving [49]. Each emphasizes the importance of psychoeducation and destigmatization as well as increasing parental collaboration by reducing parent blame for causing the disorder, helping parents distinguish between normative developmental behaviour and bipolar symptoms, taking proactive steps to decrease risk of relapse, developing tools for effectively managing emotional arousal, improving family communication skills and teaching adaptive problem solving strategies. Added to these approaches is the need to find the right school support for the child, and taking advantage of a good children’s inpatient unit or residential treatment when outpatient strategies are unsuccessful. It goes without saying that parents with their own untreated psychiatric disorders need to attend to those first. Whether a child has unequivocal bipolar I disorder or that condition is part of the differential diagnosis, the child will require considerable energy and resourcefulness on the part of the family to manage his/her problems successfully.
Pharmacotherapy When treating a child who is in a manic or mixed episode, it is important to establish a baseline symptom severity to track subsequent changes in the symptoms. If the child has SMD, or if rages are the behaviours being targeted, their frequency, intensity, number and duration need to be monitored. Medication management also requires obtaining baseline laboratory tests relevant to the medication used, and monitoring side effects [50]. The evidence base for treatment of acute mania in youth has grown in recent years, largely because medications approved for adults that are likely to be used in children or adolescents must be tested for safety and effectiveness in that sample. FDA labelling requirements allow fewer studies to be done if the condition, in this case mania, is the same condition that exists in adults, such that similar measures to test safety and efficacy are valid in that age group. A consensus conference convened in 2002 established that youth between ages 10 and 17 could be found that had the same condition as in adults [51]. The condition in younger children was less well established, hence the age 10 cut-off. This is important because it means that the same medications and doses that have been used for adults are being studied in older children and adolescents. Five atypical antipsychotic medication trials have been completed for paediatric bipolar disorder, all in response to an FDA written request. As in trials with adults, a significant decrease at end of trial in the score on the Mania Rating Scale [42] compared to the placebo control group is one marker of a successful study. The other metric, easier to compare across studies, is the percent of study participants who experience a 50% reduction in symptoms.
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Risperidone, aripiprazole, quetiapine and ziprasidone were required to use low and high dose alternatives. At this time, none of these studies has been published but all have been presented at national meetings, though there is a publication summarizing and synthesizing findings for both atypical antipsychotics and mood stabiliziers [52]. Both high and low doses of atypical antipsychotics were significantly effective as measured by a 50% reduction in Y-MRS entry scores and by a decrease of Y-MRS scores of between 14 and 18 points compared to placebo responses of 8–10 points. In general, 45–65% of subjects improved on active medication versus 18–37% on placebo. The absolute treatment benefit (percent of drug responders minus placebo responders) averaged 19–38%, and the number needed to treat (NNT) in successful trials, where drug was better than placebo varied from less than three (high dose aripiprazole and high dose risperidone) to around five (low dose aripiprazole and high dose quetiapine). Effect sizes were in the range of 0.6–0.7 for the YMRS change from baseline scores. Side effects were usually greater for the high dose condition without a correspondingly higher improvement. Though overall studycompletionrateswerehigh,problemsofweight gain over both short and long term continues to be a problem in children that is far worse than is seen in adults. Interestingly, however, drug studies in adults do not track weight gain as assiduously as they are tracked in children [52]. Risperidone and aripiprazole were recently approved for treatment of acute mania down to the age of 10. Sponsors of the other medications are awaiting a response from the FDA regarding approvability. Unlike the other four atypical antipsychotics, olanzapine, which has been on the market longer, was tested only in adolescents, as their written request had been issued before the FDA decision to include children down to age 10. With doses ranging between 10 and 20 mg, 44.8% of youth on olanzapine showed at least a 50% reduction in symptoms compared to a placebo response rate of 18.5%, a significant difference (p < 0.001). The mean decrease from baseline YMRS entry score of 33 was 17.7 points and the effect size was 0.84 [53]. Although lithium has been used in children and teens for many years [54], and its approval for mania ‘grandfathered’ in, only recently have treatment studies for mania included a double-blind control. Open trials of lithium have suggested response rates of 50–60%. However, the one recently completed eight week, placebo-controlled trial of reasonable sample size (66 lithium, 56 divalproex and 31 placebo treated outpatients) reported a lithium response of 42% that did not differ significantly from the placebo response of 29%. The placebo response is similar to that found in other studies; it was the lithium response that was inadequate [52]. The question, of course, is whether this insignificant response rate is because ‘non-classical’ bipolar children were included in the trial, or is there another explanation.
These data have not yet been published and it is hoped that post-hoc analyses will be able to address patient subtypes and response. Divalproex has also been approved for treatment of mania in adults, and an industry sponsored trial requested by the FDA was completed. This was only four weeks in duration (the duration of adult trials), and was negative (drug and placebo responses 24 and 23%, respectively) [52]. On the other hand, an NIMH published study was positive with a divalproex response of 53% and a placebo response of 29% [52]. Published trials of two other anticonvulsants, topiramate [55] and oxcarbazepine [56], reported that these medications were not significantly better than placebo. An open trial of lamotrigine to treat manic and depressive symptoms in a sample of older children and adolescents with bipolar disorder found the drug to be effective on both mild manic and depressive symptoms. At the end of a 14-week trial, remission rate was 56% [57]. An industrysponsored placebo-controlled trial testing lamotrigine’s ability to prolong time to relapse in young people aged 10–17 is currently ongoing. Using more than one medication in adults and youth has increasingly become acceptable for treating mania/bipolar disorder, especially those with irritable aggression or significant psychosis. In youth, studies have included comparisons of two medications to one (e.g. combined divalproex and quetiapine vs. quetiapine alone [58]), adding one to another if the first drug does not work, (e.g. adding risperidone to lithium or divalproex [59]) and starting two together (e.g. lithium and divalproex and discontinuing one [60]). In those children and adolescents who have not responded to one medication, there is support for using two. The frequency and severity of adverse effects of drugs differ between children and adults. For instance, weight gain with metabolic syndrome, especially in medicationna€ıve patients, and polycystic ovaries may be of particular concern in young people [61]. Similarly, disinhibitory or activation responses to many types of CNS medications (sometimes misconstrued as mania) seems to occur more often in children and perhaps slightly less so in teens [62].
Treatment of bipolar depression There are no placebo-controlled studies of bipolar depression in children though there are two open medication trials in adolescents. These include lithium monotherapy in hospitalized adolescents with bipolar depression [63] and lamotrigine alone or with other medication in outpatient adolescents [64]. Symptoms declined in both studies though in the absence of placebo control, and given the high placebo response which accounted for two negative trials of lamotrigine in adults with bipolar depression, the treatment utility of these medications in youth remains to be demonstrated.
Bipolar I Disorder in Children: A Critical Review
Treatment of ‘broad phenotype’ bipolar disorder or explosive outbursts However defined, irritable, explosive aggression is not easily treated psychosocially or by medication in adults [65] or children. Atypical antipsychotics appear to have some efficacy in treating irritability in children with behaviour disorders and autism [66]. Similarly, children with ‘rages’ may have the duration of their outbursts reduced somewhat with risperidone [67]. Studies of specifically defined SMD, that is anger/sadness with ADHD symptoms and significant tantrums in more than one setting, do not appear to respond to lithium [68], and respond modestly to stimulant medication and behaviour modification [69]. In the case of obvious mania/bipolar disorder, the consensus documents recommend stabilizing the mood disorder symptoms and then treating the comorbid disorder [50] A recent meta-analysis found that comorbid ADHD lowered treatment responsiveness to the bipolar disorder treatment, which suggests that the ADHD may need to be addressed [70]. Although there have been concerns about treating ADHD in children with possible mania for fear of exacerbating or precipitating mania, an increasing number of studies are substantiating the utility of doing so [71,72]. It is important to note that treating ADHD with therapeutic doses of stimulants is quite different from abusing cocaine and other stimulant drugs.
Conclusion The ramifications of diagnosis become clear with the multifaceted approach to treatment in children with mania/ bipolar disorder and those for whom it is a consideration. In the examples presented, two children with clear episodes of mania both responded to lithium but needed other medications in addition. In Nicola’s case, this was true only for the acute episode. For Seth, lithium did not sufficiently attenuate his mania to allow discharge home. He required an adjunctive antipsychotic as well as treatment for his ADHD. In addition, he required hospitalization, ongoing special education intervention, and his mother needed support and guidance to manage his behaviour consistently and non-punitively. Although Lynda had a mood disorder, it was depressive in nature rather than manic. She was experiencing multiple failures (academic and social), and the level of acrimony in her family was more than she could handle. She responded to treatment for ADHD and depression and required out-ofhome placement. Finally, Eric typifies many children with complex problems in executive function and emotion regulation. They respond only modestly to interventions we currently have. Relevant to the premise of this chapter is the observation that all four children ‘meet criteria’ for mania depending on
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interpretation of symptom ascertainment. Two problems occur if criteria application is not done thoughtfully and consistently across studies. First, it is impossible to understand what true bipolar manifestations are likely to be. This is true insofar as treatment response is concerned, as well as in trying to isolate the biologic underpinnings of the disorder. Second, children will not be treated for the problems they are having. Given the severity of the problems with which they present, this is not an outcome anyone wishes. It will be necessary for the field of child and adolescent mood disorders to come to terms with the obvious and not so obvious differences in assessment, symptom interpretation, and how to define outcome in order for the nature of bipolar disorder in children to be understood [73].
References 1. Carlson, G.A. and Glovinsky, I. (2009) The concept of bipolar disorder in children: a history of the bipolar controversy. Child Adolesc. Psychiatr. Clin. N. Am., 18, 257–271. 2. Moreno, C., Laje, G., Blanco, C. et al. (2007) National trends in the outpatient diagnosis and treatment of bipolar disorder in youth. Arch. Gen. Psychiatry, 64, 1032–1039. 3. Blader, J.C. and Carlson, G.A. (2007) Increased rates of bipolar disorder diagnoses among U.S. child, adolescent, and adult inpatients, 1996–2004. Biol. Psychiatry, 62, 107–114. 4. Biederman, J., Faraone, S.V., Wozniak, J. et al. (2005) Clinical correlates of bipolar disorder in a large, referred sample of children and adolescents. J. Psychiatr. Res., 39, 611–622. 5. Olfson, M., Crystal, S., Gerhard, T. et al. (2009) Mental health treatment received by youths in the year before and after a new diagnosis or bipolar disorder Psychiat. Serv., 60, 1098–1106. 6. Carlson, G.A., Potegal, M., Margulies, D. et al. (2009) Rages: What are they? Who has them? J. Child. Adolesc. Psychopharmacol., 19, 281–288. 7. Zimmerman, M., Ruggero, C.J., Chelminski, I. et al. (2008) Is bipolar disorder overdiagnosed? J. Clin. Psychiatry, 69, 935–940. 8. Costello, E.J., Angold, A., Burns, B.J. et al. (1996) The great smoky mountains study of youth: goals, design, methods, and the prevalence of DSM-III-R disorders. Arch. Gen. Psychiatry, 53, 1129–1136. 9. Andreasen, N.C. (2007) DSM and the death of phenomenology in America: an example of unintended consequences. Schizophr. Bull., 33, 108–112. 10. Tillman, R. and Geller, B. (2003) Definitions of rapid, ultrarapid, and ultradian cycling and of episode duration in pediatric and adult bipolar disorders: a proposal to distinguish episodes from cycles. J. Child Adolesc. Psychopharmacol., 13, 267–271. 11. Blader, J.C. and Carlson, G.A. (2008) Bipolar disorder, in Child and Adolescent Psychopathology (eds T.P. Beauchaine and S.P. Hinshaw), John Wiley & Sons, Hoboken, NJ, pp. 543–574. 12. Wozniak, J., Biederman, J. and Kwon, A. (2005) How cardinal are cardinal symptoms in pediatric bipolar disorder? An
486
13.
14.
15.
16.
17. 18.
19.
20. 21.
22.
23.
24.
25.
26.
27.
28.
|
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examination of clinical correlates. Biol. Psychiatry, 58, 583–588. Geller, B., Zimerman, B., Williams, M. et al. (2002) Phenomenology of prepubertal and early adolescent bipolar disorder: examples of elated mood, grandiose behaviors, decreased need for sleep, racing thoughts, and hypersexuality. J. Child Adolesc. Psychopharmacol., 12, 3–9. Carlson, G.A. and Meyer, S.E. (2006) Phenomenology and diagnosis of bipolar disorder in children, adolescents, and adults: complexities and developmental issues. Dev. Psychopathol., 18, 939–969. Melnick, S.M. and Hinshaw, S.P. (2000) Emotion regulation and parenting in AD/HD and comparison boys: linkages with social behaviors and peer preference. J. Abnorm. Child Psychol., 28, 73–86. Leibenluft, E., Charney, D.S., Towbin, K.E. et al. (2003) Defining clinical phenotypes of juvenile mania. Am. J. Psychiatry, 160, 430–437. Carlson, G.A. (2007) Who are the children with severe mood dysregulation, a.k.a. “rages”? Am. J. Psychiatry, 164, 1140–1142. Brotman, M.A., Schmajuk, M., Rich, B.A. et al. (2006) Prevalence, clinical correlates, and longitudinal course of severe mood dysregulation in children. Biol. Psychiatry, 60, 991–997. Dubicka, B., Carlson, G., Vail, A. et al. (2008) Prepubertal mania: diagnostic differences between US and UK clinicians. Eur. Child Adolesc. Psychiatry, 17, 153–161. Carlson, G.A. (2009) Treating the childhood bipolar controversy: a tale of two children. Am. J. Psychiatry, 166, 18–24. Goodwin, F.K. and Jamison, K.R. (2007) Manic-Depressive Illness Bipolar Disorders and Recurrent Depression, Oxford University Press, New York. Faraone, S.V., Glatt, S.J. and Tsuang, M.T. (2003) The genetics of pediatric-onset bipolar disorder. Biol. Psychiatry, 53, 970–977. Angst, J. and Sellaro, R. (2000) Historical perspectives and natural history of bipolar disorder. Biol. Psychiatry, 48, 445–457. Ruggero, C.J., Carlson, G.A., Kotov, R. et al. (2010) 10-Year Diagnostic Consistency of Bipolar Disorder in a FirstAdmission Sample. Geller, B., Tillman, R., Bolhofner, K. et al. (2008) Child bipolar I disorder: prospective continuity with adult bipolar I disorder; characteristics of second and third episodes; predictors of 8-year outcome. Arch. Gen. Psychiatry, 65, 1125–1133. Birmaher, B., Axelson, D., Strober, M. et al. (2006) Clinical course of children and adolescents with bipolar spectrum disorders. Arch. Gen. Psychiatry, 63, 175–183. Alloy, L.B., Abramson, L.Y., Walshaw, P.D., Keyser, J. et al. (2006) A cognitive-vulnerability-stress perspective on bipolar spectrum disorders in a normative adolescent brain, cognitive and emotional development context. Dev. Psychopathol., 18, 1055–1103. Tillman, R., Geller, B., Nickelsburg, M.J. et al. (2003) Life events in a prepubertal and early adolescent bipolar disorder phenotype compared to attention-deficit hyperactive and normal controls. J. Child Adolesc. Psychopharmacol., 13, 243–251.
29. Carlson, G.A., Loney, J., Salisbury, H. et al. (2000) Stimulant treatment in young boys with symptoms suggesting childhood mania: a report from a longitudinal study. J. Child Adolesc. Psychopharmacol., 10, 175–184. 30. Carlson, G.A. and Kelly, K.L. (2003) Stimulant rebound: how common is it and what does it mean? J. Child Adolesc. Psychopharmacol., 13, 137–142. 31. Ghaemi, S.N., Hsu, D.J., Soldani, F. et al. (2003) Antidepressants in bipolar disorder: the case for caution. Bipolar Disord., 5, 421–433. 32. Goldberg, J.F., Perlis, R.H., Ghaemi, S.N. et al. (2007) Adjunctive antidepressant use and symptomatic recovery among bipolar depressed patients with concomitant manic symptoms: findings from the STEP-BD. Am. J. Psychiatry, 164, 1348–1355. 33. Thapar, A. and Rice, F. (2006) Twin studies in pediatric depression. Child Adolesc. Psychiatr. Clin. N. Am., 15, 869–881. 34. Birmaher, B., Axelson, D., Monk, K. et al. (2009) Lifetime psychiatric disorders in school-aged offspring of parents with bipolar disorder: the Pittsburgh Bipolar Offspring study. Arch. Gen. Psychiatry, 66, 287–296. 35. Chang, K.D., Steiner, H. and Ketter, T.A. (2000) Psychiatric phenomenology of child and adolescent bipolar offspring. J. Am. Acad. Child. Adolesc. Psychiatry, 39, 453–460. 36. Duffy, A., Alda, M., Crawford, L. et al. (2007) The early manifestations of bipolar disorder: a longitudinal prospective study of the offspring of bipolar parents. Bipolar Disord., 9, 828–838. 37. Meyer, S.E., Carlson, G.A., Youngstrom, E. et al. (2009) Longterm outcomes of youth who manifested the CBCL-pediatric bipolar disorder phenotype during childhood and/or adolescence. J. Affect. Disord., 113, 227–235. 38. Geller, B., Tillman, R., Bolhofner, K. et al. (2006) Controlled, blindly rated, direct-interview family study of a prepubertal and early-adolescent bipolar I disorder phenotype: morbid risk, age at onset, and comorbidity. Arch. Gen. Psychiatry, 63, 1130–1138. 39. Brotman, M.A., Kassem, L., Reising, M.M. et al. (2007) Parental diagnoses in youth with narrow phenotype bipolar disorder or severe mood dysregulation. Am. J. Psychiatry, 164, 1238–1241. 40. McClellan, J., Kowatch, R.A. and Findling, R.L. (2007) Practice parameter for the assessment and treatment of children and adolescents with bipolar disorder. J. Am. Acad. Child Adolesc. Psychiatry, 46, 107–125. 41. Pavuluri, M.N., Henry, D.B., Devineni, B. et al. (2006) Child mania rating scale: development, reliability, and validity. J. Am. Acad. Child Adolesc. Psychiatry, 45, 550–560. 42. Young, R.C., Biggs, J.T., Ziegler, V.E. et al. (1978) A rating scale for mania: reliability, validity and sensitivity. Br. J. Psychiatry, 133, 429–435. 43. Youngstrom, E., Meyers, O., Youngstrom, J.K. et al. (2006) Diagnostic and measurement issues in the assessment of pediatric bipolar disorder: implications for understanding mood disorder across the life cycle. Dev. Psychopathol., 18, 989–1021. 44. Thuppal, M., Carlson, G.A., Sprafkin, J. et al. (2002) Correspondence between adolescent report, parent report, and
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45.
46.
47.
48.
49.
50.
51.
52.
53.
54.
55.
56.
57.
58.
59.
teacher report of manic symptoms. J. Child Adolesc. Psychopharmacol., 12, 27–35. Carlson, G.A. and Youngstrom, E.A. (2003) Clinical implications of pervasive manic symptoms in children. Biol. Psychiatry, 53, 1050–1058. Fristad, M.A. (2006) Psychoeducational treatment for schoolaged children with bipolar disorder. Dev. Psychopathol., 18, 1289–1306. Miklowitz, D.J. and Chang, K.D. (2008) Prevention of bipolar disorder in at-risk children: theoretical assumptions and empirical foundations. Dev. Psychopathol., 20, 881–897. West, A.E., Henry, D.B. and Pavuluri, M.N. (2007) Maintenance model of integrated psychosocial treatment in pediatric bipolar disorder: a pilot feasibility study. J. Am. Acad. Child Adolesc. Psychiatry, 46, 205–212. Greene, R.W. and Ablon, J.S. (2006) Treating Explosive Kids-The Collaborative Problem-Solving Approach, Guilford Press, New York. Kowatch, R.A., Fristad, M., Birmaher, B. et al. (2005) Child psychiatric workgroup on bipolar disorder. Treatment guidelines for children and adolescents with bipolar disorder. J. Am. Acad. Child Adolesc. Psychiatry, 44, 213–235. Carlson, G.A., Jensen, P.S., Findling, R.L. et al. (2003) Methodological issues and controversies in clinical trials with child and adolescent patients with bipolar disorder: report of a consensus conference. J. Child Adolesc. Psychopharmacol., 13, 13–27. Correll, C.U., Schenk, E.M. and DelBello, M.P. (2010) Antipsychotic and mood stabilizer efficacy and tolerability in pediatric and adult patients with bipolar i mania: a comparative analysis of acute, randomized, placebo-controlled trials. Bipolar Disord. Tohen, M., Kryzhanovskaya, L., Carlson, G. et al. (2007) Olanzapine versus placebo in the treatment of adolescents with bipolar mania. Am. J. Psychiatry, 164, 1547–1556. Youngerman, J. and Canino, I.A. (1978) Lithium carbonate use in children and adolescents. A survey of the literature. Arch. Gen. Psychiatry, 35, 216–224. Delbello, M.P., Findling, R.L., Kushner, S. et al. (2005) A pilot controlled trial of topiramate for mania in children and adolescents with bipolar disorder. J. Am. Acad. Child Adolesc. Psychiatry, 44, 539–547. Wagner, K.D., Kowatch, R.A., Emslie, G.J. et al. (2006) A double-blind, randomized, placebo-controlled trial of oxcarbazepine in the treatment of bipolar disorder in children and adolescents. Am. J. Psychiatry, 163, 1179–1186. Pavuluri, M.N., Henry, D.B., Moss, M. et al. (2009) Effectiveness of lamotrigine in maintaining symptom control in pediatric bipolar disorder. J. Child Adolesc. Psychopharmacol., 19, 75–82. Delbello, M.P., Schwiers, M.L., Rosenberg, H.L. et al. (2002) A double-blind, randomized, placebo-controlled study of quetiapine as adjunctive treatment for adolescent mania. J. Am. Acad. Child Adolesc. Psychiatry, 41, 1216–1223. Pavuluri, M.N., Henry, D.B., Carbray, J.A. et al. (2004) Openlabel prospective trial of risperidone in combination with lithium or divalproex sodium in pediatric mania. J. Affect. Disord., 82, S103–S111.
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60. Findling, R.L., McNamara, N.K., Youngstrom, E.A. et al. (2005) Double-blind 18-month trial of lithium versus divalproex maintenance treatment in pediatric bipolar disorder. J. Am. Acad. Child Adolesc. Psychiatry, 44, 409–417. 61. Correll, C.U. and Carlson, H.E. (2006) Endocrine and metabolic adverse effects of psychotropic medications in children and adolescents. J. Am. Acad. Child Adolesc. Psychiatry, 45, 771–791. 62. Safer, D.J. and Zito, J.M. (2006) Treatment-emergent adverse events from selective serotonin reuptake inhibitors by age group: children versus adolescents. J. Child Adolesc. Psychopharmacol., 16, 159–169. 63. Patel, N.C., DelBello, M.P., Bryan, H.S. et al. (2006) Openlabel lithium for the treatment of adolescents with bipolar depression. J. Am. Acad. Child Adolesc. Psychiatry, 45, 289–297. 64. Chang, K., Saxena, K. and Howe, M. (2006) An open-label study of lamotrigine adjunct or monotherapy for the treatment of adolescents with bipolar depression. J. Am. Acad. Child Adolesc. Psychiatry, 45, 298–304. 65. Goedhard, L.E., Stolker, J.J., Heerdink, E.R. et al. (2006) Pharmacotherapy for the treatment of aggressive behavior in general adult psychiatry: A systematic review. J. Clin. Psychiatry, 67, 1013–1024. 66. McCracken, J.T., McGough, J., Shah, B. et al. (2002) Research units on pediatric psychopharmacology autism network. Risperidone in children with autism and serious behavioral problems. N. Engl. J. Med., 347, 314–321. 67. Carlson, G.A., Potegal, M., Margulies, D. et al. (2010) Liquid Risperidone in the treatment of rages in psychiatrically hospitalized children with severe mood dysregulation or community diagnosed bipolar disorder. Bipolar Disord. 68. Dickstein, D.P., Towbin, K.E., Van Der Veen, J.W. et al. (2009) Randomized double-blind placebo-controlled trial of lithium in youths with severe mood dysregulation. J. Child Adolesc. Psychopharmacol., 19, 61–73. 69. Waxmonsky, J., Pelham, W.E., Gnagy, E. et al. (2008) The efficacy and tolerability of methylphenidate and behavior modification in children with attention-deficit/hyperactivity disorder and severe mood dysregulation. J. Child Adolesc. Psychopharmacol., 18, 573–588. 70. Consoli, A., Bouzamondo, A., Guile, J.M. et al. (2007) Comorbidity with ADHD decreases response to pharmacotherapy in children and adolescents with acute mania: evidence from a metaanalysis. Can. J. Psychiatry, 52, 323–328. 71. Galanter, C.A., Pagarm, D.L., Davies, M., et al. (2005) ADHD and manic symptoms: Diagnostic and treatment implications. Clin. Neurosci. Res., 5, 283–294. 72. Scheffer, R.E., Kowatch, R.A., Carmody, T. et al. (2005) Randomized, placebo-controlled trial of mixed amphetamine salts for symptoms of comorbid ADHD in pediatric bipolar disorder after mood stabilization with divalproex sodium. Am. J. Psychiatry, 162, 58–64. 73. Carlson, G.A., Findling, R.L., Post, R.M. et al. (2009) AACAP 2006 research forum: advancing research in early onset BP: barriers and suggestions. J. Child Adolesc. Psychopharmacol., 19, 3–12.
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Bipolar Disorder in the Elderly Martha Sajatovic1 and Lars Vedel Kessing2 1 2
University Hospitals Case Medical Center, Cleveland, Ohio, USA Department of Psychiatry, University Hospital of Copenhagen, Rigshospitalet, Denmark
Introduction In 2005, a report from the United Nations Populations Division [1] noted that the number of individuals over age 60 is expected to nearly triple, increasing from 672 million in 2005 to almost 1.9 billion by 2050. The elderly population in developed countries has surpassed the number of individuals under the age of 14 years, and by the year 2050 it is anticipated that there will be two elderly persons for every child [1]. Population ageing is thus an important factor globally, including the issue of health care and health care delivery in older-adult populations with mental disorders. The current literature-base on late-life bipolar disorder is insufficient to adequately answer many clinical questions regarding late-life bipolarity. While 30% of patients in John Cades seminal publication on the use of lithium in manic agitation were older adults [2], there was no trajectory of substantial inclusion of elderly subjects in scientific reporting, and for many years there was a near-absence of publications focused on the topic of late-life bipolar disorder. Fortunately, and in concert with global demographic trends, there has been recent growth in research on geriatric populations with bipolar disorder [3]. This chapter will review available evidence on key clinical and research considerations in late-life bipolar disorder including epidemiology, clinical presentation (including gender differences and diagnostic stability), course of illness, medical and psychiatric comorbidity, cognitive functioning, treatment effects, treatment adherence and attitudes and beliefs, as well as satisfaction with treatment. The chapter will conclude with recommendations for areas of future research.
Epidemiology The most recent epidemiological studies suggest that types I and II bipolar disorder affect approximately 0.5–1.0% of older adults [4–6]. However, it is likely that this figure Bipolar Disorder: Clinical and Neurobiological Foundations Edited by Lakshmi N. Yatham and Mario Maj © 2010 John Wiley & Sons, Ltd. ISBN: 978-0-470-72198-8
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represents a lower boundary of individuals with bipolar illness, and does not include all individuals within the bipolar spectrum [7]. A review of epidemiologic and large-scale treatment studies suggests that bipolar disorder becomes less common with age and in geriatric populations, it is approximately one-third as common as it is in younger populations [8]. In contrast to low rates in the community, bipolar illness in clinical populations is substantially more common, with bipolar disorder accounting for 6% of geriatric psychiatry outpatient visits and 8–10% of geriatric inpatient admissions [8]. Studies from North America report that 3% of nursing home residents and 17% of elders presenting to psychiatric emergency rooms have bipolar disorder [8,9]. As might be expected, given the longer life-span of women compared to men, approximately 70% of older adults with bipolar disorder in clinical populations are female [8]. The growing absolute numbers and proportion of older adults in the population may be causing a rise in the number of elders seeking care for bipolar disorder. An Australian study [10] noted that the number of individuals over the age of 65 with bipolar illness increased from 2% in 1980 to 10% in 1998.
Clinical presentation It is likely that early- and late-onset bipolar disorder may be different forms of the illness, as early-onset bipolar disorder may be more associated with a family history of affective disorder [11] and late-onset bipolar disorder may be more associated with brain disease related to other condition [12–14]. Bipolar disorder in old age may develop in different ways: some may develop new-onset mania associated with vascular changes or other organic states, some may become manic after recurrent depressive episodes, and some may have been diagnosed with bipolar disorder at an early age and have survived to old age with the illness [8]. There is a lack of quantitative data about the precipitants of episodes in older adults with bipolar illness, although some retrospective studies have indicated that negative life events precipitated a majority of psychiatric admissions [8,15]. One study specifically tested whether the
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impact of major stressful life events and other risk factors for first admission with mania change throughout life [16]. The susceptibility to major life stressors of inducing mania did not change with age and was further similar for men and women [16]. Differences in the phenomenology of bipolar disorder amongst patients with late- and patients with early-onset disorder have not been well-studied and the results are often conflicting [8]. In general, only minor differences have been found in the phenomenology of bipolar disorder between patients with late onset and patients with early onset [8]. The difference is most pronounced amongst patients with the most severe disorders requiring hospitalization [17]. Most [11,17–19], but not all studies [20–22], have found overall psychotic features to be less frequent amongst older inpatients. In a study of 469 patients hospitalized for the first time ever with bipolar disorder when older than 50 years, the prevalence of overall psychotic symptoms was reduced compared with 568 younger patients – due to a lower prevalence of manic episodes with psychotic symptoms. Conversely, older inpatients more often presented with severe depressive episodes with psychotic symptoms than younger inpatients (32.0% vs. 17.0%). Older inpatients have been found to more often present with severe depressive episodes and less often with severe manic episodes than patients with earlier age at first hospitalization [17], but one other study could not confirm this finding [23]. There seems to be no difference between patients with late- and early-onset disorder in the type of first episode (depressive vs. manic/mixed episodes) [11,17,20,24], duration of mania, psychiatric hospitalization [17,25] or outpatient contact [17], or the prevalence of mixed episodes [10,14,17], although regarding the latter, some findings suggest a lower prevalence of mixed episodes amongst patients with late onset [11]. Only a few studies have been published on outpatients with bipolar disorder. The two largest studies reported from a sample of all outpatients (682 outpatients) nationwide in psychiatric health care in Denmark [17] and from a large psychiatric service database in Western Australia of 6182 patients with bipolar disorder. These studies found minimal differences between older and younger patients [10,17]. There may be some gender differences in the clinical presentation of early-onset bipolar disorder [26], but there seems to be no or few gender differences in patients with late onset of bipolar disorder [10,11,17,19–21,23,24,27–29]. Results from naturalistic studies suggest that the prevalence of misdiagnosis is high in bipolar disorder ranging from 48% [30] to 69% [31]. One study has investigated the association between age and diagnostic stability in bipolar disorder [32]. Although misclassification seemed to decrease with age, amongst older patients the prevalence of misclassification still appears substantial [32]. Amongst patients who were older than 60 years at first psychiatric
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hospital contact, 66.9% got a diagnosis of bipolar disorder at this contact compared with 55.1%, 52.8% and 34.9% amongst individuals aged 40–60, 20–40 or individuals younger than 20 years of age, respectively [32]. The most prevalent diagnoses other than bipolar disorder were depressive disorder (38.6%), acute psychotic disorders (15.6%), stress or adjustment disorder (10.4%) and disorders due to substance use (9.2%).
Course of illness While mean age of onset of illness for bipolar disorder has been found to be approximately 28 years, a wide range of onset has been reported [33]. In a pooled sample of 1300 patients, fewer than 5% of individuals had their first age of onset of illness after age 60 [33]. Depp and Jeste identified 13 studies in older bipolar patients that reported age of onset of any psychiatric disorder and eight studies that reported age of first onset of mania [8]. The sample-weighted mean age of these samples was 68.2 years (SD ¼ 3.9; range 60–72). The weighted mean age of onset of any affective disorder was 48.0 years (SD ¼ 6.4; range 28–65) and age of onset of mania was 56.4 years (SD ¼ 7.3; range 38–70). These figures indicate that the average older person with bipolar disorder/mania has experienced affective symptoms for 20 years, and that the age of onset for elderly people is substantially later than that in younger individuals [8]. Several studies have found a bimodal distribution of age at onset [14,34], especially amongst women [17], with an intermode at age 65, but others have not [10,14,35–39]. The reason for the discrepancies may be differences in composition of gender and type of contact (outpatient vs. inpatient) between studies, as age at onset may vary according to these factors [17]. The course of illness in bipolar disorder appears heterogeneous. Early clinical observations suggested that ageing with bipolar disorder was associated with longer duration of episodes and higher rates of recurrence [40], whereas later observations suggest that bipolar burns out later in life [41]. More recent data suggest that for patients with late onset bipolar disorder, the course of illness is progressive with an increasing risk of recurrence for every new episode [42]. Despite this progressive recurrency during the course of illness, the rate of relapse leading to psychiatric hospitalization following first affective episode seems to decrease with age (age < 30, RR ¼ 1; age 30–44, RR ¼ 0.887; age 45–59, RR ¼ 0.701; age 60–79, RR ¼ 0.686; age 80 þ , RR ¼ 0.617; d.f. ¼ 4, P < 0.0001; [43]). In contrast, data from the prospective long-term Zurich study by Angst and colleagues suggest that the risk of recurrence following any affective episode seems to be increased amongst the elderly [44]. Regarding recovery from episodes, the rate of recovery seems to be constant across affective episodes in modern
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treatment settings and across the life-span [45]. It is unclear whether the rate of functional recovery varies with age [8]. Some older patients with bipolar disorder develop rapid cycling but it is unknown whether the prevalence and presentation of rapid cycling differ between elderly and younger people [8]. The risk of completed suicide in bipolar disorder has been found highest amongst patients under age 35 [46], suggesting that older patients with early-onset of bipolar disorder have a decreased rate of suicide, presumably as such patients may belong to a survivor cohort [8]. The rate of suicide amongst older patients with late-onset of bipolar disorder has not been specifically investigated, but it is possible that such patients have an increased rate of suicide due to the potential additive effect of higher risk of suicide in both elderly and in bipolar populations [8].
Comorbidity Medical comorbidity Bipolar disorder ranks in the top 10 of the worlds most disabling conditions [47]. It has been suggested that 40–70% of personal and societal costs of bipolar illness are attributable to medical comorbidity, and it is known that elderly bipolar individuals are disproportionately affected by medical burden, particularly cardiovascular disease, diabetes, hypertension, hyperlipidaemia and obesity [48]. McIntyre [49] reported that amongst 938 individuals who screened positive for a lifetime manic episode from a database of 36 984, 64.3% had a chronic medical condition, compared to 48.3% of the non-manic patients. Approximately 20% of elderly bipolar elders have seven or more comorbid medical diagnoses [50]. Gildengers and colleagues [51] recently analysed medical burden in 54 elders with bipolar I or II disorder, compared to 108 elders with major depression matched on age, sex, race, and lifetime duration of mood disorder illness. This analysis found that while overall medical burden was comparable in elders with bipolar disorder versus major depression, individuals with bipolar disorder had higher body mass index (BMI) and greater burden of endocrine/metabolic and respiratory disease [51]. Krishnan [52] has noted that it is often not clear whether medical disorders amongst those with bipolar disorder are truly comorbid, a consequence of treatment, or a combination of both. In the case of some of the more common medical comorbidities, such as diabetes, there may be a bidirectional relationship between bipolar and medical illnesses [53]. Unfortunately, it is also known that older individuals with bipolar disorder are less likely to receive adequate care for the most common medical conditions [54–56], and medical disorders in bipolar populations contribute to increased morbidity and mortality. Patients
with bipolar disorder have been demonstrated to suffer premature mortality from cardiovascular disease compared to the general population [57]. In addition to the morbidity and mortality associated with medical illness, medical conditions are associated with a more disabling course of bipolar illness [49]. One aspect of particular relevance to older adults is the potential for increased suicidality in the context of worsening medical comorbidity. Juurlink [58] reported a robust association between the cumulative number of illnesses and the estimated relative risk of suicide [58], noting that individuals with five illnesses have a five-fold increase in suicide risk. A special consideration for older adult populations with manic symptoms is secondary mania due to medical or neurological causes or mania related to medications. While secondary mania is not exclusive to elderly populations, it occurs more often in the elderly compared with younger individuals [59] and is generally associated with an absence of either previous psychiatric history or family psychiatry history [60]. An extensive list of potential causes for secondary mania has been identified including endogenous factors such as thyroid abnormalities, and dementia-related disinhibition or agitation, as well as a host of possible precipitant medications and toxins [60]. Causes uncovered on neuro-imaging include encephalomalacia or brain tumour, right hemispheric cerebrovascular events or lesions of the orbitofrontal circuit, silent cerebral infarctions and traumatic brain injury [7]. Similar to the vascular depression hypothesis [61], which posits a relationship between vascular injury and subsequent depression, it has been suggested that there is also a vascular sub-type of mania [53,62]. Brain magnetic resonance imaging studies demonstrate a higher prevalence of white matter hyperintensities amongst elderly individuals with late-onset bipolar disorder compared to controls and elders with early-onset bipolarity [63].
Psychiatric comorbidity Psychiatric comorbidity is extremely common amongst mixed- age populations with bipolar disorder, particularly substance use disorders and anxiety disorders [64]. Substance use comorbidity is seen amongst bipolar populations more than with any other Axis I disorder [65]. Rates for comorbid psychiatric illnesses may be somewhat lower for bipolar elders compared to that seen in younger populations. Rates of lifetime substance abuse reported in bipolar patients over the age of 60 ranges between 13% and 38% [8,66–68], compared to 61% in mixed-age populations [64]. Goldstein and colleagues [67] found lifetime and 12-month rates of alcohol use disorder (38.1% and 38.1%, respectively), dysthymia (15.5% and 7.1%), generalized anxiety disorder (GAD (20.5% and 9.5%) and panic disorder (19.0% and 11.9%) in bipolar older adults. Fenn and
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colleagues [69] reported that trends for other psychiatric comorbidities were highest amongst individuals under age 50 and that there were significant age effects were found in younger cohorts for current obsessive-compulsive disorder and cannabis use disorder [69]. As with younger populations, substance use comorbidity in bipolar elders is generally associated with more negative outcomes, as demonstrated by the study by Cassidy and colleagues [70], in which substance abuse was associated with a greater number of hospitalizations amongst bipolar elders. Both panic disorder and GAD have been found in significantly higher prevalence in patients with bipolar disorder compared to the general population. A study involving 4668 geriatric veterans with bipolar disorder found Post-traumatic stress disorder (PTSD) in 875 (5.4%) and other anxiety disorders in 1592 (9.7%) [71]. Goldstein and colleagues [67] recently reported that elderly men with bipolar disorder have a greater prevalence of alcoholism, while elderly women with bipolar disorder have a greater prevalence of anxiety disorder. While there is very limited data on personality disorder prevalence or presentation amongst geriatric bipolar populations, a small clinical sample (N ¼ 27) by Molinari and Marmion found Axis II disorders present in 70% of geropsychiatric inpatients and outpatients. It must be remembered that cross-sectional analyses of older adult bipolar samples likely represent a survivor cohort, and that individuals with bipolar disorder complicated by severe comorbidity or multiple comorbidities might be expected to have increased morbidity and overall reduced life-span.
Cognitive function Cognitive impairment has been reported in euthymic mixed-age patients with bipolar disorders. Verbal memory, attention and executive function impairments are the most consistent findings [72]. Only a few studies have assessed cognitive function during the euthymic phase of old-age bipolar disorder. Broadhead and Jacoby studied manic patients who recovered prior to discharge, and found that 25% of the older group scored in the demented range on the Kendrick Battery Subtests [23]. Kessing compared 118 unipolar patients, 28 bipolar patients during euthymia and 58 controls with a mean age over 60 years [73]. Analyses were adjusted for differences in the level of education and for subclinical depressive and anxiety symptoms. No differences were found between patients with bipolar disorder and patients with unipolar disorder. Patients with recurrent episodes were significantly more impaired than patients with a single episode and more impaired than controls. Also, within patients, the number of prior episodes seemed to be associated with cognitive outcome. In a more recent study, nearly half of late-life bipolar patients showed one or more standard deviations from the mean compared to
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healthy controls on the Mini-Mental State Examination (MMSE) and Mattis Dementia Rating Scale, and 17% scored between one and two standard deviations below the mean of the comparison subjects on the Executive Interview [74]. Martino et al. found worse performance amongst 20 older patients with bipolar disorder during the euthymic phase compared to healthy controls in psychomotor speed, verbal memory and executive functions, even after controlling sub-clinical symptomatology [75]. These findings were not associated with age at onset, length of illness or current pharmacological exposure. Psychosocial functioning correlated negatively with psychomotor speed, executive function and extrapyramidal symptoms. Based on these data, it is estimated that overall approximately half of euthymic bipolar patients over the age of 60 years might exhibit neupsychological deficits [74,76]. The prevalence of dementia in older people with bipolar disorder has received inadequate attention [8]. Kessing and colleagues have found that patients discharged from a firstever psychiatric hospitalization with a diagnosis of mania or bipolar disorder had increased risk of subsequent dementia diagnosis on subsequent hospital readmission compared to patients with a diagnosis of neurosis and compared to the general population [77] or patients with osteoarthritis or diabetes [78]. Furthermore, the rate of a diagnosis of dementia on readmission was significantly related to the number of prior affective episodes leading to admission. On average, the rate of dementia tended to increase 6% with every affective episode leading to admission for bipolar patients, when adjusted for differences in age and gender [79]. Results from a new nationwide Danish register-based study suggest that maintenance lithium treatment is associated with a reduced rate of dementia, to the same level as for the general population [80]; however, methodological reasons for this finding, particular unknown confounding factors, cannot be excluded. Mechanism of action of lithium in relation to dementia is not clear but lithium has been found to inhibit glycogen synthase kinase-3, which is a key enzyme in the metabolism of amyloid precursor protein and in the phosphorylation of tau protein involved in the pathogenesis of Alzheimers disease [81–83]. In addition, in bipolar elders (mean age 66.0 9.7 years), brain lithium levels and N acetyl aspartate (NAA) seems to be positively associated in magnetic resonance spectroscopy (MRS), supporting the evidence of neuroprotective/neurotrophic effects of lithium [84].
Treatment effects While treatment of late-life bipolar disorder has primarily been informed by evidence from mixed-age and younger adult populations, extrapolating such data does not take into account important ageing-related pharmacodynamic
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and pharmacokinetic factors as well as psychosocial contexts typical for geriatric bipolar populations [3]. There is a general paucity of treatment data specific to late-life bipolar illness with no published, placebo-controlled randomized trials. Fortunately, there have been some recent larger-scale trials that are anticipated to provide important future information regarding medication treatment efficacy and tolerability in geriatric patients [85,86].
Geriatric mania First-line treatments for mixed-age populations with bipolar mania include lithium, selected anticonvulsant compounds (valproate, carbamezepine) and antipsychotic medications. A review of studies by Young and colleagues [87] of lithium therapy in bipolar, predominantly manic elders, found that two-thirds of older patients improved with lithium therapy, with serum lithium levels ranging from 0.3–2.0 mEq/L. Older adults with classic mania and minimal neurological impairment might be anticipated to do the best on lithium therapy [88]. A particular risk with lithium therapy in elderly patients is due to reduced renal clearance and volume of distribution, generally occurring with age, and an increased propensity for elevated lithium concentrations [87]. Commonly prescribed concommitant medications, such as thiazide diuretics, NSAIDS and angiotensin converting enzyme (ACE) inhibitors all additionally increase serum lithium concentrations [89]. In summary, lithium appears to have good anti-manic activity in geriatric manic patients, but tolerability concerns may temper relative utility. Young and colleagues reviewed valproate studies in elderly manic patients [87], noting that overall, 59% of individuals improved with therapy. Drug dosing was in the order of 250–2250 mg/day with serum valproate levels of 25–120 mcg/ml. Chen and colleagues [90] suggested that geriatric manic patients with plasma valproate concentrations of 65–90 mcg/ml had more robust improvement than individuals with plasma levels of 45–65 mcg/ml. In elderly populations, intrinsic clearance of valproate is reduced by up to 39%, and the free fraction of serum valproate can increase by 44% [91]. Older adults on concomitant therapy with high-protein-binding drugs (e.g. aspirin or warfarin) may have elevated active drug levels. Both total and free serum levels of active drugs should thus be assessed if there is concern that measured total levels may not accurately reflect active circulating drug levels. Carbamezepine is generally a second-line anticonvulsant for treatment of acute mania in mixed-age populations [92]. It might be expected that, as with valproate, tolerability concerns need to be balanced with optimal target dosing for management of manic symptoms. Antipsychotic medications, particularly atypical or second-generation compounds have assumed a substantial
role in the management of acute mania in mixed-age populations, and there are uncontrolled trials and secondary analyses that suggest that most of the atypical antipsychotics including clozapine, risperidone, olanzapine, quetiapine and aripiprazole all have anti-manic activity in older adult populations with mania [89]. A particular concern with respect to geriatric populations is potentially increased mortality associated with both typical and atypical antipsychotic medications, and the US Food and Drug Administration (FDA) has specifically placed a black box warning on all atypical and typical agents, warning of a relatively small but significant increased risk of death in elderly patients with dementia-related psychoses [93]. It is not clear how completely the relative risk for mortality may be extrapolated to geriatric bipolar populations [89]. An additional risk concern in elderly populations with atypical antipsychotics is increased risk of weight gain, metabolic syndrome and diabetes. Correll and colleagues [94], reporting on patient treated with second-generation antipsychotics, have noted that older age is significantly associated with metabolic syndrome and that patients with metabolic syndrome have a doubled 10-year coronary heart disease risk.
Geriatric bipolar depression In spite of the extensive burden imposed by bipolar depression, the evidence-base for treatment of acute bipolar depression is generally rather limited [92]. First-line therapies in mixed-age patients include lithium, the anticonvulsants valproate, lamotrigine, atypical antipsychotics and combination therapy with antidepressant medications adjunct to mood stabilizers [92]. Uncontrolled and secondary analyses in geriatric bipolar depression suggest a possible role for lithium and for lamotrigine [87]. A small (n ¼ 20), uncontrolled study in older adult bipolar patients (mean age 59.6 years, range 50–83 years) found reduction in bipolar depressive symptoms with the atypical antipsychotic aripiprazole at a mean dosage of 10.26 mg/day SD 4.9 [95]. As with treatment of mania, dosing and tolerability concerns are paramount in the elderly, often limiting both choice of agent and maximum daily dose. While the role of antidepressant agents to treat bipolar depression in mixed-age populations is controversial, due to concerns regarding manic switching, mixed episodes and rapid cycling [92], preliminary data in geriatric bipolar depression suggests that antidepressants can have beneficial effects on selected health outcomes. One report demonstrated decreased rates of hospitalization for manic/ mixed episodes during a 5135 person-years follow-up study of antidepressant use amongst bipolar elders [96]. Another report suggested that bipolar elders with a recent history of suicide attempts were less likely to have received treatment with mood-stabilizers and antidepressants compared to
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bipolar elders with no recent history of suicide attempts [97]. Finally, it must be remembered that electroconvulsive therapy (ECT) may be particularly efficacious and well tolerated amongst elders with bipolar depression [98].
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needed to establish the utility and generalizability of interventions that address both bipolar and medical outcome in bipolar elders in an integrated fashion.
Adherence to treatment Maintenance treatment in geriatric bipolar disorder There is only very limited data on medication and psychotherapeutic approaches in geriatric bipolar maintenance treatment. A recent retrospective analysis of older adults with unipolar depression and bipolar disorder compared each patient to his/her own clinical course before and after lithium treatment. The probability of relapse and recurrence, suicidal behaviour and severity of mood disturbance were significantly decreased by lithium maintenance [99]. Sajatovic and colleagues [100] conducted a secondary analysis of older adults (age 55 and older) from two placebo-controlled, double-blind bipolar maintenance treatment studies. Patients were first treated with open-label lamotrigine for 8–16 weeks. Stabilized patients were randomized to treatment with lamotrigine, lithium or placebo for up to 18 months. The primary endpoint was time-to-intervention for any mood episode; secondary measures included timeto-intervention for depression and mania/hypomania/ mixed mood. Altogether, 638 patients qualified for the double-blind treatment phase and included 98 older adults. Mean age of the older adult sample was 61 years (SD 6.0, range 55–82 years). Lamotrigine, but not lithium, significantly delayed time-to-intervention for any mood episode compared with placebo. Lamotrigine also significantly delayed time-to-intervention for a depressive episode compared with lithium and placebo. Lithium did significantly better than lamotrigine for time-to-intervention for mania. Side effects for both lamotrigine and lithium were generally time-limited and mild to moderate in intensity, including similar rates of skin rash (3% for lamotrigine, 5% for lithium). Daily doses were 240 mg/day for lamotrigine and 750 mg/day for lithium. As bipolar disorder is a chronic illness, life-stage or developmental issues arise that, over time, must be addressed within the context of ageing. McBride and Bauer [101] have suggested that older adults with bipolar disorder appear to benefit from psychosocial interventions that assist in managing both mental illness and ageingrelated issues. Kilbourne and colleagues [48] recently reported on the development, implementation and feasibility/tolerability of a manual-based medical care model (BCM) for older patients with bipolar disorder. The BCM included sessions on bipolar symptom patient self management, use of nurse-run coordination/management and dissemination of guidelines to care providers on cardiovascular disease risk in bipolar elders [48]. While the BCM model appears feasible and well accepted, future work is
While the past decade has seen proliferation of available medication treatments for individuals with bipolar disorder, it has been demonstrated that nearly one in two individuals is non-adherent with prescribed medications [102,103]. Treatment non-adherence is noted to contribute to illness relapse, hospitalization and other negative sequelae [103,104]. Characteristics that appear to be associated with adherence include age, marital status, gender, educational level and psychiatric comorbidity, in particular substance abuse [102,105,106]. One study [107] specifically compared adherence with antipsychotic medication amongst older (age 60 and older) versus younger individuals with bipolar disorder using a large VA case registry (N ¼ 73 964). Medication adherence was evaluated using pharmacy refill patterns. Amongst older adults, 61.0% (N ¼ 3350) were fully adherent, while 19% (N ¼ 1043) were partially adherent and 20% (N ¼ 1098) were non-adherent. Amongst younger adults, 49.5% (N ¼ 10 644) were fully adherent, while 21.8% (N ¼ 4680) were partially adherent and 28.7% (N ¼ 6170) were non-adherent. Comorbid substance abuse and homelessness predicted non-adherence and overall, a substantial proportion (39%) of bipolar older adults had difficulties with adherence.
Attitudes and beliefs/satisfaction with treatment A recent review [102] concluded that attitudes and beliefs are at least as important as side effects in predicting adherence in depressive and bipolar disorders [108–110]. Beliefs and expectations have been found to be associated with non-adherence to lithium [102,111,112] and a recent study similarly concluded that attitudes and behaviours are better predictors of non-adherence to mood-stabilizers than side effects of medication [113]. There are rather consistent findings on the correlation between knowledge of mood stabilizers and age – patients knowledge of mood-stabilizers has been found to correlate negatively with age, whereas sex and duration of treatment seem unrelated to knowledge [114,115]. Furthermore, using the Mood-Stabilizer Compliance Questionnaire (MSQC) [115], older patients with bipolar disorder consistently have a more negative view on the doctor-patient relationship, more non-correct views on the effect of mood-stabilizers and a more negative view on mood-stabilizers [115]. Such attitudes may result in reluctance to take mood-stabilizers in the long run. The relation to age is further in accordance with results from studies of the general population [116,117], suggesting that
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the elderly have less correct knowledge on mental illnesses and depression and are more critical towards diagnosis and treatment. As moodstabilizers often are prescribed for many years and as elderly patients may present with cognitive dysfunction and comorbidity, lack of knowledge and a critical attitude towards diagnosis and treatment may further deteriorate the prognosis [115]. This may explain relatively low rates of treatment adherence in individuals over the age of 60 [118]. On the other hand, there is a general finding that older patients are more satisfied with health care. A meta-analysis on satisfaction with medical care concludes that amongst a number of variables, age has the strongest positive correlation with satisfaction with care [118]. This also seems to be the case for patients with bipolar disorder. Using a comprehensive multi-dimensional questionnaire scale, The Verona Service Satisfaction Scale – Affective (VSSS-A), it was found that older patients were consistently more satisfied with psychiatric care, that is the professionals skills and behaviour, the information, the access of the service, the efficacy and the type of intervention provided [119]. Thus, on the one hand, elderly patients with bipolar disorder often present with incorrect views on diagnosis and treatment possibly resulting in decreased adherence to treatment, and on the other hand, they may be more satisfied with treatment. For these reasons older patients may be at risk of undetected non-adherence as they may simple not inform the doctor of their non-adherence to medical treatment.
Clinical recommendations Assessment and treatment of older adults with bipolar disorder represents a relative treatment challenge. Overall, clinicians need to be attentive to the issue of diagnosis, and consider possible bipolarity in elders with depressive symptoms. Assessment of elderly individuals with no previous history of mania should include assessment of family history and careful analysis and characterization of prior mood episodes. In some cases past/remote episodes of mania or hypomania are missed or incorrectly diagnosed, particularly with mania/hypomania presenting with irritability, or postpartum mood states amongst female patients. Medication history should be evaluated amongst elders with apparent new-onset mania, including new treatments that may have been initiated by medical sub-specialists (e.g. initiation of steroids for rheumatologic conditions) and use of complementary and/or alternative treatment that the patient may have initiated on his or her own (e.g. Saint Johns Wort). A complete physical and neurological examination should include laboratory assessment with comprehensive metabolic panel, complete blood count (CBC), thyroid function, toxicology screen and more specialized
assessments as may be indicated by the history, physical or neurological examination. Brain imaging (i.e. CT or MRI) to rule out acute CNS pathology should be complemented by additional studies, such as EEG and lumbar puncture with CSF analysis as indicated. Treatments of both acute mania and acute bipolar depression, as noted previously, are informed by the published evidence in mixed-age populations, but should always include treatment with a foundational moodstabilizing medication (lithium, anticonvulsant or atypical antipsychotic compound known to be effective for the treatment of patients with bipolar disorder). It is very likely that two or more psychotropic compounds used concurrently will be required to achieve recovery or optimal management of symptoms. Antidepressant monotherapy is generally not recommended due to the potential for precipitation of mania, and antidepressant drugs should be discontinued in elders who develop mania/hypomania. Clinicians should be alert to the possibility that elderly patients may be prescribed drugs in the antidepressant class for non-psychiatric indications, for example duloxetine for diabetic neuropathy and that these treatments may complicate bipolar outcomes. Medication dosing modifications in bipolar elders will generally be required and should be guided by medical burden/frailty as well as the presence of medications that are inevitably prescribed for medical illnesses. Family members and/or caregivers should be involved in treatment planning to the extent possible, and can assist clinicians in evaluating such critical factors as on-going treatment adherence or the development of medication intolerance that may develop over time (e.g. tremor or cognitive impairments that may occur with lithium therapy). Laboratory monitoring, such as renal function must be evaluated longitudinally. Finally, it must be remembered that the ageing process will in itself often necessitate modifications in both medication and psychosocial treatments for bipolar illness. For example, an individual who has been maintained for many years on lithium monotherapy may develop neurological symptoms at a serum lithium level that was previously well-tolerated. The treating clinician must then determine whether to reduce lithium dose (possibly with the addition of an augmenting agent) or change to an alternative agent. While there is often no correct answer this and similar clinical scenarios, bipolar elders will generally require close clinical monitoring, flexibility on the part of the treating clinician and utilization of available supports such as family or ancillary care staff.
Conclusions and areas for future research Demographic trends predict a growing number of older adults with bipolar disorder. While the literature on late-life bipolarity has increased in recent years, numerous and
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important gaps persist, including insufficient information on the neurobiology, epidemiology and phenomenology to fully understand future healthcare requirements and to inform care-system planning. It is clear that bipolar elders often experience substantial symptoms, functional impairment and extensive medical comorbidity. There is minimal evidence to support specific pharmacologic or psychosocial interventions for either acute or longer-term care of bipolar elders. Data from mixed-age bipolar treatment trials can not be readily extrapolated to geriatric populations given the expected ageing-related biologic and social contexts. More research is critically needed to understand expected illness trajectory, relationship to cognitive status and treatments that optimize all levels of health and functioning.
References 1. http://www.un.org/News/Press/docs/2005/pop918. doc.htm United Nations Press Release. Accessed Sept 15, 2008. 2. Cade, J.F.L. (1949) Lithium salts in the treatment of psychotic excitement. Med. J. Aust., 3, 349–352. 3. Gyulai, L.,and Young, R. (2008) New research perspectives in the treatment of bipolar disorder in older adults. Bipolar Disord., 10, 659–661. 4. Kessler, R.C., Berglund, P., Demler, O. et al. (2005) Lifetime prevalence and age-of-onset distributions of DSM-IV disorders in the national comorbidity survey replication. Arch. General Psychiatry, 62, 593–602. 5. Unutzer, J., Simon, G., Pabiniak, C. et al. (1998) The treated prevalence of bipolar disorder in a large staff-model HMO. Psychiatr. Serv., 49, 1072–1078. 6. Hirschfeld, R.M., Calabrese, J.R., Weissman, M.M. et al. (2003) Screening for bipolar disorder in the community. J. Clin. Psychiatr., 64, 53–59. 7. Chen, P., Ahmed, M. and Sajatovic, M. (2006) Bipolar Disorder in later life. Aging Health, 2, 333–347. 8. Depp, C.A. and Jeste, D.V. (2004) Bipolar disorder in older adults: a critical review. Bipolar Disord., 6, 343–367. 9. Depp, C.A., Lindamer, L.A., Folsom, D.P. et al. (2005) Differences in clinical features and mental health service use in bipolar disorder across the lifespan. Am. J. Geriatr. Psychiatry, 13, 290–298. 10. Almeida, O. and Fenner, S. (2002) Bipolar disorder: similarities and differences between patients with illness onset before and after 65 years of age. Int. Psychogeriatr., 14, 311–322. 11. Schurhoff, F., Bellivier, F., Jouvent, R. et al. (2000) Early and late onset bipolar disorders: two different forms of manicdepressive illness? J. Affect. Disord., 58, 215–221. 12. Fujikawa, T., Yamawaki, S. and Touhouda, Y. (1995) Silent cerebral infarctions in patients with late-onset mania. Stroke, 26, 946–949. 13. Hays, J.C., Krishnan, K.R., George, L.K. and Blazer, D.G. (1998) Age of first onset of bipolar disorder: demographic,
14. 15.
16.
17. 18. 19.
20.
21.
22.
23. 24.
25. 26. 27.
28. 29. 30.
31.
32.
33.
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family history, and psychosocial correlates. Depress Anxiety, 7, 76–82. Cassidy, F. and Carroll, B.J. (2002) Vascular risk factors in late onset mania. Psychol. Med., 32, 359–362. Yassa, R., Nair, V., Nastase, C. et al. (1988) Prevalence of bipolar disorder in a psychogeriatric population. J. Affect. Disord., 14, 197–201. Kessing, L.V., Agerbo, E. and Mortensen, P.B. (2004) Major stressful life events and other risk factors for first admission with mania. Bipolar Disord., 6, 122–129. Kessing, L.V. (2005) Diagnostic subtypes of bipolar disorder in older versus younger adults. Bipolar Disord., 7, 1–9. McGlashan, T.H. (1988) Adolescent versus adult onset of mania. Am. J. Psychiatry, 145, 221–223. Rosen, L.N., Rosenthal, N.E., Van Dusen, P.H. et al. (1983) Age at onset and number of psychotic symptoms in bipolar I and schizoaffective disorder. Am. J. Psychiatry, 140, 1523–1524. Wylie, M.E., Mulsant, B.H., Pollock, B.G. et al. (1999) Age at onset in geriatric bipolar disorder. Effects on clinical presentation and treatment outcomes in an inpatient sample. Am. J. Geriatr. Psychiatry, 7, 77–83. Depp, C.A., Jin, H., Mohamed, S. et al. (2004) Bipolar disorder in middle-aged and elderly adults: is age of onset important? J. Nerv. Ment. Dis., 192, 796–799. Ernst, C.L. and Goldberg, J.F. (2004) Clinical features related to age at onset in bipolar disorder. J. Affect. Disord., 82, 21–27. Broadhead, J. and Jacoby, R. (1990) Mania in old age: A first prospective study. Int. J. Geriatr. Psychiatry, 5, 215–222. Carlson, G.A., Davenport, Y.B. and Jamison, K. (1977) A comparison of outcome in adoles. Am. J. Psychiatry, 134, 919–922. Blackburn, I.M., Loudon, J.B. and Ashworth, C.M. (1977) A new scale for measuring mania. Psychol. Med., 7, 453–458. Kessing, L.V. (2004) Gender differences in the phenomenology of bipolar disorder. Bipolar Disord., 6, 421–425. Taylor, M. and Abrams, R. (1973) Manic states. A genetic study of early and late onset affective disorders. Arch. Gen. Psychiatry, 28, 656–658. Tohen, M., Shulman, K.I. and Satlin, A. (1994) First-episode mania in late life. Am. J. Psychiatry, 151, 130–132. Kessing, L.V. (2006) Gender differences in subtypes of lateonset depression and mania. Int. Psychogeriatr., 9, 1–12. Lish, J.D., Dime-Meenan, S., Whybrow, P.C. et al. (1994) The National Depressive and Manic-depressive Association (DMDA) survey of bipolar members. J. Affect. Disord., 31, 281–294. Hirschfeld, R.M., Lewis, L. and Vornik, L.A. (2003) Perceptions and impact of bipolar disorder: how far have we really come? Results of the national depressive and manic-depressive association 2000 survey of individuals with bipolar disorder. J. Clin. Psychiatry, 64, 161–174. Kessing, L.V. (2005) Diagnostic stability in bipolar disorder in clinical practise as according to ICD-10. J. Affect. Disord., 85, 293–299. Goodwin, F.K. and Jamison, K.R. (1990) Manic-Depressive Illness, Oxford University Press, Oxford.
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|
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34. Sibisi, C.D. (1990) Sex differences in the age of onset of bipolar affective illness. Br. J. Psychiatry, 156, 842–845. 35. Spicer, C.C., Hare, E.H. and Slater, E. (1973) Neurotic and psychotic forms of depressive illness: evidence from ageincidence in a national sample. Br. J. Psychiatry, 123, 535–541. 36. Loranger, A.W. and Levine, P.M. (1978) Age at onset of bipolar affective illness. Arch. Gen. Psychiatry, 35, 1345–1348. 37. Baron, M., Risch, N. and Mendlewicz, J. (1982) Age at onset in bipolar-related major affective illness: clinical and genetic implications. J. Psychiatr. Res., 17, 5–18. 38. Joyce, P.R. (1984) Age of onset in bipolar affective disorder and misdiagnosis as schizophrenia. Psychol. Med., 14, 145–149. 39. Eagles, J.M. and Whalley, L.J. (1985) Ageing and affective disorders: the age at first onset of affective disorders in Scotland, 1969–1978. Br. J. Psychiatry, 147, 180–187. 40. Rennie, T. (1942) Prognosis in manic-depressive illness. Am. J. Psychiatry, 98, 801–814. 41. Winokur, G. (1975) The Iowa 500: heterogeneity and course in manic-depressive illness (bipolar). Compr. Psychiatry, 16, 125–131. 42. Kessing, L.V. (1998) Recurrence in affective disorder. II. Effect of age and gender. Br. J. Psychiatry, 172, 29–34. 43. Kessing, L.V., Hansen, M.G. and Andersen, P.K. (2004) Course of illness in depressive and bipolar disorders. Naturalistic study, 1994–1999. Br. J. Psychiatry, 185, 372–377. 44. Angst, J. and Preisig, M. (1995) Course of a clinical cohort of unipolar, bipolar and schizoaffective patients. Results of a prospective study from 1959 to 1985. Schweiz. Arch. Neurol. Psychiatr., 146, 5–16. 45. Kessing, L.V. and Mortensen, P.B. (1999) Recovery from episodes during the course of affective disorder: a caseregister study. Acta Psychiatr. Scand., 100, 279–287. 46. Tsai, S.Y., Kuo, C.J., Chen, C.C. and Lee, H.C. (2002) Risk factors for completed suicide in bipolar disorder. J. Clin. Psychiatry, 63, 469–476. 47. Murray, C.J. and Lopez, A.D. (1996) Evidence-based health policy–Global Burden of Disease Study. Science, 274, 740–743. 48. Kilbourne, A.M., Post, E.P., Nossek, A. et al. (2008) Service delivery in older patients with bipolar disorder: a review and development of a medical care model. Bipolar Disord., 10, 672–683. 49. McIntyre, R.S., Konarski, J.Z., Socznyska, J.K. et al. (2006) Medical comorbidity in bipolar disorder: implications for functional outcomes and health service utilization. Psychiatr. Serv., 57, 1140–1144. 50. Brown, S. (1998) Variations in utilization and cost of inpatient psychiatric services among adults in Maryland. Psychatr. Serv., 52, 841–843. 51. Gildengers, A.G., Whyte, E.M., Drayer, R.A. et al. (2008) Medical burden in late-life bipolar and major depressive disorders. Am. J. Geriatric Psychiatry, 16, 194–200. 52. Krishnan, K.R. (2005) Psychiatric and medical comorbidities of bipolar disorder. Psychosom. Med., 67, 1–8. 53. Kales, H.C. (2007) Medical comorbidity in late-life bipolar disorder, in Bipolar Disorders in Later Life (eds M. Sajatovic
54.
55.
56.
57. 58.
59.
60.
61.
62.
63.
64.
65.
66.
67.
68.
69.
70. 71.
and F. Blow), Johns Hopkins Press, Baltimore, MD, pp. 162–181. Druss, B.G., Bradford, W.K., Rosenheck, R.A. et al. (2001) Quality of medical care and excess mortality in older patients with mental disorders. Arch. Gen. Psychiatry, 58, 565–572. Desai, M.M., Rosenheck, R.A., Druss, B.G. et al. (2002) Mental disorders and quality of diabetes care in the veterans health administration. Am. J. Psychiatry, 159, 1584–1590. Kilbourne, A.M., Post, E.P., Zeber, J.E. et al. (2007) For the CIVIC-MD project team. Therapetuic drug and metabolic risk factor monitoring in veterans with bipolar disorder. J. Affect. Disord., 102, 145–151. Sharma, R. and Markar, H.R. (1994) Mortality in affective disorder. J. Affect. Disord., 31, 91–96. Juurlink, D.N., Herrmann, N., Szalai, J.P. et al. (2004) Medical illness and the risk of suicide in the elderly. Arch. Intern. Med., 164, 1179–1184. Krauthammer, C. and Klerman, G.L. (1978) Secondary Mania: manic syndromes associated with antecedent physical illness or drugs. Arch. Gen. Psychiatry, 35, 1333–1339. Van Gerpen, M.W., Johnson, J.E. and Winstead, D.K. (1999) Mania in the geriatric patient population: a review of the literature. Am. J. Geriatr. Psychiatr., 7, 188–202. Alexopoulos, G.S., Meyers, B.S., Young, R.C. et al. (1997) Vascular depression hypothesis. Arch. Gen. Psychiatry, 54, 915–922. Steffens, D.C. and Krishnan, K.R. (1998) Structural neuroimaging and mood disorders. Recent findings, implications for classification, and future directions. Biol. Psychiatry, 43, 705–712. Tamashio, J.H., Zung, S., Zanetti, M.V. et al. (2008) Increased rates of white matter hyperintensities in late-onset bipolar disorder. Bipolar Disord., 10, 765–775. Kessler, R.C., Rubinow, D.R., Holmes, C. et al. (1997) The epidemiology of DSM-III R bipolar I disorder in a general population survey. Psychol. Med., 27, 1079–1089. Suppes, T., Dennehy, E.B. and Gibbons, E.W. (2000) The longitudinal course of bipolar disorder. J. Clin. Psychaitry, 61 (suppl), 23–30. Ponce, H., Kunik, M., Molinari, V. et al. (1999) Divalproex sodium treatment in elderly male bipolar patients. J. Geriatr. Drug Therapy, 12, 55–63. Goldstein, B.I., Harrmann, N. and Shulman, K.I. (2006) Comorbidity in bipolar disorder among the elderly: results from an epidemiological community sample. Am. J. Psychiatry, 163, 319–321. Sajatovic, M., Blow, F.C., Ignacio, R. and Kales, H.C. (2005) New onset bipolar disorder in later life. Am. J. Geriatr. Psychiatry, 13, 282–289. Fenn, H.H., Bauer, M.S., Altshuler, L. et al. (2005) Medical comorbidity and health-related quality of life in bipolar disorder across the adult age span. J. Affect. Disord., 86, 47–60. Cassidy, F., Ahearn, P. and Carroll, B. (2001) Substance use in bipolar disorder. Bipolar Disord., 3, 181–188. Sajatovic, M., Blow, F.C. and Ignacio, R.V. (2006) Psychiatric comorbidity in older adults with bipolar disorder. Int. J. Geriatr. Psych., 21, 582–587.
Bipolar Disorder in the Elderly 72. Robinson, L.J., Thompson, J.M., Gallagher, P. et al. (2006) A meta-analysis of cognitive deficits in euthymic patients with bipolar disorder. J. Affect. Disord., 93, 105–115. 73. Kessing, L.V. (1998) Cognitive impairment in the euthymic phase of affective disorder. Psychol. Med., 28, 1027–1038. 74. Gildengers, A.G., Butters, M.A., Seligman, K. et al. (2004) Cognitive functioning in late-life bipolar disorder. Am. J. Psychiatry, 161, 736–738. 75. Martino, D.J., Igoa, A., Marengo, E. et al. (2008) Cognitive and motor features in elderly people with bipolar disorder. J. Affect. Disord., 105, 291–295. 76. Tsai, S.Y., Lee, H.C., Chen, C.C. and Huang, Y.L. (2007) Cognitive impairment in later life in patients with earlyonset bipolar disorder. Bipolar Disord., 9, 868–875. 77. Kessing, L.V., Olsen, E.W., Mortensen, P.B. and Andersen, P.K. (1999) Dementia in affective disorder: a case-register study. Acta Psychiatr. Scand, 100, 176–185. 78. Kessing, L.V. and Nilsson, F.M. (2003) Increased risk of developing dementia in patients with major affective disorders compared to patients with other medical illnesses. J. Affect. Disord., 73, 261–269. 79. Kessing, L.V. and Andersen, P.K. (2004) Does the risk of developing dementia increase with the number of episodes in patients with depressive disorder and in patients with bipolar disorder? J. Neurol. Neurosurg. Psychiatry, 75, 1662–1666. 80. Kessing, L.V., Søndergaard, L., Forman, J.L. and Andersen, P.K. (2008) Lithium treatment and risk of dementia. Arch. Gen. Psychiatry, 65, 1331–1335. 81. Manji, H.K., Moore, G.J. and Chen, G. (2000) Clinical and preclinical evidence for the neurotrophic effects of mood stabilizers: implications for the pathophysiology and treatment of manic-depressive illness. Biol. Psychiatry, 48, 740–754. 82. Caccamo, A., Oddo, S., Tran, L.X. and LaFerla, F.M. (2007) Lithium reduces tau phosphorylation but not A beta or working memory deficits in a transgenic model with both plaques and tangles. Am. J. Pathol., 170, 1669–1675. 83. Fountoulakis, K.N., Vieta, E., Bouras, C. et al. (2008) A systematic review of existing data on long-term lithium therapy: neuroprotective or neurotoxic? Int. J. Neuropsychopharmacol., 11, 269–287. 84. Forester, P.B., Fin, C.T., Berlow, Y.A. et al. (2008) Grain lithium, N-acetyl aspartate and myo-inosital levels in older adults with bipolar disorder treated with lithium: a lithium7 and proton magnetic resonance spectroscopy study. Bipolar Disord., 10, 691–700. 85. Young, R.C., Beyer, J., Gyulai, L. et al. (2005) A randomized, controlled trial of acute treatments in late-life mania. International Congress Bipolar Disorder (New Research). P270, June 16–18, Pittsburgh, PA, USA. 86. Geddes, J.R., Rendell, J.M. and Goodwin, G.M. (2002) BALANCE: a large simple trial of maintenance treatment for bipolar disorder. World Psychiatry, 1, 48–51. 87. Young, R.C., Gyulai, L., Mulsant, B.H. et al. (2004) Pharmacotherapy of bipolar disorder in old age: review and recommendations. Am. J. Geriatr. Psychiatry, 12, 342–357.
|
497
88. Sajatovic, M. (2002) Treatment of bipolar disorder in older adults. Int. J. Geriatr. Psychiatry, 17, 865–873. 89. Aziz, R., Lorber, B. and Tampi, R.R. (2006) Treatments for late-life bipolar disorder. Am. J. Geriatr. Psychiatry, 4, 347–364. 90. Chen, S.T., Altshuler, L.L., Melnyk, K.A. et al. (1999) Efficacy of lithium vs valproate in the treatment of mania in the elderly: a retrospective study. J. Clin. Psychiatry, 60, 181–186. 91. Dunner, D.L. (2005) Safety and tolerability of emerging pharmacological treatment for bipolar disorder. Bipolar Disord., 7, 307–325. 92. Fountoulakis, K.N. and Vieta, E. (2008) Treatment of bipolar disorder: a systematic review of available data and clinical perspectives. Int. J. Neuropsychopharmacol., 11, 999–1029. 93. Food and Drug Administration, FDA Alert 6/16/2008. Information for Healthcare Professionals Antipsychotics, www.fda.gov/cder/drug/InfoSheets?HCP/antipsychotics_ conventional.htm. Accessed Oct 24, 2008. 94. Correll, C.U., Frederickson, A.M., Kane, J.M. and Manu, P. (2006) Metabolic syndrome and the risk of coronary health disease in 367 patients treated with second-generation antipsychotic drugs. J. Clin. Psychaitry, 67, 575–583. 95. Sajatovic, M., Coconcea, N., Ignacio, R.V. et al. (2008) Aripiprazole therapy in 20 older adults with bipolar disorder: A 12-week, open label trial. J. Clin. Psychiat., 69, 41–46. 96. Schaffer, A., Mamdani, M., Levitt, A. and Hermann, N. (2006) Effect of antidepressant use on admissions to hospital among elderly bipolar patients. Int. J. Geriatr. Psychiatry, 13, 275–280. 97. Aizenberg, D., Olmer, A. and Barak, Y. (2006) Suicide attempts amongst elderly bipolar patients. J. Affect. Disord., 91, 91–94. 98. Van der Wurff, F.B., Stek, M.L., Hoogendijk, W.J.G. and Beekman, A.T.F. (2003) The efficacy and safety of ECT in depressed older adults, a literature review. Int. J. Geriatr. Psychiatry, 18, 894–904. 99. Lepkifker, E., Iancu, I., Horesh, N. and Strous, R.D.,Kotler (2006) Lithium therapy for unipolar and bipolar depression among the middle-aged and older adult ptient subpopulation. Depression and Anxiety, 24, 571–576. 100. Sajatovic, M., Gyulai, L., Calabrese, J.R. et al. (2005) Maintenance treatment outcomes in older patients with bipolar I disorder. Am. J. Geriatr. Psychiatry, 13, 305–311. 101. McBride, L. and Bauer, M.S. (2007) Psychosocial interventions for older adults with bipolar disorder, in Bipolar Disorders in Later Life (eds M. Sajatovic and F. Blow), Johns Hopkins Press, Baltimore, MD. 102. Lingam, R. and Scott, J. (2002) Treatment non-adherence in affective disorders. Acta Psychiatr. Scand, 105, 164–172. 103. Perlick, D.A. (2004) Medication non-adherence in BPD: A patient – centered review of research findings. Clinical Approaches in Bipolar Disord., 3, 56–64. 104. Greenhouse, W.J., Meyer, B. and Johnson, S.L. (2000) Coping and medication adherence in BPD. J. Affect. Disord., 59, 237–241. 105. Berk, M., Berk, L. and Castle, D. (2004) A collaborative approach to the treatment alliance in BPD. Bipolar Disord., 6, 504–518.
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106. Aagaard, J., Vestergaard, P. and Maarbjerg, K. (1988) Adherence to lithium prophylaxis: II. Multivariate analysis of clinical, social, and psychosocial predictors of nonadherence. Pharmacopsychiatry, 21, 166–170. 107. Sajatovic, M., Blow, F.C., Kales, H.C. et al. (2007) Age comparison of treatment adherence with antipsychotic medications among individuals with bipolar disorder. Int. J. Geriatr. Psych., 22, 992–998. 108. Katon, W., Von Korff, M., Lin, E. et al. (1992) Adequacy and duration of antidepressant treatment in primary care. Med. Care, 30, 67–76. 109. Frank, E., Kupfer, D.J. and Siegel, L.R. (1995) Alliance not compliance: a philosophy of outpatient care. J. Clin. Psychiatry, 56 (Suppl 1), 11–16. 110. Schumann, C., Lenz, G., Berghofer, A. and Muller-Oerlinghausen, B. (1999) Non-adherence with long-term prophylaxis: a 6-year naturalistic follow- up study of affectively ill patients. Psychiatry Res., 27, 247–257. 111. Jamison, K.R., Gerner, R.H. and Goodwin, F.K. (1979) Patient and physician attitudes toward lithium: relationship to compliance. Arch. Gen. Psychiatry, 36, 866–869. 112. Cochran, S.D. (1984) Preventing medical noncompliance in the outpatient treatment of bipolar affective disorders. J. Consult. Clin. Psychol., 52, 873–878.
113. Scott, J. and Pope, M. (2002) Nonadherence with mood stabilizers: prevalence and predictors. J. Clin. Psychiatry, 63, 384–390. 114. Schaub, R.T., Berghoefer, A. and Muller-Oerlinghausen, B. (2001) What do patients in a lithium outpatient clinic know about lithium therapy? J. Psychiatry Neurosci., 26, 319–324. 115. Kessing, L.V., Hansen, H.V. and Bech, P. (2006) Attitudes and beliefs among patients treated with mood stabilizers. Clin. Pract. Epidemol. Ment. Health, 19, 8. 116. Hasin, D. and Link, B. (1988) Age and recognition of depression: implications for a cohort effect in major depression. Psychol. Med., 18, 683–688. 117. Fisher, L.J. and Goldney, R.D. (2003) Differences in community mental health literacy in older and younger Australians. Int. J. Geriatr. Psychiatry, 18, 33–40. 118. Hall, J.A. and Dornan, M.C. (1990) Patient sociodemographic characteristics as predictors of satisfaction with medical care: a meta-analysis. Soc. Sci. Med., 30, 811–818. 119. Kessing, L.V., Hansen, H.V., Ruggeri, M. and Bech, P. (2006) Satisfaction with treatment among patients with depressive and bipolar disorders. Soc. Psychiatry Psychiatr. Epidemiol., 41, 148–155.
Index
Note: page numbers in italics refer to figures, those in bold refer to tables and boxes acamprosate 358, 361, 362, 363 acetylcholine 210–15, 212, 255 activator protein-1 (AP-1) 236 adaptive function 309 adenosine 396 cyclic adenosine monophosphate (cAMP) pathway 232–3 adherence see treatment adherence adolescents 54, 55 Interpersonal and Social Rhythm Therapy 437–8 medications 483–4 adrenergic–cholinergic balance hypothesis 211–12 adrenocorticotropic hormone (ACTH) 218, 401 affect, sleep and circadian function 265 affective disorders 8, 9, 84–5 affective symptom treatment 28 age of onset 334 early onset illness 102–3, 482 ageing 98, 232 see also elderly patients agomelatine 398 air travel 335 alcohol abuse/dependence 31–3 comorbid 354, 417–18, 490 treatment 360–1, 362–3 elderly patients 490 maintenance therapy 313–14 pregnancy 466 psychoeducation 417–18 rapid cycling bipolar disorder 335 treatment 32–3, 360–1, 362–3 withdrawal syndrome 357–8 women 464 allopurinol 396
Alpers syndrome, POLG mutations 247 amino acidergic hypotheses 215–16 amino acids 215–18 amino-3-hydroxy-5-methyl-isoxazole-4propionic acid (AMPA) potentiators 399–400 amino-3-hydroxy-5-methyl-isoxazole-4propionic acid (AMPA) receptors 215, 216, 217, 399 gamma-aminobutyric acid (GABA) 215, 216–18 gamma-aminobutyric acid transporters (GATs) 216 amygdala 125–6, 203 ankyrin 3 (ANK3) gene 116 antalarmin 401–2 anterior cingulate 201, 203, 204 anti-anxiety disorder agents 37–8 anticholinergic agents, cognitive impact 74 antidepressants 297–8, 300, 345–7 comorbid anxiety disorder treatment 38–9, 357 CREB activity 237 defeat stress paradigm 100, 101 elderly patients 492–3 maintenance therapy 308–9, 321–2 neonatal toxicity 469 oxidative system effects 249 pregnancy 468 rapid cycling bipolar disorder treatment 300, 337–8 rapid cycling induction 334–5, 337, 359 suicide risk 63, 66 see also named groups anticonvulsants 345 anxiety disorders 38
Bipolar Disorder: Clinical and Neurobiological Foundations Edited by Lakshmi N. Yatham and Mario Maj © 2010 John Wiley & Sons, Ltd. ISBN: 978-0-470-72198-8
bipolar depression comorbid condition treatment 362 maintenance therapy 317–20 mania treatment 286–7 rapid cycling bipolar disorder 336 suicide protective effect 65 antioxidants, oxidative stress 248–50 antipsychotics atypical 6 anxiety disorder treatment 38 bipolar depression treatment bipolar I disorder in children 483–4 bipolar II disorder 345 cognitive impact 74, 79 combination treatment 311 elderly patients 492 maintenance therapy 320–1 mania treatment 286, 288, 289 oxidative systems 248 pregnancy 321 rapid cycling bipolar disorder 337 side-effects 321 suicide protective effect 66 toxicity 321 cancer screening 375 ECG monitoring 376–7 metabolic parameters 373–5 monitoring 373–7 prolactin monitoring 375–6, 377 sudden death 376–7 typical anxiety disorder treatment 38 mania treatment 286, 287–8 oxidative profile 248 anxiety disorders 34–9, 66 behavioural dimensions 48–9 bipolar II disorder 343 comorbid 34–9, 56, 353–4, 490–1 children 480 suicide risk 64–5, 66 treatment 357, 358–9 elderly patients 490–1
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anxiety disorders (Continued ) epidemiology of bipolar disorder 56, 57–8 maintenance therapy 314–15 pregnancy 466 treatment 37–9, 357, 358–9 apparent diffusivity coefficient (ADC) 174, 181, 182 arachidonic acid (AA) cascade 402–3 aripiprazole anxiety disorders 38 bipolar I depression 299 bipolar I disorder in children 484 maintenance therapy 320–1, 322 mania treatment 286, 288–9 rapid cycling bipolar disorder 337 artistic achievements 83–4, 85 asenapine 286, 289 asylums 1, 3 attention deficit hyperactivity disorder (ADHD) 479, 480, 481, 485 bipolar II disorder differential diagnosis 343–4 epidemiology of bipolar disorder 56, 57–8 basal ganglia, imaging 126 Bcl-2 404 Bcl-2-associated athanogene (BAG1) 219 BDNF gene polymorphism 77 behavioural dyscontrol, children 477–8, 485 behavioural strategies 309 benzodiazepines 38, 74, 357, 358 binge eating disorder, comorbid 354 bioenergetics 404 biological rhythm function 266–8 bipolar disorder broad phenotype in children 485 emergence 5–7 juvenile 7 mixed states 11–13 spectrum concept 49 see also depression, bipolar bipolar I disorder 11, 13, 342 adherence to treatment 27 affective symptom treatment 28 children 477–85 assessment 482–3 course 480–1 differential diagnosis 481 DSM IV 342, 477, 478 treatment 483–5 chronicity 19, 26 clinical characteristics 26–7 clinical management 26–8 clinical monitoring 28 cognitive deficits 72
depression/depressive episode 21–2, 28, 294–9 early onset 482 episode frequency 19–20 evidence-based information 26–7 incomplete recovery from major affective episodes 24–5 long-term course 18–26 manic episode treatment 28 medication regimens 27 patient status definitions 24–5 prevalence rates 53–4 psychosis 13, 342–3 psychosocial impairment 22, 23 psychosocial interventions 27 subthreshold symptoms 21 symptom severity 18, 20–1 women 463 bipolar II disorder 13–14 adherence to treatment 27 affective symptom treatment 28 antidepressants 345–6, 346–7 anxiety 343 chronicity 19, 26 clinical characteristics 26–7 clinical importance 23–4 clinical management 26–8 clinical monitoring 28 cognitive deficits 72 creativity 344 depression/depressive episodes 21–2, 28, 299–300, 346–7 diagnosis 343–5 episode frequency 19–20 hypomania 13, 24, 342, 343, 346, 347–8 incomplete recovery from major affective episodes 24–5 long-term course 18–26 management 342–51 medications 27, 345–8 obsessive–compulsive disorder 343 patient education 348–9 patient status definitions 24–5 prevalence rates 53–4 psychosocial impairment 22, 23, 24 psychosocial interventions 27, 349–50 psychotic features 342–3 subthreshold symptoms 21 switching 346 symptom severity 18, 20–1 wellbeing plans 350 women 463 bipolar spectrum 45–6 bipolar–unipolar distinction 8 blood dyscrasias 287 blood pressure monitoring 369 Borbelys two-process model 264
brain stimulation methods 384–91 see also electroconvulsive therapy (ECT) brain-derived neurotrophic factor (BDNF) 98, 100–1, 103, 104, 106 dopaminergic pathway 100–1 functions 231–2, 233 serum level lowering 248 upregulation by CREB 237 brain-derived neurotrophic factor (BDNF) gene 114 breast cancer screening 376, 377 breastfeeding 470, 471 buprenorphine/naloxone 358, 361 bupropion 298, 300, 361 calbindin 217 calcium 244 lithium monitoring 371 signalling in mitochondrial dysfunction 246–7, 248 calcium channel blockers 337 calcium ions 247, 248 phosphoinositide pathway 233, 234–5 calretinin 217 cAMP-dependent protein kinase (PKA) pathway 232–3 cAMP-response element (CRE) 237 cancer screening 375 carbamazepine 73, 296, 371, 372 anxiety disorder treatment 37 combination therapy 311, 320 comorbid substance abuse treatment 360 maintenance therapy 319–20, 322 mania treatment 286–7 neurobiology 104 oxidative system effects 249 pregnancy 320, 467, 468 rapid cycling bipolar disorder 336 suicide protective effect 65 toxicity 320, 371, 372, 373, 467, 468 cardiac safety monitoring 376–7 cardiovascular disease 97, 378, 454 metabolic syndrome as risk prediction tool 374 risk and wellness programmes 378–9 cardiovascular system, lithium effects 317 care management 458–60 caregiver(s) family therapy 449 psychoeducation 413 support 309 caregiver group psychoeducation 309 catecholamine(s) 210–11, 213, 214, 255 catecholamine hypothesis 210 catechol-O-methyl transferase (COMT) 211
Index catechol-O-methyl transferase (COMT) gene polymorphism 77 beta-catenin 236 celecoxib 403 cellular vulnerability 244 cerebellum 126, 203 cerebral blood flow 201–4, 205, 206–7 cerebral metabolism 200–7 euthymic patients 205–6, 207 mania 204–5, 207 childbirth electroconvulsive therapy 312 lithium 317 suicide risk 463 valproate 318 children 48 behavioural dyscontrol 477–8 bipolar depression treatment 484 bipolar I disorder 477–85 assessment 482–3 clinical phenomenology 478–9 course 480–1 differential diagnosis 481 offspring studies 482 broad phenotype bipolar disorder 485 comorbidity 480 diffusion tensor imaging 181–2 epidemiology of bipolar disorder 54, 55, 56 functional MRI 194 illness progression 103 irritability 9–10, 485 mania 479, 485 mood stabilizers 7 outcomes from maternal bipolar disorder 467–8 perinatal risk 466 severe mood disorder 478 chlorpromazine, mania treatment 286, 287–8 choline (Cho) containing compounds 144–5, 146–54, 155 cholinergic metabolism 212 cholinergic system 396–7 chromium 338 Chronic Care Model (CCM) 453, 454–6 chronic progressive external ophthalmoplegia (CPEO) 245, 246, 247 chronotherapeutic interventions 268 cigarette smoking 33–4, 354, 466 circadian rhythms 99, 263–8 genetics 267–8 lithium effects 267 mood relationship 431 psychoeducation 418–19 rapid cycling bipolar disorder 338 sleep-wake cycle relationship 431
circular insanity 4 citicoline 360 clinical features of bipolar disorders 8–13 clinical information systems 459–60 clinical management, treatment adherence 278 CLOCK genes 99, 106, 267 clozapine 300 maintenance therapy 312–13, 321, 322 oxidative stress 248 rapid cycling bipolar disorder 337 cocaine 103–4 sensitization 105 withdrawal syndrome 357–8 cognitive behavioural relapse prevention therapies 313–14 cognitive behavioural therapy (CBT) 27, 413–14, 422–8 biological rhythm stabilization 268 bipolar II disorder 349 clinical trials 425–8 cognitive schemas 424 comorbid anxiety treatment 359 comparative studies 426–7 economic costs 93 family therapy 448 manuals 422–4 psychoeducation comparison 427 rapid cycling bipolar disorder 338 suicide protective effect 66 theoretical underpinning 424–5 third generation models 426 treatments 422–4 cognitive impairment 69–79 adherence impact 276 age-related 232 clinical significance 77–8 elderly patients 491 genetic vulnerability 76–7 medications 73–4 mood symptom association 70–1 neuroimaging 74–6 progressive cognitive decline 77 psychosis history 73 puerperal psychosis 470 treatment strategies 78–9 valproate during pregnancy 467–8 cognitive strategies 309 collaborative care 427, 453–60 models 454–60 communication, treatment adherence 304 communication enhancement training (CET) 445 comorbidity 31–9, 353–63 alcohol abuse/dependence 31–3 psychoeducation 417–18 treatment 360–1, 362–3
|
501
anxiety disorders 34–9, 56, 353–4 children 480 suicide risk 64–5 treatment 357, 358–9 children 480 detoxification 357–8 diagnosis 355–6 elderly patients 490–1 epidemiology of bipolar disorder 56–7 generalized anxiety disorder 38 heart disease/hypertension 57 integrated care provision 355 management 354–5 mental health professionals training 361 migraine 57 nicotine dependence 33–4 obsessive–compulsive disorder 35, 36, 38–9 panic disorder 35, 36 physical disease 57 psychotherapy 359, 362 public health problem 453–4 social phobia 35, 36–7 stabilization 357–8 stigmatization 357 substance abuse 56–7 psychoeducation 417–18 suicide risk 65 treatment 359–63 systematic screening 356 treatment 356–63 adherence 357 medication interactions 363 phases 357–8 withdrawal syndromes 357–8 women 463–4 congenital malformations 467, 468 contraception, hormonal 464–5 corpus callosum imaging 126 cortical deficits 101, 102 corticolimbic dysregulation 201–2, 207 corticolimbic network model 200, 201 corticotropin-releasing factor (CRF) 218, 219, 255, 256, 401 corticotropin-releasing factor (CRF) antagonists 401, 402 corticotropin-releasing factor (CRF) receptors 257 cortisol 219, 255–6, 298 cost of illness (COI) studies 90–2 costs electroconvulsive therapy 92–3 maintenance treatment 93 mental illness 453 counselling, comorbid substance use 360 creatine (Cr) containing compounds 145, 146–54, 165, 166–8
502
|
Index
creatine (Cr) supplementation 404 creativity 84, 86–7 affective disorders 84–5 bipolar II disorder 344 CREB 236–7 cyclicity 8, 454 cycloid disorders 7 see also rapid cycling bipolar disorder cyclo-oxygenase (COX) inhibitors 402–3 cyclophilin D (CypD) 247 cyclothymia 14, 85, 86 cyclothymic state 4 D-amino acid oxidase activator (DAOA) 114 decision support 460 defeat stress paradigm 100, 101 dementia 4, 491 dementia praecox 2, 3, 4 demographic factors 55–6 Depakote 5, 6 depression 3, 4, 5 bipolar II disorder 14, 346–7 bipolar I disorder clinical features 10–11 DSM IV 11 epidemiology of bipolar disorder 57–8 family therapy 449 indoleamine hypothesis 210 lactate levels 218 phosphocreatine frontal lobe decrease 244 postpartum 470 prefrontal circuit 204 pregnancy 466 suicide risk 66 symptom severity 18 transcranial magnetic stimulation 389, 390–1 see also major depressive disorder (MDD) depression, bipolar 10–11, 46–7 elderly patients 489, 492–3 transition to maintenance treatment 308–9 treatment 28 children 484 pharmacological 294–301 depressive states manic-hypomanic state mix 46 mixed 12 dexamethasone suppression test 256 dexamethasone/corticotrophin-releasing hormone test 256 dexamethasone/vasopressin test 256–7 diabetes mellitus 97, 368, 378 atypical antipsychotics 321 POLG mutations 247
diacylglycerol (DAG) 233–4 diacylglycerol kinase (DGK) 234 Diagnostic and Statistical Manual of Mental Disorders (DSM III) 5,8, 9–10, 44-49 bipolar I disorder 342 children 477, 478 bipolar II disorder 13, 342 depression 11 mixed episode 12 rapid cycling bipolar disorder 333, 334 dialectical behavioural therapy 66 diffusion tensor imaging (DTI) 133, 173–4, 175–80, 181–2 paediatric bipolar disorder 181–2 region-of-interest approach 174, 181 voxel-based approach 181 disrupted-in-schizophrenia-1 (DISC-1) gene polymorphism 77 disulfiram 361, 362, 363 divalproex 12, 295–6, 300, 346 bipolar I disorder in children 484 bipolar I depression cognitive impact 73 combination therapy 296, 336 lithium combination 336 maintenance therapy 311, 317–18 mania treatment 286 quetiapine combination 296 rapid cycling bipolar disorder 311, 336, 337 suicide protective effect 65 DMX3 12 DNA base pairs 113 modifications 104, 106 doctor–patient relationship 276–7, 304, 309 donepezil 396–7 dopamine neuroimaging studies 214 post-mortem brain tissue studies 213 sleep circadian emotion interaction 265 dopaminergic pathway brain-derived neurotrophic factor 100–1 oxidative stress 247 sleep circadian emotion interaction 265 dopaminergic receptors, G-protein coupled 230–1 dynorphin opioid neuropeptide system 395–6 dyslipidaemia 369 antipsychotics 374, 375
early onset illness 102–3, 482 see also adolescents; children early warning signs detection 418 economics of bipolar disorder 90–4 education bipolar II disorder 348–9 see also patient education elderly patients 488–95 attitudes/beliefs 493–4 clinical presentation 488–9 clinical recommendations 494 comorbidity 490–1 course of illness 489–90 depression 489, 492–3 epidemiology 488 maintenance treatment 493 mania 492 misdiagnosis 489 mood stabilizers 493–4 suicide risk 490 treatment 491–4 electrocardiogram (ECG) monitoring 376–7 electroconvulsive therapy (ECT) 384–5 antidepressant action 384–5 economic costs 92–3 electrode placement 384 long-term treatment 311–12 maintenance therapy 322 mania treatment 289, 385 pregnancy 312, 469 rapid cycling bipolar disorder 338 relapse rate 385 emotional memory, amygdala 125 emotional processing, neuroimaging 75, 183, 191–2 endophenotypes 58, 77 circadian rhythm disturbance 267–8 engagement, treatment adherence 278 environmental factors 101–2 epidemiology of bipolar disorder 52–9 ADHD 56, 57–8 adolescents 54, 55 adults 53–4 age of onset 54 anxiety disorders 56, 57–8 children 54, 55, 56 depression 57–8 elderly patients 488 endophenotypes 58 family history 57–8 genetic factors 57–8, 110–11 incidence rates 54 physical disease 57 prevalence rates 53–4 risk factors 55–7 treatment rates 55
Index epigenetic mechanisms of disease progression 99–100, 103, 104–5, 106 episode sensitization 104 ethyl-eicosapentaenoic acid 298–9 euthymic patients 75 catecholamine studies 214 cerebral blood flow 203, 206–7 cerebral metabolism 205–6, 207 cognitive impairment 71–2 fronto-executive control function 192 intracellular pH 173, 245 paediatric bipolar disorder 194 executive function 192–3 expressed emotion 443–4 Falret, Jean-Pierre 1 family history 57–8, 482 family therapy 27, 443–50 cognitive-behavioural models 448 communication enhancement training 445 expressed emotion 443–4 mechanisms of action 448–9 moderators of treatment effects 449–50 multifamily group approaches 415, 447–8, 449 neural mechanisms 450 preventative applications 450 problem solving 445–6 psychoeducation 413, 415–16, 444–5, 449, 450 psychosocial interventions 413, 415–16, 450 substance abuse 450 theoretical background 443–4 family-focused therapy (FFT) 415, 426–7, 444–5 empirical studies 446–7 moderators of treatment effects 449–50 objectives 444 FKBP5 polymorphisms 401 fluorodeoxyglucose-18 positron emission tomography (18FDG-PET) 200, 202–7 fluoxetine 297–8, 347 olanzapine combination 296–7 folic acid supplements 468 fractional anisotropy 174, 181, 182 free thyroxine index (FTI) 258, 377 fronto-executive control function 192–3 G72 gene 114 GABA see gamma-aminobutyric acid (GABA) GABAergic interneurons 217, 247 gabapentin 37–8, 345 galantamine 79
gambling, pathological 354 gender see sex; women generalized anxiety disorder 38 elderly patients 490–1 genes, candidate 112–15 genetics/genetic factors 98–9, 110–16 circadian rhythms 267–8 cognitive impairment 76–7 epidemiology 57–8, 110–11 functional MRI 193 glutamatergic neurotransmission 218 linkage studies 111–12 metabolic adverse effects 368 mitochondrial dysfunction 246 neurotransmitters 215 genius–insanity debate 83–7 genome-wide association studies 115–16 glucocorticoid receptor(s) 219, 257, 401 glucocorticoid receptor antagonists 401 glucocorticoid synthesis inhibitors 401–2 glucose abnormalities 368–9 antipsychotics 374–5 glucose monitoring 369, 378 glutamate 215–17 glutamate receptors, metabotropic 400–1 glutamate/glutamine/gammaaminobutyric acid (Glutamix, Glx) 155, 159–64, 165, 218 mitochondrial dysfunction 247–8 glutamatergic system 165, 218, 398–402 glutamic acid decarboxylase (GAD) 216 glutathione (GSH) system 249–50 glycine 215 glycogen synthase kinase 3 (GSK-3) inhibitors 402, 491 glycogen synthase kinase 3 (GSK-3) second messenger 235–6, 402 glycogen synthase kinase 3 beta (GSK3beta) gene 267 G-protein 228 PI-coupled activation 234 receptor coupling 229–31 stimulatory alpha subunits 229, 230 G-protein receptor kinase 3 (GRK3) 230–1 grief/grief for the lost healthy self 434 group psychoeducation 27, 413, 414–15, 419 multifamily 415, 447–8, 449 growth hormone (GH) 260 haloperidol economic costs 92 maintenance therapy 308 mania treatment 286, 287–8, 308 oxidative stress 248 health screening 369 healthy habits encouragement 418–19
|
503
heart disease 57 heat shock protein 70 (Hsp70) 236 heritability of bipolar disorder 110 hippocampus, imaging 125 histone deacetylase inhibitors 105 histone H3 lysine 27 (H3K27) dimethylation 101 histone-deacetylase inhibitor (HDAC) 99, 100 homovanillic acid (HVA) 211, 212 hormone replacement therapy 470–1 HSF-1 236 5HTT gene 115 human genome scans 112 hydrogen peroxide 247 5-hydroxyindoleacetic acid (5-HIAA) 211, 212 5-hydroxytryptamine (5-HT) see serotonin 5-hydroxytryptamine (5-HT) receptors 260, 397–8 G-protein coupled 230 hyperprolactinaemia 375–6 hypertension 57, 97 hyperthymia 85, 86 hypomania 9, 10, 18, 342 bipolar II disorder 13, 24, 342, 343, 346, 347–8 cognitive behavioural therapy 425 depressive episode 12 subsyndromal 18 hypomanic state 4 hypothalamic–pituitary–adrenal (HPA) axis 218–19, 255–6 novel therapeutic strategies 401–2 pregnancy 465 hypothalamic–pituitary–gonadal (HPG) axis 465 hypothalamic–pituitary–thyroid (HPT) axis 219, 258, 260 hypothalamus, suprachiasmatic nucleus 263 hypothyroidism 257 lithium-induced 317, 334, 371 rapid cycling bipolar disorder association 334, 335 illness awareness 416–17 illness beliefs 278 illness progression 96–101 clinical implications 103–4 early-onset 102–3 substance abuse 103 imipramine 297, 401 impulse control disorders, comorbid 354 incremental cost-effectiveness ration (ICER) per quality-adjusted life year (QALY) 93
504
|
Index
indoleamine hypothesis of depression 210 indoleamines 211 indomethacin 402 infanticide, puerperal psychosis 470 infectious disease risk 454 inflammation mediators 98 inheritance of bipolar disorder 267 inositol 234 inositol-1,4,5-triphosphate (IP3) 234 insanity 83–7 insula, cerebral blood flow 203 insulin resistance 368 insulin-like growth factor 1 (IGF-1) 231 integrated care provision 355, 453–5 Integrated Group Therapy (IGT) 360, 418 intensive clinical management (ICM) 438–40 International Classification of Disease (ICD-10) 8 bipolar affective disorders 342 hypomania 342 rapid cycling bipolar disorder 333 International Classification of Disease (ICD-11) 44 Interpersonal and Social Rhythm Therapy (IPSRT) 27, 268, 414, 418, 426, 430–41 adolescents 437–8 component integration 435 instability model 430–1 interpersonal psychotherapy 431, 433–5 monotherapy 440 phases 435–7 psychoeducation 431, 432 research studies 438–40 social rhythm therapy 431, 433 theoretical background 430–1 treatment strategies 431–7 interpersonal deficits 434, 435 interpersonal psychotherapy 431, 433–5 interpersonal role dispute 434–5 intervention care programmes, multicomponent 94 intracellular pathways, novel therapeutic strategies 402–4 intracellular pH (pHi) 170, 172, 173, 245 irritability 9–10, 485 Kahlbaum, Karl 1, 2 kainate receptors 215, 216, 217, 399 kappa opiate antagonists 395–6 ketamine 399 Kraepelin, Emil 2–3, 6, 7, 96 lactate 218 lamotrigine 295, 300, 336–7, 345, 347
adjunctive 295 bipolar depression bipolar I disorder in children 484 combination therapy 295, 311, 319 comorbidity anxiety treatment 359 economic costs 93 elderly patients 492, 493 lithium combination 295 maintenance therapy 318–19, 322 monitoring 373 monotherapy 295, 318–19 oxidative system effects 249 pregnancy 319, 467, 468 rapid cycling bipolar disorder 310, 336–7 toxicity 319, 373, 467, 468 valproate combination 319 LARS2 gene 246 lateral ventricles, imaging 125 leadership 85, 86 Leonhard, Karl 5 Life Goals Collaborative Care (LGCC) 453, 456–60 care management 458–60 clinical information systems 459–60 decision support 460 self-management support 456–7, 458, 459 Life-Goals Programme 415, 418 lifestyle factors, metabolic adverse effects 368 light exposure 431 light therapy 338 limbic hyperactivity 101, 102 limbic structures, imaging 125–6 linkage disequilibrium (LD) 113 linkage studies 111–12 lipids, monitoring 369, 378 lithium 5, 294–5, 297, 300, 345, 347, 348 antipsychotic combination treatment 311 anxiety disorders 38, 359 bipolar I depression bipolar I disorder in children 484 childbirth 317 circadian rhythms 267 cognitive impact 73 combination therapy 295, 296, 311, 320–1, 336 comorbid disorder treatment 359, 360 contraindication in breastfeeding 470 CREB activity 237 dementia rate in elderly patients 491 divalproex combination 336 dosage 285–6 drug interactions 371 economic costs 92, 93 effectiveness 315
elderly patients 492, 493 lamotrigine combination 295 maintenance therapy 308, 311, 315–17, 322 management 316 mania treatment 285–6, 308 monitoring 316, 371 neurobiology 104 neuroprotection 229, 244 oxidative system effects 249 pharmacokinetics 315–16 pregnancy 317, 467, 468 proton MRS studies 155 quetiapine combination 296 rapid cycling bipolar disorder 258, 311, 336 safety monitoring 370–1 side-effects 316–17 suicide protective effect 65, 66, 314 therapeutic response 285–6 thyroid dysfunction 258–9 tolerability 286 toxicity 316–17, 370–1, 467, 468, 469 unacceptability to artists 86–7 lithium clinics 413 LOD scores 111 lymphoid enhancer factor (Lef) 236 magnesium ions 237 magnetic resonance imaging (MRI) 124–7 magnetic resonance imaging, functional (fMRI) 133, 182–3, 184–90, 191–4 bipolar disorder comparison to other psychiatric disorders 193 cognitive impairment 74–6 emotional processing 183, 191–2 fronto-executive control function 192–3 genetic characterization of bipolar disorder 193 medication effects 193 paediatric bipolar disorder 194 magnetic resonance spectroscopy (MRS) 133–4 phosphorus (31P) 165, 169–72, 173 proton (1H) 134, 135–43, 144–5, 146–54, 155–65, 166–8 major depressive disorder (MDD) 17, 18 bipolar II disorder 23–4 hypothalamic–pituitary–adrenal axis activity 255 incomplete recovery 24–5 suicide risk 63 major depressive episode (MDE) 17 bipolar II disorder 23, 24 incomplete recovery 24–5 mania/manic episodes 1, 5, 8–10
Index acute 285–90 economic costs 92–3 bipolar II disorder 23 catecholamine studies 214 cerebral blood flow 205 cerebral metabolism 204–5, 207 children 479, 485 combination therapy 289 criteria 10 DSM IV definition 9, 10 ECT use 289, 385 elderly patients 490, 492 family therapy 449 lactate levels 218 mixed 12, 289 monotherapy 289 oxidative stress 248 pregnancy 466 protein kinase C alteration 289 psychotic state 342 pure 12 symptom severity 18 transition to maintenance treatment 308 treatment 28, 285–90 manic-depressive illness 2–5, 4, 6 manic-hypomanic states, depressive state mix 46 Markov models 93 maternal rearing behaviour 99–100 mecamylamine 397 medical conditions 57, 454 medications acceptance 276 adolescents 483–4 adverse outcomes 367, 454 children 484 bipolar I disorder in children 483–4 bipolar II disorder 345–8 breastfeeding 470, 471 cognitive impairment 73–4, 79 comorbid substance abuse 360–3 economic evaluation of use 92–3 functional MRI 193 interactions 363, 371 maintenance therapy 304–23 antidepressants 321–2 antiepileptics 317–20 atypical antipsychotics 320–1 combination 311 comparator treatments 306 controlled trials 309–11 costs 93 course of illness 306 exclusions from clinical trials 305 goals 304 index episode polarity 305–6 index episode treatment 306
lithium 315–17 major treatments 315–22 monotherapy 309–11 previous response to treatment 306 residual symptoms 309 studies 304–8 subject characteristics for clinical trials 305, 306 targets other than affective episodes 313–15 transition to 308–9 metabolic effects 367, 368 neonatal toxicity/withdrawal symptoms 468–9 neurobiology 104, 105 pregnancy 417, 466–9, 471 side effects 276, 281 children 484 teratogenic effects 417, 467, 468 tolerance 97 treatment refractoriness 97 see also treatment adherence melancholia 1, 3, 4, 5, 86 melatonin 211 melatonin system 397–8 memantine 398–9 membrane phospholipids 165, 169–72 membrane receptors 229–32 menarche 464 menopause 465, 470–2 menstrual cycle 464, 465 mental illness costs 453 creative output 86–7 genius–insanity debate 83–7 mesolimbic region 101 metabolic abnormalities 368–9 metabolic monitoring 369, 378 metabolic syndrome 368, 369, 374, 378 metabolism 367–9 metabotropic glutamate receptors (mGluRs) 400–1 3-methoxy-4-hydroxyphenylglycol (MHPG) 211, 212 mifepristone 79, 298, 401 migraine 57 mineralocorticoid receptors 219, 257 minor depression/dysthymia (MinD) 18 mitochondria, calcium uptake 247 mitochondrial diseases 245 mitochondrial DNA 246 deletion 245 mitochondrial dysfunction 244–5 calcium signalling 246–7 consequence 246–8 gene expression analysis 245–6 oxidative stress 247–8 progressive cell loss 247
|
505
mitochondrial myopathy, encephalopathy, lactic acidosis and stroke-like episodes (MELAS) 245 mitochondria-related genes, downregulation 245–6 mitogen-activated protein kinase (MAPK) signalling cascade 231 mixed episodes, classification 46 modafenil 298, 403 molecular biology of bipolar disorder 228–38 membrane receptors 229–32 second messengers 232–6 transcription factors 236–7 monaminergic hypotheses 210, 212 monoamine(s) 210–15 monoamine challenge studies 213 monoamine oxidase (MAO) 210, 211, 247 monoamine oxidase A (MAOA) gene 114–15 monoamine oxidase inhibitors (MAOI) 258, 298 monoaminergic function, post-mortem brain tissue studies 213–14 mood disorders adrenergic–cholinergic balance 211–12 catecholamine hypothesis 210 children 478 cognitive impairment 70–1, 75 hypothalamic–pituitary–thyroid axis 219 menstrual cycle 464 monaminergic hypotheses 210, 212 suicide 62–3 thyroid hormones 259 mood instability 86 mood stabilizers 5–6 anxiety disorders 37–8 bipolar II disorder 345–6, 348 children 7 cognitive impairment 79 elderly patients 493–4 long-term management 26 neuroprotection 229 oxidative system effects 249 rapid cycling bipolar disorder 335–6 suicide protective effect 65, 66 unacceptability to artists 86–7 movement disorders, atypical antipsychotics 321 multifamily group approaches 415, 447–8, 449 muscarinic system 396–7 myo-inositol 155, 156–8 myristoylated alanine rick C (MARCKS) 237
506
|
Index
N-acetylaspartate (NAA) 134, 135–43, 144, 218, 244 N-acetylcysteine (NAC) 105, 248, 249, 403 naltrexone 358, 361, 362–3 National Institute of Mental Health (NIMH) Collaborative Depression Study clinical management 26–8 long-term course of bipolar illness 18–26 methods 17–18 psychiatric symptom ratings 18 necessity–concerns framework 283 neck pain 57 neonates, toxicity/withdrawal symptoms 468–9 neostigmine 212 nerve growth factor (NGF) 231 nerve growth factor-inducible protein-A (NGF 1-A) 99 neural mechanisms, family therapy 450 neural tube defects 467, 468 neurobiology of bipolar illness 96–106 clinical therapeutics 104–5 early onset illness 102–3 environmental factors 101–2 patterns 101 progression 96–101, 103–4 neurocognition 69–79 neuroendocrine systems 218–20, 255–61 see also hypothalamic–pituitary–adrenal (HPA) axis; hypothalamic–pituitary–gonadal (HPG) axis; hypothalamic–pituitary–thyroid (HPT) axis; named hormones neurogenesis 104, 106 neuroimaging 74–6 structural 124–7 see also named modalities neurokinin-1 (NK-1) receptors 220 neuropeptide Y (NPY) 219 neuropeptides 218–20 neuropsychological assessment 69–70, 78 neurotransmitter systems 210–20, 255 acetylcholine 210–15 amino acids 215–18 genetic factors 215 gonadal hormone effects 465 monoamines 210–15 neuroendocrine systems 218–20 neuroimaging studies 214–15 neuropeptides 218–20 sleep circadian emotion interaction 265 neurotrophins 98 nicotine dependence 33–4, 354, 361
nicotine replacement therapy 361 nicotinic acetylcholine receptor system 397 nicotinic receptors 212 nimodipine 337 N-methyl-D-aspartate (NMDA) receptor(s) 215, 216, 217 mitochondrial dysfunction 247–8 N-methyl-D-aspartate (NMDA) receptor antagonists 399 non-rapid eye movement (REM) sleep 264 norepinephrine 211, 213, 255 obesity 97, 367–8, 369 obsessive–compulsive disorder 35, 36, 38–9, 343 offspring studies 482 olanzapine 296–7, 347 anxiety disorders 38 bipolar depression bipolar I disorder in children 484 combination therapy 296–7, 311 comorbidity anxiety treatment 359 economic costs 92, 93 fluoxetine combination 296–7 maintenance therapy 320–1, 322 mania treatment 286, 288–9 oxidative stress 248 rapid cycling bipolar disorder 337 omega-3 fatty acids 402 opioids 255 substitution therapy 361 withdrawal syndrome 357, 358 opponent process model 264 orbitofrontal circuit 200–1 overactivity 10 overweight 97 oxcarbazepine 73–4, 287, 320 oxidative stress 97, 98, 248–50 dopaminergic pathway 247 illness progression 103 mitochondrial dysfunction 247–8 N-acetylcysteine effects 403 oxygen-15 water positron emission tomography (H215O-PET) 200, 202, 205, 206 paliperidone 286, 289 panic disorder 35, 36, 490–1 parathyroid, lithium adverse events 371 Parkinsons disease, POLG mutations 247 paroxetine 297 parvalbumin 217 patient education 309, 348–9 pentazocine 396
permissive serotonin hypothesis of function 210 pervasive developmental disorder (PDD) 480 pharmacotherapy see medications phenelzine 401 phenotype of bipolar disorder 267–8 see also endophenotypes phosphate monoester (PME) 165, 169–72, 173 phosphocreatine (PCr) 155, 156–64, 165, 166–8, 173, 244 phosphodiester (PDE) 165 phosphoinositide (PI) pathway 233–5, 238 phospholipase C gamma1 231 phosphomonoester (PME) 165, 169–72, 173 phosphorus (31P) magnetic resonance spectroscopy (MRS) 134, 155, 165, 169–72, 173 mitochondrial dysfunction 244–5 physical disease see medical conditions physical health screening 369 physostigmine 212, 396 PI3 kinase 231 Pinel, Philippe 1 piroxicam 402 PKA pathway 232–3 polarity 5, 8 POLG mutations 246, 247 polycystic ovarian syndrome 378 positron emission tomography (PET) 200, 202–7 posterior cingulate 204 postpartum period 469–70 see also puerperal psychosis pramipexole 79, 298, 299–300 prefrontal circuit 204 prefrontal cortex 101 dorsolateral circuit 200–1, 204 imaging 124–5 metabolism rate 203, 204 subgenual 201 pregnancy 465 advice 466 atypical antipsychotics 321 carbamazepine 320 electroconvulsive therapy 312, 469 intrauterine growth 467 lamotrigine 319 lithium effects 317 management 465–9 medications 417, 466–9, 471 teratogenicity 417, 467, 468 neurobehavioural sequelae 467–8 pharmacokinetic changes 468 planning 465–6
Index psychotherapy/psychoeducation/ psychological interventions 469 recurrence of symptoms 465 treatment during 312, 417, 466–9 valproate 318 premenstrual dysphoric disorder (PMDD) 464 prescribing, effective 279–81 prevention of bipolar disorder, family therapy 450 problem solving, substance abuse 450 pro-brain-derived neurotrophic factor (proBDNF) 98–9 prodrome monitoring 309 productivity loss 90–1 prolactin monitoring 375–6, 377 protein kinase B (AKT) 235 protein kinase C (PKC) 234, 237, 289, 402 proton (1H) magnetic resonance spectroscopy (MRS) 134, 135–43, 144–5, 146–54, 155–65, 166–8 GABA imaging 218 psychic anxiety 48–9 psychoeducation 412–19 adherence enhancement 417 caregivers 413 CBT comparison 427 definition 412–13 early warning signs detection 418 evidence-based approaches 413–16 family-based 413, 415–16, 450 family-focused therapy 444–5 group interventions 27, 413, 414–15, 419 multifamily 447–8, 449 healthy habits encouragement 418–19 illness awareness 416–17 individual interventions 413–14 internet delivery 416 Interpersonal and Social Rhythm Therapy 431, 432 pregnancy 469 substance misuse avoidance 417–18 psychomotor activation 10 psychosis 13, 342–3 creative genius association 84 history and cognitive deficit 73 see also puerperal psychosis psychosocial impairment 22, 23, 24 psychosocial interventions 426–7 adjunctive with long-term medication 27 biological rhythm stabilization/ targeting 268 bipolar I disorder in children 483 bipolar II disorder 349–50 family therapy 450 pregnancy 469
psychotherapy bipolar II disorder 349–50 comorbidity treatment 359, 362 interpersonal 431, 433–5 pregnancy 469 rapid cycling bipolar disorder 338 suicide protective effect 66 see also Interpersonal and Social Rhythm Therapy (IPSRT) psychotic symptoms 10 public health 453–4 puerperal psychosis 2, 5, 463, 470 purinergic system 396 QTc interval 376–7 quality-adjusted life year (QALY) 93 quetiapine 296, 299, 300, 345, 347 adjunctive 296 anxiety disorders 38 bipolar I disorder in children 484 combination therapy 296, 311, 320–1 comorbid condition treatment 359, 360, 362 divalproex combination 296 lithium combination 296 maintenance therapy 308, 320–1, 322 mania treatment 286, 288–9, 308 monotherapy 296 rapid cycling bipolar disorder 337 rapid cycling bipolar disorder 46, 258, 333–9 age of onset 334 antidepressant treatment 300, 337–8 antidepressant-induced 334–5, 337, 359 chronobiological treatments 338 cycle length reduction 336 definition 333–4 electroconvulsive therapy 338 maintenance treatment 310, 311 persistence 334 phenomenology 334 psychotherapy 338 treatment 335–8 women 463 rapid eye movement (REM) sleep 264, 265 reactive oxygen species (ROS) 247 reelin 217 renal system, lithium effects 316–17, 370–1 reproductive life cycle, women 464–9 riluzole 398 risk factors, epidemiology of bipolar disorder 52, 55–7 risk management plans 367
|
507
risperidone anxiety disorders 38 bipolar I disorder in children 484 comorbidity anxiety treatment 359 maintenance therapy 308, 320–1, 322 mania treatment 286, 288–9, 308 neonatal toxicity 469 oxidative stress 248 rapid cycling bipolar disorder 337 role transition 434 safety monitoring 367–79 current guidelines 377–8 generic 370 specific treatments 370–7 thyroid function 377 Salvinorin-A 396 schizoaffective disorder 47, 368 schizophrenia 111, 368 antipsychotic side effects 374–5 schizotype 85 Schou, Mogens 5 scopolamine hydrobromide 397 screening tools for comorbidity 356 seizures, induced by transcranial magnetic stimulation 389 selective serotonin reuptake inhibitors (SSRIs) 346, 347 cognitive impact 74 comorbid anxiety disorder treatment 357 suicide risk 66 self-help groups 357 self-management 456–7, 458, 459 serotonin 210, 211, 213–15, 255 see also 5-hydroxytryptamine (5-HT) receptors serotonin system 397–8 serotonin transporter gene 115 sertraline 298, 300, 346 severe mood dysregulation (SMD) 478 sex epidemiology of bipolar disorder 55 metabolic abnormalities 368 monitoring levels 378 obesity prevalence 369 rapid cycling bipolar disorder 334 see also women sex steroids, exogenous 464–5 shift work 335 signal transduction pathways 228–38 membrane receptor coupling 229–32 single nucleotide polymorphisms (SNPs) 113 single photon emission tomography (SPECT) 200, 202, 205, 206
508
|
Index
sleep 263–7, 268, 418–19 disturbance 265, 266, 431 infant feeding 470 rapid cycling bipolar disorder 335 sleep–wake cycle 264, 338, 431 smoking cessation treatment 34 social phobia 35, 36–7 Social Rhythm Metric (SRM) 433, 436 social rhythm therapy 268, 431, 433 social zeitgeber hypothesis 268, 431 soft-bipolar patients 355 somatostatin 220 staging model of bipolar disorder 334 state versus trait abnormalities 105–6 statins 378 Stevens–Johnson syndrome 287, 373 stigmatization 357 stress 255 stressors 103–4 subcortical hyperintensity 244 subcortical structure imaging 126 substance abuse 56–7 avoidance 417–18 cognitive behavioral relapse prevention therapies 313–14 comorbid 354 medications 360–3 psychoeducation 417–18 treatment 359–63 diagnosis 355–6 family therapy 450 illness progression 103–4 maintenance therapy 313–14 pregnancy 466 problem solving 450 rapid cycling bipolar disorder 335 suicide risk 65 withdrawal syndromes 357–8 women 464 see also alcohol abuse/dependence substance P 219–20 subtypes of bipolar disorder 13–14 sudden death, antipsychotic medication 376–7 suicide/suicidality 12, 62–6 antidepressant-induced 63, 66 anxiety comorbidity 64–5 elderly patients 490 maintenance therapy 314 maternal mortality 463 mood disorders 62–3 pharmacotherapy effects 65–6 prevention 66 protective factors 65–6 puerperal psychosis 470 risk 412 risk assessment 66 risk factors 63–5
varenicline 34 women 463 superoxide dismutase 249 suprachiasmatic nucleus (SCN) 263 sympathoadrenal medullary system (SAM) 255 Systematic Care Programme 415 Systematic Treatment Enhancement Program for Bipolar Disorder (STEP-BD) 447 tamoxifen 289, 402 technetium-99m HMPAO single photon emission tomography (99mTc-HMPAO-SPECT) 200, 202, 205, 206 temperament, creative process 84–5 teratogenicity of medications 417, 467, 468 thalamus imaging 126 therapeutic relationships 276–7, 304 thiobarbituric acid reactive substance (TBARS) 248, 249 thyroid autoimmunity 258–9 thyroid dysfunction, lithiuminduced 258–9 thyroid function 377 thyroid hormone(s) 257–8, 259–60 lithium toxicity 317, 371 mood disorders 259 rapid cycling bipolar disorder 337 thyroid hormone receptors 260 thyroid peroxidase (TPO) antibodies 259 thyroid-stimulating hormone (TSH) 219, 258, 371 thyrotrophin-releasing hormone (TRH) 219, 260 thyroxine (T4) 219, 258, 259, 260 bipolar II depression 300 rapid cycling bipolar disorder 337 tolerance phenomenon, illness progression 97 topiramate 321, 322, 345, 361 toxic epidermal necrolysis 373 training, mental health professionals 361 transcranial magnetic stimulation (TMS) 387–91 transcription factors 236–7 tranylcypromine 298 treatment acceptability 279–80 bipolar I disorder in children 483–5 elderly patient satisfaction 493–4 maintenance controlled trials 309–11 costs 93 elderly patients 493 electroconvulsive therapy 311–12
major treatments 315–22 nonpharmacological 309 pharmacological 304–23 studies 304–8 targets other than affective episodes 313–15 transition to 308–9 manageable 280–1 neurobiology informing 104–5 novel strategies 395–405 cholinergic system 396–7 dynorphin opioid neuropeptide system 395–6 glutamatergic system 398–402 hypothalamic–pituitary–adrenal axis 401–2 intracellular pathways 402–4 melatonin system 397–8 purinergic system 396 serotonin system 397–8 during pregnancy 466–9 refractoriness 97 understandable 280 see also cognitive behavioural therapy (CBT); medications; psychosocial interventions treatment adherence 275–83 clinical management 278 collaborative relationship 309 communication 304 comorbidity 357 doctor–patient relationship 276–7, 304, 309 effective prescribing 279–81 elderly patients 493 engagement 278 enhancement 281–3, 417 illness beliefs 278 maintenance treatment 304 monitoring 281–3 necessity–concerns framework 283 non-adherence intentional 282 rapid cycling bipolar disorder 334 risk factors 276, 277 subjective reasons 276 unintentional 282 pattern establishment 282 predictors 276 therapeutic relationships 276–7, 304 treatment goal understanding 277–9 treatment cards 281 trichostatin A 99 tricyclic antidepressants 258, 396 triglyceride monitoring 378 triiodothyronine (T3) 219, 258, 259 tyrosine kinase receptors (TRK) 229, 231–2
Index unipolar disorder 8, 9 recurrent 110, 111 uridine RG2417 403 vagus nerve stimulation 385–7 valproate antipsychotic combination treatment 311 anxiety disorder treatment 37 bipolar II disorder 348 carbamazepine combination 320 childbirth 318 combination therapy 311, 319, 320–1 comorbid condition treatment 360, 362 economic costs 92, 93 effectiveness 317–18 elderly patients 492 lamotrigine combination 319 maintenance therapy 308, 317–18, 322 mania treatment 286, 308
monitoring 318, 373 neurobiology 104, 105 neuroprotection 244 oxidative system effects 249 pregnancy 318, 467–8 toxicity 318, 372–3, 467–8, 469 varenicline 34, 361 vasopressin (AVP) 255 dexamethasone test 256–7 venlafaxine 298, 300, 345, 346 ventrolateral preoptic nucleus (VLPO) 264 verapamil 337, 402 vermis imaging 126 weight gain 368 antipsychotics 321, 374 lithium 316, 371 weight loss 378–9 wellbeing plans, bipolar II disorder
|
wellness programmes, CVD risk 378–9 white matter abnormalities 173–4 white matter hyperintensities (WHI) 173–4 Wnt pathway 235 women 463–72 comorbidity 463–4 menopause 465, 470–2 postpartum period 469–70 relapse risk 470 reproductive life cycle 464–9 workforce, productivity loss 90–1
350
Zeitgebers 268, 431, 433 Zeitst€ orers 431, 433 ziprasidone 286, 288–9, 337, 484 maintenance therapy 320–1, 322 Zyprexa 6
509