Preliminary evidence for persistent abnormalities in amygdala volumes in adolescents and young adults with bipolar disorder

OBJECTIVES: Abnormalities in volumes of the amygdala have been reported previously in adolescents and adults with bipolar disorder (BD). Several studies have reported reduced volumes in adolescents with BD; however, both decreases and increases in volumes have been reported in adults with BD. Understanding of potential developmental contributions to these disturbances in morphology of the amygdala has been limited by the absence of longitudinal data in persons with BD. Here we use a within-subject longitudinal design to investigate whether amygdala volume abnormalities persist in adolescents and young adults with BD over a time interval of approximately 2 years. METHODS: Participants included 18 adolescents and young adults: 10 participants with BD I and 8 healthy comparison participants. Amygdala volumes were measured on high-resolution magnetic resonance imaging scans acquired twice for each subject over intervals of approximately 2 years. Amygdala volumes were the dependent measures in a mixed-model statistical analysis to compare amygdala volumes between groups over time while covarying for total brain volume. RESULTS: Amygdala volumes were significantly smaller in adolescents and young adults with BD compared with healthy participants (p = 0.018). The effect of time was not significant. CONCLUSIONS: Although the sample size is modest, this study provides preliminary evidence to support the presence of decreased amygdala volumes in adolescents and young adults with BD that persist during this developmental epoch.     

Trait and state corticostriatal dysfunction in bipolar disorder during emotional face processing

Liu J, Blond BN, van Dyck LI, Spencer L, Wang F, Blumberg HP. Trait and state corticostriatal dysfunction in bipolar disorder during emotional face processing.
Bipolar Disord 2012: 14: 432–441. © 2012 The Authors. Journal compilation © 2012 John Wiley & Sons A/S. Objectives: Convergent evidence supports limbic, anterior paralimbic, and prefrontal cortex (PFC) abnormalities in emotional processing in bipolar disorder (BD) and suggests that some abnormalities are mood‐state dependent and others persist into euthymia. However, few studies have assessed elevated, depressed, and euthymic mood states while individuals processed emotional stimuli of varying valence to investigate trait‐ and state‐related neural system responses. Here, regional brain responses to positive, negative, and neutral emotional stimuli were assessed in individuals with BD during elevated, depressed, and euthymic mood states. Methods: One hundred and thirty‐four subjects participated in functional magnetic resonance imaging scanning while processing faces depicting happy, fearful, and neutral expressions: 76 with BD (18 in elevated mood states, 19 depressed, 39 euthymic) and 58 healthy comparison (HC) individuals. Analyses were performed for BD trait‐ and mood state‐related features. Results: Ventral anterior cingulate cortex (VACC), orbitofrontal cortex (OFC), and ventral striatum responses to happy and neutral faces were decreased in the BD group, compared to the HC group, and were not influenced by mood state. Elevated mood states were associated with decreased right rostral PFC activation to fearful and neutral faces, and depression was associated with increased left OFC activation to fearful faces. Conclusions: The findings suggest that abnormal VACC, OFC, and ventral striatum responses to happy and neutral stimuli are trait features of BD. Acute mood states may be associated with additional lateralized abnormalities of diminished right rostral PFC responses to fearful and neutral stimuli in elevated states and increased left OFC responses to fearful stimuli in depressed states.     

The functional neuroanatomy of bipolar disorder: a consensus model

Strakowski SM, Adler CM, Almeida J, Altshuler LL, Blumberg HP, Chang KD, DelBello MP, Frangou S, McIntosh A, Phillips ML, Sussman JE, Townsend JD. The functional neuroanatomy of bipolar disorder: a consensus model.
Bipolar Disord 2012: 14: 313–325. © 2012 The Authors. Journal compilation © 2012 John Wiley & Sons A/S. Objectives: Functional neuroimaging methods have proliferated in recent years, such that functional magnetic resonance imaging, in particular, is now widely used to study bipolar disorder. However, discrepant findings are common. A workgroup was organized by the Department of Psychiatry, University of Cincinnati (Cincinnati, OH, USA) to develop a consensus functional neuroanatomic model of bipolar I disorder based upon the participants’ work as well as that of others. Methods: Representatives from several leading bipolar disorder neuroimaging groups were organized to present an overview of their areas of expertise as well as focused reviews of existing data. The workgroup then developed a consensus model of the functional neuroanatomy of bipolar disorder based upon these data. Results: Among the participants, a general consensus emerged that bipolar I disorder arises from abnormalities in the structure and function of key emotional control networks in the human brain. Namely, disruption in early development (e.g., white matter connectivity and prefrontal pruning) within brain networks that modulate emotional behavior leads to decreased connectivity among ventral prefrontal networks and limbic brain regions, especially the amygdala. This developmental failure to establish healthy ventral prefrontal–limbic modulation underlies the onset of mania and ultimately, with progressive changes throughout these networks over time and with affective episodes, a bipolar course of illness. Conclusions: This model provides a potential substrate to guide future investigations and areas needing additional focus are identified.     

Stroop performance in bipolar disorder: further evidence for abnormalities in the ventral prefrontal cortex

OBJECTIVES: Bipolar patients are impaired in Stroop task performance, a measure of selective attention. Structural and functional abnormalities in task-associated regions, in particular the prefrontal cortex (PFC), have been reported in this population. We aimed to examine the relationship between functional abnormalities, impaired task performance and the severity of depressive symptoms in bipolar patients. METHODS: Remitted bipolar patients (n = 10; all medicated), either euthymic or with subsyndromal depression, and age-matched control subjects (n = 11) viewed 10 alternating blocks of incongruent Stroop and control stimuli, naming the colour of the ink. Neural response was measured using functional magnetic resonance imaging. We computed between-group differences in neural response and within-group correlations with mood and anxiety. RESULTS: There were no significant between-group differences in task performance. During the Stroop condition, controls demonstrated greater activation of visual and dorsolateral and ventrolateral prefrontal cortical areas; bipolar patients demonstrated relative deactivation within orbital and medial prefrontal cortices. Depression scores showed a trend towards a negative correlation with the magnitude of orbitofrontal cortex deactivation in bipolar patients, whereas state anxiety correlated positively with activation of dorsolateral PFC and precuneus in controls. CONCLUSIONS: Our findings confirm previous reports of decreased ventral prefrontal activity during Stroop task performance in bipolar patients, and suggest a possible negative correlation between this and depression severity in bipolar patients. These findings further highlight the ventromedial PFC as a potential candidate for illness related dysfunction in bipolar disorder.     

ADHD comorbidity can matter when assessing cortical thickness abnormalities in patients with bipolar disorder

Hegarty CE, Foland‐Ross LC, Narr KL, Sugar CA, McGough JJ, Thompson PM, Altshuler LL. ADHD comorbidity can matter when assessing cortical thickness abnormalities in patients with bipolar disorder.
Bipolar Disord 2012: 14: 843–855. © 2012 John Wiley & Sons A/S.Published by Blackwell Publishing Ltd. Objectives: Attention‐deficit hyperactivity disorder (ADHD) is prevalent in patients with bipolar disorder (BP), but very few studies consider this when interpreting magnetic resonance imaging findings. No studies, to our knowledge, have screened for or controlled for the presence of ADHD when examining cortical thickness in patients with BP. We used a 2 × 2 design to evaluate the joint effects of BP and ADHD on cortical thickness and uncover the importance of ADHD comorbidity in BP subjects. Methods: The study included 85 subjects: 31 healthy controls, 17 BP‐only, 19 ADHD‐only, and 18 BP/ADHD. All patients with BP were subtype I, euthymic, and not taking lithium. Groups did not differ significantly in age or gender distribution. We used cortical thickness measuring tools combined with cortical pattern matching methods to align sulcal/gyral anatomy across participants. Significance maps were used to check for both main effects of BP and ADHD and their interaction. Post‐hoc comparisons assessed how the effects of BP on cortical thickness varied as a function of the presence or absence of ADHD. Results: Interactions of BP and ADHD diagnoses were found in the left subgenual cingulate and right orbitofrontal cortex, demonstrating that the effect of BP on cortical thickness depends on ADHD status. Conclusions: Some brain abnormalities attributed to BP may result from the presence of ADHD. Diagnostic interactions were found in regions previously implicated in the pathophysiology of BP, making it vital to control for an ADHD comorbid diagnosis when attempting to isolate neural or genetic abnormalities specific to BP.     

Neuroimaging in bipolar disorder

Objective: The authors reviewed neuroimaging studies of bipolar disorder in order to evaluate how this literature contributes to the current understanding of the neurophysiology of the illness.

Method: Papers were reviewed as identified, using the NIMH PubMed literature search systems that reported results of neuroimaging studies involving a minimum of five bipolar disorder patients compared with healthy comparison subjects.

Results: Structural neuroimaging studies report mixed results for lateral and third ventriculomegaly. Recent studies suggest subcortical structural abnormalities in the striatum and amygdala, as well as the prefrontal cortex. Proton spectroscopic studies suggest that abnormalities in choline metabolism exist in bipolar disorder, particularly in the basal ganglia. Additionally, phosphorous MRS suggests that there may be abnormalities in frontal phospholipid metabolism in bipolar disorder. Functional studies have identified affective state‐related changes in cerebral glucose metabolism and blood flow, particularly in the prefrontal cortex during depression, but no clear abnormalities specific to bipolar disorder have been consistently observed.

Conclusions: The current literature examining the neurophysiology of bipolar disorder using neuroimaging is limited. Nonetheless, abnormalities in specific frontal‐subcortical brain circuits seem likely. Additional targeted studies are needed to capitalize on this burgeoning technology to advance our understanding of the neurophysiology of bipolar disorder.     

Functional neuroanatomy of bipolar disorder: structure, function, and connectivity in an amygdala-anterior paralimbic neural system

Blond BN, Fredericks CA, Blumberg HP. Functional neuroanatomy of bipolar disorder: structure, function, and connectivity in an amygdala–anterior paralimbic neural system.
Bipolar Disord 2012: 14: 340–355. © 2012 The Authors. Journal compilation © 2012 John Wiley & Sons A/S. Objectives: In past decades, neuroimaging research in bipolar disorder has demonstrated a convergence of findings in an amygdala–anterior paralimbic cortex neural system. This paper reviews behavioral neurology literature that first suggested a central role for this neural system in the disorder and the neuroimaging evidence that supports it. Methods: Relevant articles are reviewed to provide an amygdala–anterior paralimbic cortex neural system model of bipolar disorder, including articles from the fields of behavioral neurology and neuroanatomy, and neuroimaging. Results: The literature is highly supportive of key roles for the amygdala, anterior paralimbic cortices, and connections among these structures in the emotional dysregulation of bipolar disorder. The functions subserved by their more widely distributed connection sites suggest that broader system dysfunction could account for the range of functions—from neurovegetative to cognitive—disrupted in the disorder. Abnormalities in some components of this neural system are apparent by adolescence, while others, such as those in rostral prefrontal regions, appear to progress over adolescence and young adulthood, suggesting a neurodevelopmental model of the disorder. However, some findings conflict, which may reflect the small sample sizes of some studies, and clinical heterogeneity and methodological differences across studies. Conclusions: Consistent with models derived from early behavioral neurology studies, neuroimaging studies support a central role for an amygdala–anterior paralimbic neural system in bipolar disorder, and implicate abnormalities in the development of this system in the disorder. This system will be an important focus of future studies on the developmental pathophysiology, detection, treatment, and prevention of the disorder.     

Regional cerebral glucose metabolic abnormalities in bipolar II depression.

BACKGROUND: Functional neuroimaging studies of bipolar disorder (BD) performed in conjunction with antidepressant treatment trials generally require that patients remain on mood stabilizers to reduce the risk of inducing mania; yet, it is unknown whether the metabolic abnormalities evident in unmedicated BD depressives remain detectable in patients receiving mood stabilizers. This study investigated whether cerebral metabolic abnormalities previously reported in unmedicated BD subjects are evident in depressed bipolar disorder type II (BD II) subjects receiving lithium or divalproex. METHODS: Using [18F]-fluorodeoxyglucose-positron-emission tomography, cerebral glucose metabolism was compared between 13 depressed BD II subjects on therapeutic doses of lithium or divalproex and 18 healthy control subjects. Regional metabolism was compared between groups in predefined regions of interest. RESULTS: Metabolism was increased in the bilateral amygdala, accumbens area, and anteroventral putamen, left orbitofrontal cortex and right pregenual anterior cingulate cortex in depressives versus control subjects. Post hoc exploratory analysis additionally revealed increased metabolism in left parahippocampal, posterior cingulate, and right anterior insular cortices in depressives versus control subjects. Correlational analyses showed multiple limbic-cortical-striatal interactions in the BD sample not evident in the control sample, permitting sensitive and specific classification of subjects by discriminant analysis. CONCLUSIONS: These results confirm previous reports that bipolar depression is associated with abnormally increased metabolism in the amygdala, ventral striatum, orbitofrontal cortex, anterior cingulate, and anterior insula, and extend these results to bipolar disorder type II depressives on lithium or divalproex. They also implicate an extended functional anatomical network known to modulate visceromotor function in the pathophysiology of BD II depression.     

White matter abnormalities in children with and at risk for bipolar disorder

OBJECTIVES: Diffusion tensor magnetic resonance imaging (DT-MRI) assesses the integrity of white matter (WM) tracts in the brain. Children with bipolar disorder (BPD) may have WM abnormalities that precede illness onset. To more fully examine this possibility, we scanned children with DSM-IV BPD and compared them to healthy peers and children at risk for BPD (AR-BPD), defined as having a first-degree relative with the disorder. METHODS: Ten children with BPD, eight healthy controls (HC), and seven AR-BPD, similar in age, had MRI scans on a 1.5 Tesla GE scanner, including a standard DT-MRI sequence (T2-EPI) with 25 axial slices. Fractional anisotropy (FA) values were compared between groups to determine regions of significant difference (p < 0.05). RESULTS: Compared to HC, children with BPD had decreased FA in right and left superior frontal tracts, including the superior longitudinal fasciculus I (SLF I) and the cingulate-paracingulate WM (CG-PAC(WM)). In addition, the BPD group had reduced FA in left orbital frontal WM and the right corpus callosum body. Compared to AR-BPD, children with BPD showed reduced FA in the right and left CG-PAC(WM). Both the BPD and AR-BPD groups showed reduced FA relative to HC in bilateral SLF I. CONCLUSIONS: The bilateral SLF I finding in both the BPD and AR-BPD groups may represent a trait-based marker or endophenotype of the disorder. The finding of decreased FA in the right and left CG-PAC(WM) in children with BPD compared to the other two groups may represent a disease-state related finding.     

Magnetic resonance imaging analysis of amygdala and other subcortical brain regions in adolescents with bipolar disorder

Objectives: Few studies have examined the abnormalities that underlie the neuroanatomy of bipolar disorder in youth. The aim of this study was to evaluate brain regions that are thought to modulate mood utilizing quantitative analyses of thin‐slice magnetic resonance imaging (MRI) scans of adolescents with bipolar disorder. We hypothesized that adolescents with bipolar disorder would exhibit abnormalities in brain regions that are involved in the regulation of mood including the amygdala, globus pallidus, caudate, putamen, and thalamus. Methods: Bipolar adolescents (n = 23) and healthy subjects (n = 20) matched for age, race, sex, socioeconomic status, IQ, education and Tanner stage, were evaluated using the Washington University at St Louis Kiddie‐Schedule for Affective Disorders and Schizophrenia (WASH‐U K‐SADS). Contiguous 1 mm axial T1‐weighted MRI slices were obtained using a GE 1.5 T MR scanner. Regions of interest (ROI) included total cerebral volume, amygdala, globus pallidus, caudate, putamen, and thalamus. Results: Total cerebral volume was smaller in bipolar adolescents than in healthy adolescents. A MANCOVA revealed a significant group difference in overall ROI volumes after adjusting for total cerebral volume. Specifically, adolescents with bipolar disorder exhibited smaller amygdala and enlarged putamen compared with healthy subjects. Conclusions: Our findings indicate that adolescents with bipolar disorder exhibit abnormalities in some of the brain regions that are thought to be involved in the regulation of mood. Additional structural and functional neuroimaging investigations of children, adolescents, and adults with bipolar disorder are necessary to clarify the role of these brain regions in the neurophysiology of adolescent bipolar disorder.     

N-acetylaspartate levels in bipolar offspring with and at high-risk for bipolar disorder

OBJECTIVES: Studies have reported decreased N-acetylaspartate (NAA) in dorsolateral prefrontal cortex (DLPFC) of adults and children with bipolar disorder (BD), suggesting decreased neuronal density in this area. However, it is unclear if this finding represents neurodegeneration after or a trait marker present before BD onset. To address this question, we used proton magnetic resonance spectroscopy ((1)H-MRS) to compare DLPFC levels of NAA among bipolar offspring with early-onset BD, bipolar offspring with subsyndromal symptoms of BD and healthy children. METHODS: Participants were 9-18 years old, and included 60 offspring of parents with bipolar I or II disorder (32 with BD and 28 with subsyndromal symptoms of BD), and 26 healthy controls. (1)H-MRS at 3 T was used to study 8-cm(3) voxels placed in left and right DLPFC. RESULTS: There were no significant group differences in mean right or left DLPFC NAA/Cr ratios. Exploratory analyses of additional metabolites (myoinositol, choline) also yielded no significant group differences. NAA/Cr ratios were not correlated with age, duration of illness, or exposure to lithium or valproate. CONCLUSIONS: Our findings suggest that DLPFC NAA/Cr ratios cannot be used as a trait marker for BD. Although we did not find decreased DLPFC NAA/Cr ratios in children and adolescents with BD, it is still possible that such levels begin to decrease after longer durations of illness into adulthood. Longitudinal neuroimaging studies of patients with BD accounting for developmental and treatment factors are needed to further clarify the neurodegenerative aspects of BD.     

Abnormal cellular energy and phospholipid metabolism in the left dorsolateral prefrontal cortex of medication-free individuals with bipolar disorder: an in vivo1H MRS study

Objectives:  While the pathophysiology of bipolar disorder (BD) remains to be elucidated, postmortem and neuroimaging studies have suggested that abnormalities in the dorsolateral prefrontal cortex (DLPFC) are implicated. We compared the levels of specific brain chemicals of interest measured with proton magnetic resonance spectroscopy (¹H MRS) in medication-free BD subjects and age- and gender-matched healthy controls. We hypothesized that BD subjects would present abnormal cellular metabolism within the DLPFC, as reflected by lower N -acetyl-aspartate (NAA) and creatine + phosphocreatine (Cr + PCr).
Methods:  Thirty-two medication-free BD subjects (33.8 ± 10.2 years) and 32 matched controls (33.8 ± 9.0 years) underwent a short echo-time (TE = 30 ms) ¹H MRS. An 8-cm³ single voxel was placed in the left DLPFC, and individual concentrations of NAA, Cr + PCr, choline-containing compounds (GPC + PC), myo -inositol, and glutamate were obtained, using the water signal as an internal reference.
Results:  BD subjects had lower Cr + PCr [ F _(1,62) = 5.85; p = 0.018; one-way analysis of variance (ANOVA)] and lower GPC + PC [ F _(1,62) = 5.79; p = 0.019; one-way ANOVA] levels in the left DLPFC. No significant differences were observed for other brain metabolites.
Conclusions:  These findings provide further evidence that the pathophysiology of BD involves impairment in the DLPFC. Our findings can be interpreted as evidence for reduced cellular energy and phospholipid metabolism, consistent with the hypothesis of mitochondrial dysfunction in BD.     

Amygdala activity and prefrontal cortex-amygdala effective connectivity to emerging emotional faces distinguish remitted and depressed mood states in bipolar disorder

Perlman SB, Almeida JRC, Kronhaus DM, Versace A, LaBarbara EJ, Klein CR, Phillips ML. Amygdala activity and prefrontal cortex–amygdala effective connectivity to emerging emotional faces distinguish remitted and depressed mood states in bipolar disorder. Bipolar Disord 2012: 14: 162–174. © 2012 The Authors. Journal compilation © 2012 John Wiley & Sons A/S. Objectives: Few studies have employed effective connectivity (EC) to examine the functional integrity of neural circuitry supporting abnormal emotion processing in bipolar disorder (BD), a key feature of the illness. We used Granger Causality Mapping (GCM) to map EC between the prefrontal cortex (PFC) and bilateral amygdala and a novel paradigm to assess emotion processing in adults with BD. Methods: Thirty‐one remitted adults with BD [(remitted BD), mean age = 32 years], 21 adults with BD in a depressed episode [(depressed BD), mean age = 33 years], and 25 healthy control participants [(HC), mean age = 31 years] performed a block‐design emotion processing task requiring color‐labeling of a color flash superimposed on a task‐irrelevant face morphing from neutral to emotional (happy, sad, angry, or fearful). GCM measured EC preceding (top‐down) and following (bottom‐up) activity between the PFC and the left and right amygdalae. Results: Our findings indicated patterns of abnormally elevated bilateral amygdala activity in response to emerging fearful, sad, and angry facial expressions in remitted‐BD subjects versus HC, and abnormally elevated right amygdala activity to emerging fearful faces in depressed‐BD subjects versus HC. We also showed distinguishable patterns of abnormal EC between the amygdala and dorsomedial and ventrolateral PFC, especially to emerging happy and sad facial expressions in remitted‐BD and depressed‐BD subjects. Discussion: EC measures of neural system level functioning can further understanding of neural mechanisms associated with abnormal emotion processing and regulation in BD. Our findings suggest major differences in recruitment of amygdala–PFC circuitry, supporting implicit emotion processing between remitted‐BD and depressed‐BD subjects, which may underlie changes from remission to depression in BD.     

Normal pituitary volumes in children and adolescents with bipolar disorder: a magnetic resonance imaging study

The volume of the pituitary gland in adults with bipolar disorder has previously been reported to be smaller than that of healthy controls. Such abnormalities would be consistent with the HPA dysfunction reported in this illness. We conducted a study of children and adolescents with bipolar disorder to determine whether size abnormalities in the pituitary gland are already present early in illness course. Magnetic resonance imaging (MRI) morphometric analysis of the pituitary gland was carried out in 16 DSM-IV children and adolescents with bipolar disorder (mean age+/-sd=15.5+/-3.4 years) and 21 healthy controls (mean age+/-sd=16.9+/-3.8 years). Subjects underwent a 1.5 T MRI, with 3-D Spoiled Gradient Recalled (SPGR) acquisition. There was no statistically significant difference between pituitary gland volumes of bipolar patients compared to healthy controls (ANCOVA, age, gender, and ICV as covariates; F=1.77, df=1,32, P=.19). There was a statistically significant direct relationship between age and pituitary gland volume in both groups (r=.59, df=17, P=.007 for healthy controls; r=.61, df=12, P=.008 for bipolar patients). No evidence of size abnormalities in the pituitary gland was found in child and adolescent bipolar patients, contrary to reports involving adult bipolar patients. This suggests that anatomical abnormalities in this structure may develop later in illness course as a result of continued HPA dysfunction.     

Affective neural circuitry during facial emotion processing in pediatric bipolar disorder.

BACKGROUND: Facial emotions are central to human interaction. Identifying pathophysiology in affect processing circuitry that supports the ability to assess facial emotions might facilitate understanding of affect regulation in pediatric bipolar disorder. METHODS: Ten euthymic, unmedicated pediatric bipolar patients and 10 healthy control subjects matched for age, gender, race, socioeconomic status, and IQ were scanned with functional magnetic resonance imaging. Angry, happy, and neutral faces were presented in 30-sec blocks, with a 20-sec rest period between blocks. Subjects were asked to press a button when each face appeared, to ensure that attention was maintained on-task. RESULTS: In bipolar patients, in response to both angry and happy faces relative to neutral faces, we observed reduced activation of right rostral ventrolateral prefrontal cortex together with increased activity in right pregenual anterior cingulate, amygdala, and paralimbic cortex. Bipolar patients also showed reduced activation of visual areas in occipital cortex together with greater activation in higher-order visual perceptual areas, including superior temporal sulcus and fusiform gyrus with angry faces and posterior parietal cortex with happy faces. CONCLUSIONS: Findings document a disturbance in affective neurocircuitry in pediatric bipolar disorder. Reduced activation in ventrolateral prefrontal cortex might reflect diminished top-down control that leads to the observed exaggerated activation in amygdala and paralimbic areas. Changes in occipital areas might represent an effort to gate sensory input when affective responses to the faces could not be successfully modulated. Disturbances in affect processing circuitry could contribute to emotional dysregulation and social cognitive difficulties in bipolar youth.     

Regional brain changes in bipolar I depression: a functional magnetic resonance imaging study

Objective:  To investigate neural activity in prefrontal cortex and amygdala during bipolar depression.
Methods:  Eleven bipolar I depressed and 17 normal subjects underwent functional magnetic resonance imaging (fMRI) while performing a task known to activate prefrontal cortex and amygdala. Whole brain activation patterns were determined using statistical parametric mapping (SPM) when subjects matched faces displaying neutral or negative affect (match condition) or matched a geometric form (control condition). Contrasts for each group for the match versus control conditions were used in a second-level random effects analysis.
Results:  Random effects between-group analysis revealed significant attenuation in right and left orbitofrontal cortex (BA47) and right dorsolateral prefrontal cortex (DLPFC) (BA9) in bipolar depressed subjects. Additionally, random effects analysis showed a significantly increased activation in left lateral orbitofrontal cortex (BA10) in the bipolar depressed versus control subjects. Within-group contrasts demonstrated significant amygdala activation in the controls and no significant amygdala activation in the bipolar depressed subjects. The amygdala between-group difference, however, was not significant.
Conclusions:  Bipolar depression is associated with attenuated bilateral orbitofrontal (BA47) activation, attenuated right DLPFC (BA9) activation and heightened left orbitofrontal (BA10) activation. BA47 attenuation has also been reported in mania and may thus represent a trait feature of the disorder. Increased left prefrontal (BA10) activation may be a state marker to bipolar depression. Our findings suggest dissociation between mood-dependent and disease-dependent functional brain abnormalities in bipolar disorder.     

Juvenile bipolar disorder

OBJECTIVE: Bipolar disorder in children and adolescents is less well studied than bipolar disorder in adults. This review addresses issues related to its underdiagnosis, precursors of bipolarity, comorbidity, natural course and treatment. METHOD: Literature from Medline and other searches, and earlier relevant articles including references from recent review articles on juvenile bipolarity were reviewed. RESULTS: Bipolar disorder in juveniles is underdiagnosed and misdiagnosed on various counts. Few recent studies have reported high rates of comorbid attention deficit and disruptive disorders, prompting some researchers to consider them as probable developmental precursors of juvenile bipolarity. There is also evidence to suggest that some juvenile depression could be pre-bipolar, and that certain temperamental predispositions are probable precursors to bipolarity. Limited data on the natural course and outcome suggest that juvenile bipolar disorder is a highly recurring illness as in adults, and that it is associated with significant functional impairment. The psychopharmacological treatment of juvenile bipolar disorder is remarkably understudied, and treatment is often based on studies of adults. CONCLUSION: There is a need for epidemiological studies of juvenile bipolar disorder. Similarly, there is an urgent need for the methodologically rigorous studies to establish the efficacy of various antimanic drugs. Finally, issues related to comorbidity and temperamental predispositions to juvenile bipolarity need greater clarity, as they may have important treatment and research implications.