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Review Article Neuroprogression in bipolar disorder Introduction Bipolar disorder is a major psychiatric illness typically characterized by recurrent episodes of mania and depression (1). In the United States, the lifetime prevalence estimate of bipolar I disorder is �1.1%, with an estimated annual cost of $45 billion (2). While the pathophysiology of bipolar disorder remains incompletely understood, evi- dence suggests that people with bipolar disorder show progressive changes in symptomatology over the course of illness. Specifically, patients with bipolar disorder may exhibit progressive increases in the frequency and severity of affective episodes over time (3), and a worsening of long-term outcome (4). Furthermore, several studies have noted episode-related decrements in cognitive function potentially indicative of underlying neu- ropathologic changes (5–8). Over the last few years, investigators have begun to link these clinical observations with emerging neuroimaging findings, and to explore whether these findings represent aberrant neurodevelopmental processes or evidence of illness-related epiphenomena. Nonetheless, the effects of time and illness exposure on individuals with, and at risk for, bipolar disorder have been only scantily studied. The studies that have been performed may be divided into cross-sectional, usually retrospective, studies and more prospective, longitudinal studies. The former raise obvious issues of historical reliability and the interpretation of correlational findings, whereas the latter are necessarily limited in scope and timing. Both of these methodologies Schneider MR, DelBello MP, McNamara RK, Strakowski SM, Adler CM. Neuroprogression in bipolar disorder. Bipolar Disord 2012: 14: 356–374. � 2012 The Authors. Journal compilation � 2012 John Wiley & Sons A ⁄S. Objective: Recent theories regarding the neuropathology of bipolar disorder suggest that both neurodevelopmental and neurodegenerative processes may play a role. While magnetic resonance imaging has provided significant insight into the structural, functional, and connectivity abnormalities associated with bipolar disorder, research assessing longitudinal changes has been more limited. However, such research is essential to elucidate the pathophysiology of the disorder. The aim of our review is to examine the extant literature for developmental and progressive structural and functional changes in individuals with and at risk for bipolar disorder. Methods: We conducted a literature review using MEDLINE and the following search terms: bipolar disorder, risk, child, adolescent, bipolar offspring, MRI, fMRI, DTI, PET, SPECT, cross-sectional, longitudinal, progressive, and developmental. Further relevant articles were identified by cross-referencing with identified manuscripts. Conclusions: There is some evidence for developmental and progressive neurophysiological alterations in bipolar disorder, but the interpretation of correlations between neuroimaging findings and measures of illness exposure or age in cross-sectional studies must be performed with care. Prospective longitudinal studies placed in the context of normative developmental and atrophic changes in neural structures and pathways thought to be involved in bipolar disorder are needed to improve our understanding of the neurodevelopmental underpinnings and progressive changes associated with bipolar disorder. Marguerite Reid Schneidera, Melissa P DelBellob, Robert K McNamarab, Stephen M Strakowskib and Caleb M Adlerb aPhysician Scientist Training Program, Neuroscience Graduate Program, bDepartment of Psychiatry and Behavioral Neuroscience, Division of Bipolar Disorders Research, University of Cincinnati College of Medicine, Cincinnati, OH, USA doi: 10.1111/j.1399-5618.2012.01024.x Key words: bipolar disorder – degeneration – development – magnetic resonance imaging (MRI) neuroimaging – progression. Received 6 January 2011, revised and accepted for publication 23 March 2012 Corresponding author: Caleb M. Adler, M.D. Department of Psychiatry and Behavioral Neuroscience University of Cincinnati College of Medicine 260 Stetson Street, Suite 3200 Cincinnati, OH 45219-0516 USA Fax: (513) 558-3399 E-mail: adlercb@ucmail.uc.edu Bipolar Disorders 2012: 14: 356–374 � 2012 John Wiley and Sons A/S BIPOLAR DISORDERS 356 have now been applied to patients with bipolar disorder across the age and illness spectrum, with varied results. In this review, we will summarize some of these findings and attempt to place them in the larger context of recent advances in our understanding of bipolar disorder. To do so, we review the findings from both adult and pediatric samples, as well as findings from multiple at-risk populations, including child, adolescent, and adult offspring of parents with bipolar disorder; twins discordant for bipolar disorder; and unaffected siblings of patients with bipolar disorder. Bipolar disorder is arguably one of the most heritable of the Axis I disorders. Family studies have found that individuals with a first-degree relative with bipolar disorder have a substantially elevated risk for developing bipolar disorder com- pared with the general population (9, 10), with prevalence estimates in this population as high as 10–16% (11, 12). Furthermore, approximately 55% of the offspring of parents with bipolar disorder are ultimately diagnosed with a psychia- tric illness of some kind, most commonly mood, anxiety, or disruptive behavior disorders (11, 13, 14). Emerging evidence has identified a number of other potential endophenotypes that may precede and ⁄or increase risk for overt bipolar symptom- atology (15–17). Approximately 50% of bipolar disorder patients report a history of severe trauma or abuse during childhood, which may be associ- ated with an earlier age of onset and a more severe course of illness (18–22). In addition, some emerg- ing evidence suggests that long-term exposure to psychostimulant and antidepressant medications may precipitate and accelerate the onset of mania in vulnerable individuals (23–26). Lastly, some evidence from cross-sectional and preliminary intervention studies suggests that nutritional defi- ciencies, including essential vitamin and fatty acid insufficiency, may also exacerbate the course of mood and psychotic disorders (27–31). Offspring of parents with bipolar disorder often exhibit a range of subsyndromal mood symptoms, including depression, anxiety, sleep disturbances, and irritability, as well as other clinical manifesta- tions of underlying psychopathology that may precede the initial onset of mania by as much as 10 years (32). One prospective study found that 25% of children and adolescents initially diagnosed with subsyndromal symptoms of bipolar disorder (e.g., bipolar disorder, not otherwise specified), and 20% diagnosed with type II bipolar disorder, were ultimately diagnosed with type I bipolar disorder during a two-year follow-up period (33). Cognitive symptoms, particularly deficits in concentration and attention, may also precede the onset of mania. Studying neurofunctional and neurostruc- tural changes occurring prior to illness onset in these individuals at increased risk for developing bipolar disorder is crucial to understanding the development and progression of the illness. Fur- thermore, conducting neuroimaging studies on individuals with a known risk for developing bipolar disorder may lead to identification of potential neuronal endophenotypes, as well as possible neurostructural and neurofunctional risk and resiliance factors. 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Neocor- tical gray matter volume in first-episode schizophrenia and first-episode affective psychosis: a cross-sectional and longitudinal MRI study. Biol Psychiatry 2007; 62: 773– 783. Schneider et al. 374neurodevelop- mental abnormalities associated with bipolar dis- order during childhood and adolescence, but several studies have reported neurostructural find- ings in youth that differ from those seen in adults. Only a small number of these imaging studies are longitudinal—and only a single study obtained scans both before and after the onset of full bipolar disorder symptoms (36). Rather, a majority of published research addresses potential alterations in neurodevelopmental trajectories and other pro- gressive changes by evaluating correlations of structural measurements with age or with measures of illness burden (e.g., duration of illness and number of mood episodes). However, the typical developmental trajectories of brain structures thought to be involved in bipolar disorder are often non-linear, have large variability even within typically developing youth, and demonstrate important sex differences (37). Therefore, linear correlations with age or illness burden identified in cross-sectional studies are extremely difficult to interpret. Longitudinal studies are needed to pro- spectively explore the developmental abnormalities detected via correlation in these cross-sectional investigations. While illness-related changes in children and adolescents with bipolar disorder are often inter- preted as demonstrating neurodevelopmental abnormalities, changes in adults may represent areas of bipolar-related neuropathology that reflect either underlying neurophysiological progression or epiphenomena of recurrent affective episodes. This interpretation is buttressed by long-standing clinical and cognitive findings. For instance, while Kraepelin (38) highlighted the gradual cognitive decline associated with dementia praecox he also Neuroprogression in bipolar disorder 357 published data suggesting that bipolar disorder patients demonstrated progressively shorter euthy- mic periods over the course of their illness, findings that have been repeated in much more recent cohorts (39). Data published over the last few decades echo this clinical observation. Several studies have reported cognitive deficits associated with illness duration or number of affective epi- sodes (5–8, 40). The nature, or even presence, of the neuropathologic underpinnings of these obser- vations, however, remains controversial. While extensive findings have documented the presence of neurostructural and neurofunctional differences in patients with bipolar disorder, evidence of illness-related neuropathologic changes remains scant and conflicting. Structural findings Global neurostructural studies As early as 1983, Rieder and colleagues (41) found a correlation between age and ventricle-to-brain ratios in a group of adult bipolar disorder patients. Since that time, several studies identified evidence of atrophic changes in the brains of older patients with bipolar disorder, reflected in decreased total gray matter volume and increased lateral and third ventricle volumes. Positive findings in adult bipolar disorder samples have been far from universal, however (42, 43). The majority of studies employ- ing proxies for illness exposure have been unrevealing; age of onset and illness duration, for instance, have generally correlated poorly with total gray matter volume (44–46), although two studies did report an inverse correlation between length of illness and total gray matter volume (47), and at least a trend toward increased lateral ventricle size (48). In addition, a recent meta- analysis found an inverse correlation between illness duration and total cerebral volume (49). The number of affective episodes constitutes an arguably more direct measure of illness exposure; although this metric has not, for the most part, been found to correlate with total gray matter volume (44, 45, 47). One study found lateral ventricle size to be larger in multiple- versus first- episode patients (48). Two small studies using a prospective design failed to identify changes in cerebral volume over spans of a few years (50, 51). The at least equivocal evidence for global structural changes in adult bipolar disorder patients must be reconciled with the relative absence of conclusive findings in children and adolescents with bipolar disorder. Several studies have failed to detect overall differences in gray matter (52, 53), white matter (52), total brain volume (52, 54, 55), or intracranial volume (56–60) between young patients with bipolar disorder and healthy subjects, though there have also been several reports of smaller total cerebral or brain volumes in young bipolar disorder patients (61– 65). Thus far, studies that examined correlations between age at onset (62) or duration of illness (53) and overall volumes have been negative. However, it is difficult to intrepret these findings, as studies did not specifically consider the non-linear trajec- tory of typical brain development in childhood and adolescence. Ventricular findings in pediatric patient samples are similarly mixed, and often complicated by significant clinical heterogeneity including the presence of psychotic symptoms. The two positive reports of increased ventricular volumes in young patients with bipolar disorder suggest that ventric- ular enlargement may be associated broadly with psychosis rather than bipolar disorder specifically. In one study, enlargement was only detected in the subset of paitents with psychotic bipolar disorder (66), while another study reported results from a mixed patient sample of youth with either bipolar disorder or schizophrenia (67). To date, no differences in ventricular volumes (66, 68) or ventricle-to-brain ratios (53) have been reported for pediatric or adolescent bipolar disorder pa- tients without psychosis. In addition, no correla- tion was detected between age or medication use and ventricular volumes in youth with bipolar disorder, either with or without psychosis (66). It is possible that the discrepancy in results between adult and younger bipolar disorder patients is explained by failure in many adult bipolar disorder studies to control for normal age-related neuronal changes. Similarly, there is no evidence for global volu- metric or neurostructural changes in relatives of patients with bipolar disorder or those at risk for the illness, and there have been several negative reports. One study using voxel-based morphometry to assess relationships of brain structure to genetic liability for bipolar disorder and schizophrenia concluded that there was no relationship between genetic liability and either gray or white matter volumes in the former (69). In another study, unaffected relatives of patients with bipolar disor- der did not exhibit abnormalities in ventricular volumes (70). Overall, the heterogeneity of results makes it difficult to draw conclusions regarding the develop- mental or progressive nature of global volumetric and ventricular abnormalities in patients with bipolar disorder. It seems reasonable to conclude, Schneider et al. 358 given the lack of findings in patient relatives and at-risk samples, that these measures are not good candidate risk factors or endophenotypes for the disorder. Overall deficits in gray matter volume may develop early in the course of bipolar illness in subpopulations of young patients, and there is at least some evidence for progressive gray matter loss in adults. However, we do not have enough evidence to determine if such changes are reflective of volume loss or the absence of expected devel- opmental gains in young patients, or reflect accel- erated neuronal loss in older bipolar disorder patients. Furthermore, findings of overall volume decrease may merely reflect more specific regional volume changes rather than true global volumetric differences. Future research should explore these questions longitudinally, and more rigorously control for the expected age-related changes, both developmental and degenerative, in the population being considered. Regional neurostructural studiesPrefrontal cortical structures Several regions of the cortex have been implicated in the pathophysiology of bipolar disorder, due to both structural and functional imaging evidence and behavioral and cognitive deficits that are associated with the illness. The areas with the most significant evidence for involvement include the ventral prefrontal cortex and the anterior cingulate (ACC), although other regions may also be implicated. It is for this reason that cortical regions have been studied extensively in at-risk individuals, as well as pediatric and adult bipolar disorder patients. Twin studies have identified a relationship between genetic risk of developing bipolar disorder and decreased gray matter density in the right medial frontal and precentral gyri (71, 72). Other studies of unaffected siblings of adults with bipolar disorder identified an association between genetic risk for bipolar disorder and gray matter deficits in the right ACC as well as bilateral frontal, left temporoparietal, and right parietal regions (73). However, abnormalities have not been detected prior to the onset of illness in all cortical regions studied. For example, no differ- ences in subgenual cingulate volume were detected in individuals from families with bipolar disorder (74). Singh and colleagues (75) reported no volu- metric differences in the prefrontal cortex between 8- to 12-year-old children with a familial risk for mania and children of parents without psychopa- thology. Another study, examining at-risk youths who were free of any psychiatric disorder, also found no differences in orbitomedial prefrontal cortical volumes versus the offspring of healthy subjects. However, their unusual lack of any psychiatric symptomatology suggests the possible presence of protective factors in these individuals, and this finding may represent a resiliency factor (76). Numerous studies have detected structural abnormalities in cortical gray matter in youth with bipolar disorder, including decreases in prefrontal and cingulate volume (58, 77–85). However, the developmental nature of these findings is often unclear. Several studies have failed to detect correlations between cortical volumes and either age or duration of illness (53, 59, 78–81, 83). A cross-sectional study of ventrolateral prefrontal cortex (VLPFC) volume found an interaction between volume and age, suggesting that there may be an acceleration of normal age-related volume loss in late adolescence and early adult- hood in patients with bipolar disorder (54), but the underlying mechanism is unknown. Cross-sectional findings in adults are similarly unrevealing. Structural abnormalities in portions of the prefrontal cortex have been widely observed, and several investigators suggested that progressive clinical changes in patients with bipolar disorder may be linked to neuropathology in this region. However, as in at-risk and youth samples, the evidence for progressive changes associated with bipolar symptomology is mixed. While two studies identified inverse correlations between number of manic episodes and prefrontal gray matter volume and density (86, 87), a majority of investigators failed to observe any relationship between age, age of onset, illness duration, or even number of affective episodes and prefrontal volume (45, 54, 86, 88, 89). There is, nonetheless, some evidence that portions of the VLPFC may be particularly vulnerable to the effects of bipolar symptomatol- ogy in adult patients, although the direction of this association is not clear. Patient age and illness duration inversely correlated with cortical thick- ness in the middle frontal cortex and gray matter volume in the right medial prefrontal gyrus, including Brodmann�s areas (BA) 8 ⁄10 (43, 90). Conversely, in other studies, illness duration and number of affective episodes were found to posi- tively correlate with prefrontal volume in other, partially overlapping, regions (45, 91). Some of these apparent inconsistencies may be related to variations in the age of the sample, mood state, history of substance use, or treatment. In the anterior cingulate cortex, for instance, age at onset was negatively correlated with volumes on the right only in patients receiving lithium. No significant Neuroprogression in bipolar disorder 359 findings were observed in unmedicated patients (88). It may also be significant that subjects in the studies by Li et al. (45) and Lopez-Larson et al. (91), which reported positive associations, were somewhat younger; several investigators suggested that the VLPFC may be characterized by an initial increase in volume early in the course of illness, only later followed by longer-term atrophic changes (92). Recent efforts to connect neurostruc- tural changes to specific genetic polymorphisms (93) may help to elucidate the underlying patho- physiology associated with these changes. Studies of cortical development represent the largest body of longitudinal structural data in individuals with bipolar disorder, including multi- ple longitudinal studies of cortical development in child, adolescent, and young adult bipolar disorder samples. However, as with cross-sectional studies, interpretation of the results of these studies in a developmental context remains a challenge. Typi- cal cortical development is distinctly non-linear, particularly during adolescence, and has been characterized as an inverted U-shape, with the timing of peak volume varying across cortical lobes and even subregions within each lobe, and occur- ring later in boys than in girls. This volume peak is followed by regional volume reductions in typically developing individuals (37). The implication is that even typically developing individuals within an adolescent patient population would be expected to show a wide range of cortical volume changes over time. Nonetheless, longitudinal studies represent some of the best resources for understanding progressive changes in bipolar disorder patients across the course of the illness. One important longitudinal study that scanned patients both before and after the onset of bipolar disorder specifically considered cortical develop- ment by using dynamic cortical mapping (36). This study identified children and adolescents present- ing with symptoms of mood lability and attention- deficit hyperactivity disorder (ADHD), but who did not meet criteria for either bipolar disorder or schizophrenia. These patients were labeled as multi-dimensionally impaired, and followed with repeated structural magnetic resonance imaging (MRI) scans. Several of the patients went on to develop bipolar disorder, and those patients showed a pattern of cortical development distinct from that of healthy adolescents, including increases in left cortical gray matter in the VLPFC and orbitofrontal cortex (OFC), as well as bilateral loss of anterior and subgenual cingulate volume. Results were clearer when the scans were aligned with respect to the first manic episode, suggesting that this pattern was associated with the onset of bipolar illness. However, a similar pattern was seen in patients who were initially impaired but did not develop bipolar disorder, suggesting that these findings may be associated with mood lability generally as opposed to bipolar disorder specifi- cally. However, this study does support suggestions that prefrontal volume increases may be associated with the early period of bipolar illness. A study by Kalmar and colleagues (94) exploring cortical development in children and adolescents with bipolar disorder found that over two years, adolescents with bipolar disorder showed greater volume decreases than healthy subjects in the prefrontal cortex bilaterally, including left BAs 10 and 11, the rostralACC, and the rightmedial frontal gyrus. In this study, participants had a mean duration of illness of more than five years at the first scan, supporting suggestions that cortical volume increases may precede longer-term cortical atrophy. Similarly, Lisy andcolleagues (95) reported that, while adolescents and adults with bipolar disorder showed smaller volumes compared to healthy sub- jects in several prefrontal regions at baseline, sub- jects with bipolar disorder demonstrated increases over time in several regions. Parsing the sample by age, they found areas of increased left superior and right medial frontal volumes only in adolescents. Temporal cortex The temporal cortex in general, and medial tem- poral structures in particular, have been widely implicated in the pathophysiology of bipolar dis- order. Structures in this region, including the superior temporal gyrus, amygdala, and hippo- campus, have been particularly well studied in both at-risk samples and patients with bipolar disorder. In youth with bipolar disorder, overall temporal cortical findings have been mixed; one study failed to detect any difference in temporal lobe volume between healthy adolescents and those with bipolar disorder (56), while others reported both decreased (78) and increased (82) temporal lobe volumes. No association between total temporal cortical volume and the duration of illness was reported for young bipolar disorder patients (78). Overall temporal cortical findings in adult patients have also been inconsistent; those reporting a change in volume associated with bipolar disorder exposure have separately identified both positive and negative correlations (42, 96, 97). Superior temporal gyrus. Several studies reported decreased superior temporal gyrus volume in children and adolescents with bipolar disor- der (78, 80, 81). However, those that examined Schneider et al. 360 correlation with age (81) and duration of illness (78) did not detect an association. In adult patients, studies of the superior temporal gyrus have also been generally unrevealing. Investigators observed only an inverse correlation between volume and age, which did not carry over into associations with the duration or number of affective episodes (43, 98). Interestingly, a longitudinal study including both adolescent and adult patients with bipolar disorder reported increased volume in the superior temporal gyrus over time in patients but not controls (95). Overall, the interpretation of findings in the superior temporal gyrus is complicated by the observation of different developmental trajec- tories in anterior and posterior subregions, and late maturation in healthy individuals, with expected decreases in volume extending into early adulthood (99). To our knowledge, no study has specifically examined this temporal structure in at-risk popu- lations. Amygdala. Volumetric and functional alterations in the amygdala are common findings in patients with bipolar disorder, although the findings in adult and pediatric samples are inconsistent. Amygdala volume has been often found to be increased in adults with bipolar disorder, but the effect of bipolar symptomatology on amygdala structure is not entirely clear. Although some studies have failed to identify any effects of bipolar disorder course of illness on amygdala volumes (42, 89, 98, 100, 101), other findings suggest that illness course characteristics are associated with morphological changes. Altshuler and colleagues (97), for instance, found that amygdala volumes in patients with bipolar disorder inversely correlated with the number of previous manic episodes, while others noted smaller amygdala volumes in older patients (102). In contrast, at least one longitudinal study and some meta-analyses have noted amyg- dala enlargement over time in adult patients (103– 105). These findings, however, may be distorted by developmental differences in amygdala volume and trajectory between children ⁄adolescents and adults, or differences in illness duration or medi- cation exposure between samples (95, 103–105); in particular, lithium exposure may lead to increased amygdala volumes in adults (101). In contrast to adults, reduction in amygdala volume is the most frequently replicated structural finding in children and adolescents with bipolar disorder (55, 56, 62, 77, 100, 106), although such differences have not been universally detected (63– 65, 107). Two different meta-analyses found that amygdala volume is consistently smaller in children and adolescents with bipolar disorder, compared to psychiatrically healthy comparison groups (104, 105). Two studies suggest that amygdala volume decreases over time. Geller and colleagues (107) found decreasing amygdala volume with age in bipolar disorder and increases in these volumes with age in healthy subjects. In a second paper, DelBello and colleagues (62) reported no association with age, but noted a negative correlation between amygdala volume and the duration of illness in patients with bipolar disorder. These findings are not, however, entirely consistent; Chen and col- leagues (56) found a direct correlation between age and amygdala volume in bipolar disorder and an inverse relationship in healthy adolescents. Nonetheless, recent findings from a longitudinal study of adolescents following their first episode of mania lend support to the hypothesis that a decrease in volume occurs following the onset of symptoms. Bitter and colleagues (108) recruited patients who were initially scanned during their first manic or mixed episode and then again approximately one year later. At baseline, the first-episode patients did not differ in amygdala volumes from either healthy adolescents or ado- lescents with ADHD. However, over a one-year follow-up, there were significant differences in developmental trajectories, such that at endpoint, bipolar disorder patients had significantly smaller amygdala volumes bilaterally. Consistent with these findings, a second longitudinal study of amygdala volume in multi-episode adolescents with bipolar disorder found that patients had smaller amygdala volumes at index assessment. In this study, differences remained stable over a follow-up period of approximately two years, with no effects of time on amygdala volumes in either the patients or healthy subjects (109). Studies in multiple at-risk populations failed to detect amygdala abnormalities in either family members of bipolar disorder patients or youth at risk for the disease. Hajek and colleagues (110) reported no differences in amygdala volume be- tween affected and non-affected high-risk partici- pants from families affected with bipolar disorder (i.e., having a first- or second-degree relative with bipolar I disorder or a first-degree relative with bipolar II disorder) and healthy subjects. Singh and colleagues (75) also found no differences in amygdala volume in 8- to 12- year-old children with a familial risk for mania compared to children of parents without psychopathology, and Karchemskiy and colleagues (111) reported no differences in amygdala volumes of children and adolescents with ADHD and non-bipolar mood symptoms and who were offspring of parents with bipolar disorder compared to healthy controls. Neuroprogression in bipolar disorder 361 Together, this evidence suggests that structural abnormalities of the amygdala likely develop following the onset of illness, rather than repre- senting a risk factor or endophenotype associated with bipolar disorder. Taken together, these findings suggest that decreased amygdala volumes associated with bipo- lar disorder in adolescents may be neurodevelop- mental, begin with the onset of the illness, and be limited to a relatively short period close to the appearance of mania. This pattern, combined with the high variability in amygdala volumes in healthy youth, and the observation that correla- tions between amygdala volume and age are sexually dimorphic (112), may explain the contra- dictory correlational findings in cross-sectional studies of amygdala volumes in youth with bipolar disorder. The underlying mechanism of these volumetric abnormalities remains unknown. How- ever, it has been shown that amygdala volume inversely correlates with activity duringthe view- ing of emotional facial stimuli in adolescents with bipolar disorder (106), suggesting either excitotox- icity or the selective loss of inhibitory neurons as potential mechanisms that could be associated with both hyperactivity and decreased volumes in this region. Findings in children and adolescents with bipolar disorder are distinctly different than the majority of findings in adults. It is possible that early-onset bipolar disorder is associated with different amygdala pathology than bipolar disor- der in adults. Alternatively, the initial decrease in volume observed in adolescence may be followed by an increase over a longer timescale. Further research is needed to distinguish between these possibilities. Hippocampus. Hippocampal findings in adult bipo- lar disorder patients have been somewhat contra- dictory. Some studies have failed to identify any effects of bipolar illness course on hippocampal volumes (89, 98, 100), while others are suggestive of decreases in volume with illness exposure (49, 113), and longitudinal data suggest hippocampus vol- umes increase over time (95). These latter findings are further supported by a study in which Strakow- ski and colleagues (48) observed hippocampi to be larger in multi- versus first-episode patients, although multi-episode patients did not differ from healthy subjects. Similarly, studies in children and adolescents with bipolar disorder have either failed to detect alterations in hippocampal morphometry (55, 56, 64, 77, 107) or found reductions in volume (52, 63, 65, 100). Isolated abnormalities in hippocampal subregions may help to explain these discrepancies. A recent study using three-dimensional modeling found significant volume reductions in hippocampal volume in adolescents with bipolar disorder, with localized deficits in the head and tail on the left, most pronounced in the auricular region (52). This same study found alterations in the volumetric changes associated with age; adolescents with bipolar disorder showed an increase in hippocam- pal volumes over time, specifically in the anterior and posterior CA1 subfields, while healthy adoles- cents showed volume decreases associated with age, specifically in the subiculum and anterior CA1 regions. This increase in volume over time in patients seems difficult to reconcile with the general findings of decreased volume, although it may be related to alterations in the timing of normal hippocampal development in youth with bipolar disorder. Interpretation of correlational findings in the hippocampus is further complicated by evidence that changes in hippocampal volumes during adolescence are sexually dimorphic both in healthy and in bipolar disorder subjects. Women and girls with bipolar disorder have been found to have smaller hippocampi in several studies (63–65), and in one study of healthy adolescents, a significant correlation between volume and age was reported only for girls (112). Therefore, these detected differences in hippocampal volumes may be due to alterations in developmental processes, leading to differences that become increasingly apparent as healthy girls show expected increases in hippocam- pal volume; whereas, girls with bipolar disorder have altered timing or trajectory of hippocampal development. Further research is needed to deter- mine if sex differences in structural correlates are associated with clinical or functional differences between young men and women with bipolar disorder. Combined with evidence from adult popula- tions, these results suggest that individuals with bipolar disorder may show later development of hippocampal structures with continued increases over time, either with age or with illness exposure. It remains possible that there are heterogeneous alterations across multiple subregions of the hip- pocampus, and future research should explore this possibility. Thus far, there have been no reports of altered hippocampus volumes in relatives of patients with bipolar disorder or in at-risk samples (75, 110, 111). One study, examining at-risk youth who were free of any psychiatric disorder, identi- fied significantly increased gray matter volumes in the left parahippocampal ⁄hippocampal gyrus in healthy offspring of parents with bipolar disorder. Given that the lack of any psychiatric symptom- Schneider et al. 362 atology in such a high-risk group is unusual, this finding may represent a resiliency factor (76). Nucleus accumbens The volume of the nucleus accumbens has been reported to be increased (61, 64, 65, 77), decreased (77), and unchanged (107) in youth with bipolar disorder. While these mixed results make it difficult to draw definitive conclusions, there is some evidence that there may be developmental expla- nations for these varied findings. In one study, larger right nucleus accumbens volumes were found only in a prepubertal subgroup of patients with bipolar disorder, while there was no relation- ship between volumes and puberty status in healthy adolescents (61). Consistent with these findings, Geller and colleagues (107) reported a decrease in nucleus accumbens volume associated with age in boys with bipolar disorder, with no age- related change in healthy subjects. Recent studies in adult patients have similarly reported decreased volumes in this region (114, 115). Basal ganglia ⁄ striatum Some of the most consistently reported structural findings associated with genetic risk for bipolar disorder involve striatal volume. Nonetheless, even these data have been mixed, with reports of both increased and decreased striatal volumes in at-risk samples. Both unaffected and affected twins of probands with bipolar disorder show larger left caudate volumes than healthy subjects (71, 116), while other studies of unaffected siblings of adults with bipolar disorder identified an association between genetic risk for bipolar disorder and gray matter deficits in the ventral striatum (73). Simi- larly, Hajek and colleagues (117) also reported finding differences between caudate volumes in affected and unaffected at-risk subjects, although the finding was not significant after controlling for the non-independence of observations in multiple subjects per family. Further, neither affected nor unaffected high-risk participants from families with bipolar disorder exhibited differences in putamen volumes compared to healthy subjects (117). The interpretation of these findings is further complicated by the limited evidence for volumet- ric differences in the basal ganglia of adolescents with bipolar disorder. A majority of studies have found no differences between bipolar disorder and healthy adolescents in caudate (55, 60–62, 64, 65, 118), putamen (60, 61, 64, 65), or globus pallidus volumes (61, 62, 64, 65). In contrast, there has been only one report of increased volume in the putamen of youth with bipolar disorder (62), while one voxel-based morphometry study found areas of increased volume in subregions of the basal ganglia that include the anterior putamen and the head of the caudate (82). The inconsis- tency in the findings in youth with bipolar disorder may be due in part to the high levels of ADHD comorbidity in this population. Striatal volume reduction and abnormal trajectory of striatal development is an often replicated finding in youth with ADHD (119). A recent study looking at the differential effects of ADHD and bipolar disorder diagnosis on striatal volumes found that bipolar disorder was associated with increases in the volume of the caudate, putamen, and globus pallidis, while ADHD was associated with decreases in these regions (120). These findings are in contrast with an earlier study that found that bipolar disorder patients with and without ADHD did not differ from each other or from healthy subjects (65), although both studies reported reductions in striatal volumes in patients with ADHD alone. In one cross-sectional study, bipolar disorder adolescents exhibited an inverse correlation be- tween age and volume ofthe left and right caudate, and the left putamen, while there was no relation- ship between striatal volumes and age in healthy youth (60). While, to our knowledge, no longitu- dinal studies have been published exploring the development of, or progressive changes in, the basal ganglia of adolescents with bipolar disorder, a single longitudinal study in relatively young adults with bipolar disorder reported increases in basal ganglia volume over several years (95). Subcortical volumes in adults have not, for the most part, been otherwise found to correlate with age, age at onset, illness duration or number of affective episodes (43, 48, 89, 121). Only Brambilla and colleagues (122) noted an inverse correlation between duration of illness and left putamen size, as well as evidence of increasing globus pallidus volume. Thalamus To our knowledge, there have been no descriptions of thalamic volume changes specific to relatives of patients with bipolar disorder. However, a com- parison of MRI findings among unaffected rela- tives of patients with bipolar disorder or schizophrenia, unaffected individuals from families with both schizophrenia and bipolar disorder, patients with bipolar disorder or schizophrenia, and healthy subjects identified reduced anterior Neuroprogression in bipolar disorder 363 thalamic gray matter in both patient groups and unaffected relatives, compared with healthy sub- jects, suggesting that thalamic volume changes may represent a general marker of psychosis (123). This suggestion is supported by the findings from an early study in adolescents with either bipolar disorder or schizophrenia, which found that the combined patient group had a smaller thalamic area than healthy adolescents (124). In contrast, thalamic findings in groups of both young and adult bipolar disorder patients are quite sparse. The majority of studies in children and adolescents have found no differences in thalamic volumes (55, 62–65, 125) and associations have not been reported between thalamic volume and age or measures of illness burden in either young or adult patients. Cerebellum and subtentorial structures One of the earliest, computerized tomography studies of bipolar brains found no correlation between patients� age and measures of cerebellar atrophy (41). Another early study using structural MRI similarly failed to observe any relationship between either duration of illness or number of affective episodes and cerebellar volume (89). Since that time, however, other investigators have noted negative correlations between age and cerebellar size (43), and at least one longitudinal study found progressive loss of cerebellar gray matter (126). It may be that portions of the cerebellum are dispa- rately affected; three studies found an association between the number of affective episodes and a specific portion of the cerebellar vermis, including lobules VIII through X (V3), and one study found an association for lobules IV through VII (V2) (127–129). In children with bipolar disorder, a single study found no statistically significant differences in volume of the total cerebellum, or in any cerebellar subregion, compared with healthy subjects, although there was a trend toward a smaller V2 area in the bipolar group (130). In this sample, however, age was inversely correlated with the V3 area in patients but not healthy subjects, and there was a trend toward an inverse correlation between the V2 area and the number of previous episodes, largely driven by the male patients. Kempton and colleagues (131) observed that greater left cerebel- lar volumes may be associated with the absence of a clinical diagnosis in adult relatives of patients with bipolar disorder, suggesting preserved cere- bellar volume may represent a protective factor in individuals at risk for bipolar illness. White matter findings The observation that greater numbers of white matter hyperintensities (WMH) are present in older bipolar disorder patients dates back almost two decades (132). The earliest MRI studies in youth with bipolar disorder specifically explored white matter pathology, with recently replicated reports of WMH in a case study and small sample of youth with bipolar disorder (68, 133–135). Some more recent studies report finding similarly high rates of WMH in family members of bipolar disorder patients (136). However, this finding has not been replicated; another study failed to identify any differences in the number of WMH among healthy relatives of bipolar probands, relatives of bipolar probands who met criteria for an Axis I mood disorder, or healthy subjects, but also failed to replicate earlier findings of increased WMH in bipolar disorder patients (137). Studies involving twins discordant for bipolar disorder report volumetric abnormalities in the white matter of unaffected siblings of bipolar disorder patients, including decreased left hemi- spheric white matter volume, suggesting that reduced white matter connectivity may represent an endophenotype for bipolar illness (71, 116). In youth with bipolar disorder, several studies have focused on the corpus callosum structure, and have detected several abnormalities, including decreased volume overall (138), decreased signal intensity (139), and lower measures of splenium circularity (140). Abnormal correlations were observed between age and both signal intensity (139) and volume (138). These findings may be due to alterations in myelination, which is occur- ring during this developmental period, abnormal tract development, or a combination of these and other factors. Age also appears to affect the shape of the corpus callosum in adult patients with bipolar disorder, as does duration of bipolar illness (141). Newer studies have utilized a range of MRI techniques to expand on previous findings of progressive white matter changes in patients with bipolar disorder. Using diffusion tensor imaging (DTI), several investigators found decreased frac- tional anisotropy (FA) in the corpus callosum, prefrontal regions, the cingulate-paracingulate white matter, fornix, and superior longitudinal fasciculus (79, 142–146) in youth with bipolar diorder. These tracts are known to provide con- nections between regions involved in emotional regulation, and white matter changes in these regions may have functional correlates (79, 143). Schneider et al. 364 Some cross-sectional findings suggest that alter- ations in white matter tracts may represent aber- rant developmental patterns associated with bipolar disorder. In a cross-sectional DTI study of at-risk youth, Versace and colleagues (147) reported a linear increase with age in FA in healthy subjects in the left corpus callosum and the right inferior longitudinal fasciculus. In contrast, high-risk offspring showed a linear decrease in FA with age in the left corpus callosum and no relationship in the right inferior longitudinal fas- ciculus, suggesting that abnormalities in these white matter tracts may represent endophenotypic markers of risk. In another study involving both high-risk youth (with one affected first-degree relative) and youth with bipolar disorder, only the latter exhibited reduced FA relative to healthy subjects in the cingulate-paracingulate white mat- ter, while both the bipolar and high-risk groups exhibited decreased FA in the bilateral superior longitudinal fasciculus I, although the high-risk subjects exhibited greater FA values even than those with bipolar disorder (142). Another study of first-episode manic patients detected significant alterations early in the illness course (146). Together these findings suggest that some white matter abnormalities may represent risk factors while others represent early disease markers. It is possible that abnormal connectivity between re- gions contributes to developmental alterations of key neural structures in bipolar disorder. Longi- tudinal studies assessing the correlation between white matter development and other structural volumetric alterations areneeded to evaluate this possibility. DTI studies in adults have also noted age- and illness-related decreases in FA, suggestive of white matter changes in networks linking prefrontal, medial temporal, and subcortical structures (148, 149). Furthermore, white matter volume has been observed to increase over time in portions of the posterior frontal ⁄parietal cortex, temporo-parietal junction, and portions of the parietal lobe and cerebellum (150). These findings are balanced, however, by the larger number of studies that failed to observe any effect of age, age of onset, illness duration, or number of affective episodes on total white matter volume or FA—even in regions previously implicated in the pathophysiology of bipolar disorder, including the corpus callosum, uncinate fasciculus, and anterior thalamic radia- tions (43, 44, 47, 151, 152). Overall, the evidence supports the conclusion that white matter altera- tions may be more stable than other structural abnormalities, and that they may represent risk and early disease markers. Functional findings Bipolar disorder has been associated with a large number of behavioral and cognitive abnormalities across the disease spectrum, and numerous func- tional MRI (fMRI) studies have attempted to correlate these behavioral findings with abnormal brain activation patterns. These studies have found functional alterations associated with bipolar dis- order across widely distributed brain regions, including frontal and limbic systems thought to be involved in emotion expression and regulation. However, to date, relatively little research has explored the developmental or progressive nature of these findings, and few longitudinal fMRI studies have been performed in patients with bipolar disorder or those at risk for the illness. Functional neuroimaging studies of individuals at risk for bipolar disorder have been generally consistent with findings of structural abnormalities (153–160). An fMRI study comparing remitted bipolar I disorder patients, their unaffected first- degree relatives, and healthy subjects during an N-back working memory task reported that there was significantly greater activation in left frontal polar ⁄VLPFC in unaffected relatives compared with controls during the 2-back task (160). Another study examining brain activation during a 2-back working memory task in adults (ages 32– 46 years) with bipolar disorder, first-degree rela- tives of adults with bipolar disorder, and healthy adults reported abnormal activation in the left anterior insula in both adults with bipolar disorder and their unaffected relatives, as well as alterations in activation in the OFC and superior parietal cortex (156). Similarly, Thermenos and colleagues (155) reported alterations in frontopolar, cerebellar vermal, amygdala ⁄parahippocampal, and insula activation during a 2-back working memory task in a younger sample of unaffected adolescents and young adults with a first-degree relative with bipolar disorder, compared to healthy subjects. In contrast, Whalley and colleagues (153) compared regional brain activation during a parametric sentence completion paradigm in high-risk adole- scents and young adults and found no group differences from healthy subjects for the overall task. However, the high-risk group exhibited increased left amygdala activation during the parametric contrast, compared with healthy sub- jects. A positive association was found across the groups between depression ratings and ventral striatal activation, and a negative association was identified between cyclothymic temperament and ventral prefrontal activation. Similarly, Chang and colleagues (159) explored relationships between Neuroprogression in bipolar disorder 365 mood symptoms and brain activation in an at-risk sample and reported that children with mood dysregulation, but not full bipolar disorder, and a parent with bipolar disorder exhibited decreases in dorsolateral prefrontal activation during an Inter- national Affective Picture System (IAPS) task that was associated with improvement in depressive symptom severity following treatment with divalp- roex. Other functional abnormalities do not appear to manifest until after the onset of symptoms. In an fMRI study examining neural activation during a cognitive flexibility task, both youth with bipolar disorder and their at-risk counterparts exhibited increased right VLPFC and inferior parietal activ- ity on successful change trials, and increased activation in the caudate during failed change trials. In contrast, youth with bipolar disorder also had increased activation in the subgenual ACC compared with the healthy and at-risk groups (154). To our knowledge, only one study to date examined functional connectivity changes in a sample at risk for bipolar disorder (157). In order to identify potential changes associated with risk and resilience, Pompei and colleagues examined functional connectivity during performance of a Stroop task in patients with bipolar disorder, their unaffected first-degree relatives with and without depression, and healthy subjects. Findings from this study suggest that there is a breakdown in VLPFC–subcortical interactions that is associated with risk and illness expression for mood disorders, whereas increased functional coupling between dorsal and ventral prefrontal regions may be related to resilience (157). Together, these findings suggest that functional impairments in at least portions of the extended limbic network might represent endophenotypic changes for bipolar dis- order. Alternatively, these findings might mark early functional abnormalities in the development of bipolar symptoms (153). Numerous functional imaging studies have been performed in young bipolar disorder patients. Collectively, these studies suggest that youth with bipolar disorder display functional abnormalities during performance of cognitive and emotional tasks across multiple cognitive domains, including emotional processing (161–165), working memory (166), inhibitory control (167–170), and reward processing (171, 172). Short-term longitudinal studies have been performed, which suggest that some functional alterations may normalize follow- ing pharmacological treatment (173, 174) while others, including amygdala over-activation, may persist (175). However, there have been no pub- lished longitudinal studies assessing the develop- ment or long-term progression of these functional abnormalities. Similarly, there have been relatively few func- tional neuroimaging studies examining the effects of illness exposure in adult patients with bipolar disorder. In these studies, patients are typically scanned during disparate affective episodes, raising issues with disentangling longitudinal effects from changes in mood state. A study of 10 depressed bipolar I disorder patients who were scanned an average of 11 months later in a euthymic state found no differences in activation during perfor- mance of a Stroop or dominant-hand motor task. Patients did, however, show increased activation in the right medial frontal gyrus (BA 9 ⁄10) and ACC (BA 24 ⁄32) on a non-dominant-hand motor task during the second scan (176). Another study of nine bipolar I disorder patients initially scanned during a facial affect task while manic and again when euthymic an average of six months later, showed a significant group · time interaction (with a group of healthy controls) in the amygdala; activity was greater in the second scan. An effect of time was also observed in the hippocampus; activation was increased in the second scan (177). In a single study of eight euthymic bipolar I disorder patients, however, a frontal region differentially activated in patients versus healthy subjects during a lan- guage task did not show any association with either patient age or duration of illness (178). Overall, while there is very little direct evidence for developmental or progressive alterations in functional brain activation, very few studies have addressedthis question. This area is ripe for further research, and as it is the cognitive and behavioral symptoms of bipolar disorder that most directly relate to the disease burden experienced by patients, further research to assess the develop- mental underpinnings and progressive nature of functional abnormalities associated with the disor- der is urgently needed. Conclusions Over the last few decades, a significant body of imaging research has demonstrated the presence of neurostructural and functional abnormalities in patients with bipolar disorder across a spectrum of ages. Only recently, however, have studies begun to reveal aspects of the neuroprogressive nature of the illness. Structural, and to a lesser extent functional, changes have been identified, but the nature of those changes alters as the illness progresses and as patients age. Further, at least some of these abnormalities appear to predate the initial appear- ance of overt bipolar symptomatology. Schneider et al. 366 A range of studies involving unaffected relatives and twins discordant for bipolar disorder have suggested the presence of structural abnormalities that may represent bipolar endophenotypes and ⁄or resilience factors. Many of the affected regions correspond to structures involved in emotional expression and regulation that have been previ- ously implicated in bipolar disorder, including portions of the prefrontal cortex, ACC, basal ganglia, and thalamus. Some of these structural abnormalities may represent risk factors for devel- opment of mood symptoms, while others may be epiphenomena, and at least some of these findings may represent resiliency factors linked to the absence of symptoms in these populations. In contrast, the majority of studies involving partic- ularly high-risk youth have not found the struc- tural abnormalities seen in affected cohorts. Some of this discrepancy may be related to the significant subject heterogeneity among groups. It is possible, however, that the lack of findings in this group might be related to their relative youth; structural changes may still evolve over time. Unaffected relatives of patients with bipolar disorder have also been shown to display abnormal patterns of neurofunctional activation in many of these same regions: the prefrontal cortex and amyg- dala, as well as networked regions including the cerebellar vermis. In contrast to much of the neurostructural data, abnormalities in prefrontal, medial temporal, and subcortical activation appear to extend to high-risk youth. At least one study suggests that a breakdown in VLPFC–subcortical networking is associated with risk of developing frankmood symptoms (157), potentially implicating white matter abnormalities as well. Evidence of white matter pathology is widely present in the relatives of bipolar disorder patients, including their high-risk offspring; in some cases the abnormality was greater even than that observed in probands. The observation of structural findings in chil- dren and adolescents lends credibility to sugges- tions that bipolar symptomatology involves neurodevelopmental abnormalities that may appear quite early. Bipolar mania often presents during the developmental period in which both regressive (synaptic pruning) and progressive (i.e., myelina- tion) cellular events are prominent. The period between childhood and early adolescence (7–12 years) is associated with rapid expansion of cortical gray matter density, while the period between adolescence (13–18 years) and young adulthood (‡ 18 years) is associated with progres- sive loss of cortical gray matter density that stabilizes only in the third decade of life (179– 181). These age-related changes in cortical volumes are sexually dimorphic, peaking later in men than women (182); are governed by both genetic and environmental factors (183, 184); and are dysreg- ulated in a variety of neurodevelopmental disor- ders (185). Human postmortem and non-human primate histological studies suggest that decreases in cortical gray matter during adolescence are primarily attributable to reductions in synaptic density (i.e., synaptic pruning) (186–189). Frontal gray matter density loss is associated with recipro- cal increases in white matter density in fiber tracts including frontotemporal pathways (190, 191), the expansion of which is positively correlated with cognitive development (i.e., performance on work- ing memory tasks) (192). These normative data therefore suggest that the onset of bipolar disorder often occurs during a developmental period asso- ciated with dynamic changes in cortical maturation and connectivity, and that perturbations in these processes may contribute to illness risk. Studies in children and adolescents with bipolar disorder further suggest that these neurodevelop- mental abnormalities are not indiscriminate, but rather, that they are confined to regions associated with emotional expression and regulation. Young patients demonstrated few global gray matter abnormalities, but showed evidence of a possibly accelerated volume loss in the prefrontal cortex that is consistent with pathologic synaptic prun- ing—particularly in late adolescents and young adults with bipolar disorder (54). Studies correlat- ing amygdala size with patient age were mixed, but patients with a longer duration of illness also appeared to have smaller amygdala volumes (62). Further, at least one longitudinal study found that amygdala volume failed to increase normally over time (108). These changes may have functional significance; amygdala activation during exposure to emotional stimuli inversely correlated with size (106). In contrast to these prefrontal and medial temporal findings, there is relatively little evidence for symptom-related changes in subcortical struc- tures, including the basal ganglia and thalamus. One exception to these findings occurs with the nucleus accumbens, which might be affected spe- cifically in very early-onset bipolar disorder (61). A few studies in youth with bipolar disorder also identified abnormal correlations between age and both signal intensity and volume in some white matter tracts, including the corpus callosum (138, 139). These findings may be due to alterations in myelination, a process which occurs during this period, abnormal white matter development, or a combination of these and other factors. Other white matter abnormalities, however, reflected in changes in measures of DTI in the frontal white Neuroprogression in bipolar disorder 367 matter tracts, appear to be present quite early in the course of illness (146). Interpreting the largely structural findings in children and adolescents with bipolar disorder is complicated by the non-linear nature of develop- mental trajectories. Some prefrontal studies in a more mixed-age population, for instance, suggest that prefrontal volume increases in some patients, supporting previous suggestions that prefrontal volume follows an inverted U-shaped pattern (37). Older adult bipolar disorder patients appear to show a different pattern of symptom-related neu- rostructural and functional changes, most likely involving a different set of neurobiological pro- cesses that may be implicated in the progressive clinical and cognitive effects observed in these patients. Several studies identified evidence of more widespread neuronal atrophy reflected in some measures of cerebral volume and ventricular enlargement (47, 48, 127, 193, 194). Prefrontal findings also appear more consistently in both late- adolescent and adult populations. The neurophys- iology underlying these findings, however, appears to differ, and the hypothesized atrophic changes have been linked with the emergence and increas- ing frequency of affective episodes. Symptom exposure also appears to be associated with smaller amygdala volumes in adults with bipolar disorder (97, 102). While the data are not entirely consistent, conflicting studies generally included at least some younger bipolar disorder patientswho may have obscured the overall finding. The larger amygdala volumes generally observed in younger adult bipolar disorder patients, coupled with the decreases in volumes seen in older patients, suggest another non-linear trajectory, with early volume increases followed by later atrophic changes. Increased functional acti- vation observed in one study over roughly six months in medial temporal structures may be related to these anatomical changes, but may also reflect changes in mood state (177). As with younger patients, adults with bipolar disorder did not generally demonstrate subcortical changes over time. Two studies, however, did suggest that at least portions of the basal ganglia may increase with illness duration in a way not observed in children and adolescents (95, 122), although this finding may be related to medication exposure. Other regions also appear to undergo neuropatho- logic changes in bipolar disorder adults, including portions of the cerebellum (127–129). While not entirely consistent, several studies suggest that illness-related effects on white matter tracts are more extensive in older bipolar disorder patients, comparedwith youthwith bipolar disorder (141, 146, 149). These findings are concordant with suggestions that bipolar symptomatology is linked to the appearance of network abnormalities. In addition to effects on the corpus callosum, adults with bipolar disorder show evidence of age- and illness-related changes in networks linking prefrontal, medial temporal, and subcortical struc- tures, as well as some posterior brain regions also associated with bipolar symptomatology (146, 149). While these findings are potentially quite pro- vocative, there are several issues with much of the data that must be addressed to better understand these processes. Patients are often tested in varying mood states and may be taking a variety of medications over the course of their illness or between scans of longitudinal studies. This latter issue may be particularly relevant given the emerging evidence that mood-stabilizer medica- tions have neuroprotective and neurotrophic effects, and the observation that lithium treatment may be associated with increased cortical volumes in adults. In addition, some data suggest that clinical subsets of bipolar disorder patients may differ substantially in their longer-term response to bipolar symptomatology. Other findings suggest that often ignored variations in sex, as well as other factors including stressful life events and nutri- tional deficiencies, may be important. Most prom- inently, the majority of studies examining the effect of illness progression on neurophysiology in bipo- lar disorder are cross-sectional, and while a few use track-back techniques, these generally rely heavily on patient recollection, the recollection of family members, and often scant medical records that may have limited validity. The potential biases introduced by retrospective recall are illustrated by the frequent discrepancies between data from retrospective studies and the limited prospective data. Nonetheless, these studies suggest a pattern of abnormalities in neural development early in the appearance of bipolar disorder that gives way to progressive neuropathic changes at least influenced by the course of illness leading to an iterative process in which structural and functional changes drive clinical symptomatology and are in turn exacerbated by the consequences of these symp- toms. A better understanding of this process is essential to create targeted treatments that may intervene early in the disease process, and prevent clinical deterioration later in the course of illness. Acknowledgements This work was supported by National Institute of Health (NIH) grants R01MH078043, R01MH078043S1, P50MH077138, R01MH080973, R34MH083924, and R01MH07193. Schneider et al. 368 Disclosures MPB has received research support from AstraZeneca, Bristol- Myers Squibb, Eli Lilly & Co., Forrest, Amylin, Glaxo- SmithKline, Pfizer, Janssen, Merck, Novartis, and Johnson & Johnson; and has served on the speakers bureau or as a consultant for Bristol-Myers Squibb, Pfizer, and Merck. RKM has received research support from Martek Biosciences Inc., Inflammation Research Foundation, Ortho-McNeil Janssen, AstraZeneca, Eli Lilly & Co., NARSAD, NIMH, and NIA; and is a consultant for the Inflammation Research Foundation. In the past year, SMS received research support from Eli Lilly & Co., Janssen, Johnson & Johnson, AstraZeneca, Sumatomo, Pfizer, NIDA, NIAAA, and NIMH; he also received fees for directed discussions on WebMD. CMA has received research support from AstraZeneca, Eli Lilly & Co., Pfizer, Otzuka, Forrest, Sunovion, Novartis, GlaxoSmithKline, and Amylin; and has served as a consultant and on the speakers bureau for Merck. 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