Molecular imaging of bipolar illness

doi:10.1017/CBO9780511782091.009

8 - Molecular imaging of bipolar illness

from Section II - Mood Disorders

Published online by Cambridge University Press: 10 January 2011

John O. Brooks III ,

Po W. Wang and

Terence A. Ketter

Edited by

Martha E. Shenton and

Bruce I. Turetsky

Show author details

John O. Brooks III: Affiliation:
Department of Psychiatry David Geffen School of Medicine University of California, Los Angeles Los Angeles, CA, USA
Po W. Wang: Affiliation:
Department of Psychiatry Mount Sinai School of Medicine New York, NY, USA and Medical Department Brookhaven National Laboratory Upton, NY, USA
Terence A. Ketter: Affiliation:
Department of Psychiatry and Behavioral Sciences Stanford University School of Medicine Stanford, CA, USA
Martha E. Shenton: Affiliation:
VA Boston Healthcare System and Brigham and Women's Hospital, Harvard Medical School
Bruce I. Turetsky: Affiliation:
University of Pennsylvania

Book contents

Get access

Summary

Introduction

Investigation of the pathophysiology of psychiatric disorders includes molecular, cellular, and behavioral studies that go from “bench to bedside” and back again, with basic, translational, and clinical studies informing one another (chapter 14 in Goodwin and Jamison,2007). For example, the serendipitous discovery of the clinical utility of medications that affect monoaminergic neurotransmission in mood, anxiety, and psychotic disorders led to extensive studies of the roles of monoamines in the pathophysiology of these conditions.

Bipolar disorders are a heterogeneous group of conditions characterized by diverse mood, anxiety, and psychotic symptoms, so it is understandable that their pathophysiology is complex. Consequently, neurochemical studies have included assessments of both intercellular signaling (i.e. neurotransmitters such as monoamines, acetylcholine, and amino acids) and intracellular signaling (e.g. signal transduction and amplification, mitochondrial function, and control of genetic expression). Intercellular (neuronal surface receptor) effects, such as the serotonergic and noradrenergic actions of antidepressants, the antidopaminergic actions of antipsychotics, and the pro-gamma-aminobutyric acid (GABAergic) and antiglutamatergic actions of anticonvulsants, as well as the intracellular actions of the mood stabilizers lithium and valproate, are relevant to the underlying neurochemistry of bipolar disorder (Table 8.1).

Neuroimaging studies of bipolar disorder have assessed the neuroanatomy, and increasingly the neurochemical anatomy of this illness. For example, functional neuroimaging studies of bipolar disorder have provided evidence of neuroanatomical and biochemically non-specific functional corticolimbic dysregulation in euthymic (Brooks et al.,2009a), manic (Brooks et al., 2010), and depressed phases (Ketter et al., 2001; Brooks et al., 2009b) of bipolar disorder.

Keywords

anterior cingulate circuit bipolar disorder corticolimbic dysregulation single photon emission computed tomography positron emission tomography neuroimaging dorsolateral prefrontal circuit lateral orbitofrontal circuit

Type: Chapter
Information: Understanding Neuropsychiatric Disorders
Insights from Neuroimaging
, pp. 125 - 138

DOI: https://doi.org/10.1017/CBO9780511782091.009 [Opens in a new window]

Publisher: Cambridge University Press

Print publication year: 2010

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

Adler, C M, DelBello, M P and Strakowski, S M. 2006. Brain network dysfunction in bipolar disorder. CNS Spectr 11, 312–20.Google Scholar

Agam, G, Shamir, A, Shaltiel, G and Greenberg, M L. 2002. Myo-inositol-1-phosphate (MIP) synthase: A possible new target for antibipolar drugs. Bipolar Disord 4 Suppl 1, 15–20.Google Scholar

Alexander, G E, Crutcher, M D and DeLong, M R. 1990. Basal ganglia–thalamocortical circuits: Parallel substrates for motor, oculomotor, “prefrontal” and “limbic” functions. Prog Brain Res 85, 119–46.Google Scholar

Amaral, J A, Tamada, R S, Issler, C K, et al. 2006. A 1HMRS study of the anterior cingulate gyrus in euthymic bipolar patients. Hum Psychopharmacol 21, 215–20.Google Scholar

Amsterdam, J D and Newberg, A B. 2007. A preliminary study of dopamine transporter binding in bipolar and unipolar depressed patients and healthy controls. Neuropsychobiology 55, 167–70.Google Scholar

Benes, F M, Todtenkopf, M S, Logiotatos, P and Williams, M. 2000. Glutamate decarboxylase(65)-immunoreactive terminals in cingulate and prefrontal cortices of schizophrenic and bipolar brain. J Chem Neuroanat 20, 259–69.Google Scholar

Bertolino, A, Frye, M, Callicott, J H, et al. 2003. Neuronal pathology in the hippocampal area of patients with bipolar disorder: A study with proton magnetic resonance spectroscopic imaging. Biol Psychiatry 53, 906–13.Google Scholar

Blasi, G, Bertolino, A, Brudaglio, F, et al. 2004. Hippocampal neurochemical pathology in patients at first episode of affective psychosis: A proton magnetic resonance spectroscopic imaging study. Psychiatry Res 131, 95–105.Google Scholar

Brambilla, P, Stanley, J A, Nicoletti, M A, et al. 2005. 1H magnetic resonance spectroscopy investigation of the dorsolateral prefrontal cortex in bipolar disorder patients. J Affect Disord 86, 61–7.Google Scholar

Brambilla, P, Stanley, J A, Sassi, R B, et al. 2004. 1H MRS study of dorsolateral prefrontal cortex in healthy individuals before and after lithium administration. Neuropsychopharmacology 29, 1918–24.Google Scholar

Brooks, J O, Hoblyn, J C and Ketter, T A. 2010. Metabolic evidence of corticolimbic dysregulation in bipolar mania. Psychiatry Res 181, 136–40.

Brooks, J O, Hoblyn, J C, Woodard, S A, Rosen, A C and Ketter, T A. 2009a. Corticolimbic metabolic dysregulation in euthymic older adults with bipolar disorder. J Psychiatr Res 94, 32–7.Google Scholar

Brooks, J O, Wang, P W, Bonner, J C, et al. 2009b. Decreased prefrontal, anterior cingulate, insula, and ventral striatal metabolism in medication-free depressed outpatients with bipolar disorder. J Psychiatr Res 43, 181–8.Google Scholar

Cannon, D M, Ichise, M, Fromm, S J, et al. 2006. Serotonin transporter binding in bipolar disorder assessed using [11C]DASB and positron emission tomography. Biol Psychiatry 60, 207–17.Google Scholar

Castillo, M, Kwock, L, Courvoisie, H and Hooper, S R. 2000. Proton MR spectroscopy in children with bipolar affective disorder: Preliminary observations. Am J Neuroradiol 21, 832–8.Google Scholar

Cecil, K M, DelBello, M P, Morey, R and Strakowski, S M. 2002. Frontal lobe differences in bipolar disorder as determined by proton MR spectroscopy. Bipolar Disord 4, 357–65.Google Scholar

Cecil, K M, DelBello, M P, Sellars, M C and Strakowski, S M. 2003. Proton magnetic resonance spectroscopy of the frontal lobe and cerebellar vermis in children with a mood disorder and a familial risk for bipolar disorders. J Child Adolesc Psychopharmacol 13, 545–55.Google Scholar

Chang, K, Adleman, N, Dienes, K, Barnea-Goraly, N, Reiss, A and Ketter, T. 2003. Decreased N-acetylaspartate in children with familial bipolar disorder. Biol Psychiatry 53, 1059–65.Google Scholar

Dager, S R, Friedman, S D, Parow, A, et al. 2004. Brain metabolic alterations in medication-free patients with bipolar disorder. Arch Gen Psychiatry 61, 450–8.Google Scholar

Davanzo, P, Thomas, M A, Yue, K, et al. 2001. Decreased anterior cingulate myo-inositol/creatine spectroscopy resonance with lithium treatment in children with bipolar disorder. Neuropsychopharmacology 24, 359–69.Google Scholar

Dean, B, Pavey, G, McLeod, M, Opeskin, K, Keks, N and Copolov, D. 2001. A change in the density of [(3)H]flumazenil, but not [(3)H]muscimol binding, in Brodmann's Area 9 from subjects with bipolar disorder. J Affect Disord 66, 147–58.Google Scholar

Dechent, P, Pouwels, P J, Wilken, B, Hanefeld, F and Frahm, J. 1999. Increase of total creatine in human brain after oral supplementation of creatine-monohydrate. Am J Physiol 277, R698–704.Google Scholar

Deicken, R F, Eliaz, Y, Feiwell, R and Schuff, N. 2001. Increased thalamic N-acetylaspartate in male patients with familial bipolar I disorder. Psychiatry Res 106, 35–45.Google Scholar

Deicken, R F, Fein, G and Weiner, M W. 1995a. Abnormal frontal lobe phosphorus metabolism in bipolar disorder. Am J Psychiatry 152, 915–8.Google Scholar

Deicken, R F, Pegues, M P, Anzalone, S, Feiwell, R and Soher, B. 2003. Lower concentration of hippocampal N-acetylaspartate in familial bipolar I disorder. Am J Psychiatry 160, 873–82.Google Scholar

Deicken, R F, Weiner, M W and Fein, G. 1995b. Decreased temporal lobe phosphomonoesters in bipolar disorder. J Affect Disord 33, 195–9.Google Scholar

Drevets, W C, Frank, E, Price, J C, et al. 1999. PET imaging of serotonin 1A receptor binding in depression. Biol Psychiatry 46, 1375–87.Google Scholar

Drevets, W C, Price, J L, Simpson, J R, et al. 1997. Subgenual prefrontal cortex abnormalities in mood disorders. Nature 386, 824–7.Google Scholar

Ebert, D, Feistel, H, Kaschka, W, Barocka, A and Pirner, A. 1994. Single photon emission computerized tomography assessment of cerebral dopamine D2 receptor blockade in depression before and after sleep deprivation – Preliminary results. Biol Psychiatry 35, 880–5.Google Scholar

Frey, B N, Andreazza, A C, Nery, F G, et al. 2007a. The role of hippocampus in the pathophysiology of bipolar disorder. Behav Pharmacol 18, 419–30.Google Scholar

Frey, B N, Stanley, J A, Nery, F G, et al. 2007b. Abnormal cellular energy and phospholipid metabolism in the left dorsolateral prefrontal cortex of medication-free individuals with bipolar disorder: An in vivo 1H MRS study. Bipolar Disord 9 Suppl 1, 119–27.Google Scholar

Friedman, S D, Dager, S R, Parow, A, et al. 2004. Lithium and valproic acid treatment effects on brain chemistry in bipolar disorder. Biol Psychiatry 56, 340–8.Google Scholar

Frye, M A, Thomas, M A, Yue, K, et al. 2007a. Reduced concentrations of N-acetylaspartate (NAA) and the NAA–creatine ratio in the basal ganglia in bipolar disorder: A study using 3-Tesla proton magnetic resonance spectroscopy. Psychiatry Res 154, 259–65.Google Scholar

Frye, M A, Watzl, J, Banakar, S, et al. 2007b. Increased anterior cingulate/medial prefrontal cortical glutamate and creatine in bipolar depression. Neuropsychopharmacology 32, 2490–9.Google Scholar

Goodwin, F K and Jamison, K R. 2007. Manic-Depressive Illness (2nd ed.). New York, NY: Oxford University Press.

Gyulai, L, Bolinger, L, Leigh, J S, Barlow, C and Chance, B. 1984. Phosphorylethanolamine – The major constituent of the phosphomonoester peak observed by 31P-NMR on developing dog brain. FEBS Lett 178, 137–42.Google Scholar

Hajek, T, Bernier, D, Slaney, C, et al. 2008. A comparison of affected and unaffected relatives of patients with bipolar disorder using proton magnetic resonance spectroscopy. J Psychiatry Neurosci 33, 531–40.Google Scholar

Hallcher, L M and Sherman, W R. 1980. The effects of lithium ion and other agents on the activity of myo-inositol-1-phosphatase from bovine brain. J Biol Chem 255, 10 896–901.Google Scholar

Hamakawa, H, Kato, T, Murashita, J and Kato, N. 1998. Quantitative proton magnetic resonance spectroscopy of the basal ganglia in patients with affective disorders. Eur Arch Psychiatry Clin Neurosci 248, 53–8.Google Scholar

Hamakawa, H, Kato, T, Shioiri, T, Inubushi, T and Kato, N. 1999. Quantitative proton magnetic resonance spectroscopy of the bilateral frontal lobes in patients with bipolar disorder. Psychol Med 29, 639–44.Google Scholar

Kato, T, Hamakawa, H, Shioiri, T, et al. 1996. Choline-containing compounds detected by proton magnetic resonance spectroscopy in the basal ganglia in bipolar disorder. J Psychiatry Neurosci 21, 248–54.Google Scholar

Kato, T, Murashita, J, Kamiya, A, Shioiri, T, Kato, N and Inubushi, T. 1998. Decreased brain intracellular pH measured by 31P-MRS in bipolar disorder: A confirmation in drug-free patients and correlation with white matter hyperintensity. Eur Arch Psychiatry Clin Neurosci 248, 301–6.Google Scholar

Kato, T, Shioiri, T, Murashita, J, Hamakawa, H, Inubushi, T and Takahashi, S. 1994a. Phosphorus-31 magnetic resonance spectroscopy and ventricular enlargement in bipolar disorder. Psychiatry Res 55, 41–50.Google Scholar

Kato, T, Shioiri, T, Murashita, J, et al. 1995. Lateralized abnormality of high energy phosphate metabolism in the frontal lobes of patients with bipolar disorder detected by phase-encoded 31P-MRS. Psychol Med 25, 557–66.Google Scholar

Kato, T, Shioiri, T, Takahashi, S and Inubushi, T. 1991. Measurement of brain phosphoinositide metabolism in bipolar patients using in vivo 31P-MRS. J Affect Disord 22, 185–90.Google Scholar

Kato, T, Takahashi, S and Inubushi, T. 1992. Brain lithium concentration by 7Li- and 1H-magnetic resonance spectroscopy in bipolar disorder. Psychiatry Res 45, 53–63.Google Scholar

Kato, T, Takahashi, S, Shioiri, T and Inubushi, T. 1993. Alterations in brain phosphorus metabolism in bipolar disorder detected by in vivo 31P and 7Li magnetic resonance spectroscopy. J Affect Disord 27, 53–9.Google Scholar

Kato, T, Takahashi, S, Shioiri, T, Murashita, J, Hamakawa, H and Inubushi, T. 1994b. Reduction of brain phosphocreatine in bipolar II disorder detected by phosphorus-31 magnetic resonance spectroscopy. J Affect Disord 31, 125–33.Google Scholar

Ketter, T A, Kimbrell, T A, George, M S, et al. 2001. Effects of mood and subtype on cerebral glucose metabolism in treatment-resistant bipolar disorder. Biol Psychiatry 49, 97–109.Google Scholar

Ketter, T A and Wang, P W. 2003. The emerging differential roles of GABAergic and antiglutamatergic agents in bipolar disorders. J Clin Psychiatry 64 Suppl 3, 15–20.Google Scholar

Malhi, G S, Ivanovski, B, Wen, W, Lagopoulos, J, Moss, K and Sachdev, P. 2007. Measuring mania metabolites: A longitudinal proton spectroscopy study of hypomania. Acta Psychiatr Scand 434(Suppl), 57–66.Google Scholar

Manji, H K and Lenox, R H. 2000. Signaling: Cellular insights into the pathophysiology of bipolar disorder. Biol Psychiatry 48, 518–30.Google Scholar

Marazziti, D, Lenzi, A, Raffaelli, S, Falcone, M F, Aglietti, M and Cassano, G B. 1993. A single electroconvulsive treatment affects platelet serotonin uptake in bipolar I patients. Eur Neuropsychopharmacol 3, 33–6.Google Scholar

Mayberg, H S. 1997. Limbic–cortical dysregulation: A proposed model of depression. J Neuropsychiatry Clin Neurosci 9, 471–81.Google Scholar

Mega, M S and Cummings, J L. 1994. Frontal–subcortical circuits and neuropsychiatric disorders. J Neuropsychiatry Clin Neurosci 6, 358–70.Google Scholar

Meyer, J H, Kapur, S, Houle, S, et al. 1999. Prefrontal cortex 5-HT2 receptors in depression: An [18F]setoperone PET imaging study. Am J Psychiatry 156, 1029–34.Google Scholar

Michael, N, Erfurth, A, Ohrmann, P, et al. 2003. Acute mania is accompanied by elevated glutamate/glutamine levels within the left dorsolateral prefrontal cortex. Psychopharmacology (Berl) 168, 344–6.Google Scholar

Molina, V, Sánchez, J, Sanz, J, et al. 2007. Dorsolateral prefrontal N-acetyl-aspartate concentration in male patients with chronic schizophrenia and with chronic bipolar disorder. Eur Psychiatry 22, 505–12.Google Scholar

Moore, C M, Breeze, J L, Gruber, S A, et al. 2000a. Choline, myo-inositol and mood in bipolar disorder: A proton magnetic resonance spectroscopic imaging study of the anterior cingulate cortex. Bipolar Disord 2, 207–16.Google Scholar

Moore, G J, Bebchuk, J M, Hasanat, K, et al. 2000b. Lithium increases N-acetyl-aspartate in the human brain: In vivo evidence in support of bcl-2's neurotrophic effects? Biol Psychiatry 48, 1–8.Google Scholar

Moore, G J, Bebchuk, J M, Parrish, J K, et al. 1999. Temporal dissociation between lithium-induced changes in frontal lobe myo-inositol and clinical response in manic-depressive illness. Am J Psychiatry 156, 1902–08.Google Scholar

Ng, W X, Lau, I Y, Graham, S and Sim, K. 2009. Neurobiological evidence for thalamic, hippocampal and related glutamatergic abnormalities in bipolar disorder: A review and synthesis. Neurosci Biobehav Rev 33, 336–54.Google Scholar

Nudmamud, S, Reynolds, L M and Reynolds, G P. 2003. N-acetylaspartate and N-acetylaspartylglutamate deficits in superior temporal cortex in schizophrenia and bipolar disorder: A postmortem study. Biol Psychiatry 53, 1138–41.Google Scholar

Ohara, K, Isoda, H, Suzuki, Y, et al. 1998. Proton magnetic resonance spectroscopy of the lenticular nuclei in bipolar I affective disorder. Psychiatry Res 84, 55–60.Google Scholar

Olvera, R L, Caetano, S C, Fonseca, M, et al. 2007. Low levels of N-acetyl aspartate in the left dorsolateral prefrontal cortex of pediatric bipolar patients. J Child Adolesc Psychopharmacol 17, 461–73.Google Scholar

Ongür, D, Jensen, J E, Prescot, A P, et al. 2008. Abnormal glutamatergic neurotransmission and neuronal–glial interactions in acute mania. Biol Psychiatry 64, 718–26.Google Scholar

Oquendo, M A, Bongiovi-Garcia, M E, Galfalvy, H, et al. 2007. Sex differences in clinical predictors of suicidal acts after major depression: A prospective study. Am J Psychiatry 164, 134–41.Google Scholar

Pearlson, G D, Wong, D F, Tune, L E, et al. 1995. In vivo D2 dopamine receptor density in psychotic and nonpsychotic patients with bipolar disorder. Arch Gen Psychiatry 52, 471–7.Google Scholar

Port, J D, Unal, S S, Mrazek, D A and Marcus, S M. 2008. Metabolic alterations in medication-free patients with bipolar disorder: A 3T CSF-corrected magnetic resonance spectroscopic imaging study. Psychiatry Res 162, 113–21.Google Scholar

Renshaw, P F, Yurgelun-Todd, D A, Tohen, M, Gruber, S and Cohen, B M. 1995. Temporal lobe proton magnetic resonance spectroscopy of patients with first-episode psychosis. Am J Psychiatry 152, 444–6.Google Scholar

Sassi, R B, Stanley, J A, Axelson, D, et al. 2005. Reduced NAA levels in the dorsolateral prefrontal cortex of young bipolar patients. Am J Psychiatry 162, 2109–15.Google Scholar

Scherk, H, Backens, M, Schneider-Axmann, T, et al. 2007. Cortical neurochemistry in euthymic patients with bipolar I disorder. World J Biol Psychiatry 1–10.Google Scholar

Sharma, R, Venkatasubramanian, P N, Bárány, M and Davis, J M. 1992. Proton magnetic resonance spectroscopy of the brain in schizophrenic and affective patients. Schizophr Res 8, 43–9.Google Scholar

Silverstone, P H, Hanstock, C C, Fabian, J, Staab, R and Allen, P S. 1996. Chronic lithium does not alter human myo-inositol or phosphomonoester concentrations as measured by 1H and 31P MRS. Biol Psychiatry 40, 235–46.Google Scholar

Silverstone, P H, Hanstock, C C and Rotzinger, S. 1999. Lithium does not alter the choline/creatine ratio in the temporal lobe of human volunteers as measured by proton magnetic resonance spectroscopy. J Psychiatry Neurosci 24, 222–6.Google Scholar

Silverstone, P H, Wu, R H, O'Donnell, T, Ulrich, M, Asghar, S J and Hanstock, C C. 2002. Chronic treatment with both lithium and sodium valproate may normalize phosphoinositol cycle activity in bipolar patients. Hum Psychopharmacol 17, 321–7.Google Scholar

Stahl, S M, Woo, D J, Mefford, I N, Berger, P A and Ciaranello, R D. 1983. Hyperserotonemia and platelet serotonin uptake and release in schizophrenia and affective disorders. Am J Psychiatry 140, 26–30.Google Scholar

Strakowski, S M, Delbello, M P and Adler, C M. 2005. The functional neuroanatomy of bipolar disorder: A review of neuroimaging findings. Mol Psychiatry 10, 105–16.Google Scholar

Suhara, T, Nakayama, K, Inoue, O, et al. 1992. D1 dopamine receptor binding in mood disorders measured by positron emission tomography. Psychopharmacology (Berl) 106, 14–8.Google Scholar

Wang, P W, Sailasuta, N, Chandler, R A and Ketter, T A. 2006. Magnetic resonance spectroscopic measurement of cerebral gamma-aminobutyric acid concentrations in patients with bipolar disorders. Acta Neuropsychiatrica 18, 120–6.Google Scholar

Watanabe, A, Kato, N and Kato, T. 2002. Effects of creatine on mental fatigue and cerebral hemoglobin oxygenation. Neurosci Res 42, 279–85.Google Scholar

Winsberg, M E, Sachs, N, Tate, D L, Adalsteinsson, E, Spielman, D and Ketter, T A. 2000. Decreased dorsolateral prefrontal N-acetyl aspartate in bipolar disorder. Biol Psychiatry 47, 475–81.Google Scholar

Wu, R H, O'Donnell, T, Ulrich, M, Asghar, S J, Hanstock, C C and Silverstone, P H. 2004. Brain choline concentrations may not be altered in euthymic bipolar disorder patients chronically treated with either lithium or sodium valproate. Ann Gen Hosp Psychiatry 3, 13.Google Scholar

Yildiz, A, Sachs, G S, Dorer, D J and Renshaw, P F. 2001. 31P Nuclear magnetic resonance spectroscopy findings in bipolar illness: A meta-analysis. Psychiatry Res 106, 181–91.Google Scholar

Young, L T, Warsh, J J, Kish, S J, Shannak, K and Hornykeiwicz, O. 1994. Reduced brain 5-HT and elevated NE turnover and metabolites in bipolar affective disorder. Biol Psychiatry 35, 121–7.Google Scholar

Zubieta, J K, Huguelet, P, Ohl, L E, et al. 2000. High vesicular monoamine transporter binding in asymptomatic bipolar I disorder: Sex differences and cognitive correlates. Am J Psychiatry 157, 1619–28.Google Scholar

Zubieta, J K, Taylor, S F, Huguelet, P, Koeppe, R A, Kilbourn, M R and Frey, K A. 2001. Vesicular monoamine transporter concentrations in bipolar disorder type I, schizophrenia, and healthy subjects. Biol Psychiatry 49, 110–6.Google Scholar

Book contents

8 - Molecular imaging of bipolar illness

Summary

Keywords

Access options

References

Save book to Kindle

Save book to Dropbox

Save book to Google Drive