Evidence for altered cerebellar vermis neuronal integrity in schizophrenia.

To determine if there was evidence for altered neuronal integrity in the cerebellar vermis of patients with schizophrenia, the authors measured N-acetyl-aspartate (NAA, a putative neuronal/axonal marker) using in vivo proton magnetic resonance spectroscopic imaging (1H-MRSI) in 20 chronically medicated male patients with schizophrenia and 15 male comparison subjects. Relative contributions of cerebrospinal fluid, gray matter, and white matter to each MRSI voxel were determined using an MRI tissue segmentation technique. The percentage of tissue was used as a co-variate to determine the extent to which tissue composition contributed to NAA differences. Schizophrenic patients showed significantly decreased NAA and creatine in the anterior cerebellar vermis, independent of differences in voxel tissue composition. Cerebellar NAA levels in control subjects were also significantly correlated with the amount of cerebellar gray matter enclosed in the MRSI voxels, but not in the schizophrenic group. There was no association between cerebellar NAA measures and duration of illness or neuroleptic dose in chlorpromazine equivalents. Reduced NAA in the anterior cerebellar vermis of male patients with schizophrenia supports the hypothesis that cerebellar dysfunction contributes to the pathophysiology of schizophrenia. Furthermore, the lack of a significant correlation between NAA and the amount of cerebellar gray matter in MRSI voxels in the schizophrenic group suggests that NAA levels in both cerebellar gray and white matter are similar in schizophrenic patients, and are presumed to be the result of reduced NAA concentration in the cerebellar gray matter.

Increased thalamic N-acetylaspartate in male patients with familial bipolar I disorder.

N-Acetylaspartate (NAA) in the anterior and mediodorsal thalamic regions was measured using proton magnetic resonance spectroscopic imaging (1H-MRSI) in 15 euthymic male patients with familial bipolar I disorder and compared to values in 15 male control subjects to determine if there was evidence for altered neuronal/axonal integrity. MRI tissue segmentation methods were also utilized to obtain tissue-contribution estimates for each MRSI voxel. Relative to the comparison group, the patients with bipolar I disorder demonstrated significantly higher NAA and creatine in both the right and left thalamus. NAA was also significantly higher in the left thalamus compared to the right in both bipolar I patients and controls. There were no group or lateralized differences in the percentages of different tissue types within the MRSI voxels, suggesting that the thalamic NAA and creatine alterations were not an artifact of variations in tissue type percentages in the MRSI voxels. There was also no significant association between NAA or creatine and illness duration. The findings of increased thalamic NAA bilaterally may represent neuronal hypertrophy or hyperplasia, reduced glial cell density, or abnormal synaptic and dendritic pruning. Increased thalamic creatine bilaterally may represent altered cellular energy metabolism and is consistent with prior studies demonstrating changes in thalamic metabolism in mood disorders.

Proton magnetic resonance spectroscopy of the human brain in schizophrenia.

In vivo proton magnetic resonance spectroscopy (1H MRS) has been utilized by neuroimaging laboratories in recent years to reliably measure compounds such as N-acetylaspartate (NAA), choline (Cho), creatine (Cr), and to a lesser extent glutamate and glutamine in the human brain. To date, the most consistently replicated findings in schizophrenia are reduced NAA measures in the hippocampal regions. Since NAA is thought to be a neuronal/axonal marker and a measure of neuronal/axonal integrity, hippocampal NAA reductions have been interpreted as strong evidence for neuronal/axonal loss or dysfunction in this brain region. The evidence for neuronal loss or dysfunction based on NAA is less consistent for the frontal cortex and white matter, temporal cortex, basal ganglia, cingulate region, and thalamus in schizophrenia. Furthermore, there are no consistently replicated findings for choline or creatine alterations in any of the brain regions examined in schizophrenia. Finally, significant technical difficulties make reliable measurement of glutamine and glutamate problematic at the present time.

Reduced concentrations of thalamic N-acetylaspartate in male patients with schizophrenia.

OBJECTIVE: The authors measured N-acetylaspartate (a putative neuronal marker) in the right and left thalamus of 17 male patients with schizophrenia using in vivo proton magnetic resonance spectroscopic imaging ((1)H MRSI). METHOD: (1)H MRSI was performed on 17 medicated male patients with schizophrenia and 10 male comparison subjects. Concentrations of N-acetylaspartate, creatine, and choline were determined in the thalamic regions bilaterally. RESULTS: The patients with schizophrenia demonstrated significantly lower concentrations of N-acetylaspartate than the comparison subjects in both the right and left thalamic regions. Right thalamic N-acetylaspartate and left thalamic N-acetylaspartate were significantly correlated in the patients but not in the comparison subjects. There was no association between N-acetylaspartate and duration of illness or medication dose. No group differences or lateralized asymmetries in choline or creatine were noted. CONCLUSIONS: The finding of reduced concentrations of N-acetylaspartate bilaterally suggests neuronal dysfunction and/or loss in both the right and left thalamic regions in male patients with schizophrenia.

Reduced hippocampal N-acetylaspartate without volume loss in schizophrenia.

Quantitative magnetic resonance imaging (MRI) can measure total gray matter volume but cannot discriminate between neurons and glia. Proton magnetic resonance spectroscopic imaging (1H MRSI) measures N-acetylaspartate (NAA) which is a selective marker of neuronal loss or neuronal dysfunction. The objective of this study was to obtain quantitative measures of hippocampal volume and hippocampal NAA to determine if there was evidence for hippocampal neuronal dysfunction or neuronal loss in schizophrenia. Quantitative MRI and 1H MRSI was performed on the right and left hippocampal regions in 23 chronic schizophrenic patients and 18 control subjects. Relative to the control group, the patients with schizophrenia demonstrated no change in hippocampal volumes bilaterally, but significantly decreased NAA in the hippocampal regions bilaterally. There was also no correlation between hippocampal volumes and NAA in either the schizophrenics or controls. These findings suggest that: (1) hippocampal NAA may be a more sensitive measure of neuronal loss than volumetric measurements; and (2) reduced hippocampal NAA may be measuring neuronal dysfunction or damage rather than neuronal loss in this sample of schizophrenics.

Hippocampal neuronal dysfunction in schizophrenia as measured by proton magnetic resonance spectroscopy.

BACKGROUND: Previous neuropathological and neuroimaging studies have documented neuronal loss in the hippocampal region in schizophrenia. N-acetylaspartate (NAA) is a neuronal/axonal marker that may be utilized to assess neuronal loss or dysfunction by proton magnetic resonance spectroscopy (1H MRS). This study measured NAA, choline, and creatine in the hippocampal region of patients with schizophrenia using in vivo proton magnetic resonance spectroscopic imaging (1H MRSI). METHODS: 1H MRSI was performed on the right and left hippocampal regions in 30 chronic schizophrenic patients and 18 control subjects. Concentration estimates of NAA, creatine, and choline were determined. RESULTS: Relative to the control group, the patients with schizophrenia demonstrated significantly lower NAA in both the right and left hippocampal regions. No group differences in choline were noted; however, there was a trend for creatine to be higher on the left than the right hippocampus in the schizophrenic group. There was also no association between NAA and duration of illness or medication dosage. CONCLUSIONS: This preliminary study provides support for neuronal dysfunction and/or decreased neuronal density in the hippocampal region. The absence of choline signal elevation does not support accelerated turnover of membrane phospholipids, which might be expected if there were ongoing neuronal atrophy or neuronal necrosis.

Proton magnetic resonance spectroscopy of the anterior cingulate region in schizophrenia.

The authors measured N-acetylaspartate (NAA, a putative neuronal marker), choline and creatine in the anterior cingulate region of 26 schizophrenic patients and 16 control subjects using in vivo proton magnetic resonance spectroscopic imaging (1H MRSI). Relative to the control group, the patients with schizophrenia demonstrated significantly lower NAA in both the right and left anterior cingulate regions. There was no association between NAA and duration of illness or medication dosage. No group differences or lateralized asymmetries in choline or creatine were noted. The NAA findings provide support for either neuronal dysfunction or neuronal loss in the anterior cingulate region in schizophrenia. The absence of choline signal elevation does not support accelerated turnover of membrane phospholipids which might be expected if there were ongoing neuronal atrophy or neuronal necrosis.

Decreased left frontal lobe N-acetylaspartate in schizophrenia.

OBJECTIVE: The authors measured N-acetylaspartate (a putative neuronal marker), using in vivo proton magnetic resonance spectroscopic imaging (1H-MRSI), in the frontal lobes of schizophrenic patients and normal subjects. METHOD: Frontal lobe 1H-MRSI was performed bilaterally on 24 medicated schizophrenic patients and 15 healthy comparison subjects. Levels of N-acetylaspartate, creatine, and choline were determined. RESULTS: Relative to the comparison group, the patients with schizophrenia demonstrated significantly lower levels of N-acetylaspartate in the left frontal lobe. There was no association between level of N-acetylaspartate and duration of illness or medication dosage. No differences between groups or lateralized asymmetries in choline or creatine were noted. CONCLUSIONS: This preliminary study provides support for decreased N-acetylaspartate in the left frontal lobe in schizophrenia and neuronal dysfunction in this brain region.

Asymmetry of temporal lobe phosphorous metabolism in schizophrenia: a 31phosphorous magnetic resonance spectroscopic imaging study.

In vivo 31Phosphorous magnetic resonance spectroscopic imaging (31P MRSI) was performed on 18 chronic schizophrenic patients and 14 normal controls to determine if there was asymmetry of high-energy phosphorous metabolism in the temporal lobes of schizophrenic patients. Temporal lobe phosphorous metabolites were also correlated with severity of psychiatric symptomatology as assessed by the Brief Psychiatric Rating Scale (BPRS). Schizophrenics demonstrated significantly higher right relative to left temporal phosphocreatine/adenosine triphosphate (PCr/ATP), phosphocreatine/inorganic phosphate (PCr/Pi), and PCr as well as significantly lower right relative to left temporal ATP. There were no asymmetries of temporal lobe phosphorous metabolites in the control group. In addition, both left temporal PCr and the degree of asymmetry of temporal lobe PCr were highly correlated with the thinking disturbance subscale of the BPRS. This study provides further support for temporal lobe metabolic asymmetry in schizophrenia and its possible association with clinical symptoms.

Abnormal frontal lobe phosphorous metabolism in bipolar disorder.

OBJECTIVE: Abnormalities in frontal lobe phosphorous metabolism in patients with bipolar disorder have been reported, but many of the patients studied were receiving lithium. In this study, medication-free bipolar patients were examined to determine abnormalities in frontal lobe high-energy phosphorous metabolism. METHOD: In vivo phosphorous-31 magnetic resonance spectroscopic imaging was performed on 12 unmedicated, euthymic bipolar patients and 16 healthy comparison subjects. The percentages of total phosphorous signal for phosphomonoesters, inorganic phosphate, phosphodiesters, phosphocreatine, and beta-ATP were calculated. RESULTS: In relation to the comparison group, the patients with bipolar disorder had significantly lower phosphomonoester values and higher phosphodiester values in both the left and right frontal lobes. The patients also had a significantly higher right-to-left ratio of frontal lobe phosphocreatine. No other differences in phosphorous metabolites or lateralized asymmetries were noted. CONCLUSIONS: This preliminary study provides support for abnormal frontal lobe phosphorous metabolism in bipolar disorder.

Decreased temporal lobe phosphomonoesters in bipolar disorder.

In vivo [31P]magnetic resonance spectroscopic imaging ([31P]MRSI) was performed on 12 unmedicated, euthymic bipolar patients and 14 control subjects to determine if there were alterations in high-energy P metabolism in the temporal lobes of bipolar patients. Compared with the control group, the patients with bipolar disorder demonstrated significantly lower phosphomonoesters (PME) in both the left and right temporal lobes. No other group differences in P metabolites or lateralized asymmetries were noted. This preliminary study provides support for altered temporal lobe phospholipid metabolism in bipolar disorder.

Basal ganglia phosphorous metabolism in chronic schizophrenia.

OBJECTIVE: The authors examined whether there are abnormalities in high-energy phosphorous metabolism in the basal ganglia of schizophrenic patients. METHOD: In vivo 31P magnetic resonance spectroscopic imaging was performed on 18 chronic schizophrenic patients and 16 healthy comparison subjects. The percentages of total phosphorous signal for phosphomonoesters, inorganic phosphate, phosphodiesters, phosphocreatine, and beta-ATP were calculated. RESULTS: The mean percentages of beta-ATP signal in the right and left basal ganglia were significantly lower for the schizophrenic patients than for the comparison group. No other group differences in phosphorous metabolites and no lateral asymmetries in the schizophrenic group were noted. CONCLUSIONS: This preliminary study provides support for abnormal high-energy phosphorous metabolism in the basal ganglia of schizophrenic patients.

Correlation between left frontal phospholipids and Wisconsin Card Sort Test performance in schizophrenia.

The relationship between frontal lobe phospholipid measures as measured by in vivo 31phosphorus magnetic resonance spectroscopic imaging and performance on the Wisconsin Card Sort Test was examined in 16 chronic schizophrenic patients and 13 normal controls. Lower left frontal phosphomonoester levels in the schizophrenics were associated with fewer categories achieved, lower percent conceptual level, and greater total errors. No significant correlations between frontal phospholipid measures and performance on the WCST were noted in the controls. The results suggest a relationship between altered left frontal phospholipid metabolism and a specific measure of frontal lobe neuropsychological functioning.

31phosphorus magnetic resonance spectroscopy of the frontal and parietal lobes in chronic schizophrenia.

In vivo 31Phosphorus magnetic resonance spectroscopic imaging (31P MRSI) was performed on 20 chronic schizophrenic patients and 16 normal controls to determine if there were specific changes in high energy phosphorus and phospholipid metabolism in the frontal lobes of schizophrenic patients. Phosphorous metabolites were assessed in each of the left and right frontal as well as the left and right parietal lobes. Frontal lobe phosphorous metabolites were also correlated with severity of psychiatric symptomatology as assessed by the Brief Psychiatric Rating Scale (BPRS). Schizophrenics demonstrated higher phosphodiesters (PDE) and lower phosphocreatine (PCr) in both the left and right frontal regions compared to controls. There was also lower left frontal inorganic phosphate (Pi) in the schizophrenic group. No group differences were noted in the left or right parietal regions. In addition, right frontal PDE and right frontal PCr were highly correlated with the hostility-suspiciousness and anxiety-depression subscales of the BPRS. This study provides further support for altered frontal lobe phosphorous metabolism in schizophrenia.

Use of computer simulations for quantitation of 31P ISIS MRS results.

The difficulties in quantitation of in vivo 31P spectra are exacerbated by the fact that, in general, coils with inhomogeneous B1 fields are used with in vivo samples. A general method for quantitation of in vivo 31P MRS results obtained with the ISIS localization method was developed using computer simulations. The simulation calculates the preparation of the sample magnetization throughout the sample by the ISIS pulse sequence, as well as the sensitivity of signal reception. The calculation accounts for both the B1 field and the B0 gradients applied to the sample. The sensitivity of the experiment is expressed by integration of the simulated signal over the sample, assuming a homogeneous sample. The primary advantage of this approach is that a separate localization experiment on a phantom of known concentration is not required each time parameters of the localization experiment, such as dimensions or location of the localized volume, are altered. In addition, the simulations indicate the degree of contamination (signal from outside of the localized volume) that occurs, and provide a means of comparing different executions of the ISIS experiment. Experiments were performed on phantoms to verify the simulations, and experimental results on human brain and liver are reproduced to show that this approach provides reasonable estimates of metabolite levels in terms of molar concentrations.

31Phosphorus magnetic resonance spectroscopy of the temporal lobes in schizophrenia.

Eleven schizophrenic patients and nine normal controls were studied using in vivo 31Phosphorous magnetic resonance spectroscopy (31P MRS) to test the hypothesis of metabolic asymmetry in the temporal lobes in schizophrenia. The controls did not demonstrate any asymmetry of phosphorous metabolite ratios, percentage of phosphorous metabolites, or pH. In the schizophrenics, however, phosphocreatine/beta-adenosine triphosphate (PCr/beta-ATP) and phosphocreatine/inorganic phosphate (PCr/Pi) effects appeared to primarily reflect higher ratios on the right side, while the percentage of beta-ATP appeared to primarily reflect higher relative concentrations in the left temporal lobe. Moreover, significant negative correlations were noted between total Brief Psychiatric Rating Scale scores and PCr/beta-ATP in both the right and left temporal lobes. These results support the hypothesis of an asymmetric distribution of 31P metabolites in the temporal lobe of schizophrenic patients, and also show an association between temporal lobe phosphorous metabolism and the severity of psychiatric symptomatology.

Alterations in brain phosphorus metabolite concentrations associated with areas of high signal intensity in white matter at MR imaging.

Areas of high signal intensity in white matter are identified on brain magnetic resonance (MR) imaging studies in 25%-50% of elderly subjects. The authors used phosphorus-31 MR spectroscopy to characterize the metabolic status of hemispheric white matter brain volumes in 30 elderly subjects with white matter areas of high signal intensity at MR imaging. Compared with white matter volumes with no or minimal areas of high intensity, white matter volumes with extensive areas of high intensity evidenced a 26% decrease in the adenosine triphosphate (ATP)/inorganic phosphate (Pi) ratio (P = .03) and a 21% decrease in the ATP concentration (P = .05), with the Pi level unchanged. A pilot P-31 spectroscopic imaging study in a subject with a large, coalescing white matter area of high signal intensity demonstrated large reductions in metabolite concentrations in the high-signal-intensity area. These results suggest that extensive white matter areas of high signal intensity indicate a process that affects white matter cellular energy metabolism.

MRI deep white matter hyperintensity in a psychiatric population.

The authors evaluated magnetic resonance imaging (MRI) of deep white matter hyperintensity (DWMH) in 90 adult psychiatric inpatients in whom MRIs were clinically indicated and 25 age-matched, medically healthy controls. Forty-two percent of the psychiatric patients and 12% of the controls had evidence of DWMH on MRI. Both incidence and severity of DWMH were significantly correlated with age in both groups. Even after controlling for age in the psychiatric population, DWMH was significantly associated with hypertension, history of myocardial infarction or angina, abnormal electrocardiogram, and abnormal neurological examinations.

Alterations in brain phosphate metabolite concentrations in patients with human immunodeficiency virus infection.

Human immunodeficiency virus (HIV)-infected individuals often demonstrate neuropsychiatric impairment; however, it is unclear how brain metabolism may be altered in such patients. We used in vivo phosphorus 31 magnetic resonance spectroscopy to noninvasively assess brain energy and phospholipid metabolism by measuring brain concentrations of adenosine triphosphate (ATP), phosphocreatine (PCr), and inorganic phosphate (Pi), as well as phospholipid compounds and intracellular pH. In study 1, 17 HIV-seropositive men with varying degrees of neuropsychiatric impairment and six control subjects were studied. Localized spectra were obtained from a heterogeneous 5 x 5 x 5-cm volume of interest (VOI). Patients with HIV infection had a significantly lower ATP/Pi ratio and a trend for a lower PCr/Pi ratio than did the control group. In addition, the ATP/Pi and PCr/Pi ratios were both significantly negatively correlated with overall severity of neuropsychiatric impairment. In study 2, three HIV-seropositive men with neuropsychiatric impairment were compared with 11 HIV-seronegative men. Localized phosphorus 31 magnetic resonance spectra were obtained from two relatively homogeneous VOIs: (1) a predominantly white matter VOI, and (2) a predominantly subcortical gray matter VOI. The three HIV-infected patients demonstrated significantly decreased ATP and PCr concentrations in the white matter VOI. These results suggest that HIV infection of the brain may impair brain cellular oxidative metabolism and that the degree of metabolic compromise may be related to the severity of neuropsychiatric impairment.