Altered white matter/gray matter proportions in the striatum of patients with schizophrenia: a volumetric MRI study.

OBJECTIVE: Anatomical structures of the striatum were studied in 58 patients with schizophrenia and 56 healthy comparison subjects of both genders matched for age and handedness. METHOD: Magnetic resonance imaging scans were used to measure gray matter, white matter, and CSF volumes of the caudate, putamen, and nucleus accumbens in the left and the right hemispheres. RESULTS: White matter/gray matter ratios of the striatal structures were significantly lower in patients than in healthy subjects. In patients, relative white matter volumes in the caudate and nucleus accumbens were reduced, whereas gray matter in the putamen was increased. The total accumbens volume did not differ by diagnosis, but left side accumbens was larger than right in the healthy subjects. The proportion of white matter was greater in women in both the patient and healthy comparison groups. Total caudate and putamen volumes demonstrated no differences due to diagnosis or laterality, but a negative correlation was found in patients between white matter volumes and increasing age. There were no significant correlations among total striatal volumes, white matter/gray matter ratios, age at onset of illness, or illness duration. An estimate of lifetime neuroleptic consumption was positively correlated with right gray matter volume of the putamen in male schizophrenia patients who received typical neuroleptics. CONCLUSIONS: The proportion of white matter to gray matter tissue volumes of the caudate, putamen, and nucleus accumbens is altered in medicated chronic schizophrenia patients, but the total volumes are unchanged.

Whole-body biodistribution, radiation dosimetry estimates for the PET norepinephrine transporter probe (S,S)-[18F]FMeNER-D2 in non-human primates.

BACKGROUND: (S,S)-[F]FMeNER-D2 is a recently developed norepinephrine transporter ligand which is a potentially useful radiotracer for mapping the brain and heart norepinephrine transporter in vivo using positron emission tomography. In this work, we quantified the biodistribution over time and radiation exposure to multiple organs with (S,S)-[F]FMeNER-D2. METHODS: Whole-body images were acquired for 21 time points in two cynomolgus monkeys for approximately 270 min after injection of radioligand. Compressed 3-D to 2-D planar images were used to identify organs with the highest radiation exposure at each time point. Estimates of the absorbed dose of radiation were calculated using the MIRDOSE 3.1 software program performed with the dynamic bladder and ICRP 30 gastrointestinal tract models. RESULTS: In planar images, peak values of the percent injected dose (%ID) at a time after radioligand injection were calculated for the lungs (26.76% ID at 1.42 min), kidneys (13.55% ID at 2.18 min), whole brain (5.65% ID at 4.48 min), liver (7.20% ID at 2 min), red bone marrow (5.02% ID at 2.06 min), heart (2.36% ID at 1.42 min) and urinary bladder (23% ID at 250 min). Assuming a urine voiding interval of 2.4 h, the four organs with highest exposures in microGy . MBq ( mrad . mCi) were kidneys 126 (468), heart wall 108 (399), lungs 88.4 (327) and urinary bladder 114 (422). The effective doses were estimated with and without urine voiding at a range of 123 (33) and to 131 (35.5) microGy . MBq ( mrad . mCi). CONCLUSION: The estimated radiation burden of (S,S)-[F]FMeNER-D2 is comparable to that of other F radioligands.

Quantitative analyses of regional [11C]PE2I binding to the dopamine transporter in the human brain: a PET study.

PURPOSE: The dopamine transporter (DAT) is a plasma membrane protein of central interest in the pathophysiology of neuropsychiatric disorders and is known to be a target for psychostimulant drugs. [(11)C]PE2I is a new radioligand which binds selectively and with moderate affinity to central DAT, as has been demonstrated in vitro by autoradiography and in vivo by positron emission tomography (PET). The aims of the present PET study were to quantify regional [(11)C]PE2I binding to DAT in the human brain and to compare quantitative methods with regard to suitability for applied clinical studies. METHODS: One PET measurement was performed in each of eight healthy male subjects. The binding potential (BP) values were obtained by applying kinetic compartment analysis, which uses the metabolite-corrected arterial plasma curve as an input function. They were compared with the BP values quantified by two reference tissue approaches, using cerebellum as a reference region representing free and non-specific radioligand binding. RESULTS: The radioactivity concentration was highest in the striatum, lower in the midbrain and very low in the cerebellum. The regional [(11)C]PE2I binding could be interpreted by kinetic compartment models. However, the BP values in the striatum obtained by the compartment analyses were about 30% higher than the BP values obtained using reference tissue methods. We suggest that the difference may be explained by the inaccurate metabolite correction, small amounts of radioactive metabolites that could account for the presence of non-specific binding in the cerebellum and insufficient data acquisition time. CONCLUSION: The reference methods may be used to quantify [(11)C]PE2I binding in clinical studies, assuming that non-specific binding in the cerebellum does not vary between subjects and that an extended data acquisition time is employed. Moreover, the study corroborates the previous observation that [(11)C]PE2I is advantageous for PET examination of DAT binding in the midbrain, a region from which dopaminergic innervation originates and which is of central interest for the pathophysiology of several neuropsychiatric disorders.

[(11)C]PE2I: a highly selective radioligand for PET examination of the dopamine transporter in monkey and human brain.

The aim of this study was to explore the potential of a new selective dopamine transporter (DAT) compound as a radioligand for positron emission tomography (PET) examination of DAT in the human brain. The high affinity DAT compound N-(3-iodoprop-2 E-enyl)-2beta-carbomethoxy-3beta-(4-methylphenyl)nortropane (PE2I) was radiolabelled by the O-methylation approach and the binding was characterised by PET in cynomolgus monkeys and a healthy man. Metabolite levels in plasma were measured by gradient high-performance liquid chromatography. O-methylation of the corresponding free acid precursor with [(11)C]methyl triflate gave high radiochemical yield (80%) and specific radioactivity (55 GBq/ microM). [(11)C]PE2I binding in cynomolgus monkeys was nine times higher in the striatum than in the cerebellum at peak equilibrium, which appeared 55-65 min after injection. Displacement and pretreatment measurements using unlabelled beta-CIT, GBR 12909, cocaine, citalopram and maprotiline confirmed that [(11)C]PE2I binds selectively to DAT. In a preliminary study in one human subject the radioactivity ratios of the striatum and substantia nigra to the cerebellum were 10 and 1.8, respectively, at peak equilibrium, which appeared at 40-50 min and 20 min, respectively, after injection. The fraction of the total radioactivity in monkey and human plasma representing unchanged [(11)C]PE2I was 15-20% at 40 min after injection. The present characterisation of binding in monkey and man suggests that [(11)C]PE2I is a suitable PET radioligand for quantitative regional examination of DAT in man.