Danilo Carreon

Brain metabolic and clinical effects of rivastigmine in Alzheimer's disease

In-vivo metabolic measures with positron emission tomography using (18)F-fluorodeoxyglucose (FDG-PET) have demonstrated hypometabolism in temporal, frontal, and hippocampal areas during the early stages of Alzheimers disease (AD). Progression of the dementia in AD involves compromised cholinergic functioning. Cholinesterase inhibitors have demonstrated efficacy in improving cognition and behaviour in AD. In this study, we demonstrate the usefulness of FDG-PET in measuring the progression of untreated AD and its modification by treatment with rivastigmine (Exelon, Novartis Pharmaceuticals, East Hanover, New Jersey, USA), a centrally selective cholinesterase inhibitor of the carbamate type. Patients with mild to moderate probable AD (Mini-Mental Status Exam scores of 10-26, inclusive) were enrolled in a double-blind, placebo controlled comparison of three fixed daily doses of rivastigmine (3, 6, or 9 mg/d) or placebo for 26 wk. FDG-PET scans were obtained on 27 patients at baseline and following 26 wk of treatment using the Snodgrass Picture Naming activation task. A total of 71.4% of the patients treated with placebo deteriorated clinically compared to only 25.0% of the patients treated with rivastigmine (chi2 = 4.8; p & 0.03). Rivastigmine-responders (i.e. those who clinically improved or remained clinically stable as measured by the Clinicianaposs Interview-Based Impression of Change-plus) showed a marked increase in brain metabolism (p <0.01) involving, but not limited to, structures comprising the memory-related cortices and the prefrontal system. These metabolic changes were not observed in the placebo-treated patients or the rivastigmine non-responders. Of note is that responders increased hippocampal metabolism by 32.5% (p < 0.03) compared to a non-significant decrease in the non-responders (6.4%) and placebo-treated patients (4.1%). These results are consistent with the literature suggesting that FDG-PET can sensitively measure the progression of AD and its improvement with cholinesterase inhibitors. Rivastigmine prevented the expected deterioration in clinical status and dramatically increased brain metabolic activity in a majority of patients.

D1 receptor alleles predict PET metabolic correlates of clinical response to clozapine

A goal of pharmacogenetics is to clarify associations between allelic variation and risk factors in psychiatric illness. We report changes in regional brain metabolism based on dopamine alleles. Treatment-resistant schizophrenic subjects were positron emission tomography scanned with 18F-fluorodeoxyglucose after 5 weeks each of placebo and clozapine treatment. Significant regional brain metabolic effects were found for the D1 receptor genotypes (P<0.05), adjusted for multiple comparisons. Metabolic decreases for the 2,2 genotype but not the 1,2 genotype were observed in all major sectors of the brain, with the exception of the ventral parts of the caudate and putamen. Frontal, temporal, parietal, and occipital neocortices showed decreased metabolism as did the cingulate juxta-allocortex and the parahippocampal allocortex. Decreases were also observed in the thalamus, amygdala, and cerebellum bilaterally. No significant metabolic differences by genotype were observed for D3, 5HT2A, and 5HT2C polymorphisms. In terms of clinical response, the DRD1 2,2 genotype significantly improved with clozapine treatment, demonstrating a 30% decrease in the Brief Psychiatric Rating Scale positive symptoms in contrast to a 7% worsening for the 1,2 genotype (P<0.05). In this preliminary study, brain metabolic and clinical response to clozapine are related to the D1 receptor genotype.

S‐adenosylmethionine blood levels in major depression: changes with drug treatment

Introduction ‐ The relationship between plasma levels of S‐adenosylmethionine (SAMe), an endogenous methyl donor, and clinical response were studied in patients with a DSM‐III‐R diagnosis of major depression. Material and methods ‐ A double‐blind randomized protocol comparingoral SAMe with oral desipramine, involving a total of 26 patients, was employed. Results ‐At the end of the 4‐week trial, 62% of the patients treated with SAMe and 50% of the patients treated with desipramine had significantly improved. Regardless of the type of treatment, patients witha 50% decrease in their Hamilton Depression Scale (HAM‐D) score showed a significant increase in plasma SAMe concentration. Conclusion ‐ The significant correlation between plasma SAMe levels and the degree of clinical improvement in depressed patients regardless of the type of treatment suggests that SAMe may play an important role in regulating mood.

Effect of fluoxetine and imipramine on the pharmacokinetics and tolerability of the antipsychotic quetiapine.

The effects of fluoxetine and imipramine on the pharmacokinetics and nonpsychiatric side effect profile of quetiapine fumarate were investigated in 26 patients with schizophrenia, schizoaffective disorder, or bipolar disorder in a multicenter, twoperiod, multiple-dose, open-label, randomized trial. Over a 1- to 2-week period, patients were titrated to a 300-mg twice-daily dose of quetiapine. Patients treated for at least 7 days at the target dose entered a combination therapy period, receiving fluoxetine (60 mg daily) or imipramine (75 mg twice daily) for 8 days. Key assessments included pharmacokinetic analysis of quetiapine, the Udvalg for kliniske undersøgelser (UKU) Side Effect Rating Scale, and safety evaluations (e.g., adverse events, electrocardiograms, laboratory tests, and vital signs). Fluoxetine increased the quetiapine area under the plasma concentration time curve during a 12-hour interval (+12%), maximum plasma concentration during the dosing interval (Cssmax; +26%), and minimum plasma concentration at the end of the dosing interval (+8%), although it decreased oral clearance (−11%). The change in Cssmax was statistically although not clinically significant. Imipramine did not affect the pharmacokinetics of quetiapine. Overall, scores on the UKU Side Effect Rating Scale improved during combination therapy with either agent, and no statistically significant deterioration was observed for any item. For safety assessments, the only clinically remarkable event was an imipramine-associated complete left bundle branch block in one patient. No unexpected side effects were reported. In conclusion, combination therapy with quetiapine and fluoxetine or imipramine had a minimal effect on quetiapine pharmacokinetics and was well tolerated.

Brain metabolic effects of Neotrofin in patients with Alzheimer’s disease

Neotrofin, a reported inducer of CNS neurotrophic factor synthesis and release, with memory-enhancing activity and demonstrated restoration of age-induced memory deficits in animals, was tested in patients with mild to moderate Alzheimers disease. Nineteen subjects were treated with 1 week of low-dose (150 mg per day) and 1 week of high-dose (500 or 1000 mg per day) Neotrofin. Cognitive composite scores demonstrated improvement in memory (F=9.6, P=0.0004), executive functioning (P=0.004), and attention (P=0.004). PET scanning was obtained before, after low, and after high dosing. The brain areas most affected were the cerebellum, and sensory and prefrontal cortices, where increases in GMR (Glucose Metabolic Rate) were observed. Increases and decreases were observed in the posterior superior temporal (BA 22), parahippocampal, inferior temporal (BA 37, 20), and fusiform gyri as well as the superior parietal lobule and postcentral gyrus. There were strong hemispheric differences, producing opposite metabolic effects in homologous brain regions. Subcortically, the posterior thalamic region, meso-pontine tegmentum, and tectum had increases in GMR on the left side. At the low dose, GMR was generally increased, but to a lesser degree. The brain areas subserving memory, attention and executive functions were significantly altered in GMR by Neotrofin; however, the directions of these changes were complex. There were significant correlations between improvement in memory and executive function in brain areas involved in circuits subserving these functions. Thus, Neotrofin appears to induce metabolic changes in brain regions involved in circuits underlying memory, attention, and executive functioning.

Standardized videotaped procedure for evaluating withdrawal-emergent tardive dyskinesia in a public residential facility

Two videotaping procedures (one-camera and two-camera) for assessing tardive dyskinesia (TD) and stereotypies were contrasted. Videotapes were subsequently rated utilizing the Dyskinesia Identification System—Condensed User Scale, which was developed in the context of a neuroleptic drug withdrawal regimen to assess abnormal involuntary movements in a developmentally disabled population. Results suggest that both videotaping procedures are able to detect TD-like movements, but that more movements are detected with the two-camera procedure, (full-view and close-up) than with the one-camera (full-view only) procedure. These procedures are applicable to clinical settings for TD monitoring.