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(—)-Deprenyl is a selective irreversible inhibitor of MAO-B. The parent compound is responsible for the enzyme inhibitory effect, but its metabolites are also playing a role in the complex pharmacological activity of the substance. In the present studies male NMRI mice were treated orally, subcutaneously, intraperitoneally and intravenously with 5mg/kg of (—)-deprenyl. The time related changes of the plasma concentrations of the parent compound and its main metabolites (methamphetamine, desmethyl-deprenyl and amphetamine) were determined by GC/ MSD technique. The main pharmacokinetic parameters (C_max, t_max, t_1/2 ^β, AUC_0–6, AUC_0-∞) have been calculated. (—)-Deprenyl is well absorbed after oral and parental treatment. The peak concentrations (C_max) were reached at 15 min after treatment and the absorption was followed by a fast elimination (t_1/2 ^β ≤ 2h). (—)-Deprenyl has an intensive “first pass” metabolism after oral treatment; only 25% of the parent compound reaches the systemic circulation. Increased bioavailability was detected after subcutaneous (87.1%) and intraperitoneal (78.7%) administration. The main metabolic pathway of (—)-deprenyl is the N -depropargylation, leading to the formation of methamphetamine. N -demethylation of (—)-deprenyl leads to formation of desmethyl-deprenyl. Amphetamine is produced from both former metabolites.

Alterations in cholesterol homeostasis are associated with Alzheimer’s disease (AD). The role played by specific fractions of serum lipoproteins in modifying the risk of AD, and the interaction with APOE genotype has not yet been investigated. We studied serum lipoprotein profiles using a gradient-density ultracentrifugation method in a cohort of lateonset sporadic AD patients without cerebrovascular lesions and in healthy elderly subjects.

The etiology of white matter hyperintensities (WMH) seen on T2-weighted cranial magnetic resonance images is a matter of debate. We investigated deep and periventricular WMH in the brains of a community-based cohort of 532 subjects aged 75–76 years. The objective of this study was to determine whether WMH at age of 75 years were associated rather with vascular factors than with degenerative factors.

Oxidative stress and neuronal energy depletion are characteristic biochemical hallmarks of Alzheimer’s disease (AD). It is therefore conceivable that pro-energetic and antioxidant drags such as α-lipoic acid might delay the onset or slow down the progression of the disease. In a previous study, 600 mg α-lipoic acid was given daily to nine patients with AD (receiving a standard treatment with choline-esterase inhibitors) in an open-label study over an observation period of 12 months. The treatment led to a stabilization of cognitive functions in the study group, demonstrated by constant scores in two neuropsychological tests (the mini mental state exam, MMSE and the Alzheimer’s disease assessment score cognitive subscale, ADAScog). In this report, we have extended the analysis to 43 patients over an observation period of up to 48 months. In patients with mild dementia (ADAScog < 15), the disease progressed extremely slowly (ADAScog: +1.2 points/year, MMSE:-0.6 points/year), in patients with moderate dementia at approximately twice the rate. However, the progression appears dramatically lower than data reported for untreated patients or patients on choline-esterase inhibitors in the second year of long-term studies. Despite the fact that this study was not double-blinded, placebo-controlled and randomized, our data suggest that treatment with α-lipoic acid might be a successful ‘neuroprotective’ therapy option for AD. However, a state-of-the-art phase II trial is needed urgently.

The triplicate intracerebroventricular (icv) application of the diabetogenic compound streptozotocin (STZ) in low dosage was used in 1-year-old male Wistar rats to induce a damage of the neuronal insulin signal transduction (IST) system and to investigate the activities of hexokinase (HK), phosphofructokinase (PFK), glyceraldehyde-3-phosphate dehydrogenase (GDH), pyruvate kinase (PK), lactate dehydrogenase (LDH) and α-ketoglutarate dehydrogenase (α-KGDH) in frontoparietotemporal brain cortex (ct) and hippocampus (h) 9 weeks after damage. In parallel, the concentrations of adenosine triphosphate (ATP), adenosine diphosphate (ADP), guanosine triphosphate (GTP) and creatine phosphate (CrP) were determined. We found reductions of HK to 53% (ct) and 60% (h) of control, PFK to 63/64% (ct/h); GDH to 56/61% (ct/h), PFK to 57/59% (ct/h), α-KGDH to 37/35% (ct/h) and an increase of LDH to 300/240% (ct/h). ATP decreased to 82/87% (ct/h) of control, GTP to 69/81% (ct/h), CrP to 82/81% (ct/h), ∼P to 82/82% (ct/h), whereas ADP increased to 189/154% (ct/h). The fall of the activities of the glycolytic enzymes HK, PFK, GDH and PK was found to be more marked after 9 weeks of damage when compared with 3- and 6-week damage whereas the diminution in the concentration of energy rich compound was stably reduced by between 20 and 10% relative to control. The abnormalities in glucose/energy metabolism were discussed in relation to tau-protein mismetabolism of experimental animals, and of sporadic AD.

The development of therapies for Alzheimer’s disease (AD) has focused on drags designed to correct the loss of cholinergic function within the central nervous system. Quantitative EEG (qEEG) changes associated with AD consist of background slowing. One way to study the effects of cholinergic drags may be through assessment of their qEEG effects. The aim of the current work was to evaluate the effect of long-term treatment with tetrahydroaminoacridine (THA) on qEEG in AD patients.

Alzheimer’s disease (AD) is the most common progressive neurodegenerative disease. Today, AD affects millions of people worldwide and the number of AD cases will increase with increased life expectancy. The AD brain is marked by severe neurodegeneration like the loss of synapses and neurons, atrophy and depletion of neurotransmitter systems in the hippocampus and cerebral cortex. Recent findings suggest that these pathological changes are causally induced by mitochondrial dysfunction, increased oxidative stress and elevated apoptosis. Until now, AD cannot be diagnosed by a valid clinical method or a biomarker before the disease has progressed so far that dementia is present. Furthermore, no valid method is available to determine which patient with mild cognitive impairment (MCI) will progress to AD. Therefore, a correct diagnosis in the early stage of AD is not only of importance considering that early drag treatment is more effective but also that the psychological burden of the patients and relatives could be decreased. In this review, we discuss the potential role of elevated apoptosis, increased oxidative stress and mitochondrial dysfunction as biomarker for AD in a peripheral cell model, the lymphocytes.

A growing body of evidence implicates impairments in brain insulin signaling in early sporadic Alzheimer disease (sAD) pathology. However, the most widely accepted hypothesis for AD aetiology stipulates that pathological aggregations of the amyloid β (Aβ) peptide are the cause of all forms of Alzheimer’s disease. Streptozotocin-intracerebroventricularly (STZ-icv) treated rats are proposed as a probable experimental model of sAD. The current work reviews evidence obtained from this model indicating that central STZ administration induces brain pathology and behavioural alterations resembling those in sAD patients. Recently, alterations of the brain insulin system resembling those in sAD have been found in the STZicv rat model and are associated with tau protein hyperphosphorylation and Aβ-like aggregations in meningeal vessels. In line with these findings the hypothesis has been proposed that insulin resistance in the brain might be the primary event which precedes the Aβ pathology in sAD.

It is believed that oxidative stress plays a central role in the pathogenesis of metabolic diseases like diabetes mellitus (DM) and its complications (like peripheral neuropathy) as well as in neurodegenerative disorders like sporadic Alzheimer’s disease (sAD). Representative experimental models of these diseases are streptozotocin (STZ)-induced diabetic rats and STZ-intracerebroventricularly (STZ-icv) treated rats, in which antioxidant capacity against peroxyl (ORAC__roo ) and hydroxyl (ORAC__oh ) free radical was measured in three different brain regions (hippocampus, cerebellum, and brain stem) by means of oxygen radical absorbance capacity (ORAC) assay. In the brain of both STZ-induced diabetic and STZ-icv treated rats decreased antioxidant capacity has been found demonstrating regionally specific distribution. In the diabetic rats these abnormalities were not associated with the development of peripheral diabetic neuropathy. Also, these abnormalities were not prevented by the icv pretreatment of glucose transport inhibitor 5-thio-D-glucose in the STZ-icv treated rats, suggesting different mechanism for STZ-induced central effects from those at the periphery. Similarities in the oxidative stress alterations in the brain of STZ-icv rats and humans with sAD could be useful in the search for new drugs in the treatment of sAD that have antioxidant activity.

Background High variability of estimates of cognitive decline in patients with Alzheimer’s disease (AD) derived from unbalanced longitudinal designs may result as much from the applied statistical model as from true biological variability. Objective To compare the accuracy of two statistical models, serial subtraction score (SSA) and mixed-effects regression analysis (MEM), to estimate rates of cognitive decline in patients with amnestic mild cognitive impairment (MCI), a group at risk for AD. Methods We recorded serial mini mental state examination (MMSE) scores from 78 MCI patients. Additionally, we derived simulated trajectories of cognitive decline with unequally spaced observation intervals. Rates of change were assessed from clinical and simulated data using SSA and MEM models. Results MEM reduced variability of rates of change significantly compared to SSA. In a polynomial model, overall length of observation time explained a significant amount of variance of SSA, but not of MEM estimates. For simulated data, MEM was significantly more accurate in predicting true rates of change compared to SSA (p < 0.001). Conclusion MEM yields more accurate estimates of cognitive decline from unbalanced longitudinal data. Simulation studies may be useful to select the appropriate statistical model for a given set of clinical data.