Dose-dependent memory effects and cerebral volume changes after in utero exposure to valproate in the rat.

PURPOSE: Recent clinical studies raised concern of a cognitive teratogenicity of the major antiepileptic drug valproate. To investigate possible cerebral correlates, we established a forced self-application schedule by diluting valproate in the drinking water of pregnant Wistar rats. METHODS: After application of medium (MD) and high doses (HDs) with mean daily intakes of about 470 and 720 mg/kg during the entire pregnancy, we analyzed effects on offspring performance in a series of behavioral paradigms as well as brain volumetric changes by magnetic resonance imaging (MRI). RESULTS: While high dosages with peak serum concentrations slightly above 100 microg/ml induced early decrements in general activity and deficits in learning and memory, medium dosages led to improved watermaze performance in 30-day-old rats. MRI analyses indicated increased hippocampal volumes in the MD condition, whereas in the HD condition significantly decreased cortical and brainstem volumes were registered. Cortical volume reduction was correlated with spatial acuity in the watermaze. CONCLUSIONS: The results indicate that effects of valproate in utero on offspring cognitive capabilities might depend on total drug load differentially affecting cerebral development during adolescence in the rat.

Hippocampal N-acetyl aspartate levels do not mirror neuronal cell densities in creatine-supplemented epileptic rats.

For neuroprotective therapy of neurodegenerative diseases creatine treatment has gained special interest because creatine has been shown to cross the blood-brain barrier, accumulate in the human brain in vivo and cause delayed neuronal cell death in a large number of animal models. Here, we used the pilocarpine model of temporal lobe epilepsy to determine whether creatine administration is able to attenuate the epilepsy-associated decrease in hippocampal N-acetyl aspartate (NAA) concentrations, impairment of mitochondrial function and neuronal cell loss. In vivo1H-NMR spectroscopy showed, in epileptic rats after creatine administration, higher hippocampal NAA concentrations, suggesting improved neuronal survival. However, in vitro observation of hippocampal slices from creatine-treated epileptic rats revealed a more pronounced loss of pyramidal neurons and decrease in activity of mitochondrial enzymes in hippocampal subfields. This indicates that NAA concentrations measured by in vivo1H-NMR spectroscopy reflect alterations of metabolism rather than neuronal cell densities. Our data indicate an adverse effect of creatine on neuronal survival under conditions of enhanced neuronal activity.