trimethyltin-hydroxide and Brain-Diseases

Trimethyltin (TMT) causes a pattern of hippocampal damage in rats that is similar to that caused by convulsant chemicals or seen in the brains of some human epileptics. Therefore, we investigated the possible role that TMT-induced seizure activity might play in the hippocampal damage produced by this organotin. The morphologic effects of systemically administered TMT were compared to those of kainic acid given by the same route. Unlike kainate, TMT produced seizures in only a subset of treated animals and with a latency of days rather than minutes. Evaluation of morphology during the acute seizure period revealed that TMT-induced seizures were associated with a variable pattern of granule and pyramidal cell necrosis and acute dendritic swelling in the two associational/commissural hippocampal pathways, one from CA3 to CA1-CA3 and the other from the hilus to the proximal dendrites of dentate granule cells. The TMT-induced damage contrasted sharply with the acute pattern of kainate-induced damage that consisted of acute dendritic swellings in the distal granule cell dendrites, hilus and mossy fiber region. TMT-treated rats that did not exhibit seizures in the one week after injection exhibited minimal pathology during this period. These results suggest that at least part of the damage to granule and pyramidal cells produced by TMT is mediated by the seizure activity produced by this compound. Although the resulting lesions to the CA1-CA3 pyramidal cells may appear similar in both TMT- and kainate-treated rats long after injection, evaluation of acute pathology during the active seizure phase indicates that these compounds induce seizure activity in different hippocampal pathways and cause different patterns of irreversible neuronal damage as a result.

Topics: Animals; Brain Diseases; Hippocampus; Male; Microscopy, Electron; Rats; Rats, Inbred Strains; Seizures; Trialkyltin Compounds; Trimethyltin Compounds

The content of Synapsin I (Protein I) was examined in brain regions of adult rats exposed to trimethyltin (TMT), and in control animals. Long Evans hooded rats were intragastrically dosed with 4 mg TMT hydroxide/kg body weight for 4 days. No perturbations in Synapsin I levels were evident by 24 h following the fourth dose; however, by 36 h, a significant decrease of 28% in Synapsin I level was present in the hippocampus of TMT treated animals. This decrease was selective, no other brain region examined was affected. As determined by regional analysis of inorganic tin, this specificity was not due to a profound preferential accumulation of tin in the hippocampus. Despite the absence of an alteration in Synapsin I levels at 24 h, morphological examination revealed perturbation in the normal uniform arrangement of granule cell neurons, with dead neurons diffusely distributed throughout the facia dentata. At 36 h, these changes were only slightly more extensive. In contrast, examination of the terminal projection area of these cells, the mossy boutons, showed to be unaffected at 24 h after the 4th dose of TMT. However, by 36 h, many of the mossy boutons contained dense bodies and showed signs of degeneration. This result suggested that the loss of Synapsin I coincides with degeneration of the nerve terminal region. In order to better establish the temporal correlation, a less severe dosing regimen (only 3 days of exposure to 4 mg TMT/kg body wt) was utilized to attenuate the time course of necrosis. Again, necrotic changes were visible in the perikaryon by 1 day after termination of toxicant dosing.(ABSTRACT TRUNCATED AT 250 WORDS)

Topics: Animals; Brain Chemistry; Brain Diseases; Hippocampus; Male; Microscopy, Electron; Nerve Tissue Proteins; Rats; Synapsins; Trialkyltin Compounds; Trimethyltin Compounds