Hippocampal and cerebellar histological changes and their behavioural repercussions caused by brain ischaemic hypoxia experimentally induced by sodium nitrite.

INTRODUCTION: Brain ischaemic hypoxia can produce severe neurological damage that leads to behavioural disorders. This research analysed the hippocampal and cerebellar histological alterations caused by brain ischaemic hypoxia experimentally induced by sodium nitrite (NaNO2) and possible direct repercussions of this hypoxia on behaviour. METHODOLOGY: An experimental study was carried out by administering 60mg/kg NaNO2 to 10 Wistar rats at 3 months of age for 15 consecutive days. Ten control rats did not receive NaNO2. To assess behavioural repercussions, the animals were evaluated in Open Field, Elevated Plus-Maze (EPM), and Forced Swim tests before and after injury to evaluate locomotion, anxiety, and depression, respectively. Markers of stress were evaluated by measuring the blood levels of cortisol, glucose, cholesterol, and lactate. The presence of hippocampal lesions was verified by histologically studying the CA1-CA4 areas. Sections of the cerebellum were also evaluated because Purkinje cells are highly sensitive to ischaemic hypoxia and may serve as markers for this process. RESULTS: The number of neurons with lesions was significantly higher in animals exposed to NaNO2 in the hippocampus areas CA2, CA3, and CA4. The cerebellum was also very vulnerable to hypoxia, presenting extensive lesion áreas. These results are correlated with the parameters of the anxiety and depression tests. CONCLUSION: NaNO2 promoted brain damage due to ischaemic hypoxia in rats. Intoxicated animals showed decreased brain weights; damage in hippocampus and cerebellum; and anxiogenic and depressive behaviour.

Effects of the neonicotinoids thiametoxam and clothianidin on in vivo dopamine release in rat striatum.

Thiamethoxam (TMX) and clothianidin (CLO) are neonicotinoids insecticides. The main characteristic of these pesticides is their agonist action on nicotinic acetylcholine receptors (nAChRs). In the present work it was studied and characterized the effects of TMX and CLO, in different concentrations, on dopaminergic system of rat striatum using in vivo brain microdialysis coupled to HPLC-EC. Intrastriatal administration of 1mM or 5mM TMX has not produced significant increases on dopamine (DA) levels, nonetheless the infusion of 10mM TMX increases the DA output to 841+/-132%, when compared to basal levels. Infusion of 1mM CLO has not induced a significant increase in DA levels, even so 2, 3.5 and 5mM CLO have produced an increase of 438+/-8%, 2778+/-598% and 4604+/-516%, respectively, every compared to basal levels. Mecamylamine (MEC), a non-competitive nAChRs antagonist, was used to investigate the role of nAChRs on DA release induced by TMX and CLO. The increases in extracellular DA levels induced by TMX and CLO when associated to MEC are 80% and 68% lower than the effect produced by CLO and TMX isolated. These results confirm that TMX and CLO appear to induce in vivo DA increased release in striatum of rats and it seems to be concentration dependent. Moreover, these results indicate that this effect might be related to nAChRs.

Differential changes of neuroactive amino acids in samples obtained from discrete rat brain regions after systemic administration of saxitoxin.

Aspartic acid, glutamic acid, gamma-amino-n-butyric acid (GABA) and 2-aminoethanesulfonic acid are neuroactive amino acids. They are found in the central rat nervous system. Here, we have studied if a relationship exists between the presence of saxitoxin (STX) a paralytic poisoning shellfish (PSP) and the neuroactive amino acids. Samples of striatum (S), hypothalamus (H), mid brain (MB), frontal cortex (FC), brain stem (BS), right hemisphere (RH) and left hemisphere (LH) of rat brain were collected and analyzed for neuroactive amino acids (AAn(t)) by Aswad method (1984). Experiments, consisting of intraperitoneal injection of SXT (5 and 10microgkg(-1) body weight) to young male rats, evoked significant changes in AAn(t) above basal values. Aspartic and glutamic acid significantly increased for RH and LH (after 30min the increased was 116% and 210%, P< or =0.001 over basal values, respectively). On the other hand, aspartic, glutamic, taurine and GABA significantly decreased for S (after 30min the decreased was 77.4%; 84%; 93.8% and 95.3%, P< or =0.001 over basal values, respectively). These results suggest that STX alters AAn(t). It is produced at least in part, because STX blocks voltage-gated sodium channels and this blockade could decrease AAn(t) release by exocytotic dependent mechanism of depolarization.

Estradiol reduces cumulative mercury and associated disturbances in the hypothalamus-pituitary axis of ovariectomized rats.

The aim of this research was to verify the incidence of endocrine dysfunction associated with mercury intoxication in the hypothalamus-pituitary reproductive system of normally cycling or castrated female rats and the possible protective action of estrogen replacement therapy. We found no differences in the frequency of estrus cycle stages (diestrus I, diestrus II, proestrus, and estrus) in normally cycling female rats during 54 days of daily oral administration of 0.004, 0.02, and 1 mg/kg MeHgCl. Conversely, the higher dose (1 mg/kg) induced a significant decrease in content of luteinizing hormone releasing hormone (LHRH) into the medial hypothalamus when administered daily during 3 days in ovariectomized rats. This effect was associated with increased levels of mercury found in the anterior pituitary gland and medial hypothalamus, rather than the anterior and posterior hypothalamus, striatum or cerebellum. A decrease in plasma levels of luteinizing hormone (LH) was also detected after administration of 7.5 mg/kg MeHgCl. These disturbances in LHRH and LH secretion induced by mercury were abolished or superimposed (respectively) by estrogenic replacement therapy (0.025 mg/kg 17beta estradiol cypionate, intramuscular). These effects were associated with a significant reduction in mercury content of the anterior pituitary gland and medial hypothalamus, suggesting a protective estrogenic effect.