Chronic subanesthetic halothane exposure causes selective alterations in neurotransmitter systems in discrete brain regions

Changes in hippocampal monoamine concentration following halothane anesthesia and concussion

The concentration of norepinephrine in the hippocampus of rats anesthetized with halothane (Wyeth-Ayerst, Philadelphia, Pa) is found to be markedly increased, presumably due to the stress of handling and administering the anesthetic. This increased norepinephrine concentration persists for about 50 minutes but is obliterated when the anesthetized rat is concussed. This 50-minute period corresponds to the time it takes for a rat (or human), comatose for 1-2 seconds following concussion, to regain normal memory. No changes in 3,4-dihydroxybenzene-acetic acid (DOPAC), 3-(3,4-dihydroxyphenyl) alanine (L-DOPA), and 3,4-dihydroxybenzylamine (DHBA) were noted. 5-Hydroxy indole acetic acid (HIAA) showed a depression at 5 minutes and again at 30 minutes, changes that were consistent but not considered statistically significant.

Neurobehavioral toxicology of halothane in rats

Halothane, a commonly used general anesthetic, is considered to be relatively safe for that purpose. Chronic exposure, however, has been found to cause long-lasting damage to neural structure and impairment of behavioral function. In rats, behavioral alterations are particularly evident after developmental exposure, but they can also be seen with adult exposure, especially when halothane is given during the period of neural regrowth following a brain lesion. The pattern of neural damage includes retarded synaptogenesis, impaired dendritic branching and disruption of organelle structure. The behavioral syndrome includes learning impairment, decreased exploratory behavior and decreased nociceptive reactivity. In general, the neural pathology is more pronounced and more easily discernible than the behavioral effects. Neural damage, particularly to the hippocampus, can be clearly seen at points when behavioral impairments have not been found. This demonstrates that in some cases changes in neural structure can be more sensitive indicators of toxic damage than behavioral dysfunction. Halothane exposure has proved to be quite useful as an experimental tool in the study of neural and behavioral recovery after brain lesions. For example, after unilateral entorhinal cortical lesions, behavioral recovery and reactive synaptogenesis occur contemporaneously. It has not been demonstrated whether the behavioral recovery is due to this reinnervation. Postlesion halothane exposure almost completely suppresses reactive synaptogenesis, however, behavioral recovery of T-maze alternation behavior occurs in the halothane-treated rats as well as in controls. This suggests that recovery of spatial performance after such a lesion is not due to recovery of innervation in the dentate, but to some other process such as other neural systems taking over the functions lost with the brain lesion. The studies reviewed highlight the dangers of halothane exposure, especially during development or when recovering from brain injury. They also provide a good case study for comparing the relative sensitivity of morphological and behavioral measures in toxicology and point to the potential use of halothane as an experimental tool for examining the relationships between neural structure and behavioral function.

Pyridoxal phosphate-unrelated inhibition of hippocampal glutamic acid decarboxylase by convulsant pyridoxal sulphate

Previous studies from this laboratory have shown that pyridoxal-5'-sulphate, the synthetic analogue of pyridoxal phosphate, causes epileptic seizures including tonic-clonic convulsions. These seizure activities are prevented or reversed by GABA or muscimol. In an attempt to delineate the biochemical basis of these seizure processes further, we have studied and shown that pyridoxal sulphate is a competitive inhibitor of glutamic acid decarboxylase. In addition, the chronic administration of pyridoxal sulphate was shown to reduce the concentration of pyridoxal phosphate in the cerebellum, the cerebrum, and basal ganglion, but not in the hippocampus. The activity of hippocampal glutamic acid decarboxylase was reduced after 1, 3, and 5 days of chronic application of pyridoxal sulphate. The inhibition was demonstrated, whether glutamic acid decarboxylase was assayed in the presence or absence of its coenzyme pyridoxal phosphate. Unlike findings in the hippocampus, the activity of glutamic acid decarboxylase in other brain regions was unaffected following chronic application of pyridoxal sulphate. The selective toxic effects of pyridoxal sulfate to the hippocampus, a brain area well known for its high susceptibility to seizure discharges, deserve additional indepth investigation.

Catecholamines in rat brain following postnatal undernutrition and nutritional rehabilitation

Norepinephrine and dopamine were examined in 19 discrete brain areas from the telencephalon, diencephalon, and mesencephalon of nutritionally rehabilitated adult rats following postnatal undernutrition from birth through 21 days of age. Following rehabilitation, catecholamine levels were not significantly different from control values in any of the areas examined. Catecholamine concentrations in young, undernourished rats are generally elevated (either from stress or from nutritional insufficiency). Data presented here show that whichever case is true, the early effect of undernourishment is transient and that normal values are restored by nutritional rehabilitation.