The glycogen content and its topography and UDP glucose: glycogen alpha-4 glucosyltransferase (EC 2.4.1.11) activity in rat brain after experimental carbon monoxide intoxication

Acute carbon monoxide poisoning: animal models: a review

Animals have been used for well over a century in an attempt to understand the toxicology, physiology, and pathology of acute carbon monoxide poisoning. Whether the toxic effects of this gas result from primary hypoxia, as in hypoxic hypoxia to which it is frequently compared, or from direct tissue effects since it enters cells and binds to certain vital components, remains a point of controversy. Acute severe poisoning in man and animals affects primarily the cardiovascular and nervous systems, and frequently produces neurologic dysfunction. Morphologically, tissue damage is usually confined to the white matter. The root cause is at best poorly understood and major investigative efforts have been made toward its elucidation. Many studies with rats, cats and primates indicate a major role for CO-induced hypotension, which serves to compromise blood flow and exacerbate acidosis. The likely cellular mechanisms in this process are only now becoming apparent. This review critically examines the recent as well as a few older CO-animal studies. In scope, they fall into several broad categories: general cardiopulmonary effects, metabolic and tissue effects, general resistance (i.e. tolerance), effects on the central nervous system including blood flow, neurochemistry, morphology and behavior, and finally, experimental therapeutic approaches.

Effects of variations in glutamic acid decarboxylase activity on acute oxygen poisoning

A study was made to test the influence of rapid variations in glutamic acid decarboxylase (GAD) activity on the susceptibility of rats to hyperbaric oxygen (HBO). GAD was inhibited by the convulsant drug unsymmetrical dimethylhydrazine (UDMH) and reactivated by pyridoxine (PYR) after onset of convulsive activity. There was a relatively long induction period after UDMH injection until the onset of convulsions and the predictable interictal periods between successive periodic convulsions made it possible to study the impact of variations in GAD activity on survival rates, suspectibility to HBO and brain glycogen levels in a time sequence after UDMH administration. The experiments showed that UDMH interferes with aerobic metabolism in brain in such a way that profound alterations in resistance to acute oxygen poisoning resulted. An accumulation of substrate proximal to the enzyme block is assumed to develop during UDMH poisoning. The protective effect against HBO toxicity that was achieved after reactivation of GAD by PYR injection, as well as the rapid re-establishment of glycogen levels, is believed to speak in favour of this hypothesis.

Effect of hypoxia, ischemia and carbon monoxide intoxication on in vivo protein synthesis in neuron and glia cell enriched fractions from rat brain

The dynamics of changes in the in vivo amino acid incorporation into proteins of the neuron and glia cell enriched fractions of rat brain following application of a number of hypoxic conditions were investigated. The experimental models include: a) simple hypoxia, b) ischemic-hypoxic hypoxia and c) carbon monoxide intoxication. Irrespective of the experimental model used, neuronal protein synthesis was more markedly inhibited than glial, maximal inhibition being observed 2 hrs after cessation of the experimental procedure. The changes were of transient character, whereby 24 hrs after the experiment the glial synthesis appeared activated above the control value. The higher sensitivity of the neuronal protein synthesis to the applied experimental procedures produced more significant changes of the protein/total radioactivity ratio in neurons than in glia, the ratio expressing the extent of radioactive amino acid utilisation in the synthesis.