Mechanisms involved in irreversible anoxic damage to the in vitro rat hippocampal slice

Abstract

The effects of anoxia on the recovery of neural transmission between the perforant path and the dentate granule cells in the in vitro rat hippocampal slice were studied. There is almost no recovery of the evoked population spike following 10 min of anoxia in slices from adult rats. A 2 h exposure of slices to creatine markedly improves the recovery of the population spike (80% vs. 5%). The creatine pre-incubation builds up phosphocreatine levels in the slice and prevents the large fall in ATP during anoxia; ATP falls to 7.9 rather than 3.6 nM/mg protein. The intracellular pH of both groups falls to the same level during anoxia. If Ca concentration in the medium is reduced to 0 while Mg concentration is raised to 10 mM during anoxia the evoked response recovers to .apprx. 65%. An attenuation of the fall in ATP or entry of Ca during anoxia protects the tissue against irreversible transmission damage. Thus, both of these factors participate in the generation of this damage. It is not yet clear if they act independently or if one acts by altering the other. In the post-anoxic recovery period the intracellular concentration of K is reduced by .apprx. 25%. It is still much higher than in slices that show only partial block of the evoked response when treated with ouabain. A fall in intracellular K 1 h after anoxia cannot explain the lack of recovery of the evoked response in adult tissue. ATP levels in the post-anoxic recovery period are reduced from their pre-anoxic levels (9.7 vs. 13.9 nM/mg protein). When azide or antimycin A are used to directly reduce ATP to the level found 1 h after anoxia the evoked response is reduced by only .apprx. 45%. Thus, the reduced post-anoxic ATP levels are not sufficient to explain the loss of the evoked response in adult tissue. The data show that the irreversible loss of transmission is not due to decreased cell ATP or to decreased cell K/Na levels 1 h after the anoxic period. Since creatine pre-incubation protects against irreversible transmission loss, this compound or one closely related to it may prove useful in attenuating irreversible brain damage in situ.