Postischemic Glucose Metabolism is Modified in the Hippocampal CA1 Region Depleted of Excitatory Input or Pyramidal Cells

Abstract

During early postischemic reperfusion, the vulnerable brain regions (e.g., hippocampal CA₁) show a relatively high deoxyglucose accumulation. To investigate if this accumulation is a marker for the later-occurring regional cell death and to determine its cellular localization, we studied the glucose metabolism in the CA₁ region post ischemia after removal of its pre- or postsynaptic components. A 20-min period of cerebral ischemia was used for selective removal of the main postsynaptic component in CA₁ pyramidal cells, and a bilateral intraventricular injection of kainic acid for removal of the majority of presynaptic axon terminals in this region (and postsynaptic terminals and cell bodies in CA₃). The glucose metabolism was studied in these two lesion types and in sham-operated animals before and after a period of ischemia. There was a 60% reduction of metabolism after ischemia in the nonvulnerable regions, whereas CA₁ and sometimes CA₃ showed a columnar pattern of high and low metabolism. CA₁ and CA₃ devoid of the postsynaptic component showed increased postischemic metabolism. The latter was due to the presence of macrophages, as demonstrated by an enzyme histochemical stain for nonspecific esterase. CA₁ with no presynaptic component showed a postischemic depression of the glucose metabolism similar to the rest of the brain. It is suggested that the level of the postischemic glucose metabolism in the ischemia-vulnerable regions is determined by the presence of both synaptic components. The presence of macrophages in a region gives rise to apparently normal values of glucose metabolism.