THE EFFECT OF AUDIOGENIC SEIZURES ON REGIONAL CNS ENERGY RESERVES, GLYCOLYSIS AND CITRIC ACID CYCLE FLUX 1

Selected energy reserves, glycolytic intermediates and citric acid cycle intermediates were measured in the cerebral cortex, thalamus, brain stem, cerebellum and spinal cord of susceptible mice during audiogenic seizures. Changes in energy reserves (ATP, phosphocreatine and glucose) differed strikingly in extent and temporal pattern from region to region. The audiogenic seizure produced a transient, large decrease in thalamic energy reserves during the early, pretonic phase of the seizure. Less extensive decreases were observed in brain stem and spinal cord; but in these latter regions the changes persisted throughout the pretonic and tonic phases of the seizures. In cerebellum there was a biphasic decrease in energy reserves; a small decrease was observed immediately after the sound stimulus and a second much greater decrease was observed during the tonic phase of the seizure. No change in energy reserves was observed in cerebral cortex. Changes in glycolytic intermediates (glucose 6‐phosphate, fructose diphosphate, pyruvate and lactate) also varied from region to region in response to the decreases in energy reserves. In contrast, changes in the two citric acid cycle intermediates, α‐oxoglutarate and malate, were essentially the same in all regions studied. α‐Oxoglutarate decreased during the tonic phase of the seizure and rose during recovery. Malate remained at control levels throughout the seizure and then slowly increased. These findings are interpreted as indicating regional variations in nueronal activity during audiogenic seizures. During the period when clinical seizure activity is apparent neuronal activity increases in the subcortical regions. This is reflected by an increase in energy utilization and an increase in glycolytic flux in these areas. However, a concomitant increase in citric acid cycle flux does not seem to occur during this period. Citric acid cycle flux does appear to increase after the seizure is over.