UMLS:C0036572 - FACTA Search

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Query: UMLS:C0036572 (seizures)
80,221 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Bicuculline-induced status epilepticus was studied in paralyzed rabbits ventilated with an oxygen and nitrous oxide mixture. An Oxford Instruments TMR 32-200 spectrometer was used to record phosphorus 31 nuclear magnetic resonance spectra of the in vivo brain. An array of conventional physiological variables including the electroencephalogram was simultaneously recorded. Several features were consistently observed during status epilepticus: (1) Phosphocreatine levels fell to about two-thirds of their control values and remained at that level despite a gradual decline in seizure activity; (2) intracellular pH declined and then remained constant, whereas seizure discharges declined; (3) adenosine triphosphate levels remained constant at their control values. These new, lower levels of brain phosphocreatine and intracellular pH were largely unaffected by increases in seizure activity brought about by elevation of blood pressure from levels too low to support adequate cerebral perfusion, by waning of anticonvulsant drug effect, or by repeated doses of bicuculline.
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PMID:In vivo phosphorus nuclear magnetic resonance spectroscopy in status epilepticus. 647 92

The effect of asphyxia on seizures was determined in neonatal dogs. In normoxic (paralyzed and ventilated) neonatal dogs, bicuculline-induced seizures produced significant elevations of arterial blood pressure, PO2, glucose, lactate, and epinephrine. Cerebral blood flow increased severalfold; brain glucose, adenosine triphosphate (ATP), and phosphocreatine (PCr) did not decrease significantly. In contrast, seizures during asphyxia were associated with hypoxia, hypotension, hypercarbia, and acidosis. Significant cerebral ischemia developed. Brain glucose, ATP, and PCr were significantly depleted. Complete oxygen deprivation during neonatal seizures exhausts brain energy stores, which leads to cessation of seizure activity.
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PMID:Physiologic and metabolic alterations associated with seizures in normoxic and asphyxiated neonatal dogs. 647 9

Sustained epileptic seizures were induced in cats by means of penicillin (PCN). After a three hour period tissue from the archicortex was removed, frozen, and extracted for metabolic studies. The concentration of ATP, ADP, AMP, phosphocreatine, glucose, glucose-6-phosphate, pyruvate, lactate, glutamate and aspartate were determined. There was a 50% decrease in phosphocreatine concentration, a slight decrease in the level of ATP and a slight increase in the levels of ADP and AMP. There was a decrease in the total adenine nucleotide and the ATP/ADP and ATP/AMP ratios. The absence of a significant change in adenylate energy charge potential reflects the remarkable ability of the brain to stabilize its energy state even after intense seizure activity. A reflection of increased glycolysis is the presence of decreased glucose (nearly 50%), and increased lactate, concentrations. The metabolic changes observed in the archicortex are comparable to those observed by others in the neocortex, indicating perhaps the relative metabolic uniformity of these two types of cortex.
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PMID:Metabolic changes in the hippocampus after prolonged epileptic discharge. 661 55

Previous studies have demonstrated that bicuculline-induced seizures of 1-2 h in duration lead to structural, metabolic, and circulatory alterations in the rat brain. Such alterations were observed even though cerebral oxygenation seemed adequate. In the present study, we explored whether pentylenetetrazole, a convulsant which interferes with gamma-aminobutyric acid inhibition by mechanisms other than that of bicuculline, leads to similar structural alterations and to similar cerebral metabolic and circulatory changes. The drug was given to paralyzed and artificially ventilated rats in a dose of 100 mg/kg i.v., and seizures were allowed to continue for 1-120 min. The onset of seizures was accompanied by a small perturbation of cerebral cortical energy state, but sustained changes were confined to decreases in phosphocreatine, glycogen, and glucose and increases in lactate, pyruvate, and cyclic nucleotides. A sustained increase in free fatty acid concentration was observed, with the largest change occurring in arachidonic acid concentration. In the cerebellum, metabolic perturbation was clearly less pronounced, but cyclic nucleotide concentrations rose substantially. Local cerebral blood flow increased in all but two structures (frontal cortex and caudoputamen), but pronounced interstructural changes occurred. Nerve cell changes and astrocytic swelling were observed in the cerebral cortex. There was marked status spongiosus due to edema, which was mainly astrocytic and most prominent in cortical layer 3 and in parts of hippocampus. Nerve cell changes were of two basic types. The type 1 injured neurons, condensed and triangular in shape, were mainly confined to the edematous areas. Many of them had cytoplasmic vacuoles which on electron microscopy proved to be mainly dilated Golgi cisternae or mitochondria. As compared with bicuculline-induced epilepsy such abnormal mitochondria appeared to be more frequent. The type 2 neurons had slit-formed intracytoplasmic and perinuclear vacuoles resulting from dilatation of the endoplasmic reticulum cisternae and the nuclear envelope. The cerebellum looked normal by light microscopy. We conclude that, in the rat, sustained seizure activity induced by pentylenetetrazole is accompanied by alterations in EEG activity, in cerebral metabolism and circulation, and in cell structure similar to those elicited by bicuculline.
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PMID:Metabolic, circulatory, and structural alterations in the rat brain induced by sustained pentylenetetrazole seizures. 670 50

We analyzed brain tissue in 139 rats for adenosine and its metabolites, inosine and hypoxanthine, during the initial 120 seconds of seizures induced by bicuculline. We also measured ATP, ADP, AMP, phosphocreatine (PCr), and lactate. We divided the rats into four groups by adjustment of their preictal arterial oxygen tension: group I, PaO2 > 200 mm Hg; group II PaO2 = 50 mm Hg; and group III: PaO2 = 100 mm Hg. We treated a fourth group whose PaO2 = 100 mm Hg with phentolamine to block the 44% rise in blood pressure which occurred with the onset of seizures. PaCO2 was maintained between 30 anf 40 mm Hg in all groups. Brain tissue was sampled rapidly after 0, 10, 20, 30, 60, and 120 seconds of seizures by the freeze-blow technique. With normoxia (PaO2 = 100 mm Hg) or hyperoxia (PaO2 > 200 mm Hg), adenosine increased within ten seconds of the onset of seizures and remained elevated even after 120 seconds. Elevations in inosine and hypoxanthine were delayed compared to the increases in adenosine. A reduction in PaO2 (50 mm Hg) or systemic blood pressure during seizures caused a further augmentation in the increase in brain adenosine levels. During the seizure period, transient changes in adenine nucleotides and energy charge were observed, but PCr remained depressed and lactate continued to rise. The rapid and sustained increase in cerebral adenosine levels, temporally paralleling the changes in cerebral blood flow, supports the role for adenosine in the regulation of cerebral blood flow.
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PMID:Changes in brain adenosine during bicuculline-induced seizures in rats. Effects of hypoxia and altered systemic blood pressure. 677 98

Audiogenic seizure-prone mice (DBA/2J) were exposed to a broad band noise source. A reproducible response consisting of wild run, clonus, and tonic stages resulted in all mice. Layers 1 and pyramidal from the parietal cortex and the molecular and Purkinje cell-rich layers from the cerebellar vermis were separately analyzed for glucose, glycogen, ATP, and phosphocreatine. Results showed a biphasic cerebellar response, with decreases in high energy phosphates occurring during the wild run and tonic stage. In the cortex, similar changes occurred in the pyramidal cell layer, but the decreases were not as pronounced as those in the cerebellum. Cells from layer 1 of the parietal cortex were not affected as much as those of the pyramidal layer, suggesting a differential effect between neuronal and nonneuronal cell populations. The greater response of the cerebellum could indicate an attempt to reduce the severity of both the wild run and the tonic extension seizure.
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PMID:Audiogenic seizure-induced changes in energy metabolites in cerebral cortical and cerebellar layers. 681

Isoniazid is a useful chemical convulsant in that metabolic events associated with the preseizure state can be easily examined. In the present study, net levels of glucose, glycogen, ATP, and phosphocreatine were measured using enzymatic techniques in control mice, and in those injected with isoniazid. Results from this study showed a differential effect of isoniazid on cells from the cerebral cortex and the cerebellum. In the preseizure stage, the high energy phosphates ATP and phosphocreatine were decreased in layer 1 and the pyramidal cell layer of the cerebral parietal cortex, but were unchanged in the cerebellum. At the onset of seizures, metabolites were decreased not only in cortical layers, but in the molecular layer and Purkinje cell rich layer of the cerebellum as well. The somewhat delayed response of the cerebellum emphasizes the differential nature of metabolism in various brain regions. Such a delay in cerebellar energy response to perturbation may be conducive to the seizure state. In another series of mice, either sodium valproate or clonazepam was administered prior to isoniazid, and metabolite studies repeated. Results showed that at a time when each anticonvulsant acted to eliminate overt seizure activity, the reduction in ATP and phosphocreatine was not as great as it was in seizing mice treated with isoniazid alone.
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PMID:Isoniazid induced seizures and cerebral cortical and cerebellar energy metabolism. 681 36

This is a study of the effects of chronic hypernatremic dehydration and rehydration on carbohydrate, energy, and amino acid metabolism in the brains of weanling mice. Chronic hypernatremic dehydration induced by 4 days of water deprivation and salt loading was associated with severe weight loss (no other observed clinical effects), increased brain Na+ levels, and a decreased brain water content. Changes in the concentrations of brain glucose, glycolytic and citric acid cycle metabolic intermediates, and phosphocreatine were compatible with reduced cerebral metabolic rate. In adaptation to chronic hypernatremia, there was a significant increase in the content of the measured brain amino acids. Rapid rehydration over a 4-h period with 2.5% dextrose in water returned plasma Na+ levels and brain Na+ and water contents to normal. After rehydration, metabolites were altered in a manner consistent with increased fluxes through the glycolytic pathway and citric acid cycle; the brain glycogen content almost tripled. Brain taurine and glutamine levels were not lowered by rehydration, and the total content of the measured amino acids in brain was still significantly higher than in controls. We speculate that these metabolic perturbations may relate to the development of cerebral edema and seizures or coma following rapid rehydration of humans with chronic hypernatremic dehydration.
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PMID:Effect of chronic hypernatremic dehydration and rapid rehydration on brain carbohydrate, energy, and amino acid metabolism in weanling mice. 684 62

Pentylenetetrazole was administered to Swiss-Albino mice, producing clonic-tonic seizures. Other groups were pretreated with one of the three anticonvulsants: phenytoin, clonazepam, or sodium valproate. Mice were sacrificed during the preseizure (1 minute) stage and at the onset of clonic-tonic seizures (2 minutes). Glucose, glycogen, ATP, and phosphocreatine were measured in layers of the parietal cortex and cerebellar vermis. Cortical metabolites were unchanged, or increased slightly, suggesting decreased utilization. In both cerebellar layers, glucose and glycogen were significantly decreased, and phosphocreatine was decreased in the molecular layer. These results indicate a regionally selective effect for pentylenetetrazole on cerebral energy metabolites. Pretreatment with anti-convulsants reduced the severity of the seizure, and eliminated the effect of pentylenetetrazole on glucose and glycogen.
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PMID:Pentylenetetrazole induced changes in cerebellar energy metabolism. 712 23

The effects of intravenously administered lidocaine on the cerebral cortical energy state and glycolytic metabolism were studied in rats. In one series, rats were divided into five groups according to EEG patterns, i.e., control, desynchronized, synchronized, seizure (1-min duration) and recovery groups. With lidocaine infusion (0.75 mg/min), there were no significant changes from the control group in the cerebral energy state except for a modest increase in phosphocreatine (PCr) in the seizure group and a small decrease in ADP in the non-seizure groups. The cerebral energy charge remained unchanged. Lactate and pyruvate significantly decreased in the non-seizure groups. In a second series, rats were divided into five groups, i.e., control, lidocaine seizure groups (5-min duration, 1.5 mg/min) at hypocapnia, normocapnia and hypercapnia, and a bicuculline (1.2 mg/kg) seizure group. The metabolic changes during lidocaine seizure were essentially the same as those observed in the seizure group in the first series. However, the increase in PCr during lidocaine seizure was significant only in the hypocapnic and the normocapnic groups. Bicuculline-induced seizures were accompanied by a significant decrease in high energy phosphates. In summary, neither a non-seizure nor-seizure dose of lidocaine caused any reduction in the cerebral energy charge nor was there any evidence of increased anaerobic metabolism in the cerebral cortex during lidocaine-induced seizures.
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PMID:Cerebral energy state and glycolytic metabolism during lidocaine infusion in the rat. 721 27

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