Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UMLS:C0038220 (status epilepticus)
 7,272 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Understanding the molecular basis of altered neuronal excitability in epilepsy is a major challenge in neuroscience research. The present study suggests an inverse correlation between changes in neuronal excitability in status epilepticus and the activity of type II multifunctional calcium/calmodulin-dependent kinase II (CaM kinase II), a major Ca(2+)-signal transducing system in brain. 'Continuous' hippocampal stimulation (CHS), a new model of non-convulsive limbic status epilepticus (SE), mimics the progression of electrographic changes characteristic in human SE and allows for quantitation of post-stimulus seizure severity. In the present study, hippocampus and anterior neocortex from CHS-stimulated rats and paired surgical controls were assayed for CaM kinase II activity by incorporation of radiolabeled phosphate from [gamma-32P]ATP into the 50-kDa subunit of the kinase itself (autophosphorylation). In all instances, CHS induced sustained interictal bursting and/or electrographic seizures. Decreased CaM kinase II activity was seen in all preparations from electrically stimulated hippocampus. CaM kinase II activity in CHS animals was diminished by 37% relative to controls (P less than 0.01; Student's paired t-test). The progressive intensity of the EEG discharges correlated directly with the decrement of CaM kinase II activity (P less than 0.05; Spearman's rank correlation test, n = 5). This is the first report of a dynamic modulation of a biochemical system that has been implicated in neuronal excitability in coordination with the characterized developmental stages of SE.
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PMID:Loss of type II calcium/calmodulin-dependent kinase activity correlates with stages of development of electrographic seizures in status epilepticus in rat. 131 99

Intracellular chloride ion concentration ([Cl-]i) plays an important role in cellular functions including the control of membrane potential and excitability. In neurons, Cl- equilibrium potential (ECl) is lower or higher than the membrane potential (Em), suggesting that [Cl-]i is lower or higher than that expected from passive distribution. As the mechanisms to control [Cl-]i, active outwardly or inwardly directed Cl- transport systems have been reported. The former includes Na(+)-dependent Cl-/HCO3- exchanger, K+/Cl- cotransporter and ATP-dependent Cl- pump; and the latter includes Na+/K+/2Cl- cotransporter and amino acid-dependent Na+/Cl- cotransporter. In hippocampal pyramidal cells, recent studies using a Cl(-)-sensitive fluorescent probe to monitor [Cl-]i revealed the presence of an ATP-dependent Cl- pump and a Na+/K+2Cl- cotransporter, and an uneven distribution of [Cl-]i (cell body less than dendrite) and these Cl- transport systems. Intracerebroventricular administration of an inhibitor of the ATP-dependent Cl- pump, ethacrynic acid, induces status epilepticus in mice. Thus, it appears to be necessary to elucidate cellular and molecular mechanisms of Cl- transporters and their control systems for a better understanding of Cl(-)-related functions in neurons.
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PMID:[Neuronal intracellular chloride ion concentrations and their regulatory mechanisms]. 159 15

The purpose of these experiments was to determine whether flurothyl-induced status epilepticus causes progressive decline of brain high-energy phosphates and progressive increase in brain lactate in neonatal dogs who are paralyzed and oxygenated. In vivo 31P nuclear magnetic resonance spectroscopic measurements showed that the fall in brain pH occurred early in the course of seizure. The decline in phosphocreatine was more gradual, i.e. 50% reduction, during the 1st h of seizure. There was no reduction in ATP during the 3 h of status epilepticus. In vivo 1H nuclear magnetic resonance measurement of brain lactate disclosed a steep rise that stabilized by 60 min. Brain and blood lactate were closely related during the initial phase of seizure, suggesting rapid efflux of lactate from brain or systemic production of lactate. Blood lactate exceeded brain lactate after 1 h of status epilepticus. The new steady state for cerebral phosphocreatine and lactate during status epilepticus was achieved much more slowly during neonatal status epilepticus than has been reported during status epilepticus in the adult experimental animal. The lack of change in ATP during 3 h of seizure indicates that brain energy state is not radically altered during prolonged seizure if oxygenation is maintained.
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PMID:Brain energy state and lactate metabolism during status epilepticus in the neonatal dog: in vivo 31P and 1H nuclear magnetic resonance study. 201 58

Status epilepticus was induced in paralyzed, ventilated rats using bicuculline and was maintained for 50 to 120 minutes. Cerebral cortex, hippocampus, and cerebellum were assayed for calmodulin kinase II activity in vitro using [gamma-32P]ATP and polyacrylamide gel electrophoresis. Seizures resulted in a 3.2 fold decrease in calmodulin kinase activity in crude synaptic membranes of cortex and in a 8.2 fold decrease in hippocampal membranes. Cytosolic calmodulin kinase activity was slightly increased in rats in status epilepticus but statistical significance was not reached. Status epilepticus did not affect calcium/calmodulin-dependent kinase activity in cerebellar membranes or cytosol. These data suggest that intense firing associated with continuous seizure activity decreases calmodulin kinase activity in cortical and hippocampal synaptic membranes, which may result in altered neuronal excitability.
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PMID:Decreased calmodulin kinase activity after status epilepticus. 283 95

There has been increasing biochemical evidence since 1970 that one of the targets for convulsion-induced changes is the cell membrane of neurons. This is partly based on the observation that following seizures, there are increased levels of diacylglycerols and free fatty acids, which are products of the degradation of the major component of cell membranes, phospholipids. In addition, the production of prostaglandins from the free fatty acid, arachidonic acid, is activated after convulsions. This implies that alterations in the metabolism of lipids in brain are a major effect of seizures, and that the further study of these biochemical pathways may reveal important information pertinent to defining the basic mechanism of seizures and seizure-related pathology and may help in the development of potentially effective treatments. The effects of seizures on brain lipid metabolism and some recent studies from our laboratory are described in this chapter. Our results demonstrate that in rat brain, dexamethasone--a phospholipase A2 inhibitor--attenuates bicuculline-induced free fatty acid accumulation in a dose-dependent manner; bicuculline-induced status epilepticus does not alter the activation (synthesis of arachidonoyl coenzyme A) or acylation of fatty acids as assayed in vitro, indicating that the availability of high-energy cofactors (ATP) may be the critical factor responsible for decreased fatty acid acylation in vivo; bicuculline-induced fatty acid accumulation is localized mainly in the synaptosomal fraction of the rat brain; induction of seizures in the rat by bicuculline treatment produces a marked stimulation of lipoxygenase activity in synaptosomes that, in turn, results in a large increase in the synthesis of hydroxyeicosatetraenoic acids (HETEs). This effect is also observed following membrane depolarization with 45 mM K+, and bicuculline-induced status epilepticus stimulates the synthesis of prostaglandin D2. Possible mechanisms and consequences of alterations in specific lipids are described. Also, the possible involvement of a stimulated arachidonic acid cascade, particularly of hydroxylated products, in the release of neurotransmitters is discussed. Other aspects of the interaction between neurotransmission and the production of eicosanoids are reviewed. The metabolic pathways leading to the "lipid effect"--i.e., the production of free fatty acids, diacylglycerols, and arachidonic acid metabolites (eicosanoids)--are numerous and involve a wide variety of enzymes. The mechanism of this "lipid effect" may involve a seizure-induced overstimulation of normal lipid pathways that operate in neurotransmission.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:The accumulation of free arachidonic acid, diacylglycerols, prostaglandins, and lipoxygenase reaction products in the brain during experimental epilepsy. 301 Jun 83

The cerebral metabolic response to bicuculline (BC)-induced status epilepticus (SE) was studied in two-week-old ketamine-anesthetized marmoset monkeys. During 30-min clonic seizures, mean blood pressure, plasma glucose and paO2 did not decrease and plasma lactate doubled. Brains were funnel-frozen and punch biopsies of frontoparietal cortex, temporal cortex and thalamus were analyzed for ATP, phosphocreatine (PCr), glucose and lactate. There were marked reductions of ATP (to 56-77% of controls), PCr (to 23-28% of controls) and glucose (to 1-4% of controls), and lactate increased 3- to 6-fold in seizure animals. NADH fluorescence increased during seizures in cerebral cortex, thalamus, amygdaloid nuclei, hippocampus, posterior striatum and hemispheric white matter. This suggests a reduced tissue redox state in these regions and is correlated with the high energy phosphate depletion and elevated lactate in cortex and thalamus. Our results demonstrate a significant depletion of energy reserves and glucose in cerebral cortex and thalamus during neonatal seizures in the absence of adverse systemic factors. These seizure-induced metabolic changes in brain could have adverse long-term effects on brain development and function.
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PMID:Generalized seizures deplete brain energy reserves in normoxemic newborn monkeys. 313 58

NMR spectroscopic methods have recently been developed for measurement of several concentrated cerebral metabolites in vivo. At present, 31P spectra from the brain permit detection of ATP, PCr, Pi, and certain sugar and lipid phosphates. The resonant frequency of Pi also provides a measure of cerebral pHi, and under some conditions ADP concentration can be calculated from information available in the 31P spectrum. The 1H spectrum of brain provides measurements of lactate, creatine, and several amino acids and choline-containing compounds. Both kinds of spectra can be obtained from the same subject. Our group at Yale used combined 31P and 1H methods to demonstrate that loss and recovery of phosphate energy stores and concomitant changes in cerebral amino acids during hypoglycemic coma in rodents could be observed in vivo. We then used the same methods to show that cerebral pHi can be normal while lactate is elevated in status epilepticus. NMR spectroscopy performed in vivo provides an array of chemically specific measurements unavailable by any other non-invasive method. It is thought to be entirely free of deleterious biological effects; hence, its potential for use in humans is considerable.
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PMID:Combined 1H and 31P NMR studies of cerebral metabolism in vivo. 357 13

The substantia nigra pars reticulata (SNPR) has previously been shown to undergo tissue necrosis following status epilepticus induced by flurothyl in the rat. Even if the rat is ventilated, the SNPR develops necrosis if the epileptic period lasts more than 30 min. Rat brains were frozen in situ after 20 and 60 min of seizure activity and after 60 min of seizure activity followed by 60 min recovery. Labile energy metabolites were then analyzed in the SNPR and in the periaqueductal grey matter (PAG, control region). In the PAG, the metabolite changes during status epilepticus were similar to those reported for cerebral cortex and hippocampus. Measurements showed an unchanged ATP content and energy charge (97% and 98% of control, respectively) and an accumulation of lactate to 9.2 +/- 0.6 mumol/g in the 60-min group. In the PAG, all metabolites measured had returned to control values after 60 min of recovery. In the SNPR, the perturbation of the energy metabolites was much more pronounced during status epilepticus. The concentration of ATP decreased to 75 +/- 3%, the energy charge to 91% +/- 12% and the adenylate pool to 86.7 +/- 5.7% of control. Lactate accumulated to concentrations of 16.1 +/- 1.8 mumol/g and 24.9 +/- 2.3 mumol/g in the 20-min and 60-min groups, respectively. The concentration of lactate was still increased above control after 60 min recovery, whereas the concentration of ATP and the energy charge were lower than control. The findings demonstrate that sustained and intense neuronal activation can cause metabolic disturbance and thereby lead to necrosis.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Metabolic alterations underlying the development of hypermetabolic necrosis in the substantia nigra in status epilepticus. 380 59

The effects of prolonged bicuculline-induced seizures on cerebral blood flow and metabolism were determined in paralyzed, mechanically ventilated neonatal dogs. Transient changes occurring early in the course of status epilepticus included significant arterial hypertension, hypocarbia, elevation of plasma norepinephrine levels, and decline in brain glucose concentration. Cerebral blood flow remained elevated throughout the 45 minutes of seizure. Determination of cerebral metabolite values by in vivo phosphorus 31 nuclear magnetic resonance spectroscopy and by in vitro enzymatic analysis of frozen brain samples showed significant decreases in the level of phosphocreatine and relatively less change in ATP values. Progressive intracellular acidosis occurred, coincident with elevation of brain lactate concentrations. We conclude that the physiological and metabolic alterations that occur during prolonged seizures are not uniform, but change with time. Any hypothesis advanced to explain the mechanism of neuronal injury during prolonged seizures must take into account these temporally related changes.
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PMID:31P NMR study of cerebral metabolism during prolonged seizures in the neonatal dog. 403 47

31P NMR studies on the brains of living rabbits were carried out at 32 MHz in a spectrometer having a 200-mm clear bore. Paralyzed pump-ventilated animals under nitrous oxide analgesia were inserted into the 1.89-T field and signals were focused in the brain by using a 4-cm surface coil. Several conventional physiological variables were monitored together with 31P spectra during induction and reversal of insulin shock and hypoxic hypoxia sufficient to abolish the electroencephalogram and during status epilepticus. A reversible decrease in phosphocreatine stores accompanied by an increase in Pi was detected during hypoglycemia and hypoxia. Similar changes were observed in prolonged status epilepticus but were not reversed. ATP levels fell about 50% in hypoglycemia but only slightly in the other two metabolic stresses. Intracellular pH rose in hypoglycemia; in status epilepticus and hypoxia it fell, but only when cardiovascular function was severely impaired. From the measured NMR parameters and the assumptions (i) that creatine kinase was at equilibrium and (ii) that the creatine/phosphocreatine pool was constant, it was possible to calculate the relative changes in cytoplasmic ADP levels associated with these metabolic disturbances.
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PMID:Cerebral metabolic studies in vivo by 31P NMR. 657 78


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