Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound   Target Concepts: 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)

The inducible 72-kDa heat shock protein (HSP72) is a highly conserved stress protein that is expressed in CNS cells and may play a role in protection from neural injury. We used a monoclonal antibody to HSP72 and immunocytochemistry to localize HSP72 in the rat brain 24 h following either 30 or 60 min of flurothyl-induced status epilepticus. Sprague-Dawley rats were anesthetized with halothane, paralyzed, and ventilated, and remained normotensive and well oxygenated for the duration of the seizures. Seizure activity was quantified via analysis of the scalp EEG pattern. HSP72-like immunoreactivity (HSP72-LI) was induced in specific brain regions in a graded fashion that correlated, in part, with the duration and degree of seizure activity. Milder seizures produced HSP72-LI limited to layers 2 and 3 of frontoparietal cortex, dentate hilus cells, and CA3 pyramidal neurons. More extensive seizures led to HSP72-LI in layers 2, 3 and 5 of frontoparietal and visual cortex, dentate hilus cells, CA1 and CA3 pyramidal neurons, and certain thalamic and amygdaloid nuclei. These are similar to many, but not all, of the brain regions known to be injured with this model. No HSP72-LI was observed in sham-treated controls or flurothyl-treated animals whose seizures were controlled with pentobarbital. HSP72-LI thus localizes to certain regions of seizure-induced injury, and may provide a sensitive method of detecting neuronal 'stress' or injury relatively soon after status epilepticus. Whether or not HSP72 synthesis plays a protective role in the pathogenesis of seizures, or is only a marker for cell injury, remains to be determined.
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PMID:The pattern of 72-kDa heat shock protein-like immunoreactivity in the rat brain following flurothyl-induced status epilepticus. 228 19

The effect of intermittent seizures on the pyramidal neurons of the hippocampus is largely unknown. To determine whether recurrent seizures centered in the hippocampus can produce neuronal loss in this region, a morphometric analysis was performed from standardized sections of hippocampus using 5 groups of animals: (1) surgical control subjects, (2) rats kindled by the rapidly recurring hippocampal seizure (RRHS) paradigm, (3) kindled rats with a few additional limbic seizures (528 +/- 66 seizures), (4) kindled rats with many limbic seizures (1,523 +/- 130 seizures), and (5) rats experiencing limbic status epilepticus (SE) induced by "continuous" hippocampal stimulation. The RRHS and SE protocols induced significant neuronal loss in the CA1 region, but no evidence was found for additional cell loss with increasing numbers of intermittent seizures. These intermittent seizures were, however, associated with a significant thickening of the basal and apical dendritic fields of the CA1 region. These findings indicate that intermittent seizures produce no significant hippocampal neuronal loss and may result in a hypertrophy of CA1 dendritic fields.
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PMID:The hippocampus in experimental chronic epilepsy: a morphometric analysis. 230 27

The behavioral and electrographic effects of 4-aminopyridine (4-AP) administered i.p. or microinjected into the hippocampal CA1 region (i.h.) were studied in rats. The modification of such effects by the systemic administration of the Ca2+ antagonist dihydropyridine, nifedipine, was also studied. 4-AP i.p. (5 mg/kg) induced generalized tonic convulsions in 74% of the animals and death in 13%. Convulsions were characterized by electrical discharges of relatively short duration in all structures studied (frontal cortex, amygdala, dorsal hippocampus and dorsal raphe). Limbic seizures and frequent wet-dog shakes were observed when 4-AP was administered i.h. (2-4 nmol) and this behavior was correlated with hippocampal discharges, which rapidly propagated to the other structures. Pretreatment with nifedipine (7.5-50 mg/kg s.c.) markedly potentiated the effects of 4-AP. The percentage of rats that died during generalized convulsion after i.p. 4-AP increased to 56-87% and the frequency of wet-dog shakes increased after i.h. microinjection of 4-AP. Moreover, nifedipine-treated rats showed long-lasting (greater than 60 min) continuous discharges in all structures studied (status epilepticus). These results are discussed in the light of the possible participation of Ca2+ channels in the convulsant effect of 4-AP and its potentiation by nifedipine.
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PMID:Seizures and wet-dog shakes induced by 4-aminopyridine, and their potentiation by nifedipine. 234 Aug 61

Pathological conditions which interfere with normal brain energy metabolism causes similar neuronal degeneration. Cerebral ischemia, hypoglycemia, and status epilepticus are well known examples of such disease processes. Recently, it has come to be realized that the similarity of the pattern of neuronal degeneration is probably due to the toxicity of a putative neurotransmitter glutamate. Ischemic hippocampal damage in rodents has been studied as a typical experimental model. Following brief ischemia, the rodent hippocampus recovers completely and then starts degenerating over a few days. The delayed neuronal death of the hippocampus could be accounted for by excitotoxic action of glutamate. There is a considerable body of evidence to support this hypothesis. Extracellular glutamate actually increases following brief ischemia. Preceding destruction of glutamatergic input to the hippocampal CA1 (deafferentation) partially prevents ischemic neuronal damage in CA1. Various drugs are reportedly effective in preventing ischemic CA1 damage and some of them have a property of glutamate antagonist. However, why glutamate brings about cell necrosis is still not fully understood. Further study of basic mechanism is awaited.
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PMID:[Neuronal degeneration and glutamate]. 257 28

Subconvulsant doses (20 mg/kg) of pilocarpine administered to a kindled rat convert a kindled seizure to status epilepticus. The hippocampus is involved in such status epilepticus. Furthermore, evidence is accumulating that GABA-mediated inhibition in the hippocampus is chronically diminished by kindling. The studies presented here compared the electrophysiologic effects of pilocarpine in vivo in the CA1 region of the hippocampus in naive and amygdala-kindled rats. A paired pulse paradigm previously shown to quantify the potency of GABAergic inhibition was employed. Stimuli were delivered in the CA3 region of urethane-anesthetized rats and population spikes were recorded in the contralateral CA1 region. In naive rats, pilocarpine (6-60 mg/kg) caused a left shift in the input-output curve measuring stimulus intensity vs population spike amplitudes, indicating an increase in neuronal excitability. In addition, paired pulse inhibition was reduced for interpulse intervals less than 70 ms. In amygdala-kindled rats, neuronal excitability was also enhanced following pilocarpine administration. The potency of baseline paired pulse inhibition was decreased in kindled rats compared to naive controls. Following pilocarpine, inhibition for interpulse intervals less than 70 ms was further reduced, but to a lesser extent than in naive rats. These findings suggest that the ability of subconvulsive doses of pilocarpine to change a discrete kindled seizure triggered by one stimulus to status epilepticus depends on the suppression of GABAergic inhibition below a critical level.
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PMID:Reduction of paired pulse inhibition in the CA1 region of the hippocampus by pilocarpine in naive and in amygdala-kindled rats. 272 29

Kainic acid (KA, 8-15 ng) was injected into the amygdala of conscious freely moving rats via chronically implanted fused silica cannulas. At 15-25 min after the injection, most rats suffered a limbic seizure attack of short duration, consisting of mastication, forelimb clonus, and raising on hind limbs, behaviorally indistinguishable from kindled seizures. Typically, the attack was followed by stereotypies, intense exploration, and by 1 or 2 more attacks. About 60 min after the injection, most rats appeared normal again and histopathological changes in their brains did not exceed those seen in vehicle-injected rats. In 3 cases, however, recurrent seizures culminated in behavioral status epilepticus 60-90 min after the injection. The status epilepticus was stopped by i.p. injection of diazepam (10 mg/kg) after a duration of 10 min (1 case) and 30 min (2 cases), respectively. After 10 min status epilepticus, we observed marginal neuronal damage with slight gliosis in both hippocampi (CA3 and CA1); after 30 min, hippocampal histopathology was more pronounced, with additional necrosis of the ipsilateral piriform cortex. After 0.8 microgram KA, a hundredfold higher dose, the incidence of limbic seizures during the first 40 min was not significantly higher (9/12) than after the lower KA doses (13/19). However, a significantly higher proportion of rats exhibited long-lasting seizure activity, associated with confluent destruction of CA3 pyramidal cells and additional seizure-related brain damage. Our results show that limbic motor seizures do not inevitably lead to histopathological changes in the brain, provided they do not culminate in a state of permanent seizure activity.
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PMID:Limbic seizures without brain damage after injection of low doses of kainic acid into the amygdala of freely moving rats. 274 56

The accumulation of the stress protein HSP70 was found to be an excellent marker for prolonged seizure related metabolic activity of neurons. After kainic acid (KA) induced status epilepticus we observed HSP70 immunoreactivity in the hippocampal CA4 and CA1 sectors, the subiculum, the basolateral and the lateral nuclei of the amygdala, the mediodorsal nucleus of the thalamus, the caudal part of the striatum, the claustrum and in neurons of certain neocortical areas. HSP70-positive nerve cells appeared normal in conventional histological stains. Conversely, degenerating neurons (e.g. in the hippocampal CA3 sector) remained unlabeled.
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PMID:Induction of stress protein HSP70 in nerve cells after status epilepticus in the rat. 276 75

Detailed neurohistological studies were undertaken on 35 cases of cardiac arrest, 17 of hypoglycaemia and 16 of status epilepticus. It was found that the frequency and pattern of selective vulnerability in the hippocampus were similar following cardiac arrest, hypoglycaemia and status epilepticus with the exception that the lateral limb of the dentate fascia was more frequently involved in hypoglycaemia than in the other two groups of cases. Within each group, however, CA1 was the most vulnerable. The cerebellum was less frequently affected in hypoglycaemia and status epilepticus than after cardiac arrest. These findings are compared with recent experimental studies in the rodent which have suggested that the pattern of neuronal damage in each of the three conditions is different.
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PMID:Changes in the hippocampus and the cerebellum resulting from hypoxic insults: frequency and distribution. 278 53

In this chapter, the pathophysiology and neurochemical pathology of epileptic brain damage is discussed on the basis of an integrative approach in which a comparison is made to cell necrosis resulting from ischemia and hypoglycemia. Two main questions are asked. First, is the brain damage resulting from these three disorders of cerebral energy metabolism similar in distribution and structural characteristics, as previously proposed? Second, is it possible to identify one or several neurochemical events, at the cellular and subcellular level, that qualify as the final common pathways leading to neuronal necrosis? A related question is, will seizures cause structural damage even if they do not critically curtail cellular oxygen supply? A review of the literature and of recent results obtained in animals with long-term recovery following status epilepticus of known duration suggests that although brain damage caused by epilepsy shows some similarities to that incurred due to ischemic and hypoglycemic insults, it is far from identical. In well oxygenated animals with an adequate cardiovascular function, 2 hr of status epilepticus causes moderate neuronal necrosis in the cerebral cortex (layers 3-4), the hippocampus (CA4 and CA1 pyramidal cells), and the thalamus (ventromedial nuclei). In rats, status epilepticus of 30 min duration or longer invariably causes infarction of the substantia nigra (pars reticularis), with some affectation of globus pallidus as well. Notably, CA3 pyramids and dentate neurons are spared, as is the pars compacta of the substantia nigra. Neurochemical events in ischemia, hypoglycemia, and status epilepticus show some striking dissimilarities, yet all three conditions lead to neuronal necrosis. In complete or near-complete ischemia, in which metabolic rate virtually ceases; deterioration of tissue energy state is rapid and extensive, with dramatic loss of ion homeostasis; cellular redox systems are reduced; and acidosis is marked to excessive. In hypoglycemic coma, oxygen consumption continues, albeit at a reduced rate; loss of high energy phosphates is extensive but less than complete, as is loss of ion homeostasis; cellular redox system become oxidized; and acidosis is absent. In epileptic seizures, finally, metabolic rate is markedly enhanced; perturbation of tissue energy state and of ion homeostasis is minimal to small; and acidosis is moderate. Results obtained in experimental animals suggest that neuronal necrosis, when incurred, is unrelated to energy failure and occurs in spite of adequate cellular oxygenation. Four neurochemical events are common to all three conditions discussed.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:Epileptic brain damage: pathophysiology and neurochemical pathology. 287 25

Kainic acid administration induces status epilepticus seizures in the rat which damage CA1 and CA3 hippocampal neurons. Rats made hypoglycemic prior to seizure had enhanced volumes of damage, when compared to normo- or hyperglycemic rats. The mild hypoglycemia was not in the range which, itself, typically produces hippocampal damage. This suggests that limited energy availability compromised the ability of neurons to survive seizures. Our data also suggest that the CA1 damage seen after status epilepticus is not hypoxic-ischemic in origin, since elevating pre-seizure glucose concentrations to a range which typically exacerbates hypoxic-ischemic CA1 damage did not augment status-epilepticus CA1 damage.
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PMID:Status epilepticus-induced hippocampal damage is modulated by glucose availability. 291


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