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)

Lowering of extracellular Mg2+ results in various forms of epileptiform activity in different parts of temporal lobe slices [5,22] which contain neocortical areas such as areas Te2 or Te3, the entorhinal cortex (EC), subiculum, hippocampal areas CA1 to CA3 and the dentate gyrus [5,11]. In the EC, the subiculum and Te2/Te3 seizure-like events (SLEs) with tonic and clonic electrographic discharge patterns, negative slow field potentials and ionic changes comparable to those during tonic-clonic seizures in intact animals were observed. After 30 to 120 min of recurrent seizure activity (80 +/- 37 min) the seizure-like events (SLEs) developed into a state of late recurrent discharges (LRDs). Since previous studies had shown that the LRDs do not respond to valproic acid in contrast to a blocking effect of this drug on SLEs, we investigated the effects of the clinically employed anticonvulsants phenytoin, carbamazepine, phenobarbital, midazolam and ethosuximide on LRDs. All these agents were unable to block the LRDs in the EC, subiculum and Te2/Te3. This was found true both for concentrations which can block SLEs and for higher concentrations. Thus we conclude that this activity may represent a model of difficult to treat status epilepticus.
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PMID:Paroxysmal epileptiform discharges in temporal lobe slices after prolonged exposure to low magnesium are resistant to clinically used anticonvulsants. 775 May 6

As seizure propagation within limbic structures is mediated in part by a small area of deep prepiriform cortex (area tempestas), we investigated the role of area tempestas in modulating hippocampal injury induced by systemic kainate administration. Injury was quantitated by counting the numbers of neurons that stained for the 72,000 mol. wt heat shock protein and with acid-fuchsin dye. Status epilepticus induced these markers of neuronal injury in the CA1 and CA3a regions of the hippocampus, thalamus, piriform cortex and the amygdaloid complex. Microinjection of 2-amino-7-phosphonoheptanoic acid, a competitive antagonist of the N-methyl-D-aspartate subclass of the glutamate receptor, into area tempestas prior to systemic administration of kainate attenuated both heat shock protein induction and acid-fuchsin labeling in CA1 and CA3a pyramidal neurons without reducing the duration of electrographic seizures. Injections of bicuculline, a GABA antagonist, into area tempestas produced hippocampal damage when given with subcytotoxic doses of intravenous kainate. Thus, area tempestas may be a uniquely sensitive anatomical structure involved not just in seizure propagation but also in modulating the extent and pattern of damage induced in hippocampal neurons as a result of prolonged, systemically induced seizures. These effects are due in part to excitatory and inhibitory projections to neurons in area tempestas.
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PMID:Deep prepiriform cortex modulates kainate-induced hippocampal injury. 783 80

The influence of hyperthermia and hypothermia on epileptic brain damage was studied in rats, in which status epilepticus was induced by flurothyl. Histopathological changes were examined by light microscopy after 1 or 7 days of recovery. Two series of animals were studied. In the first, short periods of seizures (20 and 25 min) were employed to examine whether moderate hyperthermia (39.5 degrees C) would aggravate epileptic brain damage, and a longer period (45 min) was used to investigate whether moderate hypothermia (32.5 degrees C) would ameliorate the damage. The second series investigated whether brief periods of status epilepticus (10 min) would cause brain damage if hyperthermia were high or excessive. For this series, animals with body temperatures of 37.0, 39.0, and 41.0 degrees C were studied. Data from normothermic animals (37.5 degrees C) confirmed previously described neuronal damage. Although hyperthermic animals failed to show increased damage in the CA1 sector, or in the hilar region of the dentate gyrus, they showed enhanced damage in the neocortex and globus pallidus (GP). In substantia nigra pars reticulata (SNPR) four out of five hyperthermic animals had bilateral infarcts after 20 min of status epilepticus, whereas no normothermic animal showed such damage. Hypothermia seemed to ameliorate epileptic brain damage in the neocortex (n.s.) and GP (P < 0.05) following status epilepticus for 45 min. Three out of seven hypothermic animals had mild SNPR involvement compared to severe infarction of the nucleus in five out of six normothermic animals (P < 0.05). Thus, hyperthermia aggravated and hypothermia ameliorated epileptic brain damage both in regions showing selective neuronal necrosis (neocortex) and in regions developing pan-necrosis (GP and SNPR). The second series displayed an unexpected result of excessive hyperthermia. Animals subjected to only 10 min of status epilepticus at a temperature of 41 degrees C showed not only neocortical lesions, but also moderate to extensive damage to the hippocampus (CA1, subiculum, and dentate gyrus). It is concluded that at high body and brain temperature, brief periods of status epilepticus can yield extensive brain damage, primarily affecting the hippocampus.
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PMID:Hyperthermia aggravates and hypothermia ameliorates epileptic brain damage. 792 95

Systemic administration of pilocarpine to adult rats induces an acute status epilepticus followed by spontaneous recurrent seizures after a 1-2-week silent period. We recorded field potentials in hippocampal slices obtained from rats with spontaneous recurrent seizures after pilocarpine-induced status. The frequency of the interictal discharges induced in these slices by 4-aminopyridine (4AP) was reduced and their duration was increased. Cutting the Schaffer collaterals caused interictal discharges in CA1 to disappear in normal rats and in rats 3 weeks after pilocarpine-induced status. However, 12 weeks after pilocarpine, these discharges remained in CA1 after such a cut but occurred at a lower frequency. These findings show that in rat hippocampi with a lesion similar to that of human Ammon's horn sclerosis some electrophysiological features of 4AP-induced interictal discharges are altered in comparison to those induced in normal hippocampi.
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PMID:Interictal discharges in the hippocampus of rats with long-term pilocarpine seizures. 797 Jan 73

Systemic administration of the cholinergic agonist pilocarpine (350-400 mg/kg, i.p.) to rats induces acute behavioral and EEG status epilepticus followed by apparent complete neurological recovery. In rats receiving higher doses of pilocarpine (i.e., 380-400 mg/kg), recurrent seizures reappear 2-2.5 weeks later and continue to occur as long as the rats are kept alive. Stereological estimates of neurons in regions CA1, CA3 and the dentate granule cell layer in the dorsal hippocampus show a dose-dependent neuronal loss in the CA3 and CA1 subregions. The granule cell layer of the dentate gyrus is not affected. No progressive neuronal loss was observed in the regions studied after 3, 6 and 12 weeks during which the animals displayed spontaneous recurrent seizures. The temporal profile of the epileptic condition induced by pilocarpine and the resulting pattern of neuronal loss in the rat hippocampus are similar to those seen in many cases of human temporal lobe epilepsy. The neuronal loss is dose-dependent and primarily results from the acute pilocarpine-induced seizures as chronic seizures do not produce any measurable additional cell loss in the regions examined in the experimental model used in this study.
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PMID:Quantitative evaluation of neuronal loss in the dorsal hippocampus in rats with long-term pilocarpine seizures. 801 46

The kynurenine pathway metabolites quinolinic acid and kynurenic acid have been hypothetically linked to the occurrence of seizure phenomena. The present immunohistochemical study reports the activation of astrocytes containing three enzymes responsible for the metabolism of quinolinic acid and kynurenic acid in a rat model of chronic epilepsy. Rats received 90 min of patterned electrical stimulation through a bipolar electrode stereotaxically positioned in one hippocampus. This treatment induces non-convulsive limbic status epilepticus that leads to chronic, spontaneous, recurrent seizures. One month after the status epilepticus, the rats showed neuronal loss and gliosis in the piriform cortex, thalamus, and hippocampus, particularly on the side contralateral to the stimulation. Astrocytes containing the kynurenic acid biosynthetic enzyme (kynurenine aminotransferase) and the enzymes for the biosynthesis and degradation of quinolinic acid (3-hydroxyanthranilic acid oxygenase and quinolinic acid phosphoribosyltransferase, respectively) became highly hypertrophied in brain areas where neurodegeneration occurred. Detailed qualitative and quantitative analyses were performed in the hippocampus. In CA1 and CA3 regions, the immunostained surface area of reactive astrocytes increased up to five-fold as compared to controls. Enlarged cells containing the three enzymes were mainly observed in the stratum radiatum, whereas the stratum pyramidale, in which neuronal somata degenerated, showed relatively fewer reactive glial cells. Hypertrophied kynurenine aminotransferase- and 3-hydroxyanthranilic acid oxygenase-immunoreactive cells were comparable in their morphology and distribution pattern. In contrast, reactive quinolinic acid phosphoribosyl transferase-positive glial cells displayed diversified sizes and shapes. Some very large quinolinic acid phosphoribosyl transferase-immunoreactive cells were noticed in the molecular layer of the dentate gyrus. In the hippocampus, the number of immunoreactive glial cells increased in parallel to the hypertrophic responses. In addition, pronounced increases in immunoreactivities, associated with hypertrophied astrocytes, occurred around lesioned sites in the thalamus and piriform cortex. These findings indicate that kynurenine metabolites derived from glial cells may play a role in chronic epileptogenesis.
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PMID:Kynurenine pathway enzymes in a rat model of chronic epilepsy: immunohistochemical study of activated glial cells. 823 7

The hsp70 gene is induced by denatured protein in injured cells and is an extremely sensitive and reliable marker of cells injured by ischemia, seizures, and toxins. Normal brains have little detectable hsp70 mRNA or HSP70 protein. After status epilepticus produced by systemic injections of kainic acid, however, HSP70 protein is induced in neurons but not glia in brain regions known to be injured by kainic acid. Global and focal ischemia also induce the hsp70 gene in brain. The induction of HSP70 protein in hippocampus following increasing durations of global ischemia correlates with the regional and cellular vulnerability to ischemia: CA1 neurons express HSP70 after the briefest periods of ischemia followed by CA4, CA3, dentate granule neurons, glia, and lastly, endothelial cells. Moreover, as the severity of ischemia worsens, a transcriptional and/or translational blockade of the hsp70 gene occurs in the same order so that moderate degrees of ischemia induce HSP70 in CA3 neurons and dentate granule neurons but not necrotic CA1 neurons, and severe ischemia induces HSP70 in capillary endothelial cells of hippocampus but not in any infarcted neurons or glia throughout the hippocampus. Brief periods of focal ischemia induce HSP70 primarily in neurons, suggesting that even focal ischemia can produce selective neuronal injury without infarction. In some instances, HSP70 immunoreactive astrocytes surround the HSP70 immunostained neurons. Focal ischemia that produces infarction induces HSP70 primarily in endothelial cells of cerebral blood vessels in the regions of infarction and in neurons and astrocytes on the perimeter or the penumbral area of infarction.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:HSP70 heat shock gene regulation during ischemia. 824 24

We studied a rat model of chronic epilepsy that shares key features with certain patients with temporal lobe epilepsy. This model relies on a previous period of limbic system status epilepticus established by focal stimulation to one hippocampus. Animals were examined 1 month after recovery from such status epilepticus and compared to unstimulated controls and to animals that received stimulation but did not develop status epilepticus. Two experimental procedures were employed to study changes in paired pulse inhibition of population spike (PS) discharges elicited in CA1 pyramidal cells. One procedure (homosynaptic) delivered two identical stimuli to the CA3 region contralateral to the recording site; the other procedure (heterosynaptic) delivered a conditioning stimulus to the ipsilateral angular bundle and a separate test stimulus to the contralateral CA3. For both procedures, influences of stimulus intensities and of interpulse intervals on the potency of paired pulse inhibition were determined. Based on the results, standardized protocols that assayed the maximal amount of paired pulse inhibition were developed. With the homosynaptic protocol, there was one period of inhibition (interpulse intervals up to 300 ms). Animals that previously experienced limbic status epilepticus had markedly less paired pulse inhibition under these conditions than did controls. The stimulated, non-status epilepticus animals were not different from controls. For the heterosynaptic protocol, there were 2 phases of paired pulse inhibition, early (< 50 ms) and late (> 300 ms), separated by a period of paired pulse facilitation. After status epilepticus there were, compared to controls, decreases in both early and late phases of inhibition. The stimulated, non-status epilepticus animals were not different from controls. For the paired pulse facilitation, there was no difference between the animals that experienced status epilepticus and controls. These findings indicate a profound and enduring disturbance of GABA-mediated inhibition in this model. The heterosynaptic paired pulse protocol deals with a number of confounding issues associated with the homosynaptic protocol in this regard. Furthermore, the results suggest the inhibitory disturbance is diffuse, affecting various inhibitory circuits in the hippocampus.
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PMID:Decreased heterosynaptic and homosynaptic paired pulse inhibition in the rat hippocampus as a chronic sequela to limbic status epilepticus. 843 59

There is a reduction of gamma-aminobutyric acid (GABA)-mediated inhibition of the CA1 pyramidal region of the hippocampus during status epilepticus (SE). The cellular basis of this loss of GABA-mediated inhibition is not known. This study tested the possibility that GABA type A (GABAA) receptor function in CA1 pyramidal neurons was reduced or blocked during SE, at least in part by postsynaptic cellular mechanisms. GABAA receptor currents (IGABA) were studied by whole-cell patch-clamp techniques in CA1 pyramidal neurons acutely dissociated from rats undergoing lithium/pilocarpine-induced limbic status epilepticus (SE neurons) and from naive rats (naive neurons). SE neurons had more depolarized resting membrane potential (-17.3 mV) compared with naive neurons (-56 mV). IGABA was absent in 47% of SE neurons and reduced in 55% of the remainder, compared with naive neurons. The reduction in IGABA in SE neurons resulted from a combination of factors, including reduced potency and reduced efficacy of GABA in activating chloride channels, and diminished driving force for the GABA-induced chloride currents once activated. These postsynaptic cellular mechanisms resulted in a net reduction or loss in GABA-mediated inhibition and may explain previous in vivo findings reporting a loss of inhibition in hippocampus during limbic SE.
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PMID:Experimental status epilepticus alters gamma-aminobutyric acid type A receptor function in CA1 pyramidal neurons. 852 61

1. Combined hippocampal-parahippocampal slices were employed to study the development of complex epileptiform discharges after Schaeffer collateral stimulation in vitro. With repeated stimulation, slices generated several different types of epileptiform discharges, which were temporally linked to the preceding stimulus, and predictable in their progression. The first epileptiform discharge to be elicited by stimulation was a primary afterdischarge, which began immediately after the stimulation train and progressed with repeated stimulation until it had peaked in amplitude and duration by the third to fifth stimulus train. After development of the primary afterdischarge, a secondary afterdischarge began to appear, with a 2- to 5-min latency after the third to sixth stimulation train, and progressed in amplitude and duration with repeated stimulation, sometimes to durations > 30 min. 2. After development of the secondary afterdischarge, 65-70% of rostral slices triggered long-duration, spontaneous self-sustained activity. This activity consisted of repeated spontaneous 3- to 5-min duration ictallike discharges with a short interval (< 15 min between events), lasting for hours in many cases. These discharges were similar to activity seen in depth recordings of patients with complex partial status epilepticus. This cyclic spontaneous epileptiform activity was blocked by diazepam (100 nM to 1 microM), and potentiated by the N-methyl-D-aspartate (NMDA) antagonist 2-amino-5-phosphonovaleric acid (APV, 50 microM). Analysis of the temporal progression of epileptiform activity through multiple channel extracellular recordings demonstrated that both the interictal and ictal discharges evident during spontaneous recurrent ictal-like status epilepticus (SE) originated at a site distant from the stimulation locus, and then propagated to area CA1. 3. Intracellular recordings from CA3 neurons during spontaneous recurrent ictallike SE activity revealed the cellular correlates of this activity. Recurrent ictallike discharges were initiated at a cellular level by a large depolarization, accompanied by tonic action-potential firing. As the ictal event progressed, the neuron continued to depolarize, and a period of depolarization block ensued, which was terminated by the gradual repolarization of the neuron, with accompanying phasic burst firing. 4. A second variety of long-duration self-sustained activity was also seen in 5-10% of slices. This type of continuous sustained activity was initiated by an increase in duration of the secondary afterdischarge to 30-120 min duration with repeated stimulation. These sustained discharges were also increased in amplitude and frequency by APV (50 microM) and reduced or blocked by the benzodiazepines diazepam or clonazepam (1 microM). Sustained epileptiform discharges seen in vitro were similar to one form of seizure discharges seen in patients with SE in their frequency, duration, in their progression through a similar electrographic series of stages, and their sensitivity to benzodiazepines. 5. Intracellular recordings from CA3 neurons during continuous SE-like discharges revealed large bursts within this area during generation of generalized epileptiform activity. These bursts were coincident with extracellularly recorded population burst activity in CA1, and so were a circuit phenomenon. 6. This physiological and pharmacological correspondence between the multiple types of SE-like activity seen in vitro and in patients with SE suggests that these long-duration limbic discharges seen in slices may constitute a valuable model for study of the seizure discharges of SE. Future studies exploiting the advantages of in vitro preparations may aid in understanding physiological and pharmacological factors important in generation and control of this grave neurological condition.
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PMID:Long-duration self-sustained epileptiform activity in the hippocampal-parahippocampal slice: a model of status epilepticus. 859 94


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