UMLS:C0038220 - FACTA Search

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Query: UMLS:C0038220 (status epilepticus)
7,272 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The effects of status epilepticus on the concentration, synthesis, release, and subcellular localization of acetylcholine, the concentration of choline, and the activity of acetylcholinesterase in rat brain regions were studied. Generalized convulsive status epilepticus was induced by the administration of pilocarpine to lithium-treated rats. The concentration of acetylcholine in the cortex, hippocampus, and striatum decreased prior to the onset of spike activity or status epilepticus. Once status epilepticus began, the concentration of acetylcholine increased over time in the cortex and hippocampus, reaching peak levels that were 461% and 304% of control levels, respectively, after 2 h of seizures. Such high in vivo levels of acetylcholine had not been reported previously following any treatment. During status epilepticus, the concentration of acetylcholine in the striatum returned to control levels after the initial depression, but did not accumulate to high levels as it did in the other two regions. The in vivo cortical efflux of acetylcholine was also increased during the seizures. Choline levels were increased by status epilepticus in all three brain regions. Inhibition of seizures by pretreatment with atropine blocked the increases of acetylcholine and choline. Synaptosomes prepared from the cortex and from the hippocampus of rats with status epilepticus had elevated concentrations of acetylcholine: in the hippocampus the acetylcholine was principally in the cytoplasmic fraction, whereas in the cortex the acetylcholine was elevated in both the cytoplasmic and the vesicular fractions. The extra acetylcholine was in a releasable compartment, since increased K+ in the media or ouabain increased the release of acetylcholine from cortical slices to a greater extent in tissue from seized rats than from controls.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Acetylcholine content in rat brain is elevated by status epilepticus induced by lithium and pilocarpine. 361 32

Treatment of the convulsive and neuropathologic actions of organophosphates comprise the major unsolved problem in defending against this class of chemical nerve agents. Understanding and preventing these central actions are important goals of chemical defense research. It is generally accepted that inhibition of acetylcholinesterase results in an accumulation of acetylcholine (ACh) which may be responsible for the acute toxic effects of nerve agents. Although atropine has long been used in the treatment of poisoning, it does not significantly reduce convulsions and seizures nor does it drastically alter the acute toxicity. Inasmuch as antimuscarinic agents do not provide sufficient antidotal activity, it follows that ACh may not be the only transmitter involved in the CNS actions of organophosphates. Benzodiazepines, the most potent of the clinically available anticonvulsants are potentially useful as antidote against nerve agent poisoning. However, significant disadvantages are associated with the im administration of benzodiazepines particularly diazepam the now anticonvulsant fielded drug. The present report was undertaken to compare the effectiveness of thienyl phencyclidine (TCP), a non-competitive antagonist at N-methyl-D-aspartate (NMDA) glutamate receptors, to diazepam both administered im for protection against soman toxicity (convulsions, seizures, incidence on death, brain damage). In a first set of experiments, male wistar rats were pretreated with diazepam (1 mg/kg) given im. Fifteen minutes later 1 x LD50 of soman was injected sc and the incidence of seizures and death were recorded for 24 hr. The therapeutic efficacy of a post-poisoning treatment of diazepam was also studied. In this case diazepam was administered 45 min after the onset of seizures. In a second set of experiments, guinea-pigs were pretreated with pyridostigmine (0.2 mg/kg, sc) in combination with atropine (5 mg/kg, im) 30 min before soman (62 micrograms/kg, sc) and the protective effect of TCP (2.5 mg/kg, im) evaluated when the drug was administered either before soman (15 or 30 min) or after the onset of EEG seizures (5, 30 or 60 min). Pretreatment with diazepam alone did reduce soman-induced seizures but did not reduce mortality of rats. Neuropathology was not observed in non-seizuring rats. When given 45 min after the onset of seizures, diazepam failed to protect against status epilepticus and neuropathology. Thus, diazepam was more effective when given before, rather than after, seizure initiation. Systemic injection of TCP blocked the seizures induced by 2 x LD50 of soman in guinea-pigs pretreated by pyridostigmine and atropine. The anticonvulsant potency of TCP was particularly obvious when the compound was administered curatively.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:[Prevention and treatment of status epilepticus induced by soman]. 808 42

Generalized convulsive status epilepticus (GCSE) is the most common and potentially most damaging form of status epilepticus (SE). It has been previously reported, in both human GCSE and animal models of GCSE, that the electroencephalographs (EEGs) and electrocorticographs (ECoGs) recorded during GCSE contain an ordered sequence of five identifiable patterns: discrete seizures (phase 1), waxing and waning ictal discharges (phase 2), continuous ictal discharges (phase 3), continuous activity with flat periods (phase 4), and periodic epileptiform discharge on a flat background (phase 5). In this paper, we report the same pattern of ECoG changes in 15 rats exposed to soman, an acetylcholinesterase (AChE) inhibitor. Phase 1 was observed in 12 of 15 animals, but phases 2-5 were recorded in all the animals. Taken together, these findings suggest that the sequence of EEG changes is independent of the initiating cause, represent a common electrical response to GCSE, and reflect a common underlying neurochemical mechanism.
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PMID:Electrocorticographic changes during generalized convulsive status epilepticus in soman intoxicated rats. 960 May 47

The effects of GM1 monosialoganglioside pretreatment on brain damage resulting from soman-induced seizure activity were examined in this study. Male Sprague-Dawley rats were infused with GM1 via an osmotic minipump connected through a permanent cannula implanted intracerebroventricularly and challenged with soman (83 micrograms/kg, i.e., 1.25 x LD50) 4 d after initiation of GM1 infusion. Electrocorticographic recordings were monitored via indwelling cortical electrodes. Twenty-seven hours after soman administration, anesthetized rats were euthanized via transcardial perfusion with buffered paraformaldehyde. Brains were processed for hematoxylin and eosin (H&E), cresyl violet (CV), and acetylcholinesterase (AChE) histochemistry, and glial fibrillary acidic protein (GFAP) and microtubule-associated protein 2 (MAP2) immunohistochemistry. All soman-challenged rats not infused with GM1 (n = 14) developed status epilepticus (SE).
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PMID:GM1 monosialoganglioside pretreatment protects against soman-induced seizure-related brain damage. 977 43

We have performed a detailed time-course analysis of cell death in the hippocampal formation, basal forebrain and amygdala following a single intraseptal injection of kainate in adult rats. Acetylcholinesterase histochemistry revealed a profound loss of staining in the medial septum but not in the diagonal band, and cholinergic fiber density was highly reduced in the hippocampus and amygdala at 10 days postinjection. Terminal deoxynucleotidyl transferase-mediated uridine 5'-triphosphatebiotin nick end labeling (TUNEL) histochemistry was performed for precise location of apoptotic cells. Both the medial septum and amygdala exhibited numerous TUNEL-positive nuclei after the intraseptal injection of kainate, while the lateral septum exhibited a lower but significant incidence in terms of apoptotic cells. In the medial septum, the presence of apoptotic cells was at a location displaying acetylcholinesterase staining. TUNEL histochemistry revealed a time-dependent sequential apoptotic cell death in hippocampal pyramidal cells. During the first two days postinjection, apoptosis in the hippocampus was only evident in the CA3 region. At five days postinjection, the entire CA4 region became apoptotic. At 10 days postinjection, the whole extent of the CA1 pyramidal cell layer exhibited numerous TUNEL-positive nuclei. The time-course of kainate-induced apoptosis in Ammons's horn correlated with the disappearance of hippocampal pyramidal neurons as detected by Nissl staining, which is suggestive of a prominent apoptotic death for these cells. The temporal delayed distant damage to CA4 and CA1 hippocampal subfields after a single intraseptal kainate injection is not seen in other models employing kainate and may be a valuable tool for exploring the cellular mechanisms leading to cell death in conditions of status epilepticus.
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PMID:Delayed apoptotic pyramidal cell death in CA4 and CA1 hippocampal subfields after a single intraseptal injection of kainate. 1062 49

In 1983, we reported that intracerebral or systemic administration of cholinergic agents produced seizures and seizure-related brain damage in rodents. During the following 17 years, seizures induced by cholinomimetic drugs became a popular model of epilepsy. Seizures can by produced by cholinergic agonists acting directly at muscarinic receptors or by drugs enhancing cholinergic transmission due to the inhibition of acetylcholinesterase activity. Status epilepticus evoked by pilocarpine in rodents triggers long-lasting changes which can be described as: (I) acute-onset seizures lasting for several hours, (II) a silent period characterized by normalization of electroencephalographic patterns lasting for days, and (III) spontaneous recurrent seizures lasting for life. Therefore, seizures induced by cholinomimetics in rodents are of value for studies of basic mechanisms of epileptogenesis and action of antiepileptic drugs.
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PMID:Pilocarpine-induced seizures in rodents--17 years on. 1094 24

Choline is an essential nutrient for rats and humans, and its availability during fetal development has long-lasting cognitive effects (Blusztajn, 1998). We investigated the effects of prenatal choline supplementation on memory deficits associated with status epilepticus. Pregnant rats received a control or choline-supplemented diet during days 11-17 of gestation. Male offspring [postnatal day 29 (P29)-32] were tested for their ability to find a platform in a water maze before and after administration of a convulsant dose of pilocarpine at P34. There were no differences between groups in water maze performance before the seizure. One week after status epilepticus (P41-P44), animals that had received the control diet prenatally had a drastically impaired performance in the water maze during the 4 d testing period, whereas prenatally choline-supplemented rats showed no impairment. Neither the seizures nor the prenatal availability of choline had any effect on hippocampal choline acetyltransferase or acetylcholinesterase activities. This study demonstrates that prenatal choline supplementation can protect rats against memory deficits induced by status epilepticus.
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PMID:Protective effects of prenatal choline supplementation on seizure-induced memory impairment. 1106 78

Status epilepticus (SE)-induced neuronal injury may involve excitotoxicity, energy impairment and increased generation of reactive oxygen species (ROS). Potential treatment therefore should consider agents that protect mitochondrial function and ROS scavengers. In the present study, we examined whether the spin trapping agent N-tertbutyl-alpha-phenylnitrone (PBN) and the antioxidant vitamin E (DL-alpha-tocopherol) protect levels of high-energy phosphates during SE. In rats, SE was induced by either of two inhibitors of acetylcholinesterase (AChE), the organophosphate diisopropylphosphorofluoridate (DFP, 1.25 mg/kg, sc)- or the carbamate carbofuran (1.25 mg/kg, sc). Rats were sacrificed 1 h or 3 days after onset of seizures by head-focused microwave (power, 10 kW; duration 1.7 s) and levels of the energy-rich phosphates adenosine triphosphate (ATP) and phosphocreatine (PCr) and their metabolites adenosine diphosphate (ADP) and adenosine monophosphate (AMP), and creatine (Cr), respectively, were determined in the cortex, amygdala and hippocampus. Within 1 h of seizure activity, marked declines were seen in ATP (34-60%) and PCr (25-52%). Total adenine nucleotides (TAN = ATP + ADP + AMP) and total creatine compounds (TCC = PCr + Cr) were also reduced (TAN 38-60% and TCC 25-47%). No changes in ATP/AMP ratio were seen. Three days after the onset of seizures, recovery of ATP and PCr was significant in the amygdala and hippocampus, but not in the cortex. Pretreatment of rats with PBN (200 mg/kg, ip, in a single dose), 30 min before DFP or carbofuran administration, prevented induced seizures and partially prevented depletion of high-energy phosphates. Pretreatment with the natural antioxidant vitamin E (100 mg/kg, ip/day for 3 days), partially prevented loss of high energy phosphates without affecting seizures. In controls, citrulline, a product of nitric oxide synthesis, was found to be highest in the amygdala, followed by hippocampus, and lowest in the cortex. DFP- or carbofuran-induced seizures caused elevation of citrulline levels seven- to eight-fold in the cortex and three- to four-fold in the amygdala and hippocampus. These results suggest a close relationship between SE, excitotoxicity and energy metabolism. The involvement of oxidative stress is supported by the findings that DFP and carbofuran trigger an excessive nitric oxide (NO) production in the seizure relevant regions of the brain.
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PMID:Depletion of energy metabolites following acetylcholinesterase inhibitor-induced status epilepticus: protection by antioxidants. 1140 58

Soman, a potent acetylcholinesterase inhibitor, induces status epilepticus in rats followed by conspicuous neuropathology, most prominent in piriform cortex and the CA3 region of the hippocampus. Cholinergic seizures originate in striatal-nigral pathways and with fast-acting agents (soman) rapidly spread to limbic related areas and finally culminate in a full-blown status epilepticus. This leads to neurochemical changes, some of which may be neuroprotective whereas others may cause brain damage. Pretreatment with lithium sensitizes the brain to cholinergic seizures. Likewise, other agents that increase limbic hyperactivity may sensitize the brain to cholinergic agents. The hyperactivity associated with the seizure state leads to an increase in intracellular calcium, cellular edema and metal delocalization producing an oxidative stress. These changes induce the synthesis of stress-related proteins such as heat shock proteins, metallothioneins and heme oxygenases. We show that soman-induced seizures cause a depletion in tissue glutathione and an increase in tissue 'catalytic' iron, metallothioneins and heme oxygenase-1. The oxidative stress induces the synthesis of stress-related proteins, which are indicators of 'stress' and possibly provide neuroprotection. These findings suggest that delocalization of iron may catalyze Fenton-like reactions, causing progressive cellular damage via free radical products.
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PMID:Soman-induced seizures: limbic activity, oxidative stress and neuroprotective proteins. 1192 Sep 27

Public awareness of the dangers of chemical and biological warfare has been heightened in recent times. In particular, chemical nerve agents such as soman and its analogs have been developed and used in war as well as recent incidents, such as in Iraq and Japan. Soman, a rapid acting acetylcholinesterase inhibitor, produces a status epilepticus that leads to extensive neuropathology in vulnerable brain regions (eg, piriform cortex and hippocampus). This study was undertaken to determine whether oxidative mechanisms are involved in brain pathology during soman toxicity. Intracellular thiols such as glutathione (GSH) and protein sulfhydryls (PrSH) are among the most critical antioxidants used to combat oxidative stress. Here we report that during the seizure phase (1 h post soman exposure), PrSH levels in piriform cortex and hippocampus were decreased without changes in glutathione (GSH) levels. However, by 24 h post soman exposure (pathology phase), GSH levels were decreased by nearly 50% in the piriform cortex with a corresponding decrease in PrSH groups. The shift to a more oxidized thiol status indicates that oxygen free radicals likely participate in the neuropathology associated with soman-induced seizures.
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PMID:Alterations in brain glutathione homeostasis induced by the nerve gas soman. 1283 22

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