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

Extracellular amino acid levels in the rat piriform cortex, an area highly susceptible to seizure-induced neuropathology, were determined by means of intracranial microdialysis. Seizures were induced by systemic administration of either soman (O-1,2,2-trimethylpropyl methylphosphonofluoridate), a potent inhibitor of acetylcholinesterase, or the excitotoxin kainic acid. Extracellular glutamate levels increased in animals with seizures shortly after administration of either convulsant, but this change was statistically significant only in the case of soman-treated animals. Extracellular taurine levels increased markedly, reaching two- and fourfold baseline levels during the second hour of soman- and kainic acid-induced seizures, respectively. Taurine levels did not increase in the subpopulation of soman-treated animals without seizures, a finding indicating that elevation of extracellular taurine level is seizure related. Thus, we propose that taurine efflux may be a physiological cellular response to neuronal changes produced by excitotoxic chemicals, either directly or as a consequence of seizures.
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PMID:Changes in extracellular amino acids during soman- and kainic acid-induced seizures. 359 90

The brains of seizure-sensitive (SS) and seizure-resistant (SR) gerbils were studied with an immunocytochemical method to localize glutamic acid decarboxylase (GAD) to determine whether a defect existed in the inhibitory GABAergic system similar to that which has been reported in animal models of focal epilepsy in which GABAergic cell bodies and terminals are decreased in number. A major difference between the two strains of gerbils was found in the number of GABAergic neurons in the hippocampal formation. Specifically, a paradoxical increase occurred in the number of glutamate decarboxylase GAD-immunoreactive neurons: there were approximately 65% more GABAergic cells within the dentate gyrus and the CA3 region of the hippocampus in the SS gerbils. Furthermore, the density of GAD-immunoreactive puncta, the light microscopic correlates of synaptic boutons, was greater in the SS animals. Other histological methods were used to determine if the difference between SS and SR gerbils was specific for the GABAergic system. Nissl-stained preparations showed that the number of granule cells in the dentate gyrus was 20% greater in SS gerbils than in SR gerbils. An examination of some hippocampal afferents, efferents, and intrinsic connections with acetylcholinesterase histochemistry and the Timm's stain for heavy metals demonstrated no differences between the two strains. In addition, Golgi-stained preparations of the dentate gyrus indicated that the morphology of basket cells did not differ between the two strains nor between the gerbil and the rat. Several brain regions in addition to the hippocampus were studied to determine whether or not the increased number of GAD-immunoreactive neurons was specific for the hippocampal formation. These regions included the substantia nigra, motor cortex, and nucleus reticularis thalami and were selected because they contain large populations of GABAergic neurons and have been implicated in seizure activity. No differences between the two strains were detected in any of these regions. Therefore, a major morphological difference between the brains of SS and SR gerbils exists in the hippocampal formation of SS gerbils in which an increase occurs in the number of GABAergic neurons and granule cells. If these additional inhibitory neurons act mainly to inhibit other inhibitory neurons, the net effect would be increased disinhibition of the principal excitatory neurons of the hippocampal formation. This could lead to seizure activity within the hippocampal formation and at distant sites through multiple synaptic connections.
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PMID:Hippocampus of the seizure-sensitive gerbil is a specific site for anatomical changes in the GABAergic system. 361 18

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

The organophosphorus compound soman irreversibly inhibits cholinesterase in both the central and peripheral nervous systems. High doses of this compound produce seizures and death in animals. Surviving animals exhibit neural lesions and behavioral abnormalities. The behavioral effects of a single exposure to soman were evaluated in rats injected with 50 micrograms/kg or 85 micrograms/kg soman or with saline. Each rat was tested for either activity in an open field or performance in a 14 choice point multiple T-maze. All rats were then tested for reactivity to tactile stimuli. Some rats exposed to soman showed increased activity in the open field, learning deficits in the Stone maze, and increased reactivity to tactile stimuli, while others showed behavior similar to that of controls. An increase in reactivity was correlated with increased open field activity and with poor performance in the Stone maze. Rats which had received soman and were abnormal in behavioral tests were more likely to have abnormal brain pathology than rats which had received soman and were normal in behavioral tests.
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PMID:Long-term behavioral changes in rats following organophosphonate exposure. 365 63

Seizure produced by intrahippocampal injection of zinc sulfate in rabbits is a new chronic model of experimental epilepsy. In this model, the clinical manifestations are easily observed and are expressed not only as partial clonic seizures, but also by secondary generalized seizures. The electrohippocampalogram (EHG) and electrocorticogram (ECoG) discharges change correspondingly during both types of seizures, and last for weeks. The mechanism for induced seizures may be partly related to the inhibitory effect of zinc sulfate injections on the acetylcholinesterase (AchE) activity in the hippocampus. The commonly used antiepileptic drugs, such as phenobarbital and phenytoin, afforded protection against the zinc-induced secondary generalized clonic seizures and alleviated the partial clonic seizures but had no influence on the EHG- and ECoG-monitored periodic bursts of spike discharges. Nitrazepam was found to antagonize both types of seizures and also transiently restored the EHG and ECoG to normal. D-penicillamine, a metal chelator, may be the most effective agent for the treatment of zinc-induced seizures; the agent, in addition to affording protection against both types of seizures, also caused the periodic burst spike discharges in EHG and ECoG to disappear.
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PMID:Features of seizures and behavioral changes induced by intrahippocampal injection of zinc sulfate in the rabbit: a new experimental model of epilepsy. 369 33

The effects of electroconvulsive shock on the levels of acetylcholinesterase in several brain regions of the rat were studied. Hippocampus, mesencephalon, cortex, and striatum exhibited rapid changes in acetylcholinesterase activity during the first few minutes following the convulsion, whereas brainstem and basal forebrain levels remained unchanged. In both hippocampus and midbrain there was a sustained decrease in activity: the total acetylcholinesterase activity was decreased by up to 40% within 2 min of the convulsion and did not return to control values for another 3 h. Thirty minutes after a flurothyl-induced convulsion there was a similar fall in acetylcholinesterase activity in both these regions, whereas a subconvulsive electric shock produced no change. It is concluded that a convulsion produces significant short-term decreases in acetylcholinesterase activity in areas of the rat brain that are involved in the generation and propagation of seizures, and the question is raised of whether this is related to the increase in seizure threshold that follows a convulsion.
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PMID:Acetylcholinesterase activity in regions of the rat brain following a convulsion. 370 31

It is well established that the putative excitatory neurotransmitters, glutamate (Glu) and aspartate (Asp), are neurotoxins that have the potential of destroying central neurons by an excitatory mechanism. Kainic acid (KA), a rigid structural analog of Glu, powerfully reproduces the excitatory neurotoxic (excitotoxic) action of Glu on central neurons and, in addition, causes sustained limbic seizures and a pattern of seizure-linked brain damage in rats that closely resembles that observed in human epilepsy. In the course of studying the seizure-related brain damage syndrome induced by KA, we observed that a similar type of brain damage occurs as a consequence of sustained seizure activity induced by any of a variety of methods. These included intraamygdaloid or supradural administration of known convulsants such as bicuculline, picrotoxin and folic acid, or systemic administration of lithium and cholinergic agonists or cholinesterase inhibitors that have not commonly been viewed as convulsants. We have further observed that this type of brain damage can be reproduced in the hippocampus by persistent electrical stimulation of the perforant path, a major excitatory input to the hippocampus that is thought to use Glu as transmitter. It is a common feature of all such neurotoxic processes that the acute cytopathology resembles the excitotoxic type of damage induced by Glu or Asp, which is acute swelling of dendrites and vacuolar degeneration of neuronal soma, without acute changes in axons or axon terminals. We have found that the seizure-brain damage syndrome induced by cholinergic agents can be prevented by pretreatment with atropine and that the syndrome induced by any of the above methods, cholinergic or noncholinergic, can be either prevented or aborted respectively by either pre-or posttreatment with diazepam. Our findings in experimental animals may be summarized in terms of their potential relevance to human epilepsy as follows. Sustained complex partial seizure activity consistently results in cellular damage if allowed to continue for longer than 1 hr. Hippocampal, or Ammon's horn, sclerosis is the primary pathological result. It may be a priority goal, therefore, in the management of human epilepsy to control such seizure activity within very narrow limits. This proposal is discussed in terms of three major transmitter systems that may be involved; cholinergic, GABAergic, and glutamergic/aspartergic. The cholinergic system may play a role in generating or maintaining this type of seizure activity, and anticholinergics may protect against it provided they are given prior to commencement of behavioral seizures.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:Excitotoxic mechanisms of epileptic brain damage. 370 27

The main objective of this study was to determine whether the excitotoxic cholinesterase inhibitor soman increases the catabolism of phospholipids in rat brain. Injections of soman (70 micrograms/kg, s.c.), at a dose that produced toxic effects, increased the levels of both free fatty acids (175-250% of control) and free choline (250% of control) in rat cerebrum 1 h after administration. All fatty acids contained in brain phosphatidylcholine were elevated significantly including palmitic (16:0), stearic (18:0), oleic (18:1), arachidonic (20:4), and docosahexaenoic (22:6) acids. The changes observed were consistent with those reported to occur following ischemia and the administration of other convulsants. Pretreatment of rats with the anticonvulsant diazepam (4 mg/kg, i.p.) prevented both the signs of soman toxicity and the soman-induced increase of choline and free fatty acids. Diazepam alone did not affect the levels of choline or free fatty acids, cholinesterase activity, or soman-induced cholinesterase inhibition, suggesting that soman toxicity involves a convulsant-mediated increase in phosphatidylcholine catabolism. In addition, administration of the convulsant bicuculline, at a dose that produces seizures and increases the levels of free fatty acids in brain, significantly increased the levels of choline. Results suggest that excitotoxic events enhance the hydrolysis of phosphatidylcholine in brain as evidenced by a concomitant increase in the levels of choline and free fatty acids.
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PMID:Concomitant increases in the levels of choline and free fatty acids in rat brain: evidence supporting the seizure-induced hydrolysis of phosphatidylcholine. 381 25

A procedure is described for the rapid preparation of nerve ending particles (synaptosomes) from 11 regions of one rat brain. The synaptosomal fractions have been characterized by electron microscopy and determination of four marker enzymes, i.e., glutamate decarboxylase (GAD), acetylcholinesterase, succinate dehydrogenase, and glycerol 3-phosphate dehydrogenase. Comparison with a much lengthier standard (Ficoll-sucrose) preparation showed that the synaptosomal yield of the new procedure was substantially better as judged by both morphological evaluation and protein recovery. The improved synaptosome preparation was used for determination of regional gamma-aminobutyric acid (GABA) levels in synaptosomal fractions. The postmortem increase in GABA level during removal and dissection of brain tissue and homogenization and fractionation procedures could be minimized by rapid processing of the tissue at low temperatures and inclusion of the GAD inhibitor 3-mercaptopropionic acid (3-MP; 1 mM) in the homogenizing medium. The addition of GABA (0.2 mM) to the homogenizing medium did not alter the GABA levels in the synaptosomes, indicating that no significant redistribution of GABA occurred during subcellular fractionation in sodium-free media. Synaptosomal GABA levels determined in the 11 rat brain areas showed the same regional distribution as the GABA-synthesizing enzyme GAD. On the basis of these findings, it was suggested that the synaptosome preparation could be used to evaluate the in vivo effects of drugs on nerve terminal GABA. Treatment of rats with a convulsant dose of 3-MP (50 mg/kg i.p.) 3 min before decapitation significantly lowered synaptosomal GABA levels in olfactory bulb, hippocampus, thalamus, tectum, and cerebellum. The 3-MP-induced seizures and reduction of GABA levels could be prevented by administration of valproic acid (200 mg/kg i.p.) 15 min before the 3-MP injection. The data indicate that the improved synaptosome preparation offers a convenient method of preparing highly purified synaptosomes from a large number of small tissue samples and can provide useful information on the in vivo effects of drugs on regional GABA levels in nerve terminals.
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PMID:Improved method for isolating synaptosomes from 11 regions of one rat brain: electron microscopic and biochemical characterization and use in the study of drug effects on nerve terminal gamma-aminobutyric acid in vivo. 392 10

Dipiperidinoethane (DPE) administration produces seizures and CNS lesions. Here we elucidate the cholinergic origin of DPE toxicity. DPE is both an acetylcholinesterase (AChE) inhibitor and a muscarinic antagonist. This dual action negates most of the toxic effects of the compound in vivo. The neurotoxicity is believed to arise from oxidative conversion to DPE-N-oxide, which selectively inhibits AChE. Cytotoxicity does not involve muscarinic neurons, since binding parameters were unchanged following in vivo exposure.
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PMID:Neurotoxicity of dipiperidinoethane due to in vivo conversion to a selective cholinesterase inhibitor. 398 60


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