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)

Increased but transient expression of the proto-oncogene c-fos has been recently reported in metrazol and kindling-induced seizures. Here we tested whether kainic acid-induced status epilepticus may result in a long-term increase of this oncogene. A specific pattern of immunoreactive c-fos material was observed with the development of the seizures. Intense labeling first appeared in the dentate gyrus of the hippocampus and the entorhinal cortex. Pyramidal cell layer CA3, CA4 and CA1 as well as other limbic structures were then positively stained during status epilepticus. In addition, the duration of c-fos expression was different according to the anatomical sites. In the dentate gyrus labeling did not exceed 4-5 h whereas the pyramidal cell layer CA1 exhibited increased c-fos expression for as long as 24 h. Here we propose that c-fos which has been related to growth and differentiation in previous studies, could be involved in processes inducing long-term plastic alterations in the limbic system.
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PMID:Long-lasting and sequential increase of c-fos oncoprotein expression in kainic acid-induced status epilepticus. 313 54

Flurothyl-induced status epilepticus was studied by light and electron microscopy (LM, EM) to determine the time course and structural features of neuronal necrosis in the vulnerable brain regions in epilepsy. The cerebral cortex, hippocampus and thalamus were examined after closely spaced recovery periods of up to 1 week. The results showed that acidophilic neurons appeared simultaneously in neurons of the neocortex, hippocampus and thalamus, and that this occurred within 1 h following the end of the epilepsy. The corresponding features of acidophilic neurons by EM were mitochondrial flocculent densities and large discontinuities in cell and nuclear membranes. Dark neurons were ubiquitous during the epilepsy, but recovered almost universally. A few dark neuronal forms persisted and underwent cytorrhexis after 12-h recovery or longer. Axon-sparing dendritic lesions characteristic of excitotoxic neuronal death were found in the neuropil of the neocortex, and in both vulnerable CA1 and resistant CA3 neurons of the hippocampus. Other than acute edema, glial changes were absent. The findings support an excitotoxic mechanism in epilepsy-induced selective neuronal necrosis also in brain regions outside the hippocampus, and contrast with previous reports in ischemia and hypoglycemia in that neuronal necrosis occurs virtually immediately after an epileptic insult. No "maturation" of cell damage, as described in ischemia, was seen. Furthermore, even exceedingly dark neuronal forms and massive dendritic swelling must be considered sub-lethal or prelethal cellular changes. Lethal cellular changes include acidophilia by LM, cell membrane breaks, and mitochondrial flocculent densities by EM.
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PMID:The nature and timing of excitotoxic neuronal necrosis in the cerebral cortex, hippocampus and thalamus due to flurothyl-induced status epilepticus. 336 60

To understand better the molecular and cellular events associated with status epilepticus, a multifaceted analysis has begun on hippocampal tissues therapeutically removed from patients with temporal lobe epilepsy. In this first study, quantitative changes in major ganglioside species are reported, as well as the immunocytochemical localization on the ganglioside GD3 in epileptic human hippocampus. Although significant variations were found between patients, the pattern of change was consistent when compared to normal values obtained from an autopsied specimen and the literature. Total ganglioside content was reduced in epileptic hippocampi, which was attributable, in part, to pyramidal cell loss found in CA1 and CA3. In each case, the percentage of ganglioside GD3 was increased significantly, while ganglioside GD1a decreased. The former change is probably associated with reactive astrocytosis and the latter with loss of neuronal dendrites. Immunocytochemical localization revealed GD3 in the stratum radiatum and the subgranular layer of the dentate gyrus. In these areas, GD3 was present in punctate structures and astrocytes. These findings indicate that GD3 increases in selected areas of the sclerotic hippocampus and is presumably related to localized accumulation of reactive glial cells. Since gangliosides have a high affinity for calcium and localized increase in extracellular calcium could disrupt normal neuronal function, the localized increase in GD3 may not only denote reactive glial cells but may contribute directly to the altered, hyperexcitable condition of epilepsy.
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PMID:Ganglioside changes associated with temporal lobe epilepsy in the human hippocampus. 355 91

Status epilepticus may be followed by the loss of selectively vulnerable neurons in the hippocampus and neocortex. The acute cytopathology preceding cell loss is that of "ischemic cell change" or "dark cell change." In the hippocampus, selectively vulnerable neurons (CA3 and CA1 pyramidal neurons, hilar polymorphic neurons) show swelling of mitochondria in the perikaryon and dendrites after 30 to 120 min of seizure activity. Electron-microscopic studies with the combined oxalate/pyroantimonate technique reveal dense calcium pyroantimonate deposits in the swollen mitochondria. Suppression of seizure activity for 30 to 60 min is sufficient to allow recovery of normal mitochondrial morphology and calcium load. A small proportion of vulnerable neurons develop ischemic cell change with multiple vacuoles containing calcium pyroantimonate deposits. Neurons prone to burst firing accumulate calcium during seizures, and eventually show massive "overloading" of mitochondria. Although by analogy with studies in muscle a cytotoxic role for raised cytosolic calcium concentration has been proposed, the link between increased [CA2+] activation of phospholipases and proteinases and ischemic cell change remains uncertain.
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PMID:Cell damage in epilepsy and the role of calcium in cytotoxicity. 370 26

Neuronal necrosis in the brain resulting from status epilepticus of 15 to 120 minutes duration in ventilated and well-oxygenated rats was assessed. Seizures were induced by inhalation of the convulsant gas flurothyl, and terminated by withdrawal of flurothyl and a single injection of thiopental. The animals were allowed to recover for one week, and neuronal damage was assessed by cell counts following subserial sectioning of the brain and microscopical examination of the sections. Infarction of the pars reticulata of the substantia nigra occurred in 5 of the 6 animals with seizure duration of 30 minutes, and in all animals with longer seizure durations. There also was a common affectation of the central parts of the globus pallidus. The pars compacta of the substantia nigra was never affected. After 45 to 120 minutes of seizures, moderate neuronal necrosis was observed in the neocortex (layers 3 and 4), and after 60 to 120 minutes was seen in amygdaloid and thalamic nuclei, as well as in CA4 and CA1 hippocampal pyramidal cells. Notably, CA3 neurons were not damaged nor were dentate granule cells affected. After 120 minutes of seizures, damage regularly affected the neocortex and the ventral-posterior nuclei of the thalamus. A conspicuous feature was the localization of neuronal necrosis at sites close to the ventricles.
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PMID:Status epilepticus in well-oxygenated rats causes neuronal necrosis. 405 57

Light and electron microscopy (with the combined oxalate-pyroantimonate technique for the electron microscopic visualization of intracellular calcium) were used to compare the hippocampal pathology in rats killed immediately after 1.5-2 h of L-allylglycine-induced seizures with that in rats allowed 15-60 min of a seizure-free "recovery" period before perfusion fixation. Following 1.5 h of seizure activity, cellular pathology included astrocytic swelling and dark cell degeneration of pyramidal and polymorphic neurons. This was accompanied by a marked increase in the amount of calcium pyroantimonate deposits, particularly in swollen and disrupted mitochondria of CA1 and CA3 basal dendrites and in certain neuronal cell bodies in the CA1 and CA3 regions and the hilus. After a seizure-free period of between 30 and 60 min the hippocampi showed almost complete recovery except for a few remaining dark, shrunken cells. The majority of these were presumed to be interneurons. The ultrastructural changes were consistent with the observations by light microscopy. By 60 min, excess calcium deposits had disappeared except in the dark cells in which intracellular vacuoles retained deposits. We conclude that most of the pathological changes observed after 1.5 h of L-allylglycine induced status epilepticus, including the mitochondrial calcium "overload" are reversible. At 1 h after termination of status epilepticus apparently irreversible pathology (dark cell change, "ischaemic cell change") concerns predominantly the polymorphic neurons.
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PMID:Status epilepticus: the reversibility of calcium loading and acute neuronal pathological changes in the rat hippocampus. 646 62

Using electron microscopy and the combined oxalate-pyroantimonate technique, free calcium ions were located in the hippocampus of control rats and of those that had undergone status epilepticus induced by L-allylglycine or bicuculline. The validity of this technique was established by the use of the calcium chelating agent ethylene glycol bis(beta-aminoethyl ether), N,N'-tetra-acetic acid and by an X-ray microanalytical technique. In control material, calcium deposits were visible in synaptic vesicles and multivesicular bodies, in parts of the Golgi apparatus, mitochondria, lysosomes, and in glial and neuronal nuclei. Following 2 h of status epilepticus, cellular pathology included astrocytic swelling, and dark cell degeneration of pyramidal neurons. This was accompanied by a marked increase in the amount of calcium pyroantimonate deposits, particularly in swollen and disrupted mitochondria of CA1 and CA3 basal dendrites, and in selected neuronal cell bodies in the CA1 and CA3-4 regions. We propose that enhanced calcium entry into neurons and consequent overloading of the capacity of mitochondria for calcium sequestration is part of the cytotoxic mechanism leading to selective neuronal loss in the hippocampus in status epilepticus.
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PMID:Intracellular calcium accumulation in rat hippocampus during seizures induced by bicuculline or L-allylglycine. 663 67

Status epilepticus was induced in thirteen paralysed and ventilated rats by the injection of either bicuculline or L-allylglycine. After 1-2 h of seizure activity the animals were intracardially perfused with a 2% glutaraldehyde/3% paraformaldehyde solution. Hippocampal blocks from each rat were processed for light and electron microscopy. The effects of L-allylglycine were more severe than those of bicuculline. Changes include perivascular and perineuronal swelling of astrocytic processes, and neuronal alterations which were graded as follows: Grade I (least severe), neuronal cytoplasm appears slightly darker than usual; Grade II, condensed or dark neurons, usually with microvacuoles; and Grade III classical 'ischaemic cell change'--the cytoplasm and karyoplasm is dark and shrunken, with or without microvacuoles. Many of the microvacuoles originate from mitochondria. In a few cases swollen and disrupted mitochondria are also seen is distended basal dendrites of the CA3 and CA1 pyramidal neurons. Dentate granule cells appear unaffected. The hippocampal neuronal alterations induced by seizure activity include those of 'ischaemic cell change'. The pathogenetic factors common to hypoxia/ischaemia and status epilepticus remain to be identified.
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PMID:Early changes in the rat hippocampus following seizures induced by bicuculline or L-allylglycine: a light and electron microscope study. 684 75

Taber et al. (1977) introduced new model of epilepsy to obtain experimental status epilepticus in mice, through a modification of the kindling method (Goddard et al. 1969). The aim of this paper is to report the effect of Taber's modification on a new animal specie (rats). Bipolar, twisted steel electrodes were stereotaxically implanted into the CA1-CA3 regions of the dorsal hippocampus. After one week the animals received 2 h stimulation sessions, one stimulus per minute, during which a sustained electrographical and behavioral seizures were induced. Different patterns of electrographical discharges as well as tonic-clonic convulsions were observed. The animals which were submitted to 3 stimulating sessions respectively 7, 14 and 21 days after surgery showed an increase in the epileptic activity. This has been interpreted as a plastic neural modification of the hippocampus similar to that observed during learning and memory consolidation. In comparison to other inducing kindling methods this one permits a more rapid elicitation of the phenomenon. For this reason this method will provide a good epilepsy model for the study of anticonvulsant drugs and basic mechanisms involved in the epileptic activity.
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PMID:[Modification of the "kindling" method for obtaining experimental status epilepticus in rats]. 699 53

Using electron microscopy and the combined oxalate--pyroantimonate technique, calcium was located in hippocampal neurons of rats that had undergone L-allylglycine-induced status epilepticus. In control material, calcium deposits were prominent in nearly every synaptic vesicle, and to a lesser degree in mitochondria and the Golgi apparatus of pyramidal neurons and dentate granule cells. After status epilepticus, mitochondrial calcium deposits increased, particularly in the swollen mitochondria of the pyramidal cell bodies and basal dendrites of CA3 and CA1 neurones. These studies support the theory that enhanced calcium entry leading to calcium overload of mitochondria may be an important cytotoxic mechanism producing selective neuronal loss.
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PMID:Intracellular sites of early calcium accumulation in the rat hippocampus during status epilepticus. 711 Jun 39


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