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 cerebral metabolic response to bicuculline (BC)-induced status epilepticus (SE) was studied in two-week-old ketamine-anesthetized marmoset monkeys. During 30-min clonic seizures, mean blood pressure, plasma glucose and paO2 did not decrease and plasma lactate doubled. Brains were funnel-frozen and punch biopsies of frontoparietal cortex, temporal cortex and thalamus were analyzed for ATP, phosphocreatine (PCr), glucose and lactate. There were marked reductions of ATP (to 56-77% of controls), PCr (to 23-28% of controls) and glucose (to 1-4% of controls), and lactate increased 3- to 6-fold in seizure animals. NADH fluorescence increased during seizures in cerebral cortex, thalamus, amygdaloid nuclei, hippocampus, posterior striatum and hemispheric white matter. This suggests a reduced tissue redox state in these regions and is correlated with the high energy phosphate depletion and elevated lactate in cortex and thalamus. Our results demonstrate a significant depletion of energy reserves and glucose in cerebral cortex and thalamus during neonatal seizures in the absence of adverse systemic factors. These seizure-induced metabolic changes in brain could have adverse long-term effects on brain development and function.
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PMID:Generalized seizures deplete brain energy reserves in normoxemic newborn monkeys. 313 58

During seizure-like events (SLEs), intracellular Ca2+ concentration ([Ca2+]i) increases causing depolarization of the mitochondrial membrane and subsequent intramitochondrial accumulation of Ca2+. Mitochondrial depolarization results in an interruption of oxidative phosphorylation and increase in reactive oxygen species. Calcium activates enzymes of the citrate cycle. A characteristic feature of the low-Mg2+-induced SLEs is that they are transformed to a late activity refractory to anticonvulsant drugs, which may be regarded as a model system of difficult to treat status epilepticus. In contrast, 4-aminopyridine (4-AP)-induced activity rarely evolves to such late activity. The autofluorescence of NAD(P)H was used to monitor changes in cellular energy metabolism in the entorhinal cortex in two in vitro models of focal epilepsy. During repetitive 4-AP-induced SLEs there was a short decrease followed by a long-lasting overshoot of the NAD(P)H signal. This sequence remained unaltered during recurring SLEs. In contrast, during recurrent low-Mg2+-induced SLEs, the brief initial NADH signal reduction was unchanged but the following overshoot of NADH displayed a continuous decrease. This indicates a relative energy failure, which may contribute to the transformation to late activity in the low-Mg2+ model.
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PMID:A relative energy failure is associated with low-Mg2+ but not with 4-aminopyridine induced seizure-like events in entorhinal cortex. 991

Mechanisms of seizure-induced cell death were studied in organotypic hippocampal slice cultures. These develop after withdrawal of magnesium recurrent seizure-like events (SLE), which lead to intracellular and intramitochondrial calcium accumulation. The intramitochondrial Ca accumulation seems to be involved in causing increased production of NADH, measured as NAD(P)H autofluorescence. During SLEs, depolarization of mitochondria and increased production of free radicals is indicated by fluorescence measurements with appropriate dyes. During recurrent seizures, an increased failure to produce NADH is noted while at the same time free radical production seems to increase. This increase and the decline in NADH production could be involved in transition to late recurrent discharges, a phase in which status epilepticus becomes pharmacoresistant. It also coincides with increased cell death as determined with propidium iodide fluorescence. Interestingly, some of these changes can be prevented by application of alpha-tocopherol, a free radical scavenger, which also has neuroprotective effects under our experimental conditions. The results suggest that free radical-induced mitochondrial impairment is involved in seizure-induced cell death.
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PMID:Cell death and metabolic activity during epileptiform discharges and status epilepticus in the hippocampus. 1214 41

Nitric oxide (NO) has been implicated in the neuronal hyperexcitability hence its involvement in the pathophysiology of epilepsy is clear. However, some studies indicate that NO has anticonvulsant effects while others present its convulsive effects. In the present study we tested the involvement of NO in pentylenetetrazol (Metrazol) induced Status Epilepticus (SE) rats, using the nonspecific inhibitor, N-omega-nitro-L-arginine methyl ester (L-NAME) and the neuronal-specific inhibitor, 7-nitroindazole (7N1). The effects of NOS (NO synthase) inhibitors were tested, within the seizures and between them, using the Multiparametric Assembly (MPA) which continuously monitored Cerebral Blood Flow (CBF) by Laser Doppler flowmetry, mitochondrial NADH redox state by the fluorometric technique, extracellular K(+) and H(+) levels using selective mini-electrodes and electrical activity (DC potential and ECoG) using special electrodes. Between seizures a trend of increase in CBF with oxidation of NADH was seen, with no change in K(+) and H(+) extracellular levels. Pre-treatment with L-NAME prevented this trend of increase in CBF whereas the injection of 7NI even decreased CBF between seizures. Within seizures, CBF increased and mitochondrial NADH was oxidized at the first seizures, while in the last seizure NADH was reduced. The use of NOS inhibitors significantly increased the degree of NADH oxidation at the latest convulsions. In conclusion our results demonstrated beneficial effect of NOS inhibitors on the brain cortex under SE induced by Metrazol, implying that they may serve as anticonvulsant drugs.
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PMID:The evaluation of nitric oxide involvement in metrazol induced status epilepticus using multiparametric monitoring. 2123 45

The deficiency in the mitochondrial aspartate/glutamate transporter Aralar/AGC1 results in a loss of the malate-aspartate NADH shuttle in the brain neurons, hypomyelination, and additional defects in the brain metabolism. We studied the development of cortico/hippocampal local field potential (LFP) in Aralar/AGC1 knockout (KO) mice. Laminar profiles of LFP, evoked potentials, and unit activity were recorded under anesthesia in young (P15 to P22) Aralar-KO and control mice as well as control adults. While LFP power increased 3 to 7 times in both cortex and hippocampus of control animals during P15 to P22, the Aralar-KO specimens hardly progressed. The divergence was more pronounced in the CA3/hilus region. In parallel, spontaneous multiunit activity declined severely in KO mice. Postnatal growth of hippocampal-evoked potentials was delayed in KO mice, and indicated abnormal synaptic and spike electrogenesis and reduced output at P20 to P22. The lack of LFP development in KO mice was accompanied by the gradual appearance of epileptic activity in the CA3/hilus region that evolved to status epilepticus. Strikingly, CA3 bursts were poorly conducted to the CA1 field. We conclude that disturbed substrate supply to neuronal mitochondria impairs development of cortico-hippocampal LFPs. Aberrant neuronal electrogenesis and reduced neuron output may explain circuit dysfunction and phenotype deficiencies.
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PMID:Altered postnatal development of cortico-hippocampal neuronal electric activity in mice deficient for the mitochondrial aspartate-glutamate transporter. 2193 95

Interictal spikes, ictal responses, and status epilepticus are characteristic of abnormal neuronal activity in epilepsy. Since these events may involve different energy requirements, we evaluated metabolic function (assessed by simultaneous NADH and FAD+ imaging and tissue O2 recordings) in the immature, intact mouse hippocampus (P5-P7, in vitro) during spontaneous interictal spikes and ictal-like events (ILEs), induced by increased neuronal network excitability with either low Mg2+ media or decreased inhibition with bicuculline. In low Mg2+ medium NADH fluorescence showed a small decrease both during the interictal build-up leading to an ictal event and before ILE occurrences, but a large positive response during and after ILEs (up to 10% net change). Tissue O2 recordings (pO2) showed an oxygen dip (indicating oxygen consumption) coincident with each ILE at P5 and P7, closely matching an NADH fluorescence increase, indicating a large surge in oxidative metabolism. The ILE O2 dip was significantly larger at P7 as compared to P5 suggesting a higher metabolic response at P7. After several ILEs at P7, continuous, low voltage activity (late recurrent discharges: LRDs) occurred. During LRDs, whilst the epileptiform activity was relatively small (low voltage synchronous activity) oxygen levels remained low and NADH fluorescence elevated, indicating persistent oxygen utilization and maintained high metabolic demand. In bicuculline, NADH fluorescence levels decreased prior to the onset of epileptiform activity, followed by a slow positive phase, which persisted during interictal responses. Metabolic responses can thus differentiate between interictal, ictal-like and persistent epileptiform activity resembling status epilepticus, and confirm that spreading depression did not occur. These results demonstrate clear translational value to the understanding of metabolic requirements during epileptic conditions.
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PMID:Metabolic responses differentiate between interictal, ictal and persistent epileptiform activity in intact, immature hippocampus in vitro. 2553 81