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)

Pancuronium bromide is a nondepolarizing muscle relaxant approved to induce skeletal muscle relaxation during anesthesia and to facilitate the management of patients undergoing mechanical ventilation. The use of pancuronium bromide during surgery led to the appreciation that it has advantages over drugs previously used for muscle relaxation. Patients in whom pancuronium bromide is of value are (1) hypoxemic patients resisting mechanical ventilation and so cardiovascularly unstable that use of sedatives is precluded, (2) patients with bronchospasm unresponsive to conventional therapy, (3) patients with severe tetanus or poisoning where muscle spasm prohibits adequate ventilation, (4) patients with status epilepticus unable to maintain their own ventilation, (5) shivering patients in whom metabolic demands for oxygen should be reduced, and (6) patients requiring tracheal intubation in whom succinylcholine administration is contraindicated. Without concomitant sedation, use of pancuronium bromide is associated with psychological risks. Other risks are undetected ventilator disconnection, tachyarrythmias, prolonged paralysis and drug interactions.
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PMID:Pancuronium bromide. 33 1

The properties of Althesin (anticonvulsant activity, depression of oxygen consumption, lowering of ICP, rapid excretion) led us to use this steroid combination to treat 11 patients in status epilepticus resistant to the standard drugs (benzodiazepines and barbiturates). The administration of Althesin by slow intravenous injection was ineffective in 2 of the 3 patients thus treated. The doses used (2--10 ml) were probably too small. One only administration of a 10% solution of Althesin in 10% fructose by intravenous drip (the rate was calculated so as to obtain the burst suppression stage at the EEG) stopped status epilepticus in 7 of the 9 patients thus treated. In this group the doses used varied from 25 to 50 ml. The 2 patients in whom it was necessary to repeat Althesin administration and combine it with other drugs had both been operated on for severe brain injuries involving marked cerebral edema. In spite of the very small number of cases, the definitive arrest of status epilepticus obtained in 8 out of 11 patients first treated with other drugs is encouraging: Althesin probably may be regarded as an adjunct in the treatment of status epilepticus.
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PMID:The use of althesin in drug-resistent status epilepticus. 47 37

Prolonged sustained seizure activity (status epilepticus) was created in rats and cats using paralysis and ventilation to prevent muscular contraction and its secondary systemic effects. Under physiologic control, seizure activity was maintained for 30, 60, and 120 min. At this time the brains were frozen using the in situ technique and the cortical tissue was analyzed for energy-related metabolites. The alteration of metabolites found at these times was similar to that previously described in the first 10 min of seizure activity. No evidence was found of any significant or progressive derangement of oxidative metabolism. A progressive lactic acidemia developed in spite of adequate arterial oxygen tensions. In contrast, when mice received a similar dose of the convulsant and were allowed to convulse freely in an oxygen-enriched environment, major derangements of energy metabolism were found which were progressive and persisted following recovery for at least 18 h.
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PMID:Metabolic responses to status epilepticus in the rat, cat, and mouse. 54 87

In order to study effects of catecholamines on cerebral oxygen consumption (CMRo2) and blood flow (CBF), rats maintained on 75% N2O and 25% O2 were infused i.v. with noradrenaline (2, 5, or 8 microgram.kg-1.min-1) or adrenaline (2 or 8 microgram.kg-1.min-1) for 10 min before CBF and CMRo2 were measured. In about 50% of animals infused with 2--8 microgram.kg-1.min-1 of noradrenaline, CMRo2 (and CBF) rose. However, there was no dose-dependent response, and CMRo2 did not exceed 150% of control. The effects of noradrenaline in a dose of 5 microgram.kg-1.min-1 on CMRo2 and CBF were blocked by propranolol (2.5 mg.kg-1). In animals infused with adrenaline (8 microgram.kg-1.min-1) CMRo2 was doubled and, in many, CBF rose 4- to 6-fold. It is concluded that, when given in sufficient amounts, catecholamines have pronounced effects on cerebral metabolism and blood flow, the effects of adrenaline on CMRo2 and CBF resembling those observed in status epilepticus.
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PMID:Influence of intravenously administered catecholamines on cerebral oxygen consumption and blood flow in the rat. 69 50

The possible role of systemic physiological changes (occurring secondarily during status epilepticus) in the causation of epileptic brain damage has been evaluated in rats. Animals were anaesthetized, paralysed and mechanically ventilated; sustained electrocortical seizure discharges were induced by the intravenous injection of bicuculline, 1.2 mg/kg. After two hours of seizure activity brains were fixed by perfusion for histology. Physiological variables were maintained within certain limits from the end of the initial seizure phase (approximate duration twenty minutes) until two hours after onset of seizure to provide six groups: (1) Standard: mean arterial pressure above 120 mmHg, no hypoxia or hypoglycaemia, rectal temperature close to 37 degrees C. (2) Moderate Hypotension: mean arterial pressure at 70-75 mmHg. (3) Severe Hypotension: mean arterial pressure at 50 mmHg. (4) Hypoxia: arterial oxygen tension at 50 mmHg. (5) Hypoglycaemia: non-fed animals, with blood glucose close to 3.0 mumol/g. (6) Hyperthermia: rectal temperature at 40 degrees C. Microvacuolation and ischaemic cell change were identified by light microscopy in scattered neurons in the cortex (principally in the outer layers) in animals in three groups (Standard, Severe Hypotension and Hyperthermia). Similar neuronal changes were seen in the hippocampus (predominantly in the h1 or Sommer sector) in the Standard and Hyperthermia Groups. It is tentatively proposed that neuronal damage in animals with unrestricted cerebral oxygen and glucose availability is due to oxidative mechanisms in cells with excessively enhanced neuronal activity and that lesions caused by failing energy production do not appear until severe degrees of hypoxia are reached.
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PMID:Epileptic brain damage: the role of systemic factors that modify cerebral energy metabolism. 73 25

Positron emission tomography allows an in vivo assessment of various physiological and biochemical processes, for example cerebral blood flow, metabolism, or interactions between ligands and receptors. Data quantification and interpretation rest on models describing in a simple way the behavior of the labelled molecules. The general principles are common, but each model has limitations. The different methods are first validated in and applied to normal populations under resting conditions. New techniques for rapid assessments of blood flow and metabolism make it possible to measure cerebral activation after sensori-motor, mental or pharmacological stimulation. This should allow the study of recovery or plasticity of the lesioned brain, after a stroke for example. PET measurements of cerebral blood flow, oxygen consumption and extraction, and cerebral blood volume are particularly well suited to investigate the physiopathology of cerebrovascular diseases. Remote metabolic disturbances give information on interregional cerebral connections, and on clinico-metabolic correlations. In epilepsy, PET is useful in localizing the epileptogenic focus in partial epilepsy: it is hypometabolic interictally. The meaning of the hypometabolism has still to be established. New information about the neurochemistry of the epileptogenic focus should become available from studies of benzodiazepine, excitatory amino acid or opiate systems, for example. PET has already enabled pathophysiological hypotheses to be tested in status epilepticus. Disturbances of metabolism and neurotransmission systems have been observed at various stages and in various types of neurodegenerative diseases. The modifications are not only an early reflection of anatomopathological lesions, but could give more direct information on the pathogenesis or symptomatology of these diseases and hence lead to new therapeutic endeavours, such as appropriate replacement therapy analogous by to dopatherapy in Parkinson's disease.
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PMID:[Functional metabolic neuroimaging by positron-emission tomography in man]. 223 91

In this chapter, the pathophysiology and neurochemical pathology of epileptic brain damage is discussed on the basis of an integrative approach in which a comparison is made to cell necrosis resulting from ischemia and hypoglycemia. Two main questions are asked. First, is the brain damage resulting from these three disorders of cerebral energy metabolism similar in distribution and structural characteristics, as previously proposed? Second, is it possible to identify one or several neurochemical events, at the cellular and subcellular level, that qualify as the final common pathways leading to neuronal necrosis? A related question is, will seizures cause structural damage even if they do not critically curtail cellular oxygen supply? A review of the literature and of recent results obtained in animals with long-term recovery following status epilepticus of known duration suggests that although brain damage caused by epilepsy shows some similarities to that incurred due to ischemic and hypoglycemic insults, it is far from identical. In well oxygenated animals with an adequate cardiovascular function, 2 hr of status epilepticus causes moderate neuronal necrosis in the cerebral cortex (layers 3-4), the hippocampus (CA4 and CA1 pyramidal cells), and the thalamus (ventromedial nuclei). In rats, status epilepticus of 30 min duration or longer invariably causes infarction of the substantia nigra (pars reticularis), with some affectation of globus pallidus as well. Notably, CA3 pyramids and dentate neurons are spared, as is the pars compacta of the substantia nigra. Neurochemical events in ischemia, hypoglycemia, and status epilepticus show some striking dissimilarities, yet all three conditions lead to neuronal necrosis. In complete or near-complete ischemia, in which metabolic rate virtually ceases; deterioration of tissue energy state is rapid and extensive, with dramatic loss of ion homeostasis; cellular redox systems are reduced; and acidosis is marked to excessive. In hypoglycemic coma, oxygen consumption continues, albeit at a reduced rate; loss of high energy phosphates is extensive but less than complete, as is loss of ion homeostasis; cellular redox system become oxidized; and acidosis is absent. In epileptic seizures, finally, metabolic rate is markedly enhanced; perturbation of tissue energy state and of ion homeostasis is minimal to small; and acidosis is moderate. Results obtained in experimental animals suggest that neuronal necrosis, when incurred, is unrelated to energy failure and occurs in spite of adequate cellular oxygenation. Four neurochemical events are common to all three conditions discussed.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:Epileptic brain damage: pathophysiology and neurochemical pathology. 287 25

Positron emission tomography with the oxygen-15 steady state or bolus inhalation technique was used to provide quantitative values of regional cerebral blood flow (CBF), oxygen extraction ratio (OER) and oxygen consumption (CMRO2) in 25 patients with partial complex seizures during the interictal state and in 5 patients during status epilepticus. Glucose utilization (CMRglu) was also studied in one case of status epilepticus with the 18F-fluorodeoxyglucose technique (18FDG). Interictal scans showed zone(s) of hypoperfusion and hypometabolism without significant variation of the OER in approximately 80% of patients. In 62%, there was a strong correlation between the overall EEG localization and the area(s) of hypoperfusion and hypometabolism. In all cases, ictal scans revealed a focal or multifocal increase in CBF and CMRO2. The localization of the most affected regions correlated well with the spatial distribution of the electroencephalograph (EEG) abnormalities. Comparison of the different values of CBF, CMRO2, and OER showed that the increase in perfusion always exceeded that of oxygen consumption and hence was accompanied by a significant decrease of OER; the latter was always the most prominent in the region of the epilepticus focus determined by serial EEG recordings. These results showed that the supply of oxygen by blood flow is large enough to meet metabolic demand. When comparing these values with CMRglu, it appeared that the relative changes in CMRglu and CBF were very similar, indicating that the increase in blood flow correlated with the enhancement in glucose utilization. The observed imbalance between blood flow, glucose utilization, and oxygen consumption could suggest that an impairment of oxygen utilization by the mitochondria could occur in the epileptic focus during prolonged status epilepticus.
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PMID:Regional cerebral blood flow and metabolic rates in human focal epilepsy and status epilepticus. 308 38

Cerebral blood flow was sequentially determined (every 2-3 min) with helium clearance in two "vulnerable" structures: the hippocampus and the frontoparietal cortex during bicuculline (n = 11) and kainic acid (n = 9)-induced seizures in unanaesthetized, spontaneously breathing rats. Tissue partial pressures of oxygen and carbon dioxide were continuously and simultaneously evaluated in the same brain areas. All these variables were measured by mass spectrometry with a single gas sampling cannula previously implanted in each structure. The systemic variables, arterial blood pressure, arterial partial pressures of oxygen and carbon dioxide, pH, and bicarbonate concentration were also determined. Arterial and venous catheters were chronically implanted several days prior to the definitive experiments. Bicuculline induced short (about 15 min), recurrent, generalized seizures, with an abrupt rise in arterial blood pressure, an arterial metabolic acidosis and comparable blood flow increases (4-fold) in the hippocampus and the neocortex. A marked increase in tissue partial pressure of oxygen was always preceded by an increase in tissue partial pressure of carbon dioxide. After the seizures, in the 5 rats that survived, cerebral blood flow was significantly lowered; tissue partial pressure of oxygen and partial pressure of carbon dioxide also decreased, but to a lesser extent. Histological examination revealed two types of lesions: predominantly selective chromatolysis but also ischaemic cell change. Kainic acid first induced a decrease in arterial pressure and then hypertension during status epilepticus, with a return of arterial pressure towards basal levels during the recovery period (4 h after the injection). Respiratory alkalosis occurred throughout the experiment. Cerebral blood flow increased progressively to become maximal during status epilepticus. This vasodilatation was greater in the hippocampus (x 8) than in the neocortex (x 4). During recovery, cerebral blood flow tended to decrease but remained significantly elevated. In both structures, tissue partial pressure of oxygen was first lowered while tissue partial pressure of carbon dioxide was elevated; with the occurrence of the wet dog shakes, tissue partial pressure of O2 increased and tissue partial pressure of CO2 decreased. The changes in tissue gases were maximal during status epilepticus and tended to return to their basal levels thereafter, but no decrease in tissue partial pressure of O2 was observed, even 4 h after kainic acid administration. Histological analysis demonstrated ischaemic cell changes, particularly in the limbic system.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:Continuous determination of the cerebrovascular changes induced by bicuculline and kainic acid in unanaesthetized spontaneously breathing rats. 312 92

Positron Emission Tomography (PET) with the oxygen-15 steady state inhalation technique was used to provide quantitative values of regional cerebral blood flow (CBF), oxygen consumption (CMRO2) and oxygen extraction ratio (OER) in 25 patients with partial complex seizures during the interictal state, in 1 patient with recurrent temporal seizures and in 3 patients whose EEGs were characterized by periodic lateralized epileptiform discharges (PLEDs). Interictal scans showed temporal zone(s) of hypoperfusion and hypometabolism in 80% of patients with normal X-ray CT Scan. In all cases, ictal scans revealed a focal or multifocal increase in CBF and CMRO2. The localization of the most affected regions correlated well with the spatial distribution of the EEG abnormalities. Comparison of the different values of CBF, CMRO2 and OER showed that the increase in perfusion always exceeded that of oxygen consumption and hence was accompanied by a significant decrease in OER, the latter was always the most prominent in the region of the focus determined by serial EEG recordings. The observed imbalance between blood flow and oxidative glucose metabolism could suggest an impairment of O2 utilization by the mitochondria in the epilepticus focus during seizures or status epilepticus.
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PMID:[Study of cerebral metabolism and blood flow in partial complex epilepsy and status epilepticus in man using positron emission tomography]. 349 37


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