Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UMLS:C0024591 (malignant hyperthermia)
 2,353 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

A 51-year-old male patient with no history of musculo-skeletal or myopathic abnormalities, but suffering from manic-depressive psychosis, attempted suicide with an overdose of dolpersin hydrochloride (Mydocalm), dipenzepine hydrochloride (Noveril), meprobamate (Mepronox) and nitrazepam (Mogadon). He developed high fever, muscle rigidity, tachycardia, arrhythmias, hypotension and mottled cyanosis, symptoms well-known in persons with malignant hyperthermia, an autosomally inherited disease of skeletal muscle. There is also discussed the manifestation and the symptoms of an acute rhabdomyolysis. The diagnosis was confirmed by chemical pathological laboratory findings, including respiratory and metabolic acidosis, myoglobinaemia accompanied by myoglobin diuresis, and elevated creatine phosphokinase (CPK values up to 2790 U/l). Electron microscopic examination of muscle tissue revealed signs of myolysis and mitochondrial reactions with pleoconic hyperplasia. No inhalation anaesthetics or skeletal muscle relaxants, such as succinyl choline, were used in this case. Therefore, malignant hyperthermia might have been induced by a combination of drugs which were not known to induce this abnormal muscular reaction. However, the muscle relaxant effect of dolpersin hydrochloride may have acted as a possible inducer of the attack.
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PMID:[Possible malignant hyperthermia as reaction to an overdose of myotonolytic, antidepressive and sedative drugs (author's transl)]. 611 87

A 17-year-old male received general anesthesia for repair of a torn right knee anterior cruciate ligament. The medical history revealed manic-depressive psychosis, treated with lithium carbonate and sertraline hydrochloride, and asthma for which the patient occasionally used an albuterol inhaler. Induction with propofol, isoflurane, nitrous oxide, and oxygen was uneventful. Anesthesia was maintained by isoflurane, nitrous oxide, and oxygen. During the first 90 minutes after induction, a persistent mild elevation in end-tidal carbon dioxide was noted, and several possible causes for this elevation were subsequently ruled out. A diagnosis of malignant hyperthermia was made when the patient exhibited tachycardia and a temperature increase, although some discussion remained regarding the possibility of neuroleptic malignant syndrome. The patient was treated successfully using a malignant hyperthermia protocol. Malignant hyperthermia may prove fatal if effective treatment is delayed. Favorable outcome and patient prognosis rely on astute vigilance, accurate diagnosis, and swift, appropriate treatment.
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PMID:Differential diagnosis of malignant hyperthermia: a case report. 892 98

Cellular Ca(2+)-dysregulation has been proposed as an important mechanism in certain diseases such as bipolar affective disorder (BPAD) and malignant hyperthermia. Recently it has been found that in BPAD, the plasma membrane Ca(2+)-channel blockers verapamil and nimodipine are useful substitutes in Li(+)-treatable patients. We have investigated the effects of these drugs and the antipsychotic drugs (clozapine, fluspirilene, and haloperidol) on IP3-induced Ca(2+)-release from Ca(2+)-loaded rat brain microsomes. In the presence of either the Ca(2+)-channel blockers or the neuroleptic drugs, Ca(2+)-release was blocked in a dose-dependent fashion. For the neuroleptics, the EC50 ranged from 22 microM for fluspirilene to 145 microM for haloperidol. The EC50 for nimodipine was 160 microM and 450 microM for verapamil. Carbamazapine and valproic acid, anticonvulsants recently used for treating BPAD, were relatively ineffective, as were various haloperidol metabolites. The research described in this paper establishes for the first time that antipsychotic drugs, as well as certain Ca(2+)-channel blockers, directly block the IP3-induced Ca(2+)-release in a rat brain microsome assay.
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PMID:Antipsychotic drugs block IP3-dependent Ca(2+)-release from rat brain microsomes. 887 69

Many important aspects of our life are regulated by the free cytosolic Ca2+ concentration. The intracellular Ca2+ signal is regulated both in space, frequency and amplitude. Each cell chooses a unique set of Ca2+ signals to control its function. Ca2+ signal transduction is based on rises in free cytosolic Ca2+ concentration. Ca2+ can come from the extracellular space or be released from intracellular stores. Extracellular Ca2+ enters the cell through various types of plasma-membrane Ca2+ channels and leaves the cell using Ca2+ pumps and Na+/Ca(2+)-exchangers. Ca2+ is accumulated in intracellular stores by means of Ca2+ pumps and is released via inositol 1,4,5-trisphosphate (IP3) and ryanodine receptors. Mutations or abnormalities in one of the above mentioned Ca(2+)-transporting proteins can lead to disease. Skeletal-muscle pathology can be caused by abnormal ryanodine receptors (malignant hyperthermia, porcine stress syndrome, central core disease), plasma-membrane Ca2+ channels (hypokalemic periodic paralysis, muscular dysgenesis mice, paraneoplastic Lambert-Eaton myasthenia syndrome) or Ca2+ pumps (Brody disease). Neurologic disorders can be related to altered function of plasma-membrane Ca2+ channels (episodic ataxia type 2, spinocerebellar ataxia type 6, familial hemiplegic migraine, glutamate excitotoxicity, tottering, leaner, lethargic and stargazer mice), IP3 receptors (Lowe's oculocerebrorenal syndrome, manic depression, Alzheimer's disease, opisthotonos mice) and Ca2+ pumps (deafwaddler mouse and wriggle mouse sagami). Two skin diseases are caused by Ca(2+)-pump mutations (Darier disease and Hailey-Hailey disease). Incomplete X-linked congenital stationary night blindness is caused by a mutation in the plasma-membrane Ca2+ channels in rods and cones.
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PMID:[Intracellular calcium: physiology and physiopathology]. 1119 78