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Target Concepts:
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Query: UMLS:C0024591 (
malignant hyperthermia
)
2,353
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Many physiological processes depend upon the proper functioning of plasma membrane ion channels. This is most apparent in absorptive and secretory epithelia, and in electrically excitable tissues such as nerve and muscle. Disturbances in the operation of ion channels in these settings can alter normal physiology and cause disease. This review illustrates the use of molecular genetics in identifying hereditary diseases caused by mutations in genes which encode various skeletal muscle ion channels. Recent advances in the discovery of genetic mutations in the skeletal muscle voltage-gated sodium channel in certain forms of periodic paralysis, mutations in the skeletal muscle
chloride channel
gene in myotonia congenita, and defects in two distinct calcium channels that underlie disorders of excitation-contraction coupling (murine muscular dysgenesis,
malignant hyperthermia
susceptibility) will be presented. In each case, prior knowledge of abnormal ion channel function prompted the search for mutations in candidate genes. This work is beginning to shed new light on the relationship between ion channel structure and function by studies of naturally occurring channel mutations.
...
PMID:Molecular genetics of ion channel diseases. 856 79
Recent advances in the field of molecular myology have provided significant insight into the pathological mechanisms underlying a variety of neuromuscular disorders. Genetic abnormalities can now be linked to primary and secondary pathophysiological changes in muscle fibres which compromise structural, metabolic, regulatory or contractile mechanisms. Ion channel myopathies such as paramyotonia congenita, hyper- and hypokalaemic periodic paralysis, myotonia congenita, episodic ataxia and
malignant hyperthermia
were established as linked to mutations in genes encoding the sodium channel, dihydropyridine receptor,
chloride channel
, potassium channel and the ryanodine receptor calcium release channel, respectively. Metabolic disorders affecting skeletal muscle were found to be due to deficiencies in a variety of enzymes. Identification of defects in components belonging to the gigantic dystrophin-glycoprotein complex led to the discovery of the molecular pathogenesis of Duchenne muscular dystrophy and related disorders. Based on these molecular findings, it is now feasible to design and evaluate new techniques such as gene and myoblast transfer therapy in order to replace defective components in diseased muscle fibres.
...
PMID:[Molecular pathogenesis of muscular diseases]. 903 37
Hereditary muscle channelopathies are caused by dominant mutations in the genes encoding for subunits of muscle voltage-gated ion channels. Point mutations on the human skeletal muscle Na+ channel (Nav1.4) give rise to hyperkalemic periodic paralysis, potassium aggravated myotonia, paramyotonia congenita and hypokalemic periodic paralysis type 2. Point mutations on the human skeletal muscle Ca2+ channel give rise to hypokalemic periodic paralysis and
malignant hyperthermia
. Point mutations in the human skeletal
chloride channel
CIC-1 give rise to myotonia congenita. Point mutations in the inwardly rectifying K+ channel Kir2.1 give rise to a syndrome characterized by periodic paralysis, severe cardiac arrhythmias and skeletal alterations (Andersen's syndrome). Involvement of the same ion channel can thus give rise to different phenotypes. In addition, the same mutation can lead to different phenotypes or similar phenotypes can be caused by different mutations on the same or on different channel subtypes. Bearing in mind, the complexity of this field, the growing number of potential channelopathies (such as the myotonic dystrophies), and the time and cost of the genetic procedures, before a biomolecular approach is addressed, it is mandatory to apply strict diagnostic protocols to screen the patients. In this study we propose a protocol to be applied in the diagnosis of the hereditary muscle channelopathies and we demonstrate that muscle biopsy studies and muscle cell cultures may significantly contribute towards the correct diagnosis of the channel involved. DNA-based diagnosis is now a reality for many of the channelopathies. This has obvious genetic counselling, prognostic and therapeutic implications.
...
PMID:Muscle biopsy and cell cultures: potential diagnostic tools in hereditary skeletal muscle channelopathies. 1268 54
Myotonia congenita (MC) is caused by a defect in the skeletal muscle
chloride channel
function, which may cause sustained membrane depolarisation. We describe a previously healthy 32-year-old woman who developed a life-threatening muscle spasm and secondary ventilation difficulties following a preoperative injection of suxamethonium. The muscle spasms disappeared spontaneously and the surgery proceeded without further problems. When subsequently questioned, she reported minor symptoms suggesting a myotonic condition. Myotonia was found on clinical examination and EMG. The diagnosis MC was confirmed genetically. Neither the patient nor the anaesthetist were aware of the diagnosis before this potentially lethal complication occurred. We give a brief overview of ion channel disorders including
malignant hyperthermia
and their anaesthetic considerations.
...
PMID:Anaesthetic complications associated with myotonia congenita: case study and comparison with other myotonic disorders. 1567 99
