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Query: UMLS:C0022716 (
Menkes
)
1,057
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Many metabolic diseases result in pathological changes within the cardiovascular system, often with the most severe effects on the function of the heart and great vessels. Metabolic disorders affecting the heart include disorders of amino acid metabolism, storage diseases, neuromuscular diseases, diseases of metal and pigment metabolism, carnitine deficiency, and connective tissue disorders. Several inborn errors of metabolism may involve the myocardium due to the accumulation of abnormal metabolites in the myocardial cells. In addition, the heart valves and coronary vessels may be involved. If the predominant effect is in the myocardial cell, it will be manifested clinically as a
cardiomyopathy
. Some disorders, in particular oxalosis, may involve the conduction system as a result of the deposition of oxalate crystals and result in conduction disturbances such as in alkaptonuria, primary oxalosis, and homocystinuria. Myocardial involvement may result in
cardiomyopathy
of the three functional types: (1) congestive, as in Fabry's disease, (2) hypertrophic, as in glycogen storage disease, type II, or (3) restrictive, as in Gaucher's disease. In the storage disease severe valvular as well as myocardial involvement occur predominantly in the glycogen storage diseases, types II-IV, mucolipidoses, sphingolipidoses, and neuronal ceroid lipofuscinosis. There are a variety of neuromuscular disorders that may be associated with
cardiomyopathy
, including the muscular dystrophies, Friedreich's ataxia, and Kugelberg-Welander syndrome. The pathological features of these conditions are not specific, but result usually in a congestive form of
cardiomyopathy
. Patients with metal and pigment metabolic disorders include iron storage disease, either hemochromatosis or transfusional hemosiderosis,
Menkes' kinky hair syndrome
, and Dubin-Johnson syndrome. Either a restrictive or a congestive form of
cardiomyopathy
may occur. The systemic form of carnitine deficiency is an autosomal recessive disorder and may present as a
cardiomyopathy
with congestive heart failure and lipid accumulation in the myocardial cells. Connective tissue disorders are generalized diseases that may involve the heart and valvular tissue, but also the blood vessels. These include Marfan's syndrome, Ehlers-Danlos syndrome, osteogenesis imperfecta, and pseudo-xanthoma elasticum.
...
PMID:The effects of metabolic diseases on the cardiovascular system. 333 40
Copper is an essential trace element and has profound influence on cardiac myopathy and heart metabolism. Dietary Cu restriction in rats results in
cardiomyopathy
, and affects the integrity of the basal lamina of cardiac myocytes and capillaries. Decreased levels of delta subunits of ATP synthetase and nuclear encoded subunits of cytochrome oxidase system have been observed. Alteration in expression of glutathione peroxidase and catalase in heart and liver in Cu deficiency (Cu-) has been noted involving both transcriptional and post transcriptional mechanisms. A short description of two genetically inherited disorders of Cu metabolism, i.e. Wilson's disease and
Menkes
' disease, and Indian childhood cirrhosis (environmental and/or genetic) have been included to illustrate that advances in the knowledge of Cu cellular transport gives a better understanding of the molecular basis of the pathophysiology of these diseases.
Menkes
' disease, a human model of defective Cu transport and Cu- has shown many pathological changes, similar to those of heart disease in Cu-. The recent cloning of four genes of putative Cu pumping ATPases (Cu-ATPases) from widely different sources, i.e. two from Enterococcus hirae and one each from Wilson's and
Menkes disease
patients (which are defective in Cu transport and metabolism), has opened a new chapter in the study of Cu cellular transport and metabolism. The encoded gene products, i.e. Cu-ATPases, show extensive homology and are members of a new class of ATP-driven Cu pumps involved in regulation of cellular Cu. Further, Cu transport by Cop B-ATPase (E. hirae) in membrane vesicles and in isolated rat liver plasma membrane has provided biochemical evidence of its role in ATP-driven Cu transport. In this short review I have critically examined the current evidence of the molecular basis of the pathophysiology of
cardiomyopathy
in Cu- and, have indicated the possible role of P-type Cu ATPase which may be one of the obligatory factors contributing to
cardiomyopathy
in experimental animals and probably humans. Experimental verification of this hypothesis will be the aim of future studies.
...
PMID:Copper deficiency and heart disease: molecular basis, recent advances and current concepts. 945 22
