The syndrome of systemic carnitine deficiency

Karpati, George; Carpenter, Stirling; Engel, Andrew G.; Watters, Gordon V.; Allen, Jeffrey C.; Rothman, Stanley; Klassen, Gerald A.; Mamer, Orval

doi:10.1212/wnl.25.1.16

Cited by 375 publications

(51 citation statements)

References 3 publications

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“…Ala, alanine ALT, alanine aminotransferase AST, aspartate aminotransferase CPK, creatine kinase hGH, human growth hormone LA, left atrium LPEP/LVET, left pre-ejection period/left ventricular ejection time P-OHB, beta-hydroxybutyrate RPEP/RVET, right pre-ejection period/right ventricular ejection time LVED, left ventricular end diastolic dimension LVES, left ventricular end systolic dimension MCT, medium chain triglyceride PC, pyruvate carboxylase PEPCK, phosphoenol phosphate carboxykinase U, units Hepatic long-chain acyl CoA carnitine transferase deficiency (4), multiple acyl CoA dehydrogenase deficiency (glutaric aciduria type 11) (18), and systemic carnitine deficiency (3,9,12,17,24,37,43), all of which are associated with impaired fatty acid oxidation, have hypoglycemia as a major clinical manifestation.…”

Section: Abbreviationsmentioning

confidence: 99%

Hypoglycemia, Hepatic Dysfunction, Muscle Weakness, Cardiomyopathy, Free Carnitine Deficiency and Long-Chain Acylcarnitine Excess Responsive to Medium Chain Triglyceride Diet

et al. 1983

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SummaryFraternal twins who had fasting hypoglycemia, hypoketonemia, muscle weakness, and hepatic dysfunction are reported. The hepatic dysfunction occurred only during periods of caloric deprivation. The surviving patient developed a cardiomyopathy. In this sibling, muscle weakness and cardiomyopathy were markedly improved by a diet high in medium chain triglycerides. There was a marked deficiency of muscle total carnitine and a mild deficiency of hepatic total carnitine. Unlike patients with systemic carnitine deficiency, serum and muscle long-chain acylcarnitine were elevated and renal reabsorption of carnitine was normal. It was postulated that the defect in long-chain fatty acid oxidation in this disorder is caused by an abnormality in the mitochondria1 acylcarnitine transport.Detailed studies of the cause of the hypoglycemia revealed that insulin, growth hormone, cortisol, and glucagon secretion were appropriate and that it is unlikely that there was a major deficiency of a glycolytic or gluconeogenic enzyme. Glucose production and alanine conversion to glucose were in the low normal range when compared to normal children in the postabsorptive state. The hypoglycemia in our patients was probably due to a modest increase in glucose consumption, secondary to the decreased oxidation of fatty acids and ketones, alternate fuels which mare glucose utilization, plus a modest decrease in hepatic glucose production secondary to decreased available hepatic energy substrates. AbbreviationsAla, alanine ALT, alanine aminotransferase AST, aspartate aminotransferase CPK, creatine kinase hGH, human growth hormone LA, left atrium LPEP/LVET, left pre-ejection period/left ventricular ejection time P-OHB, beta-hydroxybutyrate RPEP/RVET, right pre-ejection period/right ventricular ejection time LVED, left ventricular end diastolic dimension LVES, left ventricular end systolic dimension MCT, medium chain triglyceride PC, pyruvate carboxylase PEPCK, phosphoenol phosphate carboxykinase U, units Hepatic long-chain acyl CoA carnitine transferase deficiency (4), multiple acyl CoA dehydrogenase deficiency (glutaric aciduria type 11) (18), and systemic carnitine deficiency (3,9,12,17,24,37,43), all of which are associated with impaired fatty acid oxidation, have hypoglycemia as a major clinical manifestation.The purpose of this paper is twofold: (1) to report fraternal twins with free carnitine deficiency and long-chain acylcarnitine excess in whom hypoglycemia, hepatic dysfunction, muscle weakness, and in the surviving patient cardiomyopathy were major problems and (2) to discuss results of studies to evaluate the etiology of the disorder. CASE REPORTSPatient I . The patient was the 1.8-kg product of 7% month uncomplicated twin pregnancy. He did well until 9 months of age. After a respiratory infection (parainfluenza 3 virus recovered from nasopharynx), he developed an illness characterized by vomiting, listlessness, and hypotonia. Progressive hepatomegaly (span 6 cm on admission, span 12 cm, 2 wk later) and more abnormal liver functi...

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Section: Abbreviationsmentioning

confidence: 99%

Hypoglycemia, Hepatic Dysfunction, Muscle Weakness, Cardiomyopathy, Free Carnitine Deficiency and Long-Chain Acylcarnitine Excess Responsive to Medium Chain Triglyceride Diet

et al. 1983

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“…Carnitine is involved in the transport of long-chain fatty acids across the mitochondrial membrane so that they can undergo oxidation. In deficiency states in which carnitine levels are very low (<10% normal levels) hepatic steatosis can develop (35) . Although plasma carnitine levels are low in patients receiving parenteral nutrition, they are about 50% normal levels and so considerably higher than levels in patients with congenital or acquired deficiency (30,31,35) .…”

Section: Nutrient Deficiencymentioning

confidence: 99%

“…In deficiency states in which carnitine levels are very low (<10% normal levels) hepatic steatosis can develop (35) . Although plasma carnitine levels are low in patients receiving parenteral nutrition, they are about 50% normal levels and so considerably higher than levels in patients with congenital or acquired deficiency (30,31,35) . There is limited evidence to suggest an inverse relationship between carnitine levels and ALP in patients receiving parenteral nutrition (36) .…”

Section: Nutrient Deficiencymentioning

confidence: 99%

Managing liver dysfunction in parenteral nutrition

Lloyd

Gabe

2007

Proc. Nutr. Soc.

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Parenteral nutrition is life saving in patients with intestinal failure but liver dysfunction is commonly encountered, especially in neonates. Although abnormal liver function tests associated with short-term parenteral nutrition are usually benign and transient, liver dysfunction in both children and adults receiving long-term parenteral nutrition can progress to end-stage liver disease and liver failure. The aetiology of parenteral nutrition-associated liver disease is complex and multifactorial, with a range of patient, disease and nutrition-related factors implicated. Sepsis is of particular importance, as is the lack of enteral nutrition and overfeeding with intravenous glucose and/or lipid. Deficiencies of a number of amino acids including choline and taurine have also been implicated. Management of hepatic dysfunction in parenteral nutrition should initially focus on preventing its occurrence. Sepsis should be managed appropriately, enteral nutrition should be encouraged and maximised where possible and parenteral overfeeding should be avoided. Provision of parenteral lipid should be optimised to prevent the adverse effects of both deficiency and excess, and cyclical rather than continuous parenteral feeding should be administered. There is some evidence of benefit in neonates from oral antibiotics to prevent intestinal bacterial overgrowth and from oral ursodeoxycholic acid, but less to support their use in adults. Similarly, data to support widespread use of parenteral choline or taurine supplementation are lacking at present. Ultimately, severe parenteral nutrition-associated liver disease may necessitate referral for small intestine and/or liver transplantation.

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“…In primary carnitine deficiency, in which tissue concentrations may fall to 10% to 20% of normal, fatty liver is a common clinical finding. 65 In secondary carnitine deficiency, abnormally low concentrations of carnitine, albeit not as low as those present in primary carnitine deficiency, occur secondary to defects in intermediary metabolism, certain diseases, drug reactions, and impaired nutritional conditions such as kwashiorkor. 66,67 Because the major sources of carnitine come from de novo synthesis from the essential amino acids lysine and methionine, as well as from dietary sources such as meats and dairy products, low carnitine concentrations in kwashiorkor are probably related to deficient protein intake.…”

Section: Kwashiorkor and Protein Calorie Malnutritionmentioning

confidence: 99%