Carnitine deficiency presenting as familial cardiomyopathy: A treatable defect in carnitine transport (original) (raw)
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Chronic cardiomyopathy and weakness or acute coma in children with a defect in carnitine uptake
Annals of Neurology, 1991
A defect in intracellular uptake of carnitine has been identified in patients with severe carnitine deficiency. To define the clinical manifestations of this disorder, the presenting features of 15 affected infants and children were examined. Progressive cardiomyopathy, with or without chronic muscle weakness, was the most common presentation (median age of onset, 3 years). Other patients presented with episodes of fasting hypoglycemia during the first 2 years of life before cardiomyopathy had become apparent. A defect in carnitine uptake was demonstrable in fibroblasts and leukocytes from patients. The defect also appears to be expressed in muscle and kidney. Concentrations of plasma carnitine and rates of carnitine uptake in parents were intermediate between affected patients and normal control subjects, consistent with recessive inheritance. Early recognition and treatment with high doses of oral carnitine may be life-saving in this disorder of fatty acid oxidation.
Carnitine Membrane Transporter Deficiency: A Rare Treatable Cause of Cardiomyopathy and Anemia
Pediatric Cardiology, 2008
Carnitine transporter defect is an autosomal recessive disorder caused by mutations in the SLC22A5 gene that encodes the high-affinity carnitine transporter OCTN2. Affected patients can present with predominant metabolic or cardiac manifestations. Early recognition of this disorder in a context of life-threatening cardiac failure and treatment with carnitine can be lifesaving in this inborn error of fatty acid oxidation. Here we describe a boy with a severe cardiomyopathy and severe anemia who improved with carnitine therapy. Physiopathology of anemia, a probably less recognized symptom of carnitine deficiency, is also discussed.
Pediatric Research, 1990
Evidence is emerging that primary systemic carnitine deficiency, a potentially lethal but eminently treatable inborn error of fatty acid oxidation, involves a cellular defect in the uptake of carnitine. We present four unrelated children with primary carnitine-responsive cardiomyopathy, weakness (with or without hypoketotic hypoglycemic encephalopathy), low serum and/or tissue carnitine concentrations, and severe renal carnitine leak. Dicarboxylic acids were absent in the urine of three children who were tested, and all four had a rapid and dramatic improvement in cardiac function, strength, and somatic growth after carnitine therapy. We studied carnitine uptake in cultured skin fibroblasts from all four children and seven of the eight healthy nonconsanguinous parents.
Primary carnitine deficiency is a life‐long disease
JIMD Reports
Primary carnitine deficiency is a rare autosomal recessive disease associated with acute hypoketotic hypoglycaemia, cardiomyopathy and sudden cardiac death. Effective treatment with carnitine supplementation is available. An 18 months old boy, who presented with cardiomyopathy was diagnosed with primary carnitine deficiency, and carnitine supplementation resulted in a full recovery. At age 13 years, he discontinued his medication and at 20 years, he discontinued clinical monitoring. Nine years later, age 29, he presented with heart failure and atrial fibrillation and was admitted to an intensive care unit, where he was treated with furosemide, enoximone and intravenous carnitine supplementation, this lead to improved cardiac function within 2 weeks, and with continued oral carnitine supplements, his left ventricular ejection fraction normalised. The last 8 years were uneventful and he continued to attend his regular follow‐up visits at a specialised metabolic outpatient clinic. We r...
Carnitine deficiency-induced cardiomyopathy
Molecular and cellular biochemistry, 1998
The results of clinical and animal studies suggest that a short term period of moderate secondary carnitine deficiency, in and of itself, does not have a major effect on the cardiac contractile function, although substrate oxidation may be altered. However, with longer durations of carnitine deficiency, alterations occur within the heart that may result in impaired contractile performance, particularly at high workloads. At this point, the mechanisms responsible for the cardiac depression are uncertain. We hypothesize that the alterations in substrate metabolism produced by the carnitine deficient state results in inadequate ATP production under high workload conditions which result in impaired cardiac contractile performance. Carnitine deficiency may also induce a number of changes in gene expression of key enzymes required for normal cardiac contractile function and metabolism.
The Syndrome of Carnitine Deficiency: Morphological and Metabolic Correlations in Two Cases
Canadian Journal of Neurological Sciences / Journal Canadien des Sciences Neurologiques, 1978
SUMMARY:Two cases of systemic carnitine deficiency are described. In both patients, carnitine concentration was lower than normal in serum and muscle tissue. In the first case, the illness began at age 35; the clinical manifestations were only muscular. In the second case, the illness began in childhood; there were intermittent episodes of hepatic enlargement and coma. An excessive lipid content was present in muscle tissue, especially in type I fibers, of both cases, and in the liver of the second patient. Ultrastructural studies of muscle tissue revealed important changes of mitochondria.During muscular exercise, aerobic and anaerobic metabolism were in vestigated. For a given relative work intensity, these patients showed abnormally high blood lactic acid concentration and lactic acid/pyruvic acid ratios. These data, together with the morphological alterations observed in mitochondria, suggest an impaired function of the respiratory chain, leading to a shift of the red/ox potenti...
Primary Carnitine Deficiency – A Rare Treatable Cause of Cardiomyopathy and Massive Hepatomegaly
Indian Journal of Pediatrics, 2016
Systemic primary carnitine deficiency (CDSP) is a rare autosomal recessive disorder caused by a defect in plasma membrane uptake of carnitine due to SLC22A5 gene mutations. A nine-mo-old boy presented with hypertrophic cardiomyopathy, massive hepatomegaly and jaundice. Metabolic testing revealed very low free carnitine levels. Genetic analysis using Sanger sequencing method revealed compound heterozygous mutations in SLC22A5 gene, c. 1354 G > A (p. Glu452Lys, previously reported) and c.231_234del (novel frame-shift). Oral carnitine supplementation resulted in improved clinical outcome with ejection fraction to 75 % and normalization of liver size and enzymes after 3 mo.
Jornal de Pediatria, 2005
Objectives: Malnutrition is an independent predictor of death in idiopathic dilated cardiomyopathy. An analysis was performed of the impact of L-carnitine supplementation on the nutritional status and echocardiogram parameters of children with idiopathic dilated cardiomyopathy. Methods: This was an open label cohort of 11 patients who received L-carnitine (100 mg/kg/day) plus the conventional medical treatment, compared with 40 controls, matched for gender and age. The L-carnitine group was weighed 118 times and the controls 264 times. Additionally, the L-carnitine group underwent 65 two-dimensional echocardiograms and the controls 144. Chi-square, Students t test, Pearson correlation and ANOVA were calculated with alpha = 0.05. Results: For the L-carnitine group: age at presentation = 3.82 years old, 72.7% (p = 0.033) were females younger than 2 years and 90.9% (p = 0.0001) were in functional classes III and IV. There were no deaths during this period. At presentation, no differences were observed in weight percentile (31.2±8.74 vs. 19.6±21.2) (p = 0.29) or z score (-0.68±1.05 vs. 1.16±0.89) (p = 0.24). Increases were observed in both the percentile (p = 0.026) and z score (p = 0.033) after the introduction of L-carnitine. At presentation, there were no differences in ejection fraction (54.9%±3.8 vs. 49.3%±6.6) (p = 0.19), but LV mass/BSA were greater in the L-carnitine group (169.12 g/m 2 ±26.24 vs. 110.67 g/m 2 ±15.62) (p = 0.0005). After the introduction of L-carnitine an increase in ejection fraction (48.3±7 to 67.2±7) (p = 0.044) was observed. LV mass/BSA decreased (164.29 g/m 2 ±28.14 to 110.88 g/m 2 ±28.88), but without significance (p = 0.089) Conclusion: In children with idiopathic dilated cardiomyopathy, supplementation of L-carnitine may be helpful for nutritional and echocardiographic improvement.