Acute pancreatitis with rapid clinical improvement in a child with isovaleric acidemia.

Isovaleric acidemia is a rare branched-chain organic acidemia. The authors describe a 3.5-year-old girl with isovaleric acidemia and acute abdominal pain associated with bilious emesis. Elevated serum amylase and abdominal ultrasonography demonstrating an enlarged and edematous pancreas, along with the presence of peripancreatic exudates, confirmed the presence of acute pancreatitis. The patient recovered quickly with intravenous hydration, pancreatic rest, and administration of intravenous L-carnitine. Pancreatitis should be ruled out in the context of vomiting in any patient with isovaleric acidemia. Conversely, branched-chain organic acidemias should be included in the differential diagnosis of any child with pancreatitis of unknown origin.

Anticonvulsant hypersensitivity syndrome closely mimicking Kawasaki disease.

Anticonvulsant hypersensitivity syndrome (AHS) is an acute, life-threatening, idiosyncratic drug reaction seen within 1-8 weeks after administration of an aromatic antiepileptic drug. The authors present the case of a 16-month-old boy who developed prolonged fever, a generalised pruritic rash and eosinophilia within 4 weeks after starting treatment with phenobarbital for complicated febrile seizures. He gradually fulfilled the diagnostic criteria for classical Kawasaki disease (KD), although the rash and the subsequent desquamation were atypical, he did not defervesce quickly with administration of corticosteroids and intravenous γ-globulin, and he had only two suggestive cardiac features of KD-that is, perivascular echogenicity of the coronary arteries and a small pericardial effusion. Other conditions considered in the differential diagnosis were excluded by appropriate extensive serological and microbiological studies. He recovered fully. This report shows that drugs such as phenobarbital may be responsible for febrile exanthematous illnesses that closely mimic KD.

Carnitine deficiency in children and adolescents with type 1 diabetes.

Carnitine is essential for the lipid and carbohydrate metabolism, and proper metabolic control in type 1 diabetes has potential impact on long-term complications. The plasma total, free, and acylcarnitine levels in 47 children and adolescents with type 1 diabetes were determined by a radioisotopic assay and compared to the values of a series of anthropometric measurements and metabolic parameters, including blood glycosylated hemoglobin Alc, serum cholesterol and triglycerides, and urine microalbumin levels. Plasma values for total, free, and acylcarnitine were 30.1+/-7.26, 20.0+/-4.50, and 10.2+/-6.47 micromol/l, respectively. Acyl/free carnitine ratio was 0.544+/-0.369. Individuals with type 1 diabetes had significantly lower total and free carnitine levels and significantly higher acyl/free carnitine ratios than controls (P<.001). Plasma total and free carnitine levels were inversely correlated to the duration of diabetes (P=.036 and P=.071, respectively). No statistical relationship was documented between carnitine levels and the remaining anthropometric and metabolic variables. In conclusion, total and free carnitine levels are decreased in children and adolescents with type 1 diabetes. This reduction is time related and may have potential interactions with the long-term complications of type 1 diabetes. Larger studies are required for final conclusions to be drawn on the precise role of carnitine and the possible benefit, if any, of carnitine supplementation in diabetic patients.

Early events of the exogenously provided L-Carnitine in murine macrophages, T- and B-lymphocytes: modulation of prostaglandin E1 and E2 production in response to arachidonic acid.

L-carnitine is an essential energy-providing compound to the cell since it transports long chain fatty acids through the mitochondrial membrane and delivers them to the beta-oxidation pathway for catabolism and/or entrance to biosynthetic pathways. Some of the early events taking place in immune cells after L-carnitine inoculation in vitro are defined in this report. Using arachidonic acid as a fatty acid source, we determined the utilization rate of L-carnitine by murine T-, B-lymphocytes and macrophages within two hours of cell culture, its effect on prostaglandin E1 and E2 production and the levels of beta-hydroxy-butyrate. The results show that although all immune cells consume a small portion of L-carnitine, beta-hydroxy-butyrate decreases upon addition of arachidonic acid and/or L-carnitine indicating that active biosynthetic pathways are induced. L-carnitine is shown to increase the arachidonic acid-induced production of prostaglandins E1 and E2 in macrophages, while their secretion from T- and B-lymphocytes is decreased. These findings indicate the L-carnitine may very rapidly alter the activation state of immune cells and lead to the development of various reactions, beneficial or not to the organism.