Clinical aspects of short-chain acyl-CoA dehydrogenase deficiency.

Short-chain acyl-CoA dehydrogenase deficiency (SCADD) is an autosomal recessive inborn error of mitochondrial fatty acid oxidation. SCADD is biochemically characterized by increased C4-carnitine in plasma and ethylmalonic acid in urine. The diagnosis of SCADD is confirmed by DNA analysis showing SCAD gene mutations and/or variants. SCAD gene variants are present in homozygous form in approximately 6% of the general population and considered to confer susceptibility to development of clinical disease. Clinically, SCADD generally appears to present early in life and to be most frequently associated with developmental delay, hypotonia, epilepsy, behavioral disorders, and hypoglycemia. However, these symptoms often ameliorate and even disappear spontaneously during follow-up and were found to be unrelated to the SCAD genotype. In addition, in some cases, symptoms initially attributed to SCADD could later be explained by other causes. Finally, SCADD relatives of SCADD patients as well as almost all SCADD individuals diagnosed by neonatal screening remained asymptomatic during follow-up. This potential lack of clinical consequences of SCADD has several implications. First, the diagnosis of SCADD should never preclude extension of the diagnostic workup for other potential causes of the observed symptoms. Second, patients and parents should be clearly informed about the potential lack of relevance of the disorder to avoid unfounded anxiety. Furthermore, to date, SCADD is not an optimal candidate for inclusion in newborn screening programs. More studies are needed to fully establish the relevance of SCADD and solve the question as to whether SCADD is involved in a multifactorial disease or represents a nondisease.

Flavin adenine dinucleotide status and the effects of high-dose riboflavin treatment in short-chain acyl-CoA dehydrogenase deficiency.

Short-chain acyl-CoA dehydrogenase deficiency (SCADD) is an inborn error, biochemically characterized by increased plasma butyrylcarnitine (C4-C) concentration and increased ethylmalonic acid (EMA) excretion and caused by rare mutations and/or common gene variants in the SCAD encoding gene. Although its clinical relevance is not clear, SCADD is included in most US newborn screening programs. Riboflavin, the precursor of flavin adenine dinucleotide (FAD, cofactor), might be effective for treating SCADD. We assessed the FAD status and evaluated the effects of riboflavin treatment in a prospective open-label cohort study involving 16 patients with SCADD, subdivided into mutation/mutation (mut/mut), mutation/variant (mut/var), and variant/variant (var/var) genotype groups. Blood FAD levels were normal in all patients before therapy, but significantly lower in the mut/var and var/var groups compared with the mut/mut group. Riboflavin treatment resulted in a decrease in EMA excretion in the mut/var group and in a subjective clinical improvement in four patients from this group. However, this improvement persisted after stopping treatment. These results indicate that high-dose riboflavin treatment may improve the biochemical features of SCADD, at least in patients with a mut/var genotype and low FAD levels. As our study could not demonstrate a clinically relevant effect of riboflavin, general use of riboflavin cannot be recommended.

Fasting and fat-loading tests provide pathophysiological insight into short-chain acyl-coenzyme a dehydrogenase deficiency.

OBJECTIVE: To gain insight into the pathophysiological and clinical consequences of short-chain acyl-coenzyme A dehydrogenase deficiency (SCADD). STUDY DESIGN: A retrospective study of 15 fasting and 6 fat-loading tests in 15 Dutch patients with SCADD, divided into 3 genotype groups. Metabolic and endocrinologic measurements and the biochemical characteristics of SCADD, ethylmalonic acid (EMA), and C4-carnitine were studied. RESULTS: Three patients had development of hypoglycemia during fasting; all of these had originally presented with hypoglycemia. Metabolic and endocrinologic measurements remained normal during all tests. The EMA excretion increased in response to fasting and fat loading, and plasma C4-carnitine remained stable. Test results did not differ between the 3 genotype groups. CONCLUSIONS: The metabolic profiles of the 3 patients with development of hypoglycemia resemble idiopathic ketotic hypoglycemia. Because hypoglycemia generally requires a metabolic work-up and because SCADD is relatively prevalent, SCADD may well be diagnosed coincidently, thus being causally unrelated to the hypoglycemia. If SCADD has any other pathologic consequences, the accumulation of potentially toxic metabolites such as EMA is most likely involved. However, the results of our study indicate that there is no clear pathophysiological significance, irrespective of genotype, supporting the claim that SCADD is not suited for inclusion in newborn screening programs.

Clinical, biochemical, and genetic heterogeneity in short-chain acyl-coenzyme A dehydrogenase deficiency.

CONTEXT: Short-chain acyl-coenzyme A (CoA) dehydrogenase (SCAD) deficiency (SCADD) is an autosomal recessive, clinically heterogeneous disorder with only 22 case reports published so far. Screening for SCADD is included in expanded newborn screening programs in most US and Australian states. OBJECTIVES: To describe the genetic, biochemical, and clinical characteristics of SCADD patients in the Netherlands and their SCADD relatives and to explore the genotype to phenotype relation. DESIGN, SETTING, AND PARTICIPANTS: Retrospective study involving 31 Dutch SCADD patients diagnosed between January 1987 and January 2006 and 8 SCADD relatives. SCADD was defined by the presence of (1) increased butyrylcarnitine (C4-C) levels in plasma and/or increased ethylmalonic acid (EMA) levels in urine under nonstressed conditions on at least 2 occasions, in combination with (2) a mutation and/or the c.511C>T or c.625G>A susceptibility variants on each SCAD-encoding (ACADS) allele. Patients were included only if the SCAD-encoding (ACADS) was fully sequenced and if current clinical information could be obtained. Relatives were included when they carried the same ACADS genotype as the proband, and had increased C4-C and/or EMA. MAIN OUTCOME MEASURES: Prevalence, genotype (mutation/mutation, mutation/variant, variant/variant), C4-C and EMA levels, clinical signs and symptoms, and clinical course. RESULTS: A birth-prevalence of at least 1:50,000 was calculated. Most patients presented before the age of 3 years, with nonspecific, generally uncomplicated, and often transient symptoms. Developmental delay, epilepsy, behavioral disturbances, and hypoglycemia were the most frequently reported symptoms. The ACADS genotype showed a statistically significant association with EMA and C4-C levels, but not with clinical characteristics. Seven out of 8 SCADD relatives were free of symptoms. CONCLUSIONS: SCADD is far more common than assumed previously, and clinical symptoms in SCADD are nonspecific, generally uncomplicated, often transient, and not correlated with specific ACADS genotypes. Because SCADD does not meet major newborn screening criteria, including a lack of clinical significance in many patients and that it is not possible to differentiate diseased and nondiseased individuals, it is not suited for inclusion in newborn screening programs at the present time.

Neuroleptic malignant syndrome in a 4-year-old girl associated with alimemazine.

UNLABELLED: Neuroleptic malignant syndrome (NMS) is a rare but serious disorder caused by antipsychotic medication including phenothiazines. For sedative purposes, increasing doses of alimemazine were administered to a 4-year-old multiple handicapped girl, with cerebral damage of the basal ganglia. She developed extra-pyramidal motor disturbances, an autonomic disorder, lowered consciousness and hyperthermia, characterising NMS. Alimemazine was stopped and dantrolene and supportive measures, including ventilation under sedation and paralysis with midazolam and vecuronium, were started. As clinical symptoms remained unabated, increasing doses of bromocriptine were administered. Two days after maximal bromocriptine dosage, her clinical condition improved and paralysis and ventilation were stopped. Midazolam and bromocriptine could be gradually decreased and suspended during the following months. A few days after bromocriptine cessation NMS recurred and was complicated by a fatal cardiorespiratory arrest. CONCLUSION: caution must be exercised when prescribing alimemazine, especially to children with basal ganglia damage and in the case of inexplicable fever and restlessness, neuroleptic malignant syndrome should be considered. Long-term therapy with bromocriptine combined with dantrolene and midazolam may be a successful medical treatment.