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Excerpt from Maple Syrup Urine DiseaseSynonyms, Key Words, and Related Terms: maple syrup urine disease, MSUD, maple sugar urine disease, branched-chain ketonuria, branched chain ketonuria, branched-chain ketoaciduria, branched chain ketoaciduria, muscular hypotonia, muscular hypertonia, dystonia, seizures, encephalopathy, pseudotumor cerebri, pancreatitis, ketosis, otitis media, thiamine-responsive MSUD, ketotic hypoglycemia Please click here to view the full topic text: Maple Syrup Urine DiseaseBackgroundMaple syrup urine disease (MSUD) is an aminoacidopathy secondary to an enzyme defect in the catabolic pathway of the branched-chain amino acids leucine, isoleucine, and valine. Accumulation of these 3 amino acids and their corresponding keto acids leads to encephalopathy and progressive neurodegeneration in untreated infants. Early diagnosis and dietary intervention prevent complications and may allow for normal intellectual development. Consequently, MSUD has been added to many newborn screening programs, and preliminary results indicate that asymptomatic newborns with MSUD have a better outcome compared with infants who are diagnosed after they become symptomatic. In 1954, Menkes et al reported a family in which 4 infants died within the first 3 months of their lives because of a neurodegenerative disorder. The urine of these infants had an odor resembling maple syrup (burned sugar).1 Therefore, this disorder was called maple sugar urine disease and, later, maple syrup urine disease. In the following years, Dancis et al identified the pathogenetic compounds as branched-chain amino acids and their corresponding alpha-keto acids.2 In 1960, Dancis et al demonstrated that the enzymatic defect in MSUD was at the level of the decarboxylation of the branched-chain amino acids.3 Snyderman et al initiated the first successful dietary treatment of MSUD by restricting intake of branched-chain amino acids.4 In 1971, Scriver et al reported the first case of thiamine-responsive MSUD.5 The branched-chain alpha-keto acid dehydrogenase (BCKD) complex was purified and characterized in 1978.2 PathophysiologyMSUD is caused by a deficiency of the BCKD complex, which catalyses the decarboxylation of the alpha-keto acids of leucine, isoleucine, and valine to their respective branched-chain acyl-CoAs. These are further metabolized to yield acetyl-CoA, acetoacetate, and succinyl-CoA. The BCKD complex, which is associated with the inner mitochondrial membrane, has 3 different catalytic components (ie, E1, E2, E3) and 2 associated regulatory enzymes (ie, BCKD phosphatase, BCKD kinase). In addition, the E1 component consists of 2 distinct subunits (ie, E1 alpha, E1 beta) that form an alpha-2 beta-2 heterotetramer. The E3 component is associated with 2 additional alpha-ketoacid dehydrogenase complexes, namely pyruvate dehydrogenase and alpha-ketoglutarate dehydrogenase. Mutations in E1, E2, or E3 cause MSUD. No good genotype-phenotype correlation between molecular and clinical phenotypes is known, with the exemption of mutations in E2, which cause thiamine-responsive MSUD. Mutations in E3 cause additional deficiencies of pyruvate and alpha-ketoglutarate dehydrogenases. Mutations in the regulatory enzymes have not been reported. Accumulation of leucine in particular causes neurological symptoms, whereas elevation of plasma isoleucine is associated with the maple syrup odor. Leucine is rapidly transported across the blood-brain barrier and is metabolized to presumably yield glutamate and glutamine. FrequencyUnited StatesMSUD occurs in about 1 case per 180,000 newborns in the United States but may be as common as 1 case per 176 newborns in selected inbred populations (eg, the Mennonites in Pennsylvania). As an autosomal recessive disorder, MSUD is more prevalent in populations with a high frequency of consanguinity. InternationalIn Austria, one case of MSUD has been detected among 250,000 newborn infants who have been through the Austrian Screening Program. Mortality/MorbidityInfants with untreated early onset (ie, classic) MSUD have significant developmental delay and die within the first months of life. Children or juveniles with late-onset (ie, intermediate, intermittent) forms of MSUD may have some form of developmental delay, depending on the residual activity of BCKD. All children are at increased risk for metabolic decompensation during periods of increased protein catabolism (eg, intercurrent illness, trauma, surgery). Morbidity can almost entirely be prevented with early diagnosis (in a neonate younger than 10 d), with appropriate treatment at presentation and during episodes of potential metabolic decompensation. RaceMSUD has been reported to occur in all ethnic groups, although the incidence and prevalence may widely vary. SexNo sex predilection is noted. Please click here to view the full topic text: Maple Syrup Urine Disease |
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