Fifteen children with infantile spasms and a hypsarrhythmic EEG defined by EEG-videotelemetry monitoring received a regimen of high-dose (150 IU/m2/d) ACTH for their seizures. We carried out an endocrinologic evaluation before and after initiation of the ACTH and conducted a time course study of plasma ACTH and cortisol levels after ACTH dosing. Spasms were controlled and the EEG normalized in 14 of the 15 children. Prior to starting ACTH therapy all the patients had normal prolactin, insulin, cortisol, and ACTH levels in plasma and normal thyroid function. Although the pattern of rise of ACTH levels in plasma after ACTH dosing was similar in all the children, there was great individual variation in the absolute concentrations. However, both the pattern of rise and absolute level of cortisol in plasma after ACTH was highly predictable in all patients. Plasma cortisol rose rapidly within 1 hour of ACTH administration and continued a slower rise for 12 to 24 hours after the ACTH dose. High-dose ACTH therapy seems quite effective in infantile spasms, perhaps because of a sustained high level of plasma cortisol. This sustained plateau of cortisol may be more effective in controlling infantile spasms than the pulse effect expected with oral steroids or lower doses of ACTH.
SUMMARYThe brain aspartate-glutamate carrier (AGC1) is specifically expressed in neurons, where it transports aspartate from the mitochondria to the cytosol, and plays a role in transfer of nicotinamide adenine dinucleotide (NADH)-reducing equivalents into the mitochondria as a part of the malate-aspartate shuttle. Deficient function of AGC1 underlies an inborn error of metabolism that presents with severe hypotonia, arrested psychomotor development, and seizures from a few months of age. In AGC1 deficiency, there is secondary hypomyelination due to lack of N-acetylaspartate (NAA), which is normally generated by acetylation of aspartate in the neuron and required for fatty acid synthesis by the adjacent oligodendrocyte. Based on experiences from AGC2 deficiency, we predicted that reduced glycolysis should compensate for the metabolic defect and allow resumed myelination in AGC1 deficiency. Carbohydrate restriction was therefore initiated in a patient with AGC1 deficiency at 6 years of age by introducing a ketogenic diet. The response was dramatic, clinically as well as radiologically. Psychomotor development showed clear improvement, and magnetic resonance imaging (MRI) indicated resumed myelination. This is the first successful treatment of secondary hypomyelination reported. Because AGC1 is driven by the proton gradient generated by the neuronal mitochondrial respiratory chain, the results have potential relevance for secondary hypomyelination in general.
In metachromatic leukodystrophy (MLD), the deficiency of the lysosomal enzyme arylsulfatase A (ARSA) leads to demyelination in the central and peripheral nervous system and ultimately to death. Allogeneic hematopoietic SCT (HSCT) is currently the only treatment for adult and late-onset juvenile MLD, although it is still in question because of insufficient follow-up. We wanted to determine whether HSCT could halt the progression of adult and late-onset juvenile MLD. Four treated unrelated patients and three untreated siblings were included in the study, and followed regularly for up to 18 years after transplantation. The patients were assessed from clinical examination, ARSA enzyme levels, magnetic resonance imaging of the brain and neuropsychological and neurophysiological tests. In the treated patients, ARSA levels were normal up to 18 years after transplantation. The parameters evaluated stabilized and remained stable after a latency period of 12-24 months. Two patients live normal lives, partially in a protected environment. The other two patients stabilized at a low cognitive and functional level. One of the controls is demented, one is in a vegetative state and one died. We conclude that, in comparison with their untreated siblings, HSCT halted the progression of the disease in our treated patients.
Brain malformations are a major cause of therapy-refractory epilepsy as well as neurological and developmental disabilities in children. This study examined the frequency and the nature of copy number variations among children with structural brain malformations and refractory epilepsy. The medical records of all children born between 1990 and 2009 in the epilepsy registry at the Astrid Lindgren's Children's Hospital were reviewed and 86 patients with refractory epilepsy and various brain malformations were identified. Array-CGH analysis was performed in 76 of the patients. Pathogenic copy number variations were detected in seven children (9.2%). In addition, rearrangements of unclear significance, but possibly pathogenic, were detected in 11 (14.5%) individuals. In 37 (48.7%) patients likely benign, but previously unreported, copy number variants were detected. Thus, a large proportion of our patients had at least one rare copy number variant. Our results suggest that array-CGH should be considered as a first line genetic test for children with cerebral malformations and refractory epilepsy unless there is a strong evidence for a specific monogenic syndrome.
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