Imaging Study of the White Matter Lesions in Children With Metachromatic Leucodystrophy (HCIT-MLD)

Metachromatic Leukodystrophy (MLD) is a rare autosomal recessive disorder caused by the deficiency of the Arylsulfatase A enzyme (ARSA), resulting in accumulation of galactosyl sulfatide (cerebroside sulfate), a major constituent of the myelin sheath. Accumulation of sulfatides leads to a progressive degeneration of the white matter in the central and peripheral nervous systems (CNS, PNS) and to a neuronal degeneration. The late-infantile form of MLD, which is usually diagnosed in the second year of life, is the most frequent and severe form of the disease. The prognosis is severe, leading to vegetative stage or death within few years after the diagnosis. There is no treatment for patients affected with this early-onset form of the disease.

Conventional MRI (1.5 Tesla) shows extensive involvement of the cerebral white matter (hypo-T1, hyper- T2 and FLAIR signals) indicative of rapidly progressing leukodystrophy. Early cortical atrophy reflects associated neuronal involvement. Proton MR spectroscopy demonstrates abnormalities of choline and N-acetyl-aspartate (demyelination, neuronal loss), which are non-specific but can serve as indicators to monitor the effects of any therapeutic intervention.

In early-onset forms of MLD, conventional MRI becomes abnormal at a relatively advanced stage of the disease and the neuroradiological diagnosis may be difficult before the age of 2 - 2 1/2 years of age. Moreover, topography and extent of detectable lesions are poorly correlated with the disease severity.

In order to improve information provided by neuroimaging, this study aims to investigate prospectively and longitudinally (over a period of 6 months) white and grey matter lesions in 10 MLD children aged 1 to 6 years, using high-field MRI (3 Teslas) and diffusion tensor imaging (DTI) with 3D reconstruction of the myelin tracks. The time interval between diagnosis and inclusion will not exceed 18 months, thus patients will be included at an early stage of their disease. Each time-point (T0 and 6 months) will also include neurological evaluation to correlate the imaging, cognitive and motor functions. Children will be included over a period of 5 years. The total duration of the study will be 5.5 years. Controls will include 25 age-matched children with cryptogenic partial epilepsy who should have a high-field MRI to detect structural abnormalities. Controls will have a MRI and cognitive evaluation at T0 and 12 months if necessary. This study will increase our knowledge of the natural history of MLD and provide new indicators for the selection and evaluation of patients eligible for new therapeutic approaches.