Final Nepas Journal 31-2 cs4.indd Case ReportMay-August, 2011/Vol 31/Issue 2 -143-J. Nepal Paediatr. Soc. May-August, 2011/Vol 31/Issue 2 Metachromatic Leucodystrophy: A Case Report Karki S1, Rai GK2, Kafle R2 1Dr. Subhana Karki, MBBS, MD, Assistant Professor, 2Dr. Ganesh Kumar Rai, MBBS, DCH, MD, Associate Professor, 3Dr. Raju Kafle, MBBS, MD. All from Kanti Children’s Hospital, Maharajgunj, Kathmandu, Nepal and affiliated to National Academy of Medical Sciences, Bir Hospital, Mahabauddha, Kathmandu, Nepal Address for correspondence: Dr. Subhana Karki, E-mail: suvana.karki@gmail.com Abstract Metachromatic leukodystrophy (MLD) is an autosomal recessive neurodegenerative disorder characterized by deficient activity of the enzyme arylsulfatase-A. Deficiency of this enzyme results in intralysosomal storage of sphingolipid cerebroside 3-sulfates (sulfatides), which are abundant in myelin and neurons. A pathological hallmark of MLD is demyelination and neurodegeneration, causing various and ultimately lethal neurological symptoms. Its frequency is estimated to be 1/40,000 live births. The disease encompasses three clinical subtypes: late infantile (40% of the patients with MLD), juvenile (40%), and adult (20%). The Case A four years old male, presented with a three month history of a progressively unsteady gait and deterioration of speech for the same duration. He was apparently well three months back when he started having frequent fall with gradual impairment of walking. Since one and half months back, he was unable to walk even with support. In addition, also had progressive deterioration in his speech. Initially, speech was slurred and dysarthic and then he could speak only a few words with diffi culty. However, hearing and vision seemed to be normal. There was no history of unconsciousness, seizure, bowel and bladder incontinence or head injury. Detailed history revealed that he was born full term at home. Antenatal, perinatal and postnatal history was not signifi cant. His developmental milestones were within normal limits for age prior to the illness. The family history was however signifi cant; Among the four siblings, one sister had similar type of progressive deterioration of motor as well as intellectual function and had died at age of 5 years. Another sister who was eleven years old also had mental sub normality. However, there was no history of consanguinity. On examination, there was no obvious facial dysmorphism. His head circumference was 49.5 cm (10th percentile NCHS) and weight was below 5th percentile (HCHS) with normal height. He appeared dull and emotionally labile. All cranial nerves were clinically normal. On motor system examination, all extremities were hypotonic with power of 3/5 and absence of deep tendon refl exes. Planters were fl exure in response bilaterally. There were no sensory involvement; however cortical sensation and coordination could not be assessed. Rest of the general and systemic examinations was found to be normal. MRI revealed periventricular and deep white matter high signal areas (T2, NC, and axial view) and Leopard sign in contrast enhancement. CSF fi nding was normal. A diagnosis of MLD was suggested by the family history and clinical presentation. Further, neuroimaging abnormalities were well characterized and consisted of confl uent periventricular white matter abnormalities sparing the arcuate fi bers which have helped to confi rm the diagnosis of MLD. The patient was advised for physiotherapy and regular follow up. Fig 1: Deep white matter high signal areas in T2 weighted image. -144-May-August, 2011/Vol 31/Issue 2 J. Nepal Paediatr. Soc. leukodystrophy, which usually manifests in children between 12 and 18 months of age and is characterized by motor signs of peripheral neuropathy followed by deterioration in intellect, speech, and coordination. Within two years of on-set; gait disturbance, quadriplegia, blindness, and decerebrate posturing may be seen. Disease progression is inexorable, and death occurs six months to four years after onset of symptoms3. The extremities are hypotonic, and the deep tendon refl exes are absent or diminished4. In juvenile MLD, the onset of symptoms is delayed to 5–10 yr of age. Deterioration in school performance and alterations in personality may herald the onset of the disease. This is followed by incoordination of gait, urinary incontinence, and dysarthria. In the terminal stages, generalized tonic-clonic convulsions are prominent and are diffi cult to control. Adult MLD occurs from the 2nd to 6th decade. Abnormalities in memory, psychiatric disturbances, and personality changes are prominent features4. However, extrapyramidal signs are not a commonly described feature of MLD. Both juvenile and adult types of MLD may present with extra pyramidal and cerebellar signs5. Neurophysiologic evaluation shows progressive changes in the VEPs, ABRs, and somatosensory-evoked potentials (SSEPs), and the nerve conduction velocities (NCVs) of the peripheral nerves are signifi cantly reduced4. Prenatal diagnosis by amniocentesis is possible in the fi rst trimester of pregnancy6. Since prenatal diagnosis is possible, the disease can be prevented, by fi rst trimester diagnosis of MLD by assaying ASA in chorionic villi or cultured fi broblasts and possible intervention thereafter7. At T2-weighted MR imaging, metachromatic leukodystrophy manifests as symmetric confl uent areas of high signal intensity in the periventricular white matter with sparing of the subcortical U fi bers8. The tigroid and “leopard skin” patterns of demyelination, which suggest sparing of the perivascular white matter, can be seen in the periventricular white matter and centrum semiovale8. In the later stage of metachromatic leukodystrophy, corticosubcortical atrophy often occurs, particularly when the subcortical white matter is involved8. Magnetic resonance (MR) imaging has be-come the primary imaging modality in patients with leukodystrophy and plays an important role in the identifi cation, localization, and characterization of underlying white matter abnormalities in affected Fig 3: T2-weighted MR image demonstrates bilateral confl uent areas of high signal intensity in the periventricular white matter. Note the classic sparing of the sub-cortical U fi bers (arrowheads). Fig 2: “leopard skin” patterns of demyelination, which suggest sparing of the perivascular white matter. Discussion Metachromatic leukodystrophy is an autosomal recessive disorder caused by a defi ciency of the lysosomal enzyme arylsulfatase A. This enzyme is necessary for the normal metabolism of sulfatides, which are important constituents of the myelin sheath. The accumulation of sulfatides occurs not only in the central nervous system, but also in various other tissues, including the peripheral nervous system1. The excessive cerebroside sulfate is thought to cause myelin breakdown and destruction of oligodendroglia. Three different types of metachromatic leukodystrophy are recognized according to patient age at onset: late infantile, juvenile, and adult2. The most common type is late infantile metachromatic -145-J. Nepal Paediatr. Soc. May-August, 2011/Vol 31/Issue 2 patients. MR imaging has also been extensively used to monitor the natural progression of various white matter disorders and the response to therapy8. Treatment Bone marrow transplantation is a promising experimental therapy for the management of late infantile MLD4. Prenatal diagnosis of MLD is made by assay of arylsulfatase A in chorionic villi or cultured amniotic fl uid cells. Reports of hematopoietic cell transplantation (with or without mesenchymal stromal cells) for MLD have yielded a wide range of results9, 10. Umbilical cord blood transplantation may be a better option than bone marrow transplantation because stored and cataloged umbilical blood can be rapidly identifi ed and transplanted, producing a shorter period between diagnosis and transplantation, an important characteristic to consider in neurodegenerative diseases11. References 1. Faerber EN, Melvin J, Smergel EM. MRI Appearances of metachromatic leukodystrophy. Pediatr Radiol 1999;29:669–72. 2. Kolodny EH. Sulfatide lipidosis: metachromatic leukodystrophy. In: Scriver CR, Beaedet Al, Sly W, Valle D, eds.The metabolic basis of inherited diseases. 6th ed. New York, NY: McGraw-Hill, 1989; 1721–50. 3. Wolpert SM, Anderson ML, Kaye EM. Metabolic and degenerative disorders. In: Wolpert SM, Barnes PD, eds. MRI in pediatric neuroradiology. 3rd ed. St Louis, Mo: Mosby, 1992; 121–150. 4. Michael V. Johnston. Neurodegenerative Disorders of Childhood. In: Behrman RE, Kliegman RM, Jenson HB, editors. Nelson Textbook of Pediatrics. 18th ed. W.B. Saunders Company; 2008; 592-598. 5. Pandit L, Kapadia R, Kini P. Metachromatic Leukodystropy Presenting with extrapyramidal disturbances. Indian Pediatr 1994;31:690-94. 6. Fensom AH, March J, Jackson M,McGuire VM, Vimal C, Nicolaides K,Sheridan R.First trimester diagnosis of metachromatic leucodystrophy. Clin Gen 1988; 34:122-25. 7. R.L. Koul A. GururajA.P. Chacko M.S. Elbualy S.R. P.Chand Late Infantile Metachromatic Leucodystrophy in Two Siblings. Indian Pediatr 1994;31:694-98. 8. Jung-Eun Cheon, In-One Kim et al. Leukodystrophy in Children: A Pictorial Review of MR Imaging Features. J Continuing Med Edu Radiol 2002;22:461-64. 9. Kidd D, Nelson J, Jones F, et al. Long-term stabilization after bone marrow transplantation in juvenile metachromatic leukodystrophy. Arch Neurol 1998; 55:98–99. 10. Malm G, Ringden O, Winiarski J, et al. Clinical outcome in four children with metachromatic leukodystrophy treated by bone marrow transplantation. Bone Marrow Transplant 1996;17:1003–8. 11. Tyler Mark Piersonet al. Umbilical cord blood transplantation for juvenile metachromatic leukodystrophy. Ann Neurol 2008;64(5): 583–87. How to cite this article ? Karki S, Rai GK, Kafl e R. Metachromatic Leucodystrophy: A Case Report. J Nep Paedtr Soc 2011;31(2):143-145.