MACHADO-Joseph disease

Similar documents
Original Article. Abstract. Introduction

DRPLA is an autosomal dominant neurodegenerative disorder

S pinocerebellar ataxia type 7 (SCA7) is a neurodegenerative

International Journal of Health Sciences and Research ISSN:

MULTI SYSTEM ATROPHY: REPORT OF TWO CASES Dipu Bhuyan 1, Rohit Kr. Chandak 2, Pankaj Kr. Patel 3, Sushant Agarwal 4, Debjanee Phukan 5

10/3/2016. T1 Anatomical structures are clearly identified, white matter (which has a high fat content) appears bright.

Multiple system atrophy (MSA) is a sporadic adult-onset

Amyotrophic lateral sclerosis (ALS) is a progressive neurodegenerative

Chapter 3. Structure and Function of the Nervous System. Copyright (c) Allyn and Bacon 2004

Dentatorubral-pallidoluysian atrophy (DRPLA)

ORIGINAL CONTRIBUTION. Brain Magnetic Resonance Imaging in Multiple-System Atrophy and Parkinson Disease

The Central Nervous System I. Chapter 12

Diffusion-Weighted and Conventional MR Imaging Findings of Neuroaxonal Dystrophy

Biological Bases of Behavior. 3: Structure of the Nervous System

Brainstem. Steven McLoon Department of Neuroscience University of Minnesota

FDG-PET e parkinsonismi

The neurvous system senses, interprets, and responds to changes in the environment. Two types of cells makes this possible:

ANATOMY & PHYSIOLOGY DISSECTION OF THE SHEEP BRAIN LAB GROUP:

Unit VIII Problem 5 Physiology: Cerebellum

DISSECTION OF THE SHEEP'S BRAIN

Neuroradiological, clinical and genetic characterization of new forms of hereditary leukoencephalopathies

Gross Organization I The Brain. Reading: BCP Chapter 7

b. The groove between the two crests is called 2. The neural folds move toward each other & the fuse to create a

Cerebellum. Steven McLoon Department of Neuroscience University of Minnesota

14 - Central Nervous System. The Brain Taft College Human Physiology

I: To describe the pyramidal and extrapyramidal tracts. II: To discuss the functions of the descending tracts.

Organization of The Nervous System PROF. SAEED ABUEL MAKAREM

Magnetic resonance imaging (MR!) provides

Lecture XIII. Brain Diseases I - Parkinsonism! Brain Diseases I!

Regional and Lobe Parcellation Rhesus Monkey Brain Atlas. Manual Tracing for Parcellation Template

SHORTLY AFTER ITS FIRST DEpiction

Organization of The Nervous System PROF. MOUSAED ALFAYEZ & DR. SANAA ALSHAARAWY

Brainstem. Amadi O. Ihunwo, PhD School of Anatomical Sciences

Ch 13: Central Nervous System Part 1: The Brain p 374

Pediatric MS MRI Study Methodology

Anatomy and Physiology (Bio 220) The Brain Chapter 14 and select portions of Chapter 16

DEVELOPMENT OF BRAIN

1. The basic anatomy of the Central Nervous System (CNS)

ADULT-ONSET (INFRATENTORIAL) LEUKOENCEPHALOPATHY as PRESENTING MANIFESTATION of ERDHEIM-CHESTER DISEASE

The Brain Pathology in Fukuyama Type Congenital Muscular Dystrophy -CT and Autopsy Findings-

MR Signal Intensity of the Optic Radiation

Copy Right- Hongqi ZHANG-Department of Anatomy-Fudan University. Systematic Anatomy. Nervous system Cerebellum. Dr.Hongqi Zhang ( 张红旗 )

Dissection of the Sheep Brain

Prion diseases or transmissible spongiform encephalopathies (TSEs)

HEREDITARY ATAXIAS (HA)

Course Calendar

The Nervous System: Sensory and Motor Tracts of the Spinal Cord

Nervous System: Part IV The Central Nervous System The Brain

Lecture 4 The BRAINSTEM Medulla Oblongata

DISTRIBUTION OF NEURONAL CYTOPLASMIC INCLUSIONS IN MULTIPLE SYSTEM ATROPHY

Course Calendar - Neuroscience

1 MS Lesions in T2-Weighted Images

DIRECT SURGERY FOR INTRA-AXIAL

BIOL Dissection of the Sheep and Human Brain

Anatomy & Physiology Central Nervous System Worksheet

Attenuation value in HU From -500 To HU From -10 To HU From 60 To 90 HU. From 200 HU and above

Neuropathology of Neurodegenerative Disorders Prof. Jillian Kril

By Dr. Saeed Vohra & Dr. Sanaa Alshaarawy

M555 Medical Neuroscience Lab 1: Gross Anatomy of Brain, Crainal Nerves and Cerebral Blood Vessels

Brainstem. By Dr. Bhushan R. Kavimandan

PSYC& 100: Biological Psychology (Lilienfeld Chap 3) 1

Student Lab #: Date. Lab: Gross Anatomy of Brain Sheep Brain Dissection Organ System: Nervous Subdivision: CNS (Central Nervous System)

Neural Basis of Motor Control

C14 / CNS / MC3. What two stuctures make up the central nervous system?

Fig.1: A, Sagittal 110x110 mm subimage close to the midline, passing through the cingulum. Note that the fibers of the corpus callosum run at a

MR Imaging of Wallerian Degeneration in the Brainstem:

Posterior fossa malformations

Abdullah AlZibdeh. Dr. Maha ElBeltagy. Maha ElBeltagy

UNIT 5 REVIEW GUIDE - NERVOUS SYSTEM 1) State the 3 functions of the nervous system. 1) 2) 3)

Sincerely, Ms. Paoloni and Mrs. Whitney

Introduction to the Central Nervous System: Internal Structure

SENSORY (ASCENDING) SPINAL TRACTS

A Small Trinucleotide Expansion in the TBP Gene Gives Rise to a Sporadic Case of SCA17 with Abnormal Putaminal Findings on MRI

Cerebellum John T. Povlishock, Ph.D.

Located below tentorium cerebelli within posterior cranial fossa. Formed of 2 hemispheres connected by the vermis in midline.

Brain dissection protocol for amyotrophic lateral sclerosis/motor neurone disease

The Nervous System 7PART B. PowerPoint Lecture Slide Presentation by Patty Bostwick-Taylor, Florence-Darlington Technical College

Curricular Requirement 3: Biological Bases of Behavior

Nervous System C H A P T E R 2

Internal Organisation of the Brainstem

Periventricular white matter injury, that is, periventricular

Cranial Nerve VIII (The Vestibulo-Cochlear Nerve)

Announcement. Danny to schedule a time if you are interested.

Topic/Objective: Identify the structures and functions of

Parts of the Brain. Hindbrain. Controls autonomic functions Breathing, Heartbeat, Blood pressure, Swallowing, Vomiting, etc. Upper part of hindbrain

Sectional Anatomy Head Practice Problems

The Neuroscience of Music in Therapy

TOXIC AND NUTRITIONAL DISORDER MODULE

TRANSVERSE SECTION PLANE Scalp 2. Cranium. 13. Superior sagittal sinus

Lecturer. Prof. Dr. Ali K. Al-Shalchy MBChB/ FIBMS/ MRCS/ FRCS 2014

biological psychology, p. 40 The study of the nervous system, especially the brain. neuroscience, p. 40

Central nervous system (CNS): brain and spinal cord Collections of cell body and dendrites (grey matter) are called nuclei/nucleus Nucleus can also

The Nervous System PART B

Progressive Supranuclear Gaze Palsy with Predominant Cerebellar Ataxia: A Case Series with Videos

Creutzfeldt-Jakob Disease with a Codon 210 Mutation: First Pathological Observation in a Japanese Patient

Essentials of Clinical MR, 2 nd edition. 14. Ischemia and Infarction II

Unit Three. The brain includes: cerebrum, diencephalon, brain stem, & cerebellum. The brain lies within the cranial cavity of the skull.

PSY 302: CHAPTER 3 NOTES THE BRAIN (PART II) - 9/5/17. By: Joseline

For more information about how to cite these materials visit

Transcription:

ORIGINAL CONTRIBUTION Characteristic Magnetic Resonance Imaging Findings in Machado-Joseph Disease Yoshio Murata, MD; Shinya Yamaguchi, MD; Hideshi Kawakami, MD; Yukari Imon, MD; Hirofumi Maruyama, MD; Tetsuo Sakai, MD; Toshinari Kazuta, MD; Toshiyuki Ohtake, MD; Masataka Nishimura, MD; Takahiko Saida, MD; Susumu Chiba, MD; Takekazu Oh-i, MD; Shigenobu Nakamura, MD Objective: To clarify the characteristic magnetic resonance imaging (MRI) findings in patients with Machado-Joseph disease (MJD) diagnosed by genetic analysis. Patients and Methods: Using MRI, we examined 31 patients genetically diagnosed as having MJD, 20 patients with sporadic olivopontocerebellar atrophy, and 26 control subjects. Results: The MRIs of patients with MJD disclosed remarkably reduced width of the superior cerebellar peduncles, atrophy in the frontal and temporal lobes, diminished transverse diameter of the globus pallidus, and decreased anteroposterior and transverse diameters of the pons, which correlated with the width of the middle cerebellar peduncle. The width of the superior cerebellar peduncles also correlated with the diameter of the dentate or red nucleus in patients with MJD, but not in controls or in patients with sporadic olivopontocerebellar atrophy. On T 2 - and/or proton-weighted axial MR imaging, a high signal intensity in the transverse pontine fibers was observed in 14 (45.2%) of 31 patients with MJD and in all patients with sporadic olivopontocerebellar atrophy, but not in any controls. Conclusion: Affected afferent and efferent cerebellar tracts and atrophy of the frontal and temporal lobes and globus pallidus are characteristics of MRI of patients with MJD. Arch Neurol. 1998;55:33-37 From the Third Department of Internal Medicine, Hiroshima University School of Medicine, Hiroshima, Japan (Drs Murata, Yamaguchi, Kawakami, Imon, Maruyama, and Nakamura); National Chikugo Hospital, Fukuoka, Japan (Dr Sakai); Tokyo Metropolitan Neurological Hospital, Tokyo, Japan (Drs Kazuta and Ohtake); the Department of Neurology and Clinical Research Center, National Utano Hospital, Kyoto, Japan (Drs Nishimura and Saida); Sapporo Medical University, Hokkaidō, Japan (Dr Chiba); and the Third Department of Internal Medicine, Miyazaki Medical College, Miyazaki, Japan (Dr Oh-i). Dr Yamaguchi is now with the Department of Neurology, Suiseikai Kajikawa Hospital, Hiroshima, Japan. MACHADO-Joseph disease (MJD) is an autosomal dominant, multisystem, neurodegenerative disorder originally described in Portuguese- Azorean families. 1-3 More recently, MJD has also been reported in non-azorean families worldwide and is considered the most common type of autosomal dominant spinocerebellar degeneration. 4-9 Advances in genetic analysis have made it possible to diagnose MJD more accurately. 10 We clarified the characteristic magnetic resonance imaging (MRI) findings in patients with MJD diagnosed by genetic analysis. RESULTS The Table summarizes the MRI findings of 31 patients with MJD, 20 patients with sopca, and 26 control subjects. The MJD group had severe atrophy of the pons, middle, and superior cerebellar peduncles, and the globus pallidus compared with controls. The anteroposterior and transverse diameters of the midbrain and the anteroposterior diameter of the medulla oblongata were significantly different between the MJD and control groups (P.05). We observed a significant enlargement of the fourth ventricle in patients with MJD (P.05). The area of the cerebellum was significantly smaller in patients in the MJD group than in controls (P.01). Significant atrophy was observed in the frontal and temporal lobes in patients in the MJD group (P.05), but not in the parietal or occipital lobes. There was a significant correlation between the width of the superior cerebellar peduncle and the diameter of the dentate nucleus (r=4; P.05) or of the red nucleus (r=2; P.05) in patients with MJD (Figure 2, top), but not in patients with sopca (Figure 2, center) or in controls (Figure 2, bottom). A significant correlation also was found between the width of the middle cerebellar peduncle and the anteroposterior (r=0.40; P.05) or transverse diameter of the pons (r=6; P.005) in patients with MJD. Transverse pontine fibers were observed in 14 (45.2%) of 31 patients with MJD and in all patients with sopca, but in none of the controls. The proton- 33

PATIENTS AND METHODS We studied 31 patients with MJD (16 men and 15 women; mean SD age, 5 13.7 years; mean SD duration of illness, 12.9 6.6 years), 20 patients with sporadic olivopontocerebellar atrophy (sopca) (6 men and 14 women; mean±sd age, 55.1 11.6 years; mean±sd duration of illness, 3.2 3.1 years), and 26 age-matched control subjects without intracranial lesions (11 men and 15 women; mean±sd age, 49.6 17.2 years). The condition of patients with MJD was diagnosed by genetic analysis 10 and by symptoms and signs, including cerebellar ataxia, pyramidal tract signs, extrapyramidal symptoms, and amyotrophy. The condition of patients with sopca was diagnosed by the clinical criteria proposed by Quinn, 11 excluding familial spinocerebellar degeneration by genetic analysis. Informed consent for the genetic analysis was obtained from all patients. Patients with sopca and normal volunteers were examined using -T MRI. T 1 -weighted axial images (repetition time[tr], 450milliseconds; echotime[te], 30milliseconds), T 2 -weighted axial images (TR, 2000 milliseconds; TE, 80 milliseconds), and proton-weighted axial images (TR, 2000 milliseconds; TE, 30 milliseconds) were obtained in the transaxial plane (5-mm thickness and -mm gap). Patients with MJDwereexaminedusing-to-TMRI.T 1 -weightedaxial images (TR, 300-600 milliseconds; TE, 15-30 milliseconds), T 2 -weighted axial images (TR, 2000-4000 milliseconds; TE, 80-102 milliseconds), and proton-weighted axial images (TR, 2000-4000 milliseconds; TE, 15-30 milliseconds) were obtained in the transaxial plane (5- to 8-mm thickness and 0- to -mm gap). Measurements were performed separately by 3 neuroradiologists (Y.M., S.Y., and Y.I.) who did not know the clinical or genetic status of the subjects. Anteroposterior and transverse diameters of the pons, midbrain, medulla oblongata, and fourth ventricle were measured on T 1 -weighted axial images. The width of the middle cerebellar peduncle was also measured on T 1 -weighted axial images. It was difficult to measure the width of the superior cerebellar peduncle directly on the transaxial T 1 MRI, so we evaluated the diameter of the midbrain at the level of the superior cerebellar peduncle, which would indirectly reflect the width of the superior cerebellar peduncles. The diameter of the dentate nucleus, red nucleus, and globus pallidus was determined on T 2 -weighted axial images. The area of the cerebellum was evaluated on T 1 -weighted axial images. We tried to exclude the sulcus indentations in the outline of the cerebellum at the edge shown in Figure 1 using a computer software package (MacSCOPE, Mitani Co, Fukui, Japan) on a Macintosh computer. The threshold was determined to represent the edge of the cerebellum accurately and the binary image was made. Thereafter, pixels in the cerebellar area were counted and the area of the cerebellum was measured. The degree of atrophy in the frontal, temporal, parietal, and occipital lobes was visually divided into 4 grades (0, none; 1, mild; 2, moderate; and 3, severe) by observers (Y.M., S.Y., and Y.I.) unaware of the subject status. The appearance of the abnormal signal intensity of transverse pontine fibers was assessed on T 2 - and/or proton-weighted axial images. AlldatawereanalyzedusingthecomputersoftwarepackageJMP3.0(SASInstituteInc, Cary, NC) onamacintoshcomputer. Differencesbetweenthegroupswereexaminedbyanalysis of variance. Frontal, temporal, parietal, or occipital lobe atrophy was analyzed by the Wilcoxon rank sum test. Probability values less than 5% were accepted as significant. 1 4 2 3 6 7 5 10 8 9 11 13 12 14 15 Figure 1. Measurements on T 1 - and T 2 -weighted axial magnetic resonance images. 1 indicates anteroposterior diameter of the globus pallidus; 2, transverse diameter of the globus pallidus; 3, anteroposterior diameter of the midbrain; 4, transverse diameter of the midbrain; 5, width of the superior cerebellar peduncles; 6, width of the middle cerebellar peduncle; 7, diameter of the dentate nucleus; 8, diameter of the red nucleus; 9, anteroposterior diameter of the pons; 10, transverse diameter of the pons; 11, anteroposterior diameter of the fourth ventricle; 12, transverse diameter of the fourth ventricle; 13, anteroposterior diameter of the medulla oblongata; 14, transverse diameter of the medulla oblongata; and 15, area of the cerebellum. 34

weighted axial MRI of a 64-year-old woman with MJD showed a high signal intensity in the transverse pontine fibers (Figure 3). The mean SD age was 58.1 3.1 years in 14 patients with MJD with abnormal transverse pontine fibers, and 42.3 13.3 years in 17 patients with MJD without abnormal transverse pontine fibers. The difference in age was significant (P.001), but no significant difference was found in the disease duration. COMMENT Magnetic Resonance Imaging Findings* Group Finding Control MJD sopca Pons, cm AP 2.47±1 1.81±2 2.15±9 Trans 3.00±5 2.33±0.43 2.67±4 Midbrain, cm AP 2.62±0.16 2.11±5 2.39±5 Trans 3.59±0.40 3.03±0 3.11±8 Medulla oblongata, cm AP 1.66±5 1.25±3 1.30±0.17 Trans 1.72±0.16 1.47±2 1.42±0.13 Fourth ventricle, cm AP 1.11±6 1.47±0.45 6±2 Trans 1.44±7 1.88±7 1.41±4 Middle cerebellar 1.79±4 1.16±0.45 1.45±5 peduncle, cm Superior cerebellar 0±0.12 1.47±7 1.86±0.14 peduncle, cm Dentate nucleus, cm 4±2 1.81±1.26 1.78±5 Red nucleus, cm 9±0.11 3±6 3±0.12 Globus pallidus, cm AP 4±7 2.31±0.47 5±1 Trans 3±0.16 5±0.03 1±0.13 Area of cerebellum, cm 2 41.45±6.47 35.16±4.93 28.50±6.70 Atrophy, grade Frontal lobe 5±5 1.32±9 5±2 Temporal lobe 7±1 1.29±2 1.10±1 Parietal lobe 6±7 7±1 1.20±0.41 Occipital lobe 0.46±5 5±0.49 0.15±7 *Values are given as mean±sd. MJD indicates Machado-Joseph disease; sopca, sporadic olivopontocerebellar atrophy; AP, anteroposterior diameter; and trans, transverse diameter. P.01 vs the control group. P.05 vs the control group. Graded as 0, none; 1, mild; 2, moderate; and 3, severe. Moderate cerebellar atrophy and marked brainstem atrophy, especially in the pontine tegmentum, were observed in the MJD group, which is consistent with previous MRI and pathologic studies. 12-14 Our study also disclosed a moderate to severe atrophy in the frontal and temporal lobes, and remarkable atrophy in the superior and middle cerebellar peduncles and globus pallidus in patients with MJD. Marked dilatation of the fourth ventricle was also observed in patients in the MJD group, which probably could be attributed to the atrophy of the pontine tegmentum and dentate nucleus. To evaluate the accuracy of measurement in the dentate nucleus, red nucleus, and globus pallidus on -T MRI, we investigated the size of the dentate nucleus, red nucleus, and globus pallidus in 23 healthy volunteers on -T MRI and in 26 healthy volunteers on -T MRI. The dentate nucleus, red nucleus, and globus pallidus were visible and their size was measured on the -T magnetic field, but we found no significant difference in their size between - and -T MRI (dentate nucleus, mean SD 1.70 3 cm and 4 2 cm; red nucleus, 4 0.10 cm and 9 0.11 cm; anteroposterior diameter of the globus pallidus, 2.49 7 cm and 4 7 cm; transverse diameter of the globus pallidus, 9 0.12 cm and 3 0.16 cm, respectively). These data suggest that the size measured on the -T MRI would not be underestimated compared with that measured on the -T MRI. Therefore, the size of the dentate nucleus, red nucleus, or globus pallidus would not be influenced by variable magnetic fields, and would therefore be reliable. The atrophy of the pons or midbrain is age-dependent, because significant reverse correlation was found between age and the transverse diameter of the pons (P.05) or the anteroposterior diameter of the midbrain (P.01) in patients in the MJD group. The duration of illness correlated with the decrease in the anteroposterior (r=0.40; P.05) and transverse diameters (r=3; P.01) of the globus pallidus in patients in the MJD group, and with the degree of temporal or occipital lobe atrophy in MJD (P.05). These data indicate that changes disclosed by MRI are age-related and develop according to the disease process. The width of the superior or middle cerebellar peduncle was significantly decreased in patients in the MJD group compared with controls (P.05). There was a significant correlation between the anteroposterior or transverse diameter of the pons and the width of the middle cerebellar peduncle. The atrophy of the pons and the middle cerebellar peduncle suggests that the afferent cerebellar tract from the pontine nuclei to the cerebellum through the middle cerebellar peduncle is affected in MJD. To characterize MRI features peculiar to MJD, we compared the MRI findings of 31 patients who had MJD with those of 20 patients who had sopca, although sopca might include miscellaneous disease entities. There was a significant difference in the duration of illness between the patients with MJD and sopca (P.05), probably due to more rapid progress in patients with sopca. In patients with sopca, the superior cerebellar peduncle was preserved, but it was atrophied in patients with MJD. Moreover, the correlation was observed between the width of the superior cerebellar peduncles and the diameter of the dentate or red nucleus in patients with MJD, but not in controls or in patients with sopca. Although there was no significant difference in the diameter of the dentate or red nucleus among the 3 groups by analysis of variance, the atrophy of the superior cerebellar peduncle seems to proceed in parallel with the atrophy of the dentate and red nucleus in patients with MJD. The dentate or red nucleus and the superior cerebellar peduncle are spared in patients with sopca and in controls. Therefore, no close relationship exists between the width of the superior cerebellar peduncles and the diameter of the dentate or red nucleus in patients with sopca and in control subjects. In ad- 35

1.1 0.4 n=31 r =4 P <.05 n=31 r =2 P <.05 1.1 0.4 1.1 0.4 Superior Cerebellar Peduncle, cm Superior Cerebellar Peduncle, cm Figure 2. Correlation between the width of the superior cerebellar peduncle and the diameter of the dentate and red nuclei in patients with Machado-Joseph disease (top), in patients with sporadic olivopontocerebellar atrophy (center), and in controls (bottom). There was a significant correlation between the width of the superior cerebellar peduncles and the diameter of the dentate nucleus (r=4; P.05) and of the red nucleus (r=2; P.05) in patients with Machado-Joseph disease, but not in patients with sporadic olivopontocerebellar atrophy or in controls. dition, sopca progresses more rapidly than MJD, so disproportionate atrophy may be present in sopca. Furthermore, the atrophy of the dentate nucleus seems to be related to the pontocerebellar tract, but not to the dentatorubrothalamic tract. These findings indicate intact efferent fiber systems in sopca, which has been indicated by previous reports 13,15 in contrast to MJD. The involvement of the efferent dentatorubral system, which runs through the superior cerebellar peduncle in MJD shown by autopsy studies, 14 seems to characterize the MRI of patients with MJD. A high signal intensity in the transverse pontine fibers on T 2 -weighted axial image was previously reported to be characteristic in sopca. 12,16 In the present study, almost half (14 of 31) of patients with MJD had the pontine high signal intensity, which presum- 36

Accepted for publication June 3, 1997. This work was supported by a grant-in-aid from the Research Committee of Central Nervous System Degenerative Diseases, the Ministry of Health and Welfare of Japan. We thank Kiyoshi Harada, MD (Department of Neurology, Shizuoka General Hospital, Shizuoka, Japan), and Yuichiro Inatomi, MD (Department of Neurology, Iizuka Hospital, Fukuoka, Japan), for referral of patients, and to Kaori Katayama for photography. Reprints: Yoshio Murata, MD, Third Department of Internal Medicine, Hiroshima University School of Medicine, 1-2-3 Kasumi, Minami-ku, Hiroshima 734, Japan. REFERENCES Figure 3. The proton-weighted axial magnetic resonance images of a 64-year-old woman with Machado-Joseph disease. A high signal intensity in the transverse pontine fibers is observed (arrow). The duration of illness was 3 years. ably reflects the gliosis and myelin sheath loss along the degenerated pontocerebellar fibers elucidated by morphological studies on MJD. 14,17 Age-related pathological changes in pontocerebellar fibers may contribute to the appearance of a high signal intensity in the transverse pontine fibers on T 2 and/or protonweighted MRIs, which can be detected in various cerebellar diseases. 18 Moreover, the pons or midbrain decreases its size and is packed according to aging. Consequently, an abnormal high signal intensity in the pons could be observed in older patients with MJD and is not specific to sopca. Frontal or temporal lobe atrophy or decrease in the transverse diameter of the globus pallidus and the aforementioned findings may fortify the neuroradiological diagnosis of MJD. These MRI findings and the clinical features characteristic of MJD may prompt us to identify the gene responsible for MJD. These results also seem to help the differentiation of MJD from sopca. 1. Nakano KK, Dawson DM, Spence A. Machado disease: a hereditary ataxia in Portuguese emigrants to Massachusetts. Neurology. 1972;22:49-55. 2. Woods BT, Schaumburg HH. Nigro-spino-dentatal degeneration with nuclear ophthalmoplegia: a unique and partially treatable clinico-pathological entity. J Neurol Sci. 1972;17:149-166. 3. Rosenberg RN, Nyhan WL, Bay CMS, Shore P. Autosomal dominant striatonigral degeneration: a clinical, pathologic, and biochemical study of a new genetic disorder. Neurology. 1976;26:703-714. 4. Lima L, Coutinho P. Clinical criteria for diagnosis of Machado-Joseph disease: report of a non-azorean Portuguese family. Neurology. 1980;30:319-322. 5. Healton EB, Brust JCM, Kerr DL, et al. Presumably Azorean disease in a presumably non-portuguese family. Neurology. 1980;30:1084-1089. 6. Sakai T, Ohta M, Ishino H. Joseph disease in a non-portuguese family. Neurology. 1983;33:74-80. 7. Yuasa T, Ohama E, Harayama H, et al. Joseph s disease: clinical and pathological studies in a Japanese family. Ann Neurol. 1986;19:152-157. 8. Bharucha NE, Bharucha EP, Bhabha SK. Machado-Joseph-Azorean disease in India. Arch Neurol. 1986;43:142-144. 9. Suite ND, Sequeiros J, McKhann GM. Machado-Joseph disease in a Sicilian- American family. J Neurogenet. 1986;3:177-182. 10. Maruyama H, Nakamura S, Matsuyama Z, et al. Molecular features of the CAG repeats and clinical manifestation of Machado-Joseph disease. Hum Mol Genet. 1995;4:807-812. 11. Quinn N. Multiple system atrophy. In: Marsden CD, Fahn S, eds. Movement Disorders III. London, England: Butterworths; 1994:262-281. 12. Idezuka J, Onodera O, Yuasa T, et al. MRI findings of olivopontocerebellar atrophy and Machado-Joseph disease: diagnostic value of transverse pontine fibers. Rinsho Shinkeigaku. 1993;33:289-293. 13. Kitamura J, Tsuruta K, Yamamura Y, et al. Five cases of a Joseph disease family with non-rem sleep apnea and MRI study. Rinsho Shinkeigaku. 1987;27:1180-1184. 14. Iwabuchi K, Nagatomo H, Hanihara T, et al. Clinicopathological study on autosomal dominant hereditary spastic ataxia (Greenfield): its relationship to ataxochoreoathetosis form of DRPLA, spinopontine degeneration, Machado-Joseph disease, and SCA3 [in Japanese with English abstract]. Adv Neurol Sci (Tokyo). 1995;39:164-187. 15. Oppenheimer DR, Esiri MM. Diseases of the basal ganglia, cerebellum and motor neurons. In: Adams JH, Duchen LW, eds. Greenfield s Neuropathology. 5th ed. New York, NY: Edward Arnold; 1992:988-1045. 16. Savoiardo M, Strada L, Girotti F. Olivopontocerebellar atrophy: MR diagnosis and relationship to multisystem atrophy. Radiology. 1990;174:693-696. 17. Sachdev HS, Forno LS, Kane CA. Joseph disease: a multisystem degenerative disorder of the nervous system. Neurology. 1989;32:192-195. 18. Yagishita T, Kojima S, Hirayama K. MRI study of degenerative process in multiple system atrophy. Rinsho Shinkeigaku. 1995;35:126-131. 37