Title | Progressive Aphasia and Vision Loss in a Teen-Aged Girl |
Creator | Michael K. Yoon, MD; Aseem Sharma, MD; Joseph Corbo, MD, PhD; Timothy J. McCulley, MD |
Affiliation | Department of Ophthalmology, University of California San Francisco, San Francisco, California |
Subject | Adolescent; Adrenal Cortex Hormones / therapeutic use; Aphasia / diagnosis; Aphasia / etiology; Aphasia / pathology; Corpus Callosum / pathology; Demyelinating Diseases / complications; Demyelinating Diseases / drug therapy; Demyelinating Diseases / pathology; Disease Progression; Female; Humans; Occipital Lobe / pathology; Temporal Lobe / pathology; Treatment Outcome; Vision, Low / diagnosis; Vision, Low / etiology; Vision, Low / pathology; Visual Pathways / pathology |
OCR Text | Show Progressive Aphasia and Vision Loss in a Teen-Aged Girl Michael K. Yoon, MD, Aseem Sharma, MD, Joseph Corbo, MD, PhD, Timothy J. McCulley, MD Dr. Yoon: A 16-year-old female honor student presented for evaluation of vertigo, headache, mild aphasia, and blurred vision. Her symptoms started approximately 2 months earlier when she experienced 3-4 days of intense vertigo and ear pain that waxed and waned and then gradually subsided. Her bifrontal headache initially was intermittent, but over the next several months, increased in severity and duration and by the time of presentation had become persistent. Her family indicated that she un-derstood language normally but was having increasing difficulty with word finding. Visual symptoms were vaguely characterized as blurriness with intermittent dip-lopia. She occasionally stumbled while walking, which she attributed to difficulty seeing. She had no significant medical history. The patient was assessed at another hospital where brain MRI was abnormal. Lumbar puncture revealed a protein of 53 mg/dL (normal, 14-45 mg/dL), glucose of 36 mmol/L (normal, 50-80 mmol/L), 1 leukocyte, and 1 erythrocyte. The opening pressure was not recorded, and cytological examination was not performed. IgG index was normal, and oligoclonal bands were absent. Other unremarkable CSF studies included polymerase chain reaction (PCR) for herpes simplex viruses 1 and 2, cytomegalovirus, and JC virus, assay for myelin basic protein, and staining for acid-fast bacillus. Serologic and blood studies were negative or normal, including white blood cell count, hemoglobin, hematocrit, platelet count, ferritin level, angiotensin-con-verting enzyme, anti-nuclear antibody, single-stranded DNA, double-stranded DNA antibody, PCR for human immunodeficiency virus, rapid plasma reagin, rheumatoid factor, very long-chain fatty acids, Lyme disease, and aquaporin-4 channel antibodies. When evaluated at our institution, the patient's visual acuity was 20/20 in each eye with no relative afferent pupillary defect. Extraocular motility showed slight limi-tation of abduction of the left eye. External examination, anterior segment examination, and intraocular pressure were normal in both eyes. Dilated fundus examination revealed moderate bilateral optic disc swelling (Fig. 1). There was no evidence of vitritis or other posterior seg-ment abnormalities. Automated perimetry revealed a right homonymous hemianopia and a left inferior homonymous quadrantanopia (Fig. 2). The patient had normal vital signs and was afebrile. No abnormalities were found on general physical examination. Neurologic examination revealed normal sensation and strength in the face and extremities. Cerebellar function, deep-tendon reflexes, and gait were normal. The patient's speech was moderately fluid with poor naming of low-frequency objects. Comprehension was moderate with slowing during 3-step commands. Reading was poor, and she was able to write only simple sentences. Brain MRI was obtained. Dr. Sharma: There are 2 lesions identified, both with similar imaging characteristics (Fig. 3). The larger lesion involves the left occipital lobe, extending into the posterior temporal lobe, Section Editor: Neil R. Miller, MD Department of Ophthalmology (MKY), University of California San Francisco, San Francisco, California; Department of Ophthalmology (MKY), Massachusetts Eye and Ear Infirmary, Harvard Medical School, Boston, Massachusetts; Departments of Radiology (AS) and Pathology and Immunology (JC), Washington University School of Medicine, St Louis, Missouri; Department of Ophthalmology (TJM), Wilmer Eye Institute, Johns Hopkins School of Medicine, Baltimore, Maryland; and King Khaled Eye Specialist Hospital (TJM), Riyadh, Saudi Arabia. Supported in part by an unrestricted grant to the Wilmer Oph-thalmological Institute from the Research to Prevent Blindness Inc, New York. The authors report no conflicts of interest. Address correspondence to Timothy J. McCulley, MD, Department of Ophthalmology, Wilmer Eye Institute, Johns Hopkins School of Medicine, 600 NorthWolfe Street, Wilmer 110, Baltimore, MD 21287; E-mail: tmccull5@jhmi.edu Yoon et al: J Neuro-Ophthalmol 2011; 31: 279-284 279 Clinical-Pathological Case Study Copyright © North American Neuro-Ophthalmology Society. Unauthorized reproduction of this article is prohibited. FIG. 1. Right and left optic discs with moderate disc edema. FIG. 2. Automated visual fields showing a right homonymous hemianopia and a left inferior quadrantanopia, with a few abnormal test areas in the remaining left superior homonymous quadrants. 280 Yoon et al: J Neuro-Ophthalmol 2011; 31: 279-284 Clinical-Pathological Case Study Copyright © North American Neuro-Ophthalmology Society. Unauthorized reproduction of this article is prohibited. and the splenium of the corpus callosum. The smaller lesion involves the right occipital lobe. The lesions pre-dominantly involve the white matter. Both lesions dem-onstrate central nonenhancing regions of T1 hypointensity and T2 hyperintensity, with a surrounding incomplete rim of enhancement (Figs. 3A-C). Diffusion restriction is noted along this rim but not centrally (Fig. 3D). A thin zone of vasogenic edema is also seen in the white matter around the enhancing rim (Fig. 3B). The anterior visual pathways and the spinal cord appear normal on imaging (not shown). Dr. Yoon: Because of the concern that the patient had amalignant tumor, a stereotactic biopsy of the right occipital lesion was performed. Dr. Corbo: Sections of the biopsy specimen demonstrated sheets of foamy macrophages associated with interspersed reactive hypertrophic astrocytes and blood vessels (Fig. 4A). A sparse population of reactive lymphocytes is also evident. A luxol fast blue/PAS stain shows extensive loss of myelin, including FIG. 3. T1 axial (A), FLAIR (B), contrast-enhanced T1 (C), and diffusion-weighted (D) MRIs demonstrating right occipital and the left temporo-occipital white matter lesions. Both lesions demonstrate central nonenhancing regions of T1 hypointensity (A) and T2 hyperintensity (B), and incomplete rim of enhancement (C), with minimal perilesional edema. Despite the large size of the lesions, there is a relative lack of mass effect. The central nonenhancing portion does not demonstrate diffusion restriction (D). Decreased apparent diffusion coefficient (ADC) values were noted on the ADC map (not shown), corresponding to the areas of increased signal along the rim of the lesions on diffusion-weighted images. Yoon et al: J Neuro-Ophthalmol 2011; 31: 279-284 281 Clinical-Pathological Case Study Copyright © North American Neuro-Ophthalmology Society. Unauthorized reproduction of this article is prohibited. some macrophages with fragments of partially metabolized myelin in their cytoplasm (Fig. 4B). An immunohisto-chemical stain for neurofilament shows relative preservation of axons (Fig. 4C). An occasional axonal spheroid is also apparent. There is no evidence of either a glioma or a lymphoma. Final Diagnosis: Tumefactive demyelinating lesion. Dr. Yoon: Following biopsy, the patient began treatment with in-travenous methylprednisolone 1 g daily. Over the next several days, she showed modest improvement with a stable ophthalmologic examination. The treatment was continued for 5 days, following which the patient was placed on oral prednisone for several weeks. At the last follow-up 4 months later, the patient's visual acuity was still 20/20 bilaterally, with minimal improvement in her visual fields but complete resolution of her optic disc swelling. Most authors define tumefactive demyelinating lesions (TDLs) as focal areas of demyelination of greater than 2 cm in size (1). Causative diseases include multiple sclerosis (MS), acute disseminated encephalomyelitis (2), neuro-myelitis optica (3), and myelinoclastic diffuse sclerosis (Schilder disease) (4). TDLs are rare in the pediatric pop-ulation with approximately 30 cases reported in the liter-ature (1,2,4-22). On neuroradiological studies, these lesions may mimic both intracranial abscess and tumor, making diagnosis difficult to establish by imaging alone. There are no pathognomonic imaging characteristics that distinguish TDLs from other lesions; however, there are several neuroimaging features that may help suggest the correct diagnosis. On MRI, TDLs have variable degrees of mass effect and edema, but typically, there is relatively little compared with a similarly sized neoplasm, infiltrate, or infarct (10,21,23). A classic finding associated with TDLs is the ‘‘open-ring'' enhancement of the lesion. This appear-ance is believed to result from contrast leaking from an incomplete ring of active inflammation with the loss of the normal blood-brain barrier surrounding the lesion. The incomplete portion typically abuts the gray matter or basal ganglia (24,25); however, this is not a uniform finding, as Kiriyama et al (21) found this in only 4 of 14 patients in their series. A T2 hypointense rim is found in the majority of patients with a TDL. A central dilated vascular structure may be seen within the lesion on T2 echnoplanar imaging, believed to be a dilated vein draining toward subependymal veins (26). Zivadinov et al (27) noted venular dilation and enhancement within 57% of TDLs, consistent with focal vascular structural abnormalities without vascular destruction. Despite the above findings on MRI, the diagnosis of a TDL can be difficult. For example, Riva et al (18) reported a 10-year-old girl with rapidly progressive headache, pro-jectile vomiting, and mild right hemiparesis over days. The MRI findings were thought to be most consistent with a high-grade malignancy, but an excisional biopsy revealed FIG. 4. Right occipital biopsy. A. There are sheets of foamy macrophages (arrowhead) in a background of re-active astrocytes (arrow) (hematoxylin and eosin, 3400). B. Luxol fast blue/PAS stain showing extensive loss of myelin (3200). C. Neurofilament immunostain revealing relative preservation of axons in the areas of de-myelination (3200). 282 Yoon et al: J Neuro-Ophthalmol 2011; 31: 279-284 Clinical-Pathological Case Study Copyright © North American Neuro-Ophthalmology Society. Unauthorized reproduction of this article is prohibited. a TDL. Other cases with similarly misleading or nonspecific imaging findings have been published (5,7,28,29). Other imaging modalities may improve diagnostic spec-ificity. The combination of typical features on conventional MRI as well as hypoattenuation of the lesion rim in un-enhanced CT is characteristic for TDL and usually not seen in glioma or lymphoproliferative disease (23). A report dealing with MRI perfusion suggested that a lower relative cerebral blood volume (rCBV ,0.883 the contralateral normal white matter) was more suggestive of a TDL than a neoplasm (26). In this study, intracranial neoplasms had elevated rCBVs greater than 6 times those on the contra-lateral normal side. Tsui et al (30) published a single case report in which there also was no elevation in perfusion in the TDL (30). However, it has also been shown that theremay be no significant difference in normalized rCBV values in TDLs compared with gliomas (31). Magnetic resonance spectroscopy has been assessed for its ability to distinguish tumefactive lesions from neoplasms. Elevations in glutamate, glutamine, choline, lactate, and lipid peaks, with a decrease in the N-acetyl-aspartate peak, have been described (17,31,32). Yet other studies, however, have demonstrated similarities in spectroscopy findings in both gliomas and TDLs (28). Stereotactic biopsy often is employed in cases of lesions in which the differential diagnosis includes TDL, in-tracranial abscess, and neoplasm. Although this may be the only way to obtain a definitive diagnosis, potential com-plications of the procedure include hematoma, herniation, infection, neurologic deficits related to the site of the biopsy, and death (0.3%-0.7%). The overall risk of a biopsy-related complication is approximately 3.5% (33,34). Despite these risks, brain biopsy is diagnostic in the majority of cases. Analysis of intraoperative frozen sections can, in many cases, obviate inappropriate surgical excision in patients with a presumed diagnosis of glioma who turn out to have a TDL. Although intracranial pressure (ICP) was not measured in our patient, elevated ICP was likely the cause of her optic disk swelling. We are unaware of any previously published cases of TDL associated with elevated ICP. Newman et al (35) described 3 patients with MS without TDLs but with elevated ICP with papilledema (35). Although the exact mechanism remains speculative, they attributed the eleva-tion in ICP to the demyelinative disease. The diagnostic challenge in this case centered on whether a confirmatory biopsy was necessary. The patient presented with a first episode of neurologic deficit consisting of aphasia and visual loss, without a previous demyelinating event. Although the MRI findings were consistent with a TDL, neither oligoclonal bands nor myelin basic protein were present in the CSF, and the IgG index in the CSF was normal. Also, the patient had papilledema, an infrequent finding in patients with demyelinating disease. Given the potential risk of a delay in diagnosis, the decision was made to proceed with a biopsy that established the correct diagnosis. ACKNOWLEDGMENT The authors thank Michelle Madden, MD, for her prep-aration of the histopathology figures. REFERENCES 1. Lucchinetti CF, Gavrilova RH, Metz I, Parisi JE, Scheithauer BW, Weigand S, Thomsen K, Mandrekar J, Altintas A, Erickson BJ, Konig F, Giannini C, Lassmann H, Linbo L, Pittock SJ, Bruck W. Clinical and radiographic spectrum of pathologically confirmed tumefactive multiple sclerosis. Brain. 2008;131:1759- 1775. 2. Kepes JJ. Large focal tumor-like demyelinating lesions of the brain: intermediate entity between multiple sclerosis and acute disseminated encephalomyelitis? A study of 31 patients. Ann Neurol. 1993;33:18-27. 3. Nakamura M, Endo M, Murakami K, Konno H, Fujihara K, Itoyama Y. An autopsied case of neuromyelitis optica with a large cavitary cerebral lesion. Mult Scler. 2005;11: 735-738. 4. Afifi AK, Bell WE, Menezes AH, Moore SA. Myelinoclastic diffuse sclerosis (Schilder's disease): report of a case and review of the literature. J Child Neurol. 1994;9:398-403. 5. Hunter SB, Ballinger WE Jr, Rubin JJ. Multiple sclerosis mimicking primary brain tumor. Arch Pathol Lab Med. 1987; 111:464-468. 6. Gutling E, Landis T. CT ring sign imitating tumour, disclosed as multiple sclerosis by MRI: a case report. J Neurol Neurosurg Psychiatry. 1989;52:903-906. 7. Giang DW, Poduri KR, Eskin TA, Ketonen LM, Friedman PA, Wang DD, Herndon RM. Multiple sclerosis masquerading as a mass lesion. Neuroradiology. 1992;34:150-154. 8. Peterson K, Rosenblum MK, Powers JM, Alvord E, Walker RW, Posner JB. Effect of brain irradiation on demyelinating lesions. Neurology. 1993;43:2105-2112. 9. Rusin JA, Vezina LG, Chadduck WM, Chandra RS. Tumoral multiple sclerosis of the cerebellum in a child. Am J Neuroradiol. 1995;16:1164-1166. 10. Dagher AP, Smirniotopoulos J. Tumefactive demyelinating lesions. Neuroradiology. 1996;38:560-565. 11. Case Records of the Massachusetts General Hospital. Weekly clinicopathological exercises. Case 26- 1998. A 15- year-old girl with hemiparesis, slurred speech, and an intracranial lesion. N Engl J Med. 1998;339:542-549. 12. McAdam LC, Blaser SI, Banwell BL. Pediatric tumefactive demyelination: case series and review of the literature. Pediatr Neurol. 2002;26:18-25. 13. Yapici Z, Eraksoy M. Bilateral demyelinating tumefactive lesions in three children with hemiparesis. J Child Neurol. 2002;17:655-660. 14. Obara S, Takeshima H, Awa R, Yonezawa H, Oyoshi T, Nagayama T, Hirano H, Niiro M, Kuratsu J. Tumefactive myelinoclastic diffuse sclerosis. Neurol Med Chir (Tokyo). 2003;43:563-566. 15. Anderson RC, Connolly ES Jr, Kmotar RJ, Mack WJ, McKhann GM, Van Orman CB, Hedlund G, Proctor KA, Townsend JJ, Walker ML. Clinicopathological review: tumefactive demyelination in a 12-year-old girl. Neurosurgery. 2005;56:1051-1057. 16. Puri V, Chaudhry N, Gulati P, Tatke M, Singh D. Recurrent tumefactive demyelination in a child. J Clin Neurosci. 2005; 12:495-500. 17. Cianfoni A, Niku S, Imbesi SG. Metabolite findings in tumefactive demyelinating lesions utilizing short echo time proton magnetic resonance spectroscopy. Am J Neuroradiol. 2007;28:272-277. Yoon et al: J Neuro-Ophthalmol 2011; 31: 279-284 283 Clinical-Pathological Case Study Copyright © North American Neuro-Ophthalmology Society. Unauthorized reproduction of this article is prohibited. 18. Riva D, Chiapparini L, Pollo B, Balestrini MR, Massimino M, Milani N. A case of pediatric tumefactive demyelinating lesion misdiagnosed and treated as glioblastoma. J Child Neurol. 2008;23:944-947. 19. Malhorta HS, Jain KK, Agarwal A, Singh MK, Yadav SK, Husain M, Krishnani N, Gupta RK. Characterization of tumefactive demyelinating lesions using MR imaging and in-vivo proton MR spectroscopy. Mult Scler. 2009;15: 193-203. 20. Xia L, Lin S, Wang ZC, Li SW, Xu L, Wu J, Hao SY, Gao CC. Tumefactive demyelinating lesions: nine cases and review of the literature. Neurosurg Rev. 2009;32:171-179. 21. Kiriyama T, Kataoka H, Taoka T, Tonomura Y, Terashima M, Morikawa M, Tanizawa E, Kawahara M, Furiya Y, Sugie K, Kichikawa K, Ueno S. Characteristic neuroimaging in patients with tumefactive demyelinating lesions exceeding 30 mm. J Neuroimaging. 2011;21:e69-e77. 22. VanLandingham M, Hanigan W, Vedanarayanan V, Fratkin J. An uncommon illness with a rare presentation: neurosurgical management of ADEM with tumefactive demyelination in children. Childs Nerv Syst. 2010;26:655-661. 23. Kim DS, Na DG, Kim KH, Kim JH, Kim EH, Yun BL, Chang KH. Distinguishing tumefactive demyelinating lesions from glioma or central nervous system lymphoma: added value of unenhanced CT compared with conventional contrast-enhanced MR imaging. Radiology. 2009;251:467-475. 24. Masdeu JC, Moreira J, Trasi S, Visintainer P, Cavaliere R, Grundman M. The open ring. A new imaging sign in demyelinating disease. Neuroimaging. 1996;6:104-107. 25. Masdeu JC, Quinto C, Olivera C, Tenner M, Leslie D, Visintainer P. Open-ring imaging sign: highly specific for atypical brain demyelination. Neurology. 2000;54: 1427-1433. 26. Cha S, Pierce S, Knopp EA, Johnson G, Yang C, Ton A, Litt AW, Zagzag D. Dynamic contrast-enhanced T2*-weighted MR imaging of tumefactive demyelinating lesions. Am J Neuroradiol. 2001;22:1109-1116. 27. Zivadinov R, Minagar A. Evidence for gray matter pathology in multiple sclerosis: a neuroimaging approach. J Neurol Sci. 2009;282:1-4. 28. Saindane AM, Cha S, Law M, Xue X, Knopp EA, Zagzag D. Proton MR spectroscopy of tumefactive demyelinating lesions. AJNR Am J Neuroradiol. 2002;23:1378-1386. 29. Nesbit GM, Forbes GS, Scheithauer BW, Okazaki H, Rodriguez M. Multiple sclerosis: histopathologic and MR and/or CT correlation in 37 cases at biopsy and three cases at autopsy. Radiology. 1991;180:467-474. 30. Tsui EY, Leung WH, Chan JH, Cheung YK, Ng SH. Tumefactive demyelinating lesions by combined perfusion-weighted and diffusion weighted imaging. Comput Med Imaging Graph. 2002;26:343-346. 31. Blasel S, Pfelschifter W, Jansen V, Muellser K, Zanella F, Hattingen E. Metabolism and regional cerebral blood volume in autoimmune inflammatory demyelinating lesions mimicking malignant gliomas. J Neurol. 2011;258: 113-122. 32. Masu K, Beppu T, Fujiwara S, Kizawa H, Kashimura H, Kurose A, Ogasawara K, Sasaki M. Proton magnetic resonance spectroscopy and diffusion-weighted imaging of tumefactive demyelinating plaque. Neurol Med Chir (Tokyo). 2009;49:430-433. 33. Hall WA. The safety and efficacy of stereotactic biopsy for intracranial lesions. Cancer. 1998;82:1749- 1755. 34. Tian ZM, Wang YM, Yu X, Zhao QJ, Hui R, Liu R, Li ZC. [Clinical experience of stereotactic biopsy for the brain lesions]. Zhonghua Wai Ke Za Zhi. 2010;48: 1459-1462. 35. Newman NJ, Selzer KA, Bell RA. Association of multiple sclerosis and intracranial hypertension. J Neuroophthalmol. 1994;14:189-192. 284 Yoon et al: J Neuro-Ophthalmol 2011; 31: 279-284 Clinical-Pathological Case Study Copyright © North American Neuro-Ophthalmology Society. Unauthorized reproduction of this article is prohibited. |
Date | 2011-09 |
Language | eng |
Format | application/pdf |
Type | Text |
Publication Type | Journal Article |
Collection | Neuro-Ophthalmology Virtual Education Library: Journal of Neuro-Ophthalmology Archives: https://novel.utah.edu/jno/ |
Publisher | Lippincott, Williams & Wilkins |
Holding Institution | Spencer S. Eccles Health Sciences Library, University of Utah |
Rights Management | © North American Neuro-Ophthalmology Society |
ARK | ark:/87278/s6bc74n7 |
Setname | ehsl_novel_jno |
ID | 227190 |
Reference URL | https://collections.lib.utah.edu/ark:/87278/s6bc74n7 |