| OCR Text |
Show Journal of Clinical Neuro- ophthalmology 10( 3); 206- 209, 1990. © 1990 Raven Press, Ltd / ork Diabetic Complete External Ophthalmoplegia Cristian F. Luco, M. D., and Raul F. Valenzuela, M. D. A 69- year- old diabetic patient taking oral hypoglycemic drugs and with no systemic complications presented a right peripheral facial palsy, and 2 months later a complete right external ophthalmoplegia with sparing of the pupillary function. Clinical, radiologic, and other laboratory investigation ruled out compressive, infectious, and inflammatory etiology. Four months later, after achieving good metabolic control, there was almost complete recovery of the ophthalmoplegia without signs of aberrant regeneration of the third nerve. Diabetes is proposed as the etiology of this case. A possible anatomic substrate is presented to explain the findings. Key Words: Diabetes- Facial palsy- Ophthalmoplegia. From the Department of Neurology and Neurosurgery, Neurophthalmology Section, School of Medicine, Universidad Cat6lica de Chile, Instituto de Neurocirugfa, Universidad de Chile and Oftalm6logos Asociados; and Department of Neurology and Neurosurgery ( R. F. V.), School of Medicine, Universidad Cat6lica de Chile, Santiago, Chile. Address correspondence and reprint requests to Dr. Christian F. Luco at the Department of Neurology and Neurosurgery, School of Medicine, Universidad Cat6lica de Chile, Santiago, Chile. 206 The oculomotor nerve nuclei are located in the brainstem, from which the nerve fibers emerge, and after travelling across the base of the cranial cavity, reach the ocular muscles in the orbit. Neurologic lesions involving the oculomotor nerve trunks or their nuclei produce paresis of the corresponding muscles which must be differentiated from mechanical or muscular disorders that might simulate a neurologic lesion ( 1- 3). Oculomotor nerve palsies may have numerous causes, and the most frequent ones are those that stretch or compress the nerve trunks, such as direct injury, aneurysm, or neoplasm. Less frequent causes are metabolic, ischemic, infiltrating, or demyelinating lesions ( 4,5). In large series, diabetes mellitus is not an infrequent cause of oculomotor nerve palsies. The sixth nerve is the most frequently involved ( 6) cranial nerve in diabetic ophthalmoplegia, although some have reported that the sixth and the third cranial nerves are equally affected ( 4,5,7). Diabetes rarely causes multiple simultaneous oculomotor nerve palsies, and thus, these cases must be thoroughly investigated to exclude other causes ( 1,3). Ischemia as the mechanism of diabetic oculomotor nerve palsies was histopathologically demonstrated by Dreyfus ( 8), Asbury ( 9), and Weber ( 10) by studying affected third nerves in diabetic patients. They demonstrated central core infarction of the nerve trunk with sparing of peripheral fibers. This mechanism also explains why pupillary fibers, which run in the periphery of the nerve, are spared; this is a characteristic sign of medical ( nonsurgical) palsy of the third nerve. In fact the finding of a spared pupil in a third nerve palsy of compressive etiology is exceptional ( 11). We recently studied a diabetic patient who developed a unilateral complete ophthalmoplegia without pupillary function involvement. DIABETIC OPHTHALMOPLEGIA 207 FIG. 1. Evolution of right peripheral facial palsy ( left side photograph was taken on November 28, 1988; right side photograph was taken on February 2, 1989). CASE REPORT A 69- year- old diabetic man who had no systemic complications had been treated with oral hypoglycemic drugs ( glibenclamide) for 10 years. His complaints began with a right peripheral facial palsy, without hyperacusis or chorda tympani involvement, which recovered at a very slow rate. Fasting blood glucose was 276 mg % at that time. Two months later he suddenly developed severe diplopia and right supraciliary mild pain which disappeared in about 1 week. Three weeks later he sought medical help. On examination his blood pressure was 145/ 80. General physical examination, blood count, erythrocyte sedimentation rate, cholesterol, and chest x- ray were normal. Fasting blood glucose was 234 mg %. Neurological examination disclosed a right peripheral facial palsy ( Fig. 1), diffuse deep tendon hyporeflexia, moderate distal unilateral hypoesthesia of the lower limb, and paresthesias of both lower limbs. Cerebrospinal fluid ( CSF) examination showed glucose 123 mg %, protein 86 mg %, cells 0.5 mm3 . Bacteriological studies and cytological examination for neoplastic cells in CSF were all negative. Neurophthalmological examination showed a corrected visual acuity of 20/ 25 in 00 and 20/ 20 in OS. Pupils were equal in size and both reacted briskly to light. Ocular motility tests demonstrated severe paresis of all extrinsic muscles and ptosis of the right eyelid ( Fig. 2). There was no exophthalmos. Fundoscopy showed normal papillae, a few microaneurysms, and small hemorrhages. Visual fields were normal. At the anterior pole there were no signs of vascular congestion, nor orbital or periorbital bruits. A high resolution computed tomography ( CT) scan did not show lesions in the orbit, cavernous sinus, cranial base, or brainstem. In the follOWing weeks, good metabolic control was achieved with diet and drug adjustment. Eleven weeks later, he began to recover motility of all right eye extrinsic muscles, but he still had important residual paresis with diplopia. At that time the ptosis had diminished, but the facial palsy remained. A 4- month follow- up examination showed significant recovery of facial palsy ( Fig. 1), and no changes in neurologic signs of the limbs. Neuroophthalmologic examination demonstrated a very important recovery of ocular motility, with slight limitation of lateral rectus and superior oblique muscles of the right eye ( Fig. 3), and absence of any sign of aberrant regeneration of the third nerve. At follow- up late in 1989, serum VORL and serum Lyme enzyme- linked immunosorbent assay ( ELISA) tests were negative in our laboratory and checked ( also negative) in the Louis Pasteur Institute in France. Figs. 4 and 5 show the patient's current appearance, with notable clearing of the right facial paresis, but subtle aberrant regeneration of the right facial nerve is now evident. DISCUSSION Each ocular motor nerve has its own separate pathway and they approach each other at the cavernous sinus. A multiple ocular motor nerve dysfunction tends to localize the lesion in the cavernous sinus or distally. An isolated nerve dysfunction does not allow a precise topographic localization since the lesion could be at any place FIG. 2. Ocular movements during acute phase of right ophthalmoplegia ( picture taken on November 28, 1988). JClin Neuro- ophthalmol. Vol. 10, No. 3. 1990 208 C. F. LueD AND R. F. VALENZUELA FIG. 3. Photograph taken on February 2, 1989 demonstrates very important recovery of ocular motility; a slight limitation of superior oblique and lateral rectus muscles still remains. from the nucleus to the orbit. Our patient had multiple nerve involvement which led us to clinically localize the lesion in the cavernous sinus. Causes of cavernous sinus syndrome are numerous: infraclinoidal aneurysms, primary or metastatic tu- FIG. 4. Taken late 1989; shows improvement of right facial paresis. I Gin Nnlro- ophthalmol, Vol. 10. No. 3. 1990 mors, inflammatory and vascular provo.:'; es, etc. ( 1,4,5). A high resolution CT scan excluded a structural lesion of the orbit, the cavernous sinus and the brainstem. The only associated illness this patient had was a decompensated diabetes, therefore a diabetic ophthalmoplegia was diagnosed. The evolution of the ophthalmoplegia into spontaneous resolution ( by achieving metabolic control) and the absence of aberrant regeneration signs in the third nerve, made compression a highly improbable cause of the ophthalmoplegia. Meningeal carcinomatosis, mucormycosis, or an intracranial neoplasia were ruled out with the clinical evolution; CT scan and normal CSF [ the increased level of CSF protein is in the range of values frequently encountered in diabetic neuropathy ( 12,13)]. In Tolosa- Hunt syndrome severe periorbital pain is a very important sign ( 14- 16) which was almost absent in this patient who had only a slight and transient supraciliary pain with the severe ophthalmoplegia. The singularity of this case is the simultaneous multiple paralysis of the three ocular motor nerves which has been reported in the literature as very infrequent in diabetes ( 2,3,6,7,17) and is not even mentioned in some large series ( 4,5). Weber ( 10) demonstrated a central core infarction at the subarachnoidal portion of the third nerve in a diabetic FIG. 5. Same date as Fig. 4, showing aberrant regeneration of right VII ( arrow). DIABETIC OPHTHALMOPLEGIA 209 patient with a oculomotor palsy. In our patients, we believe, as in the cases of Dreyfus and Asbury ( 8,9), that the ocular motor nerves were damaged at the cavernous sinus where they have common nutrient vessels ( 18-- 20). The internal carotid artery at its intracavernous portion gives off three branches: the meningohypophysial trunk, the inferior artery of the cavernous sinus and the capsular artery. The meningohypophysial trunk gives off three smaller branches: the tentorial artery which irrigates the third and fourth cranial nerves, the dorsomeningeal artery that irrigates the sixth nerve and the inferior hypophysial artery. The inferior artery of the cavernous sinus irrigates the third, fourth and sixth cranial nerves in almost all their intracavernous portion ( 18). In this patient probably one of these small arteries was occluded, perhaps the inferior cavernous sinus artery which could have suffered a diabetic angiopathy leading to ischemia of all three ocular motor nerves. Without histopathology we cannot be certain of the exact etiology of the ophthalmoplegia in our patient, but clinically the patient had an evolution consistent with a diabetic neuropathy, recovering when good metabolic control was achieved and having excluded all other common causes. REFERENCES 1. Bosley T, Schatz N. Clinical diagnosis of cavernous syndromes. In: Neurologic clinics 1983; 4: 929- 49. 2. Ross, A. Recurrent cranial nerve palsies in diabetes mellitus. Neurology 1962; 12: 180- 5. 3. Sergott R, Glaser J, Berger L. Simultaneous bilateral dia-betic ophthalmoplegia. Report of two cases and discussion of differential diagnosis. Ophthalmology 1984; 91: 18- 22. 4. Rucker CWo The causes of paralysis of the third, fourth and sixth cranial nerves. Am JOphthalmol 1966; 61: 1293-- 8. 5. Rucker CWo Paralysis of the third, fourth and sixth cranial nerves. Am JOphthalmoI1958; 46: 787- 94. 6. Collier J. Paralysis of the oculomotor nerve trunks in diabetes. Proc R Soc Med 1930; 23: 627- 30. 7. Walsh FB, Hoyt WF. Clinical Neuro- Ophthalmology. Vol II 3rd Ed. Baltimore: William and Wilkins, 1969: 1109- 20. 8. Dreyfus PM, Hakim S, Adams RD. Diabetic ophthalmoplegia: report of case with post- mortem study and comments on vascular supply of human oculomotor nerve. Arch NeuroI1957; 77: 337- 49. 9. Asbury AK, Aldredge H, Hershberg R, Fischer CM. Oculomotor palsy in diabetes mellitus: a clinicopathological study. Brain 1970; 93: 555- 66. 10. Weber RB, Daroff RB, Mackey EA. Pathology of oculomotor palsy in diabetes mellitus. Neural 1970; 20: 835- 8. 11. Trobe JD. Third nerve palsy and pupil, footnotes to rule. Arch Ophthalmol 1988; 102: 601. 12. Thomas PK, Eliasson SG. Diabetic neuropathy. In: Dyck T, Lambert B, eds. Peripheral Neuropathy. 2nd ed. Philadelphia: Saunders Co, 1984: 1787. 13. Fishman R. In: Cerebrospinal fluid in diseases of the nervous system. Philadelphia: Saunders Co, 1984: 317- 8. 14. Tolosa E. Periarteritic lesions of the carotid siphon with the clinical features of a carotid infraclinoidal aneurysm. J Neural Neurosurg and Psychiat 1954; 19: 300- 2. 15. Hunt W, Meagher IN, Le Fever HE, Zeman W. Painful ophthalmoplegia: its relation to indolent inflammation of the cavernous sinus. Neural 1961; 11: 56- 62. 16. Hunt W. Tolosa- Hunt syndrome: one cause of painful ophthalmoplegia. J Neurosurg 1976; 44: 544-- 9. 17. Jabs DA, Miller NR, Green WR. Ischaemic optic neuropathy with painful ophthalmoplegia in diabetes mellitus. Br J Ophthalmology 1981; 65: 673-- 8. 18. Parkinson D. Anatomy of the " cavernous sinus". In: J. L. Smith, ed. Neurophthalmology Vol. VI, St. Louis: The C. V. Mosby Co., 1972: 73. 19. Tran Dinh H. Cavernous branches of the internal carotid artery. Anatomy and nomenclature. Neurosurg 1987; 20: 205. 20. Willinsky R, Lasjunias P, Bicetre K. ICA cavernous branches. Neurosurg 1987; 21: 130- 1. J Clin Neuro- ophthalmol, Vol. 10, No. 3, 1990 |
