Journal of Neuro-Ophthalmology, March 2005, Volume 25, Issue 1

Segmental Facial Anhidrosis and Tonic Pupils with Preserved Deep Tendon Reflexes

A 31-year-old woman had exertional right-sided hemifacial flushing and sweating. Examination demonstrated slightly dilated pupils with absent constriction to light and a tonic near response and redilatation, features consistent with Adie syndrome. Neurological examination was otherwise normal, including preservation of deep tendon reflexes. Magnetic resonance imaging of brain and spine were normal. The combination of unilateral loss of sudomotor and vasomotor activity without loss of ocular sympathetic innervation fulfills the diagnosis of Harlequin syndrome. The combination of Harlequin and Adie syndromes has been called Ross syndrome, but the preservation of deep tendon reflexes precludes a diagnosis of Ross syndrome in our patient. This previously undescribed variant adds further complexity to the spectrum of autonomic neuropathies.

ORIGINAL CONTRIBUTION Segmental Facial Anhidrosis and Tonic Pupils With Preserved Deep Tendon Reflexes: A Novel Autonomic Neuropathy Freny B. Kalapesi, BSc ( Med), MBBS, Arun V. Krishnan, MBBS, FRACP, and Matthew C. Kiernan, PhD, FRACP Abstract: A 31 - year- old woman had exertional right- sided hemifacial flushing and sweating. Examination demonstrat­ed slightly dilated pupils with absent constriction to light and a tonic near response and redilatation, features consistent with Adie syndrome. Neurological examination was other­wise normal, including preservation of deep tendon reflexes. Magnetic resonance imaging of brain and spine were normal. The combination of unilateral loss of sudomotor and vasomotor activity without loss of ocular sympathetic innervation fulfills the diagnosis of Harlequin syndrome. The combination of Harlequin and Adie syndromes has been called Ross syndrome, but the preservation of deep tendon reflexes precludes a diagnosis of Ross syndrome in our patient. This previously undescribed variant adds further complexity to the spectrum of autonomic neuropathies. (/ Neuro- Ophthalmol 2005 ; 25: 5- 8) Unilateral loss of hemifacial sudomotor and vasomotor activity with normal ocular sympathetic innervation was first described by Lance and Drummond ( 1) in five patients with unilateral facial anhidrosis and reduced facial flushing in the absence of the characteristic pupillary abnormalities of Horner syndrome. The authors named this condition " Harlequin syndrome" after the Italian clown or English pantomime character ( 1,2). Autonomic testing in these patients, involving electrical stimulation of the motor cortex, suggested a selective lesion affecting the second thoracic nerve root, thus explaining the unilateral facial abnormalities with relative sparing of the sympathetic innervation to the pupil. In certain patients, unilateral facial anhidrosis may coexist with tonic pupils and depressed Department of Ophthalmology ( F. B. K.), Division of Surgery, Prince of Wales Clinical School, University of New South Wales, Sydney, Australia; Institute of Neurological Sciences ( A. VK., M. C. K.), Prince of Wales Hospital, Sydney, Australia; Prince of Wales Medical Research Institute ( A. VK., M. C. K.), University of New South Wales, Sydney, Australia Address Correspondence to Matthew Kiernan, MD, Prince of Wales Med. Research Institute, Barker Street, Randwick, Sydney, NSW 2031, Australia; E- mail: M. Kiernan@ unsw. edu. au deep tendon reflexes, now referred to as Ross syndrome ( 3,4). The present case report describes an unusual case of unilateral facial anhidrosis in conjunction with bilateral tonic pupils and preserved deep tendon reflexes, adding to the spectrum of focal autonomic disorders characterized by pupillary dysautonomia and facial sudomotor and vaso­motor changes. CASE REPORT A 31- year- old woman had a 2- year history of right-sided hemifacial flushing and sweating after moderate physical exertion. Her partner first noticed this after they had been rollerblading. Subsequently, she noticed the development of right- sided facial flushing and sweating of the right forehead, nose, cheek, and chin starting approx­imately 30 minutes after vigorous gardening, playing netball, going to the gym, and swimming. Other precipitants in­cluded eating chilies and spicy meals. Over the same 2- year period, the patient had observed the development of relative dilatation of the left pupil, the size of which varied during the course of the day. There was no history of ptosis, diplopia, or ocular pain. There was no history of syphilis, varicella zoster, ocular trauma, previous spinal surgery, migraine, or other headache. The patient did not have diabetes mellitus or describe palpitations or postural dizziness that may have suggested the presence of a generalized autonomic dis­turbance. Uncorrected visual acuities were 20/ 15 OD and 20/ 20 OS. There was no ptosis. The right pupil measured 5 mm and the left pupil 7 mm in dim illumination. Pupillary reaction to direct light was absent bilaterally. There was a slow tonic near response accompanied by slow redilatation on fixating a distant target. The patient did not have a relative afferent pupillary defect. Slit- lamp examination revealed vermiform move­ments of the pupil margin with sectoral paralysis of the iris sphincter OU Intraocular pressures were 18 mm Hg OU J Neuro- Ophthalmol, Vol. 25, No. 1, 2005 5 J Neuro- Ophthalmol, Vol. 25, No. 1, 2005 Kalapesi et al FIG. 1. Our patient immediately after exertion. There is loss of normal flushing and sweating on the left face ( A) and a dilated left pupil ( B). Side views highlight the normal flushing on the right face ( C) and absent flushing on the left face ( D). Color vision was normal on Ishihara plate examination. Ophthalmoscopy was normal. Visual fields were full to confrontation. Cranial nerve examination was otherwise normal. There was no apparent difference in facial color or sweating between the two sides of the face at room tem­perature. On exertion, however, there was loss of flushing and sweating over the left side of the face, whereas the right side appeared normally flushed and moist with perspiration ( Fig. 1). Limb examination revealed symmetrically normal muscle bulk, tone, and power. Importantly, deep tendon reflexes were easily elicited in all four limbs. There were no sensory abnormalities. There was no postural hypotension or other clinical features to suggest the presence of a generalized autonomic disturbance. Magnetic resonance imaging ( MRI) of the cervical and upper thoracic cord was normal. The patient then became pregnant and declined topical pharmacological evaluation of ocular autonomic dysfunction because of concerns of teratogenicity ( 5). A diagnosis of Harlequin syndrome with bilateral Adie syndrome was made to explain the unusual com­bination of signs. The preservation of deep tendon reflexes excluded a diagnosis of Ross syndrome. DISCUSSION Harlequin syndrome has been described as an iso­lated finding ( 6,7), in association with a superior medi­astinal neurinoma along the preganglionic sympathetic pathway ( 8), or postoperatively ( 9- 11). Internal jugular catheterization ( 9), neck surgery ( 10), and bilateral sym­pathectomy for hyperhidrosis have also been described as precipitants of the syndrome. The right- sided facial flushing of our patient is on the side of an intact sympathetic pathway. As pointed out by Lance and Drummond ( 1), the flushing and sweating experienced on the sympathetically intact side may be an overreaction to the contralateral denervation to provide normal heat control. Sympathetic hyperactivity has been reported contralateral to a cervical sympathectomy ( 11). The apparent dissociation between intact sympathetic function in the eye and unilaterally impaired vasomotor sympathetic function on the face in our patient could be 2005 Lippincott Williams & Wilkins Segmental Facial Anhidrosis and Tonic Pupils J Neuro- Ophthalmol, Vol. 25, No. 1, 2005 Internal Carotid Nerve Internal Carotid Artery FIG. 2. Facial and ocular autonomic sympathetic innervation. The second preganglionic neuron sympathetic supply to the eye leaves the spinal cord in the first thoracic nerve root ( T1); the sympathetic vasomotor and sudomotor supply to the face leaves the spinal column at T2 and T3. The pupillomotor and sudomotor/ vasomotor pathways synapse ( diamonds) in the superior cervical ganglion ( SCG). From there, pupillomotor fibers to the eyes and sudomotor/ vasomotor fibers to the forehead travel along the internal carotid artery, whereas sudomotor/ vasomotor fibers to the face travel along the external carotid artery. SCG = superior cervical ganglion, ICG = inferior cervical ganglion, T2 = second thoracic root, T3 = third thoracic root. explained by the fact that most sympathetic fibers destined for the pupil and levator palpebrae superioris ( LPS) leave the spinal cord in the first thoracic root above T2. The cervical sympathetic pathway is a three- neuron pathway. The first neuron ( preganglionic) passes from the hypothal­amus through the brainstem to the intermediolateral column in the thoracic spinal cord; the second ( also preganglionic) neuron passes from the spinal cord through the stellate ganglion to the superior cervical ganglion, where it synapses; and the third ( postganglionic) neuron passes from the superior cervical ganglion to the pupil, the LPS muscle, blood vessels of the eye and face, and the sweat glands of the face ( Fig. 2). Although vasodilator and sudomotor fibers destined for blood vessels and sweat glands of the face arise between the eighth cervical and fourth thoracic levels, most fibers 7 J Neuro- Ophthalmol, Vol. 25, No. 1, 2005 Kalapesi et al appear to arise from the second and third thoracic levels ( 1,12,13). Hence, a preganglionic, second- order neuronal sympathetic lesion in the T2 or T3 root might explain the loss of facial sweating and flushing without the occurrence of Horner syndrome ( Fig. 2). In their original report, Lance and Drummond ( 1) postulated that ischemia from anterior radicular artery occlusion from thoracic torsion during strenuous exercise might underlie Harlequin syndrome. In our patient, no lesion was detected on MRI of the spinal cord. Nor would a lesion at the T2- T3 spinal segments explain the Adie syndrome in our patient. Another localizing feature is the territory of sweating impairment, specifically whether it is hemifacial or merely limited to the upper face. Previous studies have shown that lesions distal to the bifurcation of the common carotid artery cause impairment of sweating confined to the forehead, periocular skin, and upper nose, whereas more proximal lesions produce sudomotor and vasomotor loss involving half of the face unless the lesion lies in the brachial plexus. Fibers innervating sweat glands and blood vessels of the medial forehead travel intracranially with the internal carotid artery, whereas fibers supplying the entire hemiface travel with the external carotid artery ( 6,12,14,15). Our patient experienced hemifacial loss of facial sweating and flushing. This could place the lesion proximal to the bifurcation of the common carotid artery. However, the occurrence of tonic pupils together with hemifacial anhidrosis in our patient suggests that both parasympathetic and sympathetic fibers are involved ( 15), with the sympathetic deficit being either preganglionic or postganglionic and the parasympathetic lesion being post­ganglionic ( 16). Patients with unilateral facial anhidrosis characteris­tic of Harlequin syndrome have been noted to exhibit Adie syndrome, including tonic pupils and reduced deep tendon reflexes ( 15,18,19), a combination called Ross syndrome after the original description in 1958 ( 3). In our patient, deep tendon reflexes were preserved, thus differentiating the condition from Ross's original description ( 3). As previously suggested ( 15), the catego­rization of patients into syndromes such as Adie ( tonic pupils ± hyporeflexia), Ross ( segmental anhidrosis, tonic pupils, and hyporeflexia) and Harlequin ( segmental or hemi­facial anhidrosis without Horner syndrome) have become less stringent because considerable overlap has been noted. It is likely that there exists a spectrum of disorders of partial autonomic neuropathies with variable involvement of the dorsal root ganglia affecting deep tendon reflexes ( 2,15,17). A generalized disorder of acetylcholine- releasing nerve terminals would explain the tonic pupils and the hemifacial sudomotor and vasomotor loss observed in the present case ( 19). Other postulated causes include a disorder of neural crest cell derivatives ( 15) or microvascular ischemia mediated by an autoimmune process or infectious agent ( 6). The localized autonomic disturbances described in the present case are typically benign and warrant no treatment. 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