Free
Case Reports  |   November 1996
Postoperative Autonomic Deficit: A Case of Harlequin Syndrome
Author Notes
  • (Turco, Farber) Assistant Professor of Anesthesiology.
  • Received from the Department of Anesthesiology, Medical College of Wisconsin and Children's Hospital of Wisconsin, Milwaukee, Wisconsin. Submitted for publication February 6, 1996. Accepted for publication July 17, 1996.
  • Address reprint requests to Dr. Turco: Department of Anesthesiology, Children's Hospital of Wisconsin, P.O. Box 1997, Mail Station 735, 9000 West Wisconsin Ave., Milwaukee, Wisconsin 53201.
Article Information
Case Reports
Case Reports   |   November 1996
Postoperative Autonomic Deficit: A Case of Harlequin Syndrome
Anesthesiology 11 1996, Vol.85, 1197-1199. doi:
Anesthesiology 11 1996, Vol.85, 1197-1199. doi:
Key words: Autonomic nervous system: Harlequin Syndrome. Complications, postoperative: flushing; neuropathy.
Harlequin syndrome in adults was first described by Lance et al. [1] as the sudden onset of unilateral facial flushing and sweating. The term "harlequin color change" has been used for years to characterize newborns with unilateral flushing of the dependent half of the body. [2,3] Although the etiology of these unilateral color changes is unknown, it appears to require a deficit or dysfunction of the autonomic nervous system, and to result in vasomotor instability. [4-6] There have been no previous reports of perioperative harlequin syndrome or unilateral color disturbances. We present a case of postoperative, well-demarcated, left hemifacial flushing and sweating after resection of a right neck mass in a child.
Case Report
A 2-yr-old, American Society of Anesthesiologists physical status 1 child, who weighed 12 kg, presented for elective resection of a neck mass. The mass was 2-3 cm, mobile, nontender, located in the anterior cervical portion of the right neck, and was noted to be increasing in size throughout the last 3 or 4 months. A computed tomography scan revealed a 2 x 3 x 1.5 cm solitary cystic mass medial to the lateral head of the sternocleidomastoid muscle, associated with the neurovascular structures. There were no masses in the anterior mediastinum or airway impingement. The neck mass was palpable in the anterior cervical and submandibular right neck and was thought not likely to interfere with laryngoscopy. The patient was clinically asymptomatic, had a Mallampati classification of 1, and a medical history that was otherwise unremarkable.
General anesthesia was induced uneventfully with halothane in nitrous oxide and oxygen. The trachea was intubated after administration of 1.0 mg [centered dot] kg sup -1 rocuronium, and anesthesia was maintained with 0.5-1% halothane in a 2:1 mixture of nitrous oxide and oxygen. We administered 0.1 mg [centered dot] kg sup -1 morphine sulfate for perioperative analgesia. The patient was positioned supine. To facilitate surgical exposure, the neck was extended by placement of a padded roll under the scapula, which elevated the shoulders 2 cm. The head rested freely on a foam doughnut and was turned 70-90 degrees to the left. Before incision, the skin was infiltrated with 4 ml of 1% lidocaine + 1:200,000 epinephrine. As the operation proceeded, the mass was noted to be adherent to the internal jugular vein, carotid artery, and the vagus nerve anterolaterally and was excised by blunt and sharp dissection. The mass was thought to be a benign vascular lesion, and later histologic studies suggested a cystic hygroma. The intraoperative course was uneventful, with stable respiratory and hemodynamic status throughout dissection, except for one 10-s decrease in heart rate from 110 to 80 beats per minute, without rhythm change and requiring no intervention because of its transient nature.
At the conclusion of surgery, neuromuscular blockade was antagonized with 0.07 mg [centered dot] kg sup -1 neostigmine and 0.015 mg [centered dot] kg sup -1 glycopyrolate. After removal of the surgical drapes, a sharp midline facial demarcation (Figure 1) was observed. The face contralateral to the operative site was flushed, warm, and wet with perspiration, and these signs were noted to increase in intensity during crying or coughing. The ipsilateral operative side, in contrast, was pale, cool, and dry to touch, and its color did not change with crying or coughing. The pupils were miotic and equal and reactive to light. The surgical site had been decompressed previously via a percutaneous drain, and, on inspection, no excessive bleeding or drainage was seen. The child appeared to be ventilating well before and after tracheal extubation. The patient was taken to the postanesthesia recovery unit and, after an uneventful course, with minimal improvement in the facial coloration, was discharged to the short stay unit. At this time, it was noted that facial nerve function was grossly intact bilaterally, that no ptosis was present, and that the nasal mucosa was not congested on either side. During an additional 3-h period, the facial flushing and sweating had resolved completely, and the patient was discharged to home.
Figure 1. A patient with hemifacial discoloration 30 min postoperatively in the recovery room.
Figure 1. A patient with hemifacial discoloration 30 min postoperatively in the recovery room.
Figure 1. A patient with hemifacial discoloration 30 min postoperatively in the recovery room.
×
During follow-up on postoperative days one and ten, there was no sign of the red facial discoloration observed perioperatively, nor was there evidence of autonomic, motor, or sensory neurologic deficit.
Discussion
There are several autonomic syndromes associated with unilateral facial flushing. Along with the distribution of flushing, the presence or absence of associated autonomic signs and symptoms may be used to localize the primary lesion along a three-neuron pathway. Central sympathetic lesions may occur with brainstem infarction or with migraine, producing a central Horner's syndrome or a Harlequin syndrome accompanied by hemi-body loss of thermoregulatory sweating. [1,6-8] Alternatively, immaturity of the hypothalamic centers may be responsible for the unilateral flushing often seen in premature neonates that is termed Harlequin color change. [2,3] Second order preganglionic oculomotor fibers leave the spinal cord in the first thoracic root, * whereas sudomotor and vasomotor fibers leave below T1, at T2 and T3. Noda [9] described a patient with Harlequin syndrome due to a superior mediastinal mass, interfering with second order neurons at T3. The preganglionic fibers then ascend via the sympathetic chain to synapse in the superior cervical ganglion (Figure 2). Postganglionic neurons in the rostral end of the superior cervical ganglion project into the internal carotid nerve to innervate the eyes and forehead, whereas fibers from the caudal end of the superior cervical ganglion project into the external carotid nerve to innervate the cheeks and other parts of the face.* The upper extremity receives postganglionic fibers from the stellate ganglion, so a lesion in or proximal to the stellate ganglion would disrupt sudomotor and vasomotor responses to the arm. In the case presented, upper extremity sudomotor or vasomotor changes did not occur, delineating the site of sympathetic injury as distal to the stellate ganglion. Nor did we observe oculomotor changes (ptosis or meiosis), suggesting that the injury occurred to preganglionic fibers traveling to the superior cervical ganglion arising from T2 to T4, to the caudal superior cervical ganglion, or to the nerves of the external carotid plexus distal to the superior cervical ganglion. In addition, the likeness of the superior cervical ganglion to an enlarged lymph node can result in its inadvertent removal or injury during neck dissection, producing a Horner's syndrome or autoneuropathy. [10] The extensive dissection required, both medially and posteriorly to the carotid artery to resect the cystic hygroma, made it more likely that autonomic injury would occur, and may explain why this phenomenon had not been described after a relatively superficial neck surgery like carotid endarterectomy.
Figure 2. Autonomic sympathetic innervation of the face. The preganglionic supply of the eye exit the spinal cord in the first thoracic root, whereas preganglionic sudomotor and vasomotor fibers leave below T1. The rostral superior cervical ganglion projects postganglionic fibers to the eyes, forehead, and cheeks via the internal carotid nerve, whereas the caudal part of the ganglion projects postganglionic fibers to the cheeks and other parts of the face via the external carotid nerve. Numbers 1, 2, and 3 represent sympathetic lesions that may produce hemifacial loss of flushing with ocular sparing. 1 = preganglionic fibers from T2 and T3; 2 = caudal superior cervical ganglion; 3 = postganglionic fibers of the external carotid nerve.
Figure 2. Autonomic sympathetic innervation of the face. The preganglionic supply of the eye exit the spinal cord in the first thoracic root, whereas preganglionic sudomotor and vasomotor fibers leave below T1. The rostral superior cervical ganglion projects postganglionic fibers to the eyes, forehead, and cheeks via the internal carotid nerve, whereas the caudal part of the ganglion projects postganglionic fibers to the cheeks and other parts of the face via the external carotid nerve. Numbers 1, 2, and 3 represent sympathetic lesions that may produce hemifacial loss of flushing with ocular sparing. 1 = preganglionic fibers from T2 and T3; 2 = caudal superior cervical ganglion; 3 = postganglionic fibers of the external carotid nerve.
Figure 2. Autonomic sympathetic innervation of the face. The preganglionic supply of the eye exit the spinal cord in the first thoracic root, whereas preganglionic sudomotor and vasomotor fibers leave below T1. The rostral superior cervical ganglion projects postganglionic fibers to the eyes, forehead, and cheeks via the internal carotid nerve, whereas the caudal part of the ganglion projects postganglionic fibers to the cheeks and other parts of the face via the external carotid nerve. Numbers 1, 2, and 3 represent sympathetic lesions that may produce hemifacial loss of flushing with ocular sparing. 1 = preganglionic fibers from T2 and T3; 2 = caudal superior cervical ganglion; 3 = postganglionic fibers of the external carotid nerve.
×
The determination of the pathologic side of the face is somewhat ambiguous. As the dominant effect of the sympathetic nervous system to the face is one of vasoconstriction, reactive vasodilatation may develop immediately after sympathectomy. This may imply that the sympathetic abnormality in the current patient would be on the nonsurgical side and may have resulted from extreme neck rotation leading to ischemia of the left sympathetic nerves. However, facial flushing is a reflection of the vasodilatation of cutaneous blood vessels, which may be caused by attenuation of sympathetic vasoconstrictor tone, by an active sympathetic vasodilator mechanism, or by endogenous or exogenous vasoactive mediators. [5] The relative importance of the sympathetic influence on facial blood flow was studied by Drummond*, [11] in patients undergoing stellate ganglion blockade (preganglionic sympathetic fibers to the superior cervical ganglion will also be blocked). The release of sympathetic vasoconstrictor tone increased ipsilateral facial blood flow by only 40%. In contrast, heating until sweating was visible on the normal side of the forehead increased blood flow 150-200%, with no change in blood flow to the sympathetically blocked side. These findings indicate that sympathetic blockade prevents active thermoregulatory facial cutaneous vasodilatation, and that the relative effect of the loss of sympathetic tone on facial flushing is minimal compared with active, sympathetically mediated vasodilatation. Because the left side of the face was flushed, warm, and perspiring, functional sympathetically mediated vasodilatation was present on the left, whereas the right side was pale, cool, and dry, because the sympathetic supply to the surgical side was injured. In contrast, infiltration with local anesthetic would produce a nonspecific sympathectomy that involves all the ipsilateral head (without ocular sparing) and the upper extremity, which was not observed.
In summary, we present the first report of a child with clearly demarcated hemifacial flushing postoperatively. Although the etiology of this phenomenon is unclear, an alteration in sympathetic activity secondary to injury of the right preganglionic sympathetic fibers, the superior cervical ganglion, or the postganglionic sympathetic fibers to the external carotid plexus due to neck dissection appears likely.
*Drummond PD: Sweating and vascular responses in the face: Normal regulation and dysfunction in migraine, cluster headache and harlequin syndrome. Clin Auton Res 1994; 4:273-85
REFERENCES
Lance JW, Drummond PD, Gandevia SC, Morris JGL: Harlequin syndrome: The sudden onset of unilateral flushing and sweating. J Neurol Neurosurg Psychiatry 1988; 51:635-42.
Schachner LA, Hansen RC: Pediatric Dermatology. New York, Churchill Livingstone, 1988, pp 282-3.
Esterly NB, Spraker MK: Neonatal skin problems, Dermatology. Edited by Moschella SL, Hurley HJ. Philadelphia, Saunders, 1985, p 1882.
Drummond PD, Lance JW: Site of autonomic deficit in Harlequin Syndrome: Local autonomic failure affecting the arm and the face. Ann Neurol 1993; 34:814-9.
Drummond PD, Lance JW: Facial flushing and sweating mediated by the sympathetic nervous system. Brain 1987; 110:793-803.
Freeman R, Waldorf HA, Dover JS: Autonomic neurodermatology (Part II): Disorders of sweating and flushing. Semin Neurol 1992; 12:394-407.
Morris JGL, Lee J, Lim CL: Facial sweating in Horner's syndrome. Brain 1984; 107:751-8.
Cheshire WP, Mann JD: Harlequin syndrome in migraine. Neurology 1991; 41:309.
Noda S: Harlequin syndrome due to superior mediastinal neurinoma. J Neurol Neurosurg Psychiatry 1991; 54:74.
Collins SL: The cervical sympathetic nerves in surgery of the neck. Otolaryngol Head Neck Surg 1991; 105:544-55.
Drummond PD, Finch PM: Reflex control of facial flushing during body heating in man. Brain 1989; 112:1351-8.
Figure 1. A patient with hemifacial discoloration 30 min postoperatively in the recovery room.
Figure 1. A patient with hemifacial discoloration 30 min postoperatively in the recovery room.
Figure 1. A patient with hemifacial discoloration 30 min postoperatively in the recovery room.
×
Figure 2. Autonomic sympathetic innervation of the face. The preganglionic supply of the eye exit the spinal cord in the first thoracic root, whereas preganglionic sudomotor and vasomotor fibers leave below T1. The rostral superior cervical ganglion projects postganglionic fibers to the eyes, forehead, and cheeks via the internal carotid nerve, whereas the caudal part of the ganglion projects postganglionic fibers to the cheeks and other parts of the face via the external carotid nerve. Numbers 1, 2, and 3 represent sympathetic lesions that may produce hemifacial loss of flushing with ocular sparing. 1 = preganglionic fibers from T2 and T3; 2 = caudal superior cervical ganglion; 3 = postganglionic fibers of the external carotid nerve.
Figure 2. Autonomic sympathetic innervation of the face. The preganglionic supply of the eye exit the spinal cord in the first thoracic root, whereas preganglionic sudomotor and vasomotor fibers leave below T1. The rostral superior cervical ganglion projects postganglionic fibers to the eyes, forehead, and cheeks via the internal carotid nerve, whereas the caudal part of the ganglion projects postganglionic fibers to the cheeks and other parts of the face via the external carotid nerve. Numbers 1, 2, and 3 represent sympathetic lesions that may produce hemifacial loss of flushing with ocular sparing. 1 = preganglionic fibers from T2 and T3; 2 = caudal superior cervical ganglion; 3 = postganglionic fibers of the external carotid nerve.
Figure 2. Autonomic sympathetic innervation of the face. The preganglionic supply of the eye exit the spinal cord in the first thoracic root, whereas preganglionic sudomotor and vasomotor fibers leave below T1. The rostral superior cervical ganglion projects postganglionic fibers to the eyes, forehead, and cheeks via the internal carotid nerve, whereas the caudal part of the ganglion projects postganglionic fibers to the cheeks and other parts of the face via the external carotid nerve. Numbers 1, 2, and 3 represent sympathetic lesions that may produce hemifacial loss of flushing with ocular sparing. 1 = preganglionic fibers from T2 and T3; 2 = caudal superior cervical ganglion; 3 = postganglionic fibers of the external carotid nerve.
×