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Case Reports  |   December 1996
Asystole during Temporomandibular Joint Arthrotomy
Author Notes
  • (Morey) Resident in Anesthesiology.
  • (Bjoraker) Associate Professor in Anesthesiology.
  • Received from the Department of Anesthesiology, University of Florida College of Medicine, Gainesville, Florida. Submitted for publication April 29, 1996. Accepted for publication August 28, 1996.
  • Address correspondence to Editorial Office: Department of Anesthesiology. University of Florida College of Medicine, P.O. Box 100254, Gainesville, Florida 32610-0254.
Article Information
Case Reports
Case Reports   |   December 1996
Asystole during Temporomandibular Joint Arthrotomy
Anesthesiology 12 1996, Vol.85, 1488-1491.. doi:
Anesthesiology 12 1996, Vol.85, 1488-1491.. doi:
Key words: Complications: asystole. Ophthalmology. oculocardiac reflex. Surgery: temporomantibular joint arthrotomy. Trigeminal nerve. Trigeminal reflex.
Most anesthesiologists are aware that compression of the eye or traction on the extraocular muscles can cause oculocardiac reflex. Perhaps less well known is that noxious stimulation of trigeminal divisions other than the ophthalmic division (V1) can also trigger life-threatening dysrhythmia and asystole. We present a case of asystole after stimulation of the mandibular division of the trigeminal nerve (V3).
Case Report
A 41-yr-old woman was scheduled for left temporomandibular joint (TMJ) arthrotomy. Previously, she had undergone tonsillectomy, adenoidectomy, and foot surgery, all with general anesthesia and without any known complication. Her only medication was ibuprofen, as necessary, for headache and preauricular pain.
Preoperative vital signs were: blood pressure of 125/50 mmHg, pulse of 72 beats [centered dot] min sup -1, oral temperature of 36.4 degrees Celsius, and respiratory, rate of 18 breaths [centered dot] min sup -1. Physical examination revealed an obese woman who weighed 111 kg and was 150 cm tall. She had healthy teeth, a 28-mm mandibular opening, a normal-appearing jaw, clear lungs, unremarkable heart sounds, and normal cranial nerve function and extremity strength. Hematocrit was 35%. Electrocardiogram demonstrated normal sinus rhythm at 67 beats [centered dot] min sup -1, normal axis and intervals, and no dysrhythmias.
Preoperatively, the patient was extremely anxious, and wept. She was reassured, and 5 mg midazolam and 100 micro gram fentanyl were administered in divided doses. Four percent lidocaine with 1:100,000 epinephrine was administered as an aerosol into both nares. Intraoperative monitoring included continuous electrocardiogram (limb lead 111 and precordial lead V5)tblood pressure, temperature, chest auscultation by esophageal stethoscope, pulse oximetry, and respiratory gas analysis. After preoxygenation and 3 mg d-tubocurarine intravenously, anesthesia was induced intravenously with 350 mg sodium thiopental; 180 mg succinylcholine also was administered. A 7-mm-internal-diameter, cuffed endotracheal tube was placed nasotracheally during direct vision. Anesthesia was maintained with isoflurane at an end-tidal concentration of 0.30-0.91%, nitrous oxide at 70%, and oxygen at 30%. An additional 50 micro gram fentanyl was administered after skin incision. The lungs were ventilated to maintain an end-tidal carbon dioxide of 29-38 mmHg. Temperature was maintained at 36.0-36.4 degrees Celsius. Hemoglobin oxygen saturation was 99-100%; pulse ranged from 65-80 beats [centered dot] min sup -1, and blood pressure from 115/60-140/90 mmHg. No dysrhythmias were noted during induction. We administered 300 mg clindamycin and 10 mg dexamethasone intravenously.
At surgical exposure of the TMJ, the surgeons lysed fibrous adhesions posteriorly and medially after application of 1 ml of 0.5% lidocaine, with 1:100,000 epinephrine. The joint disc cartilage was partially plicated and repositioned over the condylar head to obtain good motion without slippage. Near the end of the procedure and 140 min after anesthetic induction, the joint was irrigated with water at room temperature (approximately 20 degrees). Concurrently, the patient experienced a complete sinus arrest (Figure 1). No pulse could be detected by right radial artery palpation or by pulse oximetry. The surgeons were alerted, and the water was suctioned from the joint. Ventricular escape rhythm at approximately 20 beats [centered dot] min sup -1 appeared 20 s later; 800 micro gram atropine was administered intravenously. Heart rate promptly increased to 90-100 beats [centered dot] min sup -1 with a sinus rhythm. Blood pressure was 140/70 mmHg, and hemoglobin oxygen saturation was 99%. Irrigation of the joint was completed with water at room temperature and continuous joint suction. The procedure was completed without further incident. The patient did well postoperatively and was discharged without apparent sequelae.
Figure 1. Asystole followed irrigation of a temporomandibular joint and lasted 20 s before ventricular escape beats appeared. The nonisoelectric segment at the end of the traces is artifactual.
Figure 1. Asystole followed irrigation of a temporomandibular joint and lasted 20 s before ventricular escape beats appeared. The nonisoelectric segment at the end of the traces is artifactual.
Figure 1. Asystole followed irrigation of a temporomandibular joint and lasted 20 s before ventricular escape beats appeared. The nonisoelectric segment at the end of the traces is artifactual.
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Discussion
Anesthesiologists and ophthalmologists have long recognized that traction or pressure on the eye and orbital contents can precipitate an oculocardiac reflex. [1] This reflex is polysynaptic and mediated afferently via V1and efferently by the vagus nerve. We propose that the asystole described in the current case was caused by a trigeminal-vagal reflex similar to the oculocardiac reflex, but with afferent innervation from V3. Several facts support this hypothesis. The asystole was temporally related to TMJ irrigation. The surgeons were neither compressing the eye nor manipulating retractors during the asystole. Rather, it developed during TMJ irrigation. The patient had no known intrinsic heart disease and had not experienced any hemodynamic instability during the case. The medial, lateral, and posterior parts of the TMJ are innervated by the auriculotemporal nerve, which is derived from the posterior branch of V3and also supplies sympathetic fibers along with the plexus of the superficial temporal artery. [2-4] Small contributions from the masseter and deep temporal nerves from the anterior branch of V3also innervates the TMJ anteriorly, medially, and laterally. [2,5] Afferent input is carried via these nerves to the trigeminal ganglion, which contains the cell bodies, and then to the trigeminal main sensory nucleus and trigeminal spinal nuclei. [3,4] Short internuncial fibers exit the main sensory nucleus of the trigeminal nerve and supply the motor nucleus of the vagus nerve. [6] 
The concept of reflex vagal dysrhythmia dependency on trigeminal divisions besides V1is not new but is not well known. Many vagal reflex events afferently mediated from the maxillary division (V2) have been reported. Observations of bradycardia, sinus asystole, and other dysrhythmias have been noted during dissection and mobilization of bony tissues for Le Fort I and II osteotomies, facial disimpaction, zygomatic fracture fixation, and other facial surgeries (V2). [7-9] In the only study of this phenomena, 501 medical records of patients who underwent orthognathic surgery were reviewed for cardiac bradydysrhythmia and asystole. [10] When the maxillary segment was mobilized during Le Fort I osteotomy, six patients experienced bradycardia (heart rate 20-40 beats [centered dot] min sup -1). Based on these and other cases, to distinguish bradycardia and asystole after trigeminal stimulation from the nerve-specific oculocardiac reflex, the term trigeminocardiac reflex has been advocated. [11] 
The paucity of previous reports that stimulation to V3triggers cardiac events may indicate that this happens only rarely. In one study, two healthy patients undergoing TMJ arthrotomy suffered dysrhythmia during stretching of the temporalis coronoid muscle complex or detachment of muscular and tendonous fibers from the coronoid process. [10] In one patient, bradycardia (20-30 beats [centered dot] min sup -1) developed several times, and asystole developed twice, but responded favorably to glycopyrrolate and chest compression. In the other patient, bradycardia developed but resolved before treatment could be administered. In a separate report, in a young woman with coexisting disease, asystole developed during placement of a subperiosteal retractor along the medial aspect of the ascending mandibular ramus. [12] This dysrhythmia terminated when the retractor was withdrawn and recurred when the retractor was replaced. After 0.6 mg atropine intravenously and an inferior alveolar nerve block, the reflex was ablated.
These cases of cardiac dysrhythmia after V3stimulation, along with the current report, are interesting for several reasons. First, the reflex developed enough intensity to cause asystole in three of the four cases. Second, bradycardia did not precede asystole in two patients. Third, the reflex recurred in two when retractors were repositioned. We treated our patient immediately with atropine and did not allow an opportunity for recurrence. Such recurrences may imply that, unlike the oculocardiac reflex, the trigeminocardiac reflex mediated via V3may fatigue more slowly than the oculocardiac reflex. Fourth, all these patients probably received succinylcholine, whereas only two patients likely received fentanyl. Fentanyl, succinylcholine, and succinylmonocholine can induce enough vagal activity to elicit bradycardia. [13,14] The quantity of either drug 145 min after administration in the current case, however, was very small, and probably contributed negligibly to vagal output or sensitization. [15-17] We speculate that these considerations may indicate that V3-mediated cardiac events, unlike the oculocardiac reflex, are more likely to present with asystole and less likely to fatigue with time.
Several maneuvers are available to treat the trigeminovagal reflex. In the current case, cessation of irrigation probably disrupted the reflex. Eliminating the stimulus was previously noted to be the best first step. [18] Muscarinic antagonism with atropine or glycopyrrolate is controversial during the acute event, because some think that this therapy may convert a sinus bradycardia into ventricular premature contraction and bigeminy. [18] Administration of atropine, however, is deemed safe after heart rate has recovered due to stimulus removal. To our knowledge, no investigators have explored treatment of V3-mediated dysrhythmia with external transcutaneous or transesophageal pacing. Like the oculocardiographic reflex, avoidance of hypercapnia may help prevent V3-mediated dysrhythmia. [6] Once asystole has occurred, treatment with stimulus elimination may be all that is necessary, as occurred in the current case. Some anesthesiologists, however, may prefer to follow the algorithm recommended for asystole by the American Heart Association, which includes cardiopulmonary resuscitation, endotracheal intubation, transcutaneous pacing, epinephrine, and atropine. [19] 
This disparity between the incidence of cardiac events and the trigeminal divisions may be related to different underlying physiologic mechanisms or neural pathways, different intensities of stimuli during surgery, different frequencies of surgery in tissues innervated by the three trigeminal divisions, or a combination of these reasons.
In summary, we reported a case of cardiac dysrhythmia after stimulation of the mandibular or V3division of the trigeminal nerve. Based on the paucity of previous case reports, V3apparently mediates trigeminal-vagal reflexes infrequently compared with the other trigeminal branches but may be associated with more serious dysrhythmias. Clinically, this report emphasizes that vagal reflexes can be caused not only by afferent stimulation from V1(oculocardiac reflex), but also by stimulation of the other divisions of the trigeminal nerve. Anesthesiologists should be wary of cardiac dysrhythmia during mandibular or TMJ surgery.
REFERENCES
Miller RD: Anesthesia. 4th edition. New York, Churchill Livingstone, 1994, p 2182.
Gray H: Anatomy of the Human Body. 30th edition. Edited by Carmine D. Clemente. Philadelphia, Lea and Febiger, 1985, p 340.
McKay GS, Yem R, Cadden SW: The structure and function of the temporomandibular joint. Br Dent J 1992; 173:127-32.
DuBrul EL: Sicher and DuBrul's Oral Anatomy. 8th edition. St. Louis, Ishiyaku EuroAmerica, 1988, pp 117-8.
Hollinshead WH: Anatomy for Surgeons: Volume I, The Head and Neck. 3rd edition. Philadelphia, Harper and Row, 1982, p 341.
Blanc VF, Hardy JF, Milot J, Jacob JL: The oculocardiac reflex: A graphic and statistical analysis in infants and children. Can Anaesth Soc J 1983; 30:360-9.
Bainton R, Barnard N, Wiles JR, Brice J: Sinus arrest complicating a bitemporal approach to the treatment of pan-facial fractures. Br J Oral Maxillofac Surg 1990; 28:109-10.
Stott DG: Reflex bradycardia in facial surgery. Br J Plast Surg 1989; 42:595-7.
Barnard NA, Bainton R: Bradycardia and the trigeminal nerve. J Craniomaxillofac Surg 1990; 18:359-60.
Precious DS, Skulsky FG: Cardiac dysrhythmias complicating maxillofacial surgery. Int J Oral Maxillofac Surg 1990; 19:279-82.
Shelly MP, Church JJ: Bradycardia and facial surgery (letter). Anaesthesia 1988; 43:422.
Lang S, Lanigan DT, van der Wal M: Trigeminocardiac reflexes: Maxillary and mandibular variants of the oculocardiac reflex. Can J Anaesth 1991; 38:757-60.
Yauda I, Hirano T, Amaha K, Fudeta H, Obara S: Chronotropic effects of succinylcholine and succinylmonocholine on the sinoatrial node. Anesthesiology 1982; 57:289-92.
Ohmura A, Wong KC, Shaw L: Cardiac effects of succinylcholine and succinylmonocholine. Can Anaesth Soc J 1976; 23:567-73.
Schleimer R, Benjamini E, Eisele J, Henderson G: Pharmacokinetics of fentanyl as determined by radioimmunoassay. Clin Pharmacol Ther 1978; 23:188-94.
Foldes FF: Succinylmonocholine iodide: Its enzymatic hydrolysis and neuromuscular activity. Proc Soc Exp Biol Med 1953; 83:187-9.
Silverman DG, Donati F: Factors affecting pseudocholinesterase and the pharmacokinetics and pharmacodynamics of succinylcholine, Neuromuscular Block in Perioperative and Intensive Care. Edited by Silverman DG. Philadelphia, JB Lippincott, 1994, p 255.
Blanc VF: Trigeminocardiac reflexes. Can Anaesth Soc J 1991; 38:696-9.
Cummins RO (ed): Textbook of Advanced Cardiac Life Support. Dallas, American Heart Association, 1994, pp 1-23.
Figure 1. Asystole followed irrigation of a temporomandibular joint and lasted 20 s before ventricular escape beats appeared. The nonisoelectric segment at the end of the traces is artifactual.
Figure 1. Asystole followed irrigation of a temporomandibular joint and lasted 20 s before ventricular escape beats appeared. The nonisoelectric segment at the end of the traces is artifactual.
Figure 1. Asystole followed irrigation of a temporomandibular joint and lasted 20 s before ventricular escape beats appeared. The nonisoelectric segment at the end of the traces is artifactual.
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