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Case Reports  |   June 2000
External Compression of a Nasotracheal Tube due to the Displaced Bony Fragments of Multiple LeFort Fractures
Author Affiliations & Notes
  • Daisy T. Joo, M.D.
    *
  • Beverley A. Orser, M.D., Ph.D.
  • *Resident, Department of Anaesthesia, University of Toronto, Toronto, Ontario. †Associate Professor, Department of Physiology, University of Toronto, Toronto, Ontario, Canada; and Staff Anesthesiologist, Department of Anaesthesia, Sunnybrook and Women’s College Health Science Centre, Toronto, Ontario.
Article Information
Case Reports
Case Reports   |   June 2000
External Compression of a Nasotracheal Tube due to the Displaced Bony Fragments of Multiple LeFort Fractures
Anesthesiology 6 2000, Vol.92, 1830. doi:
Anesthesiology 6 2000, Vol.92, 1830. doi:
AIRWAY obstruction is a recognized life-threatening complication of facial fractures. Approximately 27% of patients who present with LeFort fractures require a tracheostomy or a tracheal intubation for the management of airway obstruction or respiratory depression. 1 However, obstruction of a secured endotracheal tube caused by external compression of the fracture fragments has not been reported. We present a case of intraoperative airway obstruction in a patient with multiple LeFort fractures that occurred despite the placement of a nasotracheal tube in situ  . The anatomical features of facial fractures and the presence of a nasotracheal tube predisposed the patient to this complication. Nasotracheal intubation using fiber-optic guidance in patients with basal skull fracture and alternative airway-management strategies are discussed.
Case Report
A 72-yr-old man involved in a high-speed motor vehicle accident was referred to our hospital for urgent trauma management. The patient had a left LeFort III and right LeFort II fracture that extended into a depressed frontal skull fracture, and other fractures of the extremities. The patient was orally intubated at the scene of the accident because of a depressed level of consciousness, but was hemodynamically stable and was mechanically ventilated at time of hospital admission. Later that day, cerebral spinal fluid was noted to be leaking from the patient’s nose. Consequently, the patient was scheduled to undergo a frontal craniotomy to repair the site of cerebral spinal fluid leakage and to decompress the frontal fractures. In addition, the concomitant stabilization of the midface fractures was planned to reduce the likelihood of a persistent cerebral spinal fluid leak. The plastic surgeons requested that the orotracheal tube be replaced with a nasotracheal tube to obtain adequate exposure of the oral cavity. In addition, it was decided that temporary intraoral maxillary–mandibular fixation wires would be placed during the surgery to facilitate the reduction of the LeFort fractures. The risk of cranial intubation resulting from the nasotracheal intubation was considered reduced with the careful fiber-optic guidance of the tube through the nasopharynx. The neurosurgeon decided that the risk of meningitis as a result of the nasotracheal tube was acceptable; therefore, nasotracheal intubation was chosen instead of elective tracheostomy, the alternative option.
The patient was anesthetized and the orotracheal tube was replaced by a 8.0 mm nasotracheal tube (Mallinckrodt Medical, Pointe Claire, Quebec, Canada). To ensure that the basal skull plates were not disrupted, the tube was gently inserted into the nasopharynx and trachea under direct vision using a fiber-optic bronchoscope. Bilateral air entry was noted and the nasotracheal tube was securely sutured to the nasal septum. The initial airway pressure was 25/3 cm H20 and oxygen saturation measured by pulse oximetry was 99%, with a fraction of inspired oxygen of 0.40. The patient remained in the supine position and was draped for the frontal craniotomy. During the ensuing 2 h of surgery, the airway pressures gradually increased to 30/2 cm H2O, and the peak airway pressure increased from 33 to 41 cm H2O during the subsequent 40 min of surgery. The end-tidal pressure of carbon dioxide increased from 29 to 36 mmHg and a marked increase in the slope of the end-tidal pressure of carbon dioxide trace was observed.
The differential diagnosis for an increase in airway pressures included kinking of the tube by external compression, endobronchial intubation, herniation of the cuff, and occlusion of the lumen by mucus or a foreign body. Manual ventilation confirmed a high airway resistance and auscultation of the lung fields revealed equal air entry. Although no kinking was evident at the nasal aspect of the tube, attempts to pass a suction catheter down the nasotracheal tube were unsuccessful. Fiber-optic examination showed an obstruction of the tube secondary to external compression in the nasopharynx at approximately 5 cm from the nasal orifice. Despite multiple attempts to alleviate the kinking by applying traction to the distal end of endotracheal tube or the intraoral segment, the obstruction persisted. However, after the craniotomy was halted and the neurosurgical drapes were removed, the application of gentle forward traction to the mobile maxilla relieved the obstruction of the endotracheal tube, and airway pressures immediately declined to preoperative values. The nasotracheal tube was expeditiously changed to a number 8.0 mm orotracheal tube under direct laryngoscopy and the surgery continued without maxillary–mandibular fixation. Postoperatively, the patient was stable on return to the intensive care unit and remained orotracheally intubated during the next few days. Twelve days later, the patient underwent tracheostomy for prolonged airway management and was transferred, in stable condition, to an intensive care unit closer to his home for recovery.
Discussion
The classification of facial LeFort fractures has been previously reviewed. 2 The most life-threatening complication of facial fractures is airway obstruction. Airway obstruction secondary to the displacement of fragments is less likely with LeFort I and II fractures than with LeFort III fractures. However, because of the associated laryngeal, pharyngeal, chest, or closed-head injuries, emergency airway management may be required with any midface fracture. 1 Nineteen of 117 patients with LeFort fractures required treatment for airway obstruction, the majority of whom (16 of 19 patients) underwent urgent tracheostomy. 1 An additional 39 of 86 patients with no acute airway compromise underwent elective tracheostomy before the repair of facial fractures. Therefore, airway intervention is common in patients with LeFort fractures.
Intraoral maxillary–mandibular fixation and occlusion of the teeth may be required to facilitate the alignment and internal fixation of fracture fragments. 3 Airway management in these patients is often dealt with using elective tracheostomy. An alternative surgical method used to secure the airway is a rarely used submental approach, which involves the insertion of a reinforced endotracheal tube through a submental incision that extends into the floor of the mouth. 4,5 The risks associated with this approach are similar to the risks associated with tracheostomy, such as infection and displacement of the tube. However, in many instances, maxillary–mandibular fixation is required only temporarily during the surgical procedure, and a less-invasive alternative airway strategy may be preferred. Nasal intubation was traditionally contraindicated in LeFort II or III fractures because of the possible disruption of the cribriform plate and the risk of cranial intubation 6,7 or meningitis. 2,8,9 However, several reports have described the successful placement of a nasotracheal tube over a fiber-optic bronchoscope without cranial intubation or other complications. 10,11 Therefore, in certain cases a nasotracheal tube has been used instead of elective tracheostomy to facilitate the surgical alignment and repair of LeFort II and III fractures.
An additional risk of associated with the use of nasotracheal intubation instead of tracheostomy includes the occlusion of the lumen by nasal turbinates, mucus, or blood clots. 12 Also, kinking of the tube at the naris can occur because of the weight of the breathing circuit tubing 13 and can be avoided by carefully supporting and securing the breathing circuit. External compression of a nasotracheal tube is more likely to occur after the polyvinyl chloride tube has been warmed and softened by the patient’s body heat. Because the obstruction of the nasotracheal tube can develop insidiously and at any time during the procedure, constant vigilance is required.
To the best of our knowledge, this is the first reported case in which the posterior displacement of fracture fragments (fig. 1) caused an external compression and the subsequent kinking of an unreinforced nasotracheal tube. Therefore, this complication should be included in the differential diagnosis of intraoperative airway obstruction and be considered an added risk of nasotracheal intubation in patients with LeFort fractures. In this patient, the obstruction was relieved by applying gentle forward traction to the midface. If this technique fails, expedient and definitive treatment by orotracheal intubation or urgent tracheostomy is required.
Fig. 1. Anteroposterior and lateral views of the human skull. Fracture lines are indicated for (A  ) LeFort I, (B  ) LeFort II, and (C) LeFort III fractures. In the lateral view, arrows show possible posterior displacement of fragments from each fracture type. Adapted with permission. 2 
Fig. 1. Anteroposterior and lateral views of the human skull. Fracture lines are indicated for (A 
	) LeFort I, (B 
	) LeFort II, and (C) LeFort III fractures. In the lateral view, arrows show possible posterior displacement of fragments from each fracture type. Adapted with permission. 2
Fig. 1. Anteroposterior and lateral views of the human skull. Fracture lines are indicated for (A  ) LeFort I, (B  ) LeFort II, and (C) LeFort III fractures. In the lateral view, arrows show possible posterior displacement of fragments from each fracture type. Adapted with permission. 2 
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The problem experienced during the treatment of this patient, in addition to any risk of cranial intubation or meningeal contamination, would have been avoided if the airway had been secured by elective tracheostomy. Moreover, the LeFort fracture reduction and fixation could have proceeded as planned. Therefore, our experience suggests that preliminary tracheostomy is still the choice method for securing an airway in patients undergoing the repair of complex LeFort and skull fractures during which the face is neither exposed nor accessible to the anesthetist.
The authors thank Dr. O. Antonyshyn for advice and for reviewing the CT scan.
References
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Gotta AW: Maxillofacial trauma, Textbook of Trauma Anesthesia and Critical Care. Edited by Christopher M. Grande. Missouri, Mosby Year-Book Inc., 1993, pp 529–39
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Gordon NC, Tolstunov L: Submental approach to orotracheal intubation in patients with midfacial fractures. J Oral Maxillofac Surg 1995; 79:269–72Gordon, NC Tolstunov, L
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Gotta AW: Management of the traumatized airway. ASA Refresher Courses Anesthesiology, 1997;1–7Gotta, AW
Hall DB: Nasotracheal intubation with facial fractures. JAMA 1989; 26:1198Hall, DB
Arrowsmith JE, Robertshaw HJ, Boyd JD: Nasotracheal intubation in the presence of frontobasal skull fracture. Can J Anaesth 1998; 45:71–5Arrowsmith, JE Robertshaw, HJ Boyd, JD
Sprung J, Bourke DL, Harrison C, Barnas GM: Endotracheal tube and tracheobronchial obstruction as causes of hypoventilation with high inspiratory pressures. Chest 1994; 105:550–2Sprung, J Bourke, DL Harrison, C Barnas, GM
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Fig. 1. Anteroposterior and lateral views of the human skull. Fracture lines are indicated for (A  ) LeFort I, (B  ) LeFort II, and (C) LeFort III fractures. In the lateral view, arrows show possible posterior displacement of fragments from each fracture type. Adapted with permission. 2 
Fig. 1. Anteroposterior and lateral views of the human skull. Fracture lines are indicated for (A 
	) LeFort I, (B 
	) LeFort II, and (C) LeFort III fractures. In the lateral view, arrows show possible posterior displacement of fragments from each fracture type. Adapted with permission. 2
Fig. 1. Anteroposterior and lateral views of the human skull. Fracture lines are indicated for (A  ) LeFort I, (B  ) LeFort II, and (C) LeFort III fractures. In the lateral view, arrows show possible posterior displacement of fragments from each fracture type. Adapted with permission. 2 
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