Fistula formation in the airway may be broadly defined as any defect that allows pathologic communication between the respiratory tract and an adjacent structure. The type of airway fistula is determined by which section of the tracheobronchial tree and which adjacent structure is involved. For example, a tracheoesophageal fistula (TEF) is a communication between the trachea and the esophagus, whereas a bronchopleural fistula (BPF) is a communication between a lobar or segmental bronchus and the pleural space. The cause of a fistula may be iatrogenic, traumatic, or secondary to a medical disorder. The fistula size, location, and the effects on ventilation are important in determining the morbidity for the patient, the options for therapeutic intervention, and the challenges the fistula may present to anesthesiology or intensive care providers. Table 45.1 provides an overview of the major airway fistula types in adults.

A large fistula of the central airways (such as TEF of the trachea or a BPF of a mainstem bronchus) that causes significant respiratory distress can be a devastating condition and frequently requires surgical intervention to prevent the development of pulmonary sepsis, which can be catastrophic. All types of airway fistulas warrant the utmost level of preoperative planning for even the most seasoned anesthesiologist. Thorough physical examination, reviewing the computed tomography (CT) scan, and bronchoscopic evaluation to localize the defect are essential in planning the anesthetic management. Airway techniques, such as jet ventilation or placement of a left- or right-sided double-lumen tube (DLT), may be necessary to avoid further injury to a central defect, preserve oxygenation and ventilation, and isolate the defect site for surgical repair.

In its own category of airway fistula is an alveolopleural or alveolar-parenchymal-pleural fistula (APF) of the distal tracheobronchial tree (beyond a segmental bronchus), which allows air to leak into the pleural space. The etiology and treatment of an APF is distinct from a BPF or tracheal fistula. If an APF does not readily heal it may lead to a persistent air leak (PAL), a condition where air continues to enter the pleural space from the lung parenchyma for an extended period, in particular if the patient is placed on positive pressure ventilation. A postoperative PAL is typically defined as one that lasts 4 postoperative days or beyond the expected postoperative hospital stay.^1,2 Whereas a PAL may lead to a prolonged hospital stay and increased mortality, the usual course is less ominous than that of a large central airway fistula, especially if the etiology of the APF is postsurgical. Most patients with a PAL after lung resection can be safely discharged home under conservative management, and a chest tube connected to a one-way (Heimlich) valve for later removal at a follow-up clinic visit.^1,3 However, some patients with an APF may need to undergo a surgical or endoscopic procedure to seal or isolate the defect to expedite the healing process.

A bronchopleural-cutaneous fistula (BPCF) describes a special condition occurring when a communication exists between the respiratory tree, the pleural space, and the subcutaneous area of the chest wall. Respired gases enter into the pleural space and then into the subcutaneous tissue to cause diffuse subcutaneous emphysema.⁴ This may occur when penetrating trauma to the chest wall injures a bronchus or other airway. For a BPCF, percutaneous chest tube placement will incompletely evacuate the pleural space to reinflate the lung because of continued filling via the airway fistula during spontaneous or mechanical ventilation.

Although the features of each fistula type are unique, an understanding of the pathophysiology of each is essential for the astute thoracic anesthesiology provider. The preoperative assessment of a challenging airway fistula includes ascertaining not only the characteristics of the airway fistula, but also other coexisting patient factors, a clear procedural plan, and the assurance of the availability of support staff and equipment. Communication with the surgeon or other proceduralist before initiation of the procedure often guides airway management planning and helps avoid pitfalls during the procedure. Patients must also be informed when significant difficulties are foreseen with oxygenation and ventilation or when there is a possible need for postoperative ventilatory support. The prudent approach is to have multiple backup modalities available, which may include extracorporal membrane oxygenation (ECMO) for the highest risk cases.^5–7 The following case presentation highlights a management paradigm for a real patient with a central airway fistula.

Case Presentation

A 64-year-old former 20 pack-year smoker underwent a successful spinal surgery to repair a traumatic back injury sustained during a snowmobile accident, but he was experiencing anorexia, mild dysphagia, and persistent nausea during the recovery period. He was referred for an esophagogastroduodenoscopy (EGD), which demonstrated Barrett’s mucosa in the lower third of the esophagus and a fungating, partially obstructive mass at the gastroesophageal junction. Biopsies of the mass and further imaging confirmed a diagnosis of esophageal adenocarcinoma stage uT3N1M0. He was treated with several weeks of radiation therapy (50 Gray), neoadjuvant chemotherapy (carboplatin and paclitaxel), and nutritional support with tumor response and symptomatic improvement. He subsequently underwent a minimally invasive Ivor Lewis esophagectomy and laparoscopic jejunostomy from which he recovered well and was discharged home on the sixth postoperative day. However, at two weeks postprocedure, the patient returned to the hospital with fever, productive cough, and dyspnea. He had bilateral diffuse rales on physical exam. A CT scan of the chest showed bilateral basal predominant groundglass opacities and patchy consolidations, as well as defects in the proximal left mainstem bronchus and the esophagus that appeared to communicate (Fig. 45.1A). The patient was scheduled for an urgent EGD and flexible bronchoscopy for further assessment and treatment.

Case Management

Airway Fistula Repair

In the operating room, a rapid sequence induction was performed to avoid unnecessary mask ventilation, and the patient was intubated with a single-lumen endotracheal tube. The patient was mechanically ventilated with low tidal volumes, low peak inspiratory pressures, low respiratory rate to allow for a prolong expiratory period, and no positive end-expiratory pressure (PEEP) to reduce air flow through the fistula (Box 45.3).^11,12 Bronchoscopic evaluation confirmed endotracheal tube placement above the carina and no further injury to the fistula site. The bronchial fistula measured 5 mm at this time, and the patient tolerated mechanical ventilation without difficulty. Esophagoscopy revealed partial necrosis of the gastric conduit with fistula formation at the site of anastomosis. A self-expanding metallic esophageal stent was placed to limit tracheobronchial soiling while planning for a definitive surgical repair. A chest tube thoracostomy was also performed to drain the pleural space, and the patient was placed on intravenous antibiotics.

• BOX 45.3

Mechanical Ventilation for Airway Fistulas

The volume of air leak through the fistula is proportional to the mean airway pressure, which is reduced with these strategies:

Spontaneous breathing (if possible)

Low tidal volumes

Low peak inspiratory pressure

Low respiratory rate

Short inspiratory time

Permissive hypercapnia

Low or no positive end-expiratory pressure

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