D: Airway Cases: Surgical Patients in the Operating Room

This 33-year-old white female patient with Down syndrome (Figure 32-1) presented to the gastrointestinal (GI) service with a history of vomiting blood. You first encounter her when she is brought to the operating room at 22:00 hours with gross hematemesis and the general surgeon is going to attempt GI endoscopy to determine the site of bleeding and its cause, and attempts to stop it. Failing that, an open laparotomy is planned.

As she is being transferred to the operating room (OR) table, her only IV is inadvertently pulled out. In the past, she has had repeated episodes of aspiration pneumonia felt to be related to grossly carious teeth and is scheduled for a full mouth dental extraction in 2 weeks.

On examination, she is 5 ft 2 in (157.5 cm) tall and weighs 210 lb (96 kg) with a moderate developmental delay. Vital signs are: heart rate (HR) 122 beats per minute (bpm), blood pressure (BP) 100/80 mm Hg, and her oxygen saturation on blow by oxygen is 92% (she is combative and will not permit an oxygen mask to be applied). You suspect that she has aspirated some blood.

She is not cooperative and will not permit an IV to be restarted. She does not answer questions. She lies on her side with her head flexed forward and will not extend her neck when requested nor will she permit you to do so. She will not open her mouth as per your request and it seems that blood is everywhere.

According to the surgeon, her sister has cared for her for the past 20 years (parents are deceased). As far as her sister knows, she is perfectly healthy and has never had an anesthetic before. She is on no medication and has no allergies. Her past cardiac history is unremarkable according to the surgeon. She does not smoke.

Blood work done earlier in the day shows hemoglobin of 10.2 g/dL (102 mmol/L) and is otherwise normal.

She will require a general anesthetic with an endotracheal intubation. In addition, she is grossly uncooperative, is exhibiting some evidence of hypovolemia, has features indicative of a difficult airway, and has probably aspirated some blood.

32.2.1 What Kind of Vital Organ System Reserve Does This Patient Have?

Cardiovascular reserve: The elevated pulse rate and the narrowed pulse pressure suggest an element of hypovolemia. You are hoping that the surgeon is correct and that she has no congenital heart disease (eg, an endocardial cushion defect).

CNS reserve: She is moderately developmentally delayed and anticipated to be combative on emergence. Her response to sedative hypnotic agents and ketamine for sedation is unpredictable.

Respiratory system reserve: She is moderately obese and is expected to have some restrictive lung disease with predictable consequences. In addition, she has probably aspirated blood and has a past history of repeated aspiration pneumonias. Her saturation on blow by oxygen is 92%. It is likely that she has limited oxygen reserves and will rapidly desaturate if she obstructs, or if she is paralyzed. Postoperative mechanical ventilation is a possibility. She is in extreme regurgitation and aspiration risk.

32.3.1 Employing the Mnemonics Suggested in Chapter 1, Does This Patient Have a Difficult Airway?

On MOANS-guided airway evaluation (see Section 1.6.1), you gain no confidence that you will be able to ventilate this patient using bag-mask-ventilation (BMV) when it becomes necessary. If her neck cannot be extended, a mask seal will be difficult. She is obese and the decrease in compliance may hinder BMV.

Employing LEMON (see Section 1.6.2) to assess the difficulty associated with laryngoscopy and intubation reveals that the look of this patient suggests difficulty. When you attempt to evaluate the geometry of her upper airway, you are unable to assess the volume of her mandibular space. This is particularly problematic in a person with Down syndrome (DS) in which the initial impression is that the tongue is relatively large for the volume of the mouth. You also have no idea where her larynx is relative to the base of her tongue. You are unable to evaluate a Mallampatti and get some idea as to airway access. Additionally, she is obese and you are unable to evaluate the degree of neck mobility.

The mnemonic for difficulties in using extraglottic devices (EGDs) is RODS (see Section 1.6.3). Whether there is restricted mouth opening or not is unknown. There does not appear to be any upper airway obstruction and the airway is neither distorted nor disrupted. As mentioned earlier, she is obese and the decreased compliance (stiff) may militate against successful ventilation with an EGD.

Finally, the patient should be assessed for a potentially difficult cricothyrotomy using the mnemonic SHORT (see Section 1.6.4). There is no history of prior anterior neck surgery, hematoma, or other overlying process that masks the anatomy. However, she is obese, and in addition, one is unable to ascertain whether access to the anterior neck is possible. There is no history or evidence of radiation or tumor.

In summary, she has a potentially difficult airway and is not a candidate for a rapid-sequence induction, even though with a stomach potentially full of blood that would ordinarily be the preferred technique.

32.3.2 What Other Airway Concerns Do You Have in Patients with DS?

An increased incidence of subglottic stenosis in DS patients is well known.1-4 This has been attributed, at least in part, to the increased incidence of regurgitation and aspiration in these patients during infancy and early childhood.1 Therefore, these patients may require an endotracheal tube that is one to two sizes smaller than the standard size appropriate for the patient's age. In addition, the DS patient is predisposed to obstructive sleep apnea due to a relatively narrow nasopharynx and large tongue.5,6

C-spine subluxation is also seen in these patients and may be of concern in airway management.7 Presently there is no consensus of opinion with respect to the need for preoperative radiological evaluation of the cervical spine for subluxation for patients with DS.

32.3.3 What Are the Airway Management Options?

This patient gives every indication that the management of her airway will be difficult. However, the more pressing problem is deciding how to pharmacologically manage her behavior without compromising her ability to maintain ventilation and oxygenation, to permit either an IV start and/or to gain control of the airway in a controlled fashion that minimizes the risk of aspiration.

Ideally, one would like to identify a preferable airway technique (Plan A), and two alternative methods (Plans B and C). However, with the limited airway evaluation, the most appropriate method chosen must have the least chance of producing apnea, aspiration, or a requirement for rapid action. In addition, the presence of copious amounts of blood in the airway is likely to render indirect visualization techniques (endoscopes, video laryngoscopes, optical stylets) to be of limited use. This really leaves one primary option for consideration: sedation and awake intubation employing a laryngoscope.

Plans B and C will likely include an EGD and the surgeon should be prepared to perform an immediate surgical airway if asked (a double set-up). One would be wise to consider the immediate availability of a lightwand (eg, Trachlight™) if the airway practitioner is sufficiently skilled in its use (see Chapter 11).

32.4.1 What Are the Pros and Cons of the Awake/Sedated Method?

Clearly the sedation and awake intubation approach is not without hazards. The use of sedative hypnotic agents in large oral or intramuscular dosages may provoke paradoxical excitement, or worse, lead to hypoventilation or apnea.

Ketamine is an attractive option. Seven mg·kg−1 (ideal body weight)8-11 can be given orally with the expectation that the patient will be dissociated within 20 minutes, at least to the point that an IV can be placed. If the degree of cooperation is not sufficient after this dose, half the original dose can be repeated at 20 minutes.

Clearly this is not an option in this case. Four mg·kg−1 of ideal body weight IM produces reliable sedation and dissociation in approximately 5 minutes.11-15

The margin of safety with ketamine is greater than other sedative hypnotics, such as midazolam, as it preserves ventilatory function, muscle tone, and airway protective reflexes. The disadvantages of ketamine include the risk of laryngospasm, increase in secretions, emergence reactions, and postprocedure nausea and vomiting

32.4.2 How Exactly Would You Manage the Airway of This Patient?

To prepare for airway management the neck of the patient is prepared in as sterile a fashion as the circumstances will allow and the surgeon and OR team are prepared to perform a surgical airway (double set-up). Ketamine 4 mg·kg−1 is then drawn up and ready to administer IM. Propofol 200 mg and succinylcholine 140 mg are also drawn up. Additionally, an assistant is prepared to place an IV on command if possible. A central line access kit is immediately available.

The following airway devices are immediately available for use:

• Styletted endotracheal tubes (ETTs) of various sizes (5, 6, and 7 mm ID)
• Two suctions with rigid suction handles
• LMA-Fastrach™ (Intubating LMA)
• Trachlight loaded onto a 7 mm ID ETT cut at 26 cm
• Video laryngoscope at the ready
• Flexible bronchoscope at the ready
• Topical local anesthetic spray (eg, 4% lidocaine in a syringe attached to a Mucosal Atomization Device [MAD])

The patient is then placed in the left lateral position on the OR table. An antisialogogue is not administered because it must be administered intramuscularly (see later). A pulse oximeter is applied when the patient permits, as is supplemental oxygen.

When all is ready, the ketamine is administered IM. Sufficient sedation/dissociation is typically achieved within 5 minutes. To permit an IV placement, gradual initiation of Sellick maneuver and an awake look is initiated. If the awake look indicates that orotracheal intubation is likely to be successful, then rapid-sequence intubation (RSI) may be performed, or if the patient is intubated immediately following the awake look, propofol can be administered rapidly after the airway is secured and confirmed. The dose of propofol administered must take into consideration the likelihood of hypovolemia.

Failure to visualize the airway adequately to intubate, or assure that intubation is possible if RSI is employed, in the face of ongoing acceptable oxygen saturations may lead one to resort to Plan B. In the event adequate oxygen saturation cannot be maintained, a surgical airway is immediately performed.

32.4.3 How Exactly Was the Airway of This Patient Managed?

After adequate sedation was achieved with IM ketamine, an awake look was performed in the left lateral decubitus position using a #3 Macintosh laryngoscope. About 50% of the glottis was visualized and tracheal intubation was achieved using a #7.0 ETT. After confirmation of the proper tracheal tube placement using end-tidal CO2, the patient underwent volume resuscitation and sedation was carefully titrated using IV propofol. GI endoscopy revealed a bleeding duodenal ulcer. Hemostasis was achieved. The patient was transferred to the ICU intubated and ventilated for further evaluation of her presumed aspiration and ventilatory management.

32.5.1 Should an Antisialogogue Be Given When Ketamine Is Employed?

As a general comment, antisialogogues are typically used whenever topical anesthesia of the oro- and hypopharynx is to be attempted because it minimizes the dilution of local anesthetic agent by saliva and improves the degree of topical anesthesia achieved. In this particular case, it was omitted because it would have required an IM injection.

Ketamine does stimulate tracheobronchial and salivary secretions, and this effect of the drug can potentially cause laryngospasm.12 An antisialogogue, such as glycopyrrolate or atropine, is often given IM 15 to 20 minutes prior to the administration of ketamine to reduce these secretions. Glycopyrrolate is preferred because it produces less intense tachycardia. Unlike other tertiary-substituted antimuscarinics (scopolamine and atropine), glycopyrrolate is a polar quaternary-substituted ammonium compound, which does not cross the blood–brain barrier and therefore avoids the risk of producing confusion and sedation.

32.5.2 How Common Is Laryngospasm with Ketamine?

Laryngospasm is associated with all of the sedative hypnotics to some extent, including ketamine. The incidence of laryngospasm with ketamine is about 1% (ranging between 0.017% and 1.4% in various studies, including studies with data from over 11,000 patients).13-16 It manifests as transient stridor. It is likely related to ketamine-induced sensitization of laryngeal reflexes, and in some cases is thought to be related to excessive upper respiratory secretions.12 Thus, the recommendation has been made that an antisialogogue be coadministered with ketamine. Risk factors for laryngospasm include respiratory infection (fivefold increase) and age (three times greater risk in infants aged 1-3 months than the average).17 One study of nearly 1200 pediatric patients with laryngospasm reported the incidence of complications as hypoxia 3.2%, aspiration 1.1%, and cardiac arrest 0.5%.15

32.5.3 How Common Are Emergence Reactions with Ketamine?

Emergence delirium is the most common side effect of ketamine.18 This response is thought to be caused by the drug's depression of CNS visual/auditory relay nuclei causing altered perception and interpretation of visual and auditory stimuli.19 The occurrence of emergence reactions is associated with age (adults > children), gender (females > males), anxiety level, and psychological state prior to the procedure.18,20,21 The incidence varies but may be as high as 10% to 30% in adults with a much lower occurrence in children. Severe agitation occurs in 1.6% and mild agitation in 17.6% of pediatric patients.19 Emergence reactions are less common in older children (12.1% in those more than 5 years vs 22.5% in children under 5 years of age).20

Small doses of midazolam have been used to treat severe emergence reactions. However, the prophylactic coadministration of benzodiazepines is not recommended since they have no proven benefit, delay ketamine metabolism thereby prolonging recovery, may actually increase the incidence of recovery agitation in specific patient populations, and increase the risk of respiratory depression.17,22-29

32.5.4 Should These Patients Be Recovered in a Dark and Quiet Environment to Prevent Emergence Reactions?

Whether or not a quiet, secluded environment which limits stimuli during the post-recovery period decreases the incidence of emergence reactions is debatable.12 Some suggest that pre-procedure discussions with the patient (adult or child) have a greater impact on reducing the incidence of recovery agitation.12,23 However, the prevailing impression is that less stimulation is advantageous.

32.5.5 How Often Do Patients Given Ketamine Vomit Post-Procedure?

Vomiting occurs in 6.7% of patients, which often persists into the recovery phase, and is also age related, being more common in younger children (12.5% incidence in children under 5 years vs 3.5% in those more than 5 years of age).20 There have been no documented reports of clinically significant aspiration with ketamine when used in patients without contraindications.26

This case study serves as a prototype for the uncooperative, difficult airway with a full stomach, has incipient hemodynamic instability, and is an emergency. Time to plan an approach is limited and hindered by the fact that the patient has no venous access. In an emergency, one does not have the luxury of time, and rigid adherence to the difficult and failed algorithms is advised.

Patient control is achieved with IM ketamine thereby allowing successful IV access. The difficult airway algorithm (Chapter 2) was employed to guide actions directed to managing the airway in this patient. At each step, the imperative is to ensure that adequate gas exchange occurs and one does not burn bridges.

A 68-year-old man was found on CT to have a right lung nodule and paratracheal lymphadenopathy. He was then scheduled for diagnostic bronchoscopy and mediastinoscopy.

Twenty years ago, he was diagnosed with carcinoma of the right submandibular gland, and underwent excision of the gland, right radical neck dissection, and a course of radiotherapy. He quit smoking several years ago and has had hypertension for about 5 years. He has had a nonproductive cough for several months. His only medication is metoprolol.

On examination, he is in no distress at rest. His vital signs are: blood pressure (BP) 140/90 mm Hg, heart rate (HR) 70 beats per minute (bpm), and respiratory rate (RR) 18 breaths per minute. Oxygen saturation on room air is 96%. His weight is 94 kg and he is 170 cm tall. Auscultation of the chest reveals decreased breath sounds bilaterally but no rales or rhonchi, and normal heart sounds. No carotid bruits are evident.

Airway examination reveals a Mallampati IV classification. Mouth opening is 2.5 cm and mandibular protrusion is less than 1 cm. Full upper dentition is present but the mandible is edentulous. The thyromental distance is normal. Cervical spine extension is decreased. Palpation of the submandibular tissues (mandibular space) reveals a woody, indurated consistency. On inspection, telangiectasia and pallor of the submandibular skin are noted. The right neck has the typical appearance of a previous neck dissection. The mucosa of the tongue appears dry.

Laboratory data reveal normal electrolytes and a hemoglobin of 140 g·L−1. ECG reveals nonspecific ST and T changes.

The patient has hypertension which is adequately controlled for his surgical procedure. Carcinoma of the lung is suspected on diagnostic imaging. He does not appear to require further medical optimization.

General anesthesia with endotracheal intubation is required for a brief but stimulating surgical procedure.

Radiotherapy inflicts a radiochemical injury to both normal and malignant cells.1 The damage is related to the total radiation dose and the method of radiotherapy delivery. In order to achieve adequate tumor control, damage to normal tissues is inevitable.1,2Acute tissue toxicities from radiotherapy are considered to occur within 90 days of the commencement of treatment, and late effects beyond 90 days of treatment.3 The late effects may not be manifested until years following the radiotherapy.4 In general, tissues with rapidly dividing cell populations such as mucous membranes and skin demonstrate acute effects of radiation (mucositis, desquamation), whereas those with slowly proliferating cells such as connective tissue demonstrate late effects.5 The severity of the late effects of radiation therapy in general cannot be predicted by the severity of the acute effects.5 The mechanism of late tissue toxicity may be parenchymal or stromal cell death, or irradiation injury to the microvasculature.5 Increased vascular permeability leads to deposition of fibrin in the perivascular interstitium and subsequent replacement by collagen.6 An increase in collagen content can be seen as early as 1 week following irradiation.6

Following radiation therapy to the oral cavity, pharynx, or larynx, the mucous membranes can become erythematous within 1 week, and develop areas with white pseudomembranes (mucositis) at about 2 weeks.5 The patches of mucositis may coalesce by the third week.5 This acute mucosal reaction usually heals within 2 to 4 weeks following completion of radiotherapy, although ulceration and necrosis can occur.4 Late effects of radiation on the mucosa are characterized by thinning or atrophy of the epithelium, telangiectasia, dryness, a loss of mucosal mobility, submucosal induration, and occasionally chronic ulceration and necrosis.6 The mucosa is fragile and more susceptible than normal to mechanical injury.5 Edema is seen in the subcutaneous or submucosal soft tissue in the early phase following radiotherapy, can persist for 6 to 12 months,7 and can become chronic.3,8 Fibrosis, one of the most common delayed radiation-associated manifestations, usually appears in subcutaneous tissues within 6 to 12 months of treatment,5 although it can occur as early as 4 to 12 weeks.6 The fibrosis tends to be slowly progressive,5 nonhomogeneous, and variable in extent and severity from site to site.9 The severity of the fibrosis increases when high total doses of radiation and large fraction sizes are used.4 The risk of developing moderate to severe fibrosis has been reported to be about 40%.3 The affected soft tissue loses elasticity and subcutaneous fat6 and is indurated to palpation.1,6 In the presence of moderate to severe fibrosis, contracture of the tissues also occurs.1 In severe cases, the soft tissues develop a woody consistency and may form a hard mass fixed to skin and underlying muscle or bone (Figure 33-1).5 Obstructive lymphedema may also be associated with fibrosis.5 Radiation therapy to the neck can produce a limitation of neck extension (Figure 33-2).6,10 High-dose irradiation of metastatic cervical lymphadenopathy results in more subcutaneous fibrosis in the neck than does a comparable dose in the absence of palpable lymphadenopathy.5

Hypothyroidism occurs in 5% to 10% of patients who undergo irradiation of the lower neck,4 and fibrosis of the apical segments of the lungs can also occur.5

Voluntary muscle exposed to high-dose irradiation can also develop fibrosis, and when the muscles of mastication (the temporalis, masseter, and pterygoid muscles) are involved, trismus can be produced (Figure 33-3).5 Trismus can be seen following radiotherapy for carcinoma of the nasopharynx or oropharynx. The temporomandibular joint itself is however relatively resistant to ankylosis secondary to radiation injury.5 Fibrosis of the pharyngeal musculature can produce swallowing dysfunction11 and a predisposition to aspiration.2 Stenosis of the pharynx or supraglottic larynx can occur and lead to airway compromise (Figures 33-4, 33-5, 33-6, 33-7, 33-8, 33-9, 33-10).5

Laryngeal cartilage covered by normal mucous membrane usually tolerates conventional fractionated high-dose radiation therapy.4,5 However, arytenoid edema, chrondritis, vocal cord palsy,2 and rarely, chondronecrosis can occur (Figures 33-4[B], 33-5[B], 33-7, 33-8[B], 33-9[B], and 33-10).1 Laryngeal edema can occur at any time following the completion of radiation therapy12 and can produce airway compromise.8 Laryngeal chondronecrosis has been reported to occur up to 22 years following radiotherapy.8

Radiation therapy also can produce vascular injury which includes intimal thickening, fragmentation of the internal elastic membrane, atheroma formation, and fibrosis of the media and adventitia.5 A reduction in the microvascular network can ultimately lead to ischemia, and narrowing or obstruction of larger arteries can occur, as can occlusive thrombosis.9 The changes in the vessel walls are similar to those associated with artherosclerosis due to aging.6 Symptomatic carotid atherosclerosis can be a result of cervical irradiation and may require surgical intervention.12

Radiation injury to the salivary glands produces a decrease in saliva production and a change in the composition of saliva.5 Typically, about 60% to 65% of the total salivary volume is produced by the parotid glands, 20% to 30% by the submandibular glands, and 2% to 5% by the sublingual glands.5 The remainder of the salivary volume is produced by anonymous minor salivary glands distributed throughout the oral cavity and pharynx and which are variable from patient to patient.5 The degree of salivary gland dysfunction depends on the volume of the salivary glands included in the radiation field and the total dose administered.5 It is usually not possible to irradiate the pharynx or the upper jugular nodes without irradiating the submandibular glands; however, the parotid and submandibular glands can be partially shielded during treatment.4 A significant reduction in salivary flow occurs within 1 week of fractionated radiotherapy to the head and neck.5 Salivary flow may become barely measurable by the end of a 6- to 8-week course of treatment and the xerostomia may be permanent.6 Xerostomia causes discomfort, alters taste acuity, and contributes to a deterioration in dental hygiene because the tissues become tender.5 The diminished salivary flow has an altered electrolyte content and reduced pH, and promotes dental decay as the normal oral microflora is altered to a highly cariogenic microbial population.5 In the absence of stringent measures to protect the teeth, caries can develop within 3 to 6 months and lead to complete destruction of the dentition within 3 to 5 years.5 Dental extractions from an irradiated mandible can precipitate osteoradionecrosis.4

The patient presented here had palpable fibrosis of the submandibular tissues, decreased cervical extension, trismus, complete loss of mandibular dentition, and a dry mouth.

Radiotherapy to the oral cavity, pharynx, larynx, or neck can produce limited mouth opening, limited cervical spine extension, and noncompliant immobile fibrotic soft tissue in the floor of the mouth and pharynx, as well as alteration of laryngeal anatomy. Airway management can be difficult in the presence of these anatomic changes. The degree of difficulty is dependent on the site and extent of the altered anatomy.

In a review of 53,041 general anesthetics in which mask ventilation had been attempted, Kheterpal et al identified 77 cases of impossible mask ventilation (0.15%).13 Of the subgroup of 310 patients with neck radiation, 3 could not be ventilated. Both univariate and multivariate analyses demonstrated neck radiation to be the most significant clinical predictor of impossible mask ventilation in this patient dataset. Of the 77 patients who were impossible to mask ventilate, 19 (25%) also demonstrated difficult intubation. However, the incidence of difficult intubation in the subgroup of patients with neck radiation was not provided.13

Giraud et al reported face mask ventilation to be easy after induction of general anesthesia in nine patients after oral or cervical radiation.10 LMA placement was often difficult but was successful in all five patients who had received oral radiotherapy, and ventilation was satisfactory.10 Two patients required lateral introduction of the LMA due to limitation of mouth opening.10 LMA placement was easy in the four patients who had received cervical radiation, but positive-pressure ventilation was difficult.10 On fiberoptic examination through the LMA, the vocal cords could not be visualized in any of these four patients due to vestibular-fold collapse. A large epiglottis was also seen in two of these patients. Muscle relaxation did not improve the laryngeal view. Ventilation was impossible in two of the four patients; however orotracheal intubation was successful. Fiberoptic intubation via the LMA was not attempted as the glottis could not be visualized. The authors theorized that the presence of the LMA in a narrowed, nondistensible hypopharynx may have compressed the larynx and thereby produced glottic collapse.10

Ferson et al reported the use of the Intubating LMA-Fastrach (ILMA) in 254 patients with difficult-to-manage airways of whom 40 had airway changes related to previous surgery, radiation therapy, or both.14 In this subset of patients, the authors reported that correct positioning of the ILMA was more difficult, and 10 patients required the use of a smaller ILMA than that indicated by the patient's height and weight. There were no failures to insert the ILMA and ventilation was possible in all cases. Fiberoptically guided intubation through the ILMA was also successful in all 40 patients. The authors felt that a loss of elasticity due to fibrosis in the neck tissues caused positioning of the ILMA to be more difficult and suggested that fiberoptic guidance be used when attempting intubation through the ILMA in this group of patients.14

Langeron et al compared the efficacy of blind intubation through the ILMA with fiberoptic intubation in a group of 100 patients with anticipated difficult intubation undergoing scheduled surgery.15 In this prospective randomized crossover study, following the induction of general anesthesia, intubation was initially attempted by blind intubation through the ILMA or fiberoptic intubation through an Ovassapian airway. In the event of failure of the first technique, the alternative technique was utilized. The first randomly assigned technique failed in seven patients, four in the fiberoptic group and three in the ILMA group. All were successfully intubated by the alternative technique. In the ILMA group, all three failures occurred in patients who had undergone previous cervical radiotherapy scheduled for ENT cancer surgery. In these patients, ventilation through the ILMA was not optimal for performing blind intubation, alignment of the ILMA was difficult, and increased leaks occurred during ventilation although oxygen desaturation did not occur. The authors concluded that the use of the ILMA could not be recommended in patients with previous cervical radiotherapy.15

Following cervical radiotherapy then, mask ventilation may be impossible13 and the use of an LMA for airway management may not be successful due to obstruction at the level of the larynx.10 Positioning of the ILMA14,15 and ventilation through the ILMA may also be more difficult.15 Laryngeal obstruction would also preclude ventilation using other extraglottic devices such as the Combitube™.

Reduced mouth opening due to fibrosis of the muscles of mastication, reduced cervical spine extension, and fibrosis of the structures of the floor of the mouth can make visualization of the glottis by direct laryngoscopy difficult or impossible. Fibrotic subcutaneous and submucosal soft tissues lack compliance and may constitute a poorly mobile woody mass that cannot be elevated easily, if at all, on direct laryngoscopy. Post-irradiation atrophic mucosa is also easily traumatized and bleeding can readily occur. A thickened edematous epiglottis can obscure glottic visualization, and decreased vocal cord mobility may interfere with glottic cannulation (Figures 33-5[B], 33-7, and 33-9[B]). In the literature search performed for this chapter, no data on the incidence of difficult direct laryngoscopy associated with cervical radiation was found.

Tomioka et al reported ventilation by face mask under general anesthesia to be easy in a patient who had undergone radiotherapy for a pharyngeal tumor.16 However, intubation with a #7.0 endotracheal tube was not possible due to tracheal stenosis, which Tomioka et al postulated, may have been produced by the radiation therapy.16

Yancey reported a Cormack/Lehane Grade III view with a #3 MacIntosh blade following induction of general anesthesia in a patient who had undergone left radical neck dissection and postoperative radiation 10 years previously.17 A frozen larynx that was fibrotic and swollen was described. Intubation with a #3 Miller blade and a #6.5 endotracheal tube was difficult but successful.17

Alternative intubation techniques can also be more difficult following radiation-induced changes to the upper airway. The light-guided technique using a lightwand is best avoided in the presence of anatomic distortion of the airway.18 Retrograde intubation may be feasible although laryngotracheal abnormality has been cited as a relative contraindication to this technique as well.19 Limited mouth opening may preclude rigid fiberoptic techniques, and flexible fiberoptic intubation under general anesthesia may be more difficult in the presence of distorted anatomy and decreased mobility of the airway structures. Langeron et al reported failed blind intubation through the ILMA in patients who had cervical radiation.15 However, Ferson et al reported successful fiberoptic intubation through the ILMA in patients who had airway changes secondary to radiotherapy.14 No information on the efficacy of rigid fiberoptic intubation was found in the literature search performed for this chapter.

Subcutaneous fibrosis in the neck can obscure surface anatomical landmarks, obliterate tissue planes, and make a surgical approach to the airway technically challenging (Figure 33-2). Percutaneous cricothyrotomy may fail in this setting, and tracheotomy may require more time to complete and be associated with more bleeding.20

Neck radiation produces a wide spectrum of pathophysiology 13 and airway management of the patient following cervical or oral radiotherapy requires a careful airway assessment. The assessment should focus on the four dimensions of airway management as outlined by Murphy et al, and be used to predict potential difficulty with (1) face mask ventilation, (2) ventilation using an extraglottic device, (3) tracheal intubation, and (4) surgical access to the airway.21

If mask-ventilation and intubation are both predicted to be difficult after radiotherapy, then the airway should be secured with the patient awake. Should general anesthesia be induced in this setting and mask-ventilation be inadequate, rescue ventilation by means of an LMA may also fail.10 The use of an LMA after cervical radiotherapy may in fact be contraindicated.10 Furthermore, rescue by means of a surgical airway may also be difficult.13,20 Topical anesthesia of the upper airway has been reported to produce transient glottic obstruction resulting in a profound reduction in maximum inspiratory and expiratory flows in some normal subjects,22 and in the presence of preexisting airway compromise an increase in resistance to gas flow may be poorly tolerated.23 Complete obstruction has been reported during topicalization and instrumentation of the airway.20,24,25 However, awake fiberoptic intubation, in general, maintains a wide margin of safety and has been said to be the recommended method in the patient with predicted difficult intubation post radiotherapy. Nonetheless, extreme caution must be exercised in the presence of severe airway obstruction if complete obstruction is to be avoided.10,26 Following radiotherapy to the floor of the mouth and/or pharynx, severe trismus may preclude oral intubation techniques, and in this setting awake nasal fiberoptic intubation may be the most reasonable alternative.

If mask-ventilation is predicted to be easy but intubation difficult, then fiberoptic intubation under general anesthesia may be considered, although anatomic distortion and decreased tissue mobility can make fiberoptic visualization more difficult. Fiberoptic intubation via an ILMA has been successful in the presence of radiotherapy-induced changes to the airway.14 However, failure of blind intubation through the ILMA in this setting has been reported.15

In the presence of anatomic distortion but when intubation is predicted to be possible, inhalation induction of general anesthesia may be a reasonable option.23,27,28 When an adequate depth of general anesthesia has been achieved, intubation can be performed during spontaneous ventilation utilizing a curved- or straight-blade laryngoscope, an operating laryngoscope such as the tubular Lindholm scope, or a rigid bronchoscope.23,27 If intubation is not possible, tracheotomy can be performed under general anesthesia. Inhalation induction in the presence of airway compromise can however be difficult.23,28 Complete airway obstruction can occur and an emergency surgical airway may be required.23,28 Meticulous attention to detail is necessary, in particular the maintenance of spontaneous ventilation and the avoidance of airway instrumentation until an adequate depth of general anesthesia is achieved.23 The use of a nasal airway to alleviate obstruction at the level of the soft palate during inhalation induction may be helpful.23

Patients who have an extremely compromised airway, severe stridor, gross anatomic distortion, or a larynx that cannot be visualized on endoscopy should undergo awake tracheotomy performed under local anesthesia.23,27,28

An anesthetic record from 2 years prior to this admission was available for review. Face mask ventilation had been recorded as moderately easy and intubation had been achieved using a lightwand on the third attempt.

Difficult direct laryngoscopy was predicted based on the examination of the airway (Mallampati IV, reduced mouth opening, limited mandibular protrusion, decreased cervical extension, woody induration involving the mandibular space). The predicted ease of face mask ventilation was also uncertain due to the presence of the submandibular induration and limited cervical extension. The recorded experience with face mask ventilation at the previous surgery is not reassuring. Ventilation by means of an LMA or other extraglottic device may be difficult as well in the presence of the existing anatomic distortion. Surgical access to the airway was not predicted to be difficult. An awake fiberoptic intubation was planned.

Routine monitors were attached and IV access established. No sedation was administered. The patient gargled and then expectorated 30 mL of 4% lidocaine. The Devilbiss atomizer was then used to administer 12 mL of 3% lidocaine aerosolized into the right nostril and the mouth. Five percent lidocaine paste was applied to the posterior one-third of the tongue, and an internal approach superior laryngeal nerve block was performed using Jackson forceps and cotton pledgets soaked in 4% lidocaine. The adult bronchoscope was then easily passed through the mouth into the trachea with the patient in the sitting position and using gentle tongue traction. A #8.5 endotracheal tube was then passed easily over the bronchoscope during maximum inspiration to widely abduct the vocal cords. The patient tolerated the intubation well. General anesthesia was then induced and bronchoscopy and mediastinoscopy performed uneventfully.

Severe postextubation laryngeal obstruction due to laryngeal edema has been reported following hepatic resection in a patient who had previously undergone bilateral modified radical neck dissection and radiation therapy.29 However, laryngeal edema was judged to be unlikely following this relatively brief surgical procedure in which the volume of IV fluid administered was small. Furthermore, no evidence of airway obstruction existed preoperatively.

The patient was therefore extubated fully awake in the semi-sitting position in the operating room immediately following surgery. The postoperative course was uneventful.

Radiotherapy to the head and neck can produce limited mouth opening, limited cervical spine extension, noncompliant fibrotic soft tissue in the floor of the mouth and pharynx, and alteration of laryngeal anatomy. Airway management of the patient following cervical or oral radiotherapy therefore requires a careful airway assessment focused on the prediction of difficult mask ventilation, difficult extraglottic device utilization, difficult intubation, and difficult surgical airway. While complete obstruction has been reported during topicalization and instrumentation of the airway, awake fiberoptic intubation, in general, maintains a wide margin of safety and is the preferred method in the patient with predicted difficult mask ventilation and difficult laryngoscopic intubation post radiotherapy. Patients who have an extremely compromised airway, severe stridor, gross anatomic distortion, or a larynx that cannot be visualized on endoscopy should undergo awake tracheotomy performed under local anesthesia.

A previously healthy 30-year-old man was shot at close range with a low-caliber handgun. A 911 call was placed immediately and paramedics were on the scene within 10 minutes. The victim was fully awake and cooperative. There was a single gunshot entrance wound in the midline at the level of the thyroid cartilage (Figure 34-1). The wound was about 5 mm in diameter and air was noted to be escaping from it. There was minimal bleeding. The patient complained of pain in the area of the anterior neck and the left scapula. He also complained of dyspnea and coughed up scant bloody sputum. He had no allergies, was on no medications, and was previously healthy.

Vital signs at the scene were: blood pressure (BP) 140/60 mm Hg, heart rate (HR) 90 beats per minute (bpm), respiratory rate (RR) 22 breaths per minute, oxygen saturation (SaO2) was 97%. Glasgow Coma Scale was 15. One IV was placed in each upper extremity and oxygen was administered by non-rebreathing facemask (NRFM). The patient was immobilized on a spine board and transported to the emergency department (ED). Transport time was 20 minutes.

On arrival in the ED the patient was awake and responded appropriately. Vital signs were: BP 140/90 mm Hg, HR 96 bpm, RR 20 breaths per minute, SaO2 was 98% on NRFM. He was hoarse, had scant hemoptysis, and complained of pain in the anterior neck and left scapular area. Air could again be appreciated escaping from the neck wound. There was minimal bleeding. Subcutaneous emphysema was palpable in the anterior neck but no hematoma was detected. No exit wound was identified. Air entry was decreased on auscultation of the left chest. The Glasgow Coma Scale was 15 and there were no neurologic deficits. The remainder of the examination was unremarkable.

34.2.1 How Common Is Penetrating Neck Injury?

Penetrating neck injury (PNI) has been reported to occur in 1% to 10% of all trauma patients1,2 and in 0.4% to 5% of major penetrating trauma victims.3 Not all PNIs involve vital structures. In a review of 26 reported series with a total of 4193 patients with PNI, there were 1285 vascular injuries (31%), 331 laryngotracheal injuries (8%), and 354 digestive (pharyngeal and esophageal) injuries (8.4%).4 Others have reported vascular injury in 13.3% to 37%2,5-7 of PNIs, aerodigestive tract injury in 6.3% to 18.5%,6-9 and esophageal injury in 0.9% to 8%.7,8,10,11 Pharyngoesophageal injury was reported by Thoma et al in 8.9% of PNIs.6

34.2.2 What Is the Mortality Associated with PNI?

The mortality associated with PNI has been reported in multiple series and reviews to be between 0% and 11%.1,4,5,7,12-22 A 2008 review reported that mortality rates from civilian PNIs was between 2% and 11%.23

Two series of patients with PNI have reported the mortality associated with vascular injury to be 0%6 and 2.2%.5 However, a mortality of 10% to 30% and approaching 50% has also been quoted for similar vascular injury.2,23 In a review of 11 series with a total of 1584 cases, Arsensio et al4 reported an average calculated mortality from penetrating carotid injury of 17%.

The mortality associated with penetrating laryngotracheal trauma has been reported to be 13.5%,24 3.5%,25 0%,6 and 11.5%.26 However, a mortality of 20%27 to 40%24 has also been quoted for penetrating laryngotracheal trauma.

The average calculated mortality for cervical esophageal wounds, most of which were penetrating, has been reported to be 10%.4 An increase in mortality has been observed with delayed diagnosis.2 A mortality associated with aerodigestive tract injury of 13% has also been reported.28

The mortality associated with PNI also varies with the mechanism of injury.21 The mortality associated with high-velocity bullet wounds is greater than that associated with low-velocity bullet wounds which is greater than that associated with stab wounds.21

34.2.3 Why Is Knowledge of the Anatomy of the Neck Important in PNI?

Penetrating injury to the aerodigestive tract, major vascular structures, or spinal cord in the neck can be life threatening.7 No other region of the body contains so many vital structures in such a confined space.7 Optimal evaluation and management of penetrating neck injury requires knowledge of the anatomy of the neck.29

The neck can be defined as that area located between the lower margin of the mandible and the superior nuchal line of the occipital bone superiorly, and the suprasternal notch and the upper border of the clavicles inferiorly.29 For the purpose of classification of penetrating neck injury, the neck has been divided into three anatomic zones7,29 (Figure 34-2). Although Monson and others30-33 have described the sternal notch as the boundary line between zones I and II, multiple other authors consider zone I to extend from the level of the clavicles and sternal notch to the cricoid cartilage1-3,5-7,22,27,29,34,35 and zone II to extend from the level of the cricoid cartilage to the angle of the mandible. Zone III extends from the angle of the mandible to the base of the skull. Although the three zones of the neck have been said to refer to the area anterior to the sternocleidomastoid muscles,7 posterior neck structures have also been included in this classification.7,29

The structures in zone I include the aortic arch, proximal carotid arteries, vertebral arteries, subclavian vessels, innominate vessels, apices of the lung, esophagus, trachea, brachial plexus, thoracic duct, and spinal cord (Figure 34-3). Important structures in zone II include the common, internal, and external carotids, the jugular veins, the larynx, the hypopharynx, and the proximal esophagus, as well as the spinal cord2,7,29 (Figure 34-4). Important structures in zone III include the distal cervical, petrous, and cavernous portions of the internal carotid arteries, the vertebral arteries, the external carotid arteries and their major branches, the jugular veins, the prevertebral venous plexus, the pharynx, the spinal cord, and the facial nerves2,7,29 (Figure 34-5).

The platysma, a thin superficial muscular sheet enclosed by the superficial fascia of the neck has often been cited as an important surgical landmark in the determination of whether a penetrating neck wound is superficial or deep.2,29 Penetration of the platysma raises the potential of injury to a vital structure, and has been used as an indication for neck exploration. Deep to platysma is the deep cervical fascia, which is subdivided into the investing, pretracheal, and prevertebral layers.2 The fascial compartments of the neck can limit external hemorrhage but when bleeding occurs within these closed compartments, airway compromise can be precipitated (Figure 34-6).

34.2.4 What Are Selective and Mandatory Neck Explorations?

Management of penetrating injury to zone I is complicated by difficult surgical exposure and difficult proximal control of bleeding vessels.2 Penetrating injury to zone III is similarly complicated by difficult surgical exposure and distal control of bleeding vessels.2 Operative intervention for injury in zones I and III has traditionally been selective, based on physical examination and radiologic findings.29

The surgical management of penetrating injury to zone II has been controversial. Some authors have advocated mandatory exploration for wounds that penetrate the platysma, whereas others recommend a more selective approach to surgical neck exploration due to high negative finding rates using the mandatory approach.5,7,11-16,18-21,29,36-42

Penetrating neck trauma most commonly occurs in zone II22 and requires emergency airway intervention in about one-third of cases.22 In a series of 223 patients with PNI, Demetriades et al reported zone II injury in 47%, zone I injury in 18%, and zone III injury in 19%. More than one zone was involved in 16%.5 Bell et al in a series of 120 patients reported 64% of PNI in zone II, 16% in zone I, and 20% in zone III.7

34.2.5 What Are the Mechanisms of PNI?

Forty-five percent of PNIs that penetrate the platysma have been reported to be caused by gunshot wounds (GSWs), 40% by stab wounds (SWs), and 4% by shotgun wounds (SGWs).1,5 In a series of 203 patients with PNI, Thoma et al reported GSWs in 20.7% and SWs in 78.3%,6 whereas Bell et al reported 25.8% GSWs and 52.5% SWs in a series of 120 patients.7

GSWs produce tissue destruction that is dependent on the kinetic energy of the projectile which is a function of the square of its velocity.29 The projectile produces a crush effect on tissue that it contacts and a stretch effect on tissue surrounding the missile path.43 High-velocity projectiles produce a greater blast effect and cause more extensive tissue destruction than low-velocity projectiles.44 However, the amount of damage produced depends on the interaction of the projectile and the specific tissue affected, in addition to its velocity.43 The site of the entry wound should be identified as well as the exit wound (if present), and consideration should be given to the path of the projectile.2 GSWs are more likely to cause vascular, aerodigestive, and neurologic injuries than are stab wounds (73% vs 31%).2,5 Transcervical GSWs (those that cross the midline) are also more likely to injure vital structures than GSWs that do not cross the midline.2,17 For this reason mandatory exploration of transcervical wounds has been recommended,45 although other authors have recommended a selective approach.17

34.3.1 What Are the Essential Elements of the Clinical Evaluation of PNI?

The initial evaluation of a PNI should follow the standard ABCs of resuscitation, followed by a systematic, rapid, and thorough secondary survey.2 The presence of an expanding or pulsatile hematoma, active bleeding, hemorrhagic shock unresponsive to IV fluids, airway compromise, extensive subcutaneous (SC) emphysema, absent upper extremity pulse, or air bubbling through the wound mandates urgent operative intervention2,7,22,29,46 and airway control.

In the hemodynamically stable patient without airway compromise, further diagnostic evaluation can be undertaken. The basis of this evaluation is the physical examination directed toward the identification of injury to the aerodigestive tract, the vasculature, and the nervous system.2

Physical signs indicative of vascular injury in addition to active bleeding, hemorrhagic shock, hematoma, or an absent upper extremity pulse noted earlier, include a carotid bruit or thrill, absent or decreased temporal or facial artery pulse, diminished ipsilateral radial pulse,2,7 or signs of air embolism.2 Abrupt onset of a stroke-type syndrome may herald vascular interruption, injury-induced thrombosis, or traumatic carotid or vertebral arterial dissection. Venous injury appears to be more common than arterial injury.4 Physical examination alone has been reported to be a reliable indicator of clinically significant vascular injury.7,46-49 In a retrospective review, Jarvik et al found no statistically significant difference between the sensitivities of clinical examination and angiography.49 In a review of 145 cases of PNI, Sekharan et al found that of the 114 patients without hard signs of vascular injury, only one required operative repair.50 Azuaje et al reported that physical examination alone had 93% sensitivity and 97% negative predictive value for vascular injury in a series of 216 patients.51 Similarly, Demetriades et al reported that none of 160 patients without clinical signs of vascular injury had serious vascular injury that required treatment.5 Thoma et al concluded that the absence of clinical signs and symptoms reasonably excluded vascular injury in their series of 203 patients.6

However, in a prospective study of 59 patients with a gunshot wound to the neck, Mohammed et al found physical examination alone to have a sensitivity of 57%, a specificity of 53%, a positive predictive value of 43%, and a negative predictive value of 67%.52 Ten patients without clinical signs of vascular injury in fact had vascular injury.52

Hematoma is the most common sign, followed by shock and external bleeding.7 Bleeding within the compartmentalized spaces of the neck can produce insidious displacement and distortion of the airway without external evidence. Airway obstruction can occur precipitously following a period of apparent quiescence, and airway control can be difficult.22 Any evidence of direct vascular injury to the neck has been said to be justification for intubation.22

The signs and symptoms of aerodigestive injury include hoarseness or dysphonia, stridor, subcutaneous emphysema or crepitance, dyspnea, dysphagia, hemoptysis, tenderness on palpation of the larynx, and air bubbling from the wound.2,7 Decreased breath sounds may be due to a hemothorax or pneumothorax.2 The only hard clinical sign of laryngotracheal injury is air escaping from the neck wound.8 Hoarseness is an indication of significant airway injury until proven otherwise.27 Subcutaneous emphysema is a suspicious finding that requires further investigation9 and violation of the aerodigestive tract must be assumed.53 Demetriades et al reported that subcutaneous emphysema (clinical or radiological) was almost always present in penetrating aerodigestive tract injuries8 and subcutaneous crepitus was the most common finding reported by Grewal et al in a series of 57 patients with penetrating laryngotracheal trauma.25 An absence of signs or symptoms suggestive of aerodigestive trauma has been found to reliably exclude injuries requiring surgical repair in a series of 152 patients.5 Emergency airway management has been required in 46% to 56% of patients with penetrating laryngotracheal injury.24,25,27

Esophageal injury due to penetrating neck trauma can be occult and difficult to diagnose on physical examination. Signs of esophageal trauma include dysphagia, odynophagia, hematemesis, SC crepitus, and retropharyngeal air on lateral neck radiograph.2

A thorough neurologic evaluation is necessary to detect or rule out penetrating injury to the central nervous system, cranial nerves, or peripheral nerves.2 Complete spinal cord transaction above C5 can lead to respiratory arrest, and injury below C5 can cause respiratory distress.2 Injury to cranial nerve (CN) VII is manifested by facial weakness, CN XI by an inability to shrug the shoulders, and injury to CN XII by deviation of the tongue.2 Injury to cervical nerve roots C5-C7 will manifest as sensory and motor deficit to the ipsilateral extremity.2 Interruption of blood flow in the carotid or vertebral arteries can cause ischemic stroke.2 The identification of spinal cord injury associated with PNI is important as immobilization has implications for airway management as well as physical examination.

It has been recommended that all patients with PNI be immobilized in a rigid cervical collar.54 However, there are no reports of unstable cervical spine injury in PNI due to stab wounds, and a GSW to the neck would need to fracture the cervical vertebrae in two columns to create an unstable fracture.55 The projectile would have to traverse the spinal cord to produce this injury and neurologic findings would be evident on physical examination55 in the conscious examinable patient.

In a study reported by Klein et al, 33 of 183 patients with GSWs to the neck had cervical spine injuries.56 However, only 1 of the 33 had a proven significant spinal injury with no neurologic findings on admission.56 The authors concluded that immobilization is essential for patients with GSWs to the neck until radiologic evaluation is complete.56 In a retrospective study by Medzon et al, 19 of 81 patients who had sustained a GSW to the head or neck had documented cervical spine fractures.57 However, of the 65 patients who were alert and without neurologic deficits, only 3 had a fracture, none of which were unstable.57 Sixteen of the 19 patients with fractures required acute airway management. The authors were reluctant to recommend removal of collar immobilization based on their data. However, they note that the likelihood of an unstable fracture in an alert and examinable patient without neurologic deficit is low.57 They went on to suggest that the decision to remove the collar or discontinue spinal precautions should be individualized, and when emergency airway control is required, it would be reasonable to remove obstructive devices to permit more expeditious treatment.57 In a retrospective review of 27 patients with PNI by Connell et al, 12 patients sustained a spinal cord injury, 1 due to a GSW and 11 from sharp weapons. Ten patients had obvious clinical evidence of spinal cord injury and two were in traumatic cardiac arrest. The authors concluded that fully conscious patients with isolated penetrating trauma and no neurologic deficit do not require spinal immobilization.58

Based on the available evidence, it appears unlikely that isolated PNI would produce an unstable cervical spine injury in the alert, examinable patient without a detectable neurologic deficit. Immobilization in this setting can interfere with airway management and can obscure findings on physical examination of the neck. In the presence of coincidental blunt trauma, an altered level of consciousness, or neurologic deficit, immobilization is indicated.

The patient presented here underwent cervical spine immobilization. He had the only hard clinical sign of laryngeal injury on clinical examination, air escaping from the entry wound in the anterior neck. There were no signs of vascular or neurologic injury.

34.4.1 What Airway Management Techniques Are Appropriate in PNI?

Airway management of the patient with penetrating neck trauma is intimidating and can be challenging even for the most skilled practitioners due to the coexistence of a potentially difficult airway and the need for rapid action.1,22,55 In addition, the rarity of PNI means that the experience of any one practitioner in the management of this injury can be limited.59 The need for airway control must be determined and the time available to achieve that control must be estimated. There must be a willingness to act quickly despite incomplete information as a delay in intervention can be hazardous,22 and there must be an ability to improvise and change plans under rapidly changing circumstances.27 Airway management decisions must be based on the patient's specific injuries, existing signs of airway compromise, the anticipated clinical course and risk of deterioration, the need for transport, and the patient's overall condition and level of cooperation, as well as planned diagnostic and therapeutic interventions.3,22 On examination, evidence of injury to an air-containing structure in the neck (SC emphysema, stridor, dysphagia, odynophagia, respiratory distress), vascular injury (hematoma, active bleeding, shock, palpable thrill, carotid bruit, absent or diminished pulses), and spinal cord injury (motor and sensory deficit) must be evaluated. The likelihood of difficult direct laryngoscopy must also be assessed. Emergency airway management may be necessary to secure a patent airway, in preparation for operative intervention, or as a part of airway evaluation in selective management of PNI.3 Emergency airway control is indicated in the presence of airway obstruction, respiratory failure, inability to protect the airway from aspiration, hemodynamic instability,3 and hard signs of vascular injury that mandate emergency surgical intervention.7,29 Edema, SC emphysema, or hematoma can produce sudden airway obstruction following a period of relative quiescence, and anatomic distortion can make intubation or a surgical airway more difficult to perform.22 The decision to observe a patient for impending airway compromise or to secure the airway to avoid a difficult intubation in the presence of anatomic distortion is a matter of clinical judgement.22,55 This decision must be based on the evidence on clinical examination of significant vascular, aerodigestive tract, and neurologic injury, and it must be recognized that if one choses to observe, airway obstruction may be sudden, complete, and irreversible. If there is evidence of injury to an air-containing structure in the neck (larynx, trachea, pharynx, esophagus), positive-pressure bag-mask-ventilation may be hazardous and can produce increased anatomic distortion and airway obstruction.2 Orotracheal intubation in the presence of laryngotracheal injury risks cannulation of a false passage, further disruption of damaged mucosa, and increased airway compromise.8,44,60 If there is evidence of significant vascular injury, airway management is indicated.22 A hematoma can expand in the deep tissue planes of the neck22 and airway compromise may proceed insidiously only to be followed by rapid and catastrophic deterioration.22

The timing, place, and method of airway control depend on the type of neck injury, the cardio-respiratory condition of the patient, the available resources, and the experience and skills of the resuscitation team.2,5

Several investigators have reported experience with airway management in PNI. Shearer et al reviewed the records of 107 patients who required an artificial airway from a series of 282 patients admitted with PNI.35 A surgical airway was the primary choice in 6%, RSI in 83%, awake bronchoscopic intubation in 7%, and blind nasal intubation in 4%. The success rates for these various techniques were: primary surgical, 100%; RSI, 98%; awake bronchoscopic, 100%; and blind nasal, 75%. Eight of the 107 patients had laryngotracheal injuries (8%) and 38 patients had vascular injuries (35.5%). RSI failed in two patients (2%) and a surgical airway was required. One blind nasal attempt failed (25%) and was followed by loss of the airway and death during attempted cricothyrotomy. Tracheotomy was performed as the primary airway in three of the eight patients with laryngotracheal injury. Of the nine patients who were hemodynamically unstable, five underwent a tracheotomy or cricothyrotomy in the ED. The authors concluded that airway control can be achieved in most patients with a penetrating neck injury by RSI or a surgical airway, and that a surgical airway should be strongly considered in patients who have wounds in proximity to the larynx who have stridor, dyspnea, hemoptysis, and SC emphysema.35

Mandavia et al conducted a retrospective study of ED intubations in patients presenting with PNI at a level I trauma unit over a 3-year period.61 During the study period, 748 patients with PNI were evaluated in the ED, of whom 82 (11%) required immediate airway management. Twenty-four of these 82 patients were excluded due to pre-hospital cardiac arrest or intubation. In the remaining 58 patients (45 GSWs, 12 SWs, 1 MVA), 39 underwent RSI with a 100% success rate. Thirty-three patients required one attempt, four patients required two attempts, and two required three attempts. Oxygen desaturation (<90%) occurred in two patients. Five unconscious patients were intubated orally without paralysis, and two underwent emergency tracheotomy. Flexible bronchoscopic intubation was attempted in 12 patients and was successful in 9. The three remaining patients were successfully intubated by RSI, although one patient required two attempts and experienced oxygen desaturation to 79%. Both patients who underwent emergency tracheotomy had GSWs and were unable to phonate properly. One of these patients had a laryngeal injury confirmed by endoscopic laryngoscopy prior to tracheotomy. Oral endotracheal intubation was the definitive technique in 47 of the 58 patients and was successful 100% of the time it was employed. The authors concluded that RSI was safe and effective in all of the cases in which it was attempted, and that practitioners with airway expertise should consider using RSI in the setting of PNI.61

Eggen and Jorden reviewed the charts of 114 patients with penetrating injury that breeched the platysma.30 The mechanism of injury was GSW in 59, SW in 39, shotgun wound (SGW) in 7, and miscellaneous in 9 patients. Sixty-nine patients required intubation, of whom 26 were intubated urgently. Urgent airway control was considered necessary in the presence of acute airway distress, airway compromise from blood or secretions, extensive SC emphysema, tracheal shift, or severe alteration of mental status. Eight of the 26 urgent intubations were initially unsuccessful, and six of these required an alternative technique. Four of these were failed oral intubation, three of whom were subsequently managed via the open wound, and one via a tracheotomy. Two of the six were failed nasotracheal intubations both of whom required emergency tracheotomy. Of the 26 patients who required urgent airway control, 9 required a tracheotomy and 5 of these patients had diffuse SC emphysema. Of the 98 patients with zone II injury, 22% required urgent airway control whereas all 3 patients with zone I injury and 5 of 13 (38%) with zone III injury required urgent airway control. The authors noted that a variety of approaches to airway management have been documented to be successful, and that no approach should be dismissed unless specific circumstances contraindicate it or make it technically impossible.30 It should be noted that these cases occurred and that this study was published at a time when RSI was not widely practiced by emergency physicians.

Bell et al performed a retrospective analysis of 134 patients with PNI, of whom sixty-five sustained wounds that violated the platysma.7 There were 31 patients with GSWs, 63 SWs, 13 flying glass injuries, and 15 who were impaled. Eight patients did not require airway management, except for the purpose of general anesthesia. Of the 59 patients who required emergency airway management, 48 were successfully intubated orally in the field. There were two failed intubations that required emergency tracheotomy on arrival, and seven additional tracheotomies were performed for airway compromise.7

Tallon et al performed a retrospective review of the airway management of PNI in a Canadian tertiary care center.62 Nineteen patients were identified over the 11-year period of the study. Three patients were not intubated. Of the remaining 16, 5 were intubated in the pre-hospital setting, 6 in the ED, and 5 in the OR. Eight patients were intubated awake and eight others underwent RSI. No adverse airway-related outcomes were identified in either group.62

Thoma et al performed a prospective observational study of 203 patients with PNI who presented to Groote Schuur Hospital in Cape Town between July 2004 and July 2005.6 Of these, 159 patients presented with stab wounds and 42 with low-velocity gunshot wounds. A vascular injury was identified in 27 patients, pharyngoesophageal injury in 18, and an upper airway injury in 8. Four patients had a laryngeal injury and four had tracheal injuries. Twenty-five patients required surgical intervention, and eight additional patients had endovascular procedures. Six patients underwent tracheotomy, four of whom had airway compromise associated with oropharyngeal injury. One of the patients with laryngeal injury required tracheotomy and one patient with a complete C4 spinal cord injury required long-term ventilation. Patients with airway compromise and hemodynamic stability were intubated either by oral endotracheal intubation or if that failed, emergency cricothyrotomy. However, there were no failed intubations requiring a surgical airway. The details of the technique of intubation were not provided.6

Grewal et al retrospectively analyzed the records of all patients admitted to a level I trauma center who required operative management for penetrating laryngotracheal injury over a 15-year period.25 Of the 57 patients with penetrating laryngotracheal injury, 32 had sustained GSWs and 25 had sustained SWs. Five patients were hemodynamically unstable on arrival. Emergency airway management was required in 32 of the 57 patients. Oral endotracheal intubation was performed in 14, cricothyrotomy in 3, and tracheotomy in 15. Eight of the emergency tracheotomies were performed in the ED. Forty-four patients underwent tracheotomy in the course of their resuscitation and management. The authors concluded that endotracheal intubation can be safely accomplished in selected patients with penetrating laryngotracheal injuries.25 They suggested that patients with minor to moderate laryngotracheal injury can be safely intubated whereas patients with major laryngeal injuries required individualized management. If the expertise required to perform tracheotomy in the emergency department is limited, then cricothyrotomy was felt to be the safest alternative.25

In a retrospective review of laryngotracheal trauma at two major hospitals between 1996 and 2004, Bhojani et al identified 52 patients who had sustained penetrating laryngotracheal injury.24 There were 26 GSWs and 24 SWs; 24 of the 52 patients required an emergency airway. Endotracheal intubation was performed in 20, tracheotomy in 3, and cricothyrotomy in 1. One patient, who was previously intubated, subsequently required emergency cricothyrotomy in the OR. Twelve of the patients who were intubated or who underwent cricothyrotomy required revision to tracheotomy. An additional seven patients required operative tracheotomy. The authors concluded that either routine intubation or a tracheotomy can be used to secure the airway.24

In a retrospective study of aerodigestive injuries of the neck, Vassiliu et al reviewed 1562 patients with neck trauma and identified 998 patients who had sustained penetrating injury.9 There were 432 GSWs and 524 SWs during the 5-year study period. Blunt trauma produced aerodigestive injury in 7 patients, GSWs in 44, and SWs in 25. Forty-two patients with other penetrating mechanisms did not sustain aerodigestive injury. Forty of the seventy-six patients with aerodigestive injury required an emergency airway in the ED, one of whom had sustained blunt trauma. Orotracheal intubation was successful in 28 patients. In nine patients orotracheal intubation failed, and a cricothyrotomy was performed. Flexible endoscopic intubation was performed in three patients. Of the 38 patients with laryngotracheal trauma, 20 required an emergency airway in the ED. Flexible endoscopic nasotracheal intubation was performed in one patient. Of the remaining patients, RSI failed in five and a cricothyrotomy was performed. The failure rate for RSI was 23% in the GSW group and 20% in the SW group. Twenty-five of 49 patients with isolated pharyngoesophageal injuries required an emergency airway, 16 due to airway compromise secondary to pharyngeal hematoma, and 9 due to shock. RSI was successful in 17 of these 25 patients. A flexible endoscopic intubation was performed in three patients and a cricothyrotomy in five. The authors concluded that RSI is the easiest technique in most cases of aerodigestive injury. However, in the presence of large hematomas, RSI can be difficult and potentially dangerous.9 If an RSI is undertaken, an experienced practitioner should be ready to perform a surgical airway, should the orotracheal intubation fail. In 22.5% of attempted RSI in this study, the airway was lost and a cricothyrotomy was necessary, highlighting the importance of the concept of a double set-up. The authors suggest that flexible endoscopic nasotracheal intubation is the safest approach provided that the patient has adequate cardiovascular stability.9

Bumpous et al performed a retrospective review of 16 patients with penetrating injury to the visceral compartment of the neck who were treated in a level I trauma center over an 8-year period.28 There were nine handgun injuries, one shotgun injury, five stab wounds, one razor slash, and two victims of penetrating trauma associated with a motor vehicle accident. Three patients sustained zone I injury, eleven zone II injury, and two patients, zone III injury. Eleven patients sustained tracheal injury, six esophageal injury, and five laryngeal injury. Multiple sites of aerodigestive tract injury occurred in 13 patients. Tracheotomy was required in 12 of the 16 patients.

Gussack et al reported a series of 117 patients with PNI of whom 8 had penetrating laryngotracheal injury.63 Of these eight patients with penetrating laryngotracheal injury, six underwent orotracheal intubation and two were intubated through the wound.63 Four of those who underwent orotracheal intubation subsequently required tracheotomy. Both patients intubated through the wound required tracheotomy. No untoward effect occurred related to the orotracheal intubation.63 The authors also reviewed an additional 392 cases of laryngotracheal trauma from 12 published series which included 123 cases of penetrating trauma. Seventy-three percent of the 392 cases required a tracheotomy. Gussack et al also reported a series of 12 patients with penetrating trauma to the laryngotracheal complex.59 The mechanism of injury was GSW in five patients and SW in seven. Nine of the patients with penetrating laryngotracheal injury required active airway control and were orally intubated. Three required an emergency tracheotomy, two with SWs and one patient with a GSW. No intubation failures were reported. The authors felt that intubation is the primary method of airway control, and is generally more expeditious than tracheotomy in the majority of patients. However, they went on to state that the operator should move quickly to tracheotomy if intubation is difficult.59 Cricothyrotomy was said to be relatively contraindicated if laryngeal trauma is suspected59 although it is not clear that this is an evidence based position.

There is no uniform agreement on the airway management method of choice in penetrating neck injury.3 Controversy persists and management varies from institution to institution.2 The method chosen must depend on the practitioner's expertise with the various approaches2 and, in general, the technique with which the practitioner is most comfortable is utilized.55 However, familiarly with multiple approaches to secure the airway is required as success with any single technique is not guaranteed,55 and back up plans must be in place should the primary technique fail.22 In most cases, an orotracheal intubation is the easiest and most appropriate technique.1,2 The use of rapid-sequence intubation in PNI was reported by Shearer et al with a success rate of 98%35 and by Mandavia et al with a success rate of 100%.61 Bell et al reported 2 failed and 48 successful oral intubations in PNI.7 However, Eggen and Jorden reported 8 out of 26 initially unsuccessful intubations in PNI, 4 of which were failed oral intubation.30 Gussack et al reported successful orotracheal intubation in penetrating laryngotracheal injury.59,63 However, Vassiliu et al reported a failure rate of 22.5% with RSI in penetrating aerodigestive injury.9 Rapid-sequence intubation can be difficult and potentially dangerous in the presence of PNI and should only be undertaken if judged likely to be successful and the personnel and equipment necessary to establish a surgical airway must be immediately available should the intubation fail (ie, a double set-up).

Awake flexible endoscopic intubation has been advocated as the safest method for most patients with PNI and should be considered in all cooperative patients with suspected airway injury.3 However, this technique may only be feasible in stable patients who are not in severe respiratory distress, and is usually not possible in combative patients or when immediate airway control is required.3,8 The nasal route may require less patient cooperation. The flexible endoscopic technique has the advantage that airway injuries may be identified and the endotracheal tube can be passed distal to the injury. The flexible bronchoscope can also be used to perform the intubation as part of a rapid-sequence intubation technique.8 This variation of technique may be useful in combative patients who otherwise do not have predictors of difficult intubation.8 In the moribund or apneic patient, or in the presence of massive upper airway bleeding, awake orotracheal intubation may be the most expeditious approach.8

If an airway must be immediately established and endotracheal intubation fails, then cricothyrotomy is indicated.9,22,44,60 Conversion to tracheotomy can be performed as soon as the clinical situation permits.44 Cricothyrotomy has also been considered to be contraindicated if the exact location of the airway injury is unknown3 and tracheotomy had been advocated in this setting.3 In the presence of laryngotracheal injury, if uncertainty exists about the difficulty or safety of intubation, an awake tracheotomy under local anesthesia can be performed under controlled conditions if the patient's condition permits.2,44,60 However, an awake tracheotomy requires patient cooperation and the difficulties associated with the performance of a surgical airway in the presence of anatomic distortion in a restless hypoxic patient cannot be overemphasized.8 In extreme circumstances in which a surgical airway is immediately required, most practitioners would consider a cricothyrotomy to be the procedure of choice.30,39 and emergency tracheotomy is not considered an appropriate method to establish an emergency definitive airway.27 Blind nasal intubation has been reported in the management of PNI with a success rate of 90%.64 However, most authors agree that blind intubation techniques should not be used in PNI because of the risk of producing further injury and complete airway obstruction.3

34.4.2 How Was the Patient's Airway Managed?

The patient developed increasing respiratory distress following arrival in the ED. A surgeon, an anesthesiologist, and an emergency physician were at the bedside. Options for airway management were discussed. No bronchoscope was immediately available. The degree of respiratory distress rapidly increased and awake tracheotomy was not considered to be feasible. A rapid-sequence intubation (RSI) was initiated. The necessary equipment was opened and the surgeon was ready to perform a surgical airway should intubation fail.

On direct laryngoscopy a Grade 3 (epiglottis only) view was obtained with a #4 MacIntosh blade. The Eschmann tracheal introducer (bougie) was successfully passed on the first attempt and an 8.0-mm ID endotracheal tube (ETT) easily passed into the trachea over the bougie. Edema of the pharynx and larynx was noted. Endotracheal tube position was confirmed by colorimetric carbon dioxide analysis.

34.5.1 What Investigations Are Appropriate in the Stable Patient with PNI?

Patients who do not have airway compromise and who are hemodynamically stable should undergo further diagnostic evaluation based on the findings on physical examination.7 The evaluation and management of PNI must also be tailored to the diagnostic capabilities in the individual institution and the experience and availability of personnel.2 Stable patients who have suspected aerodigestive injury on examination require further investigation. Cervical spine and chest x-rays can be done as part of the initial trauma resuscitation. Flexible endoscopy is the investigation of choice for suspected laryngotracheal trauma.8 Direct laryngoscopy may also be used in the evaluation of laryngeal trauma.53,60 The diagnostic imaging procedure of choice in the evaluation of suspected laryngeal injury is high-resolution CT scanning, which provides the most complete radiologic assessment of the larynx.60,65 However, CT scanning cannot be recommended as a replacement for triple endoscopy (pharyngolaryngoscopy, esophagoscopy, and bronchoscopy) in PNI65 and controversy exists with regard to the utility of CT scanning in the evaluation of laryngeal injury.44 The pharynx and cervical esophagus can be evaluated by endoscopy or contrast swallow studies or both modalities.8 Rigid esophagoscopy may be more reliable than flexible esophagoscopy or esophagraphy for the diagnosis of cervical esophageal injury.8 Catheter angiography continues to be the gold standard for the evaluation of suspected vascular injury and has well-documented efficacy.7,66-69 However, Rivers et al in a retrospective study concluded that the angiogram result did not alter management in zone II penetrating neck injuries.70 Furthermore angiography is invasive and has an associated complication rate of 0.16% to 2.0%.70 In a study of 223 patients with PNI, 176 underwent angiography.5 Abnormalities were detected in 34 patients, of whom 14 required treatment of the vascular lesion.5

Helical and multislice CT angiography (CTA) has emerged as a fast and minimally invasive study for the evaluation of PNI.7 This technology permits accurate evaluation of vascular and extravascular soft tissue and bone in less than 2 to 3 minutes and is readily available in most trauma centers.7 Signs of vascular, aerodigestive, neurologic, and bony injury are well demonstrated by CTA.7 Mazolewski et al, in a prospective study of zone II PNI, determined the sensitivity, specificity, positive predictive value (PPV), and negative predictive value (NPV) of CT angiography for significant injury to be 100%, 91%, 75%, and 100%, respectively.71 Inaba et al in a prospective study of PNI reported that multidetector CT angiography (MCTA) achieved 100% sensitivity and 93.5% specificity in detecting all vascular and aerodigestive injuries.72 Helical CTA (HCTA) has been compared to conventional angiography for the diagnosis of arterial injuries of the neck in several studies, and a sensitivity and specificity for HCTA as high as 90% to 100% has been reported.7,71,73-75 In 2002, Munera et al reported a sensitivity of 100% and specificity of 98.6% in the evaluation of arterial injury in PNI.76

Color flow Doppler imaging and duplex ultrasonography have also been used in the evaluation of penetrating neck injury.2,8,55

X-rays of the cervical spine and chest revealed surgical emphysema in the neck, a left upper lung field opacity compatible with contusion or hemothorax, and a bullet fragment over the left scapula.

Following intubation the patient was taken to the CT scanner sedated and paralyzed. An enhanced CT scan revealed no vascular injury in the neck. Extensive surgical emphysema was present but no airway injury was identified.

34.5.2 What Is the Appropriate Disposition of the Patient with PNI?

Unstable patients are taken urgently to the OR. Stable patients without airway compromise undergo evaluation as directed by the physical examination. If a significant injury is identified, surgical management is undertaken as indicated. If no signs or symptoms of significant injury are present, and no injury is identified on further investigation, then observation is appropriate.

The patient was taken to the OR for neck exploration. In the OR, a rigid pharyngolaryngoscopy, flexible bronchoscopy, and flexible esophagoscopy were performed. No penetrating injury was identified although the cephaled trachea could not be examined due to presence of the ETT. Edema of the pharynx and larynx was again noted. On neck exploration penetrating injury to the trachea at the third and fourth tracheal rings was identified and repaired, and a tracheotomy was performed. The projectile tract was followed to the level of the cervical spine. Soft tissue disruption was noted in the tracheoesophageal groove and raised the likelihood of recurrent laryngeal nerve injury.

Nasopharyngoscopy was performed on postoperative day 2 and confirmed vocal cord palsy. The patient was decannulated on postoperative day 3.

On follow-up examination 1 month postoperatively, the patient had no shortness of breath but was still hoarse. Endoscopy revealed a persistently paralyzed vocal cord and minimal narrowing at the site of the tracheal injury.

Optimal management of PNI requires knowledge of the anatomy of the neck, an understanding of the mechanism of injury, careful clinical examination, and investigation as directed by the physical examination. Management of the traumatized airway can prove to be the ultimate test of a practitioner's technical skills27 and clinical judgment.

A 50-year-old obese man (120 kg, 173 cm, BMI 40 kg·m−2) was scheduled for lumbar spine instrumentation. Preoperative airway examination revealed no obvious indicators of difficult laryngoscopic intubation apart from the fact that he had a beard. Following induction of anesthesia with fentanyl, propofol, and rocuronium, a Cormack/Lehane Grade 2 laryngoscopic view was obtained with a #3 Macintosh blade. Laryngoscopic intubation was achieved easily while using backward, upward, and rightward pressure (BURP) externally on the larynx. After securing the endotracheal tube (ETT), the patient was then turned into the prone position for the surgical procedure. Two hours after the start of surgery, and after 1500 mL of blood loss and the administration of 4000 mL of crystalloid, a leak in the ventilation system was identified.

35.2.1 What Are Your Concerns When a Patient Is Placed in the Prone Position for a Surgical Procedure?

Proper patient positioning for any medical procedure is an important consideration for a safe and successful outcome. The proper position provides for appropriate surgical access and guards against injury due to pressure points and strain on neurological and musculoskeletal structures. The prone position is most commonly required for surgical procedures on the spine, and for select procedures in neurosurgery, urology, and general surgery. This position is complicated by an increased risk of stretch and pressure injury of nerves, cardiovascular instability, difficulty with ventilation, and problems with providing cardiopulmonary resuscitation as compared with a supine surgical position. Airway considerations for patients placed in the prone position may include difficult access to the airway, migration of the ETT (tip of the ETT moving cephalad or caudad with head extension and flexion, respectively), limited ability to reposition the head and neck for bag-mask-ventilation (BMV), and the potential development of airway edema.

This case represents one of the most challenging situations for airway practitioners: regaining control of the airway promptly with the patient in the prone position. Limited information is currently available in the literature to assist the airway practitioner with critical decision making should they encounter this situation.

35.3.1 What Is the Differential Diagnosis of the Ventilation System Leak?

A ventilation system leak is a fairly common occurrence during surgery and is usually easy to manage. However, it is more complex when it occurs in the prone patient due to the unique challenges it presents the airway practitioner and the dangerous or life-threatening situation that may develop for the patient.

In diagnosing and managing this situation, the source of the leak must be promptly determined. This is usually accomplished by inspecting all portions of the anesthesia circuit in an organized and sequential manner. With the prone patient, it is usually easier to start at the anesthesia machine and work your way to the patient. This would include checking flow rates, ventilator/bag volumes, valves, circuit tubing, and connections.

Leaks within the anesthesia machine or circuit may involve circuit disconnects, leaks around circuit connections or valves, and undetected holes in circuit components. Management of such leaks may include increasing the fresh gas flow, or replacing part or all of the anesthesia circuit or machine.

Potential leaks associated with an airway device include: (1) partial or complete dislodgement of the device; (2) inadequate volume in the ETT cuff; (3) disruption of the ETT cuff; and (4) a leak from the pilot cuff apparatus (pilot valve or tubing leak). Leaks from these causes may require reinsertion of the device, or removal of a defective airway device, and reinsertion of an appropriate replacement device.

35.3.2 If the ETT Was Found to Be Dislodged from the Trachea, What Is Your Initial Management?

The goals of management are to regain control of the airway and to resume ventilation and oxygenation as soon as possible. If feasible, this should be achieved by turning the patient into the supine position. Operating room personnel must be informed of the emergency situation and additional help should be summoned. The difficult airway cart, the patient's stretcher or bed, and the resuscitation cart should be brought into the operating theater immediately. The surgical team should close the surgical wound as soon as possible to allow transfer of the patient to a stretcher in the supine position.

35.4.1 If a Stretcher Is Not Immediately Available, How Do You Provide Ventilation to a Patient in the Prone Position?

Options to regain control of the airway in a prone patient are similar to those in the supine patient. Bag-mask-ventilation (BMV) should be provided as soon as possible. However, BMV in the prone patient can be difficult due to limited access to the airway, difficult mask seal due to no occipital support to apply counter pressure to the head,1 and lack of clinical experience performing BMV in a prone patient. It may be necessary to use a two-person BMV technique, with one person achieving a mask seal using both hands, while the second person provides manual ventilation. Provided that a good seal can be maintained between the mask and the patient's face, BMV should be reasonably easy in a patient lying prone as gravity tends to move the tongue away from the posterior pharyngeal wall. Obtaining a good seal for BMV may prove difficult in this case scenario as the patient has a beard. The authors therefore would recommend starting with two-person BMV technique (see Chapter 7) and quickly proceeding to alternative methods of ventilation should there be any difficulty obtaining an adequate seal for BMV.

If BMV is not possible, an extraglottic device (EGD), such as the laryngeal mask airway (LMA), can be used to provide emergency ventilation and oxygenation for a patient in the prone position. A number of investigators have reported successful use of EGDs (LMA and LMA-ProSeal™) to regain control of the airway and provide positive-pressure ventilation following endotracheal tube dislodgement in the prone position.2,3 Insertion of the LMA in the prone patient should be attempted using the classic insertion technique recommended for patients in the supine position.4 Successful insertion of the LMA may actually be easier in the prone position because gravity helps to move the tongue and epiglottis5 away from the posterior pharyngeal wall and minimizes the risk of down folding of the epiglottis.

Other extraglottic devices (including the Combitube™ and LMA Supreme™6 may be used while the patient is prone, depending on the skill and experience of the practitioner, as well as the available resources. However, there are currently no reports in the literature of the successful use of non-LMA-derived extraglottic devices for patients in the prone position.

35.4.2 Would You Proceed with the Surgical Procedure, If Adequate Ventilation and Oxygenation Can Be Achieved Following the Successful Placement of a LMA?

As mentioned, successful insertion of the LMA in patients in the prone position has been reported. Ng et al reported successful LMA insertion following induction of general anesthesia for brief surgical procedures in 73 prone adult patients.5 However, difficulties were encountered with malposition of the LMA in four patients (5.5%), hypoventilation in two patients (2.7%), and bleeding in two patients (2.7%). Although these were considered to be minor problems, the authors clearly stated that successful insertion of the LMA in the prone position requires not only skill that comes from practice, but also the assurance that at any time the patient can be turned into the supine position should emergency airway management be necessary. Stevens reported successful use of the LMA in the prone position in 103 adult patients.7 One patient regurgitated green emesis (without sequelae) and another patient had inadequate ventilation, requiring reinsertion of the LMA in the supine position. Brimacombe et al described using the ProSeal LMA successfully in 245 adult patients in the prone position, although 8 patients required a second attempt at insertion of the ProSeal LMA aided by a laryngoscope and bougie.8 Herrick et al and Kee et al report incidences of airway obstruction of 3.5% and 3%, respectively, when the LMA was used in pediatric patients placed prone for radiotherapy.9,10 It is probably reasonable to use the LMA for short surgical procedures in the prone position as long as there is still the option of repositioning the patient supine in the event that airway management becomes problematic. However, it would be unwise to use the LMA for obese patients or for long surgical procedures with the potential of massive bleeding and fluid shifts, such as in this case scenario. It is common to observe an increase in the airway pressure during the course of the surgery in the prone position, particularly when there is massive blood loss and fluid shifts. In this patient, the LMA should only be considered as a temporizing measure until a more definitive airway can be secured.

Therefore, the authors believe that it is necessary to replace the ETT prior to resuming the surgical procedure in this patient.

35.4.3 How Do You Manage a Patient with a Difficult Airway Who Requires Prone Positioning?

Airway management of the patient with a difficult airway who requires surgery in the prone position poses unique challenges for the anesthesia practitioner. These issues can be categorized according to the etiology of the difficult airway: (1) anatomical characteristics making ventilation and/or tracheal intubation difficult; and (2) cervical spine instability. If difficult laryngoscopic intubation secondary to anatomical characteristics is predicted (LEMON, see Section 1.6.2), the technique utilized to manage the airway is dependent on whether or not ventilation can be readily provided by BMV, EGD, or a surgical airway, aspiration risk, the available resources, as well as the expertise of the practitioner. Once tracheal intubation has been achieved, the ETT must be carefully secured. The situation becomes more challenging when possible cervical spine instability or spinal cord damage exists. It is generally believed that awake bronchoscopic intubation and prone positioning of the patient prior to induction of anesthesia is ideal, because it allows verification of neurological integrity prior to surgery. However, there is no clinical evidence to support this practice. In a retrospective review of 150 patients with cervical spine injury, Suderman and Crosby found no difference in neurological outcomes following tracheal intubation awake or under general anesthesia, with or without in-line cervical spine immobilization11 (see Chapter 15).

35.5.1 Can Intubation Be Performed in the Lateral Position?

While transfer of the patient to the supine position would be ideal, it could be difficult to achieve in a timely manner and is not without considerable risk to the patient depending on the situation. Therefore, it is desirable to have several alternative approaches for reestablishing tracheal intubation in this particularly difficult situation.

If it is feasible to place the patient in a lateral position, the left lateral decubitus is preferred by some practitioners for laryngoscopy and intubation, as gravity will help to displace the tongue to the left and facilitate visualization of the glottis.1 However, others prefer the right lateral decubitus position as in this position, the operator's left arm has more room to maneuver during the procedure. The tongue can still be easily displaced by the laryngoscope in the right lateral decubitus position. Nathanson et al found tracheal intubation of a manikin in the lateral position to be more difficult than in the supine position.12 The ease of intubation increased with each subsequent attempt, indicating that operator experience was a confounding factor.12 An assistant may be necessary to stabilize the head, neck, and body while performing an intubation in a patient in the lateral decubitus position.

Blind endotracheal intubation techniques using the intubating LMA (Fastrach™, LMA North America, San Diego) and the lighted stylet have also been described with a patient in the lateral position.13-15 Experience with these intubation techniques will improve the operator's chance of success. Blind techniques should only be attempted after direct visualization techniques have failed, as anatomic distortion may be present.

35.5.2 What Are the Options for Tracheal Intubation in the Prone Position?

Reintubation while the patient is still in the prone position would eliminate the inherent risks associated with turning the patient. In addition to direct laryngoscopic intubation, alternative intubating techniques can be considered. These include the use of a flexible bronchoscope (FB), an intubating LMA (LMA Fastrach™, LMA North America Inc, San Diego, CA), light-guided intubation using the Trachlight™ (Laerdal Medical Corp., Wappingers Falls, New York), and digital intubation. However, there is limited clinical information with regard to the effectiveness and safety of these techniques in patients in the prone position.

Baer performed endotracheal intubation under direct laryngoscopy in the prone position in 200 patients undergoing lumbar surgery.16 Two failed intubations occurred and these patients were then intubated in the lateral or supine positions, with difficulty.16 This experience emphasizes the importance of airway assessment and management in the supine position when difficulty is predicted. We believe that tracheal intubation of patients in the prone position should be reserved for rescue situations and that elective intubation of patients requiring prone positioning should be performed in the supine position as this is most familiar to the airway practitioner.

Intubation in the prone position may be necessary if:

1. Ventilation and oxygenation are ineffective using BMV, the LMA, or the Combitube™.

2. Ventilation using BMV, the LMA, or the Combitube™ is adequate but a definitive airway is desired (eg, prolonged case, risk of aspiration).

3. Transfer of the patient to the supine position is impossible, or associated with extreme risk.

35.5.3 How Can Endotracheal Intubation Be Performed in the Prone Position in the Patient Presented Here?

Airway control in this case scenario can be reestablished by one of several techniques.

An intact ETT can be reinserted into the trachea by simple advancement, as long as the tip of the ETT is still in the glottis. This can be facilitated if a throat pack had been placed following the initial intubation. The ability to ventilate the patient through the ETT confirmed by the presence of an appropriate end-tidal CO2 waveform indicates that simple advancement of the tube may be all that is required. If ventilation through the ETT is difficult, it may still be possible to advance the ETT into the trachea with the aid of a lighted stylet, FB, or a tube exchanger. When using a tube exchanger (airway exchange catheter), the intratracheal location of the tube exchanger should be verified by flexible bronchoscopy or by detecting an appropriate end-tidal CO2 waveform when ventilating through the tube exchanger.

The tracheal tube should be replaced if there is evidence of tube damage and a significant leak exists. Small air leaks may be overcome by increasing inspired gas flow, if the remaining surgical time is short. The benefits of continuing the case without further airway manipulation must be weighed against potential further airway compromise and operating room contamination with anesthetic gases. Therefore, the anesthetic technique should be changed to TIVA, if required, should the anesthesia practitioner decide to proceed with the case in the presence of a small ETT leak. Larger leaks can be attenuated by the insertion of a throat pack, if not already present. If a throat pack was in place around the original ETT, it may be possible to pass a new ETT with a deflated cuff into the trachea through the cast (or track) made by the throat pack or it may be possible to change the tube over an airway exchange catheter. If these measures fail and airway control is lost, the throat pack should be removed if present and ventilation of the patient must be reestablished as soon as possible.

Tracheal intubation by direct laryngoscopy can be performed in the prone patient by the airway practitioner who is positioned at the head of the patient facing caudad and who uses the right hand to insert the laryngoscope into the pharynx and exposes the glottis (Figure 35-1). Operating the laryngoscope with the right hand while the practitioner faces the prone patient allows the laryngoscope blade to displace the tongue in the usual manner—away from the right side of the patient's mouth. The practitioner then uses the left hand to insert the ETT into the trachea. Alternately, direct laryngoscopy and intubation can be performed in a more conventional manner from either side of the patient (Figure 35-2). An assistant can turn the patient's head to the right and elevate the right shoulder slightly to facilitate access to the mouth. The head and neck can also be placed in the familiar sniffing position. This technique of laryngoscopic intubation in prone patients has been shown to be effective (99% success rate) and safe.16

Agrawal et al17 described the successful use of the ILMA for tracheal intubation in a patient in the prone position who presented with injuries precluding supine positioning. The ILMA can also provide a conduit through which an ETT can be advanced into the trachea blindly, or with the aid of a lightwand, or the flexible bronchoscope (see Chapter 12). However, insertion of an intubating LMA (as compared to the LMA Classic™) can be difficult in the prone position. Alternatively, a 7.0 mm ETT could be passed through a classic LMA with FB guidance if the "aperture bars" are removed to allow easier passage of the ETT through the opening in the LMA.

35.5.4 Upon Turning the Patient into the Supine Position, Bag-Mask-Ventilation Is Easy, But Direct Laryngoscopy Reveals a Grade 3 View. What Is the Appropriate Airway Management?

A previously easy intubation may be difficult upon returning the patient to the supine position. Anatomic distortion of the airway can occur due to factors inherent to the surgical procedure, to the prone position, to trauma during the initial intubation, or to dislodgement of the ETT. Cervical vertebral fixation and surgical manipulation of oropharyngeal and neck tissues can alter airway anatomy. Bleeding into the airway and hematoma formation can be associated with neck surgery. Prolonged surgical procedures with significant blood loss may be associated with generalized edema due to fluid resuscitation. Direct pressure on facial and neck structures and a dependent position compromise venous drainage and contribute to edema formation. Airway edema can alter the appearance of laryngeal structures and can make visualization of the larynx difficult.18-20 Edematous tissues may also be more easily traumatized.

In this case scenario, the patient was placed in the supine position and direct laryngoscopy revealed a Grade 3 laryngoscopic view. The application of BURP21 may improve the Cormack/Lehane view.22 If BURP does not improve the view of the glottis, alternative intubating techniques can be used, as long as effective ventilation and oxygenation can be provided by BMV. These techniques include the use of an Eschmann Introducer, lightwand (Trachlight™), intubating LMA, Glidescope™ (Keomed, Minnetonka, MN), Bullard laryngoscope, or FB. As each intubation attempt will likely decrease the chance of success on subsequent attempts, it is critical that the practitioner employs the technique with which he/she is most experienced. In general, in the presence of an abnormal upper airway (edema), tracheal intubation should be performed under direct or indirect vision, if at all possible. Use of the Eschmann Introducer can be considered to be a logical extension of direct laryngoscopy and has a high success rate in the presence of a Grade 3 view.23 It is also helpful to use a smaller ETT and lubricate the inside and outside of the ETT to minimize the resistance to passage through the larynx and assist in passing the ETT over the introducer.

If a visual technique is unsuccessful but BMV is adequate, nonvisual intubation techniques may be used with great caution, while preparing the patient for a surgical airway.

The lightwand is an invaluable tool for airway management, but its utility in obese patients is limited. Furthermore, in this case scenario, the failed laryngoscopic intubation is probably secondary to airway edema and/or trauma. The use of a nonvisual intubating technique, such as the lightwand, would therefore likely be unsuccessful in this setting.

For the patient in this case scenario, BURP did not improve the glottic view (Cormack/Lehane Grade 3 view) and passage of an Eschmann Introducer was unsuccessful. Subsequent use of the Glidescope™ (Keomed, Minnetonka, MN) with a styletted endotracheal tube resulted in successful intubation and rest of the case proceeded uneventfully.

35.6.1 How Can the Tracheal Tube Be Secured Following Intubation in a Patient with a Beard?

To minimize the risk of ETT dislodgement, it is imperative to secure the ETT properly, particularly for patients in a prone position. The most common method of securing the endotracheal tube is to tape it to the face. Unfortunately, the presence of facial hair, oils on the skin, perspiration, oropharyngeal secretions, and surgical skin preparation solutions can impair the adhesiveness of the tape. Generous use of waterproof tape and the use of multiple attachment points can reinforce the bond to the patient's face. The application of tincture of benzoin to the skin may improve tape adhesion. Although adequate taping is required for the prone patient, complete sealing off of the mouth should be avoided, as oropharyngeal secretions should be allowed to drain out. This will minimize pooling of saliva and secretions, which may loosen the tape. In addition, the use of an antisialogogue (eg, glycopyrrolate) may be helpful as a preventive measure to minimize secretions. Placement of a throat pack in the oropharynx or a gauze bite block may also limit the amount of secretions available to disrupt the bond between the tape and the skin. However, the airway practitioner must always be aware of the potential for local pressure injury (eg, lingual nerve injury) associated with the use of these throat packs and bite blocks.24,25

Patients with facial hair often pose additional problems with securing the airway. For these patients, it may be best to tie the ETT around the neck with an umbilical tape. It is important not to tie the ETT too tightly and thereby obstruct venous return from the head. If the ETT cannot be tied around the neck (eg, cervical laminectomy or post-fossa craniotomy) other possible options to secure the ETT include: (1) suturing the ETT to the lips; (2) tying/suturing the ETT to the upper incisors (if present) or nares; and (3) shaving the patient's beard prior to induction of anesthesia.

35.7.1 How Can Airway Edema Be Minimized in a Patient in the Prone Position?

Tissue edema, particularly in dependent areas, can occur in surgical procedures involving significant blood loss and/or fluid shifts. Intra-operative dislodgement of the ETT in the prone patient with significant airway edema can be a disaster. Therefore, all attempts should be made to minimize the development of edema during procedures performed in the prone position. In lieu of large amounts of crystalloid solutions, it is perhaps prudent to administer colloid solutions, such as hydroxyethyl starch preparations. Although the efficacy of this approach has not been scientifically validated, it is our practice to use colloid solutions judiciously in order to limit crystalloid use to between 2 and 3 L in total.

Venous drainage of the head and neck can be optimized by keeping the head elevated if possible and avoiding compression or kinking of jugular veins. If the head must be turned to one side for airway or surgical access, the degree of rotation should be minimized.

35.4.4 How Can Airway Edema Be Assessed and Managed?

The development of edema in the hypopharynx and larynx while in the prone position can produce airway obstruction following extubation. Clinical signs, such as facial, orbital, or conjunctival edema, distended neck veins, and venous congestion of the head may indicate the presence of upper airway edema. The use of a flexible nasopharyngoscope to assess the extent of airway edema prior to tracheal extubation may be helpful,26 although there have been no studies to confirm its utility.

There are no scientifically validated methods to assess the degree of postoperative airway edema or to predict post-extubation airway obstruction (see Section 28.4). However, the performance of a leak test prior to extubation in patients with suspected airway edema has been suggested.27 The leak test measures the decrease in exhaled volume returned to the ventilator following deflation of the endotracheal tube cuff. A positive leak test (>110 mL or >10% of the tidal volume) has been shown to indicate that airway patency is sufficient to tolerate extubation without post-extubation stridor (PES) (99% specificity, 98% PPV), although a negative leak test is not predictive of the development of PES.28 The leak test can also be performed by deflating the endotracheal tube cuff in a spontaneously breathing patient without ventilator support and then occluding the end of the ETT. The patient is observed for signs of an audible leak or coughing around the endotracheal tube. The absence of a leak and/or coughing are positive predictors for PES.29 Multiple studies have found the leak test to be either helpful for predicting adverse events30-32 or not,33-35 but they all suffer from study design flaws. Therefore, airway practitioners should recognize the potential limitations of the cuff leak test as they apply it in clinical practice.

Laryngeal ultrasound may be an emerging method for assessing laryngeal anatomy. Lakhal et al showed a strong correlation between laryngeal ultrasound and MRI for measuring tracheal diameter at the cricoid ring in 27 young adults.36 Ding et al reported a pilot study using a laryngeal ultrasound to predict post-extubation stridor in 41 patients.37 The investigators used real-time ultrasonography to evaluate the air leak and to determine the relationship between the air column width during cuff deflation and the development of PES. The results of this study suggest that laryngeal ultrasonography could be a reliable, noninvasive method in the evaluation of laryngeal morphology and airflow through the upper airway. Other predictors of PES include length of intubation, female gender, body mass index, and ratio of ETT size to laryngeal diameter.28,38 Kwon et al reported total operative time, and the volume of crystalloid and transfused blood given to be risk factors for delayed extubation.39

If the patient passes the leak test but still displays clinical evidence of facial and possible airway edema, it would be prudent to perform extubation over an endotracheal tube exchange catheter (Cook Critical Care, Bloomington, IN) to provide a means for ventilation should post-extubation airway obstruction occur. For patients failing the leak test, the authors recommend they should continue to be managed with an ETT in place until the airway edema resolves and a subsequent leak test is satisfactory. Although failing the leak test may not predict post-extubation problems with high specificity, using this approach provides for the greatest margin of safety for the patient. Appropriate treatment of airway edema includes elevation of the head and the use of steroids and diuretics. The efficacy of these measures has not yet been formally validated. Two recent meta-analyses40,41 provided a comprehensive review of the effect of steroids on PES and showed that there is evidence to support multiple doses of steroids given 12 to 24 hours prior to extubation in adults for preventing PES in high-risk patients (as determined by the cuff leak test). The evidence for prophylactic steroids in neonates or children is heterogenous but shows a trend toward benefit and should be considered for high-risk patients.41 Steroids may reduce the amount of airway edema and decrease the risk of post-extubation airway obstruction, however, evidence supporting a decreased rate of reintubation only exists in the pediatric population.42-46

Of all the potential complications associated with prone positioning for a surgical procedure, managing a failed airway is probably the most challenging. The inability to ventilate and oxygenate the patient is life threatening for the patient and demands immediate action from the airway practitioner. Airway management for the prone patient starts by ensuring the tracheal tube is well secured initially to prevent later dislodgement. Every effort must be made to minimize airway edema while the patient is in the prone position. This is particularly important for long surgical procedures involving significant blood loss and fluid shifts.

In the event that the ETT is dislodged from the trachea, oxygenation should be promptly provided by bag-mask-ventilation, or through an extraglottic device such as the LMA, until endotracheal intubation is reestablished. Provided that oxygenation can be maintained, the choice of intubating technique is dependent on the available resources, the patient position, and the skills of the airway practitioner. All airway practitioners must have a strategy to manage a failed airway in a patient in the prone position. Special attention must be paid to the assessment of airway edema prior to tracheal extubation.

A 50-year-old man presents with a 6-month history of progressive paraparesis. He had sustained a fall at work about 12 months ago and has complained of back pain since that time. He also complains of difficulty with urination and constipation over the past several weeks. Magnetic resonance imaging (MRI) reveals disc herniation at T10-T11 and spinal cord compression. He has been scheduled for T11 vertebrectomy, spinal cord decompression, and spinal instrumentation via a left thoracotomy. He is otherwise healthy. His medications include acetaminophen, and dexamethasone which has recently been added.

On examination, he is 173 cm (5 ft 8 in) tall and weighs 77 kg (170 lb). His vital signs are: blood pressure (BP) 140/80 mm Hg, heart rate (HR) 69 beats per minute (bpm) and regular, respiratory rate (RR) 16 breaths per minute, temperature 36.9°C, and oxygen saturation is 99% on room air. Examination of the lower extremities reveals 3/5 motor power in the left leg and 5/5 in the right leg. Sensation is altered below T11. The chest is clear to auscultation and the heart sounds are normal.

Airway examination reveals a Mallampati II classification, thyromental distance of 5 cm, mouth opening of 5 cm, mandibular mobility of 2 cm, normal cervical spine extension, and full dentition.

36.2.1 Is This Patient Fit for Anesthesia?

The patient has spinal cord compression with slowly progressive neurologic symptoms and requires surgery. He has no significant comorbidities and needs no preoperative medical optimization.

36.2.2 What Anesthetic Technique Is Required?

General anesthesia is required. Lung separation has been requested by the surgeon to optimize the surgical exposure.

36.2.3 How Can One Lung Ventilation or Lung Separation Be Achieved?

Double lumen tubes (DLT) have been considered to be the gold standard for lung separation.1-4 However, recently introduced bronchial blockers (BBs) have been shown to provide equivalent surgical exposure when compared to the DLT.5-8 The DLT is preferred when lung isolation is required to protect the nondiseased lung from contamination with blood or pus, in the presence of a bronchopleural or bronchopleural cutaneous fistula, and to perform unilateral pulmonary lavage.1 A contralateral DLT is preferred when a sleeve resection, or lung transplant is performed.5,9 However, there are many clinical situations in which a DLT may not be the best primary choice.2 The indications for the use of a bronchial blocker include the difficult airway, distorted bronchial anatomy, the presence of a tracheostomy, when a nasal intubation is required, and to avoid the need for a tube exchange. Currently available BBs include the Univent Torque Control Blocker, the Arndt Wire-Guided Endobronchial Blocker, the Cohen Flexitip Endobronchial Blocker, the Fuji Uniblocker, the HS Endoblocker, and the Coopdech Endobronchial Blocker.3,5,10-13

One lung ventilation using a DLT is planned in the operating room (OR), basic monitors are applied and a left radial arterial catheter is placed under local anesthesia. Following denitrogenation, general anesthesia is induced with propofol 175 mg, sufentanil 15 ug, and rocuronium 50 mg. Bag-mask-ventilation is easily performed. Direct laryngoscopy (DL) with a #4 Macintosh blade reveals a Grade 4 Cormack/Lehane view (soft palate only). Cystic tissue is noted to be present at the posterior aspect of the tongue.

36.3.1 Is This a Difficult Airway?

The term "difficult airway" has been used when conventional direct laryngoscopy reveals a Cormack/Lehane (C/L) Grade 3 (epiglottis only) or Grade 4 (soft palate only) view.9,14-16 Certainly, tracheal intubation can be more difficult in this clinical setting. The ASA Task Force on Management of the Difficult Airway defines difficult airway as "the clinical situation in which a conventionally trained anesthesiologist experiences difficulty with face mask ventilation, endotracheal intubation, or both."17 The other dimensions of airway management (ventilation by extraglottic device and surgical access to the airway) as outlined by Murphy et al must also be considered when estimating the magnitude of airway difficulty.18 DLTs and the Univent tube have been termed "difficult tubes" as they can be more difficult to insert due to their increased outside diameter (OD) and increased overall rigidity which impedes optimal shaping of the tubes.14,16 The criteria for difficult DLT insertion have not been well defined.1,2 However, difficulty can be encountered in the presence of a Cormack/Lehane II (partial glottis) view.9

36.3.2 What Are the Options for Airway Management in This Patient?

Mask ventilation has been demonstrated to be easy but direct laryngoscopy is difficult. The patient's position should have been optimal before induction. If not, then it should be optimized. Head lift and external laryngeal manipulation should be considered part of the best direct laryngoscopy technique. A blade change can be considered if it is anticipated that a specific anatomic problem can be overcome. Placement of a DLT is best accomplished with a curved blade as it leaves more space in the pharynx through which to pass the relatively bulky DLT.9 An Eschmann tracheal introducer (bougie) is unlikely to succeed in the presence of a CL Grade 4 view and may produce trauma.

In the patient who has a difficult direct laryngoscopy and who requires lung separation, the airway management options include placement of a single tube (SLT) and utilization of a bronchial blocker, placement of a Univent tube, or placement of a DLT. The decision to use an SLT as opposed to a Univent or a DLT is based on the degree of difficulty anticipated with the more difficult tube, which is a function of the available airway management equipment (eg, video laryngoscope), the airway anatomy/geometry, and the expertise of the airway practitioner, as well as the anticipated postoperative clinical course. If postoperative ventilation is possible or probable based on the length and extent or type of surgery, anticipated fluid shifts and transfusion requirements, hemodynamic stability, or marginal respiratory reserve, then placement of a DLT may require a tube change at the end of the case.1,2,9 Exchange of a DLT for an SLT at the end of the case is not without risk.2 Edema, secretions, and trauma from the initial intubation1-3,9,16 may make reintubation at the end of surgery more difficult. Optimal positioning for intubation at the end of surgery may also be more difficult to achieve. Reintubation at the end of surgery may be extremely difficult and can be a highly dangerous maneuver3 with potential loss of airway control.1 Aspiration and airway trauma can also occur.1

The decision to proceed with intubation with an SLT, a Univent, or a DLT is a matter of clinical judgment, taking into consideration the technical and airway anatomical issues as well as the anticipated clinical course. The requirement for lung separation must also be evaluated. The absolute indications for lung separation include massive bleeding or abscess in which the nondiseased lung must be protected from contamination, unilateral air leak from bronchopleural or bronchopleural cutaneous fistula, or unilateral pulmonary lavage for alveolar proteinosis or cystic fibrosis.1,3,9,16 Video-assisted thoracoscopic surgery (VATS) has also been included as an absolute indication for lung separation.1,16 Other indications for lung separation are relative and are to improve surgical exposure.3,16 Although many surgical procedures are more easily performed with the lung collapsed, if placement of a DLT or BB is problematic, the need for lung separation as well as the safety of the technique must be considered.9

Intubation techniques that can be used as an alternative to DL include flexible bronchoscopic intubation under general anesthesia, intubation using a video laryngoscope (Glidescope, McGrath, Pentax AirwayScope, Bullard, or Stortz VMAC), or intubation through an LMA or ILMA.

Intubation of the unconscious patient using the flexible bronchoscope is a widely accepted technique. Jaw thrust and tongue traction can be used to open the hypopharynx and facilitate passage of the scope. Minimizing the discrepancy between the OD of the bronchoscope and the internal diameter (ID) of the ensleeved endotracheal tube (ETT) will minimize the risk that the tube will meet obstruction as it is passed through the larynx into the trachea over the scope.

In the setting of predicted difficult DL, awake flexible bronchoscopic intubation has historically been considered to be the safest means to secure the airway9, and in the elective, predicted difficult airway, is still recommended as the preferred technique.3 However, with the introduction of devices that are proving to be useful in the difficult intubation, protocols are changing9 and video laryngoscopes are challenging bronchoscopy as the first choice for accessing the difficult airway.9,19-21

Flexible bronchoscopic intubation using a Univent tube can be more difficult than with a conventional ETT due to the fixed concavity of the Univent as well as its larger OD.1,22 When performing a flexible bronchoscopic intubation with a DLT, the length of the tube relative to the length of the shaft of the scope limits the maneuverability of the scope.16,23 The rigidity of the DLT also makes it harder to advance the tube over the scope.16

Intubation with an SLT utilizing the Glidescope is widely practiced and is associated with a high degree of success.24 Hernandez and Wong have reported the successful placement of a DLT using the Glidescope.25 Shulman and Connelly used the Bullard laryngoscope in a group of 29 patients scheduled for general anesthesia and lung separation.26 A DLT was successfully passed into the trachea in 28 of the 29 patients using the Bullard laryngoscope. Hirabayashi and Norimasa used the Airtraq laryngoscope to place #35 or #37 DLTs in 10 patients.27 Nine of the 10 patients had a CL Grade 1 to 2 view on DL with a Macintosh blade. Suzuki et al reported the successful intubation of a patient with a #39 DLT using the Pentax AirwayScope with a modified blade.28 Poon and Liu used the AirwayScope to place an Airway Exchange Catheter (AEC) into the trachea and then railroaded a #37 DLT over the catheter under visual control using the scope.29 Intubation with a DLT using the Bonfils intubation fiberscope30 and Wu scope31 have also been reported.

Retrograde intubation is an option in the clinical scenario presented here if the equipment and expertise are available.32,33

Intubation with an SLT or AEC through an LMA or ILMA is also an option.34 Intubation by transillumination utilizing a lighted stylet is a nonvisual technique and is not recommended in the presence of pharyngeal masses or anatomic abnormalities of the upper airway.35,36 However, placement of DLTs using a lighted stylet under general anesthesia in patients with predictors of difficult DL but without airway pathology has been reported.22,37,38

In the case presented here, a flexible bronchoscopic intubation under general anesthesia was attempted but the vocal cords could not be visualized. The glottis was visualized with the Glidescope but the larynx was noted to be extremely anterior and neither a bougie nor an ETT could be passed through the glottis because of the acute angle that needed to be negotiated up into the larynx. An ILMA was placed and satisfactory ventilation was achieved. The flexible bronchoscope was passed through the ILMA but the vocal cords could not be identified. The patient was ventilated through the ILMA until the muscle relaxation could be reversed and then awakened.

36.3.3 What Should Be the Next Steps in This Patient's Management?

The patient requires urgent surgery. He was transported to the post anesthesia care unit (PACU) for a period of observation. An explanation of the airway difficulty was provided to the patient, an antisialogogue was administered, and the patient was returned to the OR about 2 hours later for an awake flexible bronchoscopic intubation.

Awake flexible bronchoscopic intubation using an adult bronchoscope and an 8.5-mm ID SLT was performed under topical anesthesia (see Chapter 3). A remifentanil infusion was used to attenuate airway reflexes. The awake intubation was uneventful and was followed by the controlled induction of general anesthesia.

36.3.4 Can Awake Flexible Bronchoscopic Intubation Be Done with a DLT?

Successful awake flexible bronchoscopic intubation with a DLT has been reported by Patane et al.23 The laryngeal and carinal stimulation produced by the DLT requires profound anesthesia of the airway.23 When the DLT has been placed in the trachea, general anesthesia can also be induced before advancing the DLT into the mainstem bronchus under flexible bronchoscopic control.

36.3.5 What Are the Options for Lung Separation in This Case Now that an SLT Has Been Placed?

The options for one lung ventilation include use of a bronchial blocker passed through the SLT or exchange of the SLT for either a Univent tube or a DLT using an AEC and under visual control utilizing a video laryngoscope.2,9,15,39,40

In the case presented here, it was decided to proceed with the placement of a bronchial blocker and not to exchange the SLT for a DLT. This decision was based on the degree of difficulty anticipated with the tube change and the risk associated with this maneuver, as well as the possibility of the requirement for post-op ventilation. An Arndt WEB was chosen and placed uneventfully.

The surgical procedure required 8 hours to complete. The estimated blood loss was 8000 mL. Eleven units of packed red blood cells, 1500 mL of plasma, 8 units of platelets, 6000 mL of crystalloid, and 1500 mL of colloid were administered. At the end of the case, edema of the face and tongue was evident.

36.4.1 Should This Patient Be Extubated?

The presence of airway edema will almost certainly make reintubation conditions even less favorable than they were at the beginning of the case. In addition, the patient has undergone an extensive surgical procedure, and the risk of respiratory failure in the immediate postoperative period is significant.

The BB was deflated and removed but the ETT was left in place. The patient was transported to the intensive care unit (ICU) in stable condition and electively ventilated. Twenty-four hours after the surgery the patient was awake and no longer required ventilatory support.

36.4.2 How Should the Patient Be Extubated at This Point in Time?

Whether the patient should be extubated in the ICU or in the OR is a matter of clinical judgment and to some extent dependent on the expertise and equipment available. Nasopharyngoscopy can be performed to determine the extent, if any, of airway edema, and the presence of an air leak around the tube may be reassuring.

Given the degree of difficulty experienced with the intubation, the patient was transported to the OR for extubation. Extubation was performed over an AEC, being careful to match the numbers on the catheter with the numbers on the SLT. A surgeon skilled in the performance of a surgical airway was present in the room and the equipment required was immediately available. Extubation was uneventful.

36.5.1 If the SLT Had Been Exchanged for a DLT after Induction, How Should This Be Done?

Tube exchange should be done utilizing an AEC and under visual control.2,3,15,41 If the glottis cannot be visualized by DL, then a video laryngoscope such as the Glidescope, McGrath, Pentax, or Stortz VMAC can be used.2,15 The AEC should be introduced no further than 24 to 26 cm from the teeth or lips in order to minimize the risk of trauma to the distal trachea and bronchi.3,9,15 The AEC should be at least 70 cm in length in order to permit control of the proximal end of the catheter with the DLT ensleeved.9 Utilization of an AEC at least 83 cm in length has also been recommended for a DLT exchange.15

36.5.2 If a DLT Had Been Used for Lung Separation, What Should the Appropriate Airway Management Have Been at the End of the Case? Can the Patient Go to ICU with a DLT in Place?

Intubation was difficult at the start of the case. Given the extent and duration of the surgery and the evidence of airway edema, exchange of the DLT for an SLT at the end of the case could be a highly dangerous maneuver.3 The view of the glottis was suboptimal with the Glidescope at induction and the angle into the larynx difficult to negotiate. The options then, are to leave the DLT in place, or perform a tracheotomy. If it is anticipated that the airway edema will recede in the immediate postoperative period and that prolonged ventilatory support will not be required, tracheotomy is not necessary at this time. Given the intraoperative course, placement of a BB through the SLT was a good decision and avoided the consideration of a potentially risky tube change at the end of the case.

A DLT can be used in the critical care setting for one lung ventilation or for postoperative two lung ventilation, if tube change to an SLT is considered to be too risky.9 However, ICU staff are generally less experienced in the management of a DLT16 and most ICU nurses are not comfortable with DLTs.1 If the DLT is left in an endobronchial position, malposition can occur and it has been recommended that in this setting neuromuscular blockade be employed.16 Alternatively, the DLT can be withdrawn such that the endobronchial lumen is above the carina and both lungs ventilated with both lumens with the bronchial cuff deflated.9 Suction is also more difficult through a DLT and secretions can be problematic.16

In the postoperative setting, extubation directly from the DLT can be performed when the condition of the upper airway and ventilatory function are satisfactory. If more prolonged but short-term ventilatory support is anticipated, tube exchange to an SLT can be performed when the upper airway is favorable. If longer-term ventilation is anticipated, tracheotomy without a tube change may be more appropriate.

36.5.3 What Would Have Been Appropriate Airway Management If the Surgery Had Been an Emergency and Could Not Be Postponed?

Intubation had failed by DL, Glidescope, flexible bronchoscope, and via the ILMA. The expertise to perform a retrograde intubation was not available and the likelihood of success was uncertain given the airway pathology. If the neurologic deficit had been acute, then a tracheotomy could have been performed under general anesthesia with the patient ventilated via the ILMA. A bronchial blocker could then be passed through an armored ETT or conventional tracheotomy cannula inserted into the tracheotomy stoma.9,15,42,43 If a wire-reinforced ETT is used, this can be changed for a tracheotomy cannula at the end of the case. A conventional DLT can be inserted through a tracheotomy stoma, or a DLT modified for use in tracheostomized patients (eg, Tracheopart or Naruke tube) can also be used.3,15,43-47 A conventional DLT placed through a tracheotomy stoma has been said to be prone to malposition15 as it is too long relative to the shortened upper airway and the tracheal cuff may be proximal to the stoma.16 Cohen has recommended that a rigid large diameter DLT not be passed through an old tracheotomy stoma.1 The Univent tube has also been inserted through a tracheotomy stoma to achieve one lung ventilation.48,49

36.5.4 If a "Cannot Intubate, Cannot Ventilate" Situation Had Occurred at Induction, What Would Have Been the Appropriate Management?

If ventilation by mask or extraglottic device had become impossible during the failed intubation attempts, emergency cricothyrotomy would have been indicated.3

The patient made an uneventful recovery. The diagnosis of lingual tonsillar hyperplasia (see Chapter 37) was subsequently confirmed by an ear, nose, and throat consultant. No treatment was required.

Lung separation can be achieved using a DLT, the Univent tube, or a bronchial blocker placed through an SLT. In the setting of a difficult airway, the decision to use a particular device must take into consideration the airway anatomy and geometry, the expertise and equipment available, and the anticipated postoperative clinical course. Airway management decisions will depend on whether the difficulty is predicted or unpredicted and whether the surgery is elective or emergency. In the management of the difficult airway, the first priority is to ensure adequate oxygenation and ventilation; one lung ventilation becomes a secondary objective.3

An obese, diabetic 57-year-old woman presented for femorotibial bypass with vein and graft. Despite a recommendation in favor, she refused regional anesthesia. A general anesthetic with endotracheal intubation due to the prolonged nature of the operation was planned. Following induction of general anesthesia, bag-mask-ventilation (BMV) was difficult and an immediate attempt at direct laryngoscopy was made. An obstructing soft tissue mass in the vallecula at the base of the tongue was observed with the direct laryngoscope; tracheal intubation was impossible with both direct laryngoscopy and with a lighted stylet and some bleeding was observed after several attempts at intubation. A size 3 laryngeal mask airway (LMA) was placed, adequate ventilation was achieved, the procedure was abandoned, and the patient was awakened and taken to the recovery room. Following the procedure, the patient was referred to an otolaryngologist, and nasolaryngoscopy revealed lingual tonsillar hypertrophy (LTH). The lingual tonsil was observed to be occupying and filling the vallecula and obstructing the view of both the epiglottis and the laryngeal inlet. Because she derived no symptoms from the lesion, surgical excision was not felt to be indicated and she was referred back to her vascular surgeon.

In the patient described, LTH completely obstructed the view of the larynx and access to the airway.

37.2.1 What Are Lingual Tonsils?

The lingual tonsils are components of Waldeyer throat ring and consist of lymphoid tissue located in the posterior third of the tongue which can extend into the vallecula. Waldeyer throat ring is completed by the adenoids and the palatine tonsils. Unlike the palatine tonsils, there is no definite capsule for lingual tonsils. They are inconsistent in their presence and are most typically absent in adults. When present, they lie on either side of the median epiglottic fold, may be both variable and asymmetric in size, and can become very large (Figures 37-1 and 37-2). The natural history of lingua tonsils is not well delineated; periodic growth and regression is likely. In a manner similar to the palatine tonsils, they may become inflamed and, when swollen (as in lingual tonsillitis), the mass may fill the vallecula and press the epiglottis down toward the glottis, causing variable degrees of airway compromise. They are not readily compressible and may not permit direct viewing of the laryngeal inlet with a direct laryngoscope during the course of conventional airway management.

37.2.2 How Common Is Lingual Tonsillar Hypertrophy?

Although lingual tonsillar hypertrophy or hyperplasia (LTH) was first described by Vesalius in 1543, its prevalence and relevance to clinical practice remains ill-defined.1 Reports of airway difficulties in patients with LTH are infrequent but recurrent suggesting that patients with the condition are regularly but not commonly encountered and recognized by anesthesiologists. Whether or not LTH would always be recognized as being present and being the underlying cause of airway difficulties is a relevant question. Goldman and Greenland reported separately of two patients in whom airway difficulties were encountered by experienced anesthesiologists.2,3 Postoperative assessments with video and MRI, respectively, revealed the presence of LTH which was suspected in neither case during the initial interventions.

Breitmeier et al conducted an assessment of 497 autopsy specimens to determine the incidence of LTH in an unselected population.4 In 16 specimens (3.2%) large lingual tonsils were detected. Of the 16 specimens with LTH, 10 had normal palatine tonsils and the others had either no palatine tonsil or remnants only. Adachi et al performed fiberoptic evaluation and tracheal intubation in 105 elective adult surgical patients to determine the incidence of LTH.5 Thirty-four patients (32%) had small lingual tonsils and seven patients (7%) had large lingual tonsils identified; there was no lingual tonsil identified in 64 (61%) patients. The correlation between the presence of a lingual tonsil and difficult intubation with a direct laryngoscope was not evaluated by these authors. Guimaraes et al evaluated the airways of 71 obese children between the ages of 13 and 21 using computed tomography to determine the frequency of LTH.6 Forty-four (62%) of the subjects had LTH, which is greater than the frequency previously reported in both normal subjects and those with obstructive sleep apnea. Ten of the children had very large lingual tonsils. Children with previous palatine tonsillectomy had a higher prevalence of measurable lingual tonsils and large lingual tonsils compared with those who still had their palatine tonsils.

Lingual tonsils are likely more prevalent than past reports would indicate, but are still relatively uncommon and probably impact on airway care infrequently. This is because even when present, they are usually small in size. It is probable that they would present difficulties either when they become very large or combine with other factors to make airway management difficult.

37.3.1 What Patient Characteristics Are Associated with LTH?

There are no large-scale studies of populations of patients which would allow for an accurate evaluation of the etiologic and associated characteristics in patients with LTH. The literature suggests that the presence of LTH may be associated with obesity, sleep apnea, and previous palatine tonsillectomy.1,4,6 The strength of the associations is not quantifiable and the majority of patients with these associated conditions do not have LTH. The patient described in the case was obese and, although she may have had an increased relative risk for LTH, she would have been considered to be at relatively low absolute risk due to the low population prevalence.

37.3.2 What Symptoms Occur in Patients with LTH?

Clinical symptoms of LTH are not present in all patients with the condition and, in fact, seem absent in many, even in some who present with very large lingual tonsils. Symptoms which do occur may be subtle and are neither sensitive nor specific. Some patients report a sensation of fullness or discomfort in the throat, rarely to the extreme of dysphagia.7 When they are inflamed, sore throat may be present. But, without knowing the presence of LTH, it is likely that the symptoms of lingual tonsillitis would often be ascribed to those of a common viral pharyngitis (simple sore throat). Very large lingual tonsils may cause obstructive sleep apnea or upper airway obstruction, but may also be associated with either mild or no symptoms.1,8,9 Acute and complete airway obstruction as a result of inflamed lingual tonsils has been reported leading to sudden death.10

The patient described in the case reported no symptoms attributable to LTH and was surprised to be presented with the diagnosis. Her husband reported that she was a noisy nocturnal breather, but neither she nor her husband described any signs or symptoms suggestive of obstructive sleep apnea.

37.3.3 Is LTH Detectable with Preoperative Airway Assessment?

Most patients with characteristics associated with LTH do not have the condition and many patients who actually have LTH, including those with very large tonsils, do not have symptoms. LTH is not detectable on routine preoperative physical examination or airway assessment. It is detectable with diagnostic imaging modalities such as plain x-ray, computed tomography, and magnetic resonance imaging as well as with upper airway endoscopy. Subjecting all patients with characteristics associated with LTH to more detailed preoperative airway assessments is difficult to defend from the perspective of both evidence base and resource utilization. However, because of the association between LTH and obstructive sleep apnea (OSA), consideration should be given to diagnostic imaging or nasopharyngoscopy to rule out LTH as an underlying cause in patients newly diagnosed with OSA.

The index patient described in the case had a reassuring airway examination and would not have been considered at risk for either difficult ventilation or intubation with a conventional airway assessment. There was no indication to subject her to a more rigorous airway evaluation based on the history and airway assessment.

37.4.1 What Are the Implications of LTH for Anesthesiologists?

The presence of LTH has been associated with difficult airway management following the induction of anesthesia, and in most of the published reports, LTH seems to be either the only factor responsible for the difficulties with airway management, or the most important one. In many instances, the patients were asymptomatic, had a normal preoperative airway evaluation, and the difficulties were unanticipated. In the largest series published in the anesthesia literature, that of Ovassapian et al, none of the 33 patients reviewed retrospectively had an airway examination that suggested an increased potential for difficult laryngoscopy or intubation.11 However, unanticipated difficulties were experienced with either or both bag-mask-ventilation and direct laryngoscopy in all of them. The lungs of 12 patients were difficult to ventilate by bag and mask. In five cases, failed intubation occurred but there were no details as to the number of attempts at direct laryngoscopy; in one case two failed attempts were made; in nine cases three failed attempts were recorded; in 14 cases four failed attempts occurred; in three cases, there were five attempts; and in one case, six attempts were made before the procedure was abandoned. The tracheas of six patients were subsequently intubated using a fiberoptic bronchoscope (FOB) with the patient awake; four of these interventions were characterized as moderately difficult and two as easy. Of the remaining 27 patients who subsequently underwent FOB-assisted tracheal intubation, 4 interventions were deemed difficult, 12 were moderately difficult, and 11 were reported as easy. Difficulty was experienced passing the endotracheal tube over the FOB and into the trachea in 11 patients. All 33 patients were subsequently evaluated using fiberoptic pharyngoscopy to determine possible causes of the failure; the only finding common to all 33 patients was the presence of LTH.

Other authors have reported similar findings with either single cases or smaller series. But the themes are consistent with the report of Ovassapian et al; unanticipated difficulties were often encountered with ventilation of the lungs and intubation of the trachea.9,12,13 These difficulties with ventilation were not always or easily overcome with the use of laryngeal mask airways nor were difficulties with tracheal intubation routinely or readily overcome with the use of adjuncts or alternatives to the direct laryngoscope. Difficulties seem common even in situations where difficulties were anticipated and experienced anesthesiologists deployed advanced alternatives for airway management. It is fortunately the case that, in many of the reports, it was possible for the anesthesiologist to maintain sufficient oxygenation through a variety of interventions to safely abandon further attempts at intubation and awaken the patient. However, Jones and Cohle reported a death due to failed airway management in a 24-year-old patient presenting with probable appendicitis.14 Following induction of anesthesia, bag-mask-ventilation was impossible and tracheal intubation failed despite repeated attempts with both a direct laryngoscope and a fiberoptic bronchoscope. A tracheotomy was performed but the patient never regained consciousness and died 8 hours postoperatively. At autopsy, a large lingual tonsil was discovered.

In the patient described in the case, moderate difficulties were experienced with bag-mask-ventilation although it was possible to maintain her oxygen saturation in a clinically acceptable range. However tracheal intubation was unsuccessful with both direct laryngoscopy and with a lighted stylet. Because of the difficulties with ventilation, a decision was made to attempt placement of a laryngeal mask airway, which was successful and resulted in an effective airway.

37.4.2 How Do Lingual Tonsils Interfere with Bag-Mask-Ventilation and Direct Laryngoscopy?

If the lingual tonsils are large enough, the airway is obstructed at the base of the tongue and elevation of the tongue may be inadequate to relieve the obstruction. Placement of an oral airway may result in the distal aperture of the airway being directly opposed by the tonsillar mass and obstructed as well. It is possible that a nasal airway may better bypass the obstruction caused by LTH than an oral airway, but this is by no means certain. In the patient described in the case, an oral airway did not seem to reduce the difficulties with bag-mask-ventilation and no attempt was made to place a nasal airway.

Successful laryngoscopy is dependent on the development of a line-of-sight from the eye to the larynx. Most difficulties with direct laryngoscopy can be grouped into a limited number of categories: mouth opening is inadequate to admit the blade adequately; airway angles are sharp and irreducible; soft tissues are either overabundant and compromising or noncompliant and unyielding; there are obstructing masses present; or blood and secretions interfere with light reflection. Horton et al demonstrated the importance during laryngoscopy of control of the hyoid bone with the tip of the laryngoscope blade reporting that the body of the hyoid was drawn forward and tilted downward.15 This tip placement resulted in tensioning of the hyoepiglottic ligament, elevation of the epiglottis, and exposure of the laryngeal structures. Tripathi and Pandey similarly reported that placement of the tip of a curved Macintosh blade in the pre-epiglottic space (vallecula) proximal to the hyoid bone achieved elevation and tilting of the hyoid bone, tensioning of the hyoepiglottic ligaments, and an optimal glottic view.16 The presence of the LTH at the base of the tongue, in the pre-epiglottic space, will prevent proper placement of the laryngoscope blade thus interfering with the basic mechanisms of laryngoscopy. The obstruction of the airway lumen by the LTH is the second factor that will interfere with the direct laryngoscopy.

The presence of the lingual tonsil may completely obstruct the line-of-sight necessary for successful laryngoscopy. Many of the alternatives to the direct laryngoscope, such as the indirect fiberoptic and video-optic laryngoscopes, also depend on the development of a line-of-sight from the instrument tip and this requirement may render them ineffective for the task of airway salvage if direct laryngoscopy proves to be impossible due to LTH. The use of blind techniques, such as the lightwand, in the presence of a known soft tissue mass in the airway is controversial and some would consider such techniques to be contraindicated due to the risk of tissue trauma and bleeding.

37.4.3 What Airway Management Practices Have Been Employed in Patients with LTH?

In the majority of reports, airway management difficulties were unanticipated and included both difficult or failed ventilation and intubation. The use of laryngeal mask airways is a common feature in the reports; the outcomes of LMA deployments ranged across the spectrum from successful ventilation and intubation using the LMA as a conduit for tracheal intubation, to no improvement in ventilation and continued failed intubation. With respect to difficulties encountered with intubation, in those scenarios that were unanticipated, the most common response was persistent attempt at direct laryngoscopy without success. The use of flexible bronchoscopes, Eschmann tracheal introducers (bougies) and intubation catheters, straight blades, and an anterior commissure blade by an otolaryngologist have all been reported with variable results.

The most common technology reported as being deployed in anticipated difficult situations (interventions made subsequent to the diagnosis of LTH being made) has been the flexible bronchoscope (FB), typically in an awake patient. Although usually successful, difficulties with both accessing the airway with the FB and subsequently with advancing the endotracheal tube into the trachea are common. These difficulties likely result not only from the obstruction of the airway lumen by the LTH but also from the requirement to pass deep to the LTH with the FB along the posterior pharyngeal wall, then to turn sharply in the opposite direction to access the laryngeal inlet, and finally to turn one more time to pass into the tracheal lumen. The turning radius of the FB is likely an issue when multiple turns have to be executed over a short distance.

The Bullard laryngoscope was employed in this case as it was thought that it would be capable of lifting the epiglottis and the tonsil to allow access to the laryngeal inlet. By performing the laryngoscopy in an awake patient, it was presumed that if a laryngeal view could not be obtained, the procedure could be safely abandoned and an alternative technique attempted.

37.4.4 What Is the Role of Extraglottic Airways in the Management of LTH?

The most commonly deployed extraglottic airway reportedly being used has been the laryngeal mask airway (LMA), in one form or another. These have been placed to facilitate both ventilation and intubation with varying results. In some reports, difficult ventilation was improved after the placement of the LMA, but intubation through the device was not possible.9,13,17 In other reports, placement of an LMA resulted in both a resolution of difficult ventilation and provided a conduit for successful tracheal intubation.2,18 Finally, some authors report little apparent improvement in difficult ventilation after placement of an LMA and failed attempts at intubation using the LMA as a conduit.12,19 The success of the LMA in reducing the severity of difficult ventilation and providing an intubation conduit in the setting of LTH is likely impacted both by the size of the tonsil, the position of the LMA orifice in relation to the laryngeal inlet, and the degree of airway obstruction resulting from the tonsillar hypertrophy. In most reports, placement of an LMA has resulted in some reduction in the ventilation difficulties being encountered. The available reports support a recommendation that placement of an LMA be considered early if difficulty with ventilation is being experienced in the setting of an LTH. Whether a smaller than usual LMA may provide equal or greater benefit in this setting is speculative.

A laryngeal mask airway was placed easily in the case described and resulted in a much improved airway. A size 3 LMA was used, although it would have been conventional local practice to use a size 4 in this patient.

37.4.5 Which of the Available Airway Technologies Should Be Most Effective in the Setting of LTH?

There are two anatomic issues relevant to airway management which must be considered in a patient with LTH. The first issue is the angles to be negotiated between the mouth and the glottic inlet and the second is the degree of obstruction of the airway lumen by the tonsil. As discussed, if the tonsils are very large, then to either access the laryngeal inlet or obtain a view of the larynx, the airway instrument must pass deep to the base of the tongue and behind the tonsil along the posterior pharyngeal wall. To get a view of the larynx, it must then move sharply anteriorly and away from the posterior pharyngeal wall to develop the line-of-sight. To access the laryngeal inlet it also must pass anteriorly and over the posterior commissure, and then turn once again to move down through the cords, and into the tracheal lumen. If the instrument is dependent for its success on the development of a line-of-sight from its tip to the laryngeal inlet from a point in the airway above the larynx, this line-of-sight is likely to be obstructed by the presence of large tonsils.

A rigid device such as the Bullard™ laryngoscope (BL) is possibly the ideal instrument for the management of the airway in a patient with LTH, both in the anticipated and unanticipated scenario.18,20 It is capable of negotiating the angles described and its robust construction permits gentle manipulation of airway tissues, allowing it to create the necessary endoscopic airspace. It may be used to gently elevate the lingual tonsil to reduce the degree of obstruction and, when placed in its final position, the tip of the BL rests beyond the lingual tonsil in the laryngeal inlet, bypassing the lumenal obstruction caused by the tonsil. Although the BL does require a line-of-sight from blade tip to target, typically the blade tip should be placed beyond the tonsil when positioned. Because it can carry the tracheal tube mounted on its dedicated stylet, no second working channel is needed for tube placement—an obvious advantage in the patient with a lingual tonsil and a relatively noncompliant airway. As well, in the scenario of an airway mass, the BL can be fitted with a standard surgical camera, allowing for visualization of the entire intervention and reducing the potential for trauma to the tonsil. Despite the theoretic advantages of an instrument, such as the BL for the management of the airway in a patient with LTH, it would be imprudent to conclude that it would always be effective.

The FB may also be used to successfully negotiate the angles described and is also capable of bypassing the obstructed lumen. Whereas a rigid instrument may be used to elevate tissues and reduce the angles which must be negotiated, the FB must negotiate them as it finds them. It may be very difficult to traverse the airway due to the repeated turns which must be executed over a relatively short distance. As well, it may be difficult to avoid soiling the bronchoscope on the tonsil or cause bleeding by contacting the tonsil if there is a high degree of obstruction of the lumen. Finally, passing the tube over the FB may prove difficult as well as the tube must negotiate the same angles previously negotiated by the FB. Warming the endotracheal tube and the use of a Parker-type tube and ensuring a close match between tube and FB diameters may all increase the likelihood of successful tube passage. As well, combining a rigid blade with the FB and using the blade to elevate the soft tissues to permit passage of the FB may be an effective salvage strategy.

Ultimately, it may not be possible to secure the airway from a supraglottic approach and either a retrograde or an infraglottic surgical approach may be necessary. A wire inserted through a cricothyroid membrane puncture could be used to facilitate either a retrograde intubation or to guide a supraglottic technique (eg, threading an FB loaded with an endotracheal tube). Cricothyrotomy or tracheotomy may be performed either electively or urgently if a "cannot intubate-cannot ventilate" situation is encountered.

As previously noted, and for the reasons already outlined, awake tracheal intubation was attempted with a Bullard™ laryngoscope. The Bullard™ blade was placed under the epiglottis and used to gently elevate both the epiglottis and the tonsil affording a full view of the larynx. Intubation of the trachea was readily achieved using a tube mounted on the dedicated stylet.

37.4.6 How Should the Algorithms of Chapter 2 Be Applied to the Care of the Patient with LTH?

If LTH is recognized before the induction of anesthesia, the airway assessment would be considered non-reassuring and concerns would be raised regarding both bag-mask-ventilation and tracheal intubation. Given that assessment, management would be directed by Panel A of the ASA Difficult Airway Management Algorithm in Figures 2-1 and 2-2, or the Emergency Difficult Airway Algorithm in Figure 2-5 and an awake intubation would be recommended; consideration should also be given to a surgical airway in some instances. If LTH was unanticipated and difficulties are experienced with ventilation and/or intubation, management would be directed by Panel B of the ASA Difficult Airway Management Algorithm in Figures 2-1 and 2-2 or the Failed Airway Algorithm in Figure 2-6.

37.4.7 What Is Optimal Elective Airway Management in a Patient Known to Have LTH?

Although bag-mask-ventilation has usually been possible in situations where LTH was unanticipated and encountered, both difficult and failed ventilation have been reported. As well, difficult and failed intubation using either direct laryngoscopy, and adjuncts and alternatives to the direct laryngoscope are common. It is the author's opinion that the airway assessment in a patient known to have LTH is non-reassuring with respect to both bag-mask-ventilation and tracheal intubation and an awake intubation is both the most prudent and optimal approach to airway management as dictated by the ASA Difficult Airway Management Algorithm (Figure 2-2).

37.5.1 How Was This Patient Managed?

When rescheduled for surgery, she again refused regional anesthesia but agreed to awake tracheal intubation. Preoperatively, she received glycopyrrolate 0.6 mg subcutaneously to dry oral-pharyngeal secretions. She was provided with supplemental oxygen by nasal prongs, incremental sedation, and topical anesthesia of the airway. A Bullard™ laryngoscope (BL) fitted with oxygen tubing (8 L·min−1), a dedicated stylet with a 7.0 mm ID endotracheal tube, and a surgical camera were introduced into the airway. Under video guidance, the laryngoscope was passed to the base of the tongue and used to gently elevate the lingual tonsil, allowing the laryngoscope to move beyond and into the laryngeal inlet, whereupon the vocal cords were visualized. The trachea was intubated and the surgery then proceeded uneventfully. At the end of the procedure, the patient was allowed to awaken and once fully and cognitively responsive, her trachea was extubated. She was observed in a high-surveillance nursing unit overnight and then discharged to a ward bed.

37.5.2 Are There Special Considerations for Tracheal Extubation in Patients with LTH?

It may be impossible to reestablish an airway in a patient with LTH following extubation of the trachea. The combination of the residual effects of the anesthetics, the anatomic sequela of the airway interventions, and the stress of managing a lost airway, superimposed on the preexistent pathology will likely combine to create the nightmare airway experience. Extubation of the trachea in a patient with LTH should only occur when there is clear evidence that the anesthetic effects are fully reversed, and that the patient is awake and cognitively responsive. The management of tracheal extubation in a patient with LTH would be directed by Figure 2-7, the Difficult Airway Extubation Algorithm and consideration should also be given to the routine placement of an airway exchange catheter before extubation of the trachea in these patients. As well, the anesthesia practitioner must have made preparations for a surgical airway if extubation leads to loss of the airway and it cannot be immediately reestablished.

37.6.1 Do Other Conditions Similar to LTH Occur with Airway Implications?

Laryngeal, epiglottic, and vallecular cysts have been cited in case reports as having been associated with both difficult and failed ventilation and intubation.21-23 They are relatively common and usually small but may become very large; most are asymptomatic with symptoms becoming more common as they become larger. Very large cysts may cause dysphagia and occasionally symptoms of airway obstruction. About half originate from the epiglottis and most of these are found on the lingual surface of the epiglottis.24,25 In adults, they are presumed to largely originate from obstructed ducts of submucosal glands with eventual dilation of the glands causing a retention cyst. As they increase in size, they may fill the vallecula and distort the epiglottis in a manner similar to that of lingual tonsils (Figure 37-3). They may occur at any age although they seem most common in the fifth and sixth decades. Routine preoperative airway evaluation is unlikely to reveal the presence of the cyst in the absence of symptoms. If suspicions are present, multiple diagnostic imaging modalities may be used to identify large cysts and nasolaryngoscopy is also useful. In many of the available reports, difficulties with bag-mask-ventilation were not encountered. However, difficult ventilation is more likely to be a potential issue with very large cysts and failed ventilation and death has been reported at induction of anesthesia. Aspiration of the cysts to facilitate airway management has also been reported by a number of authors and has been successful in reducing the degree of obstruction caused by the cyst.26 If large cysts have been identified on preoperative assessments, they should be more fully evaluated using diagnostic imaging and airway endoscopy to assess their size and the degree of airway compromise. Aspiration of very large cysts before the induction of anesthesia has been reported.27 An awake intubation is probably the most prudent course of care.

37.6.2 What Information Should Be Provided to the Patient Once LTH Is Diagnosed?

The patient should be informed of the presence and implications of LTH and airway cysts and be provided with a difficult airway letter for future practitioners, stating the findings and recommendations. It has been our practice to refer these patients to an otolaryngologist for follow-up although management has been typically conservative in patients with asymptomatic lesions. Lingual tonsillectomy and excision, marsupialization, or de-roofing of cysts may be considered if the lesions are symptomatic.

LTH is a relatively uncommon disorder in adults defined by overgrowth of lymphoid tissues at the base of the tongue and in the vallecula. Most lingual tonsils, even if enlarged, are small enough so as to not interfere with airway management. But some may be so large as to completely obstruct access to the airway and be life threatening. LTH may be associated with obesity, sleep apnea, and previous palatine tonsillectomy, but the majority of patients with these conditions do not have LTH. Symptoms are not common, although, if present, are obstructive in nature and some patients provide histories of sleep apnea. Routine preoperative airway assessment is not likely to reveal the presence of underlying LTH, although imaging modalities such as radiography, computed tomography, and magnetic resonance imaging and endoscopy are all effective evaluation and diagnostic strategies. If significant LTH is recognized preinduction, consideration should be given to awake intubation. The flexible bronchoscope has been the most frequently described and the most effective technique for managing such patients. If LTH is not recognized preinduction, difficult or failed ventilation and laryngoscopy/intubation may be experienced. Varying success has been reported with the use of extraglottic devices to improve ventilation. If difficult laryngoscopy is experienced, persistent efforts at laryngoscopy are not likely to be successful. Early consideration should be given to salvage attempts with the flexible bronchoscope, rigid fiberoptic devices, subglottic airways, or abandonment of the anesthetic if that can be safely achieved. Patients who are newly diagnosed with LTH should be counseled as to its implications and offered consultation with an otolaryngologist.

A 55-year-old male patient with superior vena caval (SVC) obs-truction secondary to a mediastinal mass is scheduled for bronchoscopy and mediastinoscopy. The patient weighs 120 kg (250 lb) and has obvious swelling of the face, neck, and upper extremities. The tongue is large (Mallampati Classification IV) and the oral mucosa is plethoric. He is unable to lie flat, but is not dyspneic in the sitting position.

38.2.1 What Is the Pertinent Pathophysiology in SVC Syndrome?

The left and right subclavian and internal jugular veins join to form the brachiocephalic (innominate) veins, which in turn join to form the SVC. Venous drainage from the head and upper extremities then finds its final conduit to the heart in this large, but easily compressible, vessel. Extensive collaterals with the SVC include the azygos, the mammary, vertebral, lateral thoracic, paraspinous, and esophageal veins. The largest of these, the azygos vein, is formed from the junction of the right subcostal and the right ascending lumbar veins. It ascends in the posterior mediastinum and then passes anteriorly over the right main stem bronchus to join the SVC as the latter enters into the right atrium. Here, the area is anatomically crowded with lymph nodes, the pulmonary artery, and the tracheobronchial structures hemmed in by the sternum anteriorly. The low-pressure SVC can be obstructed, either indirectly by external compression from vascular structures, tumor, or enlarged lymph nodes or directly by primary or secondary intraluminal thrombus or tumor (Figures 38-1 and 38-2).

Obstruction of the SVC will result in upper body venous hypertension, which forces blood to seek an alternate pathway to the heart via the previously described collateral vessels and the inferior vena cava. This upper body venous hypertension results in the classic clinical signs and symptoms of the syndrome. These include facial, neck, and arm swelling, as well as engorgement of the mucous membranes, including those of the upper airway. In some patients, it may result in laryngeal or cerebral edema, predisposing to an increased risk of surgical bleeding.

Most cases of SVC syndrome are due to extrinsic tumor compression from bronchogenic carcinoma or non-Hodgkin lymphoma occurring in the right paratracheal space or right pulmonary hilum.1 From even a cursory glance at the anatomy, it is clear that the disease process may also compromise other major structures in the area, such as the pulmonary arteries, the right heart, and the tracheobronchial tree. With these factors in mind, the practitioner will want to determine the degree to which major structures are involved prior to embarking on induction of general anesthesia (GA).

38.3.1 What Evidence of Airway Compromise May Be Apparent on History and Physical Examination?

Airway compression may be heralded by cough, dyspnea, hemoptysis, and a history of recurrent pulmonary infection. A change in voice may be due to recurrent laryngeal nerve involvement or vocal cord edema. Dyspnea, often with a history of syncope, may not necessarily be due to airway compromise but secondary to right ventricular outflow tract or right heart compression.1

In this patient, the tongue is large, perhaps as a result of upper body venous hypertension, and the mucous membranes are plethoric, suggesting that the mucous membranes of the larynx in general, and glottis in particular, may also be engorged, edematous, and friable.

38.3.2 What Investigations Should Be Done to Assess the Airway of the Patient?

Smaller precarinal and left paratracheal tumors may not be evident, but information about the size and location of the majority of mediastinal tumors can be obtained from chest radiography. Pulmonary function tests may be useful in predicting postoperative respiratory complications. In a recent prospective study, Bechard et al2 found a 10-fold increase in postoperative respiratory complications (pneumonia, airway edema, atelectasis) in patients with a preoperative peak expiratory flow rate (PEFR) of less than 40% of predicted. In the same study, however, PEFR was not predictive of airway collapse. Flow-volume loops, in the supine and upright position, have been advocated to assess the degree of airway obstruction as it relates to body position and to distinguish variable from fixed intrathoracic lesions.3 However, Narang et al documented that the respiratory embarrassment caused by mediastinal masses tends to be characteristic of a fixed lesion causing predominantly inspiratory impairment.1

Recent contrast-enhanced CT or MRI imaging is the most useful of all investigations in defining the relation of the mass to the other mediastinal structures. The CT or MRI can provide the practitioner with the necessary information with regard to the presence of pericardial effusion, the degree of anatomic compression of the airway, and the degree to which structures, such as the pulmonary arteries, right ventricular outflow tract, and the heart, may be compromised (Figures 38-3 and 38-4A). Transthoracic echocardiography (TTE) is useful in assessing the presence of pericardial effusion and the dynamic effects of tumor mass on the heart and great vessels. Significant pericardial effusion can result in cardiovascular collapse on induction of general anesthesia and positive pressure ventilation.

In this patient, chest CT findings were consistent with SVC obstruction. There was no evidence of pulmonary artery, right ventricular outflow tract, and myocardial or tracheobronchial compromise, and no evidence of pericardial effusion.

38.4.1 What Complications Are Associated with Mediastinal Masses and General Anesthesia?

Most practitioners have a heightened sense of awareness when they are confronted with the patient with a mediastinal mass scheduled for surgery. We have all heard of the reports of airway obstruction or cardiovascular collapse.4,5 We may even be familiar with the anesthesia management dogmas associated with these cases. Much of the literature documenting these catastrophic scenarios, however, involves pediatric populations.6 Furthermore, it is clear that one cannot extrapolate what may happen in the adult patient from the pediatric literature. The situation is further complicated by the fact that many of the sickest patients, like those with SVC syndrome, are managed with chemotherapy or radiation to shrink their tumors prior to presenting for surgery and general anesthesia (GA) (Figure 38-4A and B), or they are managed with less invasive surgical techniques not requiring GA. Confusing the picture even more is the fact that some series include small or posterior mediastinal masses that are unlikely to be associated with significant cardiorespiratory compromise.2

The only studies that have evaluated the incidence of life-threatening cardiorespiratory compromise are those by Azarow et al6 and Bechard et al.2 Azarow et al6 noted that there was a significant difference in anesthetic risk between adults and children with mediastinal masses undergoing GA. The authors noted that although the mortality in both groups was similar, mortality in the pediatric group is primarily related to perioperative respiratory complications whereas mortality in the adult group is due to the malignancy itself.7 Total airway obstruction in pediatric patients during GA has been associated with preoperative tracheal compression of more than 50%.7 This, however, does not seem to be the case in adults. In Bechard's prospective study of 98 adult patients,2 there was no intraoperative airway obstruction in any of the eight patients with preoperative airway compression greater than 50%. Furthermore, there has only been a single case report in the literature, reporting a parturient patient with a severe airway obstruction during anesthesia.8 Tracheal compression greater than 50% in the adult population was, however, associated with a sevenfold increase in respiratory complications, but these were related to pneumonia, airway edema, and atelectasis in the first 48 hours postoperatively.2

Whether the patient exhibits signs and symptoms related to the mediastinal mass effect seems to be important. A study by Hnatiuk et al9 suggested that symptomatic patients were more likely to experience complications, and Bechard2 identified stridor, orthopnea, cyanosis, jugular distension, and SVC syndrome as factors associated with perioperative complications. In Bechard's study,2 3 of 105 anesthetics were complicated by severe cardiovascular compromise; 2 of which were associated with pericardial effusion. There have been reports of severe airway obstruction occurring in asymptomatic patients, but again this seems limited to the pediatric population.2

38.4.2 What Are the Airway Concerns for This Patient?

First of all, ventilation using a bag-mask may be difficult in this patient because he is obese, with a large tongue and edematous airway (see MOANS in Section 1.6.1).

Although the literature suggests that obesity,10-12 per se, is not a predictor of difficult oxygenation/ventilation with an extraglottic device (EGD), this patient with a large tongue in addition to an edematous upper airway should cause the wise practitioner to exercise caution when considering the EGD as a rescue technique should the airway be lost. (See RODS in Section 1.6.3.)

There are several airway characteristics of this patient that would suggest a difficult direct laryngoscopy. He has a Mallampati Class IV pharyngeal view, in spite of the fact that he may have adequate mouth opening and thyromental distance. He is likely to have some reduction in neck mobility. In addition, he does have significant venous congestion that involves the mucous membranes of the mouth, probably the tongue and likely the larynx. Therefore, in all likelihood direct laryngoscopy will be difficult.

Certainly, he is obese with swelling of his neck and evidence of upper body venous hypertension, all of which would make emergency cricothyrotomy a challenge.

38.4.3 What Are the Major Concerns with the Circulation?

The major concern, from a circulatory standpoint in the patient with a mediastinal mass, is circulatory collapse on induction of anesthesia and initiation of positive pressure ventilation. This is a possibility when the mediastinal pathology results in right ventricular outflow obstruction or direct heart compression by the tumor mass, or pericardial effusion compromising cardiac output. Again, in Bechard's study, 3 of 105 patients experienced life-threatening intraoperative cardiovascular events; 2 of whom had pericardial effusions.2

Patients with preoperative cardiovascular compromise may have symptoms, such as dyspnea, orthopnea, and a history of syncope. The structural abnormalities, whether they be right ventricular outflow obstruction or direct heart compromise, can often be appreciated on chest CT scan (Figure 38.4A and B). Dynamic factors associated with these structural abnormalities can be further assessed with transthoracic echocardiography (TTE). Significant pericardial effusions should be drained prior to presenting to the operating room for surgery. If there is significant right ventricular outflow obstruction, or direct heart compromise, as evidenced by clinical symptoms and/or CT and TTE findings, consideration should be given to planning for elective femoral-femoral cardiopulmonary bypass (CPB). Attempting to catheterize femoral vessels to initiate CPB following cardiovascular collapse is unlikely to be successful. Therefore, it is imperative that everything be in place prior to induction of anesthesia. A Japanese center recommended the use of a temporary extracorporeal axillofemoral venous bypass as a life-saving and auxiliary device in urgent operations for acute progressive SVC syndrome with symptoms of cerebral edema and upper airway obstruction due to intrathoracic malignancies.13

In patients with significant cardiovascular compromise, most surgery will be directed to obtaining a diagnosis to plan future therapy. Intrathoracic surgery under general anesthesia is a risky proposition in this group of patients. Every effort should be made to obtain a tissue sample from peripheral sites under local anesthesia. It is said that the practitioner who wishes to grow old slowly should palpate the neck and axillae of all such patients before considering GA and surgery.1

38.4.4 Are There Any Other Important Considerations?

In patients with SVC syndrome, there is the possibility of increased intracranial pressure due to obstructed cerebral venous drainage. Efforts to avoid the cerebral dilating effects of vapor anesthetics, such as hyperventilation and total intravenous anesthesia, may be considerations in this regard.

In the patient with SVC syndrome, large-bore IV catheters should be placed in the lower extremities as injected medications will make their way to the heart more quickly than through the obstructed route via the subclavian vein and SVC. Adequate intravascular volume is important, as is the immediate availability of inotropes and vasopressors.

38.5.1 What Is the Most Appropriate Airway Management Option for This Patient?

As a result of the factors discussed earlier, it is prudent to secure the airway awake using the flexible bronchoscope (FB). Successful topical anesthesia of the airway is improved by using a drying agent. This should be given subcutaneously (SC) or intravenously (IV) 20 minutes to 1 hour prior to bringing the patient to the induction area.14 Following FB intubation, the ventilation of patients with mediastinal masses can be managed in a variety of ways. In Bechard's study, only 15 out of 97 patients were induced using spontaneous ventilation and in only 3 was spontaneous ventilation used throughout.2

The textbook dogma of maintaining spontaneous ventilation throughout in the patients with mediastinal vascular and tracheobronchial compromise is based mostly on anecdotal information. Patients with an obstructive airway component, as may be the case in patients with mediastinal tumors, are potentially susceptible to so-called dynamic hyperinflation, or auto-PEEP, following initiation of positive pressure ventilation. This can increase global intrathoracic pressure contributing to decreased venous return and increased cardiovascular compromise.15

From a strictly respiratory perspective, it is a common belief that patients with airway compromise secondary to mediastinal mass effect are less likely to have an airflow obstruction with maintenance of spontaneous ventilation. This is based on the erroneous belief that mediastinal tumors behave more like variable rather than fixed intrathoracic lesions. Flow-volume loops in patients with variable intrathoracic lesions show a restricted expiratory flow but a largely unaffected inspiratory flow. Fixed lesions, in contrast, have an equal reduction in both inspiratory and expiratory flows compared to normal subjects.16 Vander Els et al3 studied patients with intrathoracic Hodgkin disease. They found that these intrathoracic masses behave more like fixed than like variable lesions with equal inspiratory/expiratory flow impairment or a predominant inspiratory flow reduction. As a result, maintenance of spontaneous ventilation in these patients would appear to be of little benefit.3

In this patient with no evidence of tracheobronchial compression or significant cardiovascular compromise, it is unlikely that there would be any advantage in maintaining spontaneous ventilation. Following awake bronchoscopic intubation, the patient can be induced breathing spontaneously followed by neuromuscular block and controlled ventilation, or neuromuscular block and controlled ventilation can be initiated immediately upon induction. Spontaneous, assisted ventilation throughout may be a consideration in patients with CT or echocardiographic evidence of significant cardiovascular compromise.

38.5.2 What Actually Happened in This Case?

The patient had no evidence of tracheobronchial, pulmonary artery, right ventricular outflow tract, or direct myocardial compromise. He received 0.4 mg glycopyrrolate subcutaneously 1 hour prior to transfer to the operating room in the sitting position. Two units of blood were immediately available. He was transferred to the operating table and was maintained in the semi-Fowler position. Standard monitors, including ECG and pulse oximetry, were applied. A 14-gauge venous catheter was placed in his left greater saphenous vein at the ankle and a #20 arterial catheter placed in the left radial artery. A 1.5-L bolus of saline was given in preparation for anesthetic induction. Increased inspired oxygen via nasal cannula at the rate of 3 L·min−1 was applied. The airway was anesthetized with a gargle of aqueous 4% lidocaine followed by nebulized 4% lidocaine using a DeVilbiss atomizer. The trachea was intubated with an 8.5 mm ID endotracheal tube over an adult FB. Breathing 100% oxygen, the patient received 150 mg of propofol and 30 mg of rocuronium. Following loss of consciousness, controlled manual ventilation was initiated and sevoflurane was introduced. Cardiovascular and respiratory parameters remained stable and the patient was placed on the ventilator. Once cardiovascular stability was assured, morphine 7.5 mg was given in divided doses. The surgical procedure lasted 50 minutes and was uneventful from a surgical and anesthetic standpoint. Neuromuscular block was reversed with neostigmine and glycopyrrolate. The patient was allowed to emerge from general anesthesia and extubated awake in the sitting position. The immediate post-extubation period was uneventful and he was transported, in the sitting position, to the post-anesthesia care unit (PACU) in stable condition breathing supplemental oxygen from a Venturi mask. The subsequent postoperative course was also uneventful.

38.5.3 What Is a Reasonable Approach for Extubation Following Emergence from General Anesthesia?

For all the reasons that this patient should have his airway secured awake, tracheal extubation should also be done when the patient is fully awake. In addition, worsening of airway edema can occur following endotracheal intubation and mediastinal surgery. Consideration may even be given to leaving an airway exchange catheter in the airway following extubation.17 The catheter can be removed when the practitioner is confident that the patient has an acceptable airway, with effective gas exchange.

In adult patients with SVC syndrome, the major considerations are with the edematous, congested mucous membranes that are prone to bleed and can make direct laryngoscopy and endotracheal intubation technically difficult and extubation potentially hazardous. It appears that life-threatening intraoperative airway obstruction in the adult is less of a problem than it is in the pediatric population. Life-threatening airway obstruction is unlikely to occur in adult patients with significantly compromised airways but pneumonia, airway edema, and atelectasis are more frequent in the first 48 hours postoperatively. The threat of post-induction cardiovascular collapse is limited to those patients with pericardial effusions, direct heart compromise by the tumor mass, and/or the potential for right ventricular outflow obstruction. These patients can be identified with careful preoperative assessment, including history, physical examination, CT scan, and echocardiography.

A 46-year-old ASA III man is scheduled to have a total knee replacement. His past medical history is remarkable for severe rheumatoid arthritis (RA) with cervical spine involvement. He was recently diagnosed with atlanto-axial subluxation, but he has no neurological signs. He has a history of gastroesophageal reflux disease (GERD), but it is well controlled with proton pump inhibitors. His other medications are an NSAID and low-dose glucocorticosteroid therapy.

On physical examination, he weighs 67 kg (148 lb) and is 167 cm (5 ft 6 in) tall, his BMI is 23.9 kg·m−2. Examination of his airway reveals that he has a full beard and small chin, no teeth, 3.0 cm of mouth opening, and that his neck is fixed in moderate flexion. This same surgery was previously cancelled as the patient refused to complete an awake bronchoscopic intubation. The patient now emphatically refuses to consent for awake bronchoscopic intubation.

39.2.1 What Is Rheumatoid Arthritis? What Are the Anesthetic Implications of This Illness?

Rheumatoid arthritis (RA) is a lifelong (chronic) multisystem illness, which represents the most common form of chronic inflammatory arthritis and affects approximately 1% of adults (range 0.3%-2.1%) in the United States and Europe. Women are typically affected two to three times more often than men and the prevalence increases with age. The etiology of RA remains unknown, but it is evident that complex interaction between environmental factors (including infectious agents) and the immune system in genetically susceptible individuals plays an essential role.1 The class II major histocompatibility complex allele HLA-DR4 has been found to be a major genetic risk factor. The onset of RA is typically gradual between the age of 35 and 50, and may be of nonspecific nature.2,3 Synovial inflammation, cartilage damage, and bone erosion with subsequent destruction of joint integrity are the hallmarks of this illness. The course is characterized by symmetrical polyarthropathy and variably, considerable systemic involvement. As the disease progresses, cervical spine involvement becomes common, second only to involvement of the metatarsophalangeal joint.1

Extraarticular manifestations of RA are widespread and can affect as many as 40% of patients, 15% of whom appear to be severely affected.1,2 Many of these manifestations have a serious impact on anesthesia care. Cardiac manifestations most commonly present as pericarditis with effusion (in one-half of patients), but may also include cardiac conduction abnormality, granulomatous myocarditis, and valvular pathology. Rheumatoid vasculitis can affect almost any organ system and may produce coronary artery arteritis contributing to coronary syndrome. Pleuropulmonary pathology, which occurs more commonly in men, includes pleural disease, effusion, pleuropulmonary nodules, interstitial fibrosis, obliterative bronchiolitis, and pneumonitis. The prevalence of airflow obstruction in rheumatoid patients is remarkably high, suggesting it might be the commonest form of pulmonary involvement.4 Rheumatoid nodules and osteoporosis may develop in up to 30% of patients with RA. Neurologic manifestations may result from cervical spine subluxation and nerve entrapment secondary to proliferative synovitis or joint deformities which can produce various neuropathies.

Other important extraarticular manifestations include ocular involvement, which occurs in 25% of individuals with RA, such as keratoconjunctivitis sicca, and hematologic changes—chronic anemia and thrombocytosis.1,2

39.2.2 How Does Rheumatoid Arthritis Affect the Airway?

Airway management is one of the most critical aspects of anesthesia care of RA patients. There are several important elements implicated in how RA progression affects the airway of these patients:

1. Cervical spine. (Figure 39-1) Progression of RA of the cervical spine affects 15% to 86% of these patients, eventually leading to disintegration of cervical spine joints. Twenty-five percent of hospitalized RA patients have cervical pathology. Pain (40%-88%), neurologic deficiencies (7%-34%), and even sudden death from brain stem compression (10%)5 are possible manifestations of cervical spine involvement.1 The three most commonly observed forms of cervical pathology in RA include: (1) anterior or rarely posterior atlanto-axial subluxation (AAS); (2) vertical subluxation or atlanto-axial impaction; and (3) sub-axial subluxation. Anterior AAS, the most common of these abnormalities occurring in 43% to 86% of patients, is associated with a greater than expected mortality in this group.1,6,7 AAS is commonly associated with spinal cord compression and neurological deficits. However, absence of preoperative neurological symptoms may not assure perioperative safety, particularly under general anesthesia when neurological symptoms may not be detectable.7 Thus, specific precautions are warranted during airway manipulation and intraoperative positioning to avoid spinal cord injury. In addition, RA-related cervical spine rigidity and flexion deformity will present further complexity in airway management.7,8

2. Temporomandibular joints (TMJs) and mandible abnormalities. Up to 31% of RA patients report TMJ dysfunction. The severe form of this abnormality can lead to TMJ ankylosis and can significantly reduce the patient's ability to open the mouth. It has also been associated with high incidence of upper airway obstruction.9,10 In a study of 218 RA patients, a positive correlation was reported between the severity of RA and the range of motion of the jaw.10

3. Micrognathia. Hypoplastic mandible, another airway hazard, is found to be associated predominantly with a juvenile form of RA, in some cases as a congenital association, in others—due to affection of TMJ arthritis.11

4. Cricoarytenoid arthritis. This is reported in 30% to 50% of RA patients, and between 45% and 88% in postmortem studies.12 The prevalence of this potentially life-threatening condition seems to be much higher than expected. There are numerous reports of severe and even fatal airway obstruction in any period of the perioperative course, frequently unanticipated.12-15

5. Rheumatoid nodules. These nodules of the larynx and laryngeal deformity related to RA have been occasionally reported as a cause of airway complications that contribute to difficulties in airway management of RA patients.9,15,16

In summary, RA patients may frequently confront the anesthesia practitioner with multiple challenges in airway management throughout the perioperative course. This may be due to a severe form of a single airway–related pathology or any combination of pathologic changes such as cervical spine problems (rigidity, AAS, low cervical subluxation), TMJ ankylosis, micrognathia, cricoarytenoid arthritis, and laryngeal tissue damage. When approaching these patients' airways, the anesthesia practitioner should bear in mind that there are two separate facets of the problem: high incidence of difficult direct laryngoscopy requiring an alternative technique(s) and a danger of neurological complications as a consequence of airway manipulation. Tests of RA activity and the duration of the disease did not show direct correlation with the incidence of difficult intubation.17 Thus, meticulous preoperative airway assessment in these patients is warranted regardless of the severity and duration of disease.

39.2.3 What Is Informed Consent? What Are the Elements of Informed Consent?

Legal and moral basis of informed consent is established on the ethical principle of respect for patient autonomy and self-determination. In the United States, this is also rooted in constitutional guarantees of privacy and noninterference. In 1914, the case of Schloendorff v. Society of New York Hospital established that it was the right of "every human being of adult years and sound mind to determine what shall happen to his own body."18,19 The term "informed consent" came into common use in 1957 as a result of the case of Salgo v. Trustees of Leland Stanford Hospital, when it was postulated that physicians have a duty to inform patients about the risks and alternatives to treatment, in addition to the procedures themselves and their consequences.19 This gave the concept of informed consent its modern interpretation, which was directed to maximize the ability of the patient to make substantially autonomous informed decisions. In other words, informed consent is the process by which a fully informed patient can participate in the decisions about his or her health in a meaningful way. It is generally accepted that in order to complete a modern informed consent properly, the following seven components and principles must be established.19

1. Decision-making capacity. Decision-making capacity is a reasonable ability to understand discussed issues and make a particular decision at a specific time as well as the ability to express a preference based on rational, internally consistent reasoning.

2. Voluntariness. The voluntariness principle is based on the notion that physicians should perform procedures only on competent patients who participate willingly. Anesthesiologists may potentially compromise voluntariness through manipulation and coercion when they physically or pharmacologically restrain patients who have sufficient decision-making capacity.

3. Disclosure. The goal of disclosure is to provide comprehensive information to the patient relevant for her/his decision-making. The exact nature of the procedure must be discussed. Reasonable alternatives to the proposed procedure must be discussed revealing pros and cons of those options.

4. Recommendation. Anesthesiologists should present an expert opinion regarding advantages and disadvantages of each option. Patients can then participate in decision-making to determine the best option which suits their priorities.

5. Understanding. Considerable efforts should be made to confirm that patients understand the risks and benefits of the proposed procedures, and why those recommendations were made. Pain and distress in various patients' groups, including parturients, do not appear to impair comprehension or preclude obtaining a legally sufficient informed consent.

6. Decision. After the comprehensive information, including the anesthesiologist's recommendation, the patient takes part in the choice of the appropriate anesthetic technique. Patients may vary in their preferences for decision-making participation; therefore, anesthesiologists should thoughtfully attempt to tailor the extent of patient and physician decision-making to the individual patient and the situation.

7. Autonomous authorization. Finally, the informed consent process concludes with the patient intentionally authorizing the anesthesiologist to perform a specific procedure or intervention, and this will constitute the patient's self-determination and the basis of informed consent.

39.2.4 What Is Informed Refusal of Treatment or a Procedure? What Are the Options for the Anesthesia Practitioner in This Case?

Informed consent would be meaningless if the patient cannot also decline medical intervention based on his/her reasoning.20-22 It is essential, in recognition of patient autonomy, to show recognition and respect for different individual values that may be reflected in the patient decision-making process.23 However, if a patient rejects an anesthesiologist's advice, or requests a technique that the anesthesiologist believes is inappropriate, the focus of discussion turns from informed consent to informed refusal. In this case, in addition to all requirements similar to informed consent, the patient should be substantially well versed about the risks and benefits of refusal and, importantly—about reasonable alternatives. Despite full disclosure and proper consent procedure, some patients may occasionally demand or reject an intervention that is extremely unreasonable, and predictably associated with inappropriately high risk. Determination of an appropriate choice of anesthesia is difficult and should not be made lightly or out of convenience. The conscientious physician cannot be forced by anyone, including a patient, to practice negligently.19 It is important to remember that just as the patient can refuse to have an awake intubation, the anesthesia practitioner may also decline to provide care to a patient, unless it is an emergency. In this case, an anesthesiologist who chooses to withdraw from the patient's care is obligated to make a reasonable effort to find a competent and willing replacement.19

In this case, in which the patient refuses an awake intubation, a complete discussion and description of the process of awake intubation must take place and an assessment must be made to determine that the patient fully understands the procedure. Efforts should be put forth to assure that patient refusal is not a result of false beliefs based on misinformation, misunderstanding, or atypical and inappropriate previous experience.20,23 Other alternatives to awake intubation must then be discussed with the patient, as well as the associated risks and benefits associated with these alternatives. Finally, the patient and the airway practitioner need to be in agreement with the proposed airway management plan, especially as the patient's cooperation is required.

In an emergency situation in which the patient requires a life- or limb-saving procedure and no other anesthesia care provider is available, the anesthesia practitioner is obliged to proceed under emergency conditions and honor the refusal of the patient to have a particular technique. In this situation, complete documentation should be performed, including a disclosure note on the chart that all inherent risks of the treatment options were described to the patient. The anesthesia practitioner must convey to the patient what procedure(s) is in the patient's best interest. If the patient denies consent, it may be helpful for the surgeon and/or family members to become involved in the decision-making. If the anesthesia practitioner ultimately fails to obtain consent for a procedure and nonetheless proceeds with that procedure, he/she assumes the risk that a charge of physical assault may ensue.24