Aspiration and Postoperative Respiratory Failure



Aspiration and Postoperative Respiratory Failure


David A. Berlin

Kapil Rajwani

Edward J. Schenck





A. Aspiration



  • What are the risk factors for perioperative aspiration?


  • How does large volume aspiration affect the respiratory system?


  • How should you manage the patient after an aspiration event?


  • How would you prevent aspiration during emergency surgery?


B. Postoperative Respiratory Failure

After successful lysis of abdominal adhesions, the patient recovers well and is extubated at the completion of surgery. Subsequently, she develops progressive hypoxemic respiratory failure while in the postanesthesia care unit.



  • How can you predict which patients will develop postoperative respiratory failure?


  • How can intraoperative anesthesia management prevent respiratory failure?


  • What is the pathogenesis of postoperative respiratory failure?


  • What is the diagnostic approach to postoperative respiratory failure?


C. Indications for Ventilator Support

The patient has worsening hypoxemia and tachypnea despite treatment with high-flow supplemental oxygen.



  • What are the indications for noninvasive positive pressure ventilation (NIPPV)?


  • What are the indications for emergency endotracheal intubation?


D. The Acute Respiratory Distress Syndrome

The patient is intubated for respiratory failure. She has bilateral pulmonary infiltrates on chest x-ray and is severely hypoxemic.



  • What is the definition and etiology of the acute respiratory distress syndrome (ARDS)?


  • Explain the pathophysiology of ARDS.


  • What role does ventilator-induced lung injury (VILI) play in ARDS?


E. Management of Mechanical Ventilation



  • Which mode of mechanical ventilation will you choose? Describe the features of that mode.


  • How should you set the fraction of inspired oxygen (FIO2)?


  • How should you set the positive end-expiratory pressure (PEEP)?


  • What tidal volume and inspiratory pressure target should you set?



F. Management of Refractory Respiratory Failure

The patient remains hypoxemic on FIO2 of 0.8.



  • What else can you promote additional lung recruitment?


  • What rescue strategies can you use for refractory ARDS?


G. Adjunctive Management of Respiratory Failure

Since intubation, the patient has become hypotensive.



  • What is the cause and treatment of the hemodynamic instability associated with mechanical ventilation?


  • What is the adjunctive medical therapy for ARDS?


H. Liberation of the Patient from Mechanical Ventilation

The patient slowly recovers over the next 3 days.



  • Explain the importance of the decision to extubate the patient or continue mechanical ventilation.


  • How will you prepare the patient for liberation from the ventilator?


  • How will you recognize when the patient is ready for extubation?


A. Aspiration


A.1. What are the risk factors for perioperative aspiration?

Clinically significant aspiration is a relatively rare complication of anesthesia. The reported incidence is 1 to 5 per 10,000 patients, although it is more common in certain situations, such as traumatic brain injury. About half of the cases of perioperative aspiration occur during induction of anesthesia. Although an emergency indication for surgery is a major risk factor for aspiration, the majority of cases occur during elective procedures. Increased gastric pressure, decreased lower esophageal sphincter tone, and blunted protective airway reflexes promote aspiration. Therefore, risk factors for aspiration include full stomach, pregnancy, bowel obstruction, gastroesophageal reflux, obesity, gastrointestinal motility disorders, and neurologic conditions. Airway manipulation in an unfasted patient or an inadequate depth of anesthesia may increase the risk of aspiration. Many anesthetics reduce lower and upper esophageal sphincter tone and diminish protective airway reflexes. The appropriate use of laryngeal mask airways does not increase the risk of aspiration, although it may induce gastroesophageal reflux. Certain surgical procedures such as laparoscopic insufflation of the abdomen and bowel manipulation are associated with increased rates of aspiration.



Kluger MT, Short TG. Aspiration during anaesthesia: a review of 133 cases from the Australian Anaesthetic Incident Monitoring Study (AIMS). Anaesthesia. 1999;54(1):19-26.

Lockey DJ, Coats T, Parr MJ. Aspiration in severe trauma: a prospective study. Anaesthesia. 1999;54(11): 1097-1098.

Marik PE. Aspiration pneumonitis and aspiration pneumonia. N Engl J Med. 2001;344(9):665-671.

Ng A, Smith G. Gastroesophageal reflux and aspiration of gastric contents in anesthetic practice. Anesth Analg. 2001;93(2):494-513.

Smith G, Ng A. Gastric reflux and pulmonary aspiration in anaesthesia. Minerva Anestesiol. 2003;69(5):402-406.


A.2. How does large volume aspiration affect the respiratory system?

Aspiration of gastric and oropharyngeal contents causes three overlapping syndromes. First, aspiration of large particulate matter may obstruct the airways and lead to atelectasis. Acute aspiration pneumonitis is more common and is a result of chemical burning of the tracheobronchial tree and pulmonary parenchyma by gastric and oral fluids. Finally, aspiration of bacteria from the oropharynx or a superinfection of the chemical pneumonitis may result in aspiration pneumonia.

Mendelson originally described aspiration pneumonitis in 66 obstetrical patients who aspirated gastric contents during anesthesia. Respiratory distress and cyanosis developed
within 2 hours after aspiration event. All patients (except two who had airway obstruction from solid food particles) recovered within 24 to 36 hours without antibiotics and had radiographic resolution. Signs and symptoms of aspiration pneumonitis include cough, wheeze, dyspnea, hypoxia, fever, tachypnea, and crackles on lung auscultation. Radiography usually demonstrates diffuse bilateral infiltrates.

Aspiration pneumonitis may be mild and elude clinical detection. Rarely, aspiration is fulminant and rapidly fatal. Most patients rapidly improve after aspiration and have clearing of radiographic lung infiltrates. Occasionally, patients initially improve but then develop progressive lung infiltrates on chest radiograph. These infiltrates probably represent secondary bacterial infection or ARDS. The volume and pH of the aspirated fluid are important factors affecting the degree of lung injury. In adults, approximately 25 mL of gastric acid with pH <2.5 is considered a clinically relevant threat. Smaller volumes may produce a milder syndrome. Bile may elicit a potent inflammatory response and has been identified in patients’ endotracheal tubes. Atelectasis, peribronchial hemorrhage, pulmonary edema, and degeneration of bronchial epithelial cells all develop within minutes of aspiration. By 4 hours, the alveoli fill with polymorphonuclear leukocytes and fibrin and hyaline membranes form. Hyaline membranes form within 4 hours. The lung becomes grossly edematous and hemorrhagic with alveolar consolidation.

Aspiration pneumonia may result from a superimposed infection of the chemical injury or inhalation of microorganisms from the oropharynx. Poor dentition is a risk factor for aspiration pneumonia. Common bacteria include Haemophilus influenzae, Streptococci, and other anaerobes. The oral flora changes in chronically ill patients and those in health care settings for greater than 48 to 72 hours. In these patients, gramnegative bacteria and resistant Staphylococcus may colonize the oropharynx and cause pneumonia.



James CF, Modell JH, Gibbs CP, et al. Pulmonary aspiration—effects of volume and pH in the rat. Anesth Analg. 1984;63(7):665-668.

Marik PE. Aspiration pneumonitis and aspiration pneumonia. N Engl J Med. 2001;344(9):665-671.

Mendelson CL. The aspiration of stomach contents into the lungs during obstetric anesthesia. Am J Obstet Gynecol. 1946;52:191-205.

Mylotte JM, Goodnough S, Gould M. Pneumonia versus aspiration pneumonitis in nursing home residents: prospective application of a clinical algorithm. J Am Geriatr Soc. 2005;53(5):755-761.

Teabeaut JR II. Aspiration of gastric contents; an experimental study. Am J Pathol. 1952;28(1):51-67.

Wu YC, Hsu PK, Su KC, et al. Bile acid aspiration in suspected ventilator-associated pneumonia. Chest. 2009;136(1):118-124.


A.3. How should you manage the patient after an aspiration event?

Awake patients capable of airway protection should be placed in the upright or recovery position and encouraged to cough. However, clinicians may need to suction or rescue the airway if the patient has impaired protective airway reflexes. Supplemental oxygen should be administered for hypoxemia. Clinicians should avoid noninvasive ventilation because of the risk of gastric insufflation unless there is no further risk of additional vomiting. There is no evidence supporting lavage with saline or sodium bicarbonate. Gastric acid is rapidly neutralized by the physiologic response. When possible, the stomach should be emptied with a nasogastric tube. A chest radiograph should be ordered. In select circumstances, a bronchoscopy may be necessary for airway clearance and evaluation especially if airway obstruction is suspected. Bronchoscopy can provide quantitative lower respiratory tract cultures from bronchoalveolar lavage or protected brushings. These techniques can distinguish aspiration pneumonitis from pneumonia.

Although some animal studies support the use of corticosteroids in aspiration pneumonitis, there is no evidence of benefit in human studies. Moreover, the literature does not support the routine use of antibiotics immediately after aspiration. However, patients should be followed closely to identify the development of a secondary infection. If the clinicians diagnose aspiration pneumonia, they should choose antibiotics that provide coverage against oral flora including gram-negative coverage for patients with nosocomial
colonization. This may include extended spectrum beta lactamases inhibitors such as piperacillin-tazobactam.



Allewelt M, Schüler P, Bölcskei PL, et al. Ampicillin + sulbactam vs clindamycin +/− cephalosporin for the treatment of aspiration pneumonia and primary lung abscess. Clin Microbiol Infect. 2004;10(2):163-170.

d’Escrivan T, Guery B. Prevention and treatment of aspiration pneumonia in intensive care units. Treat Respir Med. 2005;4(5):317-324.

Downs JB, Chapman RL Jr, Modell JH, et al. An evaluation of steroid therapy in aspiration pneumonitis. Anesthesiology. 1974;40(2):129-135.

Dudley WR, Marshall BE. Steroid treatment for acid-aspiration pneumonitis. Anesthesiology. 1974;40(2): 136-141.

Marik PE. Aspiration pneumonitis and aspiration pneumonia. N Engl J Med. 2001;344(9):665-671.

Matthay MA, Rosen GD. Acid aspiration induced lung injury. New insights and therapeutic options. Am J Respir Crit Care Med. 1996;154(2 pt 1):277-278.

Ott SR, Allewelt M, Lorenz J, et al. Moxifloxacin vs ampicillin/sulbactam in aspiration pneumonia and primary lung abscess. Infection. 2008;36(1):23-30.

van Westerloo DJ, Knapp S, van’t Veer C, et al. Aspiration pneumonitis primes the host for an exaggerated inflammatory response during pneumonia. Crit Care Med. 2005;33(8):1770-1778.


A.4. How would you prevent aspiration during emergency surgery?

Certain measures may help reduce the risk of perioperative aspiration. These include adequate fasting, prophylactic antiemetics, rapid sequence intubation (RSI), limited tidal volumes if bag ventilation used, and extubation when patient has return of laryngeal reflexes. Anti-acid medications can increase gastric pH; however, their use is only supported by expert opinion.

RSI involves preoxygenation followed by intubation using an induction agent and neuromuscular blockade without face-mask ventilation. There are no prospective randomized controlled trials that show whether RSI reduces the incidence of aspiration. However, RSI has been shown to decrease the time to achieve successful intubation, which may be beneficial when the risk of aspiration is high. The value of cricoid pressure during intubation remains controversial.



d’Escrivan T, Guery B. Prevention and treatment of aspiration pneumonia in intensive care units. Treat Respir Med. 2005;4(5):317-324.

de Souza DG, Doar LH, Mehta SH, et al. Aspiration prophylaxis and rapid sequence induction for elective cesarean delivery: time to reassess old dogma? Anesth Analg. 2010;110(5):1503-1505.

Neilipovitz DT, Crosby ET. No evidence for decreased incidence of aspiration after rapid sequence induction. Can J Anaesth. 2007;54(9):748-764.

Ng A, Smith G. Gastroesophageal reflux and aspiration of gastric contents in anesthetic practice. Anesth Analg. 2001;93(2):494-513.

Wallace C, McGuire B. Rapid sequence induction: its place in modern anaesthesia. Contin Educ Anaesth Crit Care Pain. 2014;14(3):130-135.


B. Postoperative Respiratory Failure

After successful lysis of abdominal adhesions, the patient recovers well and is extubated at the completion of surgery. Subsequently, she develops progressive hypoxemic respiratory failure while in the postanesthesia care unit.


B.1. How can you predict which patients will develop postoperative respiratory failure?

Respiratory failure commonly complicates the postoperative period and is strongly associated with an increased mortality. A number of clinical prediction rules exist to predict the risk of postoperative pulmonary complications. Predisposing factors include a high American Society of Anesthesiologists (ASA) Physical Status Classification, poor functional status, and hypoalbuminemia. Lung diseases such as obstructive airways dysfunction and extrapulmonary diseases such as liver cirrhosis, congestive heart failure, and renal failure also predispose patients to respiratory failure. Additional risk factors include emergency indications for surgery, prolonged procedural time, and the requirement for large volume fluid and blood product resuscitation. Because of their effects on respiratory mechanics,
thoracoabdominal surgeries, especially aortic aneurysm repair, are particularly high-risk procedures.



Canet J, Gallart L, Gomar C, et al. Prediction of postoperative pulmonary complications in a population-based surgical cohort. Anesthesiology. 2010;113(6):1338-1350.

Johnson RG, Arozullah AM, Neumayer L, et al. Multivariable predictors of postoperative respiratory failure after general and vascular surgery: results from the patient safety in surgery study. J Am Coll Surg. 2007;204(6):1188-1198.

Neto AS, Hemmes SN, Barbas CS, et al. Incidence of mortality and morbidity related to postoperative lung injury in patients who have undergone abdominal or thoracic surgery: a systematic review and meta-analysis. Lancet Respir Med. 2014;2(12):1007-1015.


B.2. How can intraoperative anesthesia management prevent respiratory failure?

An extensive literature has evaluated the role of limiting tidal volumes to prevent VILI. Ventilation with tidal volumes greater than 8 mL per kg ideal body weight (IBW) is a risk factor for postoperative pulmonary complications in thoracic and abdominal surgery. Moreover, a randomized controlled trial in major abdominal surgery demonstrated that restricting tidal volumes from 6 to 8 mL per kg IBW decreased the incidence of postoperative respiratory failure. This intervention was part of a lung-protective strategy, which combined restricted tidal volumes with PEEP as compared to large tidal volumes without PEEP. Because the intervention also included PEEP, we cannot ascribe the full benefit to tidal volume restriction. In sum, the current data support targeting tidal volumes to less than 8 mL per kg IBW. The optimum dose of intraoperative PEEP is less clear. A meta-analysis revealed that a no PEEP approach was a risk factor of postoperative pulmonary complications in thoracic and abdominal surgery. However, a randomized trial during high-risk abdominal surgery did not demonstrate a benefit from high PEEP and recruitment maneuvers. As a whole, the current evidence supports the use of moderate PEEP (approximately 5 cm H2O) during surgery and using higher PEEP and recruitment maneuvers when the patient’s physiology suggests derecruitment.



Cypel M, Fan E. Lung injury after abdominal and thoracic surgery. Lancet Respir Med. 2014;2(12):949-950.

Futier E, Constantin JM, Paugam-Burtz C, et al. A trial of intraoperative low-tidal-volume ventilation in abdominal surgery. N Engl J Med. 2013;369(5):428-437.

Hemmes SN, Gama de Abreu M, Pelosi P, et al. High versus low positive end-expiratory pressure during general anaesthesia for open abdominal surgery (PROVHILO trial): a multicentre randomised controlled trial. Lancet. 2014;384(9942):495-503.

Neto AS, Hemmes SN, Barbas CS, et al. Incidence of mortality and morbidity related to postoperative lung injury in patients who have undergone abdominal or thoracic surgery: a systematic review and meta-analysis. Lancet Respir Med. 2014;2(12):1007-1015.


B.3. What is the pathogenesis of postoperative respiratory failure?

Numerous mechanisms contribute to the pathogenesis of postoperative respiratory failure (Fig. 3.1). A combination of postoperative pain, recumbent position, anesthetics, and impaired secretion clearance leads to collapse of dependent lung regions. Atelectasis increases shunt fraction, diminishes respiratory system compliance, and commonly contributes to postoperative respiratory failure.

Treating postoperative patients with high concentrations of inspired oxygen can lead to absorption atelectasis. Normally, the consumption of oxygen by peripheral tissues creates a small gradient between the gas tensions in the alveoli and pulmonary capillary blood. The gradient is normally small compared to the total gas tensions because nitrogen is the most abundant gas in both compartments. Nitrogen acts as a pneumatic splint in the lung by limiting the magnitude of the gas tension gradient between the alveoli and pulmonary capillary. Breathing high FIO2 denitrogenates the body and increases the partial pressure of oxygen in alveolar gas much more than in mixed venous blood. Without nitrogen, venous blood becomes very hypobaric relative to alveolar gas. Therefore, high FIO2 increases the gas tension gradient, which drives gas from the alveoli to the pulmonary capillary blood. This promotes the collapse of poorly ventilated alveoli (Fig. 3.2).

In the postoperative period, bronchospasm and impaired mucociliary clearance can decrease the rate of expiratory airflow and increase the work of breathing. Residual sedation and neuromuscular blockade may weaken respiratory muscles and diminish protective
muscle tone in the upper airway. Shock causes acidosis and hypoperfusion of respiratory muscles leading to respiratory failure. In particular, clinicians should consider the diagnosis of occult hemorrhage in any postoperative patient who develops respiratory failure. However, the clinician must also consider the opposite problem of fluid overload. Fluid accumulation in the lungs, chest wall, pleura, and peritoneum is a common problem and may decrease respiratory compliance and worsen gas exchange.






FIGURE 3.1 Pathogenesis of postoperative respiratory failure.






FIGURE 3.2 Nitrogen content of inspired air prevents alveolar collapse. On the left, secretions obstruct the airway while the patient was breathing room air. There is a small oxygen gradient between the alveolus and mixed venous blood. On the right, secretions obstruct the airway after denitrogenation. As a result, the mixed venous blood is very hypobaric compared with the alveolus. The alveolus will tend to collapse as O2 rapidly flows down its pressure gradient. CO2 and H2O have been omitted for simplicity. (Adapted from West JB. Respiratory Physiology. 4th ed. Baltimore: Williams & Wilkins; 1990.)









TABLE 3.1 Differential Diagnosis of Postoperative Respiratory Failure










Aspiration


Pneumonitis


Exacerbation of obstructive sleep apnea


Atelectasis


Wound infections


Abdominal compartment syndrome


Pneumonia


Upper airway obstruction


Diaphragmatic palsy from scalene nerve block


Bleeding and shock


Neuromuscular weakness


Pleural


Effusions


Exacerbation of underlying lung disorder


Acute respiratory distress syndrome


Pulmonary embolism


Pulmonary edema


The systemic inflammatory response to major surgery or an acute illness will increase rates of tissue oxygen consumption and carbon dioxide (CO2) production. The increased ventilatory requirement may impose an unsustainable burden on a respiratory system impaired by the aforementioned factors. This is especially true in the setting of debility, malnutrition, and chronic lung disease.



Aubier M, Trippenbach T, Roussos C. Respiratory muscle fatigue during cardiogenic shock. J Appl Physiol Respir Environ Exerc Physiol. 1981;51(2):499-508.

West JB. Respiratory Physiology—The Essentials. 9th ed. Baltimore: Lippincott Williams & Wilkins; 2012.


B.4. What is the diagnostic approach to postoperative respiratory failure?

The history of the patient’s illness provides key evidence for determining the cause of respiratory failure. The clinician should review the past medical history, anesthesia record, operative reports, and perform a careful physical examination. The integration of these data should generate a short list of diagnostic possibilities (Table 3.1). Laboratory testing can help exclude or confirm diagnoses.

Arterial blood gas analysis can help triage disease severity and identify alveolar hypoventilation, increased alveolar-arterial oxygen gradient, and acid-base status. Additional labs including complete blood count, metabolic profile, and coagulation parameters are important part of the early evaluation. Chest x-rays are an essential part of the diagnostic approach to respiratory failure. However, their interobserver variability is high and their diagnostic accuracy is limited in acute respiratory failure.

Point-of-care diagnostic ultrasound can aid the diagnosis of acute respiratory failure (Table 3.2). In critically ill patients, pulmonary ultrasound is superior to chest x-ray in identifying pneumothorax, consolidation, pleural effusion, and lung edema. The use of basic echocardiography to identify right or left heart dysfunction can improve diagnostic accuracy. This approach can help distinguish cardiogenic from noncardiogenic causes of pulmonary edema and raise the suspicion for pulmonary embolism. Ultrasonography, like all clinical skills, requires expert training.

Pulmonary emboli (PE) are common in the postoperative period. PE cause tachycardia, tachypnea, and mildly reduce SpO2. Large PE may cause shock. An abrupt increase in arterial to end-tidal PCO2 gradient can be a sign of increased alveolar dead space from PE. If a clinician suspects PE, a computed tomography (CT) angiography is the best test. Ventilation-perfusion scintigraphy is an alternative if CT angiography cannot be performed. Given the
high-case fatality rate of untreated PE, therapeutic anticoagulation is indicated when PE is strongly suspected or confirmed. Clinicians must carefully consider the risk of bleeding from surgery sites or neuraxial anesthesia.








TABLE 3.2 Pulmonary Ultrasound Findings







Sliding lung (rules out pneumothorax)


Lung point (rules in pneumothorax)


Diaphragm movement (rules out diaphragmatic palsy)


Consolidation


B lines (interstitial edema)


A lines (normal finding)


Pleural effusion


Pneumonia is the most important postoperative infection. Surgery, hospitalization, and illness alter the host’s bacterial flora and lead to pneumonia with antibiotic-resistant organisms. A chest x-ray, arterial blood gas, and blood cultures should be obtained in all patients suspected of having health care-associated pneumonia. In the case of ventilatorassociated pneumonia, clinical diagnosis may be inaccurate. Quantitative cultures of the lower respiratory tract obtained from bronchoalveolar lavage or protected brushings can assist the diagnosis.



American Thoracic Society; Infectious Diseases Society of America. Guidelines for the management of adults with hospital-acquired, ventilator-associated, and healthcare-associated pneumonia. Am J Respir Crit Care Med. 2005;171(4):388-416.

Bataille B, Riu B, Ferre F, et al. Integrated use of bedside lung ultrasound and echocardiography in acute respiratory failure: a prospective observational study in ICU. Chest. 2014;146(6):1586-1593.

Hemnes AR, Newman AL, Rosenbaum B, et al. Bedside end-tidal CO2 tension as a screening tool to exclude pulmonary embolism. Eur Respir J. 2010;35(4):735-741.

Kearon C, Akl EA, Comerota AJ, et al. Antithrombotic therapy for VTE disease: Antithrombotic Therapy and Prevention of Thrombosis, 9th ed: American College of Chest Physicians Evidence-Based Clinical Practice Guidelines. Chest. 2012;141(2 suppl):e419S-e494S.

Lichtenstein DA, Mezière GA. Relevance of lung ultrasound in the diagnosis of acute respiratory failure: the BLUE protocol. Chest. 2008;134(1):117-125.

van Belle A, Büller HR, Huisman MV, et al. Effectiveness of managing suspected pulmonary embolism using an algorithm combining clinical probability, D-dimer testing, and computed tomography. JAMA. 2006;295(2):172-179.

Xirouchaki N, Magkanas E, Vaporidi K, et al. Lung ultrasound in critically ill patients: comparison with bedside chest radiography. Intensive Care Med. 2011;37(9):1488-1493.


C. Indications for Ventilator Support

The patient has worsening hypoxemia and tachypnea despite treatment with high-flow supplemental oxygen.


C.1. What are the indications for noninvasive positive pressure ventilation (NIPPV)?

NIPPV may be an alternative to endotracheal intubation in some situations. NIPPV can deliver high flow rates of oxygen, maintain PEEP, stent open the upper airway, and unload the work of breathing. Careful patient selection and recognition of contraindications to its use are essential. In this patient, the vomiting due to bowel obstruction is likely a contraindication to a trial of noninvasive ventilation (Table 3.3). Generally, the etiology of the respiratory failure and the type of mask interface are more important determinants of treatment success than the mode of NIPPV. The clinical indications with the best supporting evidence for NIPPV are acute cardiogenic pulmonary edema, obstructive sleep apnea, and exacerbations of chronic obstructive pulmonary disease. In cardiogenic pulmonary edema, the application of positive pressure can markedly reduce left ventricular preload and afterload. Bilevel and continuous positive airway pressure (CPAP) modes are both effective in cardiogenic pulmonary edema. Although there is little data from randomized controlled trials, there is a compelling physiologic rationale for the use of noninvasive ventilation for respiratory failure due to neuromuscular weakness and obesity-hypoventilation syndrome.

The clinical trial data for NIPPV in other causes of postoperative respiratory failure are mixed. Clinicians must exercise caution when using NIPPV for acute hypoxemic respiratory failure. Although it can help avoid intubation in some situations, about half of the patients treated with NIPPV for ARDS or pneumonia ultimately require intubation. Patients with multiorgan dysfunction are more likely to require intubation. Unfortunately, the largest randomized trial of NIPPV for acute hypoxemic respiratory found no benefit. This trial used CPAP mode, which improved gas exchange. However, there was a markedly increased mortality rate among patients who failed NIPPV. There was also an alarmingly high rate of cardiac arrest during rescue intubation in this setting. This risk is likely due to the sudden derecruitment and loss ventilation during the intubation process.









TABLE 3.3 Use of Noninvasive Positive Pressure Ventilation in Acute Respiratory Failure



































POSSIBLE INDICATIONS


CONTRAINDICATIONS


Increased dyspnea


Respiratory arrest


Tachypnea


Unable to fit/wear mask


Excessive work of breathing


Progressive shock


Hypoventilation


Multiorgan dysfunction


Obstructive sleep apnea


Poor airway protection


Hypercapnia


Recent upper-airway or gastrointestinal surgery


Hypoxia


No patient cooperation



Progressive and severe clinical instability



Vomiting/hematemesis


Adapted from Nava S, Hill N. Non-invasive ventilation in acute respiratory failure. Lancet. 2009;374:250-259.

Only gold members can continue reading. Log In or Register to continue

Stay updated, free articles. Join our Telegram channel

Mar 18, 2021 | Posted by in ANESTHESIA | Comments Off on Aspiration and Postoperative Respiratory Failure

Full access? Get Clinical Tree

Get Clinical Tree app for offline access