Clinical Science  |   April 1998
The Self-inflating Bulb to Detect Esophageal Intubation during Emergency Airway Management 
Author Notes
  • (Kasper) Clinical Specialist, Respiratory Care Department, Harborview Medical Center.
  • (Deem) Assistant Professor, Departments of Anesthesiology and Internal Medicine (Adjunct, Pulmonary and Critical Care), University of Washington School of Medicine.
Article Information
Clinical Science
Clinical Science   |   April 1998
The Self-inflating Bulb to Detect Esophageal Intubation during Emergency Airway Management 
Anesthesiology 4 1998, Vol.88, 898-902. doi:
Anesthesiology 4 1998, Vol.88, 898-902. doi:
UNRECOGNIZED esophageal intubation can lead to progressive hypoxia, cardiac arrest, neurologic injury, and death. Unfortunately, clinical signs are insufficiently sensitive to detect esophageal intubation, [1,2] and thus other techniques to confirm correct placement of an endotracheal tube (ETT) are necessary. Because detection of expired carbon dioxide using capnometry or capnography has proved highly reliable for confirming ETT position, this technique has evolved as the “gold standard” in the operating room. [3–6] In the emergency setting involving out-of-hospital, emergency department, and intensive care unit intubations, however, where esophageal intubation is perhaps more likely to occur, [7] capnometry is not always available. Portable alternatives to capnometry include colorimetric end-tidal carbon dioxide detection [8,9] and the negative-pressure test using a syringe or a self-inflating bulb (SIB). [10–12] Although these methods have been reported sensitive and specific for elective procedures done in the operating room, fewer data are available comparing their use in the emergency or intensive care setting. We studied the SIB during emergency intubations to test its efficacy outside of the operating room.
With approval from our institutional review board, we prospectively enrolled 300 consecutive patients (219 male, 81 female; mean age, 49.7 yr) who were undergoing emergency endotracheal intubation at Harborview Medical Center between September 1, 1995 and March 31, 1996. All intubations were performed in the intensive care units (56%), the emergency trauma center (35%), or elsewhere (9%) by an anesthesiology attending physician or a resident. Most intubations were performed using direct laryngoscopy after administration of a hypnotic agent and a muscle relaxant, with cricoid pressure applied until correct placement of the ETT was verified. Immediately after intubation and before ETT cuff inflation, the following sequence was strictly followed by the respiratory care practitioner who was assisting with the intubation:(1) an SIB (Tube-Chek B; Ambu, Inc., Linthicum, MD) was compressed, connected to the ETT, and released. A 10-s period was allowed for the bulb to reinflate. (2) The ETT cuff was inflated. (3) An infrared carbon dioxide analyzer (Stat-Cap; Nellcor, Pleasanton, CA) was connected to the ETT, and five manual breaths were delivered via a resuscitator bag. Esophageal intubation was diagnosed if there was no detection of carbon dioxide at the fifth manual breath, in conjunction with a consistent clinical examination. Repeated laryngoscopy with direct visualization of the ETT was performed if the tube position was in question. Immediate reintubation was performed when esophageal intubation was diagnosed. (4) If esophageal intubation was ruled out by the previous techniques and the patient's arterial saturation remained > 85%, a colorimetric carbon dioxide detector (Easy-Cap, Nellcor) was placed between the ETT and resuscitation bag and the presence of a color change was sought after the administration of five manual breaths. If a discrepancy arose between the infrared and colorimetric detector, the infrared was assumed to be correct.
Data sheets were provided in each intubation tray and were completed by the respiratory care practitioner who assisted in the intubation. Data collected included the patient's age, sex, diagnosis, indication for intubation, number of intubation attempts, and route of intubation (nasal, oral, or tracheostomy). The results from the SIB, the carbon dioxide detectors, and the clinical examination were recorded along with the final decision regarding correct placement of the ETT and the need, if any, for reintubation. The final data analysis included only those patients in whom the SIB and carbon dioxide detection were used.
Because the test is designed to detect esophageal intubation, [12] we defined failure of the SIB to reinflate within 10 s as a positive result. False-positive results were thus defined as those in which the test indicated esophageal intubation when the ETT was confirmed to be in the trachea by other means, and false-negative results occurred when the test indicated tracheal intubation when the ETT was in fact in the esophagus. Standard formulas were used to calculate the sensitivity (true positives/[true positives + false negatives]), specificity (true negatives/[true negatives + false positives]), positive predictive value (true positives/[false positives + true positives]), and the negative predictive value (true negatives/[false negatives + true negatives]). The “rule of three” was used to estimate the sensitivity limits of our data. [13] Based on the binomial distribution, the “rule of three” states that if none of n patients shows the event in question, we can say with 95% confidence that the chance of this event is at most 3/n. For our data, n is the number of esophageal intubations, and the event in question is a false-negative result with the SIB.
Three hundred consecutive patients underwent 321 attempts at emergent tracheal intubation. Table 1shows the indications for intubation, which included acute respiratory failure (145 [48%]) and airway protection or the need to facilitate pulmonary hygiene (123 [41%]). The remaining patients were intubated for various emergency diagnostic procedures or during cardiopulmonary resuscitation. Forty-two patients (14%) had known obstructive lung disease (chronic obstructive pulmonary disease or asthma); 31 (10%) had acute pulmonary edema, and 104 (35%) had copious pulmonary secretions. Nine patients (3%) met criteria for the adult respiratory distress syndrome at the time of intubation. [14] 
Table 1. Summary Demographic Data 
Image not available
Table 1. Summary Demographic Data 
Three hundred sixteen tubes were available for testing. The SIB was not available for use during three intubation attempts because of misplacement of the device, but it was used during all other intubations. Surgical airways were required for failed intubation in two patients (0.6% incidence). During five intubation attempts, a tube was neither placed nor tested. There were 19 confirmed esophageal intubations (6% incidence). Difficult intubation, defined as three or more attempts at laryngoscopy, occurred in 10 patients (3% incidence).
(Table 2) shows the predictive value of the SIB to detect esophageal intubation. The device was 100% sensitive in detecting esophageal intubation, with confidence limits defined by the “rule of three” between 84–100%. The specificity of the SIB in confirming correct ETT position also was high (99%), and its positive predictive value was 0.86. The three false-positive results obtained with the SIB occurred during one case each of chronic obstructive pulmonary disease, copious secretions, and obesity (defined by body habitus and weight > 110 kg). Of note, there were three “false-positive” test results with both carbon dioxide analyzers, which occurred during cardiopulmonary resuscitation. The SIB reinflated quickly in all these cases.
Table 2. Predictive Value of the Self-inflating Bulb in Detection of Esophageal Intubation 
Image not available
Table 2. Predictive Value of the Self-inflating Bulb in Detection of Esophageal Intubation 
Esophageal intubation occurs relatively frequently in the emergency setting, with incidences ranging from 1–20%. [7,15,16] This complication is of particular importance if it is unrecognized. Because of the inaccuracy of clinical signs to detect esophageal intubation, capnography and capnometry have been adopted as the standard of care in the operating room. [1,2,17,18] Capnography and capnometry are not widely available outside the operating theater, however, and alternative techniques have been developed for the emergency setting.
We studied the reliability and predictive value of a relatively new technique for confirming ETT position during emergency intubation. We found that the negative-pressure test using an SIB is sensitive and specific for detecting esophageal tube placement in the emergency setting when the device is used as described in this study.
Ours is the largest series of emergency intubations to be evaluated with the negative-pressure test and contains the largest number of unintentional esophageal intubations. Previous series of emergency intubations that reported 100% sensitivity in detecting esophageal intubation using the negative-pressure test are of limited value in determining the utility of the test because only one [19] and two [20] esophageal intubations occurred during the study periods. The power of our study and others that have evaluated the negative-pressure test in the emergency setting remains limited by the infrequency of esophageal intubation [19–21]; based on our correct identification of all 19 esophageal intubations, the 95% confidence limits for the sensitivity of the SIB in detecting esophageal intubation are 84–100%. A considerably larger trial is required to determine a more precise mathematical sensitivity.
The SIB had a high specificity (99%) when the intratracheal position of the tube was present but gave misleading results (i.e., did not inflate) in three patients: one each with chronic obstructive pulmonary disease, copious secretions, and obesity. These circumstances were all reported previously to cause false-positive results using this technique. [21–23] As noted before, the carbon dioxide detection devices gave misleading results (no carbon dioxide detected) in two patients undergoing cardiopulmonary resuscitation, a finding that has also been widely reported. [19,24] The complementary nature of the negative-pressure test and carbon dioxide detection is illustrated by the observation that in all instances in which one technique was misleading, the alternative technique correctly identified the intratracheal position of the ETT.
We developed a rigid protocol for this study that precluded randomization of the SIB with carbon dioxide detection. As has been suggested before, we believe that the negative-pressure test should be performed before initiation of manual ventilation to avoid inadvertent introduction of gas into the esophagus and stomach, which may in turn lead to bulb reinflation and a false-negative test. Although Salem et al. [25] suggested that the delivery of three small breaths through a tube placed in the esophagus did not affect the reliability of the SIB, a case of unrecognized esophageal intubation associated with a contradictory negative-pressure test performed after vigorous attempts at ventilation at our institution suggested that esophageal and gastric insufflation might lead to false-negative results with the SIB. We also compressed the SIB before connecting it to the ETT to avoid introduction of air into the esophagus, as described by Salem et al. [25] Although compression of the bulb after connection to the ETT increases the specificity of the test in morbidly obese persons, this benefit occurs at a potential cost of decreased sensitivity. [22] We performed the negative-pressure test with the ETT cuff deflated to allow entrainment of air from the upper airway passages when the tube is in the trachea [26] and to prevent stenting of the tip of the ETT away from the wall of the esophagus with a possible false-negative result in the opposite situation. A previous report suggests that cuff deflation does not affect the sensitivity or specificity of the SIB. [27] It is important to recognize that esophageal disease may affect the sensitivity of the SIB, although there are no reports in the literature that directly address this issue. We did not survey for the presence of esophageal disease in our patients.
We allowed 10-s for bulb reinflation to occur and counted all reinflations within that time period as negative test results. We believe that this step is important to reduce false-positive results (absent or delayed reinflation of the SIB despite intratracheal position of the tube). In contrast to the findings of Czinn et al., [21] who used a 4-s reinflation period and reported a test specificity of 86%, we found the SIB to be 99% specific. In most of our cases, the SIB reinflated immediately, and no adverse consequences were reported in those instances of delayed reinflation.
In concurrence with the opinion of Salem et al., [25] we elected to use the SIB rather than the syringe aspiration technique described by Wee [12] because of the former device's simplicity and decreased interuser variability. A difference in efficacy between different negative-pressure tests has not been shown, however.
Portability, availability, ease of use, and cost are important considerations for acceptance of devices designed to detect esophageal intubation in the emergency setting. The SIB is portable and takes little space to store, is simple to use, has an unlimited shelf life, and can be used in areas of low light. The SIB also is relatively inexpensive, with the commercial device priced approximately $10.00 less than the colorimetric carbon dioxide detector.
In conclusion, we found that the negative-pressure test using a SIB is a sensitive and specific test to detect esophageal intubation in the emergency setting. This technique is not infallible but, importantly, its few failures are usually false-positive results, or incorrect indications that the endotracheal tube is in the esophagus when it is actually in the trachea. In addition, the SIB is complementary to carbon dioxide detection, and specific instances when a particular device might fail (and where the alternative device might be of use) can be predicted. As previously shown, obesity, chronic obstructive pulmonary disease, and copious pulmonary secretions can affect the SIB's performance, [21–23] while cardiopulmonary resuscitation and the presence of carbonated beverages or antacids in the stomach [28] also may affect the reliability of exhaled carbon dioxide monitoring. At our institution, the SIB is used in combination with clinical examination to detect esophageal intubation in the emergency setting. Carbon dioxide detection with a colorimetric device is used as a backup when the SIB results do not correspond with those of clinical examination.
The authors thank Susan Bratton, M.D., for advice on statistical testing.
Andersen KH, Hald A: Assessing the position of the tracheal tube. The reliability of different methods. Anaesthesia 1989; 44:984-5.
Clyburn P, Rosen M: Accidental oesophageal intubation. Br J Anaesth 1994; 73:55-63.
Linko K, Paloheimo M, Tammisto T: Capnography for detection of accidental oesophageal intubation. Acta Anaesthesiol Scand 1983; 27:199-202.
Bashein G, Cheney FW: Carbon dioxide detection to verify intratracheal placement of a breathing tube. Anesthesiology 1984; 61:782-3.
Murray IP, Modell JH: Early detection of endotracheal accidents by monitoring carbon dioxide concentrations in respiratory gas. Anesthesiology 1983; 59:344-6.
The American Society of Anesthesiology Standards for Basic Anesthetic Monitoring: Directory of Members 1997. Parkridge, IL, American Society of Anesthesiology, 1997, p 394.
Schwartz DE, Matthay MA, Cohen NH: Death and other complications of emergency airway management in critically ill adults. Anesthesiology 1995; 82:367-76.
Denman WT, Hayes M, Higgens D, Wilkinson DJ: The Fenem CO sub 2 detector device. Anaesthesia 1990; 45:465-7.
Goldberg JS, Rawle PR, Zehnder JL, Sladen RN: Colorimetric end tidal carbon dioxide monitoring for tracheal intubation. Anesth Analg 1990; 70:191-4.
Williams KN, Nunn JF: The oesophagel detector device. Anesthesia 1989; 44:412-4.
Zaleski L, Abello D, Gold M: The esophageal detector device: Does it work? Anesthesiology 1993; 79:244-7.
Wee MYK: The oesophageal detector device: Assessment of a new method to distinguish oesophageal from tracheal intubation. Anaesthesia 1988; 43:27-9.
Hanley JA, Lippman-Hand A: If nothing goes wrong, is everything all right? Interpreting zero numerators. JAMA 1983; 249:1743-5.
Bernard GR, Artigas A, Brigham KL, Carlet J, Falke K, Hudson L, Lamy M, LeGall JR, Morris A, Spragg R, The Consensus Committee: Report of the American-European consensus conference on ARDS: Definitions, mechanisms, relevant outcomes, and clinical trial coordination. Intensive Care Med 1994; 20:225-32.
Conley JM, Smith DJ: Emergency endotracheal intubation by respiratory care personnel in a community hospital. Respir Care 1981; 26:336-8.
Stauffer JL, Olson DE, Petty, TL: Complications and consequences of endotracheal intubation and tracheotomy: A prospective study of 150 critically ill adult patients. Am J Med 1981; 70:65-76.
Holland R, Webb RK, Runciman WB: Oesophageal intubation: an analysis of 2000 incident reports. Anaesth Intensive Care 1993; 21:608-10.
Birmingham PK, Cheney FW, Ward RJ: Esophageal intubation: A review of detection techniques. Anesth Analg 1986; 65:886-91.
Bozeman WP, Hexter D, Liang HK, Kelan GD: Esophageal detector device versus detection of end-tidal carbon dioxide level in emergency intubation. Ann Emerg Med 1996; 27:595-9.
Jenkins WA, Verdile VP, Paris PM: The syringe aspiration technique to verify endotracheal tube position. Am J Emerg Med 1994; 12:413-6.
Czinn EA, Wafai Y, Salem MR, Podraza A, Lang D: Efficacy of the self-inflating bulb for confirmation of emergency tracheal intubation in critically ill patients. Anesthesiology 1995; 83:A266.
Lang DJ, Wafai Y, Salem MR, Czinn EA, Halim AA, Barkara A: Use of the self-inflating bulb in confirming tracheal intubation in the morbidity obese. Anesthesiology 1996; 85:246-53.
Baraka A: The oesophageal detector device. Anaesthesia 1991; 46:697.
Higgins D, Hayes M, Denman W, Wilkinson DJ: Effectiveness of using end tidal carbon dioxide concentration to monitor cardiopulmonary resuscitation. BMJ 1990; 300:581.
Salem MR, Wafai Y, Baraka A, Taimorrazy B, Joseph NJ, Nimmagadda U: Use of the self-inflating bulb for detection of esophageal intubation after “esophageal ventilation.” Anesth Analg 1993; 77:1227-31.
O'Leary JJ, Pollard BJ, Ryan MJ: A method of detecting oesophageal intubation or confirming tracheal intubation. Anaesth Intensive Care 1988; 16:299-301.
Salem MR, Wafai Y, Joseph NJ, Baraka A, Czinn EA: Efficacy of the self-inflating bulb in detecting esophageal intubation: Does the presence of a nasogastric tube or cuff deflation make a difference? Anesthesiology 1994; 80:42-8.
Ping ST, Mehta MP, Symreng T: Reliability of capnography in identifying esophageal intubation with carbonated beverage or antacid in the stomach. Anesth Analg 1991; 73:333-7.
Table 1. Summary Demographic Data 
Image not available
Table 1. Summary Demographic Data 
Table 2. Predictive Value of the Self-inflating Bulb in Detection of Esophageal Intubation 
Image not available
Table 2. Predictive Value of the Self-inflating Bulb in Detection of Esophageal Intubation