Success rates of pre-hospital difficult airway management: a quality control study evaluating an in-hospital training program
© The Author(s). 2018
Received: 18 October 2017
Accepted: 6 March 2018
Published: 16 March 2018
Competence in emergency airway management is key in order to improve patient safety and outcome. The scope of compulsory training for emergency physicians or paramedics is quite limited, especially in Austria. The purpose of this study was to review the difficult airway management performance of an emergency medical service (EMS) in a region that has implemented a more thorough training program than current regulations require, comprising 3 months of initial training and supervised emergency practice and 3 days/month of on-going in-hospital training as previously reported.
This is a subgroup analysis of pre-hospital airway interventions performed by non-anesthesiologist EMS physicians between 2006 and 2016. The dataset is part of a retrospective quality control study performed in the ground EMS system of Wiener Neustadt, Austria. Difficult airway missions recorded in the electronic database were matched with the hospital information system and analyzed.
Nine hundred thirty-three of 23060 ground EMS patients (4%) required an airway intervention. In 48 cases, transient bag-mask-valve ventilation was sufficient, and 5 patients needed repositioning of a pre-existing tracheostomy cannula. Eight hundred thirty-six of 877 patients (95.3%) were successfully intubated within two attempts; in 3 patients, a supraglottic airway device was employed first line. Management of 41 patients with failed tracheal intubation comprised laryngeal tubes (n = 21), intubating laryngeal mask (n = 11), ongoing bag-mask-valve ventilation (n = 8), and crico-thyrotomy (n = 1). There was no cannot intubate/cannot ventilate situation. Blood gas analysis at admission revealed hypoxemia in 2 and/or hypercapnia in 11 cases.
During the 11-year study period, difficult airways were encountered in 5% but sufficiently managed in all patients. Thus, the training regime presented might be a feasible and beneficial model for training of non-anesthesiologist emergency physicians as well as paramedics.
In pre-hospital emergency care, airway management is a time-critical intervention of utmost importance. Recent findings underline the competence of the rescuer as key factor in patient outcome, so that formal and on-going training of emergency medical service (EMS) personnel is crucial [1–4]. Compared to the in-hospital setting, the pre-hospital environment is much more challenging, with an up to tenfold higher prevalence of difficult airways [5–7]. For these reasons, training of emergency personnel should have a strong focus on airway management and emergency anesthesia. In contrast to Germany and Switzerland, where the statutory requirements for training of emergency physicians include at least 24 months of postgraduate training, of which 6–12 months are spent in anesthesia and/or intensive care medicine and on-the-job training with mobile emergency services [8, 9], the Austrian curriculum for training of emergency physicians does not include any mandatory clinical practice at all . After doctors have achieved their license to practice as a general practitioner or as specialists of any discipline, they only need to take a 60-h course to qualify as emergency physicians. Under these conditions, it is not surprising that dangerous incidents occur with some regularity in the treatment of emergency patients. Current law in Austria does not require the integration of basic anesthesia training into the education of EMS physicians, although it is undisputed that emergency anesthesia can only be taught properly in clinical practice. In a qualitative control study, we recently demonstrated that non-anesthesiologist EMS physicians are able to achieve a 95% tracheal intubation (TI) success rate when they have had in-hospital training for at least 3 months . Although no fatalities or major complications were observed in the aforementioned analysis, the quality of difficult airway management provided merits further evaluation.
Thus, the purpose of this subgroup and extended data analysis was to review the difficult airway management performance of non-anesthesiologist EMS physicians who underwent a structured airway management training and supervised emergency practice for 3 months, and had on-going training in an anesthesiology department for 3 days per month.
To assess the effectiveness of this strategy in everyday pre-hospital practice, we reassessed the data presented in a previous paper  and performed this subgroup analysis of pre-hospital difficult airway situations in all emergency physician missions from 1 January 2006 to 31 December 2016, with the approval of the ethics committee for Lower Austria (GS1-EK-4/448-2016V). It is noteworthy that our institutional difficult airway algorithm was established in 2005 and matches with current recommendations such as the European Resuscitation Guidelines. The analysis used data from the electronic EMS recording system “NACA-X™” (EDV Trimmel, 2630 Ternitz) and the hospital information system (HIS; CGM-CompuGroupMedical Austria, 4400 Steyr). Data were processed using “MS Excel™” (Microsoft 98000, Redmond, WA 98052-6399 USA).
Respiratory depression due to analgosedation
TI abandonment (do-not-escalate decision)
Bridging to NIV
Temporary respiratory insufficiency due to seizures
Conscious after ROSC
Forty-four patients (5%) presented with difficult airway: in three cases (0.3%), the airway was secured primarily by means of a supraglottic airway (SGA). In 41 patients (4.7%), attempts to set up TI failed: in 58.9% of these, it was not possible to expose the glottis opening (Cormack and Lehane grade 3 or 4); in 39% of the patients, the view in the airway was too heavily obstructed by vomit or blood. In some cases, the reason for failed TI was given as conditions after operations on the airway (7.3%) or inadequate mouth opening (4.8%). Two patients had to be treated in an extremely restricted space at the scene of the emergency, and in one patient, venous access failed. After failed TI, 22 patients (53.7%) were intubated with a laryngeal tube (LT) in accordance with the institutional DA algorithm (for difficult BMV), and 95.5% of these were successfully ventilated by this method; one patient was switched to intubating laryngeal mask airway (I-LMA). Eleven patients with unproblematic BMV were given an I-LMA after two failed TI attempts. 41.5% of the patients with difficult airway required induction of anesthesia, and 58.5% were under CPR. This was not statistically different to the total sample (p = 0.431, data shown above).
Four of the 11 patients ventilated by I-LMA were successfully intubated through the device; seven were brought to hospital with continued ventilation via I-LMA after one intubation attempt. One patient had to be given a crico-thyrotomy because of insufficient SGA ventilation. Eight patients were hospitalized following unsuccessful TI attempts using BMV without any further measures; all but one of these had short distance transport to hospital. In summary, the rate of incidence of difficult airway was 4.6%.
Blood gas analysis at hospital admission
In a sample of 47 cardiac arrest patients who already had a laryngeal tube inserted by paramedics during CPR attempts before the emergency physician arrived at the scene, we observed an interesting incidental finding. In 30 patients attended between 2006 and 2013, the LT was left in place throughout CPR. Based on the change resuscitation guidelines, the LT was replaced with TI in 17 patients in the time span between 2014 and 2016. While only one (3.3%) of the LT patients achieved ROSC, five (29.4%) of the TI patients did. This finding is significant (p = 0.018), although absolute numbers are small.
On average, over the entire study period, the emergency physicians performed an airway intervention once every 4.3 days or once every 24.7 missions. For an individual emergency physician, this means 10 prehospital TI and 0.4 SGA per year; in the clinical training program, in contrast, they performed 33.5 TI and 19.0 SGA in the first 3 months and 64.0 TI and 33.5 SGA per year during on-going OR training .
In this retrospective subgroup analysis, we sought to assess whether a comprehensive in-hospital training program might enable non-anesthesiologist EMS physicians to manage even difficult airway patients. During the 11-year study period, no cannot intubate/cannot ventilate situation was recorded and no patient was harmed due to airway management complications. Sufficient oxygenation was achieved in 90% of the difficult airway patients managed with alternative devices, but hypercapnia was observed in 55% as revealed by admission blood gases (paO2 > 60 mmHg and paCO2 > 50 mmHg, respectively).
In our opinion, there is a dilemma in emergency medicine: the influence of TI on the outcome of emergency patients may reflect the different qualification levels of EMS personnel, and the main reason for difficulties is lack of practice. Pre-hospital TI is an extremely rare experience for an individual emergency physician or paramedic. In an analysis of over 82,000 emergency physician missions, Gries et al. found an intubation frequency of 1 per 0.5–1.5 emergency physician months [13, 14]; in our EMS system, the frequency of invasive airway interventions was similarly low (4% of all missions). Therefore, a sufficient level of skill can neither be acquired nor maintained in EMS alone. To achieve a 90% success rate of TI with direct laryngoscopy requires the experience of performing 50–150 procedures [15, 16]. Besides learning the manual skills, constant training and feedback from experienced practitioners is needed [17, 18]. By our training program, emergency physicians were enabled to perform approximately 75 TIs per year and receive feedback and supervision in the operation room .
Airway assessment by modified “LEON” method 
Airway assessment: modified “LEON” method
Abnormal facial shape (craniofacial deformities)
Teeth - protruding - large incisors - false teeth?
Incisor distance > 3 fingers
Hyoid/mentum distance (mandible length) > 3 fingers
Thyroid to floor of mouth > 2 fingers
Obstructed airway (tissue swelling, foreign body, obesity)
Neck mobility (if feasible)
Algorithm-based procedures can improve success rates of interventions and patient outcome . Our results confirm for the EMS setting what Berkow et al.  demonstrated for clinical anesthesia: structured clinical training and algorithm-based treatment of patients improve patient safety. Of 41 patients whom non-anesthesiologist emergency physicians were unable to intubate, 32 were ventilated successfully using a supraglottic device and 8 via BMV, and crico-thyrotomy was needed in a single case only (0.12%). Furthermore, there were a number of cases where emergency physicians were reluctant to use TI or SGA in favor of less-invasive procedures (n = 48, Table 1). This can be interpreted as a rational and appropriate deployment of airway management methods, enabled by thorough training.
Incorrect positioning and wrong handling of an SGA device can also cause relevant complications. For the LT, several problems have been noted, such as impairment of cerebral perfusion due to excessive cuff pressure of up to 100 mmHg during CPR . Thus, we changed our standard operating procedure in 2014 in favor of immediate conversion of all LTs to TI. Interestingly, we noticed a return of spontaneous circulation rate in patients prior to 2014, with on-going LT ventilation of 3.3%, compared to 29.4% when the LT was replaced by TI. However, it is noteworthy that numbers are too small to draw any conclusion from this observation.
Finally, training in the OR covers more topics than just bag-mask ventilation and placement of laryngeal or tracheal tubes. Learning the correct rapid sequence induction technique, ventilation, and hemodynamic management of emergency patients is equally important . Unfortunately, Austrian law on training of emergency physicians , which dates from 1998, does not provide anything more detailed than an outline curriculum of some theoretical topics to be taught. As a consequence, rescuer qualifications as well as institutional approaches are likely to vary significantly between EMS systems in Austria.
Some limitations of our retrospective quality control study must be noted. First, this is a retrospective study and we are unable to provide detailed information about time intervals, SpO2, and first etCO2 levels during and after difficult airway management. Second, we are unable to provide detailed information whether the quality of airway management had an impact on outcome. The goal of our study was to assess whether life-threatening pre-hospital difficult airway situations can be successfully managed even by non-anesthesiologists with proper training. Thus, we can only discuss the feasibility and efficacy of our educational approach for EMS physicians. Accordingly, our study lacks a potential control group.
Our data indicate that a training period of 3 months, followed by regular training in the OR, is sufficient to impart an adequate level of competence in emergency difficult airway management. Strict adherence to an institutional algorithm enabled catastrophic “cannot intubate/cannot ventilate” situations to be avoided. Thus, we believe compulsory clinical training should be included in legal requirements for both emergency physicians and paramedics.
National Advisory Committee of Aeronautics
HT concepted, initiated and designed the study, analysed and interpreted data, and drafted the manuscript. CB and SH collected the data and revised the manuscript. JK contributed to data interpretation and helped to draft and revise the manuscript. WGV participated in concept and design of the study, data interpretation and drafting of the manuscript and critically revised the manuscript. All authors read and approved the final manuscript.
All authors declare that they have no competing interests.
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