Comparison of three methods for teaching mechanical ventilation in an emergency setting to sixth-year medical students: a randomized trial

Tallo, Fernando Sabia; Vendrame, Letícia Sandre; Baitello, André Luciano

doi:10.1590/1806-9282.66.10.1409

SUMMARY

OBJECTIVE:

To determine if there are significant differences between the tutorial, simulation, or clinical-case-based discussion teaching methods regarding the transmission of medical knowledge on mechanical ventilation.

METHODS:

A randomized, multicenter, open-label controlled trial was carried out using 3 teaching methods on mechanical ventilation: clinical-case-based discussion, simulation, and online tutorial. Voluntary students of the sixth year of medical school from 11 medical colleges answered a validated questionnaire on knowledge about mechanical ventilation for medical students before, immediately after, and 6 months after in-person training consisting of 20 multiple-choice questions, and 5 questions about the participants' demographic profile.

RESULTS:

Immediately after the test there was no difference between the scores in the simulation and clinical case groups,[15,06 vs 14,63] whereas, after some time, there was a significant difference in retention between the case-based and simulation groups, with the score in the simulation group 1.46 [1.31; 1.64] times higher than the score of the case group (p-value < 0.001). In the multivariate analysis, an individual who had received more than 4 hours of information showed an increase of 20.0% [09.0%; 33.0%] in the score (p-value = 0.001).

CONCLUSIONS:

Our results indicate that, in comparison with other forms of training, simulation in mechanical ventilation provides long-lasting knowledge in the medium term. Further studies are needed to improve the designing and evaluation of training that provides minimal mechanical ventilation skills.

KEYWORDS:
Respiration; Artificial; Emergencies; Students; Medical; Teaching

RESUMO

OBJETIVO:

Determinar se existem diferenças significativas entre os métodos de ensino tutorial, simulação ou discussão de casos clínicos relativos à transmissão de conhecimentos médicos sobre ventilação mecânica.

MÉTODOS:

Um ensaio clínico randomizado, multicêntrico, aberto e controlado foi realizado usando três métodos de ensino em ventilação mecânica: discussão baseada em casos clínicos, simulação e tutorial on-line. Alunos voluntários do sexto ano de medicina de 11 faculdades responderam a um questionário validado abordando o conhecimento sobre ventilação mecânica para estudantes de medicina antes, imediatamente após e seis meses depois do treinamento presencial, composto por 20 questões de múltipla escolha e cinco questões sobre perfil demográfico dos participantes.

RESULTADOS:

Imediatamente após o teste, não houve diferença entre as pontuações nos grupos de simulação e caso clínico [15,06 vs 14,63], ao passo que, após algum tempo, houve uma diferença significativa na retenção entre o baseado em caso e a simulação grupos, com a pontuação no grupo simulação 1,46 [1,31; 1,64] vez maior que a pontuação do grupo caso (p-valor <0,001). Na análise multivariada, um indivíduo que recebeu mais de quatro horas de informação apresentou aumento de 20,0% [09,0%; 33,0%] no escore (p-valor=0,001).

CONCLUSÕES:

Nossos resultados indicam que, em comparação com outras formas de treinamento, a simulação em ventilação mecânica proporciona um conhecimento duradouro a médio prazo. Mais estudos são necessários para melhorar o desenho e a avaliação do treinamento que forneça habilidades mínimas de ventilação mecânica.

PALAVRAS-CHAVE:
Respiração Artificial; Emergências; Estudantes de Medicina; Ensino

INTRODUCTION

The increased number of patients on mechanical ventilation, most of whom are not in an ICU, requires, from general practitioners, special skills on the subject¹1. Zisk-Rony RY, Weissman C, Weiss YG. Mechanical ventilation patterns and trends over 20 years in an Israeli hospital system: policy ramifications. Isr J Health Policy Res. 2019;8(1):20.^,²2. Iwashita Y, Yamashita K, Ikai H, Sanui M, Imai H, Imanaka Y. Epidemiology of mechanically ventilated patients treated in ICU and non-ICU settings in Japan: a retrospective database study. Crit Care. 2018;22(1):329.. Moreover, the increase in costs and mortality is related to the increase in the time of mechanical ventilation and its complications³3. Dettmer MR, Damuth E, Zarbiv S, Mitchell JA, Bartock JL, Trzeciak S. Prognostic factors for long-term mortality in critically ill patients treated with prolonged mechanical ventilation: a systematic review. Crit Care Med. 2017;45(1):69-74.. However, despite evidence showing that evidence-based practices can decrease these, such practices have low compliance and are underused in clinical practice⁴4. Santacruz CA, Pereira AJ, Celis E, Vincent J-L. Which multicenter randomized controlled trials in critical care medicine have shown reduced mortality? A systematic review. Crit Care Med. 2019;47(12):1680-91.^–⁷7. Spece LJ, Mitchell KH, Caldwell ES, Gundel SJ, Jolley SE, Hough CL. Low tidal volume ventilation use remains low in patients with acute respiratory distress syndrome at a single center. J Crit Care. 2018;44:72-6..

There is a large number of non-specialist physicians working in emergency and pre-hospital services attending patients who need to be intubated and kept on mechanical ventilation⁸8. Tallo FS, Abib SCV, Baitello AL, Lopes RD. An evaluation of the professional, social and demographic profile and quality of life of physicians working at the Prehospital Emergency Medical System (SAMU) in Brasil. Clinics (Sao Paulo). 2014;69(9):601-7.. However, the teaching of these skills is very deficient⁹9. Tallo FS, Abib SCV, Negri AJA, Cesar Filho P, Lopes RD, Lopes AC. Evaluation of self-perception of mechanical ventilation knowledge among Brazilian final-year medical students, residents and emergency physicians. Clinics (Sao Paulo). 2017;72(2):65-70.^,¹⁰10. Sweigart JR, Aymond D, Burger A, Kelly A, Marzano N, McIlraith T, et al. Characterizing hospitalist practice and perceptions of critical care delivery. J Hosp Med. 2018;13(1):6-12.. There are few studies about teaching and assessment methods of these skills among resident physicians, and there are no studies in the literature for undergraduate medical students.

Our study compares simulation methods, case-based discussions, and online remote education methods on artificial ventilation, and uses a validated tool for assessing knowledge on mechanical ventilation among students in the last semester of medical graduation¹¹11. Kim S, Phillips WR, Pinsky L, Brock D, Phillips K, Keary J. A conceptual framework for developing teaching cases: a review and synthesis of the literature across disciplines. Med Education. 2006;40(9):867-76.. The objective is to determine if there are, among the teaching methods, significant differences regarding the transmission of medical knowledge on mechanical ventilation.

METHODS

A randomized, multicenter, open-label controlled trial was carried out using 3 teaching methods on mechanical ventilation: clinical case-based discussion, simulation, online tutorial. A simple randomization using an electronic method was applied for each group of 10 students for each teaching method, and one group remained as the control. All participants answered a validated questionnaire on knowledge about mechanical ventilation for medical students before, immediately after training, and 6 months after it¹²12. Tallo FS, Abib SCV, Baitello AL, Lopes RD. Development and validation of a questionnaire to assess the knowledge of mechanical ventilation in urgent care among students in their last-year medical course in Brasil. Clinics (Sao Paulo). 2019;74:e663., consisting of 20 multiple-choice questions, and 5 questions about the participants' demographic profile. Figure I

FIGURE 1.
COMPARISON BETWEEN GROUPS OVER TIME

The participants were voluntary students of the sixth year of medical school from 11 medical colleges, out of 53 invited, who accepted the researcher's invitation. All of them were in the second semester of the course and had already participated in training sessions on adult intensive care, emergency room, and anesthesiology. The training sessions were offered at the headquarters of the participating universities by the same researcher in all groups.

All training was based on the basic objectives of knowledge on mechanical ventilation, divided into 55 items developed by Goligher et al.¹³13. Goligher EC, Ferguson ND, Kenny LP. Core competency in mechanical ventilation: development of educational objectives using the Delphi technique. Crit Care Med. 2012;40(10):2828-32.. Four clinical cases were used for the simulation, case-based discussion, and online tutorial scenarios. The “control” groups attended an 8-hour course that was not related to mechanical ventilation and answered the questionnaire as well.

A training session based on 4 clinical cases with a structured sequence of questions was created for each case. The schedule was divided into two methods: in the simulation, students handled the artificial ventilator and observed the effects of its changes with the simulator. In the discussion-based format, the same sequence was followed, but there was no “hands-on” practice, only the demonstration by the instructor; both methods were recorded and saved on DVDs to be presented to a random group as an online Tutorial.

Using the simulation taxonomy, Chiniara et al.¹⁴14. Chiniara G, Cole G, Brisbin K, Huffman D, Cragg B, Lamacchia M, et al. Simulation in healthcare: a taxonomy and a conceptual framework for instructional design and media selection. Med Teach. 2013;35(8):e1380-95. used a high-fidelity scenario, emergency room, respiratory system simulator, and instructor-based debriefing; the instructor evaluated the response of each handling action of the group of students and made comments simultaneously. (Annex 1) The case-based discussion¹¹11. Kim S, Phillips WR, Pinsky L, Brock D, Phillips K, Keary J. A conceptual framework for developing teaching cases: a review and synthesis of the literature across disciplines. Med Education. 2006;40(9):867-76. was based on fundamental principles of structured discussion, realism, relevance, need to trigger the learner's involvement, challenging problem, and instructional methods such as equipment, simulators, and theatricalization of scenarios. The same sequence of structured questions was used for each scenario, but students had no direct contact with the ventilator, everything was demonstrated by the instructor. The online modality recorded the case-based modality, suppressing the interaction of the students and the instructor, and providing DVDs to the participants. The artificial ventilator iX5 was used in all training groups, the technical name of which is pressure and volume ventilator (registered with the Brazilian Health Regulatory Agency – Anvisa under no. 10243240052; manufacturer: Intermed Equipamento Médico Hospitalar Ltda). The simulator used was the PneuView^® 3 Advanced Simulation Software (Michigan Instruments, Grand Rapids, Michigan, USA).

A Quasipoisson Regression (Wedderburn, 1974; McCullagh and Nelder, 1989) was used to compare the score between groups over time, with an interaction between the variables group and time, with the necessary contrasts being calculated. The software used in the analyses was R (version 3.4.1).

RESULTS

Most students reported not having attended a mechanical ventilation course as part of their undergraduate program (294, 89.1%); most of them never participated effectively in the approach to mechanical ventilation in a patient (282, 75.2%); and reported that the participation of the physical therapist prevailed in the approach to mechanical ventilation in emergency settings (213, 70.5%). The Case and Simulation groups had the highest scores for overtime retention (Table 1).

Thumbnail

TABLE 1
DESCRIPTIVE ANALYSIS OF THE SCORE BY TIME AND GROUP

I mmediately after the training (POST-TEST), there was no difference between the scores in the simulation and clinical case groups, whereas over time (RETENTION) there was a significant difference between the case-based and simulation groups, with the score in the simulation group 1.46 [1.31; 1.64] times higher than the score of the case group (p-value < 0.001).

In the multivariate analysis (Table 2) when individuals who had not had classes of mechanical ventilation as part of their undergraduate program are compared to those who had, the latter shows an increase of 27.0% [17.0%; 39.0%] in the score (p-value = 0.001); and when compared to individuals who had 0 to 1 hour of training, individuals who had more than 4 hours of training show an increase of 20.0% [09.0%; 33.0%] in the score (p-value = 0.001).

Thumbnail

TABLE 2
MULTIVARIATE ANALYSIS OF MECHANICAL VENTILATION CLASSES AND INFORMATION TIME

DISCUSSION

Our study was the first multicenter study that evaluated the influence of different teaching methods on the knowledge about mechanical ventilation among medical students with a validated instrument. A teaching program standardized in simulation and case-based discussion achieved significant results in the acquisition and retention of knowledge in the short- and medium-term. Few studies have evaluated the teaching of mechanical ventilation; among them, most did not use validated assessment instruments¹⁵15. Goldsworthy S. Mechanical ventilation education and transition of critical care nurses into practice. Crit Care Nurs Clin North Am. 2016;28(4):399-412.^,¹⁶16. Yee J, Fuenning C, George R, Hejal R, Haines N, Dunn D, et al. Mechanical ventilation boot camp: a simulation-based pilot study. Crit Care Res Pract. 2016;2016:4670672., and among those using them, none approached medical students¹⁷17. Wilcox SR, Strout TD, Schneider JI, Mitchell PM, Smith J, Lutfy-Clayton L, et al. Academic Emergency Medicine Physicians' knowledge of mechanical ventilation. West J Emerg Med. 2016;17(3):271-9.^,¹⁸18. Richards JB, Strout TD, Seigel TA, Wilcox SR. Psychometric properties of a novel knowledge assessment tool of mechanical ventilation for emergency medicine residents in the northeastern United States. J Educ Eval Health Prof. 2016;13:10..

The common concept that simulation methods are associated with better results for medical students' knowledge and skill acquisition is controversial. Our study showed no significant difference in specific knowledge in terms of the method of discussion of clinical cases. Few studies have shown similar results¹⁹19. Morgan PJ, Cleave-Hogg D. Comparison between medical students' experience, confidence and competence. Med Educ. 2002;36(6):534-9.^,²⁰20. Couto TB, Farhat SCL, Geis GL, Olsen O, Schvartsman C. High-fidelity simulation versus case-based discussion for teaching medical students in Brasil about pediatric emergencies. Clinics (Sao Paulo). 2015;70(6):393-9.. In addition, the level of fidelity, in general, correlates with the success in the acquisition of knowledge; the more sophisticated the mannequin, the better the learning result. A recent study did not show this association, and the use of high-fidelity simulation led to a performance equal to or worse of knowledge improvement if compared to low-fidelity simulation, besides inducing undesirable effects, such as overconfidence²¹21. Massoth C, Röder H, Ohlenburg H, Hessler M, Zarbock A, Pöpping DM, et al. High-fidelity is not superior to low-fidelity simulation but leads to overconfidence in medical students. BMC Med Educ. 2019;19:29..

Some studies have demonstrated the utility of using simulation in mechanical ventilation training. A study compared simulation training of mechanical ventilation for first-year residents to what the authors called “traditional bedside training” for third-year residents. Similar to our study, the simulation group (n = 40) scored significantly higher in the assessment of clinical skills than the traditional group (n = 27) (91.3% [95% CI 88.2% to 94.3 %] versus 80.9% [95% CI 76.8% to 85.0%], P = <0.001)²²22. Singer BD, Corbridge TC, Schroedl CJ, Wilcox JE, Cohen ER, McGaghie WC, et al. First-year residents outperform third-year residents after simulation-based education in critical care medicine. Simul Healthc. 2013;8(2):67-71.. Important limitations to the study are influences on the variation of patients at the bedside in the evaluation, and the lack of formal validation of the instrument, as well as the single center. Another study using a simulation of mechanical ventilation showed an improvement in knowledge and skills with an average of 40 to 67%, respectively. However, there are limitations to the study because of the use of an assessment instrument that has not been validated²³23. Yee J, Benner A, Hammond J, Malone B, Fuenning C, George R, et al. Mechanical ventilation boot camp curriculum. J Vis Exp. 2018;(133):57303.. A randomized trial evaluated the mannequin-based simulation versus computer-based simulation. The mannequin-based group had a higher overall score and key action scores than the computer-based group (3.0 versus 2.0, and 82% versus 71%, respectively). The study was carried out in a single center with a non-validated instrument²⁴24. Spadaro S, Karbing DS, Fogagnolo A, Ragazzi R, Mojoli F, Astolfi L, et al. Simulation training for residents focused on mechanical ventilation a randomized trial using mannequin-based versus computer-based simulation. Simul Healthc. 2017;12(6):349-55.. Only one study approached a tutorial form of teaching about ventilation, similarly to ours, and compared it to a method that added simulation training. Using a non-validated instrument and a small, non-randomized number of participants, the “hands-on” method achieved a higher assessment score than the tutorial alone (25% vs. 10%, p = 0.07)²⁵25. Ramar K, Moraes AG, Selim B, Holets S, Oeckler R. Effectiveness of hands-on tutoring and guided self-directed learning versus self-directed learning alone to educate critical care fellows on mechanical ventilation: a pilot project. Med Educ Online. 2016;21:10.3402/meo.v21.32727.
https://doi.org/10.3402/meo.v21.32727... . Our results using an online tutorial showed no difference in the acquisition of knowledge in relation to the control group.

CONCLUSIONS

Our results indicate that, in comparison with other forms of training, simulation of mechanical ventilation provides long-lasting knowledge in the medium term. Further studies are needed to improve the design and evaluation of training to provide minimal mechanical ventilation skills.

REFERENCES

¹
Zisk-Rony RY, Weissman C, Weiss YG. Mechanical ventilation patterns and trends over 20 years in an Israeli hospital system: policy ramifications. Isr J Health Policy Res. 2019;8(1):20.
²
Iwashita Y, Yamashita K, Ikai H, Sanui M, Imai H, Imanaka Y. Epidemiology of mechanically ventilated patients treated in ICU and non-ICU settings in Japan: a retrospective database study. Crit Care. 2018;22(1):329.
³
Dettmer MR, Damuth E, Zarbiv S, Mitchell JA, Bartock JL, Trzeciak S. Prognostic factors for long-term mortality in critically ill patients treated with prolonged mechanical ventilation: a systematic review. Crit Care Med. 2017;45(1):69-74.
⁴
Santacruz CA, Pereira AJ, Celis E, Vincent J-L. Which multicenter randomized controlled trials in critical care medicine have shown reduced mortality? A systematic review. Crit Care Med. 2019;47(12):1680-91.
⁵
Bellani G, Laffey JG, Pham T, Fan E, Brochard L, Esteban A, et al. Epidemiology, patterns of care, and mortality for patients with acute respiratory distress syndrome in intensive care units in 50 countries. JAMA. 2016;315(8):788-800.
⁶
Poole J, McDowell C, Lall R, Perkins G, McAuley D, Gao F, et al. Individual patient data analysis of tidal volumes used in three large randomized control trials involving patients with acute respiratory distress syndrome. Br J Anaesth. 2017;118(4):570-5.
⁷
Spece LJ, Mitchell KH, Caldwell ES, Gundel SJ, Jolley SE, Hough CL. Low tidal volume ventilation use remains low in patients with acute respiratory distress syndrome at a single center. J Crit Care. 2018;44:72-6.
⁸
Tallo FS, Abib SCV, Baitello AL, Lopes RD. An evaluation of the professional, social and demographic profile and quality of life of physicians working at the Prehospital Emergency Medical System (SAMU) in Brasil. Clinics (Sao Paulo). 2014;69(9):601-7.
⁹
Tallo FS, Abib SCV, Negri AJA, Cesar Filho P, Lopes RD, Lopes AC. Evaluation of self-perception of mechanical ventilation knowledge among Brazilian final-year medical students, residents and emergency physicians. Clinics (Sao Paulo). 2017;72(2):65-70.
¹⁰
Sweigart JR, Aymond D, Burger A, Kelly A, Marzano N, McIlraith T, et al. Characterizing hospitalist practice and perceptions of critical care delivery. J Hosp Med. 2018;13(1):6-12.
¹¹
Kim S, Phillips WR, Pinsky L, Brock D, Phillips K, Keary J. A conceptual framework for developing teaching cases: a review and synthesis of the literature across disciplines. Med Education. 2006;40(9):867-76.
¹²
Tallo FS, Abib SCV, Baitello AL, Lopes RD. Development and validation of a questionnaire to assess the knowledge of mechanical ventilation in urgent care among students in their last-year medical course in Brasil. Clinics (Sao Paulo). 2019;74:e663.
¹³
Goligher EC, Ferguson ND, Kenny LP. Core competency in mechanical ventilation: development of educational objectives using the Delphi technique. Crit Care Med. 2012;40(10):2828-32.
¹⁴
Chiniara G, Cole G, Brisbin K, Huffman D, Cragg B, Lamacchia M, et al. Simulation in healthcare: a taxonomy and a conceptual framework for instructional design and media selection. Med Teach. 2013;35(8):e1380-95.
¹⁵
Goldsworthy S. Mechanical ventilation education and transition of critical care nurses into practice. Crit Care Nurs Clin North Am. 2016;28(4):399-412.
¹⁶
Yee J, Fuenning C, George R, Hejal R, Haines N, Dunn D, et al. Mechanical ventilation boot camp: a simulation-based pilot study. Crit Care Res Pract. 2016;2016:4670672.
¹⁷
Wilcox SR, Strout TD, Schneider JI, Mitchell PM, Smith J, Lutfy-Clayton L, et al. Academic Emergency Medicine Physicians' knowledge of mechanical ventilation. West J Emerg Med. 2016;17(3):271-9.
¹⁸
Richards JB, Strout TD, Seigel TA, Wilcox SR. Psychometric properties of a novel knowledge assessment tool of mechanical ventilation for emergency medicine residents in the northeastern United States. J Educ Eval Health Prof. 2016;13:10.
¹⁹
Morgan PJ, Cleave-Hogg D. Comparison between medical students' experience, confidence and competence. Med Educ. 2002;36(6):534-9.
²⁰
Couto TB, Farhat SCL, Geis GL, Olsen O, Schvartsman C. High-fidelity simulation versus case-based discussion for teaching medical students in Brasil about pediatric emergencies. Clinics (Sao Paulo). 2015;70(6):393-9.
²¹
Massoth C, Röder H, Ohlenburg H, Hessler M, Zarbock A, Pöpping DM, et al. High-fidelity is not superior to low-fidelity simulation but leads to overconfidence in medical students. BMC Med Educ. 2019;19:29.
²²
Singer BD, Corbridge TC, Schroedl CJ, Wilcox JE, Cohen ER, McGaghie WC, et al. First-year residents outperform third-year residents after simulation-based education in critical care medicine. Simul Healthc. 2013;8(2):67-71.
²³
Yee J, Benner A, Hammond J, Malone B, Fuenning C, George R, et al. Mechanical ventilation boot camp curriculum. J Vis Exp. 2018;(133):57303.
²⁴
Spadaro S, Karbing DS, Fogagnolo A, Ragazzi R, Mojoli F, Astolfi L, et al. Simulation training for residents focused on mechanical ventilation a randomized trial using mannequin-based versus computer-based simulation. Simul Healthc. 2017;12(6):349-55.
²⁵
Ramar K, Moraes AG, Selim B, Holets S, Oeckler R. Effectiveness of hands-on tutoring and guided self-directed learning versus self-directed learning alone to educate critical care fellows on mechanical ventilation: a pilot project. Med Educ Online. 2016;21:10.3402/meo.v21.32727.
» https://doi.org/10.3402/meo.v21.32727

Publication Dates

Publication in this collection
06 Nov 2020
Date of issue
Oct 2020

History

Received
27 Feb 2020
Accepted
23 May 2020

This is an Open Access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

[1] ¹
Zisk-Rony RY, Weissman C, Weiss YG. Mechanical ventilation patterns and trends over 20 years in an Israeli hospital system: policy ramifications. Isr J Health Policy Res. 2019;8(1):20.

[2] ²
Iwashita Y, Yamashita K, Ikai H, Sanui M, Imai H, Imanaka Y. Epidemiology of mechanically ventilated patients treated in ICU and non-ICU settings in Japan: a retrospective database study. Crit Care. 2018;22(1):329.

[3] ³
Dettmer MR, Damuth E, Zarbiv S, Mitchell JA, Bartock JL, Trzeciak S. Prognostic factors for long-term mortality in critically ill patients treated with prolonged mechanical ventilation: a systematic review. Crit Care Med. 2017;45(1):69-74.

[4] ⁴
Santacruz CA, Pereira AJ, Celis E, Vincent J-L. Which multicenter randomized controlled trials in critical care medicine have shown reduced mortality? A systematic review. Crit Care Med. 2019;47(12):1680-91.

[5] ⁵
Bellani G, Laffey JG, Pham T, Fan E, Brochard L, Esteban A, et al. Epidemiology, patterns of care, and mortality for patients with acute respiratory distress syndrome in intensive care units in 50 countries. JAMA. 2016;315(8):788-800.

[6] ⁶
Poole J, McDowell C, Lall R, Perkins G, McAuley D, Gao F, et al. Individual patient data analysis of tidal volumes used in three large randomized control trials involving patients with acute respiratory distress syndrome. Br J Anaesth. 2017;118(4):570-5.

[7] ⁷
Spece LJ, Mitchell KH, Caldwell ES, Gundel SJ, Jolley SE, Hough CL. Low tidal volume ventilation use remains low in patients with acute respiratory distress syndrome at a single center. J Crit Care. 2018;44:72-6.

[8] ⁸
Tallo FS, Abib SCV, Baitello AL, Lopes RD. An evaluation of the professional, social and demographic profile and quality of life of physicians working at the Prehospital Emergency Medical System (SAMU) in Brasil. Clinics (Sao Paulo). 2014;69(9):601-7.

[9] ⁹
Tallo FS, Abib SCV, Negri AJA, Cesar Filho P, Lopes RD, Lopes AC. Evaluation of self-perception of mechanical ventilation knowledge among Brazilian final-year medical students, residents and emergency physicians. Clinics (Sao Paulo). 2017;72(2):65-70.

[10] ¹⁰
Sweigart JR, Aymond D, Burger A, Kelly A, Marzano N, McIlraith T, et al. Characterizing hospitalist practice and perceptions of critical care delivery. J Hosp Med. 2018;13(1):6-12.

[11] ¹¹
Kim S, Phillips WR, Pinsky L, Brock D, Phillips K, Keary J. A conceptual framework for developing teaching cases: a review and synthesis of the literature across disciplines. Med Education. 2006;40(9):867-76.

[12] ¹²
Tallo FS, Abib SCV, Baitello AL, Lopes RD. Development and validation of a questionnaire to assess the knowledge of mechanical ventilation in urgent care among students in their last-year medical course in Brasil. Clinics (Sao Paulo). 2019;74:e663.

[13] ¹³
Goligher EC, Ferguson ND, Kenny LP. Core competency in mechanical ventilation: development of educational objectives using the Delphi technique. Crit Care Med. 2012;40(10):2828-32.

[14] ¹⁴
Chiniara G, Cole G, Brisbin K, Huffman D, Cragg B, Lamacchia M, et al. Simulation in healthcare: a taxonomy and a conceptual framework for instructional design and media selection. Med Teach. 2013;35(8):e1380-95.

[15] ¹⁵
Goldsworthy S. Mechanical ventilation education and transition of critical care nurses into practice. Crit Care Nurs Clin North Am. 2016;28(4):399-412.

[16] ¹⁶
Yee J, Fuenning C, George R, Hejal R, Haines N, Dunn D, et al. Mechanical ventilation boot camp: a simulation-based pilot study. Crit Care Res Pract. 2016;2016:4670672.

[17] ¹⁷
Wilcox SR, Strout TD, Schneider JI, Mitchell PM, Smith J, Lutfy-Clayton L, et al. Academic Emergency Medicine Physicians' knowledge of mechanical ventilation. West J Emerg Med. 2016;17(3):271-9.

[18] ¹⁸
Richards JB, Strout TD, Seigel TA, Wilcox SR. Psychometric properties of a novel knowledge assessment tool of mechanical ventilation for emergency medicine residents in the northeastern United States. J Educ Eval Health Prof. 2016;13:10.

[19] ¹⁹
Morgan PJ, Cleave-Hogg D. Comparison between medical students' experience, confidence and competence. Med Educ. 2002;36(6):534-9.

[20] ²⁰
Couto TB, Farhat SCL, Geis GL, Olsen O, Schvartsman C. High-fidelity simulation versus case-based discussion for teaching medical students in Brasil about pediatric emergencies. Clinics (Sao Paulo). 2015;70(6):393-9.

[21] ²¹
Massoth C, Röder H, Ohlenburg H, Hessler M, Zarbock A, Pöpping DM, et al. High-fidelity is not superior to low-fidelity simulation but leads to overconfidence in medical students. BMC Med Educ. 2019;19:29.

[22] ²²
Singer BD, Corbridge TC, Schroedl CJ, Wilcox JE, Cohen ER, McGaghie WC, et al. First-year residents outperform third-year residents after simulation-based education in critical care medicine. Simul Healthc. 2013;8(2):67-71.

[23] ²³
Yee J, Benner A, Hammond J, Malone B, Fuenning C, George R, et al. Mechanical ventilation boot camp curriculum. J Vis Exp. 2018;(133):57303.

[24] ²⁴
Spadaro S, Karbing DS, Fogagnolo A, Ragazzi R, Mojoli F, Astolfi L, et al. Simulation training for residents focused on mechanical ventilation a randomized trial using mannequin-based versus computer-based simulation. Simul Healthc. 2017;12(6):349-55.

[25] ²⁵
Ramar K, Moraes AG, Selim B, Holets S, Oeckler R. Effectiveness of hands-on tutoring and guided self-directed learning versus self-directed learning alone to educate critical care fellows on mechanical ventilation: a pilot project. Med Educ Online. 2016;21:10.3402/meo.v21.32727.
» https://doi.org/10.3402/meo.v21.32727

Group	Time	Average	SD	Min.	1^st Q	2^nd Q	3^rd Q	Max.
Control	Pre-test	3.73	3.38	0.00	1.00	3.00	6.00	14.00
	Post-test	3.71	3.06	0.00	1.00	3.00	5.00	14.00
	Retention	3.83	3.08	0.00	1.00	4.00	6.00	16.00
Case	Pre-test	3.30	3.28	0.00	0.50	2.50	5.00	16.00
	Post-test	14.63	2.29	8.00	13.00	15.00	16.00	20.00
	Retention	10.96	1.89	5.00	10.00	11.00	12.00	16.00
Simulation	Pre-test	3.40	3.00	0.00	1.00	3.00	6.00	13.00
	Post-test	15.06	2.39	6.00	15.00	15.00	16.00	20.00
	Retention	14.60	2.82	3.00	14.00	15.00	16.00	20.00
Online tutorial	Pre-test	4.38	3.73	0.00	2.00	4.00	7.00	15.00
	Post-test	5.38	4.47	0.00	2.00	4.00	7.00	20.00
	Retention	4.68	3.96	0.00	2.00	4.00	6.00	20.00

Variables		Initial model			Final model
Variables		Exp (β)	95% CI	P-value	Exp (β)	95% CI	P-value
Time = Pre	Group = Control	1.00	-	-	1.00	-	-
	Group = Case	0.87	[0.70; 1.07]	0.194	0.87	[0.71; 1.07]	0.198
	Group = Simulation	0.95	[0.77; 1.16]	0.601	0.95	[0.77; 1.16]	0.610
	Group = Tutorial	1.15	[0.93; 1.41]	0.190	1.15	[0.94; 1.41]	0.181
Time = Post-test	Group = Control	1.00	-	-	1.00	-	-
	Group = Case	3.58	[2.98; 4.30]	0.000	3.58	[2.98; 4.30]	0.000
	Group = Simulation	3.68	[3.08; 4.40]	0.000	3.67	[3.07; 4.38]	0.000
	Group = Tutorial	1.61	[1.33; 1.96]	0.000	1.60	[1.32; 1.94]	0.000
Time = Retention	Group = Control	1.00	-	-	1.00	-	-
	Group = Case	2.80	[2.36; 3.33]	0.000	2.81	[2.36; 3.33]	0.000
	Group = Simulation	4.08	[3.46; 4.82]	0.000	4.12	[3.49; 4.85]	0.000
	Group = Tutorial	1.29	[1.05; 1.58]	0.017	1.29	[1.05; 1.58]	0.016
Course = No		1.00	-	-	1.00	-	-
Course = Yes		1.26	[1.16; 1.38]	0.000	1.27	[1.17; 1.39]	0.000