Introduction

Cardiorespiratory arrest is one of the leading causes of death worldwide, with a global incidence of about 20 thousand people per day (Portuguese Cardiology Foundation, n.d.). Basic life support increases the probability of survival when initiated in the first moments after cardiorespiratory arrest; it comprises two actions: chest compressions and ventilation (^{Smith, 2017}).

Recognizing and responding to a cardiorespiratory arrest situation is an event of great stress and anxiety for all nurses, requiring effective performance of cardiopulmonary resuscitation and response prioritization (^{Sok, Kim, Lee, & Cho, 2020}).

Sudden events are present in nurses’ daily life and these professionals must be ready to act and implement life-saving interventions. Simulation-based basic life support training provides an effective and safe environment for nurses to learn and practice the clinical skills necessary in emergencies (^{Morton, 2017}).

Nurses are able to develop their capabilities to intervene in emergencies through simulation-based basic life support, solidifying procedures and ensuring practice safety. The simulation effects on nursing practice include greater knowledge of clinical competence, communication and clinical decision making skills, problem solving, and critical thinking (^{Kim & Choi, 2019}).

This investigation study aims to understand nurses’ perception of simulation-based basic life support training on the clinical practice of nurses, to emphasize its importance in skills acquisition.

1. Theoretical framework

In Portugal, every year, around 10 thousand people are victims of cardiorespiratory arrest Portuguese Cardiology Foundation, n.d.).

This epidemiological transition, to global phenomenon, must be considered in nurses’ training programs for victim assistance in emergencies. Team performance may be improved by simulation-based basic life support trainings, executed in a safe environment (^{Armstrong, Peckler, Pilkinton, McQuade, & Rogan, 2021}), in which the participants can learn from their mistakes.

The main goals of basic life support are cardiorespiratory arrest prevention and survival improvement after cardiopulmonary resuscitation. Survival chance after sudden cardiorespiratory arrest can be doubled or tripled if cardiopulmonary resuscitation is started quickly. For each minute of delay at the start of cardiopulmonary resuscitation maneuvers, the chances of survival decrease between 7 to 10% (^{Herbers & Heaser, 2016}).

The priorities of cardiopulmonary resuscitation are defined by time and sequence of resuscitator responses, which are the immediate start of chest compressions, immediate defibrillation, and minimization of chest compressions interruptions (^{Chu & Robilotto, 2018}). Resuscitation success and its neurological outcome depend on the efficient and successive implementation of these actions, so simulation-based basic life support training demonstrates positive results in nurses’ clinical practice (^{Buléon et al., 2016}).

Thus, even in institutions that have an in-hospital emergency team, all health professionals should have basic life support training to be able to act in situations of peri-arrest and cardiorespiratory arrest until the arrival of a defibrillator and/or specialized team (^{Vincelette, Quiroz-Martinez, Fortin, & Lavoie, 2018}). Nurses are, most of the time, the first to respond to medical emergencies, so they should be confident to act and provide the required care when facing cardiorespiratory arrests; simulation-based basic life support training contributes positively to the development of these skills (^{Herbers & Heaser, 2016}).

The basic life support course lasts four hours (European Resuscitation Council, n.d.). Regarding the recertification time, there is no consensus, however the interval of one year between training in basic life support is not enough for your quality execution by nurses (^{Everett-Thomas et al., 2016}).

Simulation-based training increases the acquisition/consolidation of skills compared with traditional courses. Simulation-based training can be of low, medium, or high fidelity. Low-fidelity simulation is developed using role playing/case studies; medium-fidelity simulation involves realistic scenarios with simple mannequins; high-fidelity simulation uses realistic scenarios in situ or within simulation centers, using computer-controlled mannequins (^{Chu & Robilotto, 2018}).

Compared with traditional trainings, high-fidelity simulation allows professionals to practice and apply skills in basic life support situations and to learn in a safe environment. Thus, frequent simulations improve basic life support skills (^{Halm & Crespo, 2018}).

Simulation-based training in situ are a quick and efficient way of applying theoretical knowledge and developing muscle memory; it is also a great teamwork opportunity. Moreover, basic life support simulations significantly improve response time and increase the confidence of professionals (^{Herbers & Heaser, 2016}).

The adequate performance of a basic life support team relies on technical and non-technical skills; non-technical skills are leadership, teamwork, proper task management, and interpersonal communication. Highly effective teams are associated with coordinated functions of leadership and clarity of responsibilities when dealing with cardiorespiratory arrests (^{Armstrong et al., 2021}).

Teamwork is crucial and its development in simulation-based training is necessary for the effective evaluation of patients, due to increased specialization and complexity of care, risks associated with treatment options, and the need to ensure patient safety (^{Armstrong et al., 2021}).

Effective resuscitation requires a coordinated response from several professionals. The quality of teamwork can affect results. Identifying an efficient procedure for in-hospital response to emergencies involves at least four teamwork functions: shared mental models, clarity of roles, communication, and workload management (^{Armstrong, et al., 2021}).

Basic life support simulation with debriefing has positive effects on the way nurses control emotions, as well as performance and cognitive skills; moreover, it is an excellent pedagogical tool because due to being practical and objective, allowing the identification and understanding of the problems in implementing techniques and the proper training of professionals in emergencies. Continuous training in basic life support, carried out through simulation-debriefing, is an effective way to acquire adequate and long-lasting knowledge. The achieved satisfaction level is high since this learning method corresponds to professionals’ expectations and it is similar to real clinical practice (^{Fraga-Sampedro, 2018}).

The debriefing session after the practice ensures that professionals learn from the experience and value their participation in basic life support (^{Herbers & Heaser, 2016}).

2. Methods

This is a quantitative, descriptive, and correlational study.

3. Results

Regarding the sociodemographic characteristics of the 612 participants (Table 1), we found that they were on average 39.9±9.8 years old - the youngest was 22 and the oldest was 64 years old. Most of them were female (79.7%) The overall qualification degree was licensed; Medical-surgical Nursing was the most frequent specialization. They had an average of 16.3±10.1 years of professional experience, ranging from 0 to 44 years.

Most participants of the study work in Urgency and Emergency sectors.

Table 1 Sociodemographic characterization of nurses. 

Most nurses claim to have basic life support training (98.2%), and on average the last training occurred 3.4±3.48 years ago (ranging from 0 to 30 years ago).

Regarding the last basic life support training, 90.8% of the nurses reported that it was a formal course and 97.7% of them were simulation-based.

Regarding the acquired skills in simulation-based training, the participants presented higher mean values of understanding the basic life support algorithm and considering it an excellent contribution to clinical practice - mainly in better evaluating the victim (Table 2).

Table 2 Descriptive statistics of simulation-based skills. 

The lower mean value is related to the simulation realism of the stress level, which are higher in clinical practice than in basic life support trainings.

The Pearson correlation (r) verified that the different variables present a significant and negative correlation with age and professional experience (Table 3).

Table 3 Correlation matrix of the variables with age and professional experience. 

* Significant correlation for p = 0.05. ** Significant correlation for p < 0.001.

We found that as the age and professional experience of the participant’s increases, they recognize less impact of simulation-based basic life support trainings in their clinical practice in the different variables evaluated. Age and experience did not correlate with realism of stress level in simulation-based training.

4. Discussion

Data analysis of knowledge and skills acquired in simulation-based basic life support training show that recurring training contributes to the clinical practice of nurses (^{Colquitt, Walker, & Haney, 2019}; ^{Whitmore et al., 2019}).

We found with the assessment of the data that simulation-based training of basic life support promotes better capacity of assessing victims, with high mean values that are corroborated by the evidence (^{Halm & Crespo, 2018}) and improves technical and non-technical skills (^{Kim & Choi, 2019}; ^{Więch et al., 2019}).

We noticed from the analysis of the collected data that simulation-based training encourages teamwork, as evidenced in the studies by ^{Colquitt et al. (2019}) and ^{Halm & Crespo (2018}), which increases nurses’ self-confidence in non-technical skills, such as interpersonal communication (^{Kim & Choi, 2019}; ^{Morton, 2017}).

In the data analysis, we can also verify that nurses gave positive feedback after receiving simulation-based basic life support training, as evidenced by ^{Kim, & Choy (2019}), since the activities and clinical cases of simulation-based basic life support were realistic, as in the studies by ^{Halm & Crespo (2018}) and ^{Whitmore et al., (2019}).

Although nurses’ answers do not present high mean levels regarding the level of stress, the evidence argues that simulation-based training decreases stress levels experienced by nurses in real contexts (^{Sok et al., 2020}).

From the data analysis, it appears that the simulation-based courses have a greater impact on clinical practice of nurses than conventional trainings, as corroborated by other studies (^{Halm & Crespo, 2018}; ^{Kim & Choi, 2019}).

Since cardiorespiratory arrest is a sudden event that requires priority response and cardiopulmonary resuscitation, the simulation-based basic life support training allows nurses to develop skills to intervene in emergencies, with a high analyzed mean value. The acquired and consolidated skills contribute not only to teamwork, but also help team members to focus on the care priorities during cardiopulmonary resuscitation and situation management (^{Colquitt et al., 2019}; ^{Halm & Crespo, 2018}; ^{Whitmore et al., 2019}).

Regarding basic life support, simulation-based training increases performance effectiveness and develops critical thinking and decision-making skills, which promote confidence in clinical nursing practice, attesting the mean values obtained, increasing nurses’ satisfaction and competence (^{Halm & Crespo, 2018}; ^{Kim & Choi, 2019}; ^{Whitmore et al., 2019}).

However, the statistical analysis showed that as the age of participants and professional experience increase, professionals recognize less impact of simulation-based trainings on their skills. So, the simulation-based models of basic life support training should be rethought to better develop skills throughout the entire professional cycle of nurses.

Basic life support training with simulation improves nurses’ competence and performance times in resuscitation situations, proving with evidence, which promotes the reduction of complications during provision of care, as well as the difficulties experienced in sudden events (^{Fraga-Sampedro, 2018}; ^{Whitmore et al., 2019}). Therefore, it is important to include Good Training Guides when planning simulation-based courses.

Nurses reported that the acquisition/consolidation of basic life support skills was significantly positive in simulation-based trainings, with high mean values, compared with conventional trainings. Frequent simulation-based training improves skills and prevents their degradation (^{Halm & Crespo, 2018}).

High fidelity simulation-based training with advanced software and realistic scenarios provides clinical realism to basic life support formation, which promotes the understanding and involvement of nurses (^{Everett-Thomas et al., 2016}; ^{Halm & Crespo, 2018}; ^{Whitmore et al., 2019}).

Basic life support simulations do not replace real experience, but it is of higher fidelity compared with other training methods (^{Fraga-Sampedro, 2018}).

Analyzing the knowledge and skills acquired by nurses in simulation-based basic life support trainings, we found that they positively perceive the benefit for clinical practice.

Conclusion

Simulation-based learning is an essential tool in the initial and continuous training of nurses, crucial to maintain and train basic life support skills. The training situations should be as realistic as possible, in a pedagogical and safe environment.

The representation of clinical reality and stress environments are fundamental in the context of cardiorespiratory arrest. In situations of cardiopulmonary resuscitation, the simulated training appears as one of the most promising pedagogical options, since it overcomes the difficulties in adequately training nurses to act under stress in sudden events. It is an effective improvement in safety, efficacy, and nursing care in basic life support to critical patients. To ensure the efficiency of training, it is necessary to develop clinical cases that can transport the trainee to a reality similar to sudden events, whether in incidents, difficulties, or stress.

Simulation-based trainings should be implemented unequivocally, whether in initial or continuous trainings, because they provide active and systematic learning experiences, enhancing the development of technical and non-technical skills, such as interpersonal communication and teamwork. Allowing nurses to demonstrate their knowledge, skills, attitudes, and behaviors in a safe environment.

Simulations create an integrated vision that facilitates the balance between the adequate provision of care, the fulfillment of basic life support, and the correct execution of the maneuvers.

Adequate simulation-based training in basic life support for nurses has a positive impact on the provision of care that meets the real needs of patients suffering from cardiorespiratory arrest.

Nurses should rely on these practices to answer questions regarding cardiorespiratory arrest. In nursing, research is indispensable to allow the acquisition of skills that contribute, not only to improve people’s quality of life, but also to recognize and appreciate the nursing profession. In future studies, it is important to analyze the impact of planning of basic life support trainings, using good training guides to develop nurses’ clinical skills.

Acknowledgements

We thank all participants who dedicated themselves to this study and the translators for their work.