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Review

Healthcare Simulation: A Key to the Future of Medical Education – A Review

Omair Ayaz1 Aga Khan University Medical College, Karachi, Sindh, PakistanORCID Iconhttps://orcid.org/0000-0001-5658-5739View further author information
ORCID Icon &
Faisal Wasim Ismail2 Department of Medicine, Aga Khan University Hospital, Karachi, PakistanCorrespondence[email protected]
ORCID Iconhttps://orcid.org/0000-0003-0983-0644View further author information
ORCID Icon
Pages 301-308 | Published online: 05 Apr 2022

Abstract

Aim

Simulation originates from its application in the military and aviation. It is implemented at various levels of healthcare education and certification today. However, its use remains unevenly distributed across the globe due to misconception regarding its cost and complexity and to lack of evidence for its consistency and validity. Implementation may also be hindered by an array of factors unique to the locale and its norms. Resource-poor settings may benefit from diverting external funds for short-term simulation projects towards collaboration with local experts and local material sourcing to reduce the overall cost and achieve long-term benefits. The recent shift of focus towards patient safety and calls for reduction in training duration have burdened educators with providing adequate quantity and quality of clinical exposure to students and residents in a short time. Furthermore, the COVID-19 pandemic has severely hindered clinical education to curb the spread of illness. Simulation may be beneficial in these circumstances and improve learner confidence. We undertook a literature search on MEDLINE using MeSH terms to obtain relevant information on simulation-based medical education and how to best apply it. Integration of simulation into curricula is an essential step of its implementation. With allocations for deliberate practice and mastery learning under supervision of qualified facilitators, this technology is becoming essential in medical education.

Purpose

To review the adaptation, spectrum of use, importance, and resource challenges of simulation in medical education and how best to implement it according to learning theories and best practice guides.

Conclusion

Simulation offers students and residents with adequate opportunities to practice their clinical skills in a risk-free environment. Unprecedented global catastrophes provide opportunities to explore simulation as a viable training tool. Future research should focus on sustainability of simulation-based medical education in LMICs.

Introduction

Simulation is defined as “the imitative representation of the functioning of one system or process by means of the functioning of another”.Citation1 It is an activity that mimics natural phenomena without the added risk of sustaining expected consequences. The degree to which a simulation resembles reality is termed fidelity.Citation2 Modern day simulation is used by a wide spectrum of generalist and specialist occupations for the purpose of training and certification.Citation3 However, simulation finds its historical and utilitarian roots in the fields of military and aviation.Citation3

Military application of simulation has long been observed in the form of war games.Citation4 Although the cost of purchasing and maintaining sophisticated simulators in the military has grown, their advantages far outweigh their liability.Citation5 Edward Link introduced simulation into aviation with his “Blue box” flight trainer.Citation6 Within 50 years, simulators were formally incorporated into civil aviation to be used to certify and license pilots.Citation3 One of many notable contributions to flight simulation is the National Aeronautics and Space Administration’s (NASA) Cockpit Resource Management principles.Citation3 These have been adopted in healthcare to benefit intensive care, anesthesia and surgical residents today.Citation3

Up until the 20th century, traditional apprenticeship was standard for clinical education.Citation7 It is still used as a primary delivery vehicle in some parts of the developing world.Citation7 Although simulation has long been established in medicine by means of anatomical models and preserved cadaveric tissue, Bradley defined three movements that paved the way for its modernization: the resuscitation movement, introduction of anesthetic simulators, and medical education reform.Citation7 Laerdal’s Resusci-Anne, Gaba’s CASE 1.2, and Good and Gravenstein’s GAS serve as predecessors to the modern human-patient simulator.Citation8 Medical simulators have continued to evolve rapidly in the past few decades.Citation8

Simulation has been adopted by medical educators throughout most of the developed world.Citation9 Although its advantages are comparable between resource contrasted settings, developing countries still struggle to employ it into mainstream use.Citation10 This stems from misconceptions regarding its availability, range and cost, and ambiguity related to its consistency and validity.Citation11 Because of the SARS-CoV-2 pandemic, patient interaction has been limited for students and residents to prevent spread of the disease.Citation12 This has created a unique opportunity to help galvanize momentum towards simulation in low- to middle-income countries (LMICs).Citation13

The aim of this literature review is to provide relevant and comprehensive information regarding the utility of simulation in medical education and use knowledge theories to determine how to best implement it in under and postgraduate medical education. We undertook a literature search on MEDLINE using MeSH terms: undergraduate medical education, postgraduate medical education, review, guidelines and simulation. Only articles in written in English were selected for further review, and preference was given to research published within the last 10 years.

The Spectrum of Healthcare Simulation (HS) in Medical Education

Gaba described 11 dimensions of the application of simulation in medical education.Citation14 Dimension 8 categorizes simulation technology based on complexity.Citation14 The five components of that dimension are role playing, standardized patients (SP), part-task trainers, the computer patient, and the electronic patient/virtual reality (VR).Citation14 SPs are trained individuals who can provide a concise medical history and portray relevant physical findings for their scenario.Citation8 They are popularly employed by medical educators throughout the globe because no technology is needed for the set-up.Citation8 SPs can also effectively simulate a vast array of medical and ethical scenarios.Citation8 Their validity and reliability in clinical skills assessment has led to the incorporation of SPs in examinations for licensure in Canada and the United States.Citation11,Citation15Citation17

Part-task trainers comprise a representation of only a component of the human body.Citation7 These are frequented by subspecialties that recognize the benefit of deliberate practice to obtain mastery in technical, procedural, or psychomotor skills.Citation7 High-fidelity simulators can exhibit multiple clinical scenarios, and they are interactive and reactive.Citation18 Advanced part-task trainers with haptic feedback (ie, creating an experience of touch by applying force, vibration or movement in response to user operation) are being increasingly accepted in interventional and surgical training specialties such as ophthalmology and orthopedics.Citation11 summarises the progress of medical simulators over time.

Table 1 The Progress of Medical Simulators

Initial resistance to the implementation of simulation stemmed from the financial burden of training staff and maintenance of expensive technology.Citation19 Development of simulation centers is bridging the tricky gap between educator needs and access to equipment.Citation11 Despite the recent contributions to the gamut of simulation fidelity and cost-reduction, issues regarding its consistency and validity are the primary reason for the delay in global application.Citation11 However, evidence for the transition of the medical training enterprise towards simulation has gathered volume in the past 2 decades.Citation20 This is, in part, due to the growing emphasis on patient safety rather than bedside teaching.Citation20

The Imperative to Incorporate HS in Medical Education

Medical education is intensive and extensive.Citation21 Medical professionals are expected to be proficient and effective.Citation21 With a rapidly changing pattern of healthcare delivery, medical students and residents face an added challenge to keep up to date with the most recent standards of care.Citation22,Citation23 Calls to reduce the duration of professional training and time constraints throughout the education process have the adverse effect of limiting exposure of students and residents to an adequate quality and quantity of clinical exposure.Citation24,Citation25

This is where simulation may flourish. It can provide all learners with an acceptable variety and number of clinical scenarios. Furthermore, exposing all participants to the same scenarios and uncommon clinical cases might allow a more standard approach to clinical curricula.Citation2 This might also be useful downstream in potentially confronting the inadequacy and lack of preparedness felt by medical students and novice physicians in recent years.Citation26Citation31

It is important to correct the perception of simulation as a universally expensive commodity. Low-fidelity simulators like SPs and part-task trainers are readily available, inexpensive, and easily implemented.Citation8 This can ease incorporation into continued education and recertification programs without substantial impact on financial resources.Citation2

Most medical care is now delivered by teams, and simulation is integral in improving patient safety by means of Crisis Resource Management and team training techniques.Citation14,Citation32 Real team training has the advantage over improvised team training because it allows for better observational learning, verbal persuasion, and heightened physiological responses borne out of member familiarity.Citation33,Citation34 Moreover, testing team simulation in-situ yields far more constructive results than conducting the exercise at a simulation center.Citation33

It is also important to address the misconception that simulation is meant only to improve psychomotor skills. Studies show that simulation improves participant affective interpersonal communication and yields more empathic and adept professionals entering the workforce.Citation35Citation37

The utility of simulation is in allowing participants to revisit clinical scenarios and practice skills individually and collectively as a team until competence is achieved. A new model of medical education is thus required that has patient safety at its core, avoids the flaws of a purely apprenticeship training model, and provides unlimited opportunities to practice and perfect skills in a risk-free environment.

The Challenge for Low- to Middle-Income Countries (LMICs)

HS has already become the gold standard for medical education in a vast majority of the developed world.Citation9 The benefits of simulation-based medical education (SBME) are comparable between resource poor and resource abundant settings.Citation10 However, the need for these benefits is far more pronounced in developing countries due to inadequate access of care.Citation10 Using SBME to train entry-level providers, educate community workers, and bridge the gaps of understanding between healthcare providers and local populations who mistrust modern medicine may enhance the overall impact of HS.Citation10 It may also lower the rate of preventable adverse events that are already underreported in LMICs.Citation38

A recent literature review done by Martinerie et al showed that most studies investigating SMBE in LMICs were conducted in collaboration with international organizations.Citation9 Indeed, most quality improvement projects launched in LMICs are reliant on external funding.Citation38 Unit cost and operator expertise remain notable areas of concern regarding SBME implementation in resource poor settings.Citation9 This is worsened by inadequate cost reporting in SBME research.Citation39 Nevertheless, the availability of modern low-cost simulators could promote self-reliance in LMICs.Citation9 This is important as it will prevent unnecessary disruptions in the continuity of SBME due to bureaucratic tribulations.Citation40

Simulation may also be conducted online or virtually where the use of the internet or computer programs can help eliminate costs related to purchasing expensive equipment for on-site training.Citation41Citation43 A study by Okrainec et al demonstrated effective use of laparoscopic telesimulation in Botswana where resident training took place through SkypeTM.Citation42 In another study, Adhikari et al used immersive virtual reality to conduct a sepsis game for pre-registered nurses.Citation43 Virtual reality provides three-dimensional environment that closely resembles real life.Citation43 The experience may be enhanced with haptics that provide real-time force feedback.Citation44 They reported a significant improvement in self-confidence and reduction in anxiety faced by the participants.Citation43 In addition to cost reduction, these courses can be taught over several weeks using a more dispersed strategy as opposed to short intensive modules.Citation42 However, there are limitations to these initiatives such as availability of technology, a stable internet connection, and digital literacy and confidence of users.Citation42,Citation43

Another challenge for LMICs is the adaptability of SBME.Citation40 SBME is only effective if the simulations mimic realistic and relevant scenarios that account for resource limitations and disease distribution in the target setting.Citation40 If the simulation involves rare scenarios or clinical management that is not in common practice, the overall impact of the educational activity is lost.Citation40 Additionally, vital learner feedback during the process may be hindered by hierarchy in training structures, social and cultural norms, gender implications or language barriers.Citation40 Since each LMIC faces different challenges, dedicated time from experts and educators is required to define clear learning objectives, establish effective delivery of feedback and evaluate the type of SBME modality to use.Citation40

LMICs may also benefit from collaboration of local experts, institutions and manufacturers to develop and implement SBME.Citation40 A recent study by Gheza et al has shown that overall cost of expensive medical equipment can be effectively controlled using locally sourced materials and readily available devices while yielding comparable outcomes to patented products.Citation45 These efforts not only improve accessibility but also help increase market share for the products.Citation46

Sound Educational Andragogy

Bioscience, sociocultural, and learning theories have been used to design frameworks that are core to HS education strategies.Citation47 Kolb’s learning cycle is the most prominent among these theories and has been commonly used as a conceptual framework for simulation programs involving team training.Citation48 Kolb emphasizes that transformation of experience is essential in creation of knowledge.Citation49 His theory consists of four parts: concrete experience, reflective observation, abstract conceptualization, and active experimentation.Citation49 Participants undergo concrete experience as they complete the simulation scenario.Citation49 This is followed by debriefing where they reflect upon the experience and draw generalizations and conclusions from their observations to form abstract concepts.Citation49 These concepts are then actively used to influence actions in repeat simulations.Citation49 Active experimentation is an important but neglected step in the simulator learning process in most programs.Citation33 This is partly due to time and resource constraints.Citation33

Knowles’ adult learning principles of prior experience and response to problem-centered learning as opposed to content-centered learning, and Dewey’s theory of reflective thought argue that learners exhibit increased internal motivation to reflect on their performance when faced with difficult and relevant scenarios.Citation49Citation51 Debriefing in a group of participants where critique is offered under the observation of trained facilitators creates an environment for individuals to reflect on their own conceptual framework (innate beliefs that guide their thinking and actions).Citation33 According to Schön, this kind of reflection is more beneficial than reflecting-in-action during the simulation or reflecting-on-action after the simulation, which individuals usually do on their own and without peer input.Citation52

The convergence of the behavioral, constructivist, and social cognitive learning theories makes a strong case for HS to be incorporated into medical education curricula in both developed and developing countries.Citation53

COVID-19 and the Case for Simulation

The SARS-CoV-2 pandemic has negatively impacted the education of undergraduate and postgraduate trainees globally.Citation12 In response to isolation and preventative requirements issued by governments worldwide, there has been a unanimous shift towards technology-based education. Medical teaching employs a two-pronged approach: learning and practice.Citation54 Learning has been effectively delivered using online platforms during the pandemic, however the transition to a virtual setup presents its own problems.Citation54 These include time management, lack of infrastructure and resources, poor communication, negative attitudes and student engagement.Citation54 The opportunity for students to practice their clinical skills remains an area of concern.Citation54,Citation55 While the gradual transition to telemedicine and the use of prerecorded clinical encounters have been helpful, they do not provide a viable substitute for physical examinations and direct observation of skills for feedback.Citation55 This is particularly pronounced with surgical/procedural training due to rationing of personal protective equipment and limiting of non-essential staff in operating rooms.Citation55 With access to patients being limited, elective surgical procedures being cancelled or reduced, and a limited number of students and residents allowed to engage in care to maintain standard operating procedures, it has become evident that simulation can fill a very important niche during this unprecedented time.Citation13 It will allow students and residents adequate exposure, time, and opportunity to learn and hone their skills.Citation13 This may be the best time for institutions to adopt HS as a medical education strategy and prepare for future contingencies.Citation13

The COVID-19 pandemic has also disproportionately affected vulnerable medical students such as those from developing countries and those with financially disadvantaged backgrounds.Citation56 Although the use of technology has been effective in these developing circumstances, students in LMICs may not have access to appropriate equipment and a stable internet connection to run them.Citation56 It is in part because of these issues that online learning is met with a poor response in the developing world.Citation56 This makes it more important to dispel the misconception of simulation as an expensive commodity and promote the use of local manufacturing and low-cost simulation.

Implementation of HS in Medical Education

Incorporation of HS as a teaching strategy in undergraduate and postgraduate medical education curricula requires a stepwise approach.Citation57,Citation58 The first step is the assembly of human capital.Citation59 Simulation, as a teaching method, requires properly trained facilitators.Citation59 Improperly executed simulation can lead to unaccomplished objectives, poor to no learning, and disengaged or even psychologically impacted participants.Citation2,Citation60Citation63 It is extremely important for medical institutions to recognize this and provide their faculty with adequate training in the operation of healthcare simulators before planning for induction and implementation of simulation as an education strategy. Adherence to best practices during the pre-brief, the simulation itself, and the debrief (including skill sign-off) is essential in the long-term success of a simulation program.Citation64

The next step is integration of simulation into the standard curriculum of a teaching program.Citation57 This can be done via amalgamation of this modality into an existing curriculum or through development of new curricula.Citation57 The process is carried out by a collaboration of the program director, content expert, and simulation expert in four phases: planning, implementation, evaluation, and revision.Citation57 Curricular integration has the advantage of using simulators to achieve learning objectives instead of ad hoc use that only adds to the course load, without achieving palpable benefit.Citation57

Once part of the curriculum, there should be provisions for deliberate practice.Citation57 Coined by Ericsson in 2004, deliberate practice is the repetition of psychomotor or cognitive skills to achieve defined goals in a controlled setting.Citation65 It is designed to provide feedback for error correction in subsequent practice until the participant displays competence and advances onto the next skill.Citation65 Deliberate practice is a more powerful predictor of superior expert performance than clinical aptitude.Citation66 It is also particularly useful in training for rarely performed procedures.Citation65 Simulation is versatile in the ability to not only expand on psychomotor skills but also assist in refining trainee confidence and self-sufficiency.Citation35Citation37,Citation67

Deliberate practice is crucial in mastery learning.Citation57 The objective of mastery learning is to achieve performance on a level higher than basic competence.Citation57 Residents take different times to achieve mastery as they have dissimilar strengths and weaknesses.Citation57 Each participant must meet a set standard to progress through educational units of increasing difficulty.Citation57 Once mastery is achieved for a skill, range of difficulty and clinical variation in simulation training is increased in the case mix.Citation57 Both need to be adjusted according to the needs of the training program.Citation57

True learning occurs when participants are given time to achieve goals at a pace that is complementary to their learning capability. Desired outcomes can be accomplished by integrating simulation into curricula with the support of trained facilitators.

Conclusion

It is imperative that HS is adopted in undergraduate and postgraduate medical education globally. The evidence for its efficacy in adult learning is overwhelming, yet its use remains variable and opportunistic. Medical education needs to produce proficient and poised doctors for the future. Therefore, students and residents need to be provided with opportunities to practice and perfect their skills before real patient encounters. Future research priorities should focus on sustainability of simulation in LMICs and prioritize adequate and informative cost reporting. Foreign funds invested in limited and short-term simulation initiatives in developing countries should be redirected in collaboration with local experts towards more attainable and long-term projects. Unprecedented times when global healthcare is operating under extreme pressure (eg, during the COVID-19 pandemic) where patient interaction is limited provide unique opportunities to explore these areas. Strategic and integrated use of simulation is the way forward.

Disclosure

The authors report no conflicts of interest in this work.

Additional information

Funding

The authors have received no funding for this article.

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