key: cord-0736910-gntghofs
authors: Christodoulides, Natasha; Duggan, William P; Dalrymple, Kirsten R
title: COVID-SIM: building testing capacity through public engagement with healthcare simulation
date: 2020-04-30
journal: BMJ Simul Technol Enhanc Learn
DOI: 10.1136/bmjstel-2020-000637
sha: a28fa815ba351e9e59ff1c16a90a4c191690606d
doc_id: 736910
cord_uid: gntghofs

nan

An outbreak of respiratory disease caused by COVID-19 has caught the world off guard. As death tolls rise and governments implement stringent measures to control its spread, members of the public show desire to help.

Testing as a means to manage and contain the disease has been recognised worldwide. This has spurred numerous initiatives including set-up of drive-through COVID-19 testing clinics. Currently, drive-through testing is performed by healthcare workers.

Using these drive-through clinics as inspiration, we propose integrating simulation to train volunteers from the public to perform safe testing of symptomatic patients for COVID-19 in the community.

The initial uptake of simulation in contemporary healthcare education was first employed to prepare for crisis events. As we combat the COVID-19 pandemic, healthcare educators have a duty to expand the use of simulation beyond its dominant use in training and assessment to its full potential, including making it readily accessible and relevant to the public. We suggest Kneebone et al's model of 'distributed simulation' as an easily accessible, widely available method to deliver a low-cost, 'immersive' simulated experience. 1 This can be achieved by taking simulation away from the physical confines of a simulation facility and into the community. We envisage that this could be successful as learners and educators will be working towards a common goal with personal meaning. ► Safely teach new skills to volunteers. ► Create a representation of 'safe swabbing' for the purposes of practice. ► Extend the benefits of simulation to the community. ► Provide a safe space for learners for feedback and debriefing. In the preparation phase, comprehensive and achievable intended learning objectives should be set around the use of PPE, appropriate sample collection and communicating with patients. We propose that educators use a low-technology manikin head, PPE and testing kits to deliver situated training in the community, based on a standardised protocol.

Following an introduction and demonstration of the simulators, volunteers will learn through practice and experimentation. The educator's role will be to provide 'Vygotskian'-style 'scaffolding', encouraging novice learners to experiment and providing support and feedback when required to advance learning. 2 A formal debrief will conclude each session (figure 1).

The simulation design progressively layers and integrates skills as follows: stage 1: skills-based simulations ► Safe donning and doffing of PPE (demonstration, practice with PPE, feedback). ► Swabbing of patients (demonstration, practice with swabs and manikin heads, feedback). ► Communication for gaining consent, explanation of the procedure and process of obtaining test results (demonstration, role-play, feedback).

► Task performance using the manikin in a 'car', with the voice of an educator/volunteer (briefing, experimentation, simulation practice, debriefing). Multiple debriefing tools exist to structure the discussion that follows the simulation. The primary aim is to foster a supportive environment where the learners feel safe and psychologically challenged to engage in reflective practice. 3

The rise in popularity of technology in simulation accompanies the assumption that greater simulation fidelity (ie, a high resemblance to real patients, events and/or environments) will lead to enhanced learning. 4 This has shifted focus away from the intended educational outcomes of the simulated experience. Hamstra et al argue that higher fidelity does not necessarily correspond to improved educational effectiveness. They go so far as to maintain that the concept of fidelity is unhelpful and that 'functional task alignment' and 'learner engagement' are more important features of learning using simulation. 4 Going beyond the above definition of fidelity, Stokes-Parish and colleagues describe two complementary modes of reality: (1) conceptual or 'semantical' realism, that is, the cue that invites the learner to progress in the scenario, and (2) 'phenomenal' realism or the emotional buy-in of the learner. 5 The potential for COVID-SIM's success lies in the phenomenal realism that learners bring to the simulation. Our intended learners have willingly signed up so we anticipate they enter the programme with greater emotional investment, greater sense of purpose and, hence, a greater average level of engagement. As effective simulation lies largely in engagement and meaningfulness for the learner, COVID-SIM is poised to create learning gains using flexible and low-cost simulation approaches. 1 2 4 how Can we use The lessons learnT here To InTegraTe sIMulaTIon In The fuTure?

COVID-19 has created a global healthcare crisis. Here we propose a role for simulation that goes beyond the confines of the simulation facility and beyond the healthcare community. As a new initiative addressing an expanded 'audience' we believe COVID-SIM offers space and potential for exploration.

In an attempt to reflect the emergent nature of the COVID-19 crisis, we have not added details on how we would train educators nor what suitable equipment could be used where potential shortages of PPE or testing kits exist.

Like this virus, simulation sees no boundaries. Moving forward, this initiative could provide a starting point to illustrate an expanded scope for simulation, one that potentially forges greater connections and collaboration between healthcare and the public.

Contributors NC conceived and designed the work. All authors were involved in the planning and leadership of this work; were involved in the development of the idea; and contributed in the preparation of this manuscript.

funding The authors have not declared a specific grant for this research from any funding agency in the public, commercial or not-for-profit sectors.

Provenance and peer review Not commissioned; internally peer reviewed. orCId id Natasha Christodoulides http:// orcid. org/ 0000-0002-5951-6867

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