The old medical education approach of ‘see one, do one, teach one’ (whilst learning on actual patients) has been described as inappropriate for the twenty-first century (Donaldson 2009) and has raised ethical questions about the use of patients as a training resource (Issenberg & Scalese 2008). Meanwhile, the reduction in teaching time and practice placements has increased the need for high-quality education. As the focus has shifted from the apprenticeship model to an outcome-based approach, simulation has been proposed as an ideal method of assessing competence.

Simulation can also be used to enhance the ad hoc nature of practice education and give all learners a standardised experience of rarer cases and incidents. Performing simulations in-situ, in the actual practice environment, allows for training of the extended team, including individuals who would not normally be the focus of more formal training. It has been found that such sessions can help detect organisational system-based risks in the clinical environment and reduce patient and institutional risk (Yajamanyam et al. 2012). Indeed, while serving as Chief Medical Officer, Sir Liam Donaldson called for simulation-based training to be fully integrated, resourced and supported by a skilled faculty to enable high-quality training (Donaldson 2009).

Simulation is often initially viewed as a tool to teach clinical procedures. However, the above definition demonstrates that it can be used not only to develop knowledge and skills but also to focus on attitudes, ways of behaving and their development. Thus, the same scenario can be used for a number of different learning outcomes. In recent years, there has been considerable interest in the use of simulation for inter-professional education, with a particular focus on patient safety (Gough et al. 2012). Innovative simulation sessions are increasingly being used to develop a greater awareness of how to recognise and prevent patient harm incidents and the human factors that can contribute to them.

Each simulated learning event has elements that engage with these different learning styles, whether in the scenario, debriefing or subsequent scenario where learning is put into action. Experiential learning is described as a form of constructivism, in which learners construct their understanding of the world through their interaction with it, by means of a process of assimilation and accommodation (Bradley & Postlethwaite 2003). The central tenet of constructivism is that learning is an active process in which the lecturer acts as a guide or facilitator (Tam 2000). Because simulation is now recognised as taking a constructivist approach, we refer to those who guide the scenario or debriefing as facilitators.

Deliberate practice, in which the learner repeats a task and receives rigorous assessment and specific feedback, aims to achieve better skills performance (Duvivier et al. 2011), which becomes fluent and instinctive (Weller et al. 2012). Often, the task is a cognitive or psychomotor one (Grant 2012). There is also an emphasis on motivation and feedback (Castanelli 2009), which aligns it more to behaviouristic theory, where a positive behaviour is rewarded and any action is a learnt behaviour.

As already stated, a simulation requires far more than just a manikin. Whilst simulation hardware is part of the process, it is by no means the whole story. With aircraft simulators, the air crew interact directly with technology and the same equipment can therefore be used in a simulator to recreate a very realistic cockpit environment. However, healthcare staff interact with people (not just equipment), and a manikin is never a perfect representation of a patient. Manikins may be described as low fidelity (for instance, a part task trainer such as a cannulation arm), medium fidelity (for example, a resuscitation manikin, perhaps with ECG and other physical parameters) and finally high fidelity (such as the very realistic human patient simulators, which can breathe, blink, sweat and react physiologically to drugs and events). As we have seen, it is not just the fidelity of the manikin that gives a simulation defined fidelity. Yet the two are often equated in research and published literature. Does a low-fidelity manikin only allow a low-fidelity simulation? Does a high-fidelity manikin always ensure a high-fidelity simulation? The answer is ‘Clearly not’.

Equipment, environment and psychology can also have varying degrees of fidelity. For instance, how far does the simulation mirror the actual environment and equipment the learner would normally work with (Berragan 2011)? Environmental fidelity includes the physical layout, the provision of other supporting equipment, and the test results that would normally be available. Psychological fidelity involves the extent to which learners believe in the scenario and whether they feel it is a realistic equivalent to an actual clinical episode.

I have to say, because of the misuse, confusion and inconsistency surrounding the term ‘fidelity’, it is not a word I often use. Gaba (2004) and others have suggested terms that better describe elements of a simulated event but these are not in widespread use.