Comparative Effectiveness of Technology-Enhanced Simulation Versus Other Instructional Methods

Cook, David A.; Brydges, Ryan; Hamstra, Stanley J.; Zendejas, Benjamin; Szostek, Jason H.; Wang, Amy T.; Erwin, Patricia J.; Hatala, Rose

doi:10.1097/sih.0b013e3182614f95

Cited by 283 publications

(178 citation statements)

References 35 publications

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“…Certain study subgroups were absent or present in lower proportions compared with the larger cohort from which this sample was extracted, [13][14][15] including nonprocedural activities such as physical exam, patient counseling, or clinical reasoning; procedures such as surgery and anesthesiology; and some learner groups (notably medical students). This suggests selection bias in the topics and learners represented.…”

Section: Implications For Practice and Researchmentioning

confidence: 99%

“…71,[80][81][82][83][84][85][86] These comparisons with active interventions were included in previous meta-analyses. 14,15 Three articles omitted the number of trainees; we contacted these authors and two provided needed information.…”

Section: Trial Flowmentioning

confidence: 99%

“…[10][11][12] Previous reports from our review have demonstrated that simulation is superior to no intervention (609 studies) 13 and to nonsimulation instruction (92 studies), 14 and have used comparisons of different simulation interventions (289 studies) to identify evidence-based best practices. 15 The present study is a planned sub-analysis of these data.…”

Section: Introductionmentioning

confidence: 99%

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Patient Outcomes in Simulation-Based Medical Education: A Systematic Review

et al. 2013

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OBJECTIVES:Evaluating the patient impact of health professions education is a societal priority with many challenges. Researchers would benefit from a summary of topics studied and potential methodological problems. We sought to summarize key information on patient outcomes identified in a comprehensive systematic review of simulation-based instruction. DATA SOURCES: Systematic search of MEDLINE, EMBASE, CINAHL, PsychINFO, Scopus, key journals, and bibliographies of previous reviews through May 2011. STUDY ELIGIBILITY: Original research in any language measuring the direct effects on patients of simulationbased instruction for health professionals, in comparison with no intervention or other instruction. APPRAISAL AND SYNTHESIS: Two reviewers independently abstracted information on learners, topics, study quality including unit of analysis, and validity evidence. We pooled outcomes using random effects. RESULTS: From 10,903 articles screened, we identified 50 studies reporting patient outcomes for at least 3,221 trainees and 16,742 patients. Clinical topics included airway management (14 studies), gastrointestinal endoscopy (12), and central venous catheter insertion (8). There were 31 studies involving postgraduate physicians and seven studies each involving practicing physicians, nurses, and emergency medicine technicians. Fourteen studies (28 %) used an appropriate unit of analysis. Measurement validity was supported in seven studies reporting content evidence, three reporting internal structure, and three reporting relations with other variables. The pooled Hedges' g effect size for 33 comparisons with no intervention was 0.47 (95 % confidence interval [CI], 0.31-0.63); and for nine comparisons with non-simulation instruction, it was 0.36 (95 % CI, −0.06 to 0.78). LIMITATIONS: Focused field in education; high inconsistency (I 2 >50 % in most analyses). CONCLUSIONS: Simulation-based education was associated with small-moderate patient benefits in comparison with no intervention and non-simulation instruction, although the latter did not reach statistical significance. Unit of analysis errors were common, and validity evidence was infrequently reported.

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Section: Implications For Practice and Researchmentioning

confidence: 99%

Section: Trial Flowmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Patient Outcomes in Simulation-Based Medical Education: A Systematic Review

et al. 2013

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“…Simulation-based training allows trainees to practice skills in a low-pressure environment, without risk to patients, and allows trainees to make and learn from mistakes before they occur in surgery [13]. Previous research has shown that simulation can be highly effective for learning technical and nontechnical surgical skills [3,4,9,[14][15][16][17] and that the skills learned can transfer to clinical settings [5]. Furthermore, simulation-based training can shorten the learning curve, enhance later intraoperative learning [8,14], and improve patient outcomes [19].…”

Section: Introductionmentioning

confidence: 99%

Simulation for Teaching Orthopaedic Residents in a Competency-based Curriculum: Do the Benefits Justify the Increased Costs?

Nousiainen

McQueen

Ferguson

et al. 2016

Clinical Orthopaedics &Amp; Related Research

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Background Although simulation-based training is becoming widespread in surgical education and research supports its use, one major limitation is cost. Until now, little has been published on the costs of simulation in residency training. At the University of Toronto, a novel competency-based curriculum in orthopaedic surgery has been implemented for training selected residents, which makes extensive use of simulation. Despite the benefits of this intensive approach to simulation, there is a need to consider its financial implications and demands on faculty time. Questions/purposes This study presents a cost and faculty work-hours analysis of implementing simulation as a teaching and evaluation tool in the University of Toronto's novel competency-based curriculum program compared with the historic costs of using simulation in the residency training program. Methods All invoices for simulation training were reviewed to determine the financial costs before and after implementation of the competency-based curriculum. Invoice items included costs for cadavers, artificial models, skills laboratory labor, associated materials, and standardized patients. Costs related to the surgical skills laboratory rental fees and orthopaedic implants were waived as a result of special arrangements with the skills laboratory and implant vendors. Although faculty time was not reimbursed, faculty hours dedicated to simulation were also evaluated. The academic year of 2008 to 2009 was chosen to represent an academic year that preceded the introduction of the competency-based curriculum. During this year, 12 residents used simulation for teaching. The academic year of 2010 to 2011 was chosen to represent an academic year when the competency-based curriculum training program was functioning parallel but separate from the regular stream of training. In this year, six residents used simulation for teaching and assessment. The academic year of 2012 to 2013 was chosen to represent an academic year when simulation was used equally among the competencybased curriculum and regular stream residents for teaching 123 Clin Orthop Relat Res (2016) 474:935-944 DOI 10.1007/s11999-015-4512-6 Clinical Orthopaedics and Related Research ® A Publication of The Association of Bone and Joint Surgeons® (60 residents)and among 14 competency-based curriculum residents and 21 regular stream residents for assessment. Results The total costs of using simulation to teach and assess all residents in the competency-based curriculum and regular stream programs (academic year 2012-2013) (CDN 155,750, USD 158,050) were approximately 15 times higher than the cost of using simulation to teach residents before the implementation of the competencybased curriculum (academic year 2008-2009) (CDN 10,090, USD 11,140). The number of hours spent teaching and assessing trainees increased from 96 to 317 hours during this period, representing a threefold increase. Conclusions Although the financial costs and time demands on faculty in running the simulation program in...

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“…In health education, there is growing evidence that simulation improves learners' safety [1], competence, and skills [2], especially when compared to traditional didactic methods and/or no simulation training [3]. Of significant importance to the health profession is airways management [4], where inadequate skill and poor judgment can lead to patient complications and death [5].…”

Section: Introductionmentioning

confidence: 99%

Pedagogy before Technology: A Design-Based Research Approach to Enhancing Skills Development in Paramedic Science Using Mixed Reality

Cowling

Birt

2018

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Abstract:In health sciences education, there is growing evidence that simulation improves learners' safety, competence, and skills, especially when compared to traditional didactic methods or no simulation training. However, this approach to simulation becomes difficult when students are studying at a distance, leading to the need to develop simulations that suit this pedagogical problem and the logistics of this intervention method. This paper describes the use of a design-based research (DBR) methodology, combined with a new model for putting 'pedagogy before technology' when approaching these types of education problems, to develop a mixed reality education solution. This combined model is used to analyse a classroom learning problem in paramedic health sciences with respect to student evidence, assisting the educational designer to identify a solution, and subsequently develop a technology-based mixed reality simulation via a mobile phone application and three-dimensional (3D) printed tools to provide an analogue approximation for an on-campus simulation experience. The developed intervention was tested with students and refined through a repeat of the process, showing that a DBR process, supported by a model that puts 'pedagogy before technology', can produce over several iterations a much-improved simulation that results in a simulation that satisfies student pedagogical needs.

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Comparative Effectiveness of Technology-Enhanced Simulation Versus Other Instructional Methods

Cited by 283 publications

References 35 publications

Patient Outcomes in Simulation-Based Medical Education: A Systematic Review

Patient Outcomes in Simulation-Based Medical Education: A Systematic Review

Simulation for Teaching Orthopaedic Residents in a Competency-based Curriculum: Do the Benefits Justify the Increased Costs?

Pedagogy before Technology: A Design-Based Research Approach to Enhancing Skills Development in Paramedic Science Using Mixed Reality

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