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Chapter 2 - Use of Simulation and Patient Safety

from Section 1 - Design and Simulation

Published online by Cambridge University Press:  27 July 2023

Sally E. Rampersad
Affiliation:
University of Washington School of Medicine, Seattle
Cindy B. Katz
Affiliation:
Seattle Children’s Hospital, Washington
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Summary

Simulation is used to provide training in critical tasks and also to practice for certain critical events. Simulation can unmask latent threats in a situation and can allow groups to practice communication and build their cohesion as a team. It is highly valued as a tool in medicine and in high-reliability organizations.

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Chapter

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References

Owen, H. Simulation in Healthcare Education: An Extensive History. Switzerland, Springer International Publishing, 2016.Google Scholar
Herzer, KR, Rodriguez-Paz, JM, Doyle, PA, et al. A practical framework for patient care teams to prospectively identify and mitigate clinical hazards. Joint Commission Journal on Quality and Patient Safety. 2009;35(2):7281.Google Scholar
Fent, G, Blythe, J, Farooq, O, et al. In situ simulation as a tool for patient safety: A systematic review identifying how it is used and its effectiveness. BMJ Simulation & Technology Enhanced Learning. 2015;1(3):103110.CrossRefGoogle Scholar
Alfredsdottir, H and Bjornsdottir, K. Nursing and patient safety in the operating room. Journal of Advanced Nursing. 2008;61(1):2937.CrossRefGoogle Scholar
Riley, W, Davis, S, Miller, KM, et al. Detecting breaches in defensive barriers using in situ simulation for obstetric emergencies. Quality & Safety in Health Care. 2010;19(suppl 3):i53–i56.CrossRefGoogle Scholar
Wetzel, EA, Land, TR, Pendergrass, TL, et al. Identification of latent safety threats using high-fidelity simulation-based training with multidisciplinary neonatology teams. Joint Commission Journal on Quality and Patient Safety. 2013;39(6):268273.CrossRefGoogle Scholar
Huang, GC, Smith, CC, Gordon, CE, et al. Beyond the comfort zone: Residents assess their comfort performing inpatient medical procedures. American Journal of Medicine. 2006;119(1):71.e17–71.e24.CrossRefGoogle Scholar
Deering, S, Poggi, S, Macedonia, C, et al. Improving resident competency in the management of shoulder dystocia with simulation training. Obstetrics & Gynecology. 2004;103(6):12241228.Google Scholar
Draycott, TJ, Crofts, JF, Ash, JP, et al. Improving neonatal outcome through practical shoulder dystocia training. Obstetrics & Gynecology. 2008;112(1):1420.Google Scholar
Evans, LV, Dodge, KL, Shah, TD, et al. Simulation training in central venous catheter insertion: Improved performance in clinical practice. Academic Medicine. 2010;85(9):14621469.CrossRefGoogle Scholar
Britt, RC, Novosel, TJ, Britt, LD, et al. The impact of central line simulation before the ICU experience. American Journal of Surgery. 2009;197(4):533536.Google Scholar
Zendejas, B, Cook, DA, Bingener, J, et al. Simulation-based mastery learning improves patient outcomes in laparoscopic inguinal hernia repair: A randomized controlled trial. Annals of Surgery. 2011;254(3):502511.CrossRefGoogle Scholar
Oriol, MD. Crew resource management: Applications in healthcare organizations. Journal of Nursing Administration. 2006;36(9):402406.CrossRefGoogle Scholar
Helmreich, RL, Merritt, AC, Wilhelm, JA. The evolution of Crew Resource Management in training in commercial aviation. International Journal of Aviation Psychology. 1999;9(1):1932.Google Scholar
Andreatta, P, Saxton, E, Thompson, M, et al. Simulation-based mock codes significantly correlate with improved pediatric patient cardiopulmonary arrest survival rates. Pediatric Critical Care Medicine. 2011;12(1):3338.CrossRefGoogle Scholar
Knight, LJ, Gabhart, JM, Earnest, KS, et al. Improving code team performance and survival outcomes: Implementation of pediatric resuscitation team training. Critical Care Medicine. 2014;42(2):243251.CrossRefGoogle Scholar
Riley, W, Davis, S, Miller, K, et al. Didactic and simulation nontechnical skills team training to improve perinatal patient outcomes in a community hospital. Joint Commission Journal on Quality and Patient Safety. 2011;37(8):357364.CrossRefGoogle Scholar

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