Thornton Mu 1 , Tricia Garcia-Choudary 2 , Amanda Staudt 2 , Melissa Tyree 3 , Krystal Valdez-Delgado 2 , Nicole Caldwell 2 , Nicholas Carr 1 , Matthew Borgman 1 , Heather Delaney 4 Show Affiliations »
Abstract
Introduction: Extracorporeal membrane oxygenation (ECMO) is a classic low-volume high-risk procedure that requires just in time and/or refresher training through animal or simulation modalities. This manuscript evaluated the performance of ECMO personnel trained with both modalities to determine which is better suited for ECMO skills training. Methods: Participants (physicians, nurses and respiratory/medical technicians) completed a series of ECMO scenarios with synthetic tissue cannulation task trainer as well as a live tissue model. Objective performance quality was based on task completion using a validated ECMO skills assessment tool. Results: Thirty-eight individuals completed this study. Participants completed individual scenario tasks 3 min faster using the simulator (26 min vs 29 min; p=0.03). No differences were seen in percentage of individual tasks completed. In the group scenarios, participants completed a higher percentage of critical tasks using the simulator (97%) versus the animal model (91%; p=0.05), but no differences were seen in task completion times. Additionally, no differences were seen in either lab-based or participants' prelab cognitive scores. Conclusions: Regardless of their self-assessment or experience, participants' objective performances were similar among both animal and simulation labs. Task completion times were quicker with simulation model. The distinction between simulation versus animal model may be less important as both demonstrate benefit in development of and/or maintaining skill competency. In the era of questioning the need for and costs of live tissue training, expanding the role of simulation may achieve similar training goals. © Author(s) (or their employer(s)) 2021. No commercial re-use. See rights and permissions. Published by BMJ.
Introduction: Extracorporeal membrane oxygenation (ECMO) is a classic low-volume high-risk procedure that requires just in time and/or refresher training through animal or simulation modalities. This manuscript evaluated the performance of ECMO personnel trained with both modalities to determine which is better suited for ECMO skills training. Methods: Participants (physicians, nurses and respiratory/medical technicians) completed a series of ECMO scenarios with synthetic tissue cannulation task trainer as well as a live tissue model. Objective performance quality was based on task completion using a validated ECMO skills assessment tool. Results: Thirty-eight individuals completed this study. Participants completed individual scenario tasks 3 min faster using the simulator (26 min vs 29 min; p=0.03). No differences were seen in percentage of individual tasks completed. In the group scenarios, participants completed a higher percentage of critical tasks using the simulator (97%) versus the animal model (91%; p=0.05), but no differences were seen in task completion times. Additionally, no differences were seen in either lab-based or participants' prelab cognitive scores. Conclusions: Regardless of their self-assessment or experience, participants' objective performances were similar among both animal and simulation labs. Task completion times were quicker with simulation model. The distinction between simulation versus animal model may be less important as both demonstrate benefit in development of and/or maintaining skill competency. In the era of questioning the need for and costs of live tissue training, expanding the role of simulation may achieve similar training goals. © Author(s) (or their employer(s)) 2021. No commercial re-use. See rights and permissions. Published by BMJ.
Entities: Chemical
Keywords:
High fidelity simulation; infant, newborn; interprofessional education; procedural skills training; procedure based assessments
Year: 2020
PMID: 35516819 PMCID: PMC8936557 DOI: 10.1136/bmjstel-2020-000682
Source DB: PubMed Journal: BMJ Simul Technol Enhanc Learn ISSN: 2056-6697