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Updated: Oct 19, 2025

Creation of a High-Fidelity, Low-Cost, Intraosseous Line Placement Task Trainer via 3D Printing
Published on: August 17, 2022
Leah A Mallory1, Cara B Doughty, Kasey I Davis
1From the Tufts University School of Medicine (L.A.M.), Boston, MA; Department of Medical Education (L.A.M.), The Hannaford Center for Simulation, Innovation and Education; Section of Hospital Medicine (L.A.M.), Department of Pediatrics, The Barbara Bush Children's Hospital at Maine Medical Center, Portland, ME; Section of Emergency Medicine (C.B.D.), Department of Pediatrics, Baylor College of Medicine; Simulation Center (C.B.D.), Texas Children's Hospital, Pediatric Emergency Medicine, Baylor College of Medicine; Section of Critical Care Medicine (K.I.D.), Department of Pediatrics, Baylor College of Medicine, Texas Children's Hospital, Houston, TX; Departments of Pediatrics and Emergency Medicine (A.C.), University of Calgary, Calgary, Canada; Division of Pediatric Critical Care (A.W.C.), University of Louisville School of Medicine and Norton Children's Hospital, Louisville, KY; Section of Emergency Medicine (M.A.A.), Yale University School of Medicine, New Haven, CT; Division of Critical Care (J.P.D.), University of Alberta, Alberta, Canada; and Columbia University Vagelos College of Physicians and Surgeons (D.O.K.), New York, NY.
A decade of progress in pediatric simulation research has been reviewed. Key domains for future growth include prioritization, methodology, collaboration, implementation, technology, and resources, offering lessons for healthcare simulation science.
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