Development and Evaluation of a Three-Dimensional-Printed Pediatric Intraosseous Infusion Simulator To Enhance Medical Training

Wade, Ryan E; McCullum, Brent; Patey, Chris; Dubrowski, Adam

doi:10.7759/cureus.21080

Cited by 2 publications

(1 citation statement)

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“…Alternative do-ityourself (DIY) IO simulators, such as animal bones, lack human anatomical features necessary for optimal learning and pose logistical and ethical concerns related to practicing on animals [6]. To resolve these concerns, additive manufacturing (AM) techniques using three-dimensional (3D) printing and silicone allow for the creation of cost-effective and anatomically realistic simulators for practicing IO infusion in situations where existing IO simulators are difficult to access [6,10,11]. Previously, the development and validation steps of several 3D-printed and silicone-based IO simulators that can be used for this type of training have been described [6].…”

Section: Introductionmentioning

confidence: 99%

Hacking Intraosseous Infusion Skills Training With 3D Printing: maxSIMIO Drilling System

Clarke¹,

Micallef²,

Jolly³

et al. 2022

Cureus

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Intraosseous (IO) infusion is an alternative way to access the vascular system to administer drugs and fluids, which is particularly helpful when the commonly used peripheral intravenous route is inaccessible. The IO procedure can be done using a drill that involves disinfecting the area, landmarking the insertion point, seating the needle in a firm and stable position in the bone, and then delivering a smooth fluid flush. However, in the current medical training landscape, access to commercially available IO drills such as the Arrow® EZ-IO® Power Driver (EZ-IO; Teleflex, Morrisville, North Carolina, United States) is difficult, especially for rural and remote areas, due to the high costs. Furthermore, the EZ-IO is not rechargeable and does not clearly indicate the remaining battery life, which could potentially put patients at risk during the IO procedure. This technical report aims to address these concerns by describing the development of an alternative, affordable, and reliable IO drilling system for training use: the maxSIMIO Drilling System. This system consists of a cordless and rechargeable IKEA screwdriver which connects to a conventional, hexagon-shaped 3D-printed drill bit needle adapter. Two needle adapters were created: Version A was designed to use a friction-based mechanism to couple the screwdriver with the EZ-IO training needle, while Version B relies on a magnetic mechanism. The major differences between the EZ-IO and the screwdriver are that a) the EZ-IO has only one rotation to advance the cannula while the screwdriver features both directions, b) the EZ-IO is not rechargeable while the screwdriver is, and c) the EZ-IO has a custom needle holder that can fit any EZ-IO training needle size while the screwdriver needs to have a custom needle adapter made to connect to the EZ-IO training needle. Overall, through this exploration, the features of the maxSIMIO Drilling System in comparison to the EZ-IO appear more accessible for IO training. Future considerations for this development include gathering clinical expertise through rigorous testing of this novel system.

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