Translational Design for Limited Resource Settings As Demonstrated by Vent-Lock, a 3D-printed Ventilator Multiplexer

Overview

Journal 3D Print Med

Publisher Biomed Central

Date 2022 Sep 14

PMID 36102998

Authors

Helen Xun

Christopher Shallal

Justin Unger

Runhan Tao

Alberto Torres

Michael Vladimirov

Jenna Frye

Mohit Singhala

Brockett Horne

Bo Soo Kim

Broc Burke

Michael Montana

Michael Talcott

Bradford Winters

Margaret Frisella

Bradley S Kushner

Justin M Sacks

James K Guest

Sung Hoon Kang

Julie Caffrey

Affiliations

Soon will be listed here.

Abstract

Background: Mechanical ventilators are essential to patients who become critically ill with acute respiratory distress syndrome (ARDS), and shortages have been reported due to the novel severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2).

Methods: We utilized 3D printing (3DP) technology to rapidly prototype and test critical components for a novel ventilator multiplexer system, Vent-Lock, to split one ventilator or anesthesia gas machine between two patients. FloRest, a novel 3DP flow restrictor, provides clinicians control of tidal volumes and positive end expiratory pressure (PEEP), using the 3DP manometer adaptor to monitor pressures. We tested the ventilator splitter circuit in simulation centers between artificial lungs and used an anesthesia gas machine to successfully ventilate two swine.

Results: As one of the first studies to demonstrate splitting one anesthesia gas machine between two swine, we present proof-of-concept of a de novo, closed, multiplexing system, with flow restriction for potential individualized patient therapy.

Conclusions: While possible, due to the complexity, need for experienced operators, and associated risks, ventilator multiplexing should only be reserved for urgent situations with no other alternatives. Our report underscores the initial design and engineering considerations required for rapid medical device prototyping via 3D printing in limited resource environments, including considerations for design, material selection, production, and distribution. We note that optimization of engineering may minimize 3D printing production risks but may not address the inherent risks of the device or change its indications. Thus, our case report provides insights to inform future rapid prototyping of medical devices.

Citing Articles

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Medical 3D Printing Using Desktop Inverted Vat Photopolymerization: Background, Clinical Applications, and Challenges.

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