三维打印呼吸机多路复用器 Vent-Lock 展示了在资源有限的环境下的转化设计。

IF 3.2 Q1 RADIOLOGY, NUCLEAR MEDICINE & MEDICAL IMAGING
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
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引用次数: 0

摘要

背景:机械呼吸机对于急性呼吸窘迫综合征(ARDS)重症患者至关重要,而新型严重急性呼吸系统综合征冠状病毒 2(SARS-CoV-2)的出现导致了机械呼吸机的短缺:我们利用三维打印(3DP)技术快速制作并测试了新型呼吸机多路复用系统 Vent-Lock 的关键部件原型,该系统可将一台呼吸机或麻醉气体机分给两名患者使用。新型 3DP 限流器 FloRest 可让临床医生控制潮气量和呼气末正压 (PEEP),并使用 3DP 压力计适配器监测压力。我们在模拟中心测试了人工肺之间的呼吸机分流电路,并使用麻醉气体机成功地为两头猪进行了通气:作为首批在两头猪之间拆分一台麻醉气体机的研究之一,我们提出了一个全新、封闭、多路复用系统的概念验证,该系统具有流量限制功能,可对患者进行个性化治疗:结论:呼吸机多路复用虽然可行,但由于其复杂性、对经验丰富的操作人员的要求以及相关风险,只能在没有其他选择的紧急情况下使用。我们的报告强调了在资源有限的环境中通过三维打印技术快速制作医疗设备原型所需的初始设计和工程考虑因素,包括设计、材料选择、生产和配送方面的考虑因素。我们注意到,工程优化可以最大限度地降低 3D 打印的生产风险,但可能无法解决设备的固有风险或改变其适应症。因此,我们的病例报告为未来医疗设备的快速原型设计提供了启示。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Translational design for limited resource settings as demonstrated by Vent-Lock, a 3D-printed ventilator multiplexer.

Translational design for limited resource settings as demonstrated by Vent-Lock, a 3D-printed ventilator multiplexer.

Translational design for limited resource settings as demonstrated by Vent-Lock, a 3D-printed ventilator multiplexer.

Translational design for limited resource settings as demonstrated by Vent-Lock, a 3D-printed ventilator multiplexer.

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.

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