From intra- to extra-uterine: early phase design of a transfer to extra-uterine life support through medical simulation.

IF 2.7 Q3 ENGINEERING, BIOMEDICAL Frontiers in medical technology Pub Date : 2024-08-20 eCollection Date: 2024-01-01 DOI:10.3389/fmedt.2024.1371447

J S van Haren, F L M Delbressine, M Monincx, T Hoveling, N Meijer, C Bangaru, J Sterk, D A A van der Woude, S G Oei, M B van der Hout-van der Jagt

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Abstract

Introduction: Extra-uterine life support technology could provide a more physiologic alternative for the treatment of extremely premature infants, as it allows further fetal growth and development ex utero. Animal studies have been carried out which involved placing fetuses in a liquid-filled incubator, with oxygen supplied through an oxygenator connected to the umbilical vessels. Hence, by delaying lung exposure to air, further lung development and maturation can take place. This medical intervention requires adjustments to current obstetric procedures to maintain liquid-filled lungs through a so-called transfer procedure.

Methods: Our objective was to develop obstetric device prototypes that allow clinicians to simulate this birth procedure to safely transfer the infant from the mother's uterus to an extra-uterine life support system. To facilitate a user-centered design, implementation of medical simulation during early phase design of the prototype development was used. First, the requirements for the procedure and devices were established, by reviewing the literature and through interviewing direct stakeholders. The initial transfer device prototypes were tested on maternal and fetal manikins in participatory simulations with clinicians.

Results & discussion: Through analysis of recordings of the simulations, the prototypes were evaluated on effectiveness, safety and usability with latent conditions being identified and improved. This medical simulation-based design process resulted in the development of a set of surgical prototypes and allowed for knowledge building on obstetric care in an extra-uterine life support context.

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从宫内到宫外：通过医学模拟进行向宫外生命支持转移的早期阶段设计。

前言宫外生命支持技术可为极早产儿的治疗提供一种更符合生理学原理的替代方法，因为它允许胎儿在宫外进一步生长发育。已开展的动物实验将胎儿置于充满液体的培养箱中，通过连接脐带血管的供氧器向胎儿供氧。因此，通过延迟肺部与空气的接触，可以使肺部进一步发育和成熟。这种医疗干预措施需要调整目前的产科程序，通过所谓的转移程序来维持充满液体的肺：我们的目标是开发产科设备原型，让临床医生能够模拟这种分娩过程，将婴儿从母亲的子宫安全转移到宫外生命支持系统。为促进以用户为中心的设计，在原型开发的早期设计阶段采用了医学模拟。首先，通过查阅文献和采访直接利益相关者，确定了对手术和设备的要求。在临床医生的参与式模拟中，在母体和胎儿人体模型上测试了最初的转移装置原型：结果与讨论：通过分析模拟试验的记录，对原型的有效性、安全性和可用性进行了评估，并确定和改进了潜在的条件。通过这一基于医学模拟的设计过程，开发出了一套手术原型，并积累了宫外生命支持背景下的产科护理知识。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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