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CARETestLung:一种具有可配置气道阻力、肺弹性和呼吸努力的机械测试肺。

CARETestLung: A mechanical test lung with Configurable airway Resistance, lung Elastance, and breathing efforts.

作者信息

Yang Tay Wei, Yew Shuen Ang Christopher, Shiong Chiew Yeong, Geoffrey Chase J

机构信息

Monash University Malaysia, Jalan Lagoon Selatan, Bandar Sunway, 47500 Subang Jaya, Selangor, Malaysia.

Department of Mechanical Engineering, University of Canterbury, Christchurch 8041, New Zealand.

出版信息

HardwareX. 2024 Aug 28;19:e00579. doi: 10.1016/j.ohx.2024.e00579. eCollection 2024 Sep.

DOI:10.1016/j.ohx.2024.e00579
PMID:39318641
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11419886/
Abstract

A mechanical test lung is a crucial tool in accurately simulating patient-specific physiological responses of patients undergoing mechanical ventilation (MV), which, in turn, offer clinicians insight into lung mechanics during MV. In particular, it can be used to facilitate better methods to identify optimal ventilator settings, modes for individual patients by providing a platform to experiment with different MV settings. This addresses the challenge of optimising MV settings caused by variability in pathological conditions and the progression of respiratory disease over time within patients. However, the accessibility and cost of versatile test lungs limit widespread adoption in clinical settings, underscoring the need for affordable alternatives. This paper presents detailed instructions for the design and construction of a replicable, cost-effective mechanical test lung. The design features 3 subsystems: 1) the lung compartment; 2) the airway; and 3) a spontaneous breathing system. A detailed tests series shows its ability to replicate clinically realistic lung elastance values ranging from 25 to 85 cmHO/L and airway resistance values from 10 to 45 cmHO·s/L. It can also simulate a range of clinically realistic spontaneous breathing patterns. These capabilities yield pressure and flow ventilation data comparable to certified clinical test lungs across diverse scenarios, as well as matching clinically observed behaviours and dynamics. This accessible and versatile test lung offers valuable opportunities for optimising MV settings and advancing patient care, as well as its use in developing a range of physiological models for model-based decision support.

摘要

机械测试肺是准确模拟接受机械通气(MV)患者特定生理反应的关键工具,这反过来又能让临床医生深入了解机械通气期间的肺力学。特别是,它可用于通过提供一个试验不同机械通气设置的平台,促进更好地确定个体患者最佳通气设置和模式的方法。这解决了因患者病理状况的变异性和呼吸系统疾病随时间的进展而导致的优化机械通气设置的挑战。然而,通用测试肺的可及性和成本限制了其在临床环境中的广泛应用,凸显了对经济实惠替代品的需求。本文介绍了一种可复制、经济高效的机械测试肺的设计和构建的详细说明。该设计具有3个子系统:1)肺腔室;2)气道;3)自主呼吸系统。一系列详细测试表明,它能够复制临床实际的肺弹性值,范围从25到85 cmH₂O/L,气道阻力值从10到45 cmH₂O·s/L。它还可以模拟一系列临床实际的自主呼吸模式。这些能力在各种情况下产生的压力和流量通气数据与经过认证的临床测试肺相当,并且与临床观察到的行为和动态相匹配。这种易于使用且通用的测试肺为优化机械通气设置和推进患者护理提供了宝贵机会,以及在开发一系列基于模型的决策支持生理模型中的应用。

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