评估与便携式机械通风机配合使用的再呼吸系统。

Q3 Medicine

Journal of special operations medicine : a peer reviewed journal for SOF medical professionals Pub Date : 2024-06-25 DOI:10.55460/9E9N-X3QB

Thomas Blakeman, Maia Smith, Richard Branson

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引用次数: 0

摘要

简介：最大限度地发挥现有低流量氧气的能力是提供充足氧气以预防/治疗低氧血症和节约氧气的关键。我们设计了一种闭路系统，该系统可与便携式机械呼吸机在工作台模型中结合使用，在洗涤二氧化碳（CO2）的同时进行气体再呼吸：我们使用美国国防部目前部署的两台便携式机械呼吸机--Zoll 731 和 AutoMedx SAVe II，在不同的呼吸机设置和肺部模型范围内，使用 1 升/分钟和 3 升/分钟的低流量氧气注入储氧袋，对该系统进行了评估。我们测量了吸入氧峰值浓度（FiO2）、二氧化碳吸收寿命、气体温度和湿度，以及气道吸引和呼吸机断开对地面和高空 FiO2 的影响：在所有呼吸机设置和海拔高度下，使用两种氧气流量，FiO2 均为 =0.9。二氧化碳吸收寿命大于 7 小时。气道湿度范围为 87%-97%。平均气道温度为 25.4°C（SD 0.5°C）。10 秒钟抽吸可使 FiO2 降低 22%-48%。根据所用氧气流量的不同，呼吸机断开 30 秒可使 FiO2 降低 29%-63% ：结论：在使用机械通气的同时使用再通气系统具有节约氧气的潜力，但需要密切监测吸入的 FiO2 和 CO2，以避免不良后果。

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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Evaluation of a Rebreathing System for Use with Portable Mechanical Ventilators.

Introduction: Maximizing the capabilities of available lowflow oxygen is key to providing adequate oxygen to prevent/treat hypoxemia and conserve oxygen. We designed a closed-circuit system that allows rebreathing of gases while scrubbing carbon dioxide (CO2) in conjunction with portable mechanical ventilators in a bench model.

Methods: We evaluated the system using two portable mechanical ventilators currently deployed by the Department of Defense-Zoll 731 and AutoMedx SAVe II-over a range of ventilator settings and lung models, using 1 and 3L/min low-flow oxygen into a reservoir bag. We measured peak inspired oxygen concentration (FiO2), CO2-absorbent life, gas temperature and humidity, and the effect of airway suctioning and ventilator disconnection on FiO2 on ground and at altitude.

Results: FiO2 was =0.9 across all ventilator settings and altitudes using both oxygen flows. CO2-absorbent life was >7 hours. Airway humidity range was 87%-97%. Mean airway temperature was 25.4°C (SD 0.5°C). Ten-second suctioning reduced FiO2 22%-48%. Thirtysecond ventilator disconnect reduced FiO2 29%-63% depending on oxygen flow used.

Conclusion: Use of a rebreathing system with mechanical ventilation has the potential for oxygen conservation but requires diligent monitoring of inspired FiO2 and CO2 to avoid negative consequences.

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来源期刊

Journal of special operations medicine : a peer reviewed journal for SOF medical professionals Medicine-Medicine (all)

CiteScore

1.30

自引率

0.00%

发文量