对 Laerdal 气道训练器进行新颖的再利用,以模拟气溶胶作用。

IF 1.1 Q2 Social Sciences BMJ Simulation & Technology Enhanced Learning Pub Date : 2021-03-18 eCollection Date: 2021-01-01 DOI:10.1136/bmjstel-2020-000802
Sven Peter Oman, Scott Helgeson, Philip Lowman, Pablo Moreno Franco, Jonathan Tomshine, Neal Patel, Bhavesh Patel, Devang Sanghavi
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引用次数: 0

摘要

在美国,COVID-19 已夺去了 20 多万人的生命,并将医护人员置于危险之中。在气管插管等产生气溶胶的操作过程中,医护人员的暴露风险会增加。丙烯酸盒和水平塑料帘等新的屏障设计已经出现,以减少接触空气中的微粒。测试气溶胶产生程序(AGP)屏障设计需要气溶胶产生模型。为此,我们制作了一个气溶胶模型,该模型能产生可见的、可测量的、SARS-CoV-2 可携带的、可插管的微粒。该模型是使用 Laerdal 气道管理训练器(Laerdal Medical,挪威斯塔万格)结合雾化器和 Ambu 袋阀复苏器(Ambu,美国马里兰州哥伦比亚)制作的。溶解在生理盐水中的雾化 Glo Germ(Glo Germ,美国犹他州摩阿布)通过管道移动,并通过压缩 Ambu 袋从人体模型的口中流出。在紫外光下观察雾化情况,并用粒子计数器测量 0.3 至 10.0 μm 之间的粒子数量。可以看到雾化从人体模型的口中流出。在紫外线下可看到雾化的 Glo Germ 在环境空气中移动。粒径在 0.3-0.5 微米范围内的颗粒增加了 20 倍,粒径在 1-10 微米范围内的颗粒增加了 10 252%。SARS-CoV-2 可以通过气溶胶和液滴微粒传播,因此需要建立微粒生成模型,以直观显示和测量暴露区域以及微粒在 AGP 期间的移动路径。我们利用现有的医疗和模拟用品创建了一个粒子模拟器。
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Novel repurposing of a Laerdal Airway trainer to simulate aerosolisation.

COVID-19 has claimed over 200 000 lives in the USA and put healthcare workers at risk. Healthcare workers have an increased exposure risk from aerosol-generating procedures such as endotracheal intubation. New barrier designs such as the acrylic box and horizontal plastic drape have emerged to reduce exposure to airborne particles. Particle generating models are needed to test aerosol generating procedure (AGP) barrier designs. To achieve this, an aerosol model that generates a visible and measurable increase in particles which SARS-CoV-2 could travel on and that can also be intubated was created. The model was created using a Laerdal Airway Management Trainer (Laerdal Medical, Stavanger, Norway) combined with a nebuliser and Ambu bag-valve resuscitator (Ambu, Columbia, Maryland, USA). Nebulised Glo Germ (Glo Germ, Moab, Utah, USA) dissolved in saline solution was moved through the tubing and out of the mannequin's mouth with compression of the Ambu bag. This nebulisation was visualised under ultraviolet light and the quantity of particles between 0.3 and 10.0 μm was measured with a particle counter. Nebulisation was visible exiting the mouth of the mannequin. Nebulised Glo Germ was visualised under ultraviolet light moving in the ambient air. Particles in the size range of 0.3-0.5 µm increased by 20-fold and 1-10 µm increased by 10 252%. SARS-CoV-2 can travel on aerosol and droplet particles and particle generating models are needed to visualise and measure exposure areas and the path particles take during AGPs. We used existing medical and simulation supplies to create a particle simulator.

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BMJ Simulation & Technology Enhanced Learning
BMJ Simulation & Technology Enhanced Learning HEALTH CARE SCIENCES & SERVICES-
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