Tamaralayefa Agbiki , Richard Arm , David W. Hewson , Sandor Erdody , Andrew M. Norris , Ricardo Correia , Sergiy Korposh , Barrie R. Hayes-Gill , Arash Shahidi , Stephen P. Morgan
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For high-volume low-pressure polyurethane cuffs, much lower leakage rates were observed than polyvinyl chloride cuffs in both models with leakage rates higher for the bio-inspired trachea model (0.1 [0.2] <em>vs</em> 0 [0] ml h<sup>−1</sup>).</p></div><div><h3>Conclusion</h3><p>A reproducible tracheal model that incorporates the mechanical properties of the human trachea can be manufactured from segmented CT images and additive manufactured moulds, providing a useful tool to inform future cuff development, leakage testing for industrial applications, and clinical decision-making. There are differences between cuff leakage rates between the bio-inspired model and the rigid cylinder recommended in EN ISO 5361:2023. The bio-inspired model could lead to more accurate and realistic cuff leakage rate testing which would support manufacturers in refining their designs. 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引用次数: 0
摘要
导言口腔分泌物通过气管导管充气罩囊泄漏是导致呼吸机相关性肺炎的一个因素。麻醉和呼吸设备国际标准》(EN ISO 5361:2023)中规定的当前测试袖带泄漏的台架测试方法涉及使用气管的玻璃或塑料硬质圆柱体模型。我们利用人体计算机断层扫描数据和增材制造(3D 打印)技术,结合铸造技术,制造出具有类似组织特征的生物启发合成气管模型。我们根据 EN ISO 5361:2023 标准进行了充气罩囊泄漏测试,并比较了硬质圆柱体气管与我们的生物启发模型之间的高容量低压聚氯乙烯和聚氨酯充气罩囊的测试结果。对于大容量低压聚氯乙烯袖套,生物启发气管模型的泄漏率比刚性圆柱体模型低 50%(151 [8] vs 261 [11] ml h-1)。对于高容量低压聚氨酯袖带,在两种模型中观察到的泄漏率都比聚氯乙烯袖带低得多,而生物启发气管模型的泄漏率更高(0.1 [0.2] vs 0 [0] ml h-1)。生物启发模型与 EN ISO 5361:2023 推荐的硬质圆柱体之间的袖带泄漏率存在差异。生物启发模型可以带来更准确、更真实的袖带泄漏率测试,从而为制造商改进设计提供支持。这样,临床医生就能根据测试结果选择更好的气管导管。
Fabrication and assessment of a bio-inspired synthetic tracheal tissue model for tracheal tube cuff leakage testing
Introduction
Leakage of orogastric secretions past the cuff of a tracheal tube is a contributory factor in ventilator-associated pneumonia. Current bench test methods specified in the International Standard for Anaesthetic and Respiratory Equipment (EN ISO 5361:2023) to test cuff leakage involve using a glass or plastic rigid cylinder model of the trachea. There is a need for more realistic models to inform cuff leakage.
Methods
We used human computerised tomography data and additive manufacturing (3D printing), combined with casting techniques to fabricate a bio-inspired synthetic tracheal model with analogous tissue characteristics. We conducted cuff leakage tests according to EN ISO 5361:2023 and compared results for high-volume low-pressure polyvinyl chloride and polyurethane cuffs between the rigid cylinder trachea with our bio-inspired model.
Results
The tracheal model demonstrated close agreement with published tracheal tissue hardness for cartilaginous and membranous soft tissues. For high-volume low-pressure polyvinyl chloride cuffs the leakage rate was >50% lower in the bio-inspired tracheal model compared with the rigid cylinder model (151 [8] vs 261 [11] ml h−1). For high-volume low-pressure polyurethane cuffs, much lower leakage rates were observed than polyvinyl chloride cuffs in both models with leakage rates higher for the bio-inspired trachea model (0.1 [0.2] vs 0 [0] ml h−1).
Conclusion
A reproducible tracheal model that incorporates the mechanical properties of the human trachea can be manufactured from segmented CT images and additive manufactured moulds, providing a useful tool to inform future cuff development, leakage testing for industrial applications, and clinical decision-making. There are differences between cuff leakage rates between the bio-inspired model and the rigid cylinder recommended in EN ISO 5361:2023. The bio-inspired model could lead to more accurate and realistic cuff leakage rate testing which would support manufacturers in refining their designs. Clinicians would then be able to choose better tracheal tubes based on the outcomes of this testing.
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