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利用预测单室模型中的损伤成本函数评估机械通气引起的肺损伤的严重程度。

Using injury cost functions from a predictive single-compartment model to assess the severity of mechanical ventilator-induced lung injuries.

机构信息

Department of Bioengineering, University of Colorado Denver , Aurora, Colorado.

College of Medicine, University of Vermont , Burlington, Vermont.

出版信息

J Appl Physiol (1985). 2019 Jul 1;127(1):58-70. doi: 10.1152/japplphysiol.00770.2018. Epub 2019 May 2.

DOI:10.1152/japplphysiol.00770.2018
PMID:31046518
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC6692741/
Abstract

Identifying safe ventilation patterns for patients with acute respiratory distress syndrome remains challenging because of the delicate balance between gas exchange and selection of ventilator settings to prevent further ventilator-induced lung injury (VILI). Accordingly, this work seeks to link ventilator settings to graded levels of VILI to identify injury cost functions that predict injury by using a computational model to process pressures and flows measured at the airway opening. Pressure-volume loops were acquired over the course of ~2 h of mechanical ventilation in four different groups of BALB/c mice. A cohort of these animals were subjected to an injurious bronchoalveolar lavage before ventilation. The data were analyzed with a single-compartment model that predicts recruitment/derecruitment and tissue distension at each time step in measured pressure-volume loops. We compared several injury cost functions to markers of VILI-induced blood-gas barrier disruption. Of the cost functions considered, we conclude that mechanical power dissipation and strain heterogeneity are the best at distinguishing between graded levels of injury and are good candidates for forecasting the development of VILI. This work uses a predictive single-compartment model and injury cost functions to assess graded levels of mechanical ventilator-induced lung injury. The most promising measures include strain heterogeneity and mechanical power dissipation.

摘要

确定急性呼吸窘迫综合征患者的安全通气模式仍然具有挑战性,因为气体交换和选择呼吸机设置以防止进一步的呼吸机引起的肺损伤(VILI)之间存在微妙的平衡。因此,这项工作旨在将呼吸机设置与不同程度的 VILI 联系起来,通过使用计算模型来处理在气道开口处测量的压力和流量,从而确定损伤成本函数来预测损伤。在机械通气过程中约 2 小时内,在 4 组不同的 BALB/c 小鼠中获得了压力-容积环。这些动物中的一部分在通气前接受了损伤性支气管肺泡灌洗。使用预测每个时间步长在测量的压力-容积环中募集/去募集和组织扩张的单室模型对数据进行了分析。我们比较了几种损伤成本函数与 VILI 引起的血-气屏障破坏的标志物。在所考虑的成本函数中,我们得出结论,机械功率耗散和应变异质性在区分不同程度的损伤方面表现最好,是预测 VILI 发展的良好候选者。这项工作使用预测性单室模型和损伤成本函数来评估机械通气引起的肺损伤的分级水平。最有前途的措施包括应变异质性和机械功率耗散。

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