粒子沉积对人体肺动力学的计算流体动力学研究:健康肺与纤维化肺的比较

Carlo Carotenuto, L. Scurani, L. Fontanili, L. Montorsi, M. Milani
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引用次数: 0

摘要

肺是由新型冠状病毒SARS-CoV-2引起的严重冠状病毒病(COVID-19)主要影响的人体器官。在这种病理中,动态肺功能和呼吸力学受损,导致ARDS(急性呼吸窘迫综合征)的发展。由此造成的损害是气体交换的逐渐减少和最危重患者的死亡。由于这些原因,研究和分析这种病毒如何对肺动力学产生不利影响是很重要的。本文的主要目的是提出一种SARS-CoV-2病毒颗粒在第23代肺树中传播的建模方法,以及以肺纤维化为特征的Covid-19严重阶段如何影响肺泡囊扩张从而影响患者呼吸能力的机械估计。在此背景下,通过数值方法,对实际条件下SARS-CoV-2传播对人体肺部影响的动态分析。因此,通过多相三维计算流体动力学(CFD)研究估算了第23代支气管树的简化模型中Covid-19病毒颗粒在肺泡区域的分散情况。然后,结合网格变形技术和固体位移特性,采用完全耦合流固耦合(FSI)方法获得肺泡囊膨胀过程中真实的壁面位移。对健康的肺和患病的肺进行比较。该分析的新颖之处在于:首先,提出了创新的CFD方法,以模拟在肺泡区域内扩散的颗粒;其次,评估了Sars-Cov-2的存在如何影响感染晚期患者(例如肺纤维化患者)的肺泡囊的力学特性和肺功能的损害。
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Computational Fluid Dynamics Study of Particle Deposition On Human Lung Dynamic: A Comparison Between the Healthy and Fibrotic Lung
The lung is the human organ mainly affected by severe coronavirus disease (COVID-19) caused by the novel coronavirus SARS-CoV-2. In this pathology, the dynamic lung function and the respiratory mechanics are compromised, leading to the development of the ARDS (acute respiratory distress syndrome). The resulting damage is the progressive reduction of gas exchange and death in the most critical patients. For these reasons, it is important to study and analyze how this virus adversely affects lung dynamics. The main objective of the present paper is to propose a modeling methods of SARS-CoV-2 virus particles spread in the 23rd generation of lung tree and the mechanical estimation of how a severe stage of Covid-19 characterized by pulmonary fibrosis affects the alveolar sac expansion and hence the breathing capability of the sick person. In this context, the dynamic analysis of the influence of SARS-CoV-2 spread on human lung under real conditions has been shown by means of a numerical approach. Therefore, a multiphase three-dimensional computational fluid dynamics (CFD) study is performed to estimate the Covid-19 virus particles dispersion throughout a simplify model of the 23rd generation of bronchial tree, at the alveolar region. Then, a fully coupled fluid-structure interaction (FSI) with the mesh morphing technique and solid displacement characteristics are used to obtain and evaluate a realistic wall displacement during the expansion of the alveolar sac. A comparison is made between a healthy and a diseased lung. These phases are studied under cyclic steady-state conditions The novelties of this analysis are: firstly, the innovative CFD method proposed in order to model the particles spread inside the alveolar region, and secondly the evaluation of how the presence of Sars-Cov-2 can affect the mechanical properties of the alveolar sac and damage the lung function of a sick person at an advanced stage of infection, such as a person affected by pulmonary fibrosis.
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