放射性气溶胶在不同人体呼吸道几何形状中沉积的多物理场计算模型。

Ignacio R. Bartol, Martin S. Graffigna Palomba, Mauricio E. Tano, Shaheen A. Dewji
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引用次数: 0

摘要

对气溶胶暴露的评估依赖于通用数学模型,这些模型假定粒子在人体呼吸道上的沉积剖面是均匀的,而不考虑受试者的具体特征。在这里,我们介绍了一种混合自动化计算工作流程,该流程利用计算流体和粒子动力学模拟,通过计算机断层扫描扫描生成三维重建人体气道中的个性化粒子沉积剖面。这是第一项考虑到现实气道变异性的大规模研究,对 380 个下呼吸道和 40 个上呼吸道三维几何图形进行了重建和参数化。使用随机森林回归法将数据分为九组。在这些具有代表性的几何图形上进行了计算流体和粒子动力学模拟,使用了现实的重呼吸周期和放射性碘-131 作为源项。通过蒙特卡罗辐射传输模拟,获得了详细的能量沉积图。我们的研究结果强调了个性化研究的重要性,因为呼吸道的细微变化会显著影响沉积模式,而不是下呼吸道的整体参数,观察到的质量沉积分数差异超过 30%。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Computational multiphysics modeling of radioactive aerosol deposition in diverse human respiratory tract geometries

Computational multiphysics modeling of radioactive aerosol deposition in diverse human respiratory tract geometries
The evaluation of aerosol exposure relies on generic mathematical models that assume uniform particle deposition profiles over the human respiratory tract and do not account for subject-specific characteristics. Here we introduce a hybrid-automated computational workflow that generates personalized particle deposition profiles in 3D reconstructed human airways from computed tomography scans using Computational Fluid and Particle Dynamics simulations. This is the first large-scale study to consider realistic airways variability, where 380 lower and 40 upper human respiratory tract 3D geometries are reconstructed and parameterized. The data is clustered into nine groups using random forest regression. Computational fluid and particle dynamics simulations are conducted on these representative geometries using a realistic heavy-breathing respiratory cycle and radioactive iodine-131 as a source term. Monte Carlo radiation transport simulations are performed to obtain detailed energy deposition maps. Our findings emphasize the importance of personalized studies, as minor respiratory tract variations notably influence deposition patterns rather than global parameters of the lower airways, observing more than 30% variance in the mass deposition fraction. Shaheen Dewji and colleagues introduce a hybrid-automated computational framework for modelling particles in the human respiratory tract (HRT) with variable geometries. Their method produces patient specific particle deposition profiles that highlights how geometrical characteristics can vary aerosol deposition within the HRT and radiation exposure between patients.
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