Abstract
Characterizing particle deposition in the airways of the human lungs is essential to evaluate the health effects of particulate air pollution. However, lung deposition is rather complicated, and its main influencing factors remain unclear. Hence, this study applied computational fluid dynamics (CFD) to investigate the roles of airflow (Reynolds number [Re] = 100–2000) and particle size (1–10 µm) in deposition using a human tracheobronchial airway model (G3–G6). We calculated the deposition efficiency (DE) based on two mechanisms, inertial impaction (DEi) and gravitational sedimentation (DEg), which produced hot spots around the bifurcations and uniform distributions along the tube, respectively. Furthermore, as the particle size increased, DEi grew rapidly, whereas DEg grew log-linearly. Particles that were less than 2 µm in diameterµ only penetrated deep in the lungs where the airflow rate was low, but 3 µm particles were more likely to settle in this region owing to the combination of gravitational sedimentation and inertial impaction. Larger particles, on the other hand, mainly deposited in the proximal bifurcations as a result of inertial impaction. Additionally, the deposition due to inertial impaction and that due to gravitational sedimentation primarily depended on the Stokes number (St) and the ratio of St to Re2, respectively. The orientation of the human body was another potential factor in the pattern of deposition, although the upright and lateral positions exhibited similar deposition efficiencies for 3 µm particles regardless of Re. These findings identify the critical Reynolds number at which the particle deposition mechanism for a specific size shifts from gravitation to inertia.
Highlights
A predictive understanding of particle transport through bifurcating airways is essential either to optimize therapeutic effects of pharmaceutical aerosols or to minimize harmful effects of toxic aerosol exposure (Patton and Byron, 2007; Finlay and Martin, 2008; Löndahl et al, 2017; Deng et al, 2018)
We found that the particle size and inhalation rate determined the site, amount, and mechanism of deposition, with most of the accumulation occurring on the inner walls of the tubes that were subjected to a higher axial flow rate and stronger inward secondary velocity
Neither inertial impaction nor gravitational sedimentation allowed the size fraction less than 3 μm in diameter to settle in the G3–G6 airways
Summary
A predictive understanding of particle transport through bifurcating airways is essential either to optimize therapeutic effects of pharmaceutical aerosols or to minimize harmful effects of toxic aerosol exposure (Patton and Byron, 2007; Finlay and Martin, 2008; Löndahl et al, 2017; Deng et al, 2018). Particle deposition in human lung is rather complicated (Deng et al, 2019). Particle deposition in human airways is a rather complicated process, and affected by many factors. These factors include particle size and shape, breathing rate, lung volume, and Numerous studies have investigated the effects of mechanisms on particle deposition in human lung airways. Comer et al (1999) found that inertial impaction is important for Copyright The Author(s).
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