The effect of oral and nasal breathing on the deposition of inhaled particles in upper and tracheobronchial airways

journal article in Web of Science

English

The inhalation route has a substantial influence on the fate of inhaled particles. An outbreak of infectious diseases such as COVID-19, influenza or tuberculosis depends on the site of deposition of the inhaled pathogens. But the knowledge of respiratory deposition is important also for occupational safety or targeted delivery of inhaled pharmaceuticals. Simulations utilizing computational fluid dynamics are becoming available to a wide spectrum of users and they can undoubtedly bring detailed predictions of regional deposition of particles. However, if those simulations are to be trusted, they must be validated by experimental data. This article presents simulations and experiments performed on a geometry of airways which is available to other users and thus those results can be used for intercomparison between different research groups. In particular, three hypotheses were tested. First: Oral breathing and combined breathing are equivalent in terms of particle deposition in TB airways, as the pressure resistance of the nasal cavity is so high that the inhaled aerosol flows mostly through the oral cavity in both cases. Second: The influence of the inhalation route (nasal, oral or combined) on the regional distribution of the deposited particles downstream of the trachea is negligible. Third: Simulations can accurately and credibly predict deposition hotspots. The maximum spatial resolution of predicted deposition achievable by current methods was searched for. The simulations were performed using large-eddy simulation, the flow measurements were done by laser Doppler anemometry and the deposition has been measured by positron emission tomography in a realistic replica of human airways. Limitations and sources of uncertainties of the experimental methods were identified. The results confirmed that the high-pressure resistance of the nasal cavity leads to practically identical velocity profiles, even above the glottis for the mouth, and combined mouth and nose breathing. The distribution of deposited particles downstream of the trachea was not influenced by the inhalation route. The carina of the first bifurcation was not among the main deposition hotspots regardless of the inhalation route or flow rate. On the other hand, the deposition hotspots were identified by both CFD and experiments in the second bifurcation in both lungs, and to a lesser extent also in both the third bifurcations in the left lung.

Computational fluid mechanics; Numerical simulations; Particle deposition; Positron emission tomography; Laser Doppler anemometry; Flow; Airways; Lungs; Deposition hotspots

LÍZAL, F.; ELCNER, J.; JEDELSKÝ, J.; MALÝ, M.; JÍCHA, M.; FARKAS, Á.; BĚLKA, M.; REHAK, Z.; ADAM, J.; LÁZŇOVSKÝ, J.; KAISER, J.; BŘÍNEK, A.; ZIKMUND, T.

1. 12. 2020

ELSEVIER SCI LTD

OXFORD

0021-8502

JOURNAL OF AEROSOL SCIENCE

150

105649

United Kingdom of Great Britain and Northern Ireland

1

23

23

https://www.ncbi.nlm.nih.gov/pmc/articles/PMC7455204/