4.7 Article

Non-spherical drug particle deposition in human airway using computational fluid dynamics and discrete element method

Journal

INTERNATIONAL JOURNAL OF PHARMACEUTICS
Volume 639, Issue -, Pages -

Publisher

ELSEVIER
DOI: 10.1016/j.ijpharm.2023.122979

Keywords

DEM-CFD coupling; Human airways; Drug delivery; Non -spherical particles; Particle deposition

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In this study, the transport of non-spherical drug particles in the human airway was analyzed using Weibel's airway model. The results showed that the size, shape, and density of drug particles affected the drug deposition, and the airway geometry also played a role in the deposition. These findings provide important recommendations for the design of drug delivery devices and the treatment of patients receiving pharmaceutical aerosols.
Currently, the air pollution and the respiratory disease problems that affect human health are increasing rapidly. Hence, there is attention for trend prediction of the located deposition of inhaled particles. In this study, Weibel's based human airway model (G0-G5) was employed. The computational fluid dynamics and discrete element method (CFD-DEM) simulation was successfully validated by comparison to the previous research studies. The CFD-DEM achieves a better balance between numerical accuracy and computational requirement when comparing with the other methods. Then, the model was used to analyze the non-spherical drug transport with different drug particle sizes, shapes, density, and concentrations. The results found that all the studied factors affected the drug deposition and particle out-mass percentage except the drug concentration. The drug deposition was increased with the increasing of particle size and particle density due to the influence of particle inertia. The Tomahawk-shaped drug deposited easier than the cylindrical drug shape because of the different drag behavior. For the effect of airway geometries, G0 was the maximum deposited zone and G3 was the minimum deposited zone. The boundary layer was found around bifurcation due to the shear force at the wall. Finally, the knowledge can give an essential recommendation for curing patients with pharmaceutical aerosol. The design suggestion of a proper drug delivery device can be summarized.

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