Abstract
Dry powder inhalations (DPIs) have gathered attention as a treatment for respiratory diseases due to the large effective absorption area in a human lung. A cascade impactor is generally used to investigate the inhalation performance of DPIs. For the improvement of the efficiency of DPIs, understanding the particle motion and deposition behavior in the human lung and the cascade impactor is required. In the present study, computer simulations were conducted to calculate the particle motion and deposition behavior in the human lung and the cascade impactor. As simulation methods, a coupling model of a computational fluid dynamics and a discrete phase method (CFD−DPM) and a coupling model of a CFD and a discrete element method (CFD−DEM) were used. The CFD−DEM simulation could reproduce the experimental particle deposition behavior in the cascade impactor, although it was difficult by the CFD−DPM simulation. Furthermore, the calculation results using the CFD−DEM simulation quantitatively demonstrated the higher particle reachability into the simple lung model when smaller particles were used. It was found that the CFD−DEM simulation is a powerful tool to calculate the particle motion and deposition behavior in the cascade impactor and human lung.
Highlights
Dry powder inhalations (DPIs) are a dosage form for delivering powdered medicine to the human lungs by an inhaled airflow of patients, and it is mainly used as a treatment for respiratory diseases such as bronchial asthma and chronic obstructive lung disease (Islam and Gladki, 2008)
The present study proposed the usage of a coupling model of a computational fluid dynamics and a discrete phase method (CFD−DPM) and a coupling model of a CFD and a discrete element method (CFD−DEM)
The 20 μm particles showed high arrival ratios to Zone-2 and Zone-5, while 5 μm particles showed the highest arrival ratio to Zone-6. This would be because the large particles transported in the direction of gravity regardless of the fluid dynamics, while the small particle motions agreed with the fluid flow
Summary
Dry powder inhalations (DPIs) are a dosage form for delivering powdered medicine to the human lungs by an inhaled airflow of patients, and it is mainly used as a treatment for respiratory diseases such as bronchial asthma and chronic obstructive lung disease (Islam and Gladki, 2008). Main factors affecting the deposition site in the human respiratory system are the particle properties (size, density, and shape). The design of DPIs for the effective transportation in the human respiratory system has been investigated, in which a cascade impactor is generally used to evaluate the particle reachability into the human lung (Kaialy et al, 2012). Understanding particle motion and deposition behavior in a respiratory system and a cascade impactor is necessary to improve the efficiency of DPIs. The present study proposed the usage of a coupling model of a computational fluid dynamics and a discrete phase method (CFD−DPM) and a coupling model of a CFD and a discrete element method (CFD−DEM). A cascade impactor model and a simple lung model were constructed to calculate the behavior of the fluid and particle transportation
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