Airflow inside the nasal cavity: visualization using computational fluid dynamics

Zubair, Mohammed; Riazuddin, Vizy Nazira; Abdullah, Mohammed Zulkifly; Ismail, Rushdan; Shuaib, Ibrahim Lutfi; Hamid, Suzina Abdul; Ahmad, Kamarul Arifin

doi:10.2478/abm-2010-0085

Abstract

Background: It is of clinical importance to examine the nasal cavity pre-operatively on surgical treatments. However, there is no simple and easy way to measure airflow in the nasal cavity. Objectives: Visualize the flow features inside the nasal cavity using computational fluid dynamics (CFD) method, and study the effect of different breathing rates on nasal function. Method: A three-dimensional nasal cavity model was reconstructed based on computed tomographic images of a healthy Malaysian adult nose. Navier-Stokes and continuity equations for steady airflow were solved numerically to examine the inspiratory nasal flow. Results: The flow resistance obtained varied from 0.026 to 0.124 Pa.s/mL at flow-rate from 7.5 L/min to 40 L/min. Flow rates by breathing had significant influence on airflow velocity and wall shear-stress in the vestibule and nasal valve region. Conclusion: Airflow simulations based on CFD is most useful for better understanding of flow phenomenon inside the nasal cavity.

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Airflow inside the nasal cavity: visualization using computational fluid dynamics

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