BACKGROUND: Fluid dynamics theory, which is a fundamental underlying concept applied to fluid management, has not been introduced to analyze the human respiratory system. We hypothesized that one of the potential mechanisms that promotes airflow limitation in patients with airway obstructive disease would be elucidated by using fluid dynamics theory. METHODS: We calculated the values of pressure loss and static pressure change under virtual tracheal stenotic conditions using the fluid dynamics approach. RESULTS: Under normal conditions, the absolute values of pressure loss and static pressure change are very low. However, once airway stenosis occurs, it is confirmed that they would be dramatically elevated. CONCLUSIONS: The fluid dynamics approach to airway obstruction is very constructive. The treatment strategy for airway obstruction and the reasons for airflow limitation are well explained by using this approach.
BACKGROUND: Fluid dynamics theory, which is a fundamental underlying concept applied to fluid management, has not been introduced to analyze the human respiratory system. We hypothesized that one of the potential mechanisms that promotes airflow limitation in patients with airway obstructive disease would be elucidated by using fluid dynamics theory. METHODS: We calculated the values of pressure loss and static pressure change under virtual tracheal stenotic conditions using the fluid dynamics approach. RESULTS: Under normal conditions, the absolute values of pressure loss and static pressure change are very low. However, once airway stenosis occurs, it is confirmed that they would be dramatically elevated. CONCLUSIONS: The fluid dynamics approach to airway obstruction is very constructive. The treatment strategy for airway obstruction and the reasons for airflow limitation are well explained by using this approach.
Authors: Parth Singh; Vishnu Raghav; Vignesh Padhmashali; Gunther Paul; Mohammad S Islam; Suvash C Saha Journal: Int J Environ Res Public Health Date: 2020-02-10 Impact factor: 3.390