Airflow limitation in a collapsible model of the human pharynx: physical mechanisms studied with fluid‐structure interaction simulations and experiments
Abstract The classical Starling Resistor model has been the paradigm of airway collapse in obstructive sleep apnea (OSA) for the last 30 years. Its theoretical framework is grounded on the wave‐speed flow limitation (WSFL) theory. Recent observations of negative effort dependence in OSA patients vio...
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| Series: | Physiological Reports |
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| Online Access: | https://doi.org/10.14814/phy2.14099 |
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doaj-04cc15d156fb4390a0bae74f80946b352020-11-25T03:50:04ZengWileyPhysiological Reports2051-817X2019-05-01710n/an/a10.14814/phy2.14099Airflow limitation in a collapsible model of the human pharynx: physical mechanisms studied with fluid‐structure interaction simulations and experimentsTrung B. Le0Masoud G. Moghaddam1B. Tucker Woodson2Guilherme J. M. Garcia3Department of Biomedical Engineering Marquette University & The Medical College of Wisconsin Milwaukee WisconsinDepartment of Biomedical Engineering Marquette University & The Medical College of Wisconsin Milwaukee WisconsinDepartment of Otolaryngology and Communication Sciences Medical College of Wisconsin Milwaukee WisconsinDepartment of Biomedical Engineering Marquette University & The Medical College of Wisconsin Milwaukee WisconsinAbstract The classical Starling Resistor model has been the paradigm of airway collapse in obstructive sleep apnea (OSA) for the last 30 years. Its theoretical framework is grounded on the wave‐speed flow limitation (WSFL) theory. Recent observations of negative effort dependence in OSA patients violate the predictions of the WSFL theory. Fluid‐structure interaction (FSI) simulations are emerging as a technique to quantify how the biomechanical properties of the upper airway determine the shape of the pressure‐flow curve. This study aimed to test two predictions of the WSFL theory, namely (1) the pressure profile upstream from the choke point becomes independent of downstream pressure during flow limitation and (2) the maximum flowrate in a collapsible tube is VImax=A3/2(ρdA/dP)−1/2, where ρ is air density and A and P are the cross‐sectional area and pressure at the choke point respectively. FSI simulations were performed in a model of the human upper airway with a collapsible pharynx whose wall thickness varied from 2 to 8 mm and modulus of elasticity ranged from 2 to 30 kPa. Experimental measurements in an airway replica with a silicone pharynx validated the numerical methods. Good agreement was found between our FSI simulations and the WSFL theory. Other key findings include: (1) the pressure‐flow curve is independent of breathing effort (downstream pressure vs. time profile); (2) the shape of the pressure‐flow curve reflects the airway biomechanical properties, so that VImax is a surrogate measure of pharyngeal compliance.https://doi.org/10.14814/phy2.14099Airflow limitationfluid‐structure interaction simulations and experimentsobstructive sleep apneaStarling Resistor biomechanical model of airway collapsewave‐speed flow limitation theory |
| collection |
DOAJ |
| language |
English |
| format |
Article |
| sources |
DOAJ |
| author |
Trung B. Le Masoud G. Moghaddam B. Tucker Woodson Guilherme J. M. Garcia |
| spellingShingle |
Trung B. Le Masoud G. Moghaddam B. Tucker Woodson Guilherme J. M. Garcia Airflow limitation in a collapsible model of the human pharynx: physical mechanisms studied with fluid‐structure interaction simulations and experiments Physiological Reports Airflow limitation fluid‐structure interaction simulations and experiments obstructive sleep apnea Starling Resistor biomechanical model of airway collapse wave‐speed flow limitation theory |
| author_facet |
Trung B. Le Masoud G. Moghaddam B. Tucker Woodson Guilherme J. M. Garcia |
| author_sort |
Trung B. Le |
| title |
Airflow limitation in a collapsible model of the human pharynx: physical mechanisms studied with fluid‐structure interaction simulations and experiments |
| title_short |
Airflow limitation in a collapsible model of the human pharynx: physical mechanisms studied with fluid‐structure interaction simulations and experiments |
| title_full |
Airflow limitation in a collapsible model of the human pharynx: physical mechanisms studied with fluid‐structure interaction simulations and experiments |
| title_fullStr |
Airflow limitation in a collapsible model of the human pharynx: physical mechanisms studied with fluid‐structure interaction simulations and experiments |
| title_full_unstemmed |
Airflow limitation in a collapsible model of the human pharynx: physical mechanisms studied with fluid‐structure interaction simulations and experiments |
| title_sort |
airflow limitation in a collapsible model of the human pharynx: physical mechanisms studied with fluid‐structure interaction simulations and experiments |
| publisher |
Wiley |
| series |
Physiological Reports |
| issn |
2051-817X |
| publishDate |
2019-05-01 |
| description |
Abstract The classical Starling Resistor model has been the paradigm of airway collapse in obstructive sleep apnea (OSA) for the last 30 years. Its theoretical framework is grounded on the wave‐speed flow limitation (WSFL) theory. Recent observations of negative effort dependence in OSA patients violate the predictions of the WSFL theory. Fluid‐structure interaction (FSI) simulations are emerging as a technique to quantify how the biomechanical properties of the upper airway determine the shape of the pressure‐flow curve. This study aimed to test two predictions of the WSFL theory, namely (1) the pressure profile upstream from the choke point becomes independent of downstream pressure during flow limitation and (2) the maximum flowrate in a collapsible tube is VImax=A3/2(ρdA/dP)−1/2, where ρ is air density and A and P are the cross‐sectional area and pressure at the choke point respectively. FSI simulations were performed in a model of the human upper airway with a collapsible pharynx whose wall thickness varied from 2 to 8 mm and modulus of elasticity ranged from 2 to 30 kPa. Experimental measurements in an airway replica with a silicone pharynx validated the numerical methods. Good agreement was found between our FSI simulations and the WSFL theory. Other key findings include: (1) the pressure‐flow curve is independent of breathing effort (downstream pressure vs. time profile); (2) the shape of the pressure‐flow curve reflects the airway biomechanical properties, so that VImax is a surrogate measure of pharyngeal compliance. |
| topic |
Airflow limitation fluid‐structure interaction simulations and experiments obstructive sleep apnea Starling Resistor biomechanical model of airway collapse wave‐speed flow limitation theory |
| url |
https://doi.org/10.14814/phy2.14099 |
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