AUTHOR=Nishimura Yoichi , Arias Rafael S. , Pho Huy , Pham Luu Van , Curado Thomaz Fleury , Polotsky Vsevolod Y. , Schwartz Alan R. 

TITLE=A Novel Non-invasive Approach for Measuring Upper Airway Collapsibility in Mice

JOURNAL=Frontiers in Neurology

VOLUME=9

YEAR=2018

URL=https://www.frontiersin.org/journals/neurology/articles/10.3389/fneur.2018.00985

DOI=10.3389/fneur.2018.00985

ISSN=1664-2295

ABSTRACT=<p><bold>Introduction:</bold> Invasive procedures were previously developed for measuring pharyngeal collapsibility in rodents during expiration, when declining neuromuscular activity makes the airway unstable. We developed a non-invasive approach for streamlining collapsibility measurements by characterizing responses in physiologic markers of dynamic expiratory airflow obstruction to negative nasal pressure challenges.</p><p><bold>Methods:</bold> Anesthetized mice were instrumented to monitor upper airway pressure-flow relationships with head-out plethysmography while nasal pressure was ramped down from ~ +5 to −20 cm H<sub>2</sub>O over several breaths. Inspiratory and expiratory flow, volume, and timing characteristics were assessed breath-wise. Pcrit was estimated at transitions in expiratory amplitude and timing parameters, and compared to gold standard P<sub>CRIT</sub> measurements when nasal and tracheal pressures diverged during expiration. Predictions equations were constructed in a development data set (<italic>n</italic> = 8) and applied prospectively to a validation data set (<italic>n</italic> = 16) to estimate gold standard P<sub>CRIT</sub>.</p><p><bold>Results:</bold> The development data demonstrated that abrupt reversals in expiratory duration and tidal volume during nasal pressure ramps predicted gold standard P<sub>CRIT</sub> measurements. After applying regression equations from the development to a validation dataset, we found that a combination of expiratory amplitude and timing parameters proved to be robust predictors of gold standard P<sub>CRIT</sub> with minimal bias and narrow confidence intervals.</p><p><bold>Conclusions:</bold> Markers of expiratory airflow obstruction can be used to model upper airway collapsibility, and can provide sensitive measures of changes in airway collapsibility in rodents. This approach streamlines repeated non-invasive P<sub>CRIT</sub> measurements, and facilitates studies examining the impact of genetic, environmental, and pharmacologic factors on upper airway control.</p>