BACKGROUND: Breathing pattern influences not only pulmonary ventilation but also upper airway transport processes such as nasal heat exchange, sinus ventilation, and carbon dioxide clearance. This study used transient computational fluid dynamics to investigate how respiratory rate and waveform shape affect these processes in a single patient specific upper airway model. METHODS: , were applied to isolate the effect of breathing waveform from intersubject anatomical variability. Transient CFD simulations were performed over five complete breathing cycles to capture unsteady airflow and scalar transport. RESULTS: rebreathing, reaching about 16%. Lower respiratory rates reduced rebreathing to below 6% by increasing tidal volume relative to the fixed upper airway dead space. Sinus ventilation and nitric oxide (NO) transport were strongly influenced by ostium size and breathing waveform. The left sinus, with the smaller ostium, remained predominantly diffusion limited, whereas the sinus with the larger ostium showed intermittent convective exchange during inhalation. Among the two COPD type breathing profiles, the waveform with the shorter inspiratory phase showed the weakest thermal recovery and lowest inhaled air temperature, whereas the less abrupt waveform remained closer to the corresponding healthy case at the same respiratory rate. CONCLUSIONS: The present simulations show that breathing pattern influences intranasal airflow, air conditioning, rebreathed gas clearance, and sinus ventilation. Lower respiratory rates improved gas clearance by reducing the relative effect of anatomical dead space, while waveform differences also affected heat exchange and sinus transport. The findings should be interpreted as a mechanistic, case specific assessment of waveform effects rather than a population level comparison between healthy and COPD subjects.
Khamooshi et al. (Mon,) studied this question.