Gabriele Meyer scite author profile

Recent studies showed that nasal high flow (NHF) with or without supplemental oxygen can assist ventilation of patients with chronic respiratory and sleep disorders. The hypothesis of this study was to test whether NHF can clear dead space in two different models of the upper nasal airways. The first was a simple tube model consisting of a nozzle to simulate the nasal valve area, connected to a cylindrical tube to simulate the nasal cavity. The second was a more complex anatomically representative upper airway model, constructed from segmented CT-scan images of a healthy volunteer. After filling the models with tracer gases, NHF was delivered at rates of 15, 30, and 45 l/min. The tracer gas clearance was determined using dynamic infrared CO2 spectroscopy and 81mKr-gas radioactive gamma camera imaging. There was a similar tracer-gas clearance characteristic in the tube model and the upper airway model: clearance half-times were below 1.0 s and decreased with increasing NHF rates. For both models, the anterior compartments demonstrated faster clearance levels (half-times < 0.5 s) and the posterior sections showed slower clearance (half-times < 1.0 s). Both imaging methods showed similar flow-dependent tracer-gas clearance in the models. For the anatomically based model, there was complete tracer-gas removal from the nasal cavities within 1.0 s. The level of clearance in the nasal cavities increased by 1.8 ml/s for every 1.0 l/min increase in the rate of NHF. The study has demonstrated the fast-occurring clearance of nasal cavities by NHF therapy, which is capable of reducing of dead space rebreathing.

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Nasal high flow reduces dead space

Möller

Feng

Domanski

et al. 2017

Journal of Applied Physiology

198

155

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Clearance of expired air in upper airways by nasal high flow (NHF) can be extended below the soft palate and de facto causes a reduction of dead space. Using scintigraphy, the authors found a relationship between NHF, time, and clearance. Direct measurement of CO2 and O2 in the trachea confirmed a reduction of rebreathing, providing the actual data on inspired gases, and this can be used for the assessment of other forms of respiratory support.

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Ventilation and aerosolized drug delivery to the paranasal sinuses using pulsating airflow aeuro" a preliminary study

Moeller

Schuschnig²,

Meyer³

et al. 2009

Rhinology Journal

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Survival and Recurrence Rates after Resection for Hepatocellular Carcinoma in Noncirrhotic Livers

et al. 2007

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Gabriele Meyer

Deposition, Retention, and Translocation of Ultrafine Particles from the Central Airways and Lung Periphery

Nasal high flow clears anatomical dead space in upper airway models

Nasal high flow reduces dead space

Ventilation and aerosolized drug delivery to the paranasal sinuses using pulsating airflow aeuro" a preliminary study

Survival and Recurrence Rates after Resection for Hepatocellular Carcinoma in Noncirrhotic Livers

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