High-Flow and Low-Flow Oxygen Delivery by Nasal Cannula Evaluated in Infant and Adult Airway Replicas

Mozhgan Sabz; Michelle L Noga; Warren H Finlay; Hossein Rouhani; Andrew R Martin

doi:10.4187/respcare.11438

High-Flow and Low-Flow Oxygen Delivery by Nasal Cannula Evaluated in Infant and Adult Airway Replicas

Respir Care. 2024 Mar 27;69(4):438-448. doi: 10.4187/respcare.11438.

Authors

Mozhgan Sabz¹, Michelle L Noga¹, Warren H Finlay¹, Hossein Rouhani¹, Andrew R Martin²

Affiliations

¹ Ms Sabz, Drs Finlay, Rouhani, and Martin are affiliated with the Department of Mechanical Engineering, University of Alberta, Edmonton, Alberta, Canada. Dr Noga is affiliated with the Department of Radiology and Diagnostic Imaging, University of Alberta, Edmonton, Alberta, Canada.
² Ms Sabz, Drs Finlay, Rouhani, and Martin are affiliated with the Department of Mechanical Engineering, University of Alberta, Edmonton, Alberta, Canada. Dr Noga is affiliated with the Department of Radiology and Diagnostic Imaging, University of Alberta, Edmonton, Alberta, Canada. andrew.martin@ualberta.ca.

PMID: 38443141
DOI: 10.4187/respcare.11438

Abstract

Background: The nasal cannula is widely regarded as a safe and effective means of administering low- and high-flow oxygen to patients irrespective of their age. However, variability in delivered oxygen concentration (F_DO₂ F_DO₂ ) via nasal cannula has the potential to pose health risks. The present study aimed to evaluate predictive equations for F_DO₂ over a large parameter space, including variation in breathing, oxygen flow, and upper-airway geometry representative of both young children and adults.

Methods: Realistic nasal airway geometries were previously collected from medical scans of adults, infants, and neonates. Nasal airway replicas based on these geometries were used to measure the F_DO₂ for low-flow oxygen delivery during simulated spontaneous breathing. The present study extends previously published data sets to include higher oxygen flows. The extended data sets included nasal cannula oxygen flows that ranged from 6 to 65 L/min for the adult replicas, and from 0.5 to 6 L/min for the infant replicas. For both age groups, F_DO₂ was measured over a range of breathing frequencies, inspiratory to expiratory time ratios, and tidal volumes. Measured F_DO₂ values were compared with values predicted by using a previously derived flow-weighted equation.

Results: For both age groups, F_DO₂ was observed to increase nonlinearly with the ratio between oxygen flow supplied to the nasal cannula and the average inhalation flow. The previously derived flow-weighted equation over-predicted F_DO₂ at higher oxygen flows. A new empirical equation, therefore, was proposed to predict F_DO₂ for either age group as a function of nasal cannula flow, tidal volume, and inspiratory time. Predicted F_DO₂ values matched measured values, with average relative errors of 2.4% for infants and 4.3% for adults.

Conclusions: A new predictive equation for F_DO₂ was obtained that accurately matched measured data in both adult and infant airway replicas for low- and high-flow regimens.

Keywords: Airway replicas; Fraction of inspired oxygen; Oxygen therapy; Predictive equation; Tidal volumes.

MeSH terms

Adult
Cannula*
Child
Child, Preschool
Humans
Infant
Infant, Newborn
Intubation
Nose
Oxygen
Oxygen Inhalation Therapy
Respiration*

Substances

Oxygen