Non-contact Thermography-based Respiratory Rate Monitoring in a Post-anesthetic Care Unit

Overview

Journal J Clin Monit Comput

Publisher Springer

Specialties Anesthesiology
General Medicine
Medical Informatics

Date 2020 Sep 25

PMID 32975639

Citations 5

Authors

Hye-Mee Kwon

Keita Ikeda

Sung-Hoon Kim

Robert H Thiele

Affiliations

Soon will be listed here.

Abstract

In patients at high risk of respiratory complications, pulse oximetry may not adequately detect hypoventilation events. Previous studies have proposed using thermography, which relies on infrared imaging, to measure respiratory rate (RR). These systems lack support from real-world feasibility testing for widespread acceptance. This study enrolled 101 spontaneously ventilating patients in a post-anesthesia recovery unit. Patients were placed in a 45° reclined position while undergoing pulse oximetry and bioimpedance-based RR monitoring. A thermography camera was placed approximately 1 m from the patient and pointed at the patient's face, recording continuously at 30 frames per second for 2 min. Simultaneously, RR was manually recorded. Offline imaging analysis identified the nares as a region of interest and then quantified nasal temperature changes frame by frame to estimate RR. The manually calculated RR was compared with both bioimpedance and thermographic estimates. The Pearson correlation coefficient between direct measurement and bioimpedance was 0.69 (R = 0.48), and that between direct measurement and thermography was 0.95 (R = 0.90). Limits of agreement analysis revealed a bias of 1.3 and limits of agreement of 10.8 (95% confidence interval 9.07 to 12.5) and - 8.13 (- 6.41 to - 9.84) between direct measurements and bioimpedance, and a bias of -0.139 and limits of agreement of 2.65 (2.14 to 3.15) and - 2.92 (- 2.41 to 3.42) between direct measurements and thermography. Thermography allowed tracking of the manually measured RR in the post-anesthesia recovery unit without requiring patient contact. Additional work is required for image acquisition automation and nostril identification.

Citing Articles

Thermal Cameras for Continuous and Contactless Respiration Monitoring.

Alves R, van Meulen F, Overeem S, Zinger S, Stuijk S Sensors (Basel). 2025; 24(24.

PMID: 39771853 PMC: 11679429. DOI: 10.3390/s24248118.

Respiratory Rate Monitoring via a Fibre Bragg Grating-Embedded Respirator Mask with a Wearable Miniature Interrogator.

Limweshasin N, Castro I, Korposh S, Morgan S, Hayes-Gill B, Faghy M Sensors (Basel). 2024; 24(23).

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Speckle Vibrometry for Contactless Instantaneous Heart Rate and Respiration Rate Monitoring on Mechanically Ventilated Patients.

Que S, Cramer I, Dekker L, Overeem S, Bouwman A, Zinger S Sensors (Basel). 2024; 24(19).

PMID: 39409414 PMC: 11479045. DOI: 10.3390/s24196374.

Continuous Monitoring of Vital Signs Using Cameras: A Systematic Review.

Selvaraju V, Spicher N, Wang J, Ganapathy N, Warnecke J, Leonhardt S Sensors (Basel). 2022; 22(11).

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Karbing D, Leonhardt S, Perchiazzi G, Bates J J Clin Monit Comput. 2022; 36(3):599-607.

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