Design and Testing of a Smart Facemask for Respiratory Monitoring During Cycling Exercise

Overview

Journal Biosensors (Basel)

Specialty Biotechnology

Date 2023 Mar 29

PMID 36979581

Authors

Chiara Romano

Andrea Nicolo

Lorenzo Innocenti

Massimo Sacchetti

Emiliano Schena

Carlo Massaroni

Affiliations

Soon will be listed here.

Abstract

Given the importance of respiratory frequency () as a valid marker of physical effort, there is a growing interest in developing wearable devices measuring in applied exercise settings. Biosensors measuring chest wall movements are attracting attention as they can be integrated into textiles, but their susceptibility to motion artefacts may limit their use in some sporting activities. Hence, there is a need to exploit sensors with signals minimally affected by motion artefacts. We present the design and testing of a smart facemask embedding a temperature biosensor for monitoring during cycling exercise. After laboratory bench tests, the proposed solution was tested on cyclists during a ramp incremental frequency test (RIFT) and high-intensity interval training (HIIT), both indoors and outdoors. A reference flowmeter was used to validate the extracted from the temperature respiratory signal. The smart facemask showed good performance, both at a breath-by-breath level (MAPE = 2.56% and 1.64% during RIFT and HIIT, respectively) and on 30 s average values (MAPE = 0.37% and 0.23% during RIFT and HIIT, respectively). Both accuracy and precision (MOD ± LOAs) were generally superior to those of other devices validated during exercise. These findings have important implications for exercise testing and management in different populations.

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