Respiratory Frequency During Exercise: The Neglected Physiological Measure

Overview

Journal Front Physiol

Date 2018 Jan 12

PMID 29321742

Citations 63

Authors

Andrea Nicolo

Carlo Massaroni

Louis Passfield

Affiliations

Soon will be listed here.

Abstract

The use of wearable sensor technology for athlete training monitoring is growing exponentially, but some important measures and related wearable devices have received little attention so far. Respiratory frequency (), for example, is emerging as a valuable measurement for training monitoring. Despite the availability of unobtrusive wearable devices measuring with relatively good accuracy, is not commonly monitored during training. Yet is currently measured as a vital sign by multiparameter wearable devices in the military field, clinical settings, and occupational activities. When these devices have been used during exercise, was used for limited applications like the estimation of the ventilatory threshold. However, more information can be gained from . Unlike heart rate, [Formula: see text]O, and blood lactate, is strongly associated with perceived exertion during a variety of exercise paradigms, and under several experimental interventions affecting performance like muscle fatigue, glycogen depletion, heat exposure and hypoxia. This suggests that is a strong marker of physical effort. Furthermore, unlike other physiological variables, responds rapidly to variations in workload during high-intensity interval training (HIIT), with potential important implications for many sporting activities. This Perspective article aims to (i) present scientific evidence supporting the relevance of for training monitoring; (ii) critically revise possible methodologies to measure and the accuracy of currently available respiratory wearables; (iii) provide preliminary indication on how to analyze data. This viewpoint is expected to advance the field of training monitoring and stimulate directions for future development of sports wearables.

Citing Articles

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