Detecting Metabolic Thresholds from Nonlinear Analysis of Heart Rate Time Series: A Review

Overview

Journal Int J Environ Res Public Health

Publisher MDPI

Specialties Environmental Health
Public Health

Date 2022 Oct 14

PMID 36232025

Authors

Giovanna Zimatore

Maria Chiara Gallotta

Matteo Campanella

Piotr H Skarzynski

Giuseppe Maulucci

Cassandra Serantoni

Marco De Spirito

Davide Curzi

Laura Guidetti

Carlo Baldari

Stavros Hatzopoulos

Affiliations

Soon will be listed here.

Abstract

Heart rate time series are widely used to characterize physiological states and athletic performance. Among the main indicators of metabolic and physiological states, the detection of metabolic thresholds is an important tool in establishing training protocols in both sport and clinical fields. This paper reviews the most common methods, applied to heart rate (HR) time series, aiming to detect metabolic thresholds. These methodologies have been largely used to assess energy metabolism and to identify the appropriate intensity of physical exercise which can reduce body weight and improve physical fitness. Specifically, we focused on the main nonlinear signal evaluation methods using HR to identify metabolic thresholds with the purpose of identifying a method which can represent a useful tool for the real-time settings of wearable devices in sport activities. While the advantages and disadvantages of each method, and the possible applications, are presented, this review confirms that the nonlinear analysis of HR time series represents a solid, robust and noninvasive approach to assess metabolic thresholds.

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