On the Relevance of Computing a Local Version of Sample Entropy in Cardiovascular Control Analysis

Alberto Porta, Vlasta Bari, Beatrice De Maria, Beatrice Cairo, Emanuele Vaini, Mara Malacarne, Massimo Pagani, Daniela Lucini

Research output: Contribution to journalArticle

Abstract

OBJECTIVE: Traditional definition of sample entropy (SampEn), here referred to as global SampEn (GSampEn), provides a conditional entropy estimate that blurs the local statistical properties of the time series. We hypothesized that a local version of SampEn (LSampEn) might be more powerful in the presence of determinism than GSampEn.

METHODS: LSampEn was computed by calculating the probability of the current sample conditioned on each reference pattern and averaging it over all reference patterns. The improved ability of LSampEn compared to GSampEn was demonstrated by simulating deterministic periodic, deterministic chaotic, and linear stochastic dynamics corrupted by additive noise and over real cardiovascular variability series recorded from 16 healthy subjects (max-min age range: 22-58 years) during incremental bicycle ergometer exercise.

RESULTS: We found that: i) LSampEn is more robust in describing deterministic periodic or nonlinear features in the presence of additive noise than GSampEn, ii) in association with a surrogate approach, LSampEn is more powerful in detecting nonlinear dynamics than GSampEn, iii) LSampEn and GSampEn are equivalent in the presence of stochastic linear dynamics, and iv) only LSampEn can detect the decrease of complexity of heart period variability during bicycle exercise being a likely hallmark of sympathetic activation.

CONCLUSION: LSampEn preserves the GSampEn capability in characterizing the complexity of short sequences but improves its reliability in the presence of deterministic patterns featuring sharp state transitions and nonlinear dynamics.

SIGNIFICANCE: Variations of complexity can be measured with a greater statistical power over short series using LSampEn, especially when nonlinear features are present.

Original languageEnglish
Pages (from-to)623-631
Number of pages9
JournalIEEE Transactions on Biomedical Engineering
Volume66
Issue number3
DOIs
Publication statusPublished - Mar 2019

Keywords

  • Adult
  • Autonomic Nervous System/physiology
  • Entropy
  • Exercise Test
  • Female
  • Heart Rate/physiology
  • Humans
  • Male
  • Middle Aged
  • Models, Cardiovascular
  • Models, Statistical
  • Signal-To-Noise Ratio
  • Young Adult

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