Abstract
We propose higher-order detrending moving-average cross-correlation analysis (DMCA) to assess the long-range cross-correlations in cardiorespiratory and cardiovascular interactions. Although the original (zeroth-order) DMCA employs a simple moving-average detrending filter to remove non-stationary trends embedded in the observed time series, our approach incorporates a Savitzky–Golay filter as a higher-order detrending method. Because the non-stationary trends can adversely affect the long-range correlation assessment, the higher-order detrending serves to improve accuracy. To achieve a more reliable characterization of the long-range cross-correlations, we demonstrate the importance of the following steps: correcting the time scale, confirming the consistency of different order DMCAs, and estimating the time lag between time series. We applied this methodological framework to cardiorespiratory and cardiovascular time series analysis. In the cardiorespiratory interaction, respiratory and heart rate variability (HRV) showed long-range auto-correlations; however, no factor was shared between them. In the cardiovascular interaction, beat-to-beat systolic blood pressure and HRV showed long-range auto-correlations and shared a common long-range, cross-correlated factor.This article is part of the theme issue ‘Advanced computation in cardiovascular physiology: new challenges and opportunities’.
Highlights
Heart rate variability (HRV) in a healthy individual displays complex fluctuations even during a resting state [1,2]
The LF power in the frequency band around 0.1 Hz is associated with the synchronization between heart rate variability (HRV) and arterial blood pressure (BP) oscillation known as the Mayer wave
The second dataset consists of beat-to-beat systolic BP (SBP), diastolic BP (DBP), and RR interval (RRI)
Summary
Heart rate variability (HRV) in a healthy individual displays complex fluctuations even during a resting state [1,2]. The 1/f fluctuation means that the observed time series has a non-trivial long-range autocorrelation. The HF power in the frequency band around 0.25 Hz is primarily associated with the synchronization between HRV and respiration cycle, mediated by vagal parasympathetic activity. The LF power in the frequency band around 0.1 Hz is associated with the synchronization between HRV and arterial blood pressure (BP) oscillation known as the Mayer wave. The effects of respiration and BP control on HRV have been evaluated through frequency-specific components such as the HF and LF powers [15,16,17,18,19]. The relation between 1/f fluctuations and respiratory-cardiovascular interactions has not been investigated We explore this relation to gain new insights into the complex dynamics of HRV. We analyse heart rate (HR) and respiration variability to study cardiorespiratory interactions and HR and beat-to-beat BP variability to study cardiovascular interactions
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