Dynamical cross-correlations between RR and QT intervals in long-term electrocardiogram recordings

TL;DR

This study analyzes long-term ECG data to understand how RR and QT intervals dynamically influence each other over time, revealing age-related changes and the influence of past RR intervals on current QT intervals.

Contribution

It introduces a detailed analysis of RR-QT cross-correlations across various time lags in long-term ECG recordings, highlighting age effects and the dominance of past RR intervals.

Findings

Strong negative lag cross-correlation between RR and QT intervals.

Aging reduces RR-QT cross-correlations across all time lags.

No significant sex differences in RR-QT cross-correlations.

Abstract

Understanding the dynamic relationship between RR and QT intervals is crucial for interpreting electrocardiograms (ECGs) and managing cardiac conditions. We investigated cross-correlation between RR and QT intervals in long-term ECG recordings from 202 healthy subjects using time-lagged cross-correlation analysis to explore how QT intervals correlate with both preceding and succeeding RR intervals across various time lags. Data was preprocessed with the smoothness priors method to remove long-term trends while preserving relevant short-term dynamics. Our results reveal that, as expected, the highest RR-QT cross-correlations occur when the intervals overlap the most. Notably, we also observed a strong cross-correlation between the present QT interval and the preceding RR interval, with the overall correlations skewed toward negative lags. This suggests that past RR intervals exert a stronger influence on current QT intervals. These findings align with previous research on RR-QT transfer entropy. We found no significant differences in RR-QT cross-correlations between sexes. However, aging was associated with significantly reduced cross-correlations across all lags. This effect is consistent with existing literature on age-related cardiac changes and provides further insight into the impact of aging on RR-QT coupling. Additionally, we observed a slight positive correlation between heart rate and cross-correlation at all lags, with cross-correlation decreasing as the lag increased. These findings enhance our understanding of the dynamic RR-QT relationship and may inform future studies on cardiac electrophysiology and diseases.