Concomitant Evaluation of Heart Period and QT Interval Variability Spectral Markers to Typify Cardiac Control in Humans and Rats

Concomitant Evaluation of Heart Period and QT Interval Variability Spectral Markers to Typify Cardiac Control in Humans and Rats

The variability of heart period, measured as the time distance between two consecutive QRS complexes from the electrocardiogram (RR), was exploited to infer cardiac vagal control, while the variability of the duration of the electrical activity of the heart, measured as the time interval from Q-wave...

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Published in:Frontiers in physiology Vol. 10; p. 1478
Main Authors: De Maria, Beatrice, Bari, Vlasta, Sgoifo, Andrea, Carnevali, Luca, Cairo, Beatrice, Vaini, Emanuele, Catai, Aparecida Maria, de Medeiros Takahashi, Anielle Cristhine, Dalla Vecchia, Laura Adelaide, Porta, Alberto
Format: Journal Article
Language:English
Published: Switzerland Frontiers Media S.A 29-11-2019
Subjects:
autonomic nervous system
heart rate variability
Physiology
power spectral analysis
QTV
ventricular repolarization
wild-type rat
ventricular repolarization
QTV
wild-type rat
autonomic nervous system
heart rate variability
Wistar
power spectral analysis
head-up tilt
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Summary:The variability of heart period, measured as the time distance between two consecutive QRS complexes from the electrocardiogram (RR), was exploited to infer cardiac vagal control, while the variability of the duration of the electrical activity of the heart, measured as the time interval from Q-wave onset to T-wave end (QT), was proposed as an indirect index of cardiac sympathetic modulation. This study tests the utility of the concomitant evaluation of RR variability (RRV) and QT variability (QTV) markers in typifying cardiac autonomic control of humans under different experimental conditions and of rat groups featuring documented differences in resting sympatho-vagal balance. We considered: (i) 23 healthy young subjects in resting supine position (REST) undergoing head-up tilt at 45° (T45) and 90° (T90) followed by recovery to the supine position; (ii) 9 Wistar (WI) and 14 wild-type Groningen (WT) rats in unstressed conditions, where the WT animals were classified as non-aggressive (non-AGG, = 9) and aggressive (AGG, = 5) according to the resident intruder test. In humans, spectral analysis of RRV and QTV was performed over a single stationary sequence of 250 consecutive values. In rats, spectral analysis was iterated over 10-min recordings with a frame length of 250 beats with 80% overlap and the median of the distribution of the spectral markers was extracted. Over RRV and QTV we computed the power in the low frequency (LF, from 0.04 to 0.15 Hz in humans and from 0.2 to 0.75 Hz in rats) band (LF and LF ) and the power in the high frequency (HF, from 0.15 to 0.5 Hz in humans and from 0.75 to 2.5 Hz in rats) band (HF and HF ). In humans the HF power was lower during T90 and higher during recovery compared to REST, while the LF power was higher during T90. In rats the HF power was lower in WT rats compared to WI rats and the LF power was higher in AGG than in non-AGG animals. We concluded that RRV and QTV provide complementary information in describing the functioning of vagal and sympathetic limbs of the autonomic nervous system in humans and rats.
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Edited by: George E. Billman, The Ohio State University, United States
Reviewed by: Veronique Meijborg, Academic Medical Center (AMC), Netherlands; Jerzy Sacha, Opole University of Technology, Poland
This article was submitted to Cardiac Electrophysiology, a section of the journal Frontiers in Physiology
ISSN:1664-042X
1664-042X
DOI:10.3389/fphys.2019.01478