Va Arshajyothirmayi, Namboodiri Narayanan, Gulia Kamalesh K
Division of Sleep Research, Department of Applied Biology, Biomedical Technology Wing, Sree Chitra Tirunal Institute for Medical Sciences and Technology, Trivandrum, Kerala, India.
Department of Cardiology, Sree Chitra Tirunal Institute for Medical Sciences and Technology, Trivandrum, Kerala, India.
Ann Neurosci. 2025 Sep 25:09727531251371350. doi: 10.1177/09727531251371350.
Acute heart rate variability (HRV) is used for assessment of functional autonomic profile in awake resting state in humans subjects. Evaluation of 24-h variations in the sympatho-vagal balance across sleep stages through HRV are valuable to understand the basis of various lifestyles diseases, however, such studies are uncommon.
The present study modelled the sleep-wake associated cardiac autonomic changes in freely moving female Wistar rats across light and dark phase using HRV as a tool.
Sleep states (non-rapid eye movement [NREM] and rapid eye movement [REM] sleep) were estimated through electroencephalogram (EEG) and electromyogram (EMG), while the ECG signal was acquired simultaneously for HRV analysis. To understand circadian dynamics, HRV was analysed for noise-free distinct and transitional state segments of sleep-wakefulness.
In time domain parameters, RR intervals during NREM sleep were longer in comparison to wake and REM sleep. In the frequency domain, reductions in LF and an increase in HF power during NREM sleep were evident compared to other states. RR interval during wakefulness in the dark phase was significantly decreased compared to the light phase. The RR interval was the longest during the early phase of the light period (6-10 am) in all three states.
Parasympathetic predominance during NREM sleep was similar to a human having a monophasic pattern, while a higher sympathetic tone during the majority of transitional states in rats, which are polyphasic in nature, indicated risk of dysregulated sympatho-vagal balance with fragmented sleep. Further, the highest parasympathetic activity during the early light phase and the highest sympathetic drive during the dark phase may serve as an adaptive mechanism for survival in nocturnal life.
急性心率变异性(HRV)用于评估人类受试者清醒静息状态下的自主神经功能状态。通过HRV评估睡眠各阶段交感-迷走神经平衡的24小时变化,对于理解各种生活方式疾病的发病机制具有重要价值,然而,此类研究并不常见。
本研究以HRV为工具,模拟自由活动的雌性Wistar大鼠在明暗周期中与睡眠-觉醒相关的心脏自主神经变化。
通过脑电图(EEG)和肌电图(EMG)评估睡眠状态(非快速眼动[NREM]睡眠和快速眼动[REM]睡眠),同时采集心电图信号进行HRV分析。为了解昼夜节律动态变化,对无噪声的睡眠-觉醒不同及过渡状态片段进行HRV分析。
在时域参数方面,与清醒和REM睡眠相比,NREM睡眠期间的RR间期更长。在频域方面,与其他状态相比,NREM睡眠期间低频功率降低、高频功率增加明显。与明相相比,暗相清醒期间的RR间期显著缩短。在所有三种状态下,明相早期(上午6 - 10点)的RR间期最长。
NREM睡眠期间副交感神经占主导,类似于具有单相睡眠模式的人类,而在多相睡眠模式的大鼠中,大多数过渡状态下交感神经张力较高,这表明睡眠碎片化会导致交感-迷走神经平衡失调。此外,明相早期副交感神经活动最高,暗相交感神经驱动力最高,这可能是夜行性动物生存的一种适应性机制。
