作为心率变异性中极低频与高频功率之比的普通函数，在不同睡眠阶段的标度指数值。

Scaling exponent values as an ordinary function of the ratio of very low frequency to high frequency powers in heart rate variability over various sleep stages.

作者信息

Huang Ren-Jing, Lai Ching-Hsiang, Lee Shin-Da, Wang Wei-Che, Tseng Ling-Hui, Chen Yu-Pin, Chang Shen-Wen, Chung Ai-Hui, Ting Hua

机构信息

Department of Medical Image and Radiological Sciences, Chung Shan Medical University, Taichung, Taiwan.

Department of Applied Information Sciences, Chung Shan Medical University, Taichung, Taiwan.

出版信息

Sleep Breath. 2016 Sep;20(3):975-85. doi: 10.1007/s11325-016-1320-5. Epub 2016 Apr 2.

DOI:10.1007/s11325-016-1320-5

PMID:27039097

Abstract

PURPOSE

To assess the physiological meanings of the detrended fluctuation analysis (DFA) slope α and its relationship to spectral measures in heart rate variability, this study investigated changes of α and its corresponding spectral measures over various night-sleep stages.

METHODS

The overall DFA α and natural-logarithm-transformed power values of the spectral parameters ln[high-frequency (HF)], ln[low-frequency (LF)], and ln[very-low-frequency (VLF)], and their relationship from one 5-min proper electrocardiography segment in each of pre-sleep-wakefulness (AWK), non-rapid eye movement stage 2 (N2), slow-wave (N3), the first and the latest rapid-eye movement sleep (REM1, and REM2), were computed in 93 otherwise healthy males (44.1 ± 7.7 years.) with wide-ranged apnea-hypopnea, periodic-limb movement and arousal indices (19.0 ± 20.9, 4.7 ± 9.9, and 10.7 ± 18.2 h, respectively).

RESULTS

While ln(HF) dipped from AWK, N2, and N3 to REM1 then rebounded to the origin level at REM2, ln(VLF) dipped from AWK to N2, N3 trough, and then surged to levels surpassing AWKs and N2s at REM1 and REM2. ln(LF/HF), ln(VLF/HF), and α dipped from AWK and N2 to N3 trough, surged to levels surpassing AWKs, and N2s at REM1 then became attenuated at REM2. By general linear modeling, the relationship between α and the corresponding spectral values can be seen over various stages as α = b 0 + 0.147 × ln(VLF/HF) (R (2) = 0.766), regardless of age and sleep-sympathoexcitatory episodes.

CONCLUSION

The REM sleep attenuations appeared in ln(HF) and its derivatives, such as ln(LF/HF), ln(VLF/HF), and the overall DFA slope α values. The quantitative function of ln(VLF/HF) describes the α values constantly for overnight sleep stages, and it is not affected by age, LF, PLM, and AHI. Our findings therefore suggest that in sleep studies with spectral HRV measures, ln(VLF/HF) as a surrogate of the overall DFA slope α should be calculated at the same time.

摘要

目的

为评估去趋势波动分析（DFA）斜率α的生理意义及其与心率变异性频谱测量值的关系，本研究调查了α及其相应频谱测量值在不同夜间睡眠阶段的变化情况。

方法

计算了93名健康男性（年龄44.1±7.7岁）在睡前清醒（AWK）、非快速眼动睡眠2期（N2）、慢波睡眠（N3）、首次和末次快速眼动睡眠（REM1和REM2）各阶段中，每个5分钟合适心电图片段的总体DFAα以及频谱参数自然对数变换后的功率值，即ln[高频（HF）]、ln[低频（LF）]和ln[极低频（VLF）]，并分析了它们之间的关系。这些男性的呼吸暂停低通气指数、周期性肢体运动指数和觉醒指数范围较广（分别为19.0±20.9、4.7±9.9和10.7±18.2次/小时）。

结果

ln(HF)从AWK、N2和N3阶段下降至REM1阶段，然后在REM2阶段回升至初始水平；ln(VLF)从AWK阶段下降至N2阶段、N3阶段最低值，然后在REM1和REM2阶段飙升至超过AWK和N2阶段的水平。ln(LF/HF)、ln(VLF/HF)和α从AWK和N2阶段下降至N3阶段最低值，在REM1阶段飙升至超过AWK和N2阶段的水平，然后在REM2阶段减弱。通过一般线性模型分析可知，在不同阶段，α与相应频谱值之间的关系为α = b0 + 0.147×ln(VLF/HF)（R(2)=0.766），且不受年龄和睡眠交感神经兴奋事件的影响。

结论

ln(HF)及其衍生物，如ln(LF/HF)、ln(VLF/HF)以及总体DFA斜率α值在快速眼动睡眠阶段出现减弱。ln(VLF/HF)的定量函数在整个夜间睡眠阶段持续描述α值，且不受年龄、低频、周期性肢体运动和呼吸暂停低通气指数的影响。因此，我们的研究结果表明，在采用频谱心率变异性测量的睡眠研究中，应同时计算ln(VLF/HF)作为总体DFA斜率α的替代指标。

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作为心率变异性中极低频与高频功率之比的普通函数，在不同睡眠阶段的标度指数值。

Scaling exponent values as an ordinary function of the ratio of very low frequency to high frequency powers in heart rate variability over various sleep stages.

作者信息

机构信息

出版信息

PURPOSE

METHODS

RESULTS

CONCLUSION

目的

方法

结果

结论

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