Assessment of the Coupling Between Heart Rate and Arterial Pressure During Head-Up Tilt
Zhan Ping, Li Chenxi, Wang Zhigang, Zhang Zhengguo, Peng Yi#*
(Institute of Basic Medical Sciences, Chinese Academy of Medical Sciences, School of Basic Medicine, Peking Union Medical College, Beijing 100005,China)
摘要从动态和稳态两个视角,研究直立倾斜(HUT)引起体位改变前后以及不同速度改变体位过程中RR间期(RRI)与收缩压(SBP)间耦合性的变化。所用数据来自PhsioNet发布的体位变化所引起的生理响应数据库(PRCP),含有10位健康受试者(5男5女)在HUT过程中记录的连续心电和动脉血压信号。慢速体位变化(ST)和快速体位(RT)变化分别为在50和2 s之间从水平仰卧升至75°倾斜。提取逐拍RRI和SBP数据后,运用交叉时频分析和信息分解方法,结合时域和短时分形指数(α1),进行RRI和SBP时间序列的联合分析。信息分解分析结果表明,所有的显著差异集中在压力反射导致心率变化的后向反馈回路(SBP→RRI),ST后心率的可预测性较平卧时显著增高(0.416±0.067 vs 0.626±0.127),压力反射支路的SBP-RRI耦合性升高。而在RRI→SBP方向,HUT对其几乎没有影响。ST和RT之前,所有的同类指标相比均无显著差异。ST和RT之后的稳态,虽然RRI无显著差异,但较之ST之后,RT之后RRI的变异系数显著升高(0.054±0.014 vs 0.074±0.027),α1显著降低(1.45±0.25 vs 1.28±0.27)。同时,交叉时频分析结果揭示了ST和RT过程中自主神经不同的动态反应行为。研究证明了信息分解方法的有效性,可明确区分心率与血压相互作用时的前向反馈和后向反馈的主导因果方向,而且可反映HUT前后信号可预测性的变化。
Abstract:This study is aimed to investigate the changes of the coupling strength between RR interval (RRI) and systolic blood pressure (SBP) before and after head-up tilt (HUT) with different tilt speeds from dynamic and steady perspectives. The data used was from database Physiologic Response to Changes in Posture(PRCP) published on PhysioNet, providing documentary ECG and continuous arterial blood pressure signals of ten healthy subjects (5 males and 5 females) during HUT stimulation. Beat-by-beat time series of RRI and SBP were extracted from bothslow tilt (ST,75°HUT over 50 s) and rapid tilt (RT,75°HUT over 2 s). Then, time-frequency analysis and information decomposition analysis, combined with time-domain indexes and short-term fractal exponent (α1) were applied to perform joint analysis between RRI and SBP. The results of information decomposition analysis indicated that all of the significant differences appeared in the feedback direction (SBP→RRI)due to baroreflex control on RRI. The prediction of RRI after ST significantly increased compared to that in supine position (0.416±0.067 vs 0.626±0.127), indicating the elevation of the couplingstrength along the baroreflex. However, HUT showed few effects in the feedforward direction of RRI→SBP. There were no significant differences between ST and RT for all of the same indexes before HUT. However, the coefficient of variation of RRI (CVRRI) in the steady state after RT was significantly increased and α1 was significantly decreased compared to that after ST despite the fact that there was no difference for RRI. What’s more, the results of time-frequency analysis suggested the different behavior of dynamic response to ST and RT. Our research proved the effectiveness of information decomposition analysis to detect the dominant causal direction (feedback or feedforward) in the RRI-SBP interactions and to characterize the changes of the prediction of RRI and SBP signal before and after HUT.
湛 萍, 李晨曦, 王志刚, 张正国, 彭 屹. 直立倾斜引起的心率和血压的耦合性变化分析[J]. 中国生物医学工程学报, 2017, 36(3): 284-292.
Zhan Ping, Li Chenxi, Wang Zhigang, Zhang Zhengguo, Peng Yi. Assessment of the Coupling Between Heart Rate and Arterial Pressure During Head-Up Tilt. Chinese Journal of Biomedical Engineering, 2017, 36(3): 284-292.
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