Local nature of 0.1 Hz oscillations in microcirculation is confirmed by imaging photoplethysmography

Irina A. Mizeva, Natalia P. Podolyan, Oleg V. Mamontov, Anastasiia V. Sakovskaia, Alexei A. Kamshilin
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Abstract

Low-frequency oscillations in the human circulatory system is important for basic physiology and practical applications in clinical medicine. Our objective was to study which mechanism (central or local) is responsible for changes in blood flow fluctuations at around 0.1 Hz. We used the method of imaging photoplethysmography synchronized with electrocardiography to measure blood-flow response to local forearm heating of 18 healthy male volunteers. The dynamics of peripheral perfusion was revealed by a correlation processing of photoplethysmography data, and the central hemodynamics was assessed from the electrocardiogram. Wavelet analysis was used to estimate the dynamics of spectral components. Our results show that skin heating leads to multiple increase in local perfusion accompanied by drop in blood flow oscillations at 0.1 Hz, whereas no changes in heart rate variability was observed. After switching off the heating, perfusion remains at the high level, regardless decrease in skin temperature. The 0.1 Hz oscillations are smoothly recovered to the base level. In conclusion, we confirm the local nature of fluctuations in peripheral blood flow in the frequency band of about 0.1 Hz. A significant, but time-delayed, recovery of fluctuation energy in this frequency range after cessation of the skin warming was discovered. This study reveals a novel factor involved in the regulation microcirculatory vascular tone. A comprehensive study of hemodynamics using the new technique of imaging photoplethysmography synchronized with electrocardiography is a prerequisite for development of a valuable diagnostic tool.
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微循环中 0.1 赫兹振荡的局部性质通过成像光压计得到证实
人体循环系统的低频振荡对基础生理学和临床医学的实际应用都很重要。我们的目的是研究 0.1 赫兹左右的血流波动变化是由哪种机制(中枢机制还是局部机制)引起的。我们使用与心电图同步的成像血压计方法测量了 18 名健康男性志愿者前臂局部加热时的血流反应。通过对外周血流灌注数据进行相关处理来揭示血流动力学,并通过心电图评估中心血流动力学。小波分析用于估计频谱成分的动态变化。我们的研究结果表明,皮肤加热会导致局部血流灌注多次增加,并伴随着 0.1 Hz 频率的血流振荡下降,而心率变异性则没有变化。关闭加热后,无论皮肤温度如何下降,血流灌注仍保持在较高水平。0.1 Hz 的振荡平稳地恢复到基本水平。总之,我们证实了外周血流在 0.1 赫兹左右频段波动的局部性。我们发现,在皮肤升温后,该频率范围内的波动能量会明显恢复,但时间会延迟。这项研究揭示了一种参与调节微循环血管张力的新因素。使用与心电图同步的光电血流动力学成像新技术对血液动力学进行全面研究,是开发有价值诊断工具的先决条件。
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