Wray D Walter, Fadel Paul J, Keller David M, Ogoh Shigehiko, Sander Mikael, Raven Peter B, Smith Michael L
Department of Integrative Physiology, University of North Texas Health Science Center, Fort Worth, TX 76107, USA.
J Physiol. 2004 Sep 1;559(Pt 2):675-84. doi: 10.1113/jphysiol.2004.066183. Epub 2004 Jul 2.
We sought to determine the dynamic relationship between carotid baroreflex (CBR)-mediated control and local control of the skeletal muscle vasculature during dynamic exercise. In 12 subjects (18-35 years old), oscillatory neck pressure (NP, +40 mmHg) was applied at 0.1 Hz (i.e. 5 s on, 5 s off) for 5 min to determine the degree of CBR control over heart rate (HR), arterial blood pressure (ABP), muscle sympathetic nerve activity (MSNA), femoral blood velocity and skeletal muscle tissue oxygenation at rest and during 7 W dynamic knee-extension exercise. Skeletal muscle tissue oxygenation measurements of both the exercising and nonexercising leg were evaluated. Fast Fourier transformation was performed on 5 min segments to calculate spectral power of the R-R interval (RRI), ABP, MSNA, femoral blood velocity and tissue oxygenation time series, and the low-frequency (LF, 0.085-0.115 Hz) power spectra were compared to evaluate the degree of CBR-mediated entrainment for each variable. At rest, sinusoidal NP significantly increased LF spectral power of RRI, ABP, MSNA and femoral blood velocity. During exercise, sinusoidal NP provoked a similar increase in spectral power for RRI and MSNA, while CBR-mediated changes in ABP and femoral blood velocity were attenuated compared to rest. Changes in spectral power of skeletal muscle tissue oxygenation during sinusoidal NP were similar between the exercising and nonexercising leg at rest. However, during exercise the changes in skeletal muscle tissue oxygenation power were significantly less in the exercising leg, while changes in the nonexercising leg were similar to rest. We have demonstrated simultaneous entrainment of all CBR end-organ measurements, ranging from cardiac chronotropic effects to alterations at the level of the skeletal muscle microcirculation. Moreover, we have identified a significant and specific attenuation of end-organ responsiveness to CBR-mediated sympathoexcitation in the vasculature of the exercising muscle. However, despite a shift towards more predominant local control over the exercising muscle vasculature, systemic arterial blood pressure was well preserved.
我们试图确定动态运动期间颈动脉压力反射(CBR)介导的控制与骨骼肌血管局部控制之间的动态关系。在12名受试者(18 - 35岁)中,以0.1 Hz(即5秒开启,5秒关闭)施加振荡性颈部压力(NP,+40 mmHg),持续5分钟,以确定在静息状态和7瓦动态伸膝运动期间CBR对心率(HR)、动脉血压(ABP)、肌肉交感神经活动(MSNA)、股血流速度和骨骼肌组织氧合的控制程度。对运动腿和非运动腿的骨骼肌组织氧合测量进行了评估。对5分钟时间段进行快速傅里叶变换,以计算R - R间期(RRI)、ABP、MSNA、股血流速度和组织氧合时间序列的频谱功率,并比较低频(LF,0.085 - 0.115 Hz)功率谱,以评估每个变量的CBR介导的同步化程度。静息时,正弦波NP显著增加RRI、ABP、MSNA和股血流速度的LF频谱功率。运动期间,正弦波NP引起RRI和MSNA频谱功率的类似增加,而与静息相比,CBR介导的ABP和股血流速度变化减弱。静息时,正弦波NP期间骨骼肌组织氧合频谱功率的变化在运动腿和非运动腿之间相似。然而,运动期间,运动腿的骨骼肌组织氧合功率变化明显较小,而非运动腿的变化与静息时相似。我们已经证明了所有CBR终末器官测量值的同步化,范围从心脏变时效应到骨骼肌微循环水平的改变。此外,我们已经确定在运动肌肉的血管系统中,终末器官对CBR介导的交感兴奋的反应性存在显著且特定的减弱。然而,尽管对运动肌肉血管系统的局部控制变得更加突出,但全身动脉血压仍得到良好维持。