高强度间歇运动期间年轻人脑血管搏动性过渡减弱。
Attenuated pulsatile transition to the cerebral vasculature during high-intensity interval exercise in young healthy men.
机构信息
Human Informatics and Interaction Research Institute, National Institute of Advanced Industrial Science and Technology, Tsukuba, Japan.
Graduate School of Sport and Health Science, Ritsumeikan University, Shiga, Japan.
出版信息
Exp Physiol. 2023 Aug;108(8):1057-1065. doi: 10.1113/EP091119. Epub 2023 Jun 12.
NEW FINDINGS
What is the central question of this study? High-intensity interval exercise (HIIE) is recommended for its favourable haemodynamic stimulation, but excessive haemodynamic fluctuations may stress the brain: is the cerebral vasculature protected against exaggerated systemic blood flow fluctuation during HIIE? What is the main finding and its importance? Time- and frequency-domain indices of aortic-cerebral pulsatile transition were lowered during HIIE. The findings suggest that the arterial system to the cerebral vasculature may attenuate pulsatile transition during HIIE as a defence mechanism against pulsatile fluctuation for the cerebral vasculature.
ABSTRACT
High-intensity interval exercise (HIIE) is recommended because it provides favourable haemodynamic stimulation, but excessive haemodynamic fluctuations may be an adverse impact on the brain. We tested whether the cerebral vasculature is protected against systemic blood flow fluctuation during HIIE. Fourteen healthy men (age 24 ± 2 years) underwent four 4-min exercises at 80-90% of maximal workload (W ) interspaced by 3-min active rest at 50-60% W . Transcranial Doppler measured middle cerebral artery blood velocity (CBV). Systemic haemodynamics (Modelflow) and aortic pressure (AoP, general transfer function) were estimated from an invasively recorded brachial arterial pressure waveform. Using transfer function analysis, gain and phase between AoP and CBV (0.39-10.0 Hz) were calculated. Stroke volume, aortic pulse pressure and pulsatile CBV increased during exercise (time effect: P < 0.0001 for all), but a time-domain index of aortic-cerebral pulsatile transition (pulsatile CBV/pulsatile AoP) decreased throughout the exercise bouts (time effect: P < 0.0001). Furthermore, transfer function gain reduced, and phase increased throughout the exercise bouts (time effect: P < 0.0001 for both), suggesting the attenuation and delay of pulsatile transition. The cerebral vascular conductance index (mean CBV/mean arterial pressure; time effect: P = 0.296), an inverse index of cerebral vascular tone, did not change even though systemic vascular conductance increased during exercise (time effect: P < 0.0001). The arterial system to the cerebral vasculature may attenuate pulsatile transition during HIIE as a defence mechanism against pulsatile fluctuation for the cerebral vasculature.
新发现
本研究的核心问题是什么?高强度间歇训练(HIIE)因其有利的血液动力学刺激而被推荐,但过度的血液动力学波动可能会对大脑造成压力:在 HIIE 期间,大脑血管是否会受到保护,免受过度的全身血流波动的影响?主要发现及其重要性是什么?在 HIIE 期间,主动脉-脑脉动过渡的时频域指数降低。这些发现表明,在 HIIE 期间,向大脑血管的动脉系统可能会减弱脉动过渡,作为大脑血管对抗脉动波动的防御机制。
摘要
高强度间歇训练(HIIE)因其提供有利的血液动力学刺激而被推荐,但过度的血液动力学波动可能对大脑产生不利影响。我们测试了在 HIIE 期间大脑血管是否免受全身血流波动的影响。14 名健康男性(年龄 24 ± 2 岁)在 80-90%的最大工作量(W)下进行 4 次 4 分钟的运动,间隔 3 分钟 50-60%W 的主动休息。经颅多普勒测量大脑中动脉血流速度(CBV)。系统血液动力学(Modelflow)和主动脉压力(AoP,一般传递函数)从侵入性记录的肱动脉压力波形中估计。使用传递函数分析,计算 AoP 和 CBV(0.39-10.0 Hz)之间的增益和相位。在运动过程中,心输出量、主动脉脉搏压和脉动 CBV 增加(时间效应:P < 0.0001 均),但整个运动过程中主动脉-脑脉动过渡的时间域指数(脉动 CBV/脉动 AoP)降低(时间效应:P < 0.0001)。此外,整个运动过程中传递函数增益降低,相位增加(时间效应:P < 0.0001),提示脉动过渡的衰减和延迟。大脑血管传导指数(平均 CBV/平均动脉压;时间效应:P = 0.296),大脑血管紧张度的逆指数,尽管在运动过程中全身血管传导增加,也没有改变(时间效应:P < 0.0001)。在 HIIE 期间,向大脑血管的动脉系统可能会减弱脉动过渡,作为大脑血管对抗脉动波动的防御机制。
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