[Changes in the blood flow of the primary carotid and its branches during modifications of the O2 and CO2 composition of alveolar gas].

O Bailliart, H Marotte, H Normand, J P Martineaud, J Durand
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Abstract

We measured common carotid blood flow using a range gated Doppler velocimeter, and internal and external blood velocities using a continuous Doppler in 20 lowlanders at sea level, under normal barometric pressure, in 10 subjects in an altitude chamber under a barometric pressure of 462 Torr (61.6 KPa) and then in 5 of them over a 3-weeks period at 3850 m of elevation (475 Torr = 63.3 KPa). The same measurements were also performed in 20 permanent residents at 3850 m. Common carotid blood flow was 15% higher in all subjects exposed to high altitude, due to a lowering in downstream resistances since systemic blood pressure did not change at high altitude. The increase in common carotid blood flow was the result of an immediate increase in internal carotid blood velocities observed in the altitude chamber as well as after the arrival at high altitude, but a few days later those velocities in the internal carotid artery declined to values similar to those observed at sea level. In the same time velocities in external carotid artery rose at high altitude, remained steadily elevated and the result is a permanent increase in common carotid blood flow at altitude. In all subjects we performed the same measurements, during an acute inhalation of gas mixtures to try to quantify the mechanisms controlling the changes in common carotid blood flow while changing gas inhalation. In the limits of the variations in PO2 (60 to 400 Torr) and in PCO2 (30 to 50 Torr) the stimulation by CO2 is twice more efficient than the O2 stimulation on vasomotion.

[肺泡气体中O2和CO2组成改变时颈动脉主动脉及其分支血流的变化]。
我们使用范围门控多普勒测速仪测量颈动脉总血流,并使用连续多普勒测量正常气压下的20名低地人的颈动脉总血流,在海拔462托尔(61.6千帕)的高海拔室内的10名受试者的内外血流,然后在海拔3850米(475托尔= 63.3千帕)的3周时间内对其中5名受试者进行测量。在海拔3850米的20名常住居民中也进行了相同的测量。在所有暴露于高海拔的受试者中,颈总动脉血流量增加了15%,这是由于全身血压在高海拔没有变化,导致下游阻力降低。颈总动脉血流的增加是由于在海拔舱和到达高海拔后观察到的颈内动脉血流速度立即增加的结果,但几天后,颈内动脉的血流速度下降到与在海平面观察到的速度相似的值。与此同时,颈外动脉流速在高海拔地区上升,并保持稳定升高,结果是颈总动脉血流在高海拔地区永久性增加。在所有受试者中,我们在急性吸入混合气体期间进行了相同的测量,试图量化在改变气体吸入时控制颈总动脉血流量变化的机制。在PO2 (60 ~ 400 Torr)和PCO2 (30 ~ 50 Torr)变化的极限内,CO2刺激血管舒缩的效率是O2刺激血管舒缩的两倍。
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