Exposure to microgravity alters the distribution of body fluids and the degree of distension of cranial blood vessels, and these changes in turn may provoke structural remodelling and altered cerebral autoregulation. Impaired cerebral autoregulation has been documented following weightlessness simulated by head-down bed rest in humans, and is proposed as a mechanism responsible for postspaceflight orthostatic intolerance. In this study, we tested the hypothesis that spaceflight impairs cerebral autoregulation. We studied six astronauts ∼72 and 23 days before, after 1 and 2 weeks in space (n = 4), on landing day, and 1 day after the 16 day Neurolab space shuttle mission. Beat-by-beat changes of photoplethysmographic mean arterial pressure and transcranial Doppler middle cerebral artery blood flow velocity were measured during 5 min of spontaneous breathing, 30 mmHg lower body suction to simulate standing in space, and 10 min of 60 deg passive upright tilt on Earth. Dynamic cerebral autoregulation was quantified by analysis of the transfer function between spontaneous changes of mean arterial pressure and cerebral artery blood flow velocity, in the very low- (0.02–0.07 Hz), low- (0.07–0.20 Hz) and high-frequency (0.20–0.35 Hz) ranges. Resting middle cerebral artery blood flow velocity did not change significantly from preflight values during or after spaceflight. Reductions of cerebral blood flow velocity during lower body suction were significant before spaceflight (P < 0.05, repeated measures ANOVA), but not during or after spaceflight. Absolute and percentage reductions of mean (±s.e.m.) cerebral blood flow velocity after 10 min upright tilt were smaller after than before spaceflight (absolute, −4 ± 3 cm s−1 after versus−14 ± 3 cm s−1 before, P = 0.001; and percentage, −8.0 ± 4.8% after versus−24.8 ± 4.4% before, P < 0.05), consistent with improved rather than impaired cerebral blood flow regulation. Low-frequency gain decreased significantly (P < 0.05) by 26, 23 and 27% after 1 and 2 weeks in space and on landing day, respectively, compared with preflight values, which is also consistent with improved autoregulation. We conclude that human cerebral autoregulation is preserved, and possibly even improved, by short-duration spaceflight.
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机译:暴露于微重力下会改变体液的分布和颅内血管的扩张程度,而这些变化反过来可能会引起结构重塑和大脑自动调节的改变。在人类通过头朝下卧床休息模拟失重之后,已经证明了大脑自动调节功能受损,并被认为是造成航天后体位性不耐受的机制。在这项研究中,我们测试了太空飞行会损害大脑自动调节的假设。我们对6名宇航员进行了研究,分别在72天之前,大约72天和23天,在太空中经过1和2周(n = 4),着陆日以及16天Neurolab航天飞机飞行任务之后的1天。在5分钟的自发呼吸,30 mmHg的下半身吸力以模拟在空间中站立以及10分钟的60度被动直立倾斜过程中,测量光电容积描记器的平均动脉压和经颅多普勒大脑中动脉的血流速度变化地球。通过分析在非常低的(0.02–0.07 Hz),低的(0.07–0.20 Hz)和高频的(平均动脉压自发变化)与脑动脉血流速度之间的传递函数来量化动态大脑自动调节。 0.20–0.35 Hz)范围。在飞行过程中或飞行后,静息的大脑中动脉血流速度与飞行前的值相比无明显变化。在航天飞行之前,下半身吸气期间脑血流速度的降低是显着的(P <0.05,重复测量方差分析),但航天飞行期间或之后则没有。直立倾斜10分钟后的平均(±sem)脑血流量绝对值和百分比降低幅度小于航天飞行前(绝对值-4±3 cm s -1 与-14±3 cm s −1 之前为P = 0.001;百分比为-8.0±4.8%,之后为-24.8±4.4%,P <0.05),与改善而不是削弱脑血流调节一致。与飞行前值相比,在太空飞行1天和2周后,低频增益分别显着下降(P <0.05)26%,23%和27%,这与飞行前值相比也是如此。我们得出的结论是,通过短时航天飞行可以保留甚至可能改善人的大脑自动调节功能。
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