急性和慢性缺氧:对脑功能和运动耐力的影响。
Acute and chronic hypoxia: implications for cerebral function and exercise tolerance.
作者信息
Goodall Stuart, Twomey Rosie, Amann Markus
机构信息
Faculty of Health and Life Sciences, Northumbria University, Newcastle, UK.
School of Sport and Service Management, University of Brighton, Eastbourne, UK.
出版信息
Fatigue. 2014;2(2):73-92. doi: 10.1080/21641846.2014.909963.
PURPOSE
To outline how hypoxia profoundly affects neuronal functionality and thus compromise exercise-performance.
METHODS
Investigations using electroencephalography (EEG) and transcranial magnetic stimulation (TMS) detecting neuronal changes at rest and those studying fatiguing effects on whole-body exercise performance in acute (AH) and chronic hypoxia (CH) were evaluated.
RESULTS
At rest during very early hypoxia (<1-h), slowing of cerebral neuronal activity is evident despite no change in corticospinal excitability. As time in hypoxia progresses (3-h), increased corticospinal excitability becomes evident; however, changes in neuronal activity are unknown. Prolonged exposure (3-5 d) causes a respiratory alkalosis which modulates Na channels, potentially explaining reduced neuronal excitability. Locomotor exercise in AH exacerbates the development of peripheral-fatigue; as the severity of hypoxia increases, mechanisms of peripheral-fatigue become less dominant and CNS hypoxia becomes the predominant factor. The greatest central-fatigue in AH occurs when SO is ≤75%, a level that coincides with increasing impairments in neuronal activity. CH does not improve the level of peripheral-fatigue observed in AH; however, it attenuates the development of central-fatigue paralleling increases in cerebral O availability and corticospinal excitability.
CONCLUSIONS
The attenuated development of central-fatigue in CH might explain, the improvements in locomotor exercise-performance commonly observed after acclimatisation to high altitude.
目的
概述缺氧如何深刻影响神经元功能,进而损害运动表现。
方法
对使用脑电图(EEG)和经颅磁刺激(TMS)检测静息时神经元变化的研究,以及对急性缺氧(AH)和慢性缺氧(CH)状态下全身运动表现疲劳影响的研究进行评估。
结果
在极早期缺氧(<1小时)静息时,尽管皮质脊髓兴奋性无变化,但脑神经元活动明显减慢。随着缺氧时间延长(3小时),皮质脊髓兴奋性增加变得明显;然而,神经元活动的变化尚不清楚。长时间暴露(3 - 5天)会导致呼吸性碱中毒,从而调节钠通道,这可能解释了神经元兴奋性降低的原因。AH状态下的运动加剧了外周疲劳的发展;随着缺氧严重程度增加,外周疲劳机制的主导性降低,中枢神经系统缺氧成为主要因素。当血氧饱和度(SO)≤75%时,AH状态下出现最严重的中枢疲劳,这一水平与神经元活动的损害增加相吻合。CH状态下并未改善AH状态下观察到的外周疲劳水平;然而,它减弱了中枢疲劳的发展,这与脑氧供应和皮质脊髓兴奋性的增加平行。
结论
CH状态下中枢疲劳发展的减弱可能解释了通常在适应高海拔后观察到的运动表现改善的原因。
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