Ecole Nationale des Sports de Montagne, site de l'Ecole Nationale de Ski et d'Alpinisme, Chamonix, France.
HP2, Université Grenoble Alpes, Grenoble, France.
Scand J Med Sci Sports. 2018 Jun;28(6):1636-1652. doi: 10.1111/sms.13075. Epub 2018 Mar 22.
Live high-train low (LHTL) using hypobaric hypoxia was previously found to improve sea-level endurance performance in well-trained individuals; however, confirmatory controlled data in athletes are lacking. Here, we test the hypothesis that natural-altitude LHTL improves aerobic performance in cross-country skiers, in conjunction with expansion of total hemoglobin mass (Hb , carbon monoxide rebreathing technique) promoted by accelerated erythropoiesis. Following duplicate baseline measurements at sea level over the course of 2 weeks, nineteen Norwegian cross-country skiers (three women, sixteen men, age 20 ± 2 year, maximal oxygen uptake (VO max) 69 ± 5 mL/min/kg) were assigned to 26 consecutive nights spent at either low (1035 m, control, n = 8) or moderate altitude (2207 m, daily exposure 16.7 ± 0.5 hours, LHTL, n = 11). All athletes trained together daily at a common location ranging from 550 to 1500 m (21.2% of training time at 550 m, 44.2% at 550-800 m, 16.6% at 800-1100 m, 18.0% at 1100-1500 m). Three test sessions at sea level were performed over the first 3 weeks after intervention. Despite the demonstration of nocturnal hypoxemia at moderate altitude (pulse oximetry), LHTL had no specific effect on serum erythropoietin, reticulocytes, Hb , VO max, or 3000-m running performance. Also, LHTL had no specific effect on (a) running economy (VO assessed during steady-state submaximal exercise), (b) respiratory capacities or efficiency of the skeletal muscle (biopsy), and (c) diffusing capacity of the lung. This study, showing similar physiological responses and performance improvements in the two groups following intervention, suggests that in young cross-country skiers, improvements in sea-level aerobic performance associated with LHTL may not be due to moderate-altitude acclimatization.
先前的研究发现,采用低压低氧的高住低训(LHTL)可以提高训练有素个体的海平面耐力表现;然而,在运动员中缺乏证实性的对照数据。在这里,我们测试了这样一个假设,即在自然高海拔地区进行 LHTL 可以结合通过加速红细胞生成而促进的总血红蛋白质量(Hb,一氧化碳再呼吸技术)的扩张,从而提高越野滑雪运动员的有氧运动表现。在两周的时间内,19 名挪威越野滑雪运动员(3 名女性,16 名男性,年龄 20±2 岁,最大摄氧量(VO2max)69±5mL/min/kg)进行了两次重复的基线测量,然后被分配到 26 个连续的夜晚,分别在低海拔(1035m,对照组,n=8)或中海拔(2207m,每天暴露 16.7±0.5 小时,LHTL,n=11)。所有运动员都在一个共同的地点进行日常训练,海拔范围从 550 到 1500m(21.2%的训练时间在 550m,44.2%在 550-800m,16.6%在 800-1100m,18.0%在 1100-1500m)。在干预后的前 3 周进行了 3 次海平面测试。尽管中海拔时显示出夜间低氧血症(脉搏血氧饱和度),但 LHTL 对血清促红细胞生成素、网织红细胞、Hb、VO2max 或 3000m 跑步表现没有特异性影响。此外,LHTL 对(a)跑步经济性(在稳定状态的次最大运动中评估的 VO)、(b)骨骼肌的呼吸能力或效率(活检)以及(c)肺的弥散能力均无特异性影响。本研究表明,在年轻的越野滑雪运动员中,两组在干预后表现出相似的生理反应和运动表现的提高,这表明在年轻的越野滑雪运动员中,与 LHTL 相关的海平面有氧运动表现的提高可能不是由于中海拔适应所致。
