Non-enzymatic antioxidant blood plasma profile in the period of high training loads of elite speed skaters in the altitude

IF 2.3 Q2 SPORT SCIENCES
Elena Proskurnina , Dmitry Martynov , Andrey Yakushkin , Irina Zelenkova
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Abstract

At the altitude, hypoxia and training load are key factors in the development of oxidative stress. Altitude-induced oxidative stress is developed due to the depletion of antioxidant potential. In the current study, we examined the non-enzymatic antioxidant profile of blood plasma in 7 males and 5 females specializing in speed skating at a 21-day training camp at 1 850 ​m above sea level. Training included: cycling, roller skating, ice skating, strength training, and special training. At the start point and the endpoint, total hemoglobin mass (tHb-mass), hemoglobin concentration, and circulating blood volume were determined. Antioxidant profiles, hypoxic doses, hypoxic impulses, and training impulses were assessed at 3, 6, 10, 14, and 18 days. Antioxidant profiles consisting of “urate” and “thiol” parts were registered with chemiluminometry. In the training dynamics, antioxidant parameters changed individually, but in total there was a decrease in the “urate” capacity by a factor of 1.6 (p ​= ​0.001) and an increase in the “thiol” capacity by a factor of 1.8 (p ​= ​0.013). The changes in “urate” capacity positively correlated (rS ​= ​0.40) and the changes in “thiol” capacity negatively correlated (rS ​= ​−0.45) with changes in tHb-mass. Both exercise and hypoxic factors affect the antioxidant parameters bidirectionally. They correlated with a decrease in thiol capacity and with an increase in urate capacity. The assessment of the non-enzymatic antioxidant profile can be a simple and useful addition to screening the reactive oxygen species homeostasis and can help choose the personalized training schedule, individualize recovery and ergogenic support.

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高原优秀速滑运动员高训练负荷时期血浆非酶抗氧化特征
在高原,缺氧和训练负荷是氧化应激发展的关键因素。高原诱导的氧化应激是由于抗氧化潜力的耗尽而产生的。在目前的研究中,我们在1 850的21天训练营中,对7名专门从事速度滑冰的男性和5名女性的血浆中的非酶抗氧化剂进行了检测​海拔m。训练包括:自行车、轮滑、滑冰、力量训练和专项训练。在起始点和终点,测定总血红蛋白质量(tHb质量)、血红蛋白浓度和循环血容量。在第3天、第6天、第10天、第14天和第18天评估抗氧化剂概况、缺氧剂量、缺氧冲动和训练冲动。用化学发光法记录了由“尿酸盐”和“硫醇”部分组成的抗氧化剂图谱。在训练动力学中,抗氧化参数单独变化,但总的来说,“尿酸盐”能力下降了1.6倍(p​=​0.001),“硫醇”容量增加1.8倍(p​=​0.013)。“尿酸盐”容量的变化呈正相关(rS​=​0.40)和“硫醇”容量的变化呈负相关(rS​=​−0.45)随tHb质量的变化而变化。运动和低氧因素都会双向影响抗氧化参数。它们与硫醇容量的降低和尿酸盐容量的增加相关。非酶促抗氧化剂谱的评估可以是筛选活性氧稳态的一个简单而有用的补充,并有助于选择个性化的训练计划、个性化的恢复和工效学支持。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Sports Medicine and Health Science
Sports Medicine and Health Science Health Professions-Physical Therapy, Sports Therapy and Rehabilitation
CiteScore
5.50
自引率
0.00%
发文量
36
审稿时长
55 days
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