Reduced serum concentrations of reactive oxygen and nitrogen species following strenuous exercise in the heat are not associ-ated with an upregulation in serum antioxidative capacity

IF 0.7 Q4 SPORT SCIENCES

Baltic Journal of Health and Physical Activity Pub Date : 2022-12-31 DOI:10.29359/bjhpa.14.4.03

Sebastian Keller, H. Notbohm, W. Bloch, M. Schumann

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Abstract

Introduction: Reactive oxygen and nitrogen species (RONS) are produced as a response to exercise and play a part in guiding the adaptive response to physical training. Exercise in the heat has been shown to further increase accumulation of RONS in systemic circulation; however, a high anti-oxidative response or heat acclimatization mechanisms could attenuate this response. In a previous study, we found reduced RONS concentrations in trained athletes following strenuous cycling in the heat. Therefore, this secondary analysis assessed whether these reduced RONS serum con-centrations are induced by an increased serum antioxidant capacity. Methods: Twelve male cyclists (V̇O2peak: 60 ± 4 ml ∙ kg-1 ∙ min-1) completed a 60-minute constant workload trial (55% peak power output, ambient temperature 30.4 ± 0.6°C) with and without ice vest in a randomized order. The core body temperature (Tcore) was measured by an ingestible capsule. Blood samples were col-lected before and after each trial to determine superoxide dismutase (SOD) and catalase (CAT) activity, total antioxidant capacity (TAC) and RONS. Due to the absence of between-group dif-ferences, data of both conditions were pooled. Results: Tcore statistically increased (p < 0.001) over the experimental trials (+6.0 ± 1.6%, effect size (ES) = 5.6). Concentrations of RONS (-17.2 ± 15.5%, p < 0.001, ES = 1.0) and TAC (-8.9 ± 22.9%, p = 0.04, ES = 0.7) statistically decreased, while the activity of CAT (+15.5 ± 84.0%, p = 0.90, ES = 0.04) and SOD (+9.2 ± 58.7%, p = 0.98, ES = 0.01) remained un-changed. Conclusions: Reduced serum RONS concentrations after strenuous cycling in the heat were not associated with upregulation of serum antioxidant capacity in trained athletes. The prooxidant-antioxidant balance may rather be regulated at a myocellular level and should be further assessed in future studies.

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高温剧烈运动后血清活性氧和活性氮浓度的降低与血清抗氧化能力的上调无关

摘要:活性氧和活性氮(Reactive oxygen and nitrogen species, RONS)是机体对运动产生的反应，在指导机体对运动的适应性反应中起着重要作用。高温下的运动已被证明会进一步增加体循环中活性氧的积累;然而，高抗氧化反应或热驯化机制可能会减弱这种反应。在之前的一项研究中，我们发现训练有素的运动员在高温下剧烈骑行后，其ron浓度会降低。因此，这项二级分析评估了这些降低的RONS血清浓度是否是由血清抗氧化能力增加引起的。方法:12名男性骑自行车者(V (o) 2峰值:60±4 ml∙kg-1∙min-1)，以随机顺序完成60分钟恒定负荷试验(55%峰值功率输出，环境温度30.4±0.6°C)。核心体温(Tcore)采用可摄取胶囊测量。每次试验前后均采集血样，测定超氧化物歧化酶(SOD)和过氧化氢酶(CAT)活性、总抗氧化能力(TAC)和活性氧自由基(RONS)。由于没有组间差异，因此将两种情况的数据合并。结果:Tcore较实验组有统计学差异(p < 0.001)(+6.0±1.6%，效应量(ES) = 5.6)。小鼠血清中活性氧(-17.2±15.5%，p < 0.001, ES = 1.0)和活性氧(-8.9±22.9%，p = 0.04, ES = 0.7)含量均有统计学意义降低，而CAT(+15.5±84.0%，p = 0.90, ES = 0.04)和SOD(+9.2±58.7%，p = 0.98, ES = 0.01)活性保持不变。结论:在训练有素的运动员中，在高温下剧烈骑行后血清RONS浓度的降低与血清抗氧化能力的上调无关。促氧化-抗氧化平衡可能是在心肌细胞水平上调节的，应该在未来的研究中进一步评估。

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