Sugita Masaaki, Kapoor Mahendra P, Nishimura Akinobu, Okubo Tsutomu
Faculty of Education, University of Mie, Tsu city, Mie, Japan.
Taiyo Kagaku Co. Ltd., Nutrition Division, Yokkaichi, Mie, Japan.
Nutrition. 2016 Mar;32(3):321-31. doi: 10.1016/j.nut.2015.09.005. Epub 2015 Sep 28.
The aim of this study was to investigate the effects of green tea catechins (GTC) on oxidative stress metabolites in healthy individuals while at rest and during exercise. The effects investigated included response to fat metabolism, blood lactate concentrations, and rating of perceived exertion.
In a paralleled, crossover, randomized controlled study, 16 trained male gymnastic students were randomly divided into two groups. The rest group (n = 8; GTC-NEX) received a single dose of 780 mg GTC with water but no exercise; the exercise group (n = 8; GTC-EX) received a similar dose of GTC but were instructed to exercise. This was followed by a crossover study with similar exercise regime as a placebo group (PL-EX) that received water only. Blood samples were collected at baseline and after 60 and 120 min of GTC intake. Oxidative stress blood biomarkers using the diacron reactive oxygen metabolite (d-ROMs) and biological antioxidant potential (BAP) tests; urinary 8-hydroxydeoxyguanosine (8-OHdG); 8-OHdG/creatinine; and blood lactate concentrations were analyzed. During the cycle ergometer exercise, volume of maximal oxygen uptake, volume of oxygen consumption, volume of carbon dioxide, and respiratory exchange ratio were measured from a sample of respiratory breath gas collected during low, moderate, and high intensity exercising, and the amount of fat burning and sugar consumption were calculated. Analysis of variance was used to determine statistical significance (P < 0.05) between and among the groups.
Levels of postexercise oxidative stress metabolites BAP and d-ROMs were found significant (P < 0.0001) in the PL-EX and GTC-EX groups, and returned to pre-exercise levels after the recovery period. Levels of d-ROMs showed no significant difference from baseline upon GTC intake followed by resting and a resting recovery period in the GTC-NEX group. BAP levels were significant upon GTC intake followed by resting (P = 0.04), and after a resting recovery period (P = 0.0006) in the GTC-NEX group. Urinary 8-OHdG levels were significant (P < 0.005) for all groups after the recovery period. A significant difference was noticed between the ratios of resting BAP to d-ROMs and exercise-induced BAP to d-ROMs (P = 0.022) after 60 min of GTC intake, as well as resting 8-OHdG and exercise-induced 8-OHdG levels (P = 0.004) after the recovery period. Oxidative potentials were higher when exercise was performed at low to moderate intensity, accompanied by lower blood lactate concentration and higher amounts of fat oxidation.
The results of the present study indicate that single-dose consumption of GTC influences oxidative stress biomarkers when compared between the GTC-NEX and GTC-EX groups, which could be beneficial for oxidative metabolism at rest and during exercise, possibly through the catechol-O-methyltransferase mechanism that is most often cited in previous studies.
本研究旨在调查绿茶儿茶素(GTC)对健康个体在静息和运动状态下氧化应激代谢产物的影响。所研究的影响包括对脂肪代谢的反应、血乳酸浓度和主观用力程度分级。
在一项平行、交叉、随机对照研究中,16名受过训练的男性体操学生被随机分为两组。静息组(n = 8;GTC-NEX)服用单剂量780毫克GTC并饮水,但不进行运动;运动组(n = 8;GTC-EX)服用相似剂量的GTC,但被要求进行运动。随后进行交叉研究,设置与仅饮水的安慰剂组(PL-EX)相似的运动方案。在基线以及摄入GTC后60分钟和120分钟采集血样。使用戴克隆活性氧代谢产物(d-ROMs)和生物抗氧化能力(BAP)测试分析氧化应激血液生物标志物;检测尿8-羟基脱氧鸟苷(8-OHdG);8-OHdG/肌酐;并分析血乳酸浓度。在功率自行车运动期间,从低、中、高强度运动时采集的呼吸气体样本中测量最大摄氧量、耗氧量、二氧化碳量和呼吸交换率,并计算脂肪燃烧量和糖消耗量。采用方差分析确定组间和组内的统计学显著性(P < 0.05)。
在PL-EX组和GTC-EX组中,运动后氧化应激代谢产物BAP和d-ROMs水平显著(P < 0.0001),恢复期后恢复到运动前水平。在GTC-NEX组中,摄入GTC后静息以及静息恢复期后,d-ROMs水平与基线相比无显著差异。GTC-NEX组在摄入GTC后静息时(P = 0.04)以及静息恢复期后(P = 0.0006),BAP水平显著。恢复期后所有组的尿8-OHdG水平均显著(P < 0.005)。摄入GTC 60分钟后,静息BAP与d-ROMs的比值和运动诱导的BAP与d-ROMs的比值之间存在显著差异(P = 0.022),恢复期后静息8-OHdG和运动诱导的8-OHdG水平之间也存在显著差异(P = 0.004)。在低至中等强度运动时氧化电位较高,同时血乳酸浓度较低,脂肪氧化量较高。
本研究结果表明,与GTC-NEX组和GTC-EX组相比,单剂量摄入GTC会影响氧化应激生物标志物,这可能有利于静息和运动期间的氧化代谢,可能是通过先前研究中最常提及的儿茶酚-O-甲基转移酶机制实现的。
