Hydrogen produced in rat colon improves in vivo redox balance due to induced regeneration of α-tocopherol

Yosuke Ishida, Shingo Hino, Tatsuya Morita, Saiko Ikeda, Naomichi Nishimura

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DOI: 10.1017/S0007114519003118 DOI is the universal ID for this study.

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We investigated whether non-digestible saccharide fermentation-derived hydrogen molecules (H 2 ) in rat colon could improve the in vivo reduction–oxidation balance via regeneration of α-tocopherol, by assessing their effect on hydroxyl radicals, the α-tocopherol concentration and the reduction–oxidation balance. In experiment 1, a Fenton reaction with phenylalanine (0 or 1.37 mmol/L of H 2 ) was conducted. In experiment 2, rats received intraperitoneally 400 mg/kg of corn oil containing phorone, 7 days after drinking ad libitum water containing 0 or 4% fructooligosaccharides (groups CP and FP, respectively). In experiment 3, rats unable to synthesise ascorbic acid, drank ad libitum for 14 days, water with 240 mg/L (group AC), 20 mg of ascorbic acid/L (group DC) or 20 mg of ascorbic acid/L and 4% fructooligosaccharides (group DCF). In the Fenton reaction, H 2 reduced tyrosine produced from phenylalanine to 72% when platinum was added and to 92% when platinum was excluded. In experiment 2, liver glutathione was depleted by administration of phorone to rats. However, compared with CP, no change in the m- tyrosine concentration in the liver of FP was detected. In experiment 3, net H 2 excretion was higher in DCF than in the other rats, 3 days after the experiment ended. Furthermore, the concentrations of H 2 and α-tocopherol and the reduction–oxidation glutathione ratio in perirenal adipose tissue of rats were significantly higher and lower, respectively, in DCF than in DC. To summarise, in rat colon, fermentation-derived H 2 further reduced the reduction–oxidation balance in perirenal adipose tissue through increased regeneration of α-tocopherol.

Publish Year 2019
Country Japan
Rank Positive
Journal British Journal of Nutrition
Primary Topic Whole Body
Secondary Topic ROS-Scavenging
Model Rat
Tertiary Topic Oxidative Stress
Vehicle Gas
pH N/A
Application In Vivo Biotic Production