Nakamura Sadako, Tanabe Kenichi, Morita Shigeki, Hamaguchi Norihisa, Shimura Fumio, Oku Tsuneyuki
Institute of Food, Nutrition and Health, Jumonji University, 2-1-28, Sugasawa, Niiza, Saitama 352-8510 Japan ; Graduate School of Human Health Science, University of Nagasaki Siebold, 1-1-1, Manabino, , Nagayo, Nagasaki 851-2195 Japan.
Graduate School of Human Health Science, University of Nagasaki Siebold, 1-1-1, Manabino, , Nagayo, Nagasaki 851-2195 Japan ; Department of Food Science and Nutrition, Nagoya Women's University, 3-40, Shioji, Mizuho-ku, Nagoya 467-8610 Japan.
Nutr Metab (Lond). 2016 Feb 16;13:13. doi: 10.1186/s12986-016-0073-2. eCollection 2016.
Resistant glucan (RG) and hydrogenated resistant glucan (HRG) are new dietary fiber materials developed to decrease the risk of metabolic syndrome and lifestyle-related diseases. We investigated the metabolism and bioavailability of RG and HRG using rats and humans.
Purified RG and HRG were used as test substances. After 25 Wistar male rats (270 g) were fed with an experimental diet (AIN93M diet with the cellulose replaced by β-corn starch) ad libitum for 1 week, they were used for the experiment involving blood collection and circulating air collection. Ten participants (5 males, 22.5 y, BMI 20.4 kg/m(2); 5 females, 25.8 y, BMI 20.9 kg/m(2)) voluntarily participated in this study. The study was carried out using a within-subject, repeated measures design. Effects of RG and HRG on the response for blood glucose and insulin and hydrogen excretion were compared with those of glucose and a typical nondigestible and fermentable fructooligosaccharide (FOS) in rats and humans. Available energy was evaluated using the fermentability based on breath hydrogen excretion.
When purified RG or HRG (400 mg) was administered orally to rats, blood glucose and insulin increased slightly, but less than when glucose was administration (P < 0.05). Hydrogen started to be excreted 120 min after administration of RG with negligibly small peak at 180 min, thereafter excreted scarcely until 1440 min. Hydrogen excretion after HRG administration showed a larger peak than RG at 180 min, but was markedly less than FOS. RG and HRG were excreted in feces, but not urine. When purified RG or HRG (30 g) were ingested by healthy humans, blood glucose and insulin levels increased scarcely. Breath hydrogen excretion increased slightly, but remarkably less than FOS. Ingestion of purified RG or HRG (5 g) to evaluate available energy, increased scarcely glucose and insulin levels and breath hydrogen excretion. Available energy was evaluated as 0 kcal/g for purified RG and 1 kcal/g for HRG.
The bioavailability was very low in both humans and rats, because oligosaccharide of minor component in purified RG and HRG was metabolized via intestinal microbes but major components with higher molecular weight were metabolized scarcely. Moreover, the ingestion of 30 g of RG or HRG did not induce apparent acute side effects in healthy adults. RG and HRG might potentially be used as new dietary fiber materials with low energy.
抗性葡聚糖(RG)和氢化抗性葡聚糖(HRG)是为降低代谢综合征及生活方式相关疾病风险而研发的新型膳食纤维材料。我们使用大鼠和人类研究了RG和HRG的代谢及生物利用度。
使用纯化的RG和HRG作为受试物质。25只雄性Wistar大鼠(270克)自由采食实验饲料(用β - 玉米淀粉替代纤维素的AIN93M饲料)1周后,用于采血和循环空气收集实验。10名参与者(5名男性,22.5岁,BMI 20.4 kg/m²;5名女性,25.8岁,BMI 20.9 kg/m²)自愿参与本研究。研究采用受试者内重复测量设计。将RG和HRG对血糖、胰岛素反应及氢气排泄的影响与葡萄糖以及典型的不可消化且可发酵的低聚果糖(FOS)在大鼠和人类中的影响进行比较。基于呼气氢气排泄的发酵性评估可用能量。
给大鼠口服纯化的RG或HRG(400毫克)后,血糖和胰岛素略有升高,但低于给予葡萄糖时(P < 0.05)。给予RG后120分钟开始排泄氢气,180分钟时峰值极小,此后直至1440分钟几乎不再排泄。给予HRG后氢气排泄在180分钟时峰值大于RG,但明显低于FOS。RG和HRG经粪便排泄,而非尿液。健康人摄入纯化的RG或HRG(30克)后,血糖和胰岛素水平几乎未升高。呼气氢气排泄略有增加,但明显低于FOS。摄入纯化的RG或HRG(5克)以评估可用能量,血糖、胰岛素水平及呼气氢气排泄几乎未增加。纯化RG的可用能量评估为0千卡/克,HRG为1千卡/克。
在人类和大鼠中生物利用度均非常低,因为纯化的RG和HRG中少量成分的低聚糖经肠道微生物代谢,而高分子量的主要成分几乎不被代谢。此外,摄入30克RG或HRG在健康成年人中未引发明显的急性副作用。RG和HRG可能有潜力作为低能量的新型膳食纤维材料。
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