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锌强化即食预煮米的体外生物利用度及淀粉水解研究() 。 你提供的原文括号部分内容缺失,请补充完整以便能准确完整地翻译。

Studies on in vitro bioavailability and starch hydrolysis in zinc fortified ready-to-eat parboiled rice ().

作者信息

Wahengbam Elizabeth D, Das Arup Jyoti, Green Brian D, Hazarika Manuj K

机构信息

1Department of Food Engineering and Technology, Tezpur University, Assam, 784028 India.

2Institute for Global Food Security, Queen's University Belfast, Belfast, BT9 5HN UK.

出版信息

J Food Sci Technol. 2019 Jul;56(7):3399-3407. doi: 10.1007/s13197-019-03824-4. Epub 2019 Jun 8.

DOI:10.1007/s13197-019-03824-4
PMID:31274908
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC6582095/
Abstract

Zinc fortified parboiled rice () was produced from a low amylose variety of rice by applying 'brown rice parboiling' method. In addition to the effect of milling on fortification, the effectiveness of fortification upon the amount of bioaccessible (in vitro digest) and bioavailable (cellular uptake) form of Zn was tested. The effect on glycaemic index was also assessed by employing an in vitro starch hydrolysis assay. The bioaccessible form of Zn in the unmilled fortified rice were ranged in between 4.24 and 11.07 mg/100 g, which was significantly higher ( < 0.05) than the milled and unfortified parboiled rice. Similarly, the % absorption of bioavailable Zn was negligible in the unfortified parboiled rice as compared to the fortified rice (14.5-24.5%). The estimated GI of fortified parboiled rice samples was in the range of 50.97-59.79, which was lower than the unfortified parboiled rice (58.80-62.53) and raw rice (78.71-84.64). The results thus demonstrated that Zn fortified can be a novel and rapidly produced micronutrient enhanced ready-to-eat rice.

摘要

锌强化半熟米()是通过“糙米半熟化”方法由低直链淀粉品种的大米制成的。除了碾磨对强化的影响外,还测试了强化对锌的生物可利用形式(体外消化)和生物可利用形式(细胞摄取)量的有效性。还通过体外淀粉水解试验评估了对血糖指数的影响。未碾磨的强化米中锌的生物可利用形式含量在4.24至11.07毫克/100克之间,显著高于碾磨和未强化的半熟米(<0.05)。同样,与强化米(14.5 - 24.5%)相比,未强化的半熟米中生物可利用锌的吸收率可忽略不计。强化半熟米样品的估计血糖生成指数在50.97至59.79范围内,低于未强化的半熟米(58.80至62.53)和糙米(78.71至84.64)。结果表明,锌强化米可以是一种新型且能快速生产的富含微量营养素的即食大米。

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