利用猪盲肠模型研究两种 A 型原花青素的肠道代谢：采用傅里叶变换质谱（FTMS）详细阐明未知代谢产物的结构。

Intestinal metabolism of two A-type procyanidins using the pig cecum model: detailed structure elucidation of unknown catabolites with Fourier transform mass spectrometry (FTMS).

机构信息

NRW Graduate School of Chemistry, Westfälische Wilhelms-Universität Münster, Wilhelm-Klemm-Strasse 10, 48149 Münster, Germany.

出版信息

J Agric Food Chem. 2012 Jan 25;60(3):749-57. doi: 10.1021/jf203927g. Epub 2012 Jan 13.

DOI:10.1021/jf203927g

PMID:22175758

Abstract

Procyanidins, as important secondary plant metabolites in fruits, berries, and beverages such as cacao and tea, are supposed to have positive health impacts, although their bioavailability is yet not clear. One important aspect for bioavailability is intestinal metabolism. The investigation of the microbial catabolism of A-type procyanidins is of great importance due to their more complex structure in comparison to B-type procyanidins. A-type procyanidins exhibit an additional ether linkage between the flavan-3-ol monomers. In this study two A-type procyanidins, procyanidin A2 and cinnamtannin B1, were incubated in the pig cecum model to mimic the degradation caused by the microbiota. Both A-type procyanidins were degraded by the microbiota. Procyanidin A2 as a dimer was degraded by about 80% and cinnamtannin B1 as a trimer by about 40% within 8 h of incubation. Hydroxylated phenolic compounds were quantified as degradation products. In addition, two yet unknown catabolites were identified, and the structures were elucidated by Fourier transform mass spectrometry.

摘要

原花青素作为水果、浆果和可可、茶等饮料中的重要次生植物代谢物，据称对健康有积极影响，尽管它们的生物利用度尚不清楚。生物利用度的一个重要方面是肠道代谢。由于 A 型原花青素的结构比 B 型原花青素更为复杂，因此研究其微生物代谢具有重要意义。A 型原花青素在黄烷-3-醇单体之间具有额外的醚键连接。在这项研究中，两种 A 型原花青素，原花青素 A2 和肉桂单宁 B1，在猪盲肠模型中孵育，以模拟微生物群引起的降解。两种 A 型原花青素都被微生物群降解。二聚体原花青素 A2 在孵育 8 小时内被降解约 80%，三聚体肉桂单宁 B1 被降解约 40%。羟基化酚类化合物被定量为降解产物。此外，还鉴定出两种未知的代谢产物，并通过傅里叶变换质谱法阐明了它们的结构。

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利用猪盲肠模型研究两种 A 型原花青素的肠道代谢：采用傅里叶变换质谱（FTMS）详细阐明未知代谢产物的结构。

Intestinal metabolism of two A-type procyanidins using the pig cecum model: detailed structure elucidation of unknown catabolites with Fourier transform mass spectrometry (FTMS).

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