新型合成物AG1®在人类肠道微生物生态系统(SHIME)模型模拟器中增加短链脂肪酸的产生

Trevor O. Kirby, Jeremy R. Townsend, Philip A. Sapp, Marlies Govaert, Cindy Duysburgh, Tess M. Marshall, Massimo Marzorati, Ralph Esposito
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摘要

最近,有越来越多的使用益生元和益生菌作为膳食补充剂,由于他们声称的健康益处。AG1®(AG1)是一种新型的基础营养补充剂,含有维生素、矿物质、植物营养素、天然浓缩物、适应原和功能蘑菇。AG1可以被归类为合成菌,因为它含有传统和非传统的益生元(如菊粉和植物营养素)以及产生乳酸的益生菌。本研究的目的是利用人类肠道微生物生态系统模拟器(SHIME®)模型,测量胃肠道发酵的各个方面,研究AG1的合成效应。在施用AG1或空白对照后的基线、1、24和48 h, SHIME实验量化了产气量、pH变化以及碳水化合物和蛋白质发酵的副产物。结果表明,AG1显著升高(p <0.05;总短链脂肪酸(SCFAs)的产量(包括乙酸)增加41.9% (p = 0.001;49.0%)和丙酸(p <0.001;增加70.8%)。在非碳水化合物发酵副产物中,AG1对铵产量的影响虽小但显著(p = 0.02);增加5.1%),但没有显著促进支链短链脂肪酸的生产。这些数据表明,发酵发生在移植的人类结肠微生物群中,这些过程被AG1营养补充剂增强。最终,AG1作为一种合成物显示出临床前证据,因为它显著增加了总SCFA产量、醋酸盐、丙酸盐和其他发酵代谢副产物。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
The Novel Synbiotic, AG1®, Increases Short-Chained Fatty Acid Production in the Simulator of Human Intestinal Microbial Ecosystem (SHIME) Model®
Recently, there is growing usage of prebiotics and probiotics as dietary supplements due to their purported health benefits. AG1® (AG1) is a novel foundational nutrition supplement which contains vitamins, minerals, phytonutrients, wholefood concentrates, adaptogens, and functional mushrooms. AG1 could be classified as a synbiotic because it contains traditional and non-traditional prebiotics (e.g., inulin and phytonutrients) as well as lactic-acid-producing probiotics. The purpose of this study was to employ the Simulator of Human Intestinal Microbial Ecosystem (SHIME®) model, which measures various aspects of gastrointestinal fermentation, to investigate the synbiotic effects of AG1. The SHIME experiment quantified gas production, changes in pH, and byproducts of carbohydrate and protein fermentation at baseline, 1, 24, and 48 h following the administration of AG1 or a blank control. The results indicated that AG1 significantly increased (p < 0.05; 41.9% increase) the production of total short-chain fatty acids (SCFAs) including acetate (p = 0.001; 49.0% increase) and propionate (p < 0.001; 70.8% increase). Regarding non-carbohydrate fermentation byproducts, AG1 produced a small but significant increase in ammonium production (p = 0.02; 5.1% increase) but did not promote significant branched-chain SCFA production. These data suggest fermentation occurred in a transplanted human colonic microbiota and these processes were enhanced by the AG1 nutritional supplement. Ultimately, AG1 showed preclinical evidence as a synbiotic given the significant increases in total SCFA production, acetate, propionate, and other metabolic byproducts of fermentation.
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