Torres Duarte P M, Gonçalves Maria do Pilar F, Teixeira José A, Rodrigues Lígia R
Authors Torres and Rodrigues are with Biotempo-Biotechnology Consulting Ltd. Spinpark-Centro de Incubação de Base Tecnológica, Avepark, 4805-017 Guimarães, Portugal. Authors Torres, Teixeira, and Rodrigues are with IBB-Inst. for Biotechnology and Bioengineering, Centre of Biological Engineering, Univ. do Minho, 4710-057 Braga, Portugal. Author Torres is with Faculty of Nutrition and Food Sciences, Univ. of Porto, Rua Dr. Roberto Frias, 4200-465 Porto, Portugal. Author Gonçalves is with REQUIMTE, Dept. de Engenharia Química, Faculdade de Engenharia da Univ. do Porto, Rua Dr. Roberto Frias, 4200-465 Porto, Portugal. Direct inquiries to author Torres (E-mail:
Compr Rev Food Sci Food Saf. 2010 Sep;9(5):438-454. doi: 10.1111/j.1541-4337.2010.00119.x.
Galacto-oligosaccharides (GOS) have now been definitely established as prebiotic ingredients after in vitro and animal and human in vivo studies. Currently, GOS are produced by glycoside hydrolases (GH) using lactose as substrate. Converting lactose into GOS by GH results in mixtures containing GOS of different degrees of polymerization (DP), unreacted lactose, and monomeric sugars (glucose and galactose). Recent and future developments in the production of GOS aim at delivering purer and more efficient mixtures. To produce high-GOS-content mixtures, GH should not only have good ability to catalyze the transgalactosylation reaction relative to hydrolysis, but also have low affinity for the GOS formed relative to the affinity for lactose. In this article, several microbial GH, proposed for the synthesis of GOS, are hierarchized according to the referred performance indicators. In addition, strategies for process improvement are discussed. Besides the differences in purity of GOS mixtures, differences in the position of the glycosidic linkages occur, because different enzymes have different regiochemical selectivity. Depending on oligosaccharide composition, GOS products will vary in terms of prebiotic activity, as well as other physiological effects. This review focuses on GOS production from synthesis to purification processes. Physicochemical characteristics, physiological effects, and applications of these prebiotic ingredients are summarized. Regulatory aspects of GOS-containing food products are also highlighted with emphasis on the current process of health claims evaluation in Europe.
经过体外、动物及人体体内研究,低聚半乳糖(GOS)现已被明确认定为益生元成分。目前,低聚半乳糖是通过糖苷水解酶(GH)以乳糖为底物生产的。利用糖苷水解酶将乳糖转化为低聚半乳糖会得到包含不同聚合度(DP)的低聚半乳糖、未反应的乳糖以及单糖(葡萄糖和半乳糖)的混合物。低聚半乳糖生产的近期及未来发展目标是提供更纯净、更高效的混合物。为了生产高含量低聚半乳糖的混合物,糖苷水解酶不仅应具有相对于水解反应而言良好的催化转半乳糖基化反应的能力,而且相对于对乳糖的亲和力,对形成的低聚半乳糖的亲和力应较低。在本文中,根据所提及的性能指标,对几种提议用于合成低聚半乳糖的微生物糖苷水解酶进行了分级。此外,还讨论了工艺改进策略。除了低聚半乳糖混合物纯度的差异外,糖苷键连接位置也存在差异,因为不同的酶具有不同的区域化学选择性。根据寡糖组成,低聚半乳糖产品在益生元活性以及其他生理效应方面会有所不同。本综述重点关注低聚半乳糖从合成到纯化过程的生产情况。总结了这些益生元成分的物理化学特性、生理效应及应用。还强调了含低聚半乳糖食品的监管方面,重点介绍了欧洲目前的健康声明评估流程。
