Exopolysaccharides from lactic acid bacteria: Techno-functional application in the food industry

Background: The growing consumer demand for foods that do not contain artificial additives and are ?clean labeled? can be addressed in fermented products by using lactic acid bacteria (LAB) capable of synthesizing exopolysaccharides (EPS). There is great variability in LAB-based EPS in terms of quantity, monomer composition, molecular weight, charge, and structure, which results in an array of physicochemical and rheological properties that can be exploited for varied applications in the food industry. Scope and approach: EPS are an alternative class of bio-thickeners widely used in the food industry. This review provides a brief overview of EPS composition and production, and highlights EPS functionality, focusing on specific areas and ways of applying them in food products. Key findings and conclusions: Although EPS-producing LAB strains have been traditionally applied in the manufacture of cultured milks, their use in the production process of low-fat cheeses, different plant-based yogurt alternatives, diverse types of sourdough breads, and reduced-fat fermented meat products are some of the novel applications of these polymers. EPS interact with other food components to improve the rheological and sensory properties of foods and, thus, they can act both as texturizers and stabilizers, increasing the viscosity and mouthfeel of products. Despite the abundance of research findings, a better understanding of the structure?function relationship of EPS in food products still remains a challenge.

Automated summary

The demand for cleaner labeled foods without artificial additives can be addressed by using lactic acid bacteria capable of synthesizing exopolysaccharides (EPS). EPS, a class of alternative bio-thickeners, can improve rheological and sensory properties of food products as texturizers and stabilizers. Despite abundant research findings, understanding the structure-function relationship of EPS in food products remains a challenge.