In recent years, there has been a burgeoning interest in the role of lactic acid bacteria (LAB) not just in food fermentation, but also in their potential contributions to health and industry through the production of exopolysaccharides (EPS). In a groundbreaking review set to be published in International Microbiology, researchers N. Hamdaoui, R. Sabbahi, K. Azzaoui, and their colleagues dive into the multifaceted benefits of EPS derived from LAB. This critical examination outlines the diverse physicochemical properties of EPS, their functional roles, and their potential applications in various biotechnology sectors.
One of the most remarkable aspects of EPS is their ability to enhance the texture and viscosity of food products. These polysaccharides can create a creamy mouthfeel that is often desirable in dairy products, salad dressings, and sauces. By forming a gel-like structure, EPS can stabilize emulsions, thereby improving the overall quality and shelf-life of these products. The study highlights specific types of LAB, such as Lactobacillus and Streptococcus species, that are recognized for their efficient EPS production, indicating a potential pathway for food manufacturers to harness these bacteria for improved product formulations.
Beyond their culinary applications, exopolysaccharides exhibit remarkable bioactive properties. Evidence suggests that these compounds can possess antioxidant, antimicrobial, and even immunomodulatory effects. The review meticulously details the mechanisms by which EPS can modulate gut health, including the enhancement of microbiota diversity and the promotion of beneficial bacteria. This function of EPS is especially pertinent in the context of increasing consumer awareness regarding gut health and the growing trend towards functional foods.
The review also sheds light on the natural sources of these LAB and their EPS, drawing attention to both traditional fermented foods and innovative strategies in biotechnology. Sources like yogurt, kefir, and fermented vegetables serve as pivotal examples of how EPS can be obtained naturally. However, researchers are now exploring controlled fermentation processes that optimize the yield and functionality of EPS. Such advancements could revolutionize the food industry by standardizing the production of these valuable ingredients.
In the realm of pharmaceuticals, the bioactivity of exopolysaccharides has opened new doors for the development of novel drug delivery systems. EPS can be utilized to encapsulate bioactive compounds, enhancing their stability and bioavailability. The review discusses various methods of manipulating LAB to maximize EPS production, including genetic engineering techniques that can create strains with tailored properties, ensuring higher efficiency and yield in pharmaceutical applications.
Environmental sustainability is another critical theme addressed in this review. As the world grapples with pollution and waste management issues, natural polymers like EPS offer biodegradable alternatives to synthetic materials. The study evaluates how EPS derived from LAB can be employed in producing bioplastics and biodegradable packaging. This could play a vital role in reducing plastic waste and improving environmental health, aligning with global sustainability goals.
Furthermore, the economic implications of EPS production are profound. The potential for LAB to serve as cost-effective producers of high-valuable polysaccharides could benefit not only the food industry but also pharmaceuticals and environmental sectors. The review underscores the need for economic feasibility studies and market analyses that could pave the way for large-scale exploitation of these microbes.
The authors of this review also address the challenges that come with the commercialization of EPS. While the potential is vast, there are significant hurdles, including regulatory pathways, consumer acceptance, and technical challenges in large-scale production. The importance of collaborative efforts between academia, industry stakeholders, and regulatory bodies in addressing these challenges cannot be overstated.
In terms of future research, Hamdaoui et al. identify key areas that warrant further exploration, such as the genomics of EPS-producing LAB and the metabolic pathways involved in polysaccharide synthesis. By harnessing biotechnological advancements, researchers may unlock new strains with enhanced functional properties, driving innovation in various industries. This could lead to the emergence of novel products that cater to consumer trends favoring health, sustainability, and quality.
In conclusion, this review presents a comprehensive overview of the potential of exopolysaccharides derived from lactic acid bacteria as functional ingredients with vast biotechnological implications. As we look to the future, it is clear that ongoing research and collaboration will be integral in unlocking the full potential of these natural compounds, benefitting a myriad of sectors from food to pharmaceuticals and beyond.
With consumers evolving and becoming more health-conscious, the opportunity to incorporate EPS into mainstream diets is ripe. There is a growing demand for transparency regarding food ingredients and a keen interest in products with added health benefits, positioning exopolysaccharides as a valuable asset in this new market landscape. The contributions of lactic acid bacteria to health and industry underscore a pivotal shift towards harnessing the power of nature in innovative and functional ways.
As society moves towards more health-conscious and sustainable choices, the research surrounding EPS from LAB will likely foster new developments in functional foods and materials. The emphasis on biotechnological advancements signifies a promising horizon for food scientists, nutritionists, and entrepreneurs alike. The future holds exciting prospects for exopolysaccharides, ensuring their place as pivotal components in the next era of food technology.
Subject of Research: Exopolysaccharides from lactic acid bacteria
Article Title: Exopolysaccharides from lactic acid bacteria: functional ingredients with biotechnological potential – a critical review
Article References:
Hamdaoui, N., Sabbahi, R., Azzaoui, K. et al. Exopolysaccharides from lactic acid bacteria: functional ingredients with biotechnological potential – a critical review.
Int Microbiol (2025). https://doi.org/10.1007/s10123-025-00745-5
Image Credits: AI Generated
DOI: 11 December 2025
Keywords: Exopolysaccharides, lactic acid bacteria, biotechnology, food science, gut health, sustainability.
Tags: antimicrobial properties of exopolysaccharidesantioxidant properties of LABbiotechnology in food industryexopolysaccharides applicationsfood product formulation improvementhealth benefits of EPSindustrial applications of lactic acid bacteriaLAB in food fermentationlactic acid bacteriaLactobacillus EPS productionphysicochemical properties of EPStexture enhancement in food products
