Search Results (4,047)

This study evaluated contamination by polychlorinated dibenzodioxins and dibenzofurans (PCDDs/Fs) and polychlorinated biphenyls (PCBs) in 390 feeds and 1756 food samples collected in Latium and Tuscany (Italy, 2016–2025) using HRGC-HRMS. PCDDs/Fs and dioxin-like PCBs (dl-PCBs) are expressed as WHO 2005 toxic equivalents (WHO₀₅-TEQ). Non-dioxin-like PCBs (ndl-PCBs) lack dioxin-like toxicity mechanisms due to their non-coplanar structure and are not assigned a toxic equivalence factor. Feed results were normalised to 12% moisture content. Median levels of WHO₀₅-PCDDs/Fs+dl-PCBs TEQ at the upper limit in feed were 10–100 times lower than those reported in European monitoring data (EFSA, 2002–2010) for comparable categories, including additives, premixtures, raw materials and compound feed, with plant and animal feed materials below 0.03 ng/kg and aquaculture feed at 0.24 ng/kg. Food contamination was generally low, with the median WHO₀₅-PCDDs/Fs+dl-PCBs TEQ 2–4 times lower than Italian national data (2013–2016), considering comparable categories such as meat, fish, milk, eggs, oils, baby foods, marine oils, animal fats and liver. Higher levels were observed in game meat, sheep products and fermented milk than in pork and poultry. The contamination remained stable over time. These results indicate an improvement in food safety thanks to national and EU regulations, although continued surveillance of high-risk and undersampled categories remains essential. Full article

Lactiplantibacillus plantarum MS11, isolated from traditionally fermented yak milk in the high-altitude Gannan region of the eastern Tibetan Plateau, was investigated for its technological and functional potential in food applications. Using whole-genome sequencing combined with targeted experimental verification, this study clarified the genetic determinants and metabolic capacity associated with its production of folate, lactic acid, bacteriocin, and exopolysaccharides (EPS). The MS11 genome consists of one circular chromosome and three plasmids, totaling 3,318,231 bp with a GC content of 44.48%, and encodes 3155 predicted open reading frames. Complete biosynthetic gene clusters were identified for folate (7 genes), L-lactic acid (13 genes), bacteriocin (14 genes), and EPS (17 genes). Phenotypic assays confirmed the strain’s high metabolite productivity, including folate (0.6043 μg/mL), L-lactic acid (76.24 mg/mL), and EPS (544.2 mg/L). The cell-free fermented supernatant exhibited strong antibacterial activity against Escherichia coli, supporting the functional relevance of its bacteriocin-associated gene cluster. To the best of our knowledge, this is the integrated genomic and experimental characterization demonstrating that a L. plantarum strain originating from a unique high-altitude fermented dairy niche can concurrently synthesize high levels of folate together with multiple beneficial metabolites. The multifunctional attributes of MS11—including nutrient fortification, acidification capacity, EPS formation, and antimicrobial activity—indicate substantial promise for its application as a composite starter culture, natural bio-preservative, and nutritionally enhanced probiotic in fermented food systems. Full article

Background: Vitamin D deficiency remains a widespread public health issue in Europe, despite the availability of sunlight, dietary sources, supplements, and food fortification. National fortification strategies differ substantially in their regulatory approaches, food vehicles, and fortification levels, influencing the population’s vitamin D intake and status. Objective: The primary objective of this study was to map vitamin D food fortification policies across European Union (EU) Member States, European Free Trade Association (EFTA) countries, and the United Kingdom (UK), focusing on regulatory frameworks, eligible food categories, and implementation models. Methods: A structured review of national legislation and official guidance on vitamin D food fortification was conducted between December 2025 and March 2026 across EU Member States (n = 27), EFTA countries (n = 4), and the UK. For EU Member States, the framework established by Regulation (EC) No 1925/2006 was examined alongside national implementation measures. For EFTA countries and the UK, corresponding national legislation and official regulatory guidance were reviewed. Data were extracted on fortification policy status, eligible food categories, legal basis, and fortification levels. Targeted searches of PubMed and Scopus were performed to identify modeling studies and policy analyses supporting the interpretation of the findings. Results: Fortification policies show marked heterogeneity. Mandatory fortification is limited to a few countries and specific foods: Finland (homogenized skim milk), Sweden (low-fat milk, fermented dairy, plant-based alternatives, and fat spreads), Belgium (margarine and selected fats), and Poland (margarine and fat spreads). In most other European countries, vitamin D fortification is voluntary under EU legislation or equivalent national legislation, depending on market uptake. Food vehicles vary regionally, with Northern Europe extending fortification beyond fats to include fluid milk and plant-based drinks, whereas other regions mainly fortify margarines, cereals, dairy products, and plant-based beverages. Fortification levels also differ, with some countries specifying maximal or exact levels, while others lack national standards. Data on fortified foods are limited in several Central and Southern European countries. Modeling indicates that multi-vehicle fortification is more effective than single-vehicle approaches, safely increasing population intakes while reducing deficiency prevalence. Conclusions: Vitamin D fortification policies across Europe are highly heterogeneous. Most countries rely on voluntary approaches, which provide limited coverage. Strengthening policy through mandatory and well-coordinated multi-vehicle strategies, informed by modeling and population-based studies, can improve vitamin D intake, reduce deficiency prevalence, and enhance health equity. Full article

As probiotic microorganisms must remain viable at a certain level throughout the shelf life of fermented foods, various plant-based prebiotics are added to fermented dairy products. Pea (Pisum sativum L.) is a remarkable food source due to its prebiotic properties, high phenolic content and antioxidant capacity. In this study, fermented milks containing different proportions of pea fiber powder (0%, 0.5%, 1%, 1.5% and 2%) were produced using Limosilactobacillus reuteri ACC27, which has probiotic potential, and Streptococcus thermophilus 212S. The addition of pea fiber powder promoted the growth of Limosilactobacillus reuteri ACC27, increasing viable cell counts by approximately 1 log CFU/g compared to the control during storage. In addition, the fermentation time was shortened by approximately 30 min in samples containing pea fiber. Malic (84.07–175.58 mg/kg), lactic (11,670.45–13,791.66 mg/kg), acetic (145.12–240.53 mg/kg) and benzoic acids (17.07–20.34 mg/kg) were detected in all samples. Furthermore, pea fiber supplementation improved physicochemical properties by reducing syneresis and modifying water release behavior, while also increasing viscosity. The addition of pea fiber also enhanced total phenolic content and antioxidant capacity of the samples. The results of the principal component analysis revealed that the addition of pea fiber powder was associated with potentially improved functional attributes and enhanced probiotic viability under the studied conditions. Full article

The 1st International Online Conference on Fermentation (IOCFE2025), held on 12–13 November 2025, convened a global assembly of researchers to explore the multifaceted roles of microorganisms in biotechnology, food safety, and human health. Under the chairmanship of Professor Antonio Morata, the symposium was structured around four pivotal tracks: biotechnological tools in fermentation, sensory profile impacts, food safety and drink innovation, and the nutraceutical implications of fermented products. A significant portion of the discourse focused on enology, specifically the use of Saccharomyces and non-Saccharomyces yeast derivatives to mitigate climate-related challenges such as high alcohol content and acidity, alongside emerging biopreservation strategies like kefir-enriched coatings and natural antifungal agents. The award-winning research highlighted the breadth of the field, ranging from the development of agri-food biostimulants and enhanced carotenoid production under LED illumination to the genomic characterization of glucose transport in Torulaspora delbrueckii. Furthermore, the sessions on health and nutrition provided a critical appraisal of meta-analytic studies, examining the probiotic potential of Enterococcus faecium and the role of fermented dairy in the Mediterranean diet. By integrating traditional fermentation practices with high-tech interventions like ultra-high pressure homogenization (UHPH) and solid-state biorefinery processes, IOCFE2025 underscored the vital contribution of fermentation science to sustainable agriculture and the global functional food market. Full article

Demand for camel milk products is growing in Morocco and worldwide, creating opportunities to strengthen the livelihoods of populations living in arid regions through the development of camel-based dairy value chains. In addition to their economic potential, such value chains may contribute to sustainability by supporting food systems adapted to arid environments, promoting the use of locally resilient livestock species, and enhancing the socio-economic viability of vulnerable rural communities. This exploratory qualitative study investigates urban consumer behavior related to dairy consumption with a specific focus on the potential integration of camel milk products into local dietary habits. To capture nuanced consumer perspectives, gender-segregated focus-group discussions were conducted in three Moroccan cities using a semi-structured questionnaire on dairy consumption habits. Key factors examined included milk types, product preferences, purchasing locations, consumption frequency and willingness to include camel products in the household diet. The results indicate that camel milk is rarely consumed outside areas where camels are raised. Nevertheless, participants expressed interest in several camel milk-based products, particularly fermented milk and spreadable cheeses. This interest was primarily driven by perceptions of camel milk as a healthy product and by its association with traditional food practices. These findings suggest that expanding camel milk consumption in urban markets could support more sustainable and territorially rooted dairy systems by linking consumer demand with production models suited to dryland conditions. This study indicates promising market opportunities for the development of camel milk products in urban areas, particularly if challenges related to pricing strategies, distribution network, and region-specific supply chains are strategically managed. Full article

Excessive acidity restricts the utilization of citrus pulp, a major by-product of the dried tangerine peel industry. To overcome this bottleneck, a functional microbial consortium (BsHpMrF) comprising Bacillus subtilis L4, Hanseniaspora pseudoguilliermondii B4, and Monascus ruber CGMCC 10910 was constructed for efficient biological deacidification. The consortium exhibited a synergistic effect, achieving an 88.23% reduction in total acidity and converting the acidic pulp into a neutral, bio-stabilized substrate. Untargeted metabolomics analysis revealed that this efficiency was driven by the concurrent activation of the TCA cycle and glyoxylate shunt for organic acid mineralization, coupled with membrane lipid remodeling (increased unsaturation) to enhance acid tolerance. Notably, the fermentation process functioned as a “metabolic factory”, significantly enriching the matrix with bioactive lipids (e.g., 10-HDA, nervonic acid) and indole-3-acetic acid (IAA, 414.28 mg/L). Application assays demonstrated that the fermentation products acted as a potent biostimulant for soybean sprouts, significantly promoting lateral roots and eliciting the accumulation of antioxidant phenolics and flavonoids. This study provides a sustainable “waste-to-treasure” strategy, valorizing acidic citrus pulp into a functional biostimulant for high-quality edible sprout production, thereby achieving a sustainable “waste-to-food” circular loop. Full article

Industrial food processing generates substantial byproducts, resulting in environmental challenges and economic losses. This study explores the biovalorization of sugar-rich barbecue sauce waste streams through fermentation to create value-added ingredients for sauce production and promote circular economy practices. The barbecue stream was diluted with water at 25 and 50% incorporation levels and fermented at room temperature for 12 days using a microbial consortium comprising three lactic acid bacteria (Lactiplantibacillus plantarum, Lacticaseibacillus rhamnosus, and Weissella confusa) and one yeast (Saccharomyces boulardii). Laboratory-scale fermentation was monitored by measuring pH, total soluble solids, titratable acidity, sugar consumption, and metabolite production. The consortium demonstrated effective performance, reducing pH and TSS and increasing titratable acidity for both incorporation levels over 12 days. The fermented samples were characterized by their antioxidant capacity, color, protein content, humidity, and viscosity. The total phenolic content and antioxidant activity (DPPH) increased significantly (p < 0.05), and the viscosity increased by 254.3% and 48.3% for the fermented streams with 25% and 50% incorporation, respectively. Antimicrobial assays revealed that the fermented samples inhibited typical spoilage bacteria and yeast. This work highlights the potential of fermentation to upcycle barbecue waste, with antimicrobial characteristics contributing to extended shelf life, sustainable food production, and circular economic practices. Full article

Fermented milk is rich in probiotics, peptides, vitamins, and minerals, which are used as routine food supplements and are of great benefit for regulating human health. This study explored the mechanism of Lactobacillus delbrueckii ssp. bulgaricus CGMCC 21287 or Lacticaseibacillus casei CGMCC 15956 fermented milk for alleviating acute alcoholic liver injury. We found that fermented milk was associated with reduced activation of TLR4/NF-κB pathways, alleviating alcohol-induced liver inflammation. Meanwhile, the two probiotics regulated different intestinal microbial communities in mice. The LC group specifically increased the abundance of probiotics such as Roseburia, unidentified_Lachnospiraceae, and Allobaculum, and decreased the abundance of pathogenic bacteria such as Enterococcus and Shigella. The LB group increased the abundance of Adlercreutzia and Ruminococcus, thereby increasing butyric acid, acetic acid, and valeric acid levels and decreasing lipopolysaccharide (LPS) production. These results suggest that daily intake of fermented milk can attenuate alcohol-induced acute liver injury in mice via the gut–liver axis, though differences exist in the mechanisms of action and areas of emphasis. Full article

Kombucha is a fermented beverage produced using a symbiotic consortium of acetic acid bacteria and yeasts, often marketed for its health-promoting properties. However, probiotic bacteria in kombucha are typically present at inconsistent levels and may not remain viable during fermentation. In this study, three Lactobacillus strains (Lacticaseibacillus rhamnosus ATCC 53103 (L. rhamnosus), Lactiplantibacillus plantarum subsp. plantarum ATCC 14917 (L. plantarum) and Lentilactobacillus hilgardii (L. hilgardii) isolate) were encapsulated in whey protein using the lyophilization method and added individually at the start of kombucha fermentation. Lactic acid bacteria (LAB)–enriched kombucha samples were evaluated for chemical composition (polyphenols, flavonoids, vitamin C and organic acids) and functional properties (antimicrobial, antiproliferative, antioxidant and anti-inflammatory activities) and compared to a traditionally obtained control kombucha, primarily demonstrating in vitro and experimental assessment. Encapsulation maintained LAB viability above 6–7 log CFU/mL throughout fermentation, producing kombucha with enhanced microbial stability. LAB–enriched samples exhibited increased L-lactic acid and antimicrobial activity. L. rhamnosus and L. hilgardii–enriched samples exhibited increased antiproliferative and anti-inflammatory activities, which may be associated with strain-dependent production of organic acids, polyphenol modulation and LAB-derived bioactive metabolites. Antioxidant activity varied depending on assay, and L. rhamnosus–enriched kombucha showed higher anti-inflammatory activity. These findings demonstrate that whey protein encapsulation can preserve LAB during fermentation, enhance specific bioactive properties and provide a platform for developing functional kombucha beverages with potential applications in the food industry. Full article

Chickpea flour represents a valuable plant-based ingredient due to its high protein and fiber content; however, its application is limited by antinutritional factors and off-flavor compounds. Fermentation with LAB and yeasts, applied individually or in consortia, resulted in significant microbiological, nutritional, and aromatic changes. The fastest acidification (pH 3.9) and the most effective control of Enterobacteriaceae (<4 log CFU/g after 48 h) were observed in samples containing Lactiplantibacillus plantarum LP23, both as a monoculture and in combination with Debaryomyces hansenii Y15A. Peptide content significantly increased in all fermented samples compared to the control, with a synergistic effect in the co-culture Yarrowia lipolytica Y3 + Lacticaseibacillus paracasei L (around 230%). A pronounced reduction in raffinose-family oligosaccharides was observed, especially in the consortia Y. lipolytica Y3 + Lcb. paracasei L and D. hansenii Y15A + Lacp. plantarum LP23 (0.11–0.16 mmol/100 g). Samples with lower total volatile levels showed higher olfactory acceptability due to a marked reduction in aldehydes (up to 70–95% vs. control), and a balanced accumulation of alcohols, esters, ketones, and organic acids. Overall, LAB–yeast consortia effectively enhanced the nutritional quality, safety, and sensory properties of chickpea flour, supporting its use as a functional ingredient in plant-based foods. Full article

Glycidol, a probable human carcinogen, remains an under-investigated process contaminant in soy sauce. This study developed a sensitive and specific liquid chromatography-tandem mass spectrometry (LC-MS/MS) method for its determination in this complex condiment. The approach combined chemical derivatization with p-Dimethylaminophenol hydrochloride for analyte stabilization with an optimized sample pretreatment using a custom-packed activated carbon solid-phase extraction (SPE) cartridge effectively removed matrix interferences, and performing the derivatization at pH 6.5 prevented conversion of 2- and 3-monochloropropanediol (2-MCPD and 3-MCPD) into glycidol, ensuring high specificity and accuracy. This approach shows broad linearity from 1 to at least 100 ng/mL (R² = 0.9993), and demonstrates excellent performance, with a limit of detection and quantification of 0.5 ng/mL and 1.0 ng/mL, respectively. Application to commercial samples (n = 11) confirmed the presence of glycidol, highlighting the need for its monitoring. This work provides a robust analytical tool essential for supporting food safety surveillance of this contaminant in fermented foods. Full article

Long-term adherence to plant-based diets can modify gut bacterial microbiota composition and metabolite profiles, which may be particularly relevant for postmenopausal women who frequently adopt such diets and experience age-related changes in nutrient absorption and metabolism. Fermented foods, commonly consumed in vegetarian diets, enhance dietary diversity and nutritional quality. This study compared gut bacterial microbiota and fecal metabolomes between vegetarians (VGs) and omnivores (OMs) and evaluated the contribution of fermented food intake. Thirty-two healthy postmenopausal Thai women (>55 years; 16 VGs, 16 OMs) were enrolled. Gut bacterial microbiota and fecal metabolites were analyzed using 16S rRNA metagenomic and untargeted ¹H-NMR metabolomics. The five most frequently consumed fermented foods were microbiologically characterized. Fermented food consumption was found to be significantly different between groups. OM participants reported infrequent consumption (<10% per week), whereas VG participants consumed fermented foods daily, often in multiple forms (>60% of weekly meals). VG participants exhibited enrichment of Prevotella, Faecalibacterium, and Blautia, while OM participants showed higher abundances of Bacteroides and Escherichia–Shigella. LEfSe identified Weissella as a bacterial taxon associated with the VG group. Functional prediction and metabolomic analyses indicated enhanced carbohydrate fermentation and increased short-chain fatty acid (SCFA) production in VGs, whereas OM profiles reflected greater protein catabolism. Fermented foods consumed by VGs shared microbial biomarkers with the VG gut bacterial microbiota and were rich in SCFAs and essential amino acids, supporting their potential role as microbial and metabolic contributors within the gut ecosystem and nutritional adequacy in postmenopausal vegetarians. Full article

Phenyllactic acid (PLA), a natural antimicrobial metabolite produced by lactic acid bacteria (LAB), has emerged as a key compound for biopreservation in food systems. The aims of this review are to summarize the main findings on LAB-producing strains, the effects of primary PLA precursors, the impacts of culture conditions on PLA production, antimicrobial activity, mechanisms of action, quantification and analysis methods, food applications, regulatory status, and the challenges in PLA production and applications. In this review, the quorum sensing role in PLA production and multi-omics strain improvement was revised. Applications in dairy, bakery, fruits, vegetables, meat, and fish products as well as active packaging are analyzed, demonstrating their effectiveness in controlling microbial spoilage and pathogens while preserving sensory quality. Its broad-spectrum antifungal and antibacterial activities make it particularly attractive as a clean-label alternative to synthetic preservatives, contributing to both food safety and extended shelf life. Finally, current limitations and future research needs are outlined, particularly in optimizing PLA production and establishing its role as a sustainable and effective tool for food safety management. Full article

Enterococcus spp. are common but not predominant commensal bacteria that inhabit the gastrointestinal tracts of humans and animals and are widely distributed in various environmental matrices and diverse food sources. Multiple strains of beneficial enterococci are increasingly utilized as protective cultures, alternatives to antibiotics, and probiotics for controlling pathogens, mitigating disease, modulating the microbiome, and supporting overall host health. They also support food fermentation and safety, enhance sensory properties, and produce bioactive compounds such as bacteriocins with strong pathogen-inhibitory activity and multifarious health benefits. Despite their advantages in health and agrifood systems, their association with healthcare-associated infections and the spread of antimicrobial resistance raises concerns about their safety. These risks underscore the need for stringent safety evaluations before their use as probiotics, alternatives to antibiotics, or protective cultures. Here, we provide a comprehensive atlas of the multifaceted probiotic and antimicrobial potential, as well as safety considerations of beneficial enterococci. This would provide a valuable resource for future research, regulatory assessments, and applications in the agrifood system and healthcare. Full article