Search Results (148)

Fortifying sourdough bread with functional ingredients is an effective strategy to enhance nutritional value, bioactive content, and sensory quality. The novel strain Lactiplantibacillus paracasei SP5 was incorporated into mother sponges together with cereal-based derivatives, such as trahanas or delignified wheat bran (2% and 5% w/w), and their effects on sourdough bread functionality were compared with a control bread without supplementation. Sourdough bread containing 5% w/w trahanas exhibited the highest lactic acid bacteria (10.4 log cfu/g), approximately 22% higher than the control, and the strongest fermentation activity, leading to acetic acid levels 27% higher than the control. This sourdough bread sample also had 73% higher total phenolic content (112.1 mg GAE/100 g) and approximately 27% higher antioxidant activity compared to control bread. In addition, phytic acid degradation exceeded 91%, representing a 16% higher reduction than the control, thereby improving mineral bioavailability. Shelf-life was also markedly extended, in terms of mould and rope spoilage compared with the control. Wheat bran-supplemented breads showed moderate improvements, with LAB counts, antioxidant activity, and phytic acid reduction about 10–25% higher than the control. Overall, these findings demonstrate that L. paracasei SP5 in combination with nutrient-rich, low-cost cereal-based derivatives can significantly enhance the technological, nutritional, and bioactive properties of sourdough breads. This approach provides a simple, industrially feasible strategy for producing functional breads with improved health-promoting and preservative attributes. Full article

A bacterial cellulose (BC) producing bacterial species was isolated from spontaneous wine fermentations and identified as Acetobacter pasteurianus and assigned the strain designation ABBA. The strain had the ability to synthesize BC in orange juice, achieving a yield of 5.0 g/L. Further production optimization was studied using a non-fortified natural substrate composed of substandard raisin extracts, orange juice, and green tea extract. The Response Surface Methodology for the production design and optimization was applied, resulting in a significantly higher yield of up to 15.5 g/L. The porosity, crystallinity, and antioxidant activity of the produced BC films were affected by both the BC drying method and the substrate used. In the FT-IR spectra, characteristic peaks corresponding to citric acid, gallic acid, ascorbic acid and thiamine were observed, indicating their adsorption onto the BC matrix and explaining the increased antioxidant activity. A. pasteurianus ABBA is a promising new strain that can be used in the production of BC from agrifood sidestreams (substandard raisins; discarded oranges), contributing to their utilization and the production of value-added materials within a circular-economy framework. Full article

The valorization of food processing by-products is a key strategy for advancing sustainability in the agri-food sector. This study developed a fermented milk product incorporating tomato powder (TP) obtained from surplus tomatoes not meeting retail appearance standards. Four yogurt formulations were prepared containing TP (2% and 4%, w/v) and two controls with skim milk powder adjusted to equivalent total solids. Samples were inoculated with a commercial starter culture and fermented at 42 °C to a final pH of 4.6. TP addition did not hinder fermentation but altered acidification kinetics, as the 4% TP yogurt exhibited a faster initiation (T_m ≈ 80 vs. 120 min in the control) yet a slower rate of pH decline (V_max = 0.009 vs. 0.019 pH units/min). TP-fortified yogurts exhibited higher water holding capacity (98% vs. 83%), increased firmness (87 g vs. 47 g), and substantially elevated viscosity (63,000–68,000 mPa·s) while lycopene enrichment enhanced color attributes. Viable counts of Lactobacillus delbrueckii subsp. bulgaricus and Streptococcus thermophilus remained within typical ranges (~6.8 and ~4.9 log CFU/g, respectively, after 24 h), confirming that TP did not compromise microbial activity. Overall, incorporating TP improved structural and functional properties while simultaneously providing tomato-derived antioxidants and promoting a sustainable, circular utilization of surplus tomato streams in fermented dairy products. Full article

Background/Objectives: Lactoferrin, a key bioactive component in human milk, may bridge functional gaps in infant formula; however, its long-term effects on growth and the gut microbiota in term infants remain underexplored, particularly in real-world settings. Methods: This real-world evidence (RWE) study assessed the impact of lactoferrin-fortified formula (LF) on infant growth, the gut microbiota, and feeding tolerance compared with control formula (CF) and exclusive breastfeeding (BF). After propensity score matching (PSM) for maternal education level and infant age, 111 matched Chinese infants (37 per group: LF, CF, and BF; age: 6–12 months) were analyzed. Growth was evaluated using WHO Z-scores (WAZ, LAZ, WLZ, and zBMI). The gut microbiota was profiled via 16S rRNA sequencing (n = 81). Feeding challenges were quantified using the Montreal Children’s Hospital Feeding Scale (MCH-FS). Results: The LF group exhibited significantly higher length-for-age Z-scores (LAZ) compared with both the BF and CF groups (p < 0.001), indicating superior linear growth. LF infants also showed reduced MCH-FS scores (18.0 vs. 36.2 in CF; p < 0.001), signifying fewer feeding difficulties. Gut microbiota analysis revealed enrichment of Bifidobacterium breve and butyrate-producing taxa (e.g., Faecalibacterium and Ruminococcaceae), higher alpha diversity, and metabolic divergence, involving enhanced lysine fermentation to acetate/butyrate in LF infants, suggesting a higher level of short-chain fatty acid (SCFA) production. Beta diversity analysis demonstrated that the LF microbiota clustered close to BF. Conclusions: Lactoferrin-fortified formula was associated with improved linear growth and feeding tolerance while shaping a healthy gut microbiota, showing similarities to breastfed infants’ microbiota. These findings support LF fortification as a strategy to improve functional outcomes in formula-fed infants. Full article

This study aimed to isolate and screen lactic acid bacteria (LAB) with neuroprotective potential for food applications. Fifteen strains were screened for probiotic potential properties, γ-aminobutyric acid (GABA) production, and acetylcholinesterase (AChE) inhibitory activity. Lactobacillus delbrueckii AY8 and AY15 demonstrated the strongest probiotic potential, AChE inhibitory activity, and GABA production. Whole-genome sequencing confirmed genes linked to these probiotic and neuroprotective traits. To assess their functionality in a food matrix, the strains were used as adjunct cultures in fermented milk with and without jujube kernel powder (JP). Fermentation with the AY8 strain in JP-fortified milk significantly increased bioactive compounds, resulting in higher total phenolic content (235.75 mg GAE/g), flavonoids (114.07 mg RE/g), and superior antioxidant activity (110.24 mg Ascorbic equivalent/100 g). This biotransformation led to a remarkable increase in AChE inhibition, with the AY8-fermented sample achieving 30.66% inhibition, significantly higher than the JP control (18.27%) and the plain control (12.30%). The combination also improved the product’s viscosity and sensory profile. This study highlights the successful discovery of novel L. delbrueckii strains, whose application in a food model, when combined with a plant-based supplement, creates a functional food with enhanced neuroprotective potential, underscoring the role of microbial metabolism in food functionality. Full article

Gamma-aminobutyric acid (GABA) is a bioactive, non-protein amino acid recognized for its role as an inhibitory neurotransmitter in the human central nervous system. Increasing interest in functional foods has increased attention on GABA due to its potential health benefits, including antihypertensive, anxiolytic, antidepressant, and neuroprotective effects. This review summarizes the natural dietary sources of GABA and explores advanced strategies for enriching dairy products, particularly yogurt and frozen yogurt (froyo), with GABA. Key microbial species capable of GABA biosynthesis via the glutamate decarboxylase (GAD) pathway are discussed, alongside enzymatic production techniques that support controlled GABA synthesis. A major focus of this review is the evaluation of various methods for incorporating GABA into dairy matrices, including direct GABA fortification and in situ fermentation using GABA-producing strains, with comparisons of yield, sensory attributes, and product stability. Physicochemical analyses and sensory evaluations are presented as essential tools for assessing product performance. Furthermore, the review outlines the therapeutic effects of GABA-fortified foods and their potential roles in managing hypertension, stress, and neurodegenerative disorders. Key challenges, including strain-dependent variability in GABA-production, storage stability, and regulatory compliance are addressed, along with market and legislative considerations for GABA-fortified foods. Future perspectives include the development of novel high GABA-producing strains, process optimization to improve product stability and sensory acceptance, and expanded applications within the functional food sector. Overall, this review provides an integrated, up-to-date overview of technological, functional and regulatory aspects, offering a clear scientific foundation for the development and commercialization of GABA-fortified dairy products. Full article

The development of plant-based synbiotic beverages is gaining increasing attention as consumers seek sustainable, functional alternatives to dairy products. This preliminary study investigated the fortification of tibicos (water kefir) with lemon catnip (Nepeta cataria var. citriodora) hydrolate, an aromatic distillation byproduct rich in bioactive terpenoids. After 72 h-fermentation of tibicos, physicochemical, microbiological, health-promoting and sensory parameters were evaluated. Both control and fortified beverages exhibited typical fermentation kinetics, including a decrease in pH, reduction of soluble solids, and accumulation of organic acids. Lactic acid bacteria count remained stable, while yeast proliferation was slightly reduced in the hydrolate-fortified sample, consistent with the known yeast-sensitive nature of certain hydrolate-derived terpenoids. Importantly, hydrolate fortification significantly enhanced antioxidant capacity (DPPH: +34%; ABTS: +39%; RP: +38%). Enzyme-inhibitory activities also increased significantly in the hydrolate-fortified samples (α-Amylase and α-Glucosidase inhibition rates increased by 9% and 11%, respectively). ACE inhibition similarly increased from 32% to 44%, indicating an enhanced antihypertensive potential. HMG-CoA reductase inhibition increased from 31% to 42%, showing improved hypolipidemic activity. Sensory evaluation indicated improved sensory acceptability, imparting citrus–floral notes that balanced the acidic profile of tibicos. These findings highlight the potential of valorizing lemon catnip hydrolate as a functional fortifier in non-dairy synbiotic beverages. Full article

The latest trends focus on increasing the nutritional value of food products, including yogurts, by fortifying them with bioactive compounds derived from natural ingredients, in line with the concept of “food-to-food fortification”. Mushrooms are a rich source of protein, dietary fibre, certain vitamins, minerals, and numerous bioactive compounds, including polysaccharides (β-glucans) and phenolic compounds. Biologically active substances found in mushrooms exhibit numerous biological properties, including antioxidant, anti-inflammatory, anti-carcinogenic, hypocholesterolaemic and immunomodulatory properties. This study aimed to determine the potential of edible mushrooms as functional additives in yogurt production, based on a review of the scientific literature. The study discusses the effects of various forms of mushroom additives (powders, aqueous and ethanolic extracts, polysaccharides, β-glucans) on the course of lactic acid fermentation, the growth and survival of lactic acid bacteria, and the physicochemical and sensory properties of yogurts. In most cases, the addition of mushrooms increased the activity of lactic acid bacteria, increased the acidity, viscosity, and hardness of yogurt, and reduced syneresis, thereby improving its stability. This effect is mainly due to mushroom polysaccharides, including β-glucans. In turn, the presence of antimicrobial and antioxidant compounds significantly limits the growth of undesirable microorganisms and slows lipid oxidation, thereby extending the shelf life of yogurts. The addition of edible mushrooms to yogurts, in various forms, is a safe and effective way to create a functional product that meets consumer expectations, but it requires optimising the form and concentration of the additive. Full article

Background/Objectives: Within the spectrum of lactic acid bacteria, Lacticaseibacillus casei and Lactobacillus johnsonii are of particular technological and nutritional significance. Protein fortification of fermented dairy systems offers dual benefits: it improves product quality while enhancing probiotic resilience. Supplementary proteins supply bioavailable nitrogen and peptides that stimulate bacterial metabolism and contribute to a viscoelastic gel matrix that buffers cells against gastric acidity and bile salts. The aim of this study was to clarify the functional potential of such formulations by assessing probiotic survival under in vitro digestion simulating oral, gastric, and intestinal phases. Methods: Sheep milk was fermented with L. casei 431 or L. johnsonii LJ in the presence of whey protein isolate (WPI), soy protein isolate (SPI), or pea protein isolate (PPI) at concentrations of 1.5% and 3.0%. Physicochemical parameters (pH, titratable acidity, color, syneresis), organoleptic properties, and microbiological counts were evaluated. The viability of L. casei and L. johnsonii was determined at each digestion stage, and probiotic survival rates were calculated. Results: Samples with L. johnsonii consistently exhibited lower pH values compared to L. casei. Across both bacterial strains, the addition of 1.5% protein isolate more effectively limited syneresis than 3.0%, regardless of protein type. Samples fortified with WPI at 1.5% (JW1.5) and 3.0% (JW3.0) were rated highest by the panel, demonstrating smooth, homogeneous textures without grittiness. The greatest bacterial survival (>70%) was observed in WPI-fortified samples (JW1.5, JW3.0) and in SPI-fortified JS3. Conclusions: Protein isolates of diverse origins are suitable for the enrichment of fermented sheep milk, with 1.5% supplementation proving optimal. Such formulations maintained desirable fermentation dynamics and, in most cases, significantly improved the survival of L. casei and L. johnsonii under simulated gastrointestinal conditions, underscoring their potential in the development of functional probiotic dairy products. Full article

Background: Lophatheri Herba, a traditional East Asian herb with documented food uses, contains bioactive flavonoids. This study investigated how Aspergillus oryzae fermentation modifies its short-chain fatty acids (SCFAs) and metabolome, and evaluated the fermented product’s impact on intestinal barrier function in mice. Methods: Fermented leaf extracts were analyzed via GC-MS/LC-MS for SCFAs and metabolites. Forty-eight mice were divided into control (standard diet) and three experimental groups (25, 50, 100 mg/kg/day fermented product). After a 4-week intervention, duodenal morphology, colonic cytokines (IL-6/IL-1β), and cecal microbiota were assessed. Results: We identified significant SCFAs optimization. Significantly increased: acetic acid; butyric acid (p < 0.001); isobutyric acid (p < 0.01); isovaleric acid (p < 0.05). No significant change: propionic acid and isohexanoic acid. Significantly decreased: valeric acid and hexanoic acid (p < 0.001). Metabolomic remodeling showed (i) flavonoid pathway activation and (ii) key metabolite upregulation (daidzein, 4,7-dihydroxyflavone, 3,7-dimethylquercetin, aloe-emodin, soyasapogenol M1, etc.). Gut function peaked at 100 mg/kg with 18% higher duodenal villus height (p < 0.05), improved villus/crypt ratio, and reduced IL-6/IL-1β. Probiotic taxa including Lactobacillus, unclassified f__Lachnospiraceae, Dubosiella, and Monoglobus increased. Conclusions: Fermented Lophatheri Herba protects gut health through synergistic SCFAs optimization, flavonoid enrichment, and probiotic proliferation, supporting its potential as a microbiota-targeting functional food ingredient. Full article

Functional foods are gaining heightened popularity in diet modifications. Green bananas contain a significant quantity of resistant starch, dietary fibre, and phytochemicals that demonstrate strong antioxidant properties, particularly due to the high concentration of polyphenols. The community demand for incorporating these essential components into food products, such as bread, has increased. Therefore, the aim of this study was to evaluate the differences in the content and bio-accessibility of phenolic compounds in bread enriched with 5, 10, and 15% of Australian green banana powder (GBF) from (Cavendish “Musa acuminata”, Ladyfinger “Musa paradisiaca L.”, and Ducasse “Musa balbisiana”), as well as their antioxidant capabilities and the generation of short-chain fatty acids (SCFAs) after in vitro gastrointestinal digestion and colonic fermentation. The 15% Cavendish bread exhibited significant TPC and TFC at 1.31 mg GAE/g and 0.05 mg QE/g, respectively, along with substantial antioxidant activity (DPPH, 0.40 mg TE/g), observed following stomach and intestinal phases. However, the 15% Ladyfinger bread exhibited the highest TTC following the stomach digestion, with 17.4 mg CE/g. The bio-accessibility of most phenolic components from 10% GBF-bread was elevated following the gastric and intestinal phases. Nonetheless, a substantial total phenolic content (50.3% in Ladyfinger bread) was still observable in the residue during colonic fermentation. The highest SCFAs production occurred in Cavendish and Ducasse bread after 24 h of fermentation. Overall, the consumption of GBF bread can positively influence intestinal health and provide antioxidant properties, facilitating future advancements in the creation of nutrient-dense and health-enhancing bakery products. Full article

Fermentation has been a crucial process in the preparation of foods and beverages for consumption, especially for the purpose of adding value to nutrients and bioactive compounds; however, conventional approaches have certain drawbacks such as not being able to fulfill the requirements of the ever-increasing global population as well as the sustainability goals. This review aims to evaluate how the application of advanced fermentation techniques can transform the food production system to be more effective, nutritious, and environmentally friendly. The techniques discussed include metabolic engineering, synthetic biology, AI-driven fermentation, quorum sensing regulation, and high-pressure processing, with an emphasis on their ability to enhance microbial activity with a view to enhancing product output. Authentic, wide-coverage scientific research search engines were used such as Google Scholar, Research Gate, Science Direct, PubMed, and Frontiers. The literature search was carried out for reports, articles, as well as papers in peer-reviewed journals from 2010 to 2024. A statistical analysis with a graphical representation of publication trends on the main topics was conducted using PubMed data from 2010 to 2024. In this present review, 112 references were used to investigate novel fermentation technologies that fortify the end food products with nutritional and functional value. Images that illustrate the processes involved in novel fermentation technologies were designed using Adobe Photoshop. The findings indicate that, although there are issues regarding costs, the scalability of the process, and the acceptability of the products by the consumers, the technologies provide a way of developing healthy foods and products produced using sustainable systems. This paper thus calls for more research and development as well as for the establishment of a legal frameworks to allow for the integration of these technologies into the food production system and make the food industry future-proof. Full article

Kefir is a historic dairy-fermented beverage produced using lactic acid bacteria and yeast as a starter culture and is considered nutritious with a good taste. Many studies have been conducted to incorporate various possible functional materials into kefir to enhance its nutritional value. This study aims to enrich kefir with 0.25% and 0.5% of Stinging nettle (Sn) powder before fermentation to improve its nutritional value. Stinging nettle (Urtica dioica) is a nutritious and multifunctional herb with a variety of healthful components such as fibers and polyphenols; it has significant potential as a useful food functional ingredient. The physicochemical, microbial, and nutritional properties of kefir fortified with Sn were examined weekly during refrigerated storage for 21 days. The results showed that adding Stinging nettle significantly (p < 0.05) increased the probiotic counts from 7.90 ± 0.22 log to 8.46 ± 0.19 log CFU/g, antioxidant activity (4%), and total polyphenol contents (5%) in kefir yogurt after 12 days of refrigerated storage. The addition of Sn also had a positive effect on the acidity of kefir and increased the viscosity and the syneresis to a certain extent. Furthermore, adding Sn increased lactic acid bacteria counts and the production of short-chain fatty acids after in vitro digestion and colonic fermentation. The results of this study indicated the potential use of Sn powder as a functional ingredient in kefir yogurt and other similar products. Full article

The present study develops and optimizes a jet-cutting encapsulation method using a laboratory-scale encapsulator to incorporate herbal dietary supplements into fermented milk products. Sodium alginate and pullulan were selected as core and coating polymers, respectively, after rheological screening demonstrated that 1% alginate (η ≈ 350–450 Pa·s at 22–25 °C) and 2% pullulan (η ≈ 400 Pa·s at 25–30 °C) provide a balance between atomization, shell integrity, and fluidity. Under optimized conditions, capsules of 1.00 ± 0.05 mm diameter and high sphericity (aspect ratio 1.08 ± 0.03) were produced. In vitro gastrointestinal simulation confirmed capsule stability in simulated gastric fluid (pH 2.0) and complete disintegration within 120 min in simulated intestinal fluid (pH 7.2). Inclusion of 8% (w/w) capsules in a fermented milk beverage preserved appearance, texture, flavor, and color while increasing viscosity from 2.0 to 4.0 Pa·s. Titratable acidity rose from 87 °T at 24 h to 119 °T at 120 h, with sensory quality remaining acceptable; substantial gas formation and excessive sourness occurred only after 168 h, defining a 5-day refrigerated shelf life. These findings demonstrate that the 1% alginate–pullulan capsule system successfully protects plant extracts during gastric transit and enables targeted intestinal release, while maintaining the sensory and rheological properties of the fortified fermented milk product. Full article

Noncommunicable diseases (NCDs) like diabetes and cancer drive demand for therapeutic functional foods. This study developed freeze-dried fermented camel milk (FCM) with Ajwa date pulp (ADP), evaluating its physical and functional properties, probiotic survival, and potential benefits for diabetes and cancer. To achieve this target, six FCM formulations were prepared using ABT-5 starter culture (containing Lactobacillus acidophilus, Bifidobacterium bifidum, and Streptococcus thermophilus) with or without Lacticaseibacillus rhamnosus B-1937 and ADP (12% or 15%). The samples were freeze-dried, and their functional properties, such as water activity, dispersibility, water absorption capacity, water absorption index, water solubility index, insolubility index, and sedimentation, were assessed. Reconstitution properties such as density, flowability, air content, porosity, loose bulk density, packed bulk density, particle density, carrier index, Hausner ratio, porosity, and density were examined. In addition, color and probiotic survivability under simulated gastrointestinal conditions were analyzed. Also, antidiabetic potential was assessed via α-amylase and α-glucosidase inhibition assays, while cytotoxicity was evaluated using the MTT assay on Caco-2 cells. The results show that ADP supplementation significantly improved dispersibility (up to 72.73% in FCM15D+L). These improvements are attributed to changes in particle size distribution and increased carbohydrate and mineral content, which facilitate powder rehydration and reduce clumping. All FCM variants demonstrated low water activity (0.196–0.226), indicating good potential for shelf stability. The reconstitution properties revealed that FCM powders with ADP had higher bulk and packed densities but lower particle density and porosity than controls. Including ADP reduced interstitial air and increased occluded air within the powders, which may minimize oxidation risks and improve packaging efficiency. ADP incorporation resulted in a significant decrease in lightness (L*) and increases in redness (a*) and yellowness (b*), with greater pigment and phenolic content at higher ADP levels. These changes reflect the natural colorants and browning reactions associated with ADP, leading to a more intense and visually distinct product. Probiotic survivability was higher in ADP-fortified samples, with L. acidophilus and B. bifidum showing resilience in intestinal conditions. The FCM15D+L formulation exhibited potent antidiabetic effects, with IC₅₀ values of 111.43 μg mL⁻¹ for α-amylase and 77.21 μg mL⁻¹ for α-glucosidase activities, though lower than control FCM (8.37 and 10.74 μg mL⁻¹, respectively). Cytotoxicity against Caco-2 cells was most potent in non-ADP samples (IC₅₀: 82.22 μg mL⁻¹ for FCM), suggesting ADP and L. rhamnosus may reduce antiproliferative effects due to proteolytic activity. In conclusion, the study demonstrates that ADP-enriched FCM is a promising functional food with enhanced probiotic viability, antidiabetic potential, and desirable physical properties. This work highlights the potential of camel milk and date synergies in combating some NCDs in vitro, suggesting potential for functional food application. Full article