Search Results (1,084)

Yeast biosensors represent a promising biotechnological innovation for ensuring the safety and quality of fermented beverages such as beer, wine, and kombucha. These biosensors employ genetically engineered yeast strains to detect specific contaminants, spoilage organisms, or hazardous compounds during fermentation or the final product. By integrating synthetic biology tools, researchers have developed yeast strains that can sense and respond to the presence of heavy metals (e.g., lead or arsenic), mycotoxins, ethanol levels, or unwanted microbial metabolites. When a target compound is detected, the biosensor yeast activates a reporter system, such as fluorescence, color change, or electrical signal, providing a rapid, visible, and cost-effective means of monitoring safety parameters. These biosensors offer several advantages: they can operate in real time, are relatively low-cost compared to conventional chemical analysis methods, and can be integrated directly into the fermentation system. Furthermore, as Saccharomyces cerevisiae is generally recognized as safe (GRAS), its use as a sensing platform aligns well with existing practices in beverage production. Yeast biosensors are being investigated for the early detection of contamination by spoilage microbes, such as Brettanomyces and lactic acid bacteria. These contaminants can alter the flavor profile and shorten the product’s shelf life. By providing timely feedback, these biosensor systems allow producers to intervene early, thereby reducing waste and enhancing consumer safety. In this work, we review the development and application of yeast-based biosensors as potential safeguards in fermented beverage production, with the overarching goal of contributing to the manufacture of safer and higher-quality products. Nevertheless, despite their substantial conceptual promise and encouraging experimental results, yeast biosensors remain confined mainly to laboratory-scale studies. A clear gap persists between their demonstrated potential and widespread industrial implementation, underscoring the need for further research focused on robustness, scalability, and regulatory integration. Full article

Port wine production involves the addition of grape spirit to halt fermentation and retain natural sweetness. This spirit, produced by distilling wine and its by-products, must comply with legal standards, including a mandatory sensory assessment. Because grape spirit influences Port wine’s volatile composition, this study investigated the odour-active compounds present in several grape spirits intended for fortification. Volatile compounds were extracted by liquid–liquid extraction, concentrated, and analysed using gas chromatography–olfactometry (GC-O) and gas chromatography–mass spectrometry (GC-MS). In GC-O, based on frequency detection, a panel of assessors sniffed the extracts to determine the presence of aroma compounds. The results revealed a wide range of odour-active compounds in grape spirits, belonging to several chemical families such as esters, alcohols, terpenic compounds and acids. These compounds exhibited both pleasant aromas, such as fruity, floral and caramel notes as well as undesirable ones like cheese and foot odour. Most of these compounds originate from the fermentation process and are also found in other unaged distilled beverages, including young Cognac, Calvados and fruit spirits. This research highlights the aromatic complexity of grape spirits and, for the first time, determined the aroma thresholds for 25 of 36 the compounds studied at an ethanol content of 20%. Full article

Hawk tea (Litsea coreana Levl. var. lanuginosa), a naturally caffeine-free herbal beverage widely consumed in Southwest China, is characterized by a pronounced camphoraceous note that often deters first-time consumers. In this study, hawk tea leaves were subjected to solid-state fermentation with four microbial strains—Monascus purpureus, Aspergillus cristatus, Bacillus subtilis, and Blastobotrys adeninivorans. The volatile compounds of unfermented and fermented hawk teas were identified by ultra-fast gas chromatography electronic nose (ultra-fast GC e-nose), gas chromatography–mass spectrometry (GC-MS) and gas chromatography–ion mobility spectrometry (GC-IMS) analyses, respectively. Furthermore, the calculation of odor activity values (OAVs) and relative odor activity value (ROAV) revealed that 6 and 25 volatile chemicals, including perillaldehyde (OAV 3.692) and linalool (ROAV 100), were the main contributors to the floral, fruity, and woody aroma of fermented hawk tea. Sensory evaluation confirmed that fermentation generally enhanced woody notes while significantly reducing the characteristic camphoraceous and oil oxidation odors. Notably, the Blastobotrys adeninivorans-fermented sample exhibited the most pronounced floral and fruity nuances, accompanied by significantly elevated aroma complexity and acceptability. Consequently, Blastobotrys adeninivorans represents a promising starter culture for the improvement of hawk tea flavor. Full article

Beer is a drink that has been a staple in human history, evolving from its beginning in antiquity to the present day. Nowadays, large breweries and other companies have set up laboratories focused on finding and developing new yeast strains for the brewing sector to meet consumers’ demand for new beer styles. Monascus spp. are ascomycota that have been known for hundreds of years. They are widely popular in Asian cuisine, especially in fermented foods. Studies show that Monascus spp. produce numerous food dyes and substances that positively influence human health. In the presented work, Monascus ruber was tested as a potential microorganism for the beer industry. Experiments included fermentation trials with Monascus ruber in four regimes: in aerobic condition, anaerobic condition, anaerobic condition with pH kept above 4.5, and in anaerobic condition with pH set to 4.5. As a reference, commercial Saccharomyces cerevisiae and Saccharomyces pastorianus were used. Fermentation parameters were evaluated by measurements of ethanol and extract level. The final product was tested for its colour in order to evaluate if monascus-derived pigments were present in the beverage. Moreover, a qualitative analysis of lovastatin and citrinin was performed in order to check if those monascus metabolites were present. Finally, small-scale consumer tests were performed in order to check the organoleptic properties of the obtained beverage. Results show that Monascus ruber is able to ferment beer wort in a similar manner as Saccharomyces strains, reaching a slightly lower degree of attenuation. Nevertheless, a longer lag phase was observed in monascus trials, except for the trial with preset pH at 4.5. The most visible change in the product was a reddish colour that appeared in the sample in aerobic conditions. The qualitative analysis showed that lovastatin and citrinin were present in the tested samples. Consumer tests show that experimental beer has a different taste than Saccharomyces-fermented products. Although the presented results are preliminary, they could be a good starting point for further research on monascus-based beverages. Full article

Fermentation is a complex biochemical process that transforms brewer’s wort into beer. Beer fermentation is driven by yeast and is influenced by process parameters such as the content of fermentable sugars in wort, temperature, and pH. Traditional methods of modelling this process rely heavily on empirically tuned kinetic models. However, these models tend to be recipe-specific and often require retuning when processes change. This paper proposes a data-driven approach using a Long Short-Term Memory (LSTM) network, a type of recurrent neural network, to model beer fermentation dynamics. By training the LSTM model on real-world fermentation data (1305 fermentations across ales, IPAs, lagers, and mixed-culture beers), including variables such as apparent extract (derived from specific gravity), temperature, and pH, we demonstrate that this technique can accurately predict key fermentation trajectories and support process monitoring and optimisation. When evaluated on representative medoid fermentations as one-step-ahead roll-outs over 0–300 h, the model produces accurate predictions with low errors and minimal residuals. These results show that the LSTM-based model provides accurate and robust predictions across beer styles and operating conditions, offering a practical alternative to traditional mechanistic kinetic models. This work highlights the potential of LSTM networks to enhance our understanding, monitoring, and control of fermentation processes, providing a scalable and efficient tool for both research and industrial applications. The findings suggest that LSTM models can be effectively adapted to model other fermentation processes in beverage production, opening new possibilities for advancing food science and engineering. Full article

Milk beer, a modern Chinese dairy beverage, is usually fermented by the co-culture of lactic acid bacteria (LAB) and Kluyveromyces marxianus (K. marxianus), with the latter known for its ability to produce aroma compounds. However, the accumulation of lactic acid produced by LAB can inhibit the growth of K. marxianus, which inevitably hinders the diversity and intensity of flavor compounds in milk beer. In this study, adaptive laboratory evolution (ALE) was applied to the parental strain Kluyveromyces marxianus CICC1953 (Km-P) under different concentrations of lactic acid to obtain an evolved strain Km-ALE-X20 with enhanced acid tolerance and increased titer of phenylethyl alcohol, which has a floral, rose-like aroma. Km-ALE-X20 demonstrated a 16-fold increase in OD₆₀₀ and a 28-fold increase in phenylethyl alcohol production compared with Km-P in chemically defined medium (CDM) containing 20 g/L lactic acid. Comparative genomics analysis suggested that mutated genes CTA1, TSL1, ERG2 were related to enhanced acid tolerance, while ARO8, ARO9, FKS2 were related to increased production of aroma compounds. Furthermore, Km-ALE-X20-fermented milk beer showed 33.87% and 32.43% higher production in alcohol and ester compounds than that of Km-P-fermented milk beer. Interestingly, sensory analysis showed that while Km-ALE-X20-fermented milk beer had higher sensory scores for rose and fruity aroma attributes, Km-P-fermented milk beer possessed a more balanced aroma profile. This paper highlights the first application of ALE to enhance the signature rose aroma of K. marxianus-fermented milk beer and provides an efficient framework for ALE-based breeding of aroma-producing food microorganisms. Full article

Fermentation, one of the oldest food processing techniques, is known to play a pivotal role in improving the nutritional and functional characteristics of cereals, with positive implications for gut health and overall well-being. The present study aims to examine the phenolic acids, peptides, and potential bioactive properties of 2 novel sorghum-based fermented beverages, Niselo and Delishe. A total of 48 phenolic compounds were identified through targeted and untargeted Ultra-High Performance Liquid Chromatography coupled with a Quadrupole Orbitrap High-Resolution Mass Spectrometer (UHPLC–Q-Orbitrap HRMS) analyses, revealing a higher content of phenolic acids in Niselo and a prevalence of flavonoids in Delishe. Niselo exhibited enhanced in vitro cytoprotective and reactive oxygen species (ROS)-scavenging activity and displayed a clear cytoprotective effect against hydrogen peroxide-induced oxidative stress in Caco-2 cells. Proteomic profiling using tryptic digestion revealed that Niselo has a substantial abundance of fragments of peptides matching several stress-related and antioxidant proteins, indicating a superior stress-response and/or defense capability. Overall, these findings highlight the functional potential of sorghum-based fermented beverages, supporting their role as health-promoting products. Full article

This study investigates the potential of tsipouro liquid waste (TLW) as a sustainable substrate for cultivating the edible–medicinal mushroom Hericium erinaceus under static liquid fermentation. TLW naturally contains high glycerol levels and significant quantities of phenolic compounds; therefore, five media (0–50% v/v TLW) with varying phenolic concentrations and a standard initial glycerol level (~20 g/L) were prepared to simulate TLW-type substrates. Throughout fermentation, physicochemical parameters in the culture medium (pH, electrical conductivity, total sugars, free amino nitrogen, proteins, laccase activity, total phenolics, ethanol, glycerol) and biomass composition (intracellular polysaccharides, proteins, lipids, phenolic compounds, flavonoids, triterpenoids, antioxidant activity) were determined. Results showed that increasing TLW concentration enhanced biomass production and bioactive metabolite accumulation. The highest dry biomass (22.8 g/L) and protein (4.06 g/L) content were obtained in 50% v/v TLW, while maximum polysaccharides (6.8 g/L) occurred in 17% v/v TLW. Fungal growth led to a reduction of up to 74% in total phenolic content, indicating simultaneous bioremediation potential. Fruiting body formation—rare and uncommon in liquid cultures—occurred at the end of fermentation period. Fruiting bodies contained higher protein (24.5% w/w) and total phenolic compounds (13.36 mg GAE/g), whereas mycelium accumulated more polysaccharides (49% w/w). This study demonstrates that TLW can serve as a cost-effective, ecofriendly medium for producing high-value H. erinaceus biomass and bioactive metabolites, supporting circular bioeconomy applications in the alcoholic beverage sector. Full article

The global rise in chronic inflammatory diseases has fueled an increased demand for functional beverages containing bioactive compounds with anti-inflammatory properties. This review synthesizes trends in research output, technological innovation, and consumer behavior related to such beverages from 2006 to 2025. A total of 1635 peer-reviewed articles were analyzed using bibliometric tools and content analysis. Results indicate a thirteenfold increase in publications, with China, India, the USA, and Brazil leading in research output. Key themes include polyphenols, curcuminoids, fermentation, encapsulation, and non-thermal processing. The review identifies four major research clusters: antioxidant mechanisms, metabolic and cytokine regulation, plant-derived flavonoids, and phytochemical profiling. Consumer behavior analysis reveals that taste, clean-label appeal, and health claims influence market success. While technological advances such as nanoencapsulation and high-pressure processing improve bioavailability and sensory quality, gaps persist in clinical validation and regulatory harmonization. This study offers integrated insights for researchers, industry professionals, and policymakers to guide innovation and evidence-based development of anti-inflammatory functional beverages. Full article

Kombucha is a millennia-old beverage crafted from green or black tea and saccharides and fermented with a symbiotic culture of bacteria and yeast (SCOBY). This functional drink boasts health benefits, such as improved intestinal flora function, hepatoprotection and inhibition of amyloid fibers. It contains bioactive antioxidants, such as catechins, ascorbic acid, vitamins and other polyphenolic compounds. With kombucha’s rising popularity, the Food and Drug Administration (FDA) has implemented control procedures to ensure the quality and safety of this food product. Due to the antioxidant properties of the major bioactive compounds in kombucha, feasible and low-cost electroanalytical methods emerge as promising alternatives. The objective of this study was to evaluate the voltammetric behavior of kombucha samples to establish and compare their redox profiles and antioxidant activities. Thus, 18 kombucha samples were used, comprising commercial samples and samples prepared in the laboratory from different SCOBYs purchased from different countries, and analyzed by differential pulse voltammetry (DPV) and square wave voltammetry (SWV) on a carbon paste electrode (CPE). The electrochemical index (EI) values determined from the samples were used to establish their antioxidant activities. The EI values were also compared with spectrophotometric data from Folin–Ciocalteu (FC) and Ferric Reducing Antioxidant Power (FRAP) assays. Full article

Background/Objectives: Moderate consumption of fermented beverages such as traditional beer has been associated with antioxidant and anti-inflammatory effects. MicroRNAs (miRNAs) play key roles in inflammation and oxidative stress, yet the impact of moderate fermented beverage consumption on blood miRNA profiles remains poorly understood. This study investigated the effects of regular, moderate intake of traditional and alcohol-free beer on whole blood miRNA levels in healthy adults. Methods: Whole blood samples were collected at baseline and after a 4-week intervention with alcohol-free beer and traditional beer in healthy overweight/obese adults (n = 36). miRNA profiling was performed using Affymetrix in a discovery subset, followed by targeted validation using real-time PCR in the full cohort. Bioinformatics and system biology analysis were applied to explore potential functional associations. Results: After traditional beer consumption, 202 miRNAs showed differential expression compared to baseline (p < 0.05). Eighteen miRNAs with changes ≥1.5-fold and the two miRNAs with the lowest p-values (p < 0.005) were selected for further analysis. Of them, the six miRNAs with the most consistent expression patterns were validated by real-time PCR. Moderate beer intake was associated with increased levels of miR-144-5p and miR-19a-3p in the overall population. Sex-stratified analyses suggested a tendency toward higher levels in these miRNAs in women following traditional beer intake. In silico analysis showed that predicted target genes of these miRNAs are involved in pathways related to immune regulation and inflammatory signaling. Conclusions: Moderate beer consumption is associated with consistent changes in whole-blood miRNA expression, particularly miR-144-5p and miR-19a-3p, in a healthy overweight/obese population. These findings support a potential role for epigenetic modulation in the biological response to moderate beer intake and provide a basis for future mechanistic studies. Full article

The incorporation of native Amazonian fruits into dairy products has increased due to their ability to improve technological, sensory, nutritional, and biological properties. Therefore, this study aimed to evaluate the impact of cupuassu (Theobroma grandiflorum) pulp on the chemical, physical, and sensory characteristics of fermented milk, using a central rotational composite design with two factors (sugar and cupuassu pulp). Our results are presented as response surfaces, showing that cupuassu pulp is positively associated with the examined parameters (pH, titratable acidity, total soluble solids, total phenolic compounds, syneresis, and water retention capacity). The analysis suggested a promising formulation containing 27.8% cupuassu pulp and 8.6% sugar. The pulp and this promising formulation were characterized by pH, titratable acidity, total soluble solids, proximate composition, and bioactive compounds (total phenolic compounds (TPC) and antioxidant activity). The physicochemical stability of the beverage was monitored over 28 days. Sensory acceptance and purchase intention for the promising formulation were also evaluated. Cupuassu contributed to an increase in soluble solids, while pH and titratable acidity remained stable during storage. Additionally, cupuassu pulp increased the total phenolic content and enhanced the beverage’s antioxidant activity. Sensory analysis showed that adding cupuassu pulp positively influenced all evaluated attributes (83% acceptance) and was associated with a favorable purchase intention. Incorporating cupuassu pulp into fermented milk proved to be technologically feasible and sensorially acceptable, meeting the demand for innovative dairy beverages with functional and sensory benefits. Full article

Mead is an alcoholic beverage obtained through the action of yeast in a diluted solution of honey and water. According to the literature, recent studies have demonstrated the potential of the probiotic yeast Saccharomyces cerevisiae var. boulardii in mixed fermentation with microbial sources such as kombucha and water kefir for the development of mead. Although mead produced by mixed fermentation of S. boulardii and water kefir has already been proposed, characteristics related to the shelf life and sensory profile of this product have not yet been evaluated. The present study aimed to determine the shelf life and sensory characteristics of potentially probiotic mead produced by mixed fermentation of S. boulardii and water kefir. The main results showed that mead produced by S. boulardii and water kefir has a shelf life of 60 days when stored at 7 ± 1 °C, with viable cell counts above 6 log CFU/mL for yeasts and lactic acid bacteria, meeting the minimum count recommended for probiotic foods. With regard to sensory characteristics, the product showed high sensory acceptability with scores above 7.0 points for all attributes evaluated and obtained a high purchase intention, with an average score of 5.17 points. In addition, mead by S. boulardii and water kefir was characterized by sensory attributes and terms described by panelists as effervescent, tasty, sweeter, refreshing, honey flavor, and less alcoholic. In conclusion, the potentially probiotic mead by mixed fermentation of S. boulardii and water kefir has an adequate shelf life and high sensory acceptance. Full article

Nowadays, consumer demand for functional foods with health benefits has grown significantly. In response to this trend, a variety of potentially probiotic foods have been developed—most notably kefir and kefir-like beverages, which are highly appreciated for their tangy flavor and health-promoting properties. Traditionally, kefir is made by fermenting cow’s milk with milk kefir grains, although milk from other animals—such as goats, ewes, buffalo, camels, and mares—is also used. Additionally, non-dairy versions are made by fermenting plant-based milks (such as coconut, almond, soy, rice, and oat) with the same type of grains, or by fermenting fruit and vegetable juices (e.g., apple, carrot, fennel, grape, tomato, prickly pear, onion, kiwifruit, strawberry, quince, pomegranate) with water kefir grains. Despite their popularity, many aspects of kefir production remain poorly understood. These include alternative production methods beyond traditional batch fermentation, kinetic studies of the process, and the influence of key cultivation variables—such as temperature, initial pH, and the type and concentration of nutrients—on biomass production and fermentation metabolites. A deeper understanding of the fermentation process can enable the production of kefir beverages tailored to meet diverse consumer preferences. Full article

Chirality remains the most neglected axis of pesticide residue science. Many active ingredients are sold as racemates although their enantiomers differ in potency, persistence, transport, and toxicology; as a result, total concentration is a poor surrogate for risk. This review synthesizes green and enantioselective strategies spanning the full analytical–remediation continuum. We survey solvent-minimized sample preparation approaches (SPME/TF-SPME, FPSE, µSPE, DLLME with DES/NADES), MS-compatible chiral separations (immobilized polysaccharide CSPs in LC and SFC, cyclodextrin-based selectors in GC, CE/CEC), and HRMS-enabled confirmation and suspect screening. Complex matrices (e.g., fermented beverages such as wine and high-sugar products) are critically discussed, together with practical matrix-tolerant workflows and the complementary role of chiral GC for hydrophobic residues. We then examine emerging enantioselective materials—MIPs, MOFs/COFs, and cyclodextrin-based sorbents—for extraction and preconcentration and evaluate stereoselective removal via adsorption, biodegradation, and chiral photocatalysis. Finally, we propose toxicity-weighted enantiomeric fraction (EF) metrics for decision-making, outline EF-aware green treatment strategies, and identify metrological and regulatory priorities (CRMs, ring trial protocols, FAIR data). Our thesis is simple: to reduce hazards efficiently and sustainably, laboratories and practitioners must measure—and manage—pesticide residues in the chiral dimension. Full article