Search Results (147)

Beer aroma is a critical quality attribute shaped by volatile compounds from malt, hops, and yeast metabolism; however, the appearance of off-flavours can compromise it. This review identifies and describes the main aroma-active compounds that define the beer’s sensory profile, emphasising both key odorants and undesirable notes, such as diacetyl, dimethyl sulphide, acetaldehyde, and light-struck thiols. Based on recent literature, a troubleshooting guide was developed to link specific odours with their particular chemical compounds, origin, and corrective actions. The findings highlight how the composition of raw materials, processing and storage conditions, treatments, fermentation management, and even packaging play an important role in flavour stability. By identifying the sources of common defects and offering practical solutions, this work provides brewers with strategies to enhance aroma control and improve overall beer quality. Full article

The production of craft beer depends on the quality and availability of yeast. However, many small breweries in developing countries face high costs due to their reliance on imported yeast strains. Developing efficient and low-cost propagation methods is therefore essential for sustainable production. A lager-type Saccharomyces cerevisiae strain (SC-Lager2) was propagated using both synthetic and low-cost alternative media. The latter was formulated with malt extract as a carbon source and yeast extract obtained from brewery by-products as a nitrogen source. A Plackett–Burman design identified significant factors influencing growth (p < 0.05), and a full factorial design (2⁴) optimized conditions. Growth kinetics and biomass yield were validated at laboratory (2 L) and pilot (83 L) scales. Maltose, yeast extract, zinc sulfate, and agitation significantly affected cell density and viability (p < 0.05). Under optimized conditions, 100% viability, a maximum cell density of 1.4 × 10¹⁰ cells/mL, and a biomass yield of 10 g/L were achieved values that were statistically higher (p < 0.05) than those obtained with the synthetic medium. The maximum specific growth rate (μ_max) increased by 52%, while doubling time decreased by 39%. Overall, the use of agro-industrial by-products reduced medium costs by approximately 65% compared to conventional synthetic formulations. The proposed low-cost medium provides a scalable, economical, and sustainable solution for yeast propagation, reducing production costs while maintaining high cell viability and performance. This approach supports the autonomy and competitiveness of the craft beer sector in developing regions. Full article

Wheat cultivars significantly affect the quality of grain and then malt, which are used in the production of wheat beers, determining their potential use in brewing. Nowadays, consumers are increasingly choosing products with high biological activity, even for alcoholic beverages. Furthermore, organoleptic testing is crucial, as despite their high physicochemical parameters, wheat beers may not be met with consumer acceptance. The antioxidant activity and total polyphenol content of the obtained wheat beers were determined and identified, and organoleptic analysis was performed. Wheat beers obtained from malt derived from the Elixer cultivar of wheat were characterized by the highest polyphenol profile values (3.01 mg·L⁻¹) and antioxidant activity determined by the ABTS method (0.72 mg TE·L⁻¹). The Lawina cultivar also had a high ABTS value (0.73 mg TE·L⁻¹). Total polyphenol content (89.07 mg·L⁻¹), antioxidant activity (DPPH; 1.08 mg TE·L⁻¹), antiradical activity (FRAP; 1.58 mg Fe²⁺·L⁻¹), and organoleptic profile were highest in wheat beers obtained from malt derived from the Gimantis cultivar of wheat. Based on the conducted research, it was found that beers obtained from Gimantis wheat are characterized by the best quality parameters, including antioxidant activity. The Gimantis cultivar showed the least variation in quality of wheat beers in terms of the growing season and is recommended as a wheat cultivar for the brewing industry. It is also recommended to conduct further research on beer products obtained from the analyzed winter wheat varieties, including the antioxidant potential of finished non-alcoholic products. Full article

The aim of this study was to evaluate the effect of foliar application of selected micro-nutrients on the chemical composition and malting quality of spring barley (Hordeum vulgare L.). The scientific literature lacks in-depth studies that assess the effect of foliar application of micronutrients on barley malting quality. Most studies (especially under field conditions) focus on nitrogen fertilization rather than individual micronutrients. Three brewing-type barley cultivars (Baryłka, KWS Irina, and RGT Planet) were evaluated under foliar micronutrient fertilization (Cu, Mn, Mo, Zn). Fertilizers were applied at doses of 2 L ha⁻¹ for Cu, Mn, and Zn and 1 L ha⁻¹ for Mo. The experiment examined the hectoliter mass, theoretical extractability, contents of selected micro- and macronutrients, and the protein, fat, fiber, and ash contents of the grain. Furthermore, the following characteristics of barley malt were determined, i.e., moisture, protein, extractivity, Kolbach index, and diastatic power. The results showed significant variability in grain and malt quality depending on the cultivar and year. The Baryłka cultivar was characterized by the highest grain density (66.3 kg hL⁻¹) and protein content (10.9% d.m.), while RGT Planet had the highest extractivity and the most favorable malting profile. Foliar supplementation had a slightly positive effect on the average content of trace elements in barley. Mn application increased grain Ca content by 5.6% compared with the control, while foliar Zn fertilization resulted in the highest zinc concentration (a 24.7% increase). No significant effect of fertilization on malt quality was observed, but a significant interaction of experimental factors in extractivity, Kolbach index, and diastatic power was noted. The obtained results indicate that a single foliar application of microelements affects the contents of minerals and protein in the grain, but it does not lead to a significant improvement in malting parameters. This suggests the need for further research on dosage, application date, and interactions between the cultivar and environmental conditions. Full article

Beer consumption behaviors within China exhibited significant regional heterogeneity. To elucidate the specific differences in beer consumer behaviors across different regions and their influencing factors, this study systematically analyzed the sensory preference characteristics of consumers in the Chinese beer market based on machine learning methods, and further revealed the core driving mechanisms influencing their consumption behaviors. By integrating consumer data from different regions, a comprehensive dataset was constructed encompassing sensory attribute evaluations (bitterness, malt flavor, hop aroma, smoothness of mouthfeel, foam characteristics, etc.) and other dimensional consumption behavior variables (brand, beer packaging, etc.). Utilizing an ensemble learning framework (LightGBM), Support Vector Machine (SVM), and decision tree models for feature mining, the study identified important factors influencing the consumption behaviors of Chinese beer consumers. Specifically, consumers in mature and upgrading markets placed greater emphasis on the overall drinking experience and drinkability when purchasing beer, whereas consumers in scale-dominant and mainstream competitive markets considered foam persistence, fineness, and light brown color as core quality indicators. Conversely, consumers in potential growth and emerging cultivation markets demonstrated strong brand orientation. This indicated that the factors influencing beer consumption behaviors varied significantly across regions. Through a data-driven paradigm, this study revealed the underlying regional mechanisms behind consumption decisions in different regional beer markets in China, providing a theoretical foundation and empirical support for cross-regional product customization, precision marketing, and resource optimization. Full article

Background/Objectives: This study reports pilot-scale production of gluten-free rice malt extract powder from Thai Chainat 1 rice as a sustainable alternative to barley malt extract. Methods: The process combined controlled malting with sequential enzymatic hydrolysis, optimized through bench-scale validation and scaled up to a 1500 L pilot system. Results: The resulting powder was rich in fermentable sugars (maltose 43.9 g/100 g, glucose 14.3 g/100 g), protein (5.2 g/100 g), γ-aminobutyric acid (GABA, 245.2 mg/100 g), and thiamine (0.64 mg/100 g), while free of detectable gluten, aflatoxins, and heavy metals. Microbiological quality met international safety standards. Shelf-life studies under ambient and accelerated conditions demonstrated chemical stability and bioactive retention for up to three years in laminated and HDPE packaging. Application trials confirmed that the rice malt extract powder supported yeast, bacterial, and mold growth comparably to commercial malt extract in culture media, with optimized yeast–mold agar formulations enabling direct substitution without supplementary glucose. The powder was further applied to a gluten-free malt beverage, yielding a beer-like product with acceptable physicochemical and nutritional quality, though residual alcohol levels exceeded the non-alcoholic threshold and required process optimization. Conclusions: Rice malt extract powder represents a safe, functional ingredient suitable for food, beverage, and industrial microbiology applications, offering opportunities to reduce import dependency and advance gluten-free innovation in emerging markets. Full article

Barley (Hordeum vulgare L.) is a key cereal crop for malting and brewing, where grain plumpness and optimal grain protein concentration (GPC) are essential quality traits. This study investigated the combined effects of nitrogen fertilization strategies and a seaweed-based biostimulant (Ascophyllum nodosum extract) on malting barley production across four environments in Thessaly, Greece, over two growing seasons. Treatments included urea (U), urea with biostimulant (U + B), urea with urease inhibitor (UI), urea with urease inhibitor and biostimulant (UI + B), and a control (no fertilization). Applications were tested on genotype G20 at mid-development (Z30–33) and genotype G45 at an earlier stage (Z24–30). UI + B treatment consistently enhanced yield by up to 71%, thousand-grain weight by 27%, and spikelets per square meter by 75% relative to the control, with responses influenced by genotype and environment. Grain fractions > 2.8 mm increased by up to 22% under UI + B, while GPC remained within the optimal malting range (9.5–11.5%). Early-stage applications produced strong benefits overall. Principal component analysis distinguished treatment effects, with UI + B samples clustering consistently apart from controls. These results demonstrate that combining biostimulants with urease inhibitors can simultaneously improve yield, quality, and sustainability in malting barley, supporting reduced nitrogen input in Mediterranean systems. Full article

Soybeans are often used as a raw material for the production of plant-based beverages. Malting significantly changes the properties of malted seeds; therefore, the aim of this study was the assessment of beverages obtained from soy malts (two types: ‘Pilsener’ and ‘Caramel’) produced from three soy varieties (Abaca, Abelina, and Aurelina). Beverages produced from malts were characterized by a higher protein content compared with beverages from unmalted seeds. The control samples showed a lower content of the sum of all amino acids (363.89–371.04 mg/g) compared with beverages from both types of malts, and the highest content was determined in the beverage from caramel-type malt of the Abaca variety (434.60 mg/g). Beverages from caramel-type malt of the Abaca and Aurelina varieties contained the largest concentration of phenolic compounds (8.35–10.33 mg GAE/100 mL) and the highest antioxidant activity (ABTS^•+ 0.36–0.45 μmol Trolox/mL, FRAP 0.24–0.30 μmol Trolox/mL, and DPPH 0.08–0.09 μmol Trolox/mL). Analysis of the concentration of volatile compounds has shown that using malted soybeans had a significant effect on the composition and share of various groups of volatile compounds (aldehydes, alcohols, terpenes, and ketones) in the analyzed beverages. The obtained results indicate the possibility of using soy malt in the production of plant-based beverages. However, further work is necessary to improve the quality and organoleptic properties of these products. Full article

This study investigated the combined effects of quinoa malt addition (0%, 5%, 10%) and grain variety (white, red, black) on the nutritional and sensory properties of quinoa sourdoughs. Quinoa malt supplementation significantly (p < 0.05) enhanced fermentation characteristics, increasing titratable acidity from 20.0–20.4 to 21.2–23.8 mL NaOH/10 g and dynamic viscosity up to 733 ± 5.59 mPa·s compared to 474–611 mPa·s in controls. Malt enrichment expanded the volatile profile from predominantly alcohols and acids to include 25 distinct compounds spanning esters, terpenes, aldehydes, phenols, and furans, creating more complex aromatic profiles. Lactic acid production increased significantly in all malted samples, reaching 12.92 ± 0.00 g/kg in black quinoa with 10% malt. Black quinoa sourdoughs exhibited superior nutritional density with the highest protein (17.3 ± 0.1%), total dietary fiber (17.94 ± 0.14%), potassium (7896 ± 176 mg/kg), and manganese (55.65 ± 0.47 mg/kg) contents (p < 0.05). White quinoa variants demonstrated the highest acidity (pH 4.28 ± 0.01) and mineral bioavailability (magnesium: 5371 ± 70 mg/kg), while red quinoa achieved maximum viscosity (733 ± 5.59 mPa·s) and zinc content (38.08 ± 0.26 mg/kg). Volatile compound distribution varied significantly by variety, with white quinoa favoring ester and terpene formation, red quinoa promoting aldehydes and terpenes, and black quinoa accumulating phenols and furans. These findings demonstrate that strategic combination of quinoa variety selection and malt optimization can produce functionally enhanced, gluten-free sourdoughs with targeted nutritional and sensory characteristics for specialty bakery applications. Full article

The aim of this study, as part of a collaboration between a malt house, a brewery, and a university, was to optimize the beer production process while simultaneously maintaining or even improving the quality of the beer and creating conditions for the optimization of the malting of barley grain. The Hurbanovo malt house provided 100 t of a specially prepared batch of malt for use in industrial-scale beer production at the Żywiec brewery (which produces 4.7 million hl annually). The malt, produced from barley variety Overture, was characterized by a higher extract and protein content and increased enzymatic activity. The test malt also demonstrated favorable properties such as higher friability, lower viscosity, and a two-fold shorter saccharification time. Four HGB worts were produced during production tests. Each brew used 21.5 tons of malt, yielding an average 1020 hl of wort, with an extract content of 15.5°Blg. The malt was milled in a two-roll wet mill with a capacity of 40 t per hour. Mash filtration took place in lauter tuns with a diameter of 12.4 m each. The produced worts were transferred into a fermentation tank with a capacity of 5500 hl, and then fermentation, maturation, and lagering processes were carried out. The tested batch of malt was examined in detail and compared with a standard malt blend from three different suppliers. The tests showed an increase in extract efficiency in the process, with a simultaneous reduction in extract losses (1.2%pt.). The filterability of the mash improved compared to the standard blend, and an improvement in wort quality was observed as a result of lower turbidity (by approximately 34%). The data obtained indicate an improvement in the process with the use of the specially prepared batch of malt. Full article

This study investigated the minimization of the N₂O emissions related to brewery wastewater treatment by malt-sprout-derived biochar. The biochar was derived using slow pyrolysis (300 (B1), 400 (B2), and 550 °C (B3)). The correspondence between the N₂O emission and wastewater treatment quality was investigated by Monte Carlo simulation. An average of 25.6% of minimization in N₂O emissions was reported by malt-sprout-derived biochar. The simulation results showed that the Total Kjeldahl Nitrogen (TKN) and ammonium (NH₄-N) had the highest correspondence with N₂O emissions. Full article

The role of science and technology in enhancing beer quality is crucial amid growing market demands. This pilot study assessed the clarity and physicochemical stability of laboratory beers treated post fermentation with three clarifying (fining) agents: two chitosan-based and one collagen-based (fish bladder/isinglass). The beers were brewed with Polish barley malt and hops (alpha acids 7.5% and 14.5%). The measured parameters included pH, colour, turbidity, viscosity, surface tension, and foam volume. Within this small-scale, low-power dataset, both the collagen- and chitosan-based agents improved clarity, with the collagen agent showing the lowest turbidity in this sample. The clarifying agents also influenced the colour and surface tension, while the pH was largely unchanged. The foam volume increased with fining. Shelf-life checks suggested improved stability in clarified beers, with no clear differences between agents under these conditions. These findings are preliminary. The results should be interpreted cautiously due to the limited number of replicates. Larger scale studies with adequate replication are required before translating these observations into brewing practice. Chitosan’s effectiveness as a clarifying agent aligns with its high charge density and ability to coagulate suspended particles. This study underscores the importance of selecting appropriate clarifying agents to optimize beer clarity and stability while maintaining essential physicochemical properties. These findings contribute to the brewing industry’s efforts to meet consumer expectations for high-quality, stable beer products. Full article

Since wheats used for use in brewing mainly belong to the winter red hard hybrid endosperm type, this paper examined the influence of different proportions of wheat of this type (seven varieties) in the ratio of 0–100% in the grist, both unmalted and as wheat malt. The quality of the starting wheats, the resulting malts and mashs with different added wheat proportions (100, 80, 60, 40, 20 and 0%) were examined. The obtained results show that the maximum shares of wheat/wheat malt in the infusion are significantly different between varieties of similar initial quality. However, they can differ considerably for the same variety when it is used as unmalted raw material and when it is used as wheat malt. Wheat malt can be added to the mixture in a significantly larger proportion compared to unmalted wheat. Furthermore, when an extended number of criteria (parameters) are applied, some varieties may be acceptable that otherwise would not be if the basic number of parameters were applied (total protein—TP, total soluble protein—TSP and viscosity—VIS) and vice versa. The inclusion of other parameters—filtration speed (FIL), saccharification time (SAC), color (COL), proportion of fine extract (EXT) and fermentability of pomace (FAL) (some of which have the character of so-called “cumulative parameters”)—complicates a clear classification into the aforementioned qualitative groups but also increases the number of varieties acceptable or conditionally acceptable for brewing. Full article

Bambara groundnut (Vigna subterranean) is an important legume grain in sub-Saharan Africa, including South Africa. Nevertheless, the peculiarity of being hard to cook and mill and the availability of antinutritional factors often limit Bambara groundnut (BGN) use in food applications. This study investigated the impact of dehulling and malting on the nutritional composition, antinutritional factors, and protein digestibility of flours obtained from three BGN varieties (red, cream, and brown). Dehulling and malting significantly enhanced the moisture and protein content of BGN flours (dry basis), with values varying from 6.01% (control brown variety) to 8.71% (malted cream and brown varieties), and from 18.63% (control red variety) to 21.87% (dehulled brown), respectively. Dehulling increased the fat content from 5.82% (control red variety) to 7.84% (dehulled cream), whereas malting decreased the fat content. Nevertheless, malting significantly increased (p < 0.05) the fiber content from 4.78% (control cream) to 8.28% (malted brown variety), while dehulling decreased the fiber content. Both processing methods decreased the ash and carbohydrate contents of the BGN flours. Dehulling and malting significantly enhanced the amino acids of BGN flours, except for tryptophan and asparagine. Dehulling and malting notably increased the phosphorus, magnesium, potassium, and sulfur contents of the BGN flours, while calcium and zinc were reduced. Malting significantly enhanced the iron content of BGN flour, whereas dehulling reduced it. Both processing methods significantly enhanced palmitic, arachidic, and y-Linolenic acids. Nonetheless, processing methods significantly reduced phytic acid and oxalate, and dehulling achieved the most significant reductions. Dehulling and malting significantly enhanced the protein digestibility of the BGN flours from 69.38 (control red variety) to 83.29 g/100 g (dehulled cream variety). Overall, dehulling and malting enhanced the nutritional quality and decreased the antinutritional factors of BGN flours. Full article

Malt bagasse is the primary solid waste product from the brewing process, with notable environmental implications. Due to its nutritional value, it has potential as animal feed, primarily through ensilage. Alfalfa pellets can enhance this silage by adding digestible nitrogen and fibre. However, the high moisture content favours microbial contamination, particularly by fungi like Fusarium, which produces harmful mycotoxins. This study evaluated the impact of winter silage on fungal diversity, Fusarium presence, and mycotoxin contamination in malt bagasse, comparing the pre- and post-silage stages with the addition of alfalfa pellets. Results showed a diverse range of fungi, including Mucor, Cladosporium, Fusarium, and Penicillium, as well as yeasts. Fungal contamination was higher before silage, although the addition of alfalfa increased it after silage was produced. Fusarium verticillioides was the most common Fusarium species. Mycotoxin analysis detected DON (1.4 ppb) in only one sample. A two-month winter silage process under cold-temperate conditions appears to reduce fungal contamination and preserve feed quality. These findings support silage as a circular strategy to manage brewery waste safely, but further research and policy measures are needed to minimise biological risks in the brewing and livestock sectors amid climate change. Full article