Search Results (140)

The rising demand for sustainable and functional ingredients necessitates the development of novel replacers for traditional food components, such as eggs, which are critical for structure and aeration in baked goods. This study investigated hydrocolloids derived from cassava (Manihot esculenta) as a partial egg substitute in sponge cakes, evaluating their effect on rheological, physicochemical, nutritional, and sensory properties. The resulting cake batter exhibited characteristic non-Newtonian, pseudoplastic, and viscoelastic fluid behavior. A microstructural analysis confirmed that the stabilized, higher-viscosity doughs successfully facilitated the formation of larger, more stable air bubbles, effectively mimicking the structural role of the egg. Physicochemical assessments demonstrated a high product equivalence; the fat content showed no significant difference (p < 0.05) compared to the control, while pH and carbohydrate levels decreased. Crucially, the optimized formula, CK-S50-H2.5 (50% egg and 2.5% hydrocolloids substitutions), exhibited a minimal color difference (ΔE) consistent with the control, preserving product appearance. Sensory evaluation confirmed that hydrocolloid substitution did not compromise consumer acceptance. Panelists preferred cakes utilizing lower egg substitution levels for their enhanced flavor and texture. These findings establish that cassava hydrocolloids serve as an effective and functional partial egg replacer, yielding a high-quality and well-accepted product and offering a valuable, sustainable solution for the food industry. Full article

Leaf and spike diseases can significantly reduce wheat yield and grain quality. To mitigate these impacts, an integrated disease management approach can be adopted, incorporating measures such as the use of resistant cultivars, fungicides and nitrogen fertilization. This study aimed to evaluate the impact of these practices on chlorophyll a fluorescence, yield components, and the technological quality of wheat grains. The area under the disease progress curve (AUDPC) was correlated with the maximum efficiency of photosystem II (PSII) photochemistry (F_v/F_m), as measured at the dough development stage (ZGS80) under field conditions, which also affected quality parameters. Additionally, an increase in AUDPC values reduced the thousand kernel weight (TKW) and test weight (TW). Conversely, AUDPC values for tan spot, powdery mildew and leaf rust were positively related to ash content (affecting flour color), protein content (PC) and grain falling number. Both the recommended nitrogen rate (130 kg ha⁻¹) and the high rate (200 kg ha⁻¹) increased grain protein content (PC) and gluten index (GI), while maintaining dough stability and water absorption. Fungicide application increased flour lightness and yellowness. Overall, integrated disease management combining moderately resistant cultivars, fungicide applications and nitrogen fertilization reduced AUDPC values, increased F_v/F_m (indicating optimal physiological performance) and ensured yield components and maintenance of wheat technological quality. Full article

Type 2 diabetes mellitus (T2DM) remains a global health challenge, necessitating novel therapeutic and dietary strategies. This study optimized hydroalcoholic extraction parameters to maximize α-amylase inhibitory activity from five African medicinal plants: Combretum glutinosum (CG), Ziziphus mauritiana (ZM), Gymnosporia senegalensis (GS), Boscia senegalensis (BS), and Citrullus colocynthis (CC). A central composite design (CCD) modeled the effects of the liquid-to-solid (L/S) ratio (5–15 mL/g) and ethanol concentration (0–100%, v/v), identifying optimal conditions at low L/S ratios (5 mL/g) and moderate-to-high ethanol concentrations (40–100%) for GS, ZM, and CG, where inhibition levels exceeded 80–98% of α-amylase activity. Extracts from CG, ZM, and GS showed the strongest inhibition (IC₅₀ values of 3.67, 9.8, and 2.25 mg/mL, respectively). Antioxidant capacities, evaluated by DPPH and FRAP assays, correlated strongly with total phenolic content (TPC), with ZM exhibiting superior DPPH (IC₅₀ = 1.94 ± 0.16 mg/mL) and FRAP (IC₅₀ = 4.34 ± 0.52 mg/mL) activities. Incorporation of optimized plant powders (3%, w/v) into bread dough significantly influenced textural and colorimetric properties. Mixture design analysis revealed that CG-rich formulations (>2%) yielding hardness exceed 6 N, while ZM–GS blends maintain 3 N, offering targeted firmness control. The addition of medicinal plants significantly increased the total phenolics content by 60% of doughs and thus caused a significant improvement in antioxidant activities. These functional enrichments suggest potential for developing hypoglycemic bakery products with improved sensory attributes. This integrative approach combining extraction optimization and food formulation offers promising avenues for natural antidiabetic agents and functional food development. Full article

Highland barley (HB), a nutrient-rich grain, is limited in bread applications due to its weak gluten network and high content of non-starch polysaccharides (NSPs) such as β-glucan and arabinoxylan. This study aimed to improve the dough properties and bread quality of a composite flour containing 40% whole-grain highland barley through synergistic use of xylanase and β-glucanase. Rheological analysis revealed that dual-enzyme treatment significantly reduced dough rigidity (G′ decreased by ~40%) and increased extensibility (tan δ raised by ~25%), shifting the network from a brittle NSP-dominated gel toward an elastic gluten-based structure. Low-field NMR showed that enzymes promoted redistribution of water from tightly bound states with NSPs to protein phases, enhancing gluten hydration. Microstructural observations confirmed a more continuous and uniform gluten network with finely embedded starch granules. Consequently, enzyme-treated bread exhibited a 35% higher specific volume, reduced hardness (~50% lower), improved springiness and cohesiveness, and superior sensory scores in texture, taste, and overall acceptability compared to the untreated composite. Single-enzyme treatments yielded partial improvements, highlighting the necessity of synergistic action. These results demonstrate that combined xylanase and β-glucanase treatment effectively mitigates the negative impact of NSPs, enabling the production of high-quality, sensorially appealing HB-enriched bread with optimized structural and textural properties. Full article

Global chestnut production has grown significantly in recent years, driven by its health benefits and growing interest in sustainable agriculture. Chestnut processing produces a solid residue consisting primarily of the fruit’s outer shell (pericarp), which is generally disposed of by on-farm combustion. However, this waste biomass shows a high potential for valorization due to its nutritional composition, particularly as a source of dietary fiber and polyphenols. In this study, the valorization potential of chestnut outer shells was evaluated through two approaches, demonstrating possible applicability at an industrial level: (1) the recovery of polyphenols using a simple and environmentally friendly extraction method, easily applicable on-farm, based on hot water as a solvent under different time–temperature combinations according to Response Surface Methodology (Central Composite Design); (2) the addition of chestnut outer shell flour during breadmaking as a source of fiber supplementation. Optimization of the extraction process using Response Surface Methodology combined with the desirability function identified optimal conditions at 102 min and 115 °C, yielding a maximum of approximately 172.30 mg of polyphenols per gram of dry outer shell. The incorporation of chestnut outer shell flour into bread formulations resulted in reduced dough workability, increased crust hardness (13.00 ± 0.87; 36.00 ± 1.00), and a darker bread color (1278.33 ± 39.27; 584.33 ± 25.90 RGB), particularly in the crumb. Full article

Artemisia absinthium L. is a medicinal plant well known for the bitterness of its sesquiterpenoids. To mask its intense taste while preserving these active compounds, an ethanolic extract (AAE) was prepared, and two microencapsulation techniques (spray drying and ionotropic gelation) were investigated under different process conditions. The best-performing formulation was selected for larger-scale production and a characterisation of the microparticles (MPs) was carried out. MPs were then incorporated into baked products (biscuits), which were subsequently characterised for proximate composition, total phenolic content (TPC) and antioxidant activity (AA). Bitter compounds were quantified through HPLC-DAD. A panel test was conducted on 50 volunteers, which compiled a satisfactory questionnaire. Ionotropic gelation proved to be the most suitable technique for producing AAE alginate-based MPs for incorporation into biscuit dough, yielding a product with a desirable particle size and flowability. The biscuits still retained a significant amount of TPC and AA, indicating that microencapsulation is a suitable strategy. Data from the acceptance questionnaire revealed that biscuits containing MPs loaded with absinthin-rich extract were comparable to the control ones regarding overall acceptance. In conclusion, a promising product was developed that effectively masks the bitterness of appetite-modulating bioactive compounds, with significant health-promoting potential. However, further investigation into the biological effects (e.g., hormonal responses, feelings of hunger, etc.) of these baked products is required. Full article

Different cultivation methods significantly affect wheat quality. However, the optimal cultivation pattern for strong-gluten wheat in Shandong province remains unclear. Through field experiments conducted over three consecutive wheat-growing seasons, wheat-quality-related traits under traditional cultivation practices (TC) and different cultivation patterns for Jimai44 (a strong-gluten wheat variety) were investigated. Plowing, delayed sowing date and increasing seeding rate could enhance grain protein content, SDS sedimentation value, wet and dry gluten content, and also had a clear positive effect on thousand-kernel weight and test weight. Employing a protocol of increased basal nitrogen (300 kg/ha) and topdressing water and fertilizer twice significantly increased wheat grain protein and nitrogen content, flour yield, gluten index, SDS sedimentation value, dough stability time, and extensibility. On the basis of the two wheat seasons experiments, we developed an optimized cultivation practice (Opt, that is, combined with plowing, delayed sowing date, seeding rate of 3.15 million or 3.60 million, basal nitrogen fertilizer application of 300 kg/ha, topdressing fertilizer twice, topdressing water twice or three times). Compared with TC treatment, the optimized cultivation demonstrated superior performance in grain protein content, flour yield, SDS sedimentation value, wet and dry gluten content, stability time, formation time, extension area, extension, and maximum retensibility with high grain yield. Meanwhile, we found that the expression of TaGlu1 was significantly increased under the optimized cultivation practice. In summary, the optimized cultivation practice might be a promising approach for improving strong-gluten wheat quality in the Huang-Huai-Hai Plain. Full article

Wheat possesses inherently low concentrations and bioavailability of the essential micronutrients (EMis) zinc (Zn), iron (Fe), manganese (Mn), and copper (Cu), limiting its capacity to sufficiently address human nutritional requirements. Biofortification of wheat with EMis through agricultural methods is a strategy aimed at addressing EMi deficiencies in human populations that emphasize cost-effectiveness and sustainability. All EMis are usually applied foliarly as sulfates, which indicates sulfur (S)-assisted biofortification. The formation of EMi complexes provides solubility as well as protection during long-distance transport. Several small molecules are possible candidates as ligands—the S-containing amino acids cysteine and methionine among them—linking EMi homeostasis to S homeostasis, which represents another aspect of S-assisted biofortification. In this study, we delve into the S-assisted agronomic biofortification strategy by applying sulfate micronutrients coupled with a sulfur-containing amino acid and we explore the effect of the selected accompanying cation (Zn, Fe, Mn, or Cu) on the EMi metallome of the grain, along with the biofortification effectiveness, whilst the type of the incorporated surface active agent seems to affect this approach. A field experiment was conducted for two years with durum wheat cultivation subjected to various interventions at the initiation of the dough stage, aiming to biofortify the grain with EMis provided as sulfate salts coupled with cysteine or methionine as potential biofortification enhancers. The mixtures were applied alone or in combination with commercial surfactants of the organosilicon ethoxylate (SiE) type or the alcohol ethoxylate (AE) type. The performance of two relevant preparations, FytoAmino-Bo (FABo) and Phillon, has been studied, too. The interventions affected the accumulation of the EMi metallome into the grains, along with the interactions of the EMis within this metallome. Several interventions increased the EMi metallome of the grain and affected the contribution of each EMi to this metallome. Many interventions have increased Zn and Fe, while they have decreased Mn and Cu. An increase in Zn corresponded (i) to a decrease in Cu, (ii) to an increase or no increase in Fe, and (iii) to a variable change in Mn. Cys increased the metallome by 34% and Zn and Fe within it. ZnSO₄ and FeSO₄ increased the metallome by 5% and 9%, whilst MnSO₄ and CuSO₄ increased the metallome by 36% and 33%, respectively. The additives improved the contribution to increasing the metallome in most cases. Without surfactant, the efficacy ranking proved to be MnSO₄ > CuSO₄ > ZnSO₄ > FeSO₄. The use of SW7 sustained the order CuSO₄ > MnSO₄ > ZnSO₄ > FeSO₄. The use of Saldo switched the order to CuSO₄ > ZnSO₄ > FeSO₄ > MnSO₄. In the case of Phillon, the order was CuSO₄ > FeSO₄ > ZnSO₄ > MnSO₄. The effect of Cys or Met was case-specific. The differentiations in the intensity of both the agronomic performance (grain weight, grain weight per spike, and yield) and the biofortification performance (concentrations vs. accumulations of each EMi within the grain) among the various combinations of EMis and additives are depicted by adopting a grading scale, which highlighted the intensity of the acclimation reaction of the biofortified grain to the applied intervention. Full article

Wheat (Triticum aestivum L.) is a major global staple crop, widely consumed in processed forms such as bread and pasta. As consumer demand for healthier food options increases, organic wheat production is gaining importance. However, organic farming excludes the use of synthetic pesticides and fungicides, potentially increasing the risk of fungal contamination and mycotoxin presence. At the same time, questions remain about whether organically grown wheat can match the grain quality needed for industrial processing, particularly in terms of protein content, gluten strength, and dough properties. This study aims to evaluate grain and flour quality parameters, as well as the occurrence of selected mycotoxins, in eight winter wheat cultivars grown under both organic and conventional farming systems in northern Serbia during the 2023/2024 season. Cultivars included modern premium varieties recommended for organic production, as well as one traditional and one conventional cultivar. Despite unfavourable weather conditions in the early stages of the vegetation in 2024, favourable conditions during grain ripening contributed to the good quality of organically produced varieties. The quality parameters of most varieties from organic production (PC > 17%, WG > 49%, WA > 62%) were significantly higher than the standard for organic wheat. NS Epoha stood out as the variety with the highest yield in organic production. As expected, varieties from the organic system had a higher incidence of mycotoxin contamination, but their concentrations were low. Full article

Lactiplantibacillus plantarum is a versatile lactic acid bacterium (LAB) with broad ecological and metabolic adaptability, contributing to both technological and probiotic functions. The prevalence and functional diversity of locally adapted L. plantarum strains in traditional sourdough fermentations remain poorly understood. This study aimed to characterize ten L. plantarum strains isolated from traditional Estonian rye sourdoughs, focusing on safety, enzymatic and carbohydrate metabolism, fermentation performance, exopolysaccharide (EPS) production, and genotype-associated functional diversity, including interaction with aflatoxin B₁ (AFB₁). Strains were γ-hemolytic and susceptible to major antibiotics. Strong aminopeptidase and β-glucosidase activities were observed, whereas α-glucosidase and α-galactosidase activities varied among strains and genotypes. Strains efficiently utilized mono- and disaccharides, with genotype-specific patterns for complex carbohydrates. During sourdough fermentation, all strains acidified the dough (pH < 4.5) and produced lactic and acetic acids in optimal ratios, while fermentation kinetics differed in a genotype-dependent manner. EPS yields (131–225 mg/L) were stable across genotypes. All strains retained fermentative activity in the presence of AFB₁ and exhibited high binding capacity (~100%). These findings demonstrate the safety, metabolic versatility, and genotype-structured functional diversity of L. plantarum from traditional Estonian rye sourdoughs, supporting their application as robust, multifunctional starter cultures for sustainable food fermentations. Full article

The role of HMW-GSs in soft wheat quality remains inadequately understood. In Chinese soft wheat variety Ningmai 9, a nonsense mutation (Glu-B1x, 1Bx7null) reduced dough tenacity while enhancing dough extensibility under both low (LN) and high nitrogen (HN) inputs. The improved extensibility in the NIL carrying 1Bx7null was primarily due to a reduced glutenin/gliadin ratio, with HN further increasing extensibility compared to LN. Notably, the NIL under HN exhibited better cookie quality than WT under LN without yield loss (p < 0.05). A CAPS marker was developed based on a C-to-T SNP at 514 bp in the CDS of 1Bx7null, reliably distinguishing 1Bx7 and 1Bx7null alleles. This allele-marker combination shows promising potential for soft wheat breeding. Future studies should explore the effects of allele 1Bx7null across diverse genetic backgrounds and soft wheat products. Full article

Chokeberry (Aronia melanocarpa L.) is a valuable raw material rich in health-promoting compounds, including anthocyanins, making it an excellent ingredient in food such as bread. In this research, water in the bread recipe was substituted with chokeberry extract (ChE). Dried chokeberry powder was used to obtain extracts with 0 and 7.5 °Brix content. Two types of water chokeberry extracts (0 and 7.5 °Brix ChE) were applied in the wheat bread recipe with doses of 10, 15, 20, and 30% (m/m), replacing water, respectively. The obtained chokeberry extract contributed to the enrichment of the bread in total polyphenol content and the antioxidant capacity. The control bread sample (i.e., without the extract) had a total polyphenol content (TPC) of 25.706 mgGAE/100 g, while the bread samples with the extract had TPC values ranging from 29.037 to 45.282 mgGAE/100 g. At the same time, adding chokeberry extract to the bread matrix contributed to increasing the antioxidant capacity. Bread with ChE was characterized by the same dough yield and loaf volume of bread compared to the control sample, but with changed oven loss, total baking loss, bread yield, specific volume, bread acidity and porosity of the crumb. However, there was no statistically significant effect on the chewiness and cohesiveness of the crumb in the sample texture (α = 0.05). A small effect of anthocyanins on the color of bread was observed, and sugars played the dominant role in the tested samples. Chokeberry in the form of an aqueous extract added to wheat bread can be an excellent ingredient in bread, fulfilling both a nutritional and technological function in the design of functional foods. Full article

Composite flours have been increasingly introduced in bakery products, aiming to enhance their nutritional value and reduce overdependence on imported wheat. Crackers are popular snack items, with potential to affect body weight and health status. This study aimed to examine the effects of different flour types, specifically pulses (chickpea, lupin, yellow split pea and cowpea), agricultural by-products (grape seeds and olive stones) and cereals (barley), on flour functionality, dough quality and final product characteristics compared with wheat flour (control) at various substitution levels. The functional properties of the composite flours were associated with the properties of dough and the characteristics of the crackers. Barley flour produced crackers with significantly higher hardness and lightness (L*) compared to the control, whereas chickpea flour had a similar but non-significant trend for both hardness and L* value. In contrast, high-level olive stone formulations yielded softer textures and the highest total color difference (ΔE), followed by grape seed crackers, which also exhibited high ΔE values and reduced hardness. The effects of composite flours on product texture were mediated by water absorption capacity and the compositional characteristics of the added flours. Crackers prepared with composite flours generally resulted in darker and diverse color profiles as well as low water activity and moisture values. Overall, the findings indicate that variations in composite flour type and substitution level influence product quality, allowing targeted modification of specific cracker attributes. Full article

Sea buckthorn (Hippophae rhamnoides L.) is a rich source of bioactive compounds, including vitamin C, polyphenols, carotenoids, and dietary fiber. In this study, sea buckthorn pomace, an underutilized by-product of oil processing, was incorporated into wheat bread at levels of 0, 3, 6, 9, and 12% (based on flour weight). The technological performance (dough yield, baking loss, loaf volume, texture, and color), nutritional composition (protein, fat, dietary fiber fractions, mineral content, and caloric value), and sensory attributes of the resulting breads were comprehensively evaluated. Pomace addition markedly increased the protein content of bread (from 13.5% to 16.8%) and more than doubled total dietary fiber (from 5.4% to 11.6%), while reducing caloric value by approximately 5.6%. Increasing pomace levels also affected dough behavior and bread structure: water absorption rose from 59.9% to 68.9%, specific loaf volume decreased by 11–28%, and crumb hardness increased from 3.8 N (control) to 12.4 N (12% addition). Sensory acceptability remained high up to 6% pomace incorporation (acceptability index > 90%), whereas breads containing 9–12% received significantly lower scores, mainly due to darker crumb color and intensified sour or bitter notes. Overall, sea buckthorn pomace can be effectively used as a nutritionally enriching, value-added ingredient in wheat bread, enhancing fiber and protein content while maintaining desirable technological and sensory properties at moderate substitution levels. Full article

Forage scarcity in semi-arid regions necessitates the identification of optimal sorghum cultivars for high-quality silage production. This study systematically evaluated varietal differences in agronomic characteristics, nutritive value, fermentation quality, and bacterial community structure of whole-plant sorghum silage. A completely randomized design was implemented with four sorghum cultivars representative of semi-arid northwestern China: Liaotian1 (LT1), Jinnuo3 (JN3), Jinza2001 (JZ2001), and Jinza1531 (JZ1531). Five quadrats per cultivar in experimental fields were randomly designated as biological replicates for silage production. The plants were harvested at the dough stage, chopped, and ensiled in laboratory-scale silos (n = 20, 4 cultivars × 5 replicates) for 120 days. Analyses included agronomic measurements, chemical composition, fermentation parameters, microbial plate enumeration, and bacterial community profiling via 16S rRNA gene amplicon sequencing of the V3–V4 hypervariable region. The results showed that cultivar significantly influenced (p < 0.01) all agronomic traits and most nutritional parameters. The forage-type cultivar LT1 showed the highest biomass yield but the lowest nutritional quality, with higher neutral detergent fiber (47.77% vs. 29.21–32.35%; p < 0.05) and lower starch (10.94% vs. 18.10–24.30%; p < 0.05) contents as well as higher dry matter losses (1.39% vs. 0.91–1.23%; p < 0.05) than grain-type cultivars. In contrast, the grain-type cultivar JN3 exhibited balanced yield-quality traits with the highest (p < 0.05) starch (24.30%) and crude protein (7.50%) contents. Most fermentation parameters differed significantly (p < 0.01) among cultivars, with JN3 showing elevated ammonia-nitrogen (0.24 g/kg) but within acceptable ranges. Microbial diversity analysis revealed cultivar-driven differences in bacterial communities, with JN3 enriched in Leuconostoc and early-colonizing taxa (p < 0.05 and LDA Score > 4). It is concluded that the grain-type cultivar JN3 is the most suitable cultivar for whole-plant sorghum silage production in water-limited regions due to its optimal yield-quality balance. The findings underscore the importance of integrated cultivar evaluation and suggest the potential of targeted microbial inoculants for enhancing silage quality. Full article