Search Results (545)

This study investigated the combined influence of hydrothermal treatment and particle size on the techno-functional properties of defatted coconut residue (DCR) to optimize its use as a hydrocolloid fat replacer. A 3 × 2 factorial design evaluated boiling and autoclaving treatments in combination with coarse and fine milling. Fine particle fractions (boiling-fine [BF] and autoclaved-fine [AF]) were identified as optimal, exhibiting peak water-holding capacity (WHC) (10.95 g/g) and oil-holding capacity (4.57 g/g) due to maximized surface area and thermal unblocking of capillary networks. When incorporated into cookies, all DCR formulations qualified as “reduced-fat” (30% reduction) and “high-fiber” (6 g/100 g) products. Crucially, the extreme WHC of fine fractions induced severe water competition within the dough, leading to a direct inverse correlation with quality, characterized by a restricted spread ratio (6.9) and increased hardness (27 N). Furthermore, thermal leaching of Maillard precursors suppressed excessive browning, improving cookie color. While the BF fraction provided the best functional balance, future research should optimize dough moisture to mitigate the impact of high fiber hydration on texture. These findings demonstrate DCR’s potential for agro-food valorization and improved human health. 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

This study investigated the technological, nutritional, and sensory effects of incorporating soybean flour and radish leaves into steamed manti, with emphasis on moisture-loss kinetics, protein denaturation, true retention (TR), and relative nutrient density (RND). Four formulations were examined: potato control (PC), potato + soy (PS), greens control (GC), and greens + soy (GS). Steaming induced compositional increases in dry matter, ash, protein, and fat due to moisture reduction rather than absolute changes in solids. Greens-based formulations exhibited significantly lower moisture-loss and protein-denaturation rate constants, indicating stronger hydration stability and structural resistance during thermal processing. These kinetic advantages translated into higher TR values for protein and fat in GC and GS compared with potato-based samples. Soy flour substantially increased protein and lipid content and improved dough cohesiveness but did not influence thermal behavior or moisture-loss kinetics within the same matrix. When nutrient delivery was normalized to energy content, soy- and greens-enriched manti showed the highest RND values, reflecting a favorable combination of nutrient retention and lower caloric density. Sensory evaluation confirmed that soy enhanced textural attributes, while radish leaves contributed desirable juiciness and aroma. Overall, the combined use of radish leaves and soybean flour offers a sustainable approach to producing nutrient-dense, sensory-acceptable traditional foods while supporting the valorisation of leafy by-products. Full article

This study investigates a mechanically aerated, yeast-free bread technology incorporating apple-derived plant ingredients (juice, purée, and powder) in response to the growing demand for clean-label bakery products. The global bakery sector represents one of the largest food markets worldwide, with the baking yeast segment alone accounting for several billion USD annually, while interest in yeast-free and yeastless-dough products continues to expand. To address technological limitations associated with yeast exclusion, dough aeration was achieved using a two-stage whipping protocol (1000 rpm for 4 min, followed by 500 rpm for 1 min and stabilization at 500 rpm for 1 min under 4.0 ± 0.1 MPa gauge pressure), forming a stable protein–carbohydrate foam system. Rheological evaluation using Mixolab 2 showed that formulations containing 3–5% apple purée exhibited the most favorable dough development characteristics, with stability increasing from 3.30 ± 0.15 min in the control to 8.90 ± 0.20 min. Texture profiling using a CT-2 analyzer equipped with a cylindrical probe (50% compression, 60 mm/min, slices 25 mm thick, n = 5) revealed a significant reduction in crumb firmness, from 3.01 ± 0.15 N in the control to 2.12 ± 0.10 N in the purée- and powder-enriched samples (p < 0.05). Nutritional assessment indicated improvements in vitamin C content (up to 2.23 mg/100 g) and protein quality: the amino acid score, calculated according to FAO/WHO reference patterns on a mg/g-protein basis, increased from 76.5 ± 1.8% to 89.2 ± 2.3%. Microbiological analysis showed reduced total aerobic mesophilic counts after 72 h of storage—4.7 × 10³ CFU/g in the control versus 1.8–3.4 × 10³ CFU/g in apple-enriched breads. Overall, the results demonstrate that mechanical aeration combined with apple-derived ingredients enhances the structural, nutritional, and microbiological quality of yeast-free bread, offering a promising clean-label approach for functional bakery products. 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

Bread typically exhibits a high glycemic index (GI), motivating interest in plant-based ingredients that can modulate starch digestibility while enhancing nutritional value. This study evaluated the technological, compositional, and digestibility effects of incorporating leaf flours from Cnidoscolus aconitifolius and Crotalaria longirostrata into wheat bread. Both flours increased protein, dietary fiber, and phenolic content, while modifying dough performance and crumb structure. C. longirostrata produced the strongest reduction in predicted glycemic index (pGI), decreasing values by 5.2% on Day 0 and up to 17.8% by Day 5, associated with the highest accumulation of resistant starch. However, this nutritional advantage was accompanied by marked technological drawbacks, including reduced loaf volume and denser crumb. In contrast, C. aconitifolius exhibited better technological compatibility, generating breads with higher volume and more cohesive crumb structure, while still achieving meaningful pGI reductions (6.1% on Day 0 and 9.6% by Day 5). Firmness evolution during storage reflected staling-related structural changes but did not involve direct measurement of starch retrogradation. Overall, this work highlights the functional potential of whole leaf flours to enhance the nutritional profile and glycemic behavior of bread, while underscoring the formulation-dependent trade-offs that influence technological quality. These findings provide a foundation for developing optimized, lower-glycemic baked products using underutilized botanical ingredients. Full article

Bioprocessing grape pomace (GP) presents a sustainable solution aligned with circular economic principles and transforms it into valuable functional ingredients for baked products. This review (2020–2025) synthesizes enzymatic and microbial strategies that modify the fiber–phenolic matrix and improve dough performance. Enzyme-assisted extraction, alone or combined with ultrasound or pressurized liquids, increases extractable polyphenols and antioxidant capacity in GP fractions used as flour substitutions or pre-ferments. Fungal solid-state and lactic fermentations liberate bound phenolic compounds and generate acids and exopolysaccharides. Among these routes, enzyme-assisted extraction and lactic sourdough-type fermentations currently appear the most compatible with bakery-scale implementation, offering substantial phenolic enrichment while relying on relatively simple, food-grade equipment. In current bakery applications, GP is mainly used as crude grape pomace powder, which typically shows higher total phenolics and antioxidant capacity. Moreover, in several models it lowers starch hydrolysis and predicted glycemic index. The practical substitution rate is between 5 and 10% of flour, which balances nutritional gains with processing disadvantages. These can be mitigated by fractionation toward soluble dietary fiber or co-fortification with flours rich in protein and fiber. An additional benefit of these methods includes reduced mycotoxin bioaccessibility in vitro. A key evidence gap is the absence of standardized comparisons between raw and bioprocessed GP in identical formulations. Overall, GP emerges as a promising ingredient for bakery products, while the added technological and nutritional value of bioprocessing remains to be quantified. 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

The study explores the impact of incorporating Polygonatum cyrtonema flour (PCF) into wheat flour on dough functionality and steamed bread quality. The results show that PCF enhanced dough hydration, rheology, and protein network stability through hydrophilic and non-covalent interactions, particularly hydrogen bonding. At the optimal level, steamed bread demonstrates improved specific volume, elasticity, and cohesiveness, accompanied by reduced hardness and chewiness, with hardness decreasing by 29%, chewiness by 25.80%, and gumminess by 26.30%. Microstructural analyses have confirmed enhanced water retention, strengthened gluten matrices, and favorable secondary structure transitions. The ultraviolet visible absorption spectroscopy and fluorescence spectroscopy analyses revealed that PCF enhanced the interactions between proteins and starch, accompanied by a red shift and decreased fluorescence intensity, indicating a more compact protein conformation. These findings suggest that PCF regulates protein secondary structures through hydrogen bonding and hydrophobic interactions, thereby stabilizing the gluten network. PCF supplementation boosted antioxidant activity and modulates starch digestibility; at a 10% substitution level, resistant starch (RS) decreases from approximately 60% in the control to 34%. This reduction indicates that PCF disrupts the integrity of the starch protein matrix, increasing amylase accessibility to starch granules and thus promoting starch hydrolysis. Incorporating 4% PCF in the formulation enhances both the technological performance and nutritional quality of the product while maintaining its overall integrity. These findings highlight the dual role of PCF in improving technological functionality and nutritional attributes. PCF emerges as a promising natural fortification ingredient for steamed bread, offering quality enhancement and additional health value. Full article

The influence of different lipid blends on the physicochemical, nutritional, and sensory characteristics of short dough biscuits was investigated in comparison with a conventional formulation containing palm oil. Six different lipid matrices were employed: palm oil, butter, high-oleic sunflower oil, butter/extra virgin olive oil, butter/high-oleic sunflower oil, and a coconut/sunflower oil mixture. Biscuits were analyzed for fatty acid composition, sterols, tocols, oxidative stability, texture, and sensory attributes. The results showed a variability in the lipid composition. In particular, formulations containing high-oleic sunflower oil and its blends exhibited higher monounsaturated fatty acids and α-tocopherol, while coconut-based samples displayed greater saturated fatty acids and an improved oxidative stability. Butter-containing biscuits had the highest sterol concentration, mainly cholesterol. Textural and sensory evaluations revealed how the lipid fraction significantly affected crispiness, friability, and flavour perception. Biscuits formulated with high-oleic sunflower oil or butter achieved desirable structural and sensory properties, while the coconut/sunflower oil sample obtained the highest overall acceptability. The findings demonstrate that replacing palm oil with selected lipid blends can produce biscuits with an improved lipid quality and oxidative stability and satisfactory sensory performance, contributing to healthier and more sustainable bakery products. Full article

The current study aimed to fortify fresh pasta with red onion peels in the form of powder (OPP). For this aim, three concentrations were used (3%, 6%, and 9% w/w) and properly added to the dough. A control sample was also prepared for comparison (CTRL). Raw and cooked pasta samples were assessed for sensory acceptability and technological properties. Fibre content, total polyphenols, and antioxidant activity (by ABTS and FRAP) were assessed in raw materials and pasta samples. The glycaemic index was also predicted. Results from sensory evaluation and technological analyses demonstrated that with increasing OPP, some defects were perceived to provoke a complete unacceptance with the highest fortification level (9% score < 5). However, these effects were counterbalanced by a significant functional quality increase in fibre content, total polyphenols, and antioxidant activity, justified by the presence of the new onion-based ingredient. Therefore, to better balance benefits and drawbacks of onion peel recycling, a global quality index (GQI) was calculated, which accounted for nutritional improvements and sensory worsening. The most interesting GQI values were found for both 3% and 6% levels of fortification (52.58 vs. 51.86). Considering that these values are very comparable, the 6% can be considered the optimal concentration because it represents the highest concentration to give a fortified and sensorially friendly product. Full article

This study evaluated the application of Pediococcus acidilactici ORE 5 (applied in free or immobilized form in a prebiotic matrix called “trahanas”) in sourdough bread production. Specific volumes of all the produced bread samples varied at approximately the same levels (2.50 to 2.54 mL/g), indicating a satisfactory dough expansion. In contrast, acidity differed significantly (p < 0.05). Sourdough bread produced with immobilized cells (IB) exhibited the lowest pH (4.30) and the highest titratable acidity (9.13 mL NaOH N/10), followed by the sourdough bread produced with free cells (FB) and the control bread (CB), reflecting the enhanced metabolic activity of immobilized cells supported by the prebiotic matrix. The organic acid analysis revealed higher levels of lactic (2.96 g/kg) and acetic acid (0.99 g/kg) in the IB sample, along with increased minor acids. The high organic acid content contributed to a delayed rope (14.7 days) and mold spoilage (7.3 days) compared to the CB sample, enhancing microbial stability. In addition, the nutritional properties of the produced sourdough breads containing P. acidilactici ORE 5 were improved significantly. The IB sample demonstrated the highest total phenolic content (85 mg GAE/100 g), followed by the FB sample (61 mg/100 g) and the CB sample (48 mg/100 g), while phytic acid levels were markedly reduced (93% in IB and 80% in FB). A sensory evaluation confirmed the maintained overall acceptability, with enhanced flavor scores for sourdough breads containing P. acidilactici ORE 5. These findings indicate that P. acidilactici ORE 5, particularly in immobilized form, could be an effective functional starter culture for sourdough bread, highlighting its potential for applications in functional bakery products. 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