Search Results (109)

This study aims to investigate the possibility of using lentil flour in its native and germinated form as microgreen in bread-making technology, as well as how the fermentation process (with yeast or sourdough) influences the chemical, nutritional, antinutritional, physical and technological parameters of the bread. For this purpose, 14 bread samples were obtained using composite flours (wheat flour and black lentil flour) with the addition of 10, 20, and 30% lentil flour (LF) relative to wheat flour (WF), as well as composite flours (wheat flour and germinated lentil powder GL) in proportions of 2.5, 5, and 7%. Each flour sample was used in bread production using the direct fermentation method with yeast (yeast lentil bread BLY and yeast germinated lentil bread BGLY) and the indirect method with sourdough (sourdough lentil seed bread BLS and sourdough germinated lentil bread BGLS). Experimental results regarding nutritional composition showed a significant increase in protein content compared to the control (wheat flour bread), with the highest value recorded in the sample with 7.5% germinated lentil fermented with sourdough (29.18%), which also stood out for the highest total polyphenol content (1183.84 mg/100 g) and the lowest phytic acid content. Regarding the physical properties of the bread, an increase in elasticity, porosity, and height/diameter ratio was observed in the samples with an intermediate addition of lentil flour (20%) and germinated lentil flour (7.5%). The physical color parameters of the final product are also significantly influenced by the addition of black lentil flour, as well as germinated lentils. In conclusion, it can be stated that the use of lentil flour in its germinated form increases the nutritional and functional properties of bread, while the use of sourdough in the technological process leads to a decrease in the phytic acid content of the samples. Among the tested formulations, the addition of 20% lentil flour or 5% lentil germinated lentil resulted in the most favorable balance between bread elasticity, porosity, and H/D ratio. Full article

The aims of this study were to evaluate the impact of probiotics (added as a starter sourdough and microcapsules) on gluten-free (GF) rice–amaranth steamed bread (SB) regarding physicochemical characteristics, sensory attributes, probiotic viability, and volatile organic compounds (VOCs). Also, probiotic viability, pH, total titratable acidity (TTA), moisture content, water activity, and texture were determined for 10 days of storage. GF-SB based on rice and amaranth was formulated and cooked at 90 ± 2 °C for 40 min. Three types of GF-SB were studied: control, with 30% sourdough fermented using Lactiplantibacillus plantarum NRRL B-4496 (GF-P), and with sourdough and encapsulated Limosilactobacillus reuteri DSM 17938 (GF-PC). The encapsulation yield was 94.9%. The viability of both probiotics was drastically reduced after steamed cooking, with losses ranging from 6 to 8 log₁₀ CFU/g. Sourdough decreased the pH (from 6.04 to 5.48–5.71) and hardness (control 46 N, sourdough ~25 N) while increasing lactic and acetic acids, moisture content (control 38%, sourdough ~46%), and water activity. Sourdough and probiotic capsules did not affect volume (~1.24 cm³/g), width-to-height ratio (~2.4), color, or sensory attributes. The VOCs revealed higher relative abundances of certain yeast-derived higher alcohols and oxidation-related carbonyl-trapping derivatives in control GF-SB, whereas bread with sourdough showed higher levels of long-chain hydrocarbons and esters, such as heptacosane and decanoic acid decyl ester. During the storage, Lpb. plantarum increased to ~3 log₁₀ CFU/g and Lim. reuteri remained steady. pH and TTA (0.03–0.04%) remained constant during storage. After 10 days of storage, hardness increased significantly (p < 0.05) in all GF-SB, doubling the initial values. Moisture content remained constant, while water activity decreased in GF-P (Δ = 0.025) and the control (Δ = 0.015). The use of sourdough in GF-SB improved texture, moisture content, and VOCs without modifying physical and sensory properties. Full article

The use of Pleurotus ostreatus lyophilizate (POL) and hot water extract (POE) as potential functional ingredients for the development of enriched bread was investigated. The effects of POL and POE were examined based on the results of empirical rheological measurements and physical, textural and sensory analysis of bread. POL was incorporated into dough as a partial substitute for wheat flour (1% and 5%), while POE was added as a replacement for part of the water required to achieve optimal dough consistency (2% and 10%). Inclusion of POL in dough formulation caused dough disintegration: extreme decrease in degree of softening, from 60 FU (control) to 275 FU (POL1) and 290 FU (POL5), and extensographic measurements could not be performed. The specific volume of bread with 10% POL decreased by 46% and the crumb hardness increased approximately four times compared to the control. On the other hand, rheological properties of dough with POE were comparable to control, resulting in minimal impact on physical, textural and sensory characteristics of bread. Both fortifying ingredients positively affected the total phenolic content and antioxidant activity of the bread, with a more pronounced effect observed for POL compared to POE. Additionally, bread enriched with 5% POL had total dietary fiber content of 4.7 g/100 g and could be labeled as a source of fiber. P. ostreatus derivatives show great potential for functional bread development; however, further research is needed to optimize their use and maintain bread quality. Full article

In recent years, pulse flours have gained attention in baked goods for their nutritional value. This study evaluated the effects of incorporating common bean, yellow pea, and grass pea flours (20%, 30%, 40%) into durum wheat semolina on the technological, physical, and rheological properties of flours, doughs, and breads. Combining pulse flours with durum wheat semolina allows for improved dough handling and processing performance, leveraging the functional properties of both ingredients. Water absorption increased with pulse flour addition (average 1.90 g H₂O/g dry matter), though higher levels of yellow pea and grass pea reduced it. Color changes were most evident with common bean flour. Leavening rates varied, reaching 144% after 60 min with 30% yellow pea and 68.75% after 40 min with 30% common bean. Rheological results indicated longer dough development and stability times but reduced strength and extensibility, with higher tenacity. Bread volume decreased from 276.25 cm³ (control) to 208.75 cm³ (40% common bean). Crumb porosity declined, particularly with common bean flour, producing smaller pores. Grass pea flour promoted browning, enhancing color contrast. Texture analysis showed harder, more gum-like breads with higher chew resistance: hardness ranged from 15.85 N (20% common bean) to 30.45 N (40% yellow pea). Gumminess and chewiness increased, while cohesiveness decreased. Overall, pulse flour integration alters bread quality, yet represents a promising approach to creating healthier, functional, baked products. Full article

The replacement of synthetic preservatives with natural alternatives is increasingly important in bakery production. This study examined the antifungal activity of thyme essential oil (TEO) against bread spoilage molds and its impact on product quality and consumer acceptance. TEO was tested at concentrations from 0 to 200 ppm against Aspergillus flavus and Penicillium expansum in bread and a model system, with mold responses modeled using the Gompertz equation. Because TEO affects the sensory qualities of bread, the kinetic parameters of mold growth were used to estimate the minimum inhibitory concentration (MIC), thereby ensuring a mold-free shelf life without significantly altering sensory properties. Bread samples were analyzed for pH, moisture, water activity, texture, specific volume, and sensory attributes (odor, flavor, texture, and acceptability). Residual thymol and carvacrol (measured using GC-MS) were also evaluated. The retention of thymol and carvacrol in baked bread was 75–80%. The tested TEO concentrations did not alter the moisture content, pH, or water activity of bread, while the specific volume was reduced and the width-to-height ratio increased as the TEO concentration increased. At concentrations below 100 ppm, TEO enhanced bread softness, while higher levels (>150 ppm) slightly increased hardness. Sensory testing showed no significant differences in color or texture (p > 0.05). At 50 ppm, TEO imparted a subtle thyme aroma and flavor, improving the sensory profile. At 100 and 150 ppm, the aroma and flavor became more pronounced and were well accepted. However, at 200 ppm, the thyme aroma and flavor decreased overall acceptance. In bread, the MIC of TEO for A. flavus ranges from 104.2 ppm (200 h delay) to 120.8 ppm (250 h), and for P. expansum, from 106.6 ppm (200 h) to 123.6 ppm (250 h). The MICs (100–125 ppm) fall within sensory acceptable scores, indicating that TEO can delay mold growth while maintaining bread quality. Moderate levels of TEO extended the mold-free shelf life of bread by providing microbial control and preserving its sensory properties. Full article

Enriching bread with functional ingredients is a promising strategy to enhance the nutritional and bioactive profile of widely consumed foods. This study evaluated partial substitution of wheat flour (WF) with chestnut flour (CF) and rosehip powder (RP) on bread nutritional quality, functionality, and rheology. Five bread formulations were developed by replacing WF with CF at 0%, 5%, 10%, 15%, and 20%. Four other formulations were prepared by replacing WF in the 15% CF sample with RP at 0.5%, 1%, 2%, and 3%. Proximate composition, total phenolic content (TPC), total flavonoid content (TFC), antioxidant activity (DPPH and FRAP), and key physical characteristics were assessed, alongside the retention rates of functional attributes after baking. Rheological behavior of composite flours was analyzed using the MIXOLAB system to evaluate dough performance. Results showed that moderate WF substitution with CF (5–15%) increased dietary fiber and antioxidant activity while maintaining acceptable dough rheology and bread quality. At 20% CF substitution, TPC, TFC, FRAP, and DPPH increased 1.62-, 1.63-, 2.93-, and 3.03-fold versus control, with 59–66% retention. Addition of RP up to 3% to the 15% CF-substituted sample further enhanced bioactive properties, with TPC, TFC, FRAP, and DPPH reaching 2.13-, 2.03-, 4.49-, and 3.99-fold vs. BCF15, while retaining 61–67% of their functionality. Further inclusion of RP up to 2% in the 15% CF formulation maintains acceptable dough and bread performance, while 3% RP maximizes phytochemical enrichment but slightly affects technological properties. The combination of 15% CF and 2% RP provided a balanced enhancement in bioactive content and technological performance, offering a practical approach for producing functional bread with improved nutritional and technological attributes. Full article

The need to diversify food products on the market, the interest of producer-farmers and food processors in nutritionally healthy raw materials, and especially the demand among consumers for new, high-quality product assortments have led to the introduction of ancient wheat species into cultivation. Ancient plant species are often grown using environmentally friendly agricultural technologies. The aim of the study was to compare the technological parameters, rheological properties of dough, and baking indicators of grains (and the flour milled from them) from ancient wheat species T. sphaerococcum and T. persicum with common wheat. These were cultivated using both traditional ploughing and simplified shallow tillage systems. The wheat grain was obtained from field experiments located in three certified organic farms in Poland. In the plant material samples, physical, technological and rheological parameters were determined. The grain, flour, baked bread, and the colour of grain and flour were characterised. It was found that the tested cultivation systems did not have a significant effect on the analysed traits (except for dough parameters: dough stability time, dough softening, and bread weight after removal from the oven and 24 h after baking where shallow tillage turned out to be more advantageous). In turn, the wheat species significantly influenced the tested traits. This factor was found to determine relatively high (higher than common wheat) values of protein complex and water absorption characteristics in ancient wheat flour (T. persicum: TPC/TPCF—156/150 g·kg⁻¹, WG/WGF—39.4/34.5%, WA—62.9%; T. sphaerococcum: TPC/TPCF—145/142 g·kg⁻¹, WG/WGF—38.5/33.3%, WA—58.2%). The obtained results for the technological and rheological properties of the grain and flour indicate that ancient wheat species, particularly T. persicum, can be a potential raw material for the production of healthy food, including bread baking. Full article

This paper aims to study the potential of whey, a by-product in the dairy industry, to be used as a sustainable and health-promoting ingredient in baking. In this regard, whey powder (WhF) was produced and incorporated into three composite flours consisting of wheat flour and whey powder in proportions of 5% (WhWF5), 10% (WhWF10), and 15% (WhWF15). These composite flours were then used to produce bread. The nutritional properties (proximate composition, macro and microelement content) and bioactive compounds (total polyphenols and antioxidant activity) were assessed for both the composite flours and the resulting breads. In addition, the rheological behavior of the dough was evaluated using the Mixolab system, while the microstructural characteristics and physical properties of the composite flours were analyzed using Small/Wide Angle X-ray Scattering (SAXS/WAXS) and Fourier Transform Infrared Spectroscopy (FTIR). Sensory evaluation of the breads was also performed. The results demonstrated a positive effect of the whey powder addition on the nutritional profile of both composite flours and bakery products, particularly through increased protein levels (25.24–37.77% in fortified flours vs. 11.26% in control; 16.64–18.89% in fortified breads vs. 14.12% in control) and enhanced mineral content (11.27–80.45% higher compared to white wheat bread), alongside a reduction in carbohydrate content. Bread fortified with 15% whey powder showed higher monolement with increases of 27.80% for K, 7.01% for Mg, and 28.67% for Ca compared to control bread without whey. The analysis of the Mixolab charts confirmed the progressive influence of whey powder on dough rheology. While water absorption remains high, other functional parameters, such as gluten quality, kneading capacity, and starch viscosity, were negatively affected. Nonetheless, the nutritional advantages and reduced retrogradation tendency may offset these drawbacks in the context of developing functional bakery products. Formulations containing 5–10% whey powder appear to offer an optimal balance between technological performance, nutritional quality, and sensory acceptance. Full article

The increasing interest in fibre-enriched and functional bakery products has led to the exploration of novel plant-based ingredients with both technological functionality and consumer acceptance. This study evaluates the effects of incorporating flours derived from apple (Malus domestica cv. Oberländer Himbeerapfel), sweet chestnut (Castanea sativa), horse chestnut (Aesculus hippocastanum), and red, sessile, and pedunculate oak (Quercus rubra, Q. petraea, and Q. robur) into wheat bread at 5%, 10%, and 15% substitution levels. The impact on crumb structure, crust colour, textural parameters (hardness, adhesiveness, springiness), and sensory attributes was assessed. The inclusion of apple and sweet chestnut flours resulted in a softer crumb, lower adhesiveness, and higher sensory scores related to flavour, aroma, and crust appearance. In contrast, higher levels of oak- and horse-chestnut-derived flours increased crumb hardness and reduced overall acceptability due to bitterness or excessive density. Apple flour preserved crumb brightness and contributed to warm tones, while oak flours caused more intense crust darkening. These findings suggest that selected non-traditional flours, especially apple and sweet chestnut, can enhance the sensory and physical properties of wheat bread, supporting the development of fibre-rich, clean-label formulations aligned with consumer trends in sustainable and functional baking. Full article

The increasing demand for diverse foods and tailored nutrition encourages the development of innovative products, such as bread enriched with cricket powder (CP) or potato protein (PP). This study presents the preparation and analysis of gluten-free breads with CP and PP, focusing on their nutritional value and physical properties. Analytical methods included water activity measurement, bread volume, crumb color analysis, FTIR spectroscopy, low-field NMR relaxometry, and texture profile analysis. Ash content ranged from 0.60 ± 0.03% to 1.16 ± 0.11%, and caloric values ranged from 216.2 to 229.5 kcal/100 g. Water activity remained stable across all samples (0.975–0.976). Crumb color analysis showed the greatest change in CP samples (ΔE = 14.07), while PP had minimal impact (ΔE = 2.15). FTIR spectra revealed increased amide I and II bands, indicating higher protein content. NMR results demonstrated shorter T₁, T₂₁, and T₂₂ times for CP, suggesting reduced water mobility and a denser structure, while PP samples showed higher values, indicating a looser, more hydrated matrix. Texture analysis confirmed that CP increased firmness and compactness, whereas PP enhanced springiness. These findings suggest that CP and PP can improve the nutritional and structural properties of gluten-free bread, offering valuable alternatives for modern dietary needs. Full article

Gluten-free flour blends, consisting of quinoa and sorghum flours, were used in the present study to prepare sourdough samples, which were characterized in terms of physical–chemical properties, the thermo-mechanical behavior of dough and bread making performance. The quinoa–sorghum flour blends (100:0, 75:25, 50:50) were fermented using two different starter cultures, consisting of Lacticaseibacillus rhamnosus, Levilactobacillus brevis and Lactiplantibacillus plantarum (SC1), and Lactobacillus acidophilus, Bifidobacterium lactis and Streptococcus thermophilus (SC2). After 20 h of fermentation at 30 °C, the acidity of the sourdoughs prepared with SC1 and SC2 was significantly higher in respect to the corresponding spontaneously fermented sample. The use of the starter culture for sourdough fermentation resulted in sourdoughs with higher glycerol and lactic acid contents, and lower ethanol and acetic acid. The empirical rheological measurements indicated that the behavior of the proteins and starch within the complex dough matrix, during mixing and heating, is influenced by both sorghum level and starter culture type. The use of the sourdough allowed the preparation of gluten-free breads with good texture and high contents of bioactive compounds. In conclusion, sourdough fermentation can be successfully used for boosting the quality of the gluten-free bread products. Full article

The utilization of food industry by-products represents a significant opportunity for developing functional foods. This study investigated the incorporation of Cucurbita maxima Plomo peel powder (PS) into wheat bread formulations to assess its potential as a valuable ingredient for bread-making. PS was incorporated into wheat flour at 1%, 10%, and 20% levels. The dough’s rheological properties were analyzed using Mixolab. Bread samples were evaluated for physical characteristics (volume, texture, colour), antioxidant properties (DPPH, ABTS, FRAP), and reducing sugar content. Analyses were performed on day 0 and after 7 days of storage. PS incorporation significantly modified dough rheology, with increased development time and enhanced protein stability. Bread volume decreased progressively with PS addition (from 195.5 cm³ to 109.8 cm³ at 20% PS). However, antioxidant activity increased substantially, particularly in the crust, with ABTS values rising from 2.37 to 10.08 TE μM/g DM in water extracts. Total phenolic content and reducing sugars showed significant increases across all PS concentrations. Storage studies revealed stable antioxidant properties but progressive textural changes, with hardness increasing from 6.83 N to 108.8 N at 20% PS after 7 days. While PS incorporation affects bread’s physical properties, the significant enhancement in antioxidant activity and phenolic content suggests its potential as a functional ingredient. The optimal incorporation level should balance technological properties with nutritional benefits. Full article

The effects of different modified soybean residues’ dietary fiber on the physicochemical properties of wheat dough and the quality of steamed bread were systematically analyzed in this study. The physical and chemical parameters of dough, such as texture characteristics, water distribution, secondary structure, and the specific volume, color, and sensory evaluation results of steamed bread products were analyzed in detail. The results showed that adding 6% modified soybean residue dietary fiber enhanced the gluten network, increasing the S–S bond content and improving gluten stability. Notably, the inclusion of 6% residue modified by the ultrasound combined with enzyme method (UEDF) led to a 2.55% increase in the β-fold content of gluten proteins and a 3.60% rise in disulfide bond content. These changes resulted in a reduction in dough relaxation time, promoting a more uniform and compact pore structure in the dough. Additionally, steamed bread made with 6% UEDF showed a 0.3 mL/g increase in specific volume, a 4.69 point rise in L* value, and improved sensory attributes such as taste, odor, and appearance. These research results provide valuable insights and guidance for the development of soybean residue dietary fiber foods. Full article

This study investigated the effects of tiger nut flour (TNF) incorporation (5–25%) on wheat-based bread characteristics. Dough rheology analysis revealed optimal gas retention at 10% TNF addition, while higher concentrations decreased dough stability. Physical analysis demonstrated that 10% TNF substitution yielded the highest specific volume (2.4 mL/g) and porosity (67.0%), with significant textural changes observed at higher concentrations. Bioactive compound analysis showed progressive increases in the total polyphenol content and antioxidant activity with increasing TNF levels, particularly in 25% TNF bread (111.31 mg TE/g dm in crumb). Storage studies over 7 days indicated that TNF incorporation affected bread staling characteristics, with 10–15% substitution levels maintaining better textural properties. The results suggest that TNF incorporation up to 15% can enhance bread’s nutritional value, while maintaining acceptable technological properties, with 10% substitution showing an optimal balance between functional benefits and bread quality. Full article

The growing global population has led to increased food consumption and a significant amount of food waste, including the non-consumed parts of fruits (e.g., stems, rinds, peels, seeds). Despite their nutrient richness, these by-products are often discarded. With the rising interest in nutrient-dense foods for health benefits, fruit by-products have potential as nutritious ingredients. Upcycling, which repurposes waste materials, is one solution. White flour, which is common in food products like bread and pasta, has good functional properties but poor nutritional value. This can be enhanced by blending white flour with fruit by-product flours, creating functional, nutrient-rich mixtures. This review explores using flours from common Brazilian fruit by-products (e.g., jaboticaba, avocado, guava, mango, banana, jackfruit, orange, pineapple, and passion fruit) and their nutritional, physical–chemical properties, quality and safety, and applications. Partially replacing wheat flour with fruit flour improves its nutritional value, increasing the amount of fiber, protein, and carbohydrates present in it. However, higher substitution levels can alter color and flavor, impacting the sensory appeal and acceptability. While studies showed the potential of fruit by-product flours in food formulation, there is limited research on their long-term health impacts. Full article