Search Results (232)

The growing demand for gluten-free bakery products requires the development of formulations that overcome their typical technological and nutritional limitations. Using fruit by-products as natural fiber sources, in combination with xanthan gum (XG), supports a sustainable ingredient strategy that improves gluten-free product quality. This study investigated the effect of apple pomace (AP) (5% and 10%) and XG (1%) on the technological properties, texture profile, nutritional composition, and sensory acceptance of gluten-free muffins. Six formulations were prepared by partially replacing maize flour with AP and/or adding XG. AP (5–10%) reduced muffin height and volume compared with the control, whereas 1% XG increased muffin height by 11.16% and raised volume and specific volume by 38.46% and 36.11%, respectively. XG significantly decreased hardness compared with the control, while the effect of AP on texture was concentration-dependent: 5% AP reduced hardness, whereas 10% AP did not further improve softness. Combined use of AP and XG resulted in complementary effects, improving structural properties while increasing dietary fiber content. The muffins supplemented with AP were acceptable, and their overall acceptability did not differ significantly among the tested formulations. Overall, the results demonstrate that incorporating AP together with XG enhances both the technological and nutritional quality of gluten-free muffins, supporting the valorization of fruit-processing by-products in functional bakery applications. Full article

In response to growing consumer interest in plant-based and eco-friendly diets, the food industry is seeking to enrich bakery products with functional plant proteins, which are highly nutritious and environmentally beneficial. This study aimed to evaluate the effect of incorporating pea protein isolate (PPI) and rice protein isolate (RPI) at levels of 5% and 15% on the structural and sensory quality and nutritional properties of vegan cookies. The addition of plant-derived proteins significantly influenced the colour and texture of the cookies. The addition of PPI increased lightness (L* up to 70.05 at 5%), whereas the addition of RPI caused pronounced browning (BI = 100.00 at 15%) and structural hardening at higher inclusion levels. Protein content increased with enrichment, reaching 9.49 g/100 g in the P15% sample (a 95.7% increase compared to the control sample). Total phenolic content increased markedly, particularly in the P15% sample, rising by 144%. However, this was not accompanied by a proportional increase in antioxidant activity, as determined by ABTS and DPPH assays. Sensory evaluation revealed that cookies enriched with 5% protein maintained high consumer acceptability (overall scores > 7.0), whereas higher levels of protein incorporation led to a significant reduction in sensory quality. The results indicate a trade-off between nutritional enhancement and sensory acceptability in vegan cookies enriched with pea and rice protein isolates, with 5% incorporation providing the most balanced outcome within the studied formulations. 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

Traditional shelf-life (SL) determination in bakery products relies primarily on subjective sensory evaluation, limiting both predictive capability and technological transfer. This study aimed to develop an objective, data-driven framework by integrating statistical and Machine Learning (ML) methods to identify and quantify the core determinants of bread SL. Samples were produced under a 2 × 2 × 2 factorial design (Fermentation, Temperature, Packaging), with continuous monitoring of physicochemical and atmospheric parameters. Three-way ANOVA confirmed that Storage x Temperature (η² ÷ 0.41) and Modified Atmosphere Packaging (η² ÷ 0.36) were the dominant factors. The optimal synergy (4 °C + ATM) achieved a 100% Success Rate, extending SL to 54 days vs. 16 days under ambient conditions. For prediction, a Generalized Linear Model (GLM) was developed for binary classification and rigorously validated via 10-fold cross-validation. The GLM achieved an Overall Accuracy of 89% (AUC 92%), uniquely identifying pH and Total Titratable Acidity (TTA) as the most influential predictors. In conclusion, GLM provides a robust tool for objective SL prediction. The integrated ANOVA–GLM framework achieved a 3.3-fold SL extension and 92% predictive accuracy. The findings confirm that preservative effectiveness is not solely due to the process itself, but is mediated by the resulting chemical acidity, offering a scalable framework for Real-Time Quality Control (QC) in the food industry. Full article

Peach palm (Bactris gasipaes) is an underutilized Amazonian crop with emerging relevance for plant-based food systems. Global demand for plant-based products continues to expand, reaching USD 28.38 billion in 2024, yet current formulations rely on a narrow set of ingredients with limitations in nutritional quality, functionality, sustainability, and supply-chain resilience. This review synthesizes quantitative evidence on the nutritional composition (carbohydrates 30–72% dm, protein 2–8% dm, lipids 2–14% dm), fatty acid profile, mineral density, and bioactive compounds (carotenoids up to 800 µg/g dm; phenolics 60–90 mg GAE/100 g dm) of peach palm fruit. Techno-functional properties relevant for plant-based applications, such as emulsification, water-binding, and structural contributions in bakery products and meat analogues, are critically examined, along with the effects of processing on nutrient retention and antinutrient reduction. The review also evaluates sustainability attributes and identifies key limitations, including regional cultivation, sensory constraints, and economic and technological barriers. By integrating nutritional, technological, and ecological perspectives, this work highlights the potential of peach palm as a diversified ingredient source and outlines research gaps necessary for future industrial adoption. Full article

The functional characteristics of Partial acylglycerols (PAGs) have attracted the attention of researchers in designing PAGs for food applications as a potential substitute for conventional fats/oils. Designing PA using enzymes has been of great interest due to the greater specificity of enzymes, giving high-quality products for food applications. The utilization of PA in fat-based products, such as bakery, dairy, and emulsion foods, exhibits superior functionalities and health-friendly characteristics. The PA can also be used for cooking/frying applications. However, exposure of PA to a higher temperature for a longer time shows inferior characteristics. The functional characteristics of PA, such as solid fat content, rheology, microstructure, crystal formation, and thermal behavior, make it a potential replacement for conventional fat. The present review focuses on a comparative assessment of synthetic routes, the functional characteristics of PA, food applications, and technological drawbacks in commercializing PA-based products. Furthermore, the future prospect focuses on supporting future research that will facilitate the incorporation of PA in food products at an industrial scale. 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 development of bioactive food packaging is an important issue, given its potential to preserve food quality and safety without the use of synthetic preservatives. This study aimed to develop new polystyrene foam (PS) films with hydroxytyrosol (HOxTYR) and eugenol (EUG), alone or in combination, as bioactive molecules to preserve sliced sponge cake during long-term storage. The cake samples were analyzed periodically during storage at 15 °C in terms of quality attributes (pH, water activity, height, volume and weight loss, firmness, CIE Lab color, lipid peroxidation products, microbial spoilage, and overall acceptability) and shelf life. The active film containing the combination of 0.6% HOxTYR and 0.6% EUG showed the strongest antioxidant activity, which was attributed to a potential synergism between the compounds, resulting in lower lipid oxidation rates (TBARS). The combination of HOxTYR and EUG also offered the greatest reduction in bacterial load (62% for S. aureus and 58% for E. coli), suggesting a synergistic effect on microbial inhibition. Likewise, samples packaged in a modified atmosphere (MAP) with the active film containing the combination of HOxTYR and EUG showed the best performance, including a smoother texture and greater volume, more stable color, lower microbial counts, and greater overall acceptability, and, consequently, a longer shelf life of up to 70 days at room temperature. Furthermore, the results of this study could contribute to environmental protection by reducing food waste, and suggest that the developed active packaging technique represents a promising and innovative approach to the preservation of bakery products. Full article

As the demand for dairy-free bakery products increases, identifying plant-based milk alternatives that sustain product quality is essential. This study investigated the effects of eight milk types—soy, hazelnut, walnut, quinoa, flaxseed, coconut, oat, and almond—on the functional, nutritional, and sensory properties of muffins. A control prepared with cow’s milk served as reference. Rheological results showed that quinoa- and flaxseed-based batters exhibited stronger viscoelastic behavior, whereas oat and coconut milks reduced consistency. Physical parameters such as baking loss, volume index, and symmetry revealed no significant structural differences (p > 0.05), confirming that milk substitution did not affect baking performance. Color analysis indicated distinct chromatic variations, particularly in almond and coconut muffins with higher color difference (ΔE) and hue values. Phenolic and antioxidant assays demonstrated enhanced total phenolic content and Cupric ion reducing antioxidant capacity (CUPRAC) activity in quinoa and coconut variants. CUPRAC activity reached 0.89 micromoles Trolox equivalents per gram (µmol TE/g) in almond and 0.63 µmol TE/g in control muffins, whereas oat and hazelnut muffins exhibited the lowest activities, with 0.37 and 0.44 µmol TE/g, respectively. Amino acid profiling showed elevated glutamic acid and arginine in walnut, nearly doubling the control. Sensory scores (≥5) indicated high acceptability, confirming that selected plant-based milks can replace cow’s milk while enhancing functional and bioactive quality. 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

This study explores the effect of date palm gum (DPG) as a novel functional ingredient for whole wheat bread (WWB) to enhance its physicochemical and textural properties. Herein, samples containing varying concentrations of DPG (0–3% w/w) were prepared and analyzed, out of which D2 (containing 1% w/w DPG) exhibited superior qualities. Microscopic studies showed that D2 exhibited improved crumb aeration, suggesting better fermentation than the others. Moisture analysis revealed that D2 retained a higher quantum of moisture (50.06 ± 0.41%). Further, the colorimetric study showed that increasing DPG concentration led to a corresponding decrease in L* values (46.69 ± 0.13) due to the combined effect of Maillard browning and the inherent color of DPG. Analysis of FTIR spectra confirmed stable interactions of DPG and starch–protein complexes in D2. Stress relaxation exhibited that D2 had the highest initial (F₀; 162.95 ± 1.70 g) and residual (F₆₀; 95.81 ± 3.94 g) forces, indicating that it maintained its structure under stress. In gist, DPG exhibited strong potential as a natural hydrocolloid that could be explored to develop functional bakery products. Full article

This research investigates the incorporation of hemp seed cake (HSC), a nutrient-rich by-product of hemp oil extraction, into traditional pretzel formulations as a sustainable approach to functional dry pretzels development. Wheat flour was substituted with 5–40% HSC, and the resulting products were examined for proximate composition, bioactive profile, and sensory perception. Substitution with hemp seed cake significantly enhanced nutritional quality, raising protein from 7.49 to 12.62% and fiber from 0.90 to 11.78%, while lowering carbohydrates; notably, formulations containing ≥30% HSC meet EU Regulation 1924/2006 criteria to be labeled as a “source of protein.” Functional enrichment was further demonstrated by a four-fold increase in polyphenols (115.28–467.45 mg GAE/kg) and a corresponding rise in total flavonoids (63.40–262.28 mg GAE/kg), as well as by enhanced antioxidant capacity evaluated through DPPH (194.42–658.89 mg Trolox/kg) and ABTS assays (486.05–1647.23 mg Trolox/kg). Sensory analysis (CATA, PCoA) indicated that low substitution levels (≤10%) preserved traditional acceptability, whereas higher levels (≥30%) introduced nutty aroma and denser texture, perceived by consumers as novel. These findings highlight hemp seed cake as a multifunctional ingredient that improves nutritional density, enhances bioactive potential, and supports circular economy principles in the bakery sector. Full article

Functional bread development with clean-label ingredients remains a technological challenge due to the negative effects of certain functional additives on dough rheology and bread quality. The aim of this study was to evaluate the effectiveness of dried sourdough as a natural improver in carob-enriched bread. Dough formulations included 10–20% carob flour as a partial replacement of wheat flour, with dried sourdough added as a dough improver at 5–10%. The results demonstrated that the addition of 10% dried sourdough increased maximum creep compliance of dough with 10% and 15% carob flour by 26% and 56%, respectively. The addition of 5% and 10% dried sourdough to dough with 10% carob flour decreased its Newtonian viscosity by 24% and 36%, resulting in improved dough handling. Crumb pore structure was enhanced by the addition of 5% dried sourdough, with average pore surface area increasing around 2.5 times in breads with 15% and 20% carob flour. Incorporation of dried sourdough reduced bread hardness and chewiness by up to 40% in samples with 15% carob flour and by 20–30% in samples with 20% carob flour. Sensory properties of crumb structure (crumb development, pore fineness, elasticity and crumbliness), which were adversely affected by carob flour addition, showed varying levels of improvement by the addition of dried sourdough. These results demonstrate the feasibility of using dried sourdough as a natural improver in functional bakery formulations, supporting the development of clean-label products without synthetic additives. Full article

Aquafaba, a legume cooking water typically discarded as waste, represents a sustainable and plant-based protein source with promising functional applications. In this study, aquafaba hydrolysates were produced by enzymatic treatment with flavourzyme and savinase, yielding two products with distinct degrees of hydrolysis (DH: ~10% and ~29%). Aquafaba hydrolysates obtained using flavourzyme (AFHs) and savinase (ASHs), together with aquafaba isolate (AI), were incorporated into muffin cakes as partial flour substitutes (5%). The addition of hydrolysates significantly influenced cake quality parameters, particularly antioxidant capacity and textural attributes. Enzymatic hydrolysis, particularly with savinase, produced the most pronounced functional improvements. Technologically, ASHs supplementation significantly enhanced cake expansion, with specific volume values (2.23 mL/g) nearly doubling compared to the control (1.04 mL/g). Crust color was markedly altered, with L* decreasing and a* and b* rising, reflecting darker, more browned surfaces due to intensified Maillard reactions. Both ABTS and DPPH assays demonstrated increased radical scavenging activity with higher DH, while SDS-PAGE confirmed the release of smaller peptide fractions. The ABTS radical scavenging activity of the control muffin (CM, 262.53 mg TE/100 g) significantly increased in AIM (muffin cake substituted with aquafaba protein isolate, 481.87 mg TE/100 g) and reached its highest values in muffins containing AFHs (489.74 mg TE/100 g) and ASHs (530.56 mg TE/100 g), respectively. Hardness, a critical quality parameter particularly relevant to storage stability, decreased in hydrolysate-enriched samples compared with both control and isolate formulations. Oxitest results showed that extended induction periods for hydrolysate-containing cakes (18:47 h) were longer relative to control muffins (15:08 h). Thermal analysis also indicated improved thermal stability in the presence of aquafaba. Overall, the findings demonstrate that aquafaba hydrolysates can be effectively utilized in bakery systems to enhance antioxidant activity, oxidative stability, and technological properties, while simultaneously contributing to sustainable food valorization. Full article

The growing consumer demand for plant-based, protein- and fiber-enriched foods has encouraged the incorporation of novel functional ingredients into bakery products. Hemp flour (HF), obtained from cold-pressed hemp seeds, represents a sustainable ingredient rich in proteins, dietary fibers, lipids, and bioactive compounds, making it suitable for nutritional fortification. This study investigated the impact of HF addition (5–40%) on the quality of muffins prepared with wheat flour (WF) and whole wheat flour (WWF). An initial hedonic sensory evaluation identified 5–20% HF as the most acceptable substitution range, which was then subjected to detailed physicochemical, sensory, textural, colorimetric, and microbiological analyses. Incorporation of HF significantly increased protein (up to +44%), fiber (up to +172%), and ash (up to +76%) contents, while decreasing moisture (−39%). Both WF and WWF muffins darkened with HF incorporation, with a greater lightness reduction in WF. Texture changes (increased firmness and gumminess) were more pronounced in WF muffins. Sensory analysis revealed that WF muffins were best accepted at 10–15% HF, whereas WWF muffins maintained good acceptability up to 20% HF, indicating better integration of HF in the whole grain matrix. All samples complied with microbiological safety requirements. Overall, the optimal substitution level was 10–15% HF in WF muffins and 20% HF in WWF muffins, demonstrating that HF can enhance the nutritional profile of muffins while maintaining acceptable technological and sensory properties in a matrix-dependent manner. Full article