Search Results (125)

The aim of this study was to evaluate the possibility of using rapeseed protein–fiber concentrate (RPFC) as a functional ingredient for wheat pasta fortification, with emphasis on dough rheology, gel-like network formation, microstructure, and cooking quality. For this purpose, five formulations of rigatoni pasta were produced by partially substituting wheat flour with 0, 5, 10, 15, and 20% RPFC. Dough rheological behavior was assessed by frequency sweep and creep–recovery tests, while mixing and pasting behavior was evaluated using the Mixolab device. Microstructure was analyzed by scanning electron microscopy (SEM), and pasta technological and chemical parameters were determined using standard methods. All dough systems exhibited viscoelastic, gel-like behavior characterized by the dominance of the storage modulus (G’) over the loss modulus (G”), confirming the formation of a structured gluten-based network. Moderate RPFC incorporation (5–15%) enhanced G′, indicating reinforcement of the continuous protein–starch gel matrix and improved structural integrity and deformation resistance. Mixolab results showed a significant increase in water absorption and dough stability with RPFC addition, reflecting improved hydration and strengthening of the gel-forming protein network. SEM observations confirmed the development of a more compact and continuous starch–protein gel system, associated with reduced stickiness and improved structural cohesion. However, higher RPFC levels (15–20%) disrupted the continuity of the gel network, leading to increased cooking losses (8.8–10.4%), higher fracturability, and reduced firmness of cooked pasta. According to the data obtained, RPFC represents a promising functional protein ingredient for gel-like food systems such as cereal-based products, particularly pasta. These findings offer feasible formulation strategies and support its use as a sustainable, high-quality plant protein ingredient in pasta production. Full article

Recent trends in cereal chemistry emphasize sustainable food systems and functional fortification through upcycling and gluten reduction. This study addresses the challenges of reformulating wheat bakery products with four technologically distinct oat forms at three levels (5, 10, 15% substitution of wheat flour) by focusing on dough’s structural integrity. While conventional farinographic metrics such as Stability (STA) or Degree of Dough Softening (DSD) usually are not able to capture the dynamic fatigue of the gluten–starch matrix of wheat dough, several innovative kinetic descriptors are introduced, e.g., dough development slope angle (DDSA), and the time-resolved of both the dough curve width (DW) and farinograph elasticity loss (FEL) foursomes. Analytical results revealed that fiber-rich oat bran induced a mechanical ‘pseudostabilization’, whereas germinated diastatic malt caused a severe enzymatically driven structural collapse of wheat dough cohesiveness. This degradation was corroborated by a sharp non-linear decline in Falling Number (from 482 s to 196 s) and by a dramatic rise in the DSD/STA ratio (from 6.4 to 149.2). Statistical analysis indicated the proposed descriptors, particularly late-stage DW₁₅–DW₂₀ and FEL₁₅–FEL₂₀, provided more sensitive associations with quality parameters of small round breads baked at a laboratory scale—height, bread slice area, and specific volume—than traditional static indicators of the farinogram. As usual in such cases, a critical threshold of wheat flour substitution was identified at 10–15%. These results demonstrate that time–resolved kinetic modeling of dough elasticity serves as a robust complementary tool for predicting baking performance, enabling the rational optimization of formulations and the prevention of structural defects in industrial production. Full article

Chilacayote (Cucurbita ficifolia Bouché) is recognized as a rich source of nutrients and bioactive compounds, making it a promising ingredient for fortifying staple foods such as corn tortillas. While fortification can improve nutritional properties, it may also alter sensory characteristics that determine consumer acceptance. Therefore, a rigorous and structurally grounded assessment of these sensory modifications is required. In this study, sensory evaluations were conducted with regular tortilla consumers using Check-All-That-Apply (CATA) questionnaires to examine six attributes (color, smell, texture, taste, mouthfeel, and aftertaste) in tortillas made with nixtamalized dough and commercial flour, both with and without chilacayote powder. Then, a structured framework for dimensionality reduction and sensory profile identification of tortillas is proposed. In this framework, three classical feature extraction methods (Principal Component Analysis (PCA), Linear Discriminant Analysis (LDA), and a combination of both (PCA+LDA)) were compared with an evolutionary discriminant approach (Differential Evolutionary Linear Discriminant Analysis for Feature Extraction and Visualization (DE-${\mathrm{LDA}}_{FE}$)). The projection quality of these methods was evaluated using a multi-scale separability index that integrates global, semi-global, and local metrics, and the experiments were conducted considering global and attribute-based analyses. Beyond quantitative discrimination, the optimized projections enabled a geometric interpretation that allows the identification of sensory profiles for the tortilla variants. The proposed methodology bridges evolutionary optimization, structural separability assessment, and interpretable sensory characterization, offering a robust and adaptable strategy for multivariate food analysis and other complex discrimination problems and insights into the sensory impact of chilacayote fortification for the development of nutritionally enhanced tortillas that preserve consumer appeal. Full article

Lyophilized black goji berry powder (LBGBP) cultivated in Serbia was evaluated and optimized as a fortification agent in cookie formulation. Nutritional, chemical, technical and biological characteristics, in vitro release and storage stability were analyzed. LBGBP is characterized by a phenolic-rich profile dominated by acylated anthocyanins, 5-O-caffeoylquinic acid (5-O-CA), and spermidine-based phenylamides (S1, S2), which are partially retained in LBGBP-enriched cookies and enhance their functional properties. The substitution of different white flour shares with LBGBP in cookies statistically significantly improved their overall nutritional profile by increasing protein, dietary fiber, minerals and bioactive compounds, concurrently reducing fat, sugar and sodium levels. With the increase in the LBGBP in cookies, total phenolics and total anthocyanin content increased to the levels of 58.09 mg GAE/100 g and 10.12 mg CGE/100 g of cookies, respectively. The overall effect of LBGBP cookie fortification led to softer, more crumbly cookies with significant improvement in antioxidant and antidiabetic activity. The Z-score analysis was chosen to perform multi-criteria cookie formulation optimization with the goal of maximal functional enrichment, with minimal decrease in technological quality. The 10% LBGBP substitution was calculated to produce optimal overall quality, obtaining 65.96% of maximal score in comparison to the control sample of only 32.91%. Full article

The increasing awareness of health among consumers has made the development of functional cereal products a major trend in the food industry. This study investigated the effects of grape seed extract (GSE) on the quality parameters of medium-gluten wheat flour and fresh wet noodles, with the aim of developing functional noodle products. GSE was incorporated at concentrations of 0%, 0.2%, 0.4%, 0.6%, and 1% (w/w). Its influence on dough properties—including farinographic characteristics, extensibility, and pasting behavior—as well as on noodle quality attributes (antioxidant activity, tensile strength, color, microstructure, total phenolic content, and sensory profile) was evaluated. The results indicated that at 1% GSE addition, the farinographic properties, extensibility, and pasting characteristics of the dough were consistently enhanced. Correspondingly, the noodle microstructure exhibited a more compact and ordered arrangement. Furthermore, increasing the level of GSE fortification led to a significant rise in the total phenolic content and antioxidant capacity of the noodles (p < 0.05). This study can provide key technical support for developing novel fresh wet noodle products that possess both excellent quality and antioxidant functionality, thereby contributing to the functional enhancement of staple food products and meeting consumer demand for healthier dietary options. Full article

The aim of this study was to evaluate the potential of minimally processed beetroot pomace (BP), obtained from an industrial juice producer selected as a case study, converted into a stable beetroot pomace flour (BPF) at an industrial scale level, for flour fortification, functional confectionery development, and dietary supplementation. It was characterized by a high dietary fiber content (~27 g/100 g) and a very low carbohydrate-to-fiber ratio (1.9). High level of total phenolics and flavonoids (14.1 ± 0.1 mg GAE/g and 1.43 ± 0.1 mg QE/g), betacyanins and betaxanthins (898 ± 54 and 960 ± 65 µg/g), as well as pronounced antioxidant (FRAP 31.5 ± 1.1 and DPPH 25.8 ± 2.9 µmol TE/g), anti-hyperglycemic and anti-inflammatory activity (27.3 ± 1.3% and 41.0 ± 3.4%) remained upon in vitro digestion. Replacing 14–28% of cereal and pseudo-cereal flour with BPF reduced the carbohydrate-to-fiber ratio to the recommended 10:1, while incorporation of 20% BPF into cookies reduced this ratio by 2.5-fold and the glycemic index from ~56 to ~30. Furthermore, long-term supplementation of standard and high-fat/high-sucrose diet with BPF (0.5% w/w) reduced feed efficiency by 1.7 and 2.6-fold respectively, and improved glucose tolerance in C57BL/6J mice. Findings show the effectiveness of the by-product in bridging the fiber intake gap and body weight regulation. Full article

Instant noodle fortification with fish-derived proteins enhances nutritional value; however, the effects of catfish powder (CFP) combined with different drying methods and barrier packaging on prolonged storage stability remain unknown. This study incorporated 10% (w/w) CFP into wheat flour-based instant noodles processed by tray drying or deep-fat frying, yielding four treatments: control tray-dried (CD), control fried (CF), CFP tray-dried (TD), and CFP fried (TF). Samples were packed in metallized low-density polyethylene (M-LDPE) and evaluated every 15 days over 180 days. CFP fortification increased protein and mineral content, which remained stable throughout storage. CFP incorporation and frying elevated lipid oxidation, whereas tray drying improved oxidative stability. Drying methods influenced moisture attributes, product structure, rehydration behavior, and color; tray-dried noodles retained higher lightness and hardness, whereas fried noodles showed faster water uptake. Cooking performance remained largely stable, with gradual shifts noticed in CF and TF samples over time. Microbiological quality remained acceptable, with no pathogens detected. Multivariate analysis identified the drying method as the primary driver of quality differentiation, with storage time intensifying oxidation and color divergence. Overall, tray drying with M-LDPE packaging is recommended to optimize the nutritional and storage stability of CFP-fortified instant noodles. Full article

The study explored the impact of Microwave-Assisted Extraction (MAE) on the physicochemical, structural, functional, and antioxidant properties of protein concentrates from white pea (Lathyrus sativus), red gram (Cajanus cajan), and black gram (Vigna mungo). The objective was to evaluate the efficiency of MAE as a sustainable green extraction technique compared to the conventional method. Total amino acid content increased in MAE protein from 69.23 to 72.78 g/100 g powder in white pea protein (WPP), 69.41 to 72.39 g/100 g powder in red gram protein (RGP), and 65.56 to 70.30 g/100 g powder in black gram protein (BGP). Functionally, MAE significantly improved solubility and emulsifying capacity and water- and oil-holding capacities. Bioactive evaluation showed a significant increase in total phenolic and flavonoid contents, followed by improved DPPH, ABTS, and FRAP activities. A reduction in tannins and phytic acid correlated with enhanced in vitro protein digestibility. These enhanced MAE-derived proteins further demonstrated superior performance when incorporated into wheat flour, improving its nutritional and functional properties. Overall, MAE protein demonstrated improved structural integrity, antioxidant potential, and digestibility, highlighting white pea protein as the most responsive legume to MAE, followed by red and black gram. Full article

The present study aimed to model and optimize the fortification of corn-based extruded flips with quinoa flour to improve their nutritional, functional, and sensory quality while maintaining desirable technological properties. Corn flour was partially replaced with quinoa flour at levels of 0, 10, 20, and 30%, and the mixtures were processed using a twin-screw extruder at three screw speeds (350, 500, and 650 rpm). The influence of formulation and mechanical energy input on product quality was evaluated through comprehensive characterization, including bulk density, expansion index, texture, color, chemical composition, mineral profile, amino acid and fatty acid composition, and descriptive sensory attributes. Response surface methodology (RSM) was applied to model the effects of quinoa addition and screw speed on 56 quality responses. The Z-score approach was employed to identify optimal processing conditions. The results showed that from a technological and nutritional perspective, formulations containing 20–30% quinoa processed at medium to high screw speeds (500–650 rpm) provided the most balanced products. Z-score optimization identified that the sample with 20% quinoa extruded at 650 rpm showed a balanced combination of enhanced nutritional characteristics and preserved physical and sensory quality. Full article

The chiffon cake is widely consumed and is especially age-friendly due to its soft texture and ease of swallowing. However, conventional formulations based on low-gluten flour (LGF) are low in bioactive compounds and offer limited nutritional value. This study examined whether partial replacement of LGF with mycoprotein powder (MPP), a sustainable fungal protein rich in phenolics and flavonoids, could enhance the functional properties of chiffon cakes, with substitution levels up to 80% of LGF. Building on our previous work showing that mycoprotein substitution preserves chiffon cake texture and sensory quality, we focused on phenolic composition and antioxidant capacity in this study. Free and bound phenolics were quantified directly in cake samples, and bioactives were extracted with water, 50% ethanol, and 95% ethanol. Total flavonoid content and antioxidant capacity were assessed using DPPH, ABTS, ferric reducing antioxidant power, ferrous-ion chelating activity, and reducing power assays. Increasing MPP levels significantly elevated extraction yield, total phenolics, and total flavonoids, with 50% ethanol giving the highest recoveries. At 80% MPP substitution, total phenolics nearly doubled, and flavonoids increased more than six-fold, accompanied by marked improvements across all antioxidant assays. These findings support mycoprotein fortification as a viable strategy to enhance the nutritional and functional quality of chiffon cakes. 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

Iron deficiency anemia remains a major public health concern in Brazil, particularly among children, pregnant women, and women of childbearing age. This scoping review aimed to map the trend line of public policies on iron supplementation and food fortification implemented between 1977 and 2025. The review followed PRISMA-ScR guidelines and the Joanna Briggs Institute methodology, and included searches in PubMed/MEDLINE, Scopus, Web of Science, Embase, Google Scholar, and official government documents. Three main strategies were identified: iron supplementation, mandatory food fortification, and nutrition education. Key milestones included the National Iron Supplementation Program, the 2002 ANVISA Resolution (RDC No. 344/2002) mandating wheat and corn flour fortification, and the launch of the NutriSUS program in 2014. Despite important normative and programmatic advances, persistent critical issues remain, including low adherence, inadequate monitoring, data discontinuity, and bureaucratic barriers. Strengthening intergovernmental coordination, improving information systems, and adopting more bioavailable iron compounds are essential to increase the effectiveness of public policies aimed at preventing and controlling iron deficiency anemia in Brazil. Full article

This study aimed to evaluate the impact of green coffee flour (GCF) addition (2–8%) and drying method (convective versus microwave-vacuum drying) on the physicochemical, textural, and bioactive properties of pasta. Both factors were found to significantly influence the assessed parameters. Green coffee had no observable effect on the microstructure of convectively dried pasta, whereas microwave-vacuum drying caused visible cracks and a heterogeneous starch-protein matrix even at a 2% supplementation level. Microwave-vacuum-dried pasta exhibited a shorter optimal cooking time and higher water absorption compared with convectively dried samples, while increasing the level of GCF prolonged cooking time and increased cooking losses. Texture analysis revealed that convectively dried pasta showed decreased elasticity and cohesiveness with increasing GCF content, whereas microwave -vacuum-dried pasta maintained a relatively uniform texture regardless of supplementation. The incorporation of GCF enhanced the antioxidant capacity of pasta, with the most pronounced effect at 2% addition, while higher levels showed reduced benefits. Similarly, fortification increased the content of phenolic acids, particularly chlorogenic acid and its isomers, with convectively dried samples exhibiting higher levels than microwave-vacuum-dried pasta. Consumer acceptance was highest for convectively dried pasta without GCF and for samples containing 2%, while pasta with higher GCF levels or microwave-vacuum-dried samples received lower scores. 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

In response to the increasing consumer demand for healthier diets and the needs of individuals with gluten intolerance, chestnut flour (CF) emerges as a valuable unconventional ingredient for sustainable and functional nutrition. This study evaluated the nutritional, phytochemical, and functional properties of gluten-free biscuits formulated with whole rice flour (RF), CF, and their mixtures, where RF was replaced by CF at 0% (control), 10%, 30%, 70%, 90%, and 100% (w/w). In addition, in the 50% CF formulation, 5% of RF was substituted with fruit powders rich in phenolic compounds and recognized as fortifying agents, such as chokeberry (CP), açaí (AP), and blueberry (BP). Proximate composition, macro- and microelement content, total phenolic content (TPC), total flavonoid content (TFC), and antioxidant activity (DPPH and FRAP assays) were determined for the individual flours, composite flours, fruit powders, and biscuit formulations. Structural characteristics were assessed using Small- and Wide-Angle X-ray Scattering (SAXS/WAXS) analysis and Fourier Transform Infrared Spectroscopy (FTIR). Results showed that CF incorporation enhanced both the nutritional and functional profile of flours and biscuits, increasing protein, fiber, lipid, and mineral contents while reducing carbohydrates, and improving TPC, TFC, DPPH, and FRAP values. Fortification with 5% CP, AP, or BP further boosted the phytochemical content of the biscuits, with the chokeberry-enriched sample exhibiting the highest TPC (348.88 mg GAE/100 g d.s.), TFC (253.82 mg QE/100 g d.s.), DPPH (50.36%), and FRAP (21.07 μM Fe²⁺/g d.s.). The combination of 50% CF and 5% CP provided dual benefits, significant bioactive enrichment alongside the preservation of desirable technological properties. Complementary SAXS/WAXS and FTIR analyses indicated that CF and fruit powders enhanced molecular interactions and matrix cohesion, which may contribute to improved texture and antioxidant potential of the biscuits. Overall, this formulation offers a promising and practical approach to developing functional gluten-free biscuits with enhanced nutritional, phytochemical, functional, and structural characteristics. Full article