Functional Food Ingredients Research Articles

A comparative analysis on impact of drying methods on antioxidants, antidiabetes and antiobesity activities in green algae Caulerpa lentillifera: In vitro study

Marine algae, particularly Caulerpa lentillifera (C. lentillifera), have gained attention as potent sources of bioactive compounds with diverse health benefits. Despite its promising bioactivity, the influence of drying methods on its health-promoting properties remains underexplored. This study investigates the impact of different drying methods on the antioxidant, antidiabetic, and antiobesity activities of C. lentillifera. Fresh samples (GACL-FS) and those dried using air-fryer (GACL-AFD) and microwave (GACL-MD) methods were evaluated for carrageenan content, protein composition, and bioactive potentials. GACL-MD preserved the highest levels of protein, while fresh samples retained the highest carrageenan content. Antioxidant assays revealed superior performance in GACL-MD samples, showing significant DPPH and ABTS inhibition compared to Trolox standards. Similarly, antidiabetic assays demonstrated comparable α-glucosidase inhibition across all drying methods, suggesting robust retention of antidiabetic properties. Antiobesity activity, evaluated through lipase inhibition assays, highlighted GACL-MD's efficacy at lower concentrations, akin to Orlistat, while fresh and air-fryer dried samples showed varied results. In conclusion, C. lentillifera exhibits substantial potential as a functional food ingredient, with the drying method significantly influencing its bioactive profile. Microwave drying emerged as optimal for preserving antioxidant and antiobesity activities, emphasizing the need for tailored drying strategies to enhance nutritional benefits. Future research should focus on optimizing processing techniques and elucidating underlying mechanisms to fully harness C. lentillifera's health-promoting properties in functional food development and public health interventions.

Enhancing bioactive compounds extraction from Noni leaves (Morinda citrifolia) by enzymes-assisted extraction

Noni leaves provide several health benefits as food and traditional medicines due to their bioactive compounds. This study investigated the preliminary effects of cellulase and hemicellulase assisted extraction on bioactive compounds extraction from Noni leaves compared to maceration technique. Cellulase and hemicellulase-assisted extraction formed small holes on the extracts surface and provided rough surface, angular and fragmentation structures indicated some breakdown of Noni leaves cell wall after enzyme reaction. There was a significant difference of the extracts particle size between the samples from cellulase assisted extraction and hemicellulase assisted extraction while no significant difference was observed between the samples from maceration technique and cellulase assisted extraction. For antioxidant activity, cellulase assisted extraction provided the highest antioxidant activity (92.83 and 73.05 mg TEAC/ g of sample which was determined by DPPH and FRAP method respectively). However, hemicellulase extraction exhibited the lowest antioxidant activity (36.38 and 33.33 mg TEAC/ g of sample in DPPH and FRAP method respectively). Cellulase-assisted extraction provided higher asperuloside content (0.14±0.01 μM/ g of sample) as compared to maceration technique (0.13±0.01 μM/ g of sample) and hemicellulase-assisted extraction (0.05±0.01 μM/ g of sample). These results can lead to the use of green technology for bioactive compounds extraction from plant sources for use as a medical and functional food ingredient.

Potential blood pressure regulatory effect of low molecular weight α-chymotrypsin extract and its peptides from Stichopus japonicus: Peptide-ACE interaction study via in silico molecular docking

Hypertension is a significant risk factor for cardiovascular disease and heart damage. Stichopus japonicus (S. japonicus) is a red sea cucumber with antioxidant and anti-hypertensive activities. However, its anti-hypertensive mechanism remains unclear. In this study, we evaluated the inhibitory effects of angiotensin-converting enzyme (ACE) of α-chymotrypsin-assisted hydrolysate of S. japonicus (α-chy) and its ultrafiltrate fractions (>10 kDa [α-chy-I], 5–10 kDa [α-chy-II], and <5 kDa [α-chy-III]). Low molecular α-chy-III exerted excellent ACE inhibitory and anti-hypertensive activities in spontaneously hypertensive rats (SHR). Moreover, α-chy-III significantly reduced the systolic and diastolic blood pressure by modulating the serum angiotensin and ACE levels. Histological analysis revealed that α-chy-III markedly protected the aorta, heart, and kidney tissues of SHR from hypertension-induced tissue damage.Taken together, our findings highlight the potential of α-chy-III as a functional food ingredient for the treatment of hypertension and its comorbidities.

Protocol Refinement for the Development of Coconut Inflorescence Powder

Aims: Coconut inflorescence holds significant potential as a nutraceutical due to its rich composition of bioactive compounds, including vitamins, minerals, and antioxidants. Its use in promoting health and preventing diseases has made it a valuable ingredient in both traditional medicine and modern functional foods. The aim of the study is the protocol refinement for the development of coconut inflorescence powder with acceptable moisture content and superior sensory quality. Study Design: Completely randomized design (CRD). Place and Duration of Study: Department of Plantation, Spices, Medicinal and Aromatic Crops, College of Agriculture, Vellayani, Kerala Agricultural University, between May 2024 and October 2024. Methodology: In the present study, coconut inflorescence was harvested at 5-6 months before inflorescence opening, size reduced (1 cm3 pieces), and precooked by adopting different methods, viz., steaming, boiling, dry roasting, and microwave cooking (non-precooked inflorescence was used as the control). The precooked inflorescence pieces were dried by different drying methods viz., hot-air oven drying at 600C (Control), cabinet drier at 600C, 700C, 800C and solar drying for developing coconut inflorescence powder (CIP). CIP was analyzed for moisture content and sensory quality. Results: CIP prepared by steaming the coconut inflorescence pieces for 30 minutes and drying in cabinet dryer at 600C (C1D1) recorded the least moisture content, 1.83±0.07 per cent. However, CIP prepared by boiling (95-1000C) the inflorescence pieces by submerging for 30 minutes and drying in cabinet dryer at 600C (C2D1) showed the highest mean rank value for all the sensory attributes viz., colour (735.50), consistency (730.63), flavour (730.68), mouthfeel (734.75) and taste (735.23) on a nine-point hedonic scale with a moisture content, 4.20±0.04 per cent. The lowest mean rank value for colour was recorded by C1D1 and C2D0 (211.06). The lowest values for consistency, mouthfeel, flavour and taste were observed for the treatments C4D1 (289.81), C4D1 (290.61), C4D0 (226.05) and C0D0 (216.50), respectively. Hence, C2D1 was identified as the best precooking and drying method for the preparation of coconut inflorescence powder.

Review of hemp components as functional feed and food ingredients: impact on animal product quality traits and nutritional value

This review examined the potential of hemp components as functional feed and food ingredients, focusing on their impact on the quality and nutritional value of animal products. Following hemp legalization, there was growing interest in its potential to enhance animal diets and processed animal products due to its rich nutritional profile, including high levels of polyunsaturated fatty acids (PUFA), essential amino acids, and fibre. Incorporating hemp components into feed for monogastric animals, particularly poultry, improved lipid stability, sensory attributes, and the fatty acid composition of meat and eggs. Hemp supplementation for ruminants, especially in goats, increased PUFA and conjugated linoleic acid (CLA) content in milk, improved meat tenderness, and enhanced oxidative stability. However, research on hemp supplementation for pigs and beef remained limited, indicating the need for further exploration of these species. Hemp cake, rich in protein, fibre, and essential fatty acids, was the most widely used hemp component due to its economic viability, nutritional benefits, and sustainability, contributing to improved meat and milk quality. Regulatory concerns about the transfer of tetrahydrocannabinol (THC) residues in the produced animal products restricted the use of hemp biomass. In processed animal products, hemp components were studied for their potential to enhance nutritional value, replace animal fats, and serve as natural preservatives. Although they improved the fatty acid profile and antioxidant properties of meat products, challenges such as textural changes and increased lipid oxidation needed to be addressed for optimal use. Limited studies on dairy products indicated promising nutritional enhancements, but textural issues could impact consumer acceptance. In conclusion, hemp components show significant potential for improving the quality and nutritional value of animal products. Further research is necessary to address regulatory, sensory, and formulation challenges and to expand their application across different animal species and processed animal products.

Optimized Liquid Medium Formulation for Sanghuangporus vaninii and Biological Activity of the Exopolysaccharides

Aims: Sanghuangporus vaninii (S. vaninii) is a rare medicinal mushroom that is rich in polysaccharides, triterpenes, flavonoids, and other bioactive compounds. It has good potential development value. Methods and Results: We performed single factor experiments and Box-Behnken response surface methodology to optimize the liquid fermentation medium formulation for S. vaninii with mycelial biomass as the indicator. The in vitro antioxidant and anti-cancer capacity of the exopolysaccharides of S. vaninii were estimated. The optimal liquid fermentation media composition for the MS-4, MS-6, and MS-8 strains of Sanghuangporus vaninii consisted of 25.86 ± 0.068 g/L maltose, 7.3 ± 0.043 g/L yeast extract, and 0.71 ± 0.005 g/L dandelion powder. The average mycelial biomass of S. vaninii under optimal conditions was 12.61 g/L. The mycelial biomass of the Sanghuangporus vaninii strains in the optimized formulation was 109–191% higher than that obtained with the basic potato dextrose broth (PDB). The exopolysaccharides of Sanghuangporus vaninii exhibited an ABTS radical scavenging activity with an EC50 of 0.021 ± 0.017 mg/mL and a DPPH radical scavenging activity with an EC50 of 0.076 ± 0.043 mg/mL. In anti-cancer assays, these exopolysaccharides demonstrated an IC50 value of 1.98 ± 0.36 mg/mL against PC-3 human prostate cancer cells, indicating significant bioactivity, highlighting their potential as functional food ingredients. Conclusions: In this study, the formula of liquid fermentation of S. vaninii strains was optimized, which lays a theoretical foundation for increasing the yield of S. vaninii and its application in industry. Moreover, our data showed the clinical potential of the S. vaninii exopolysaccharides as antioxidants and anti-cancer drugs.

Industrial Production of Functional Foods for Human Health and Sustainability

Functional foods significantly affect social stability, human health, and food security. Plants and microorganisms are high-quality chassis for the bioactive ingredients in functional foods. Characterised by precise nutrition and the provision of both nutritive and medicinal value, functional foods serve a as key extension of functional agriculture and offer assurance of food availability for future space exploration efforts. This review summarises the main bioactive ingredients in functional foods and their functions, describes the strategies used for the nutritional fortification and industrial production of functional foods, and provides insights into the challenges and future developments in the applications of plants and microorganisms in functional foods. Our review aims to provide a theoretical basis for the development of functional foods, ensure the successful production of new products, and support the U.N. Sustainable Development Goals, including no poverty, zero hunger, and good health and well-being.

Conformational and processing properties of a high-active ingredient involving soy protein isolates bound with anthocyanins and its application in cake baking

Soybean protein is of plant origin and is commonly appropriate for improving the processing characteristics of foods. This study aimed to explore a novel functional ingredient that contained soybean protein isolate (SPI) and blueberry anthocyanins (BANs). The spatial conformation and secondary structure of SPI-BANs complexes were analyzed using circular dichroism and fluorescence spectroscopy, the processing properties were investigated as well as the retention of antioxidant activity during thermal treatments. Results showed that the contents of free sulfhydryl and free amino groups in complexes increased to 3.50 and 1.19 folds than those of SPI, respectively, while the surface hydrophobicity decreased by 74.23%. Compared with SPI, the BANs-modified SPI had a smaller particle size of 29.12 nm and a lower zeta-potential of -8.73 mV and on the other hand, the complexes possessed higher solubility (83.08%) and foaming and emulsifying properties (115.08% and 54.03 m2/g). After fortification with SPI-BANs, the baking loss rate and adhesiveness of chiffon cake were reduced by 10.82% and improved to 0.24 N.mm, respectively. The high antioxidant activities of SPI-BANs under heat led to the cake’s bioactivities largely enhanced by 1.99 ~ 12.71 folds, being 345.19 µg Trolox/g for the DPPH radical scavenging activity. This study developed the functional food ingredients as antioxidants and a substitute for animal-based proteins in bakery products, which was safe and sustainable by using the dietary components from plant resources.Graphical

Nutritional Quality, Functional Properties, and Biological Characterization of Watermeal (Wolffia globosa)

Watermeal (Wolffia globosa) has emerged as a promising candidate as an alternative protein source due to its outstanding nutritional profile. This study evaluated the nutritional quality, functional properties, and biological characteristics of W. globosa. The protein content was found to be high at 26.76 g/100 g of dry weight (DW). Functional properties, including water and oil holding capacities, protein solubility, foaming, and emulsifying abilities across different pH levels, were assessed to determine optimal conditions. Amino acid profiling revealed that essential amino acids constitute 67% of the total amino acids. Polyunsaturated fatty acids (PUFAs), particularly α-linolenic (18:3 n-3) and linoleic acids (18:2 n-6), were identified as the predominant fatty acids. Additionally, watermeal was found to contain significant amounts of α-tocopherol (699 µg/g) and γ-oryzanol (100 µg/g), which contribute to its antioxidant capacity, as confirmed by DPPH and FRAP assays. The prominent protein bands were observed at around 62–67 kDa, likely representing a structural, metabolic protein (vicilin-like protein) of 38% of the total protein content. Overall, W. globosa demonstrates significant potential as a functional food ingredient, offering a rich nutrient profile and health-promoting properties, making it a promising choice for future diets.

Marine-Derived Bioactive Ingredients in Functional Foods for Aging: Nutritional and Therapeutic Perspectives

Aging is closely linked to various health challenges, including cardiovascular disease, metabolic disorders, and neurodegenerative conditions. This study emphasizes the critical role of bioactive compounds derived from marine sources, such as antioxidants, omega-3 fatty acids, vitamins, minerals, and polysaccharides, in addressing oxidative stress, inflammation, and metabolic disorders closely related to aging. Incorporating these materials into functional foods not only provides essential nutrients but also delivers therapeutic effects, thereby promoting healthy aging and mitigating age-related diseases. The growth of the global anti-aging market, particularly in North America, Europe, and Asia, underscores the significance of this study. This review systematically analyzes the current research, identifying key bioactive compounds, their mechanisms of action, and their potential health benefits, thus highlighting the broad applicability of marine-derived bioactive compounds to enhancing healthy aging and improving the quality of life of aging populations.

Impact of green techniques on intricate cell wall structure of bee pollen to enhance functional characteristics and improve its in vitro digestibility.

Bee pollen is a nutrient-rich super food, but its rigid dual-layered structure limits nutrient release and absorption. The outer exine, composed of stress-resistant sporopollenin, and the inner intine, consisting of cellulose and pectin, form a barrier to digestive breakdown. This study investigates the potential of green techniques, specifically supercritical fluid extraction and ultrasonication, to disaggregate pollen cell walls, enhancing its bioavailability and maximizing nutrient utilization. Ultrasonication treated pollen (USTP) and supercritical fluid extraction-treated pollen (STP) demonstrated disruption, as evidenced by scanning electron microscopy imaging. In relation to scanning electron microscopy, techno-functional, antioxidant, and compositional analysis displayed a positive outcome, with crude lipid, protein, antioxidant activity (2,2-diphenyl-1-picrylhydrazyl activity and 2,2'-azino-bis-3-ethylbenzthiazoline-6-sulphonic acid assay) and total phenolic content increased by 34.80%, 32.58%, 10.80%, 11.37%, and 83.94%, respectively. Based on the above properties, USTP for 4 h and STP at 400 bar for 40 min were identified as the optimal conditions for disintegration. Furthermore, optimized samples analyzed for amino acid and mineral release revealed a notable increase in composition of essential amino acid and minerals (Ca, Cu, Fe, etc.) by ∼1.5 and 1.2 times, respectively. Along with significant changes in composition, fractured pollen exhibited 1.4 folds increase in protein digestibility with minor differences in thermal stability, and crystallinity as established by differential scanning calorimetry, and X-ray diffraction analysis. The study confirms that nutrient release and absorption remain restricted without pre-treatment, highlighting the necessity of specific treatment to disintegrate bee pollen before its use as a functional food ingredient. PRACTICAL APPLICATION: Bee pollen is a rich source of all the essential nutrients required by the humans and recognised as a complete food. However, its tough cellular structure restricts its utilisation in numerous food applications. Therefore, to disintegrate bee pollen and release its nutrients, ultrasonication and super critical fluid extraction processes were employed to improve its utilization for human purposes. Both the treatment techniques, enhanced bee pollen's bioavailability and functional properties, making it more suitable for use in nutraceuticals and functional foods.These treatments proved to increase the antioxidant capacity, digestibility, and create high-value ingredient for supplements, beverages, and fortified foods.

Antioxidant peptides from silver carp steak by alkaline protease and flavor enzyme hydrolysis: Characterization of their structure and cytoprotective effects against H2O2-induced oxidative stress.

Silver carp steak is a rarely utilized silver carp processing byproduct. This study aimed to optimize a dual enzymatic method to extract antioxidant peptide components from silver carp steak and characterize their structure and in vitro antioxidant activity through ultrafiltration purification, response surface methodology, molecular docking, and radical scavenging activity analysis. The optimal extraction conditions for silver carp steak antioxidant peptides (SCSAP) were determined as 1:6 solid-liquid ratio, 1500 U/g alkaline protease addition, 4 h alkaline protease hydrolysis time, 1946 U/g flavor enzyme addition, and 2.5 h flavor enzyme hydrolysis time. The <3 kDa SCSAP component (SCSAP-3kDa) showed the strongest antioxidant activity, with its 1,1-diphenyl-2-trinitrophenyl hydrazine (DPPH) radical scavenging rate, ABTS radical scavenging rate, hydroxyl radical scavenging rate, metal ion chelating rate, and reducing capacity reaching 88.75%, 91.21%, 67.02%, 69.07%, and 0.985, respectively. Moreover, the three peptides (PF-7, GP-8, and YF-10) of 100 µg/mL could protect HepG2 cells from oxidative stress damage by reducing the oxidative damage level and activating Keap1-Nrf2-ARE pathways, enabling an increase of superoxide dismutases (SOD) activity, and a decrease of malondialdehyde (MDA) content and reactive oxygen species (ROS) level. The integrated results indicate the enormous potential of SCSAP-3kDa as a functional food ingredient in the food industry. PRACTICAL APPLICATION: This study selected the antioxidant capacity of silver carp steak peptides as the index and developed a facile dual enzymatic hydrolysis method to obtain three antioxidant peptides (PF-7, GP-8, and YF-10) with biological activity, providing a theoretical basis for bioavailability of antioxidant peptides from silver carp steak and contributing to their application in new functional foods.

Analytical Determination of Squalene in Extra Virgin Olive Oil and Olive Processing By-Products, and Its Valorization as an Ingredient in Functional Food-A Critical Review.

Squalene is a bioactive compound with significant health benefits, predominantly found in extra virgin olive oil (EVOO) and its processing by-products. This critical review explores the analytical determination of squalene in EVOO and various by-products from olive oil production, highlighting its potential as a valuable ingredient in functional foods. An overview of existing analytical methods is provided, focusing on different approaches to sample preparation before analytical determination, evaluating their effectiveness in quantifying squalene concentrations. Studies not primarily centered on analytical methodologies or squalene quantification were excluded. A critical gap identified is the absence of an official method for squalene determination, which hinders comparability and standardization across studies, underscoring the importance of developing a reliable, standardized method to ensure accurate quantification. The valorization of squalene involves advocating for its extraction from olive oil processing by-products to enhance sustainability in the olive oil industry. By recovering squalene, the industry can not only reduce waste but also enhance functional food products with this health-promoting compound. Additionally, there is a need for economically sustainable and environmentally friendly extraction techniques that can be scaled up for industrial application, thus contributing to a circular economy within the olive oil sector.

The development of functionalized alginate-based hydrogels for the management of postprandial hyperglycemia and weight reduction

Polysaccharide-derived functional food ingredients are increasingly prevalent in the food industry for their health benefits and functional versatility. Among them, sodium alginate (SA), a natural polysaccharide, is widely valued for its sustainability, renewability, non-toxic nature, and broad applicability. However, its poor water solubility has limited its use as biomedical materials and food additives. Here, we enhanced SA through carboxymethylation to produce carboxymethylated SA (CMSA), aiming to develop functional food ingredients with improved physicochemical properties for health management. The synthesized CMSA was characterized for its physical properties and ability to form a hydrogel through cross-linking with Ca2+. We assessed its encapsulation efficiency for food particles in simulated gastric and intestinal fluids and evaluated its physiological effects in a rat model. Our findings demonstrated that CMSA-based hydrogels effectively encapsulate ingredients in the stomach, reducing nutrient diffusion in the intestine, and helping to manage postprandial hypoglycemia. Additionally, the hydrogel expands in the stomach and small intestine, contributing to modest weight loss. These findings suggest that CMSA-based hydrogels offer significant potential as functional food ingredients for managing postprandial hypoglycemia and supporting weight management. The development of such gelling systems presents promising applications in both medical and nutritional sciences, offering innovative strategies for addressing diet-related health concerns.

Assessment of using heart of date palm as a new source of protein and carbohydrate on the quality of low-fat bio fermented camel milk and its potential anticancer properties

The heart of date palm (HDP) is a nutrient-dense vegetable, rich in protein and carbohydrate, obtained from the core of palm trees. Carbohydrates are the major component of the heart of date palm, providing a quick source of energy and fiber content can help digestion and contribute to feeling of fullness, making it good addition to a balanced diet. The study investigated the potential of incorporating HDP into low-fat bio fermented camel milk (BCM). The initial findings highlighted HDP's medicinal properties and its significant cytotoxic effects against HepG2 cells, indicating its potential as an anticancer agent. Over 21 days of cold storage, the addition of HDP improved the water-holding capacity, color, sensory qualities, bioactive compounds, and rheological properties of low-fat BCM. Moreover, no mold, yeasts, or coliforms were detected in any samples throughout the storage. The total number of viable probiotic cells remained functional (>106 log CFU/g) for 21 days. The sensory evaluation results suggested that high-quality low-fat BCM can be achieved by adding up to 20 % HDP. The molecular docking study supports the various biological activities of HDP particularly in relation to its cytotoxic effects against HepG2 cancer cells. This study opens the door for further exploration into utilizing HDP as a novel functional ingredient in dairy foods to create value-added products.

White cabbage waste powder improves gluten-free rice-based breadsticks functional and nutritional characteristics

Fruit and vegetable industrialization generates large amounts of organic residues abundant in bioactive compounds. In the present work, white cabbage powders (WCP) were used to partially replace rice flour (5, 10, 20 and 30% w/w) in the formulation of gluten-free breadsticks. Physicochemical (moisture content, water and oil absorption capacity), pasting, and antioxidant properties (reducing sugars, total phenols and DPPH scavenge ability) were evaluated in flour blends. Breadsticks quality was evaluated by analysing dough rheology, physicochemical (aw, colour, texture) and antioxidant properties. Water and oil absorption capacities improved with WCP addition, whereas pasting properties worsened. Dynamic oscillatory tests revealed that WCP incorporation increased G’ and G’’ values. Colour attributes were also significantly modified with WCP addition, whereas breadsticks hardness reduced compared to control formulation. Nutritional properties of breadsticks improved with WCP addition, as deduced from the better antioxidant characteristics obtained for both blends and breadsticks, when vegetable powders were added. In conclusion, this study reveals that WCP can be suggested as functional food ingredient to increase the nutritional properties of new, rice-based gluten-free breadsticks.

Unveiling the structural characteristics and anti-inflammatory potential of a novel polysaccharide from sweet potato peels

Sweet potato tubers generate a significant amount of peel waste during starch production, leading to resource inefficiency and environmental pollution. This research focused on the isolation/purification of a novel polysaccharide from sweet potato peel, named as sweet potato polysaccharide (SPP-W). The SPP-W has a molecular weight of 5.764 kDa and consist of glucose monosaccharides. The backbone of SPP-W was composed of →4)-α-D-Glcp-(1→, →4,6)-α-D-Glcp-(1→, and →3,4)-β-D-Glcp-(1 → . The branched chain was α-D-Glcp-(1→ linked to the O-6 position of the sugar residue→4,6)-α-D-Glcp-(1→ and the O-3 position of the sugar residue→3,4)- β-D-Glcp-(1→ as confirmed by methylation and NMR analysis. SPP-W was found helpful in reducing the excessive NO, up-regulating IL-10, down-regulating the release of IL-6, IL-1β and TNF-α with LPS-induced RAW264.7 cell inflammation model. Furthermore, SPP-W effectively mitigates oxidative stress by reducing ROS levels, preventing nuclear damage, and preserving mitochondrial membrane potential in the context of inflammation. Immunoassays demonstrated that the clearance of endogenous ROS and the improvement of inflammatory conditions were attributable to the activation of the Nrf2 signaling pathway and inhibition of the NF-κB signaling pathway by SPP-W. Conclusively, SPP-W holds promise as a potential active ingredient for anti-inflammatory functional foods, offering unique and beneficial properties for further research and development.

Ultrasonic‐assisted enhancement of malt characteristics in amaranth: A study on physicochemical, amino acid, sugar profile, rheological properties, and muffin making

AbstractBackground and ObjectiveThis study aimed to assess the potential of incorporating ultrasonication treatment into the soaking process before germination as a method to enhance the nutritional profile of amaranth. While ultrasound has been used to expedite germination in various grains, its impact on germinated grains from a food science perspective remains underexplored. The research focused on the effects of ultrasonication on the composition, functional, and rheological properties of amaranth grains post‐germination.FindingsThe study revealed that germination alone significantly increased γ‐aminobutyric acid (GABA), protein content, phenolic acids, amino acids, and total dietary fiber while reducing phytic acid and rheological parameters. Incorporating ultrasonication during soaking further elevated amino acids, GABA, protein, and phenolic acid levels. Notably, ultrasonication increased protein content by 25%, antioxidants by 35%, and dietary fiber by 20%, and attributed to cell wall breakdown and enhanced enzymatic activity during germination. Phytic acid levels decreased by up to 95% with prolonged ultrasonication, enhancing nutritional quality. Additionally, GABA levels revealed a significant rise, with an 82% and 87% increase in the Annapurna and Durga varieties, respectively. The study also found that ultrasonication led to reduced starch content, decreased pasting properties, and increased sugar content in the grains. Muffins made with ultrasonicated amaranth showed lower water activity levels, indicating better shelf stability, though specific volume decreased due to starch breakdown and increased amylase activity.ConclusionThe study demonstrates that ultrasonication combined with germination is an effective method for enhancing the nutritional and functional properties of amaranth grains. This method significantly boosts health‐promoting components like GABA, proteins, and antioxidants while also affecting key baking quality parameters.Significance and NoveltyThis research introduces a novel application of ultrasonication to improve the physiochemical, antioxidant, functional, and rheological properties of amaranth grains. The findings suggested a promising strategy for developing nutrient‐rich, functional food ingredients, addressing the growing demand for healthier food products.

Applications of bacterial cellulose in the food industry and its health-promoting potential

Bacterial cellulose (BC) is a naturally occurring biomaterial with a wide range of potential applications in the food industry because of its exceptional mechanical qualities, unique nanofiber structure, high purity, and outstanding biocompatibility. Beyond its physical attributes, BC has gained interest recently due to research demonstrating its potential health benefits as a functional food ingredient. This article examines the many uses of BC in the food business, with a focus on how it may enhance food texture, operate as a bioactive carrier, and have promise in the packaging sector. Further research was done on the health-promoting properties of BC in functional foods, particularly with regard to its functions as a blood glucose regulator, and gastrointestinal health. This review seeks to bring fresh ideas for the study of bioactive components in the food industry by providing a summary of the existing research and demonstrating the possible role of BC in food. It also suggests future paths for research.

Mechanistic in vitro study of the effect of Cucurbita moschata (Cucurbitaceae) on carbohydrate digestive enzymes.

Diabetes is marked by postprandial hyperglycemia (PHG), an abnormal rise in blood glucose after meals. A key therapeutic goal to reduce PHG is the inhibition of α-amylase (αAM) and α-glucosidase (αGL), enzymes that break down carbohydrates into sugars. Cucurbita moschata has been shown to inhibit both enzymes. However, its inhibition mechanism has not been explored. This study investigated the in vitro inhibition mechanisms of αAM and αGL and conducted a metabolomic analysis of C. moschata (edible part) water-extract (CME), aiming to preliminarily identify its bioactive compounds (BCs). The inhibitory mechanisms were determined using Lineweaver-Burk plots. The BCs were identified and quantified using HPLC-QTOF-MS, employing both targeted and untargeted metabolomic approaches. CME had a significant higher effect (p<0.05) on αAM activity than against αGL with IC50 of 28.99 and 698.42mg/mL, respectively. The extract showed mixed and uncompetitive type inhibitions on αAM and αGL, respectively. The lowest inhibition constant (Ki) was 47.68mg/mL on αAM activity at 20mg/mL. Untargeted metabolic profiling by UPLC-MS-ESI-QTOF putatively identified 30 compounds in CME, such as amino acids, vitamins, phytohormones, fatty acids, cucurbitacins and phenolic acids, and flavonoids. Functional analysis of CME identified significant pathways, including pantothenate and CoA biosynthesis and phenylpropanoids, among others. The targeted analysis by UPLC-MS-ESI-QqQ allowed us to identify 12 compounds, with l-phenylalanine, p-hydroxybenzoic, and p-coumaric acid as majors. This study demonstrated the inhibitory potential of CME on αAM and αGL activities, which may be attributed to its metabolites. Thus, this plant represents a valuable source of BC against PHG. Practical Application: The research highlights that Cucurbita moschata has significant potential in managing postprandial hyperglycemia in diabetic patients by inhibiting enzymes like α-amylase and α-glucosidase. In addition, the identification of its compounds emphasizes its importance as a source of bioactive compounds. Therefore, C. moschata could be effectively utilized in the development of nutraceuticals or as an ingredient in functional foods specifically designed for postprandial hyperglycemia management. Thus, integrating C. moschata as part of the daily diet could offer patients with diabetes a natural alternative to control their blood glucose levels after eating.