Search Results (671)

Pigskin, a major byproduct of pork processing, has high protein content and low fat, endowing it with considerable market value for food applications. In this study, bioaugmented fermentation with Latilactobacillus sakei YBZY-W5, a strain previously isolated from traditional fermented pigskin, was applied to pigskin to systematically evaluate its effects on physicochemical parameters, microbial community succession, and volatile flavor compound (VFC) profiles over 20 days. The results showed that moisture and pH significantly decreased, while total volatile basic nitrogen (TVB-N) and thiobarbituric acid reactive substances (TBARSs) increased with fermentation time. High-throughput sequencing revealed that Lactobacilli, Fusarium and Aspergillus dominated early fermentation and were gradually replaced by Bacillus, Hanseniaspora and Debaryomyces. A total of 493 VFCs were identified, among which terpenoids, heterocyclic compounds, and alcohols were the most abundant classes. Orthogonal partial least squares discriminant analysis (OPLS-DA) identified numerous differentially changed VFCs (DCVFCs) during fermentation. Odor activity value (OAV) analysis indicated that green, meaty, and woody notes dominated initially, while sour, floral, sweet, and fruity characteristics became increasingly prominent after fermentation. Pearson correlation analysis demonstrated significant associations between key microorganisms (Lactobacilli, Bacillus, Hanseniaspora, Debaryomyces) and DCVFCs (e.g., β-myrcene, ethyl hexanoate, hexanoic acid, ethyl ester, pyrazines). Collectively, bioaugmented fermentation with Ltb. sakei YBZY-W5 effectively modulated the physicochemical and microbial profiles of pigskin, enriched desirable flavor compounds, and reduced unpleasant odor, confirming its feasibility for producing high-quality fermented pigskin products. This study provides an experimental basis for the value-added utilization of pigskin and promotes sustainable development of the pork industry. Full article

Mung beans (Vigna radiata L.) can be considered an environmentally sustainable food due to their nutritional value, environmental benefits, and their potential in reducing reliance on animal-based proteins. Mung bean protein hydrolysate (MBPH) is a plant-based functional ingredient; however, its application in beverages is restricted by intense bitterness. This study was the first one to determine the consumer rejection threshold (CRT) of MBPH in three beverage matrices [water, unsweetened brewed tea (USBT), and sweetened brewed tea (SBT)] to evaluate how sweetness modulated bitterness perception and, in turn, affected consumer acceptance. Sensory evaluation was conducted with 308 consumers to evaluate acceptance of overall quality and bitter taste (yes/no), hedonic rating (overall liking and liking of taste and bitterness; a 9-point hedonic scale), and preference (a 2-alternative forced-choice, 2-AFC test) of three beverage matrices across MBPH concentrations of 0.0–1.2% (w/v). Acceptance decreased with increasing MBPH concentration across all matrices, with distinct differences in CRT values among samples. Based on overall acceptance, CRT values were 0.40% MBPH for water, 0.48% MBPH for USBT, and 0.80% MBPH for SBT. CRT values based on bitterness liking were lower (0.18–0.64%) compared to those (0.24–0.76%) based on overall taste and overall liking, indicating that bitterness perception was the primary driver of rejection. The 2-AFC results showed consistent preference for control samples; therefore, CRT could not be determined using this method under the experimental condition in this study. Overall, CRT values increased from 0.18–0.48% MBPH for USBT to 0.64–0.80% MBPH for SBT, demonstrating a quantitative shift associated with matrix composition and the presence of sweetness, providing a practical strategy for product developers to enhance the palatability of plant-based beverages containing MBPH. Full article

Cannabis sativa L. is a medicinal plant cultivated globally due to its remarkable historical and scientific relevance. Through the consumption of its flowers, also referred to as inflorescences, which contain a high content of cannabinoids, terpenes and polyphenols, the therapeutic properties of C. sativa can be harnessed. This study therefore aimed to determine the chemical profile, antioxidant and anti-inflammatory activities of the essential oils (EOs) obtained from the fresh and dried flowers of two C. sativa cultivars, Lifter and Cherrywine, grown in Komga, South Africa, to assess which cultivar has greater biological potential. The chemical profiles of the hydro-distilled EOs were analyzed by gas chromatography–mass spectrometry (GC-MS), while the in vitro antioxidant and anti-inflammatory activity of the EOs was analyzed using the DPPH and EAD methods, respectively. The identified constituents from the EOs were molecularly docked against NOX2 and NIK (NF-κB-inducing kinase) protein, which are implicated in oxidative stress. The afforded EOs were yellow (pale and bright yellow) in color with a sweet to mildly sweet aroma description. A total of 51 constituents were identified in both fresh and dry oils from the Lifter cultivar, while the Cherrywine cultivar contained a total of 44 constituents. Eighteen compounds, were found to be the main chemical constituents consistent in the flower EOs of both cultivars, notably, caryophyllene (10.71–19.96%), levo-β-pinene (1.37–13.21%), humulene (5.88–9.77%), caryophyllene oxide (4.32–7.49%), D-limonene (1.40–5.48%), α-pinene (2.22–5.22%), nerolidol (0.63–4.97%), cis-β-ocimene (0.22–4.37%), linalool (1.12–4.28%), selina-3,7(11)-diene (0.15–4.23%), humulene-1,2-epoxide (1.23–3.32%), guaiol (0.17–2.60%), (+)-β-selinene (1.20–2.51%), trans-α-bergamotene (0.68–2.37%), β-ocimene (0.90–2.27%), fenchol exo- (0.15–1.27), terpineol (0.14–1.38%) and α-terpineol (0.19–0.75%). The fresh Lifter flower oil (LFO) showed 50% inhibition at 100 μg/mL, with an IC₅₀ of 69.50 ± 4.05 µg/mL against DPPH, suggesting moderate to low radical scavenging activity. The maximum percentage inhibition response of DLFO, CFO and DCFO remained below 50% at all concentrations. The antioxidant activity of fresh LFO may be attributed to its overall chemical composition. The flower oils showed in vitro inhibition of protein denaturation; however, the high standard deviation relative to the mean IC₅₀ values limited the ability to rank the samples’ potencies. Further in silico studies on the putative constituents in the Lifter and Cherrywine cultivars revealed β-bisabolene and α-curcumene as potential molecular targets, with binding energy scores of −7.7 and −7.9 kcal/mol, respectively. Thus, the study findings highlight the promising biological importance of C. sativa inflorescences in the management of oxidative stress-related conditions. Further studies may investigate the influence of environmental growing conditions on their chemical composition, total ROS analysis, pharmacokinetic properties, and in vivo efficacy against oxidative damage to DNA, proteins and lipids. Evaluating the toxicity of the flower EOs is also recommended. Full article

Magnesium is essential for photosynthesis and may enhance plant stress tolerance and secondary metabolism, making Mg-based treatments relevant for savory herb production. This study evaluated the effects of foliar application of 5–20 nm MgO nanoparticles (MgO-NPs) at 75, 200, 300, and 600 mg L⁻¹; MgSO₄ at 20 g L⁻¹; and aggregated MgO at 300 mg L⁻¹ (Bulk) on sweet basil (Ocimum basilicum L.) plants grown under total controlled environment conditions. Treatments were applied once at the two-true-leaf stage. MgSO₄ increased only plant height by 15%, but fresh weight (FW) was not increased. MgO-NPs had no effect on these parameters. However, 600 mg L⁻¹ MgO-NPs and bulk MgO treatments reduced FW by 41% and 39%, respectively. Chlorophyll b content increased in all treatment variants, while anthocyanins increased only in variants with 600 mg L⁻¹ MgO-NPs and MgSO₄ treatments. Higher MgO-NP doses induced oxidative stress, reflected by elevated H₂O₂ and activation of catalase and ascorbate peroxidase. Bulk caused the highest H₂O₂ accumulation and reduced soluble protein content by 26%. MgO-NPs (600 mg L⁻¹) increased essential oil concentration by 61%, but not oil yield per plant. High-dose MgO-NPs acted as elicitors of essential oil accumulation, offering a potential strategy for industrial essential oil production despite biomass reduction. Full article

Simultaneously improving the yield and, in particular, the nutritional quality of sweet corn (Zea mays L. saccharata), one of the most important cereal fresh foods worldwide, remains a major challenge. Here, we demonstrated that compared to control groups, hydrogen-enriched water (HEW) irrigation significantly improved agronomic performance, increasing kernel number (~10.55%) and ear length (~5.73%) while notably reducing barren tip length by about 60.73%. Regarding nutritional quality, HEW-treated kernels exhibited remarkable increases in soluble protein (~61.53%), total soluble sugars (~31.10%), vitamin C (~28.31%), total phenolics (~21.06%), and flavonoids (~40.56%). Micronutrients were also enhanced, such as zinc (~96.82%), iron (~51.70%), and manganese levels (~40.37%). HEW effectively modulated the expression of sugar metabolism-related genes. Specifically, the coordinated upregulation of key genes, such as ZmSUS1 (~3.8 fold), ZmINCW2 (~1.9 fold), and ZmHXK1 (~1.6 fold), might contribute to the enhanced accumulation of sucrose (~11.79%), glucose (~6.21%), and fructose (~26.50%). Starch biosynthesis was also promoted. The improved sugar–acid ratio indicated enhanced taste quality. Importantly, representative key antioxidant genes (ZmSOD2/4, ZmPOD1/2, and ZmCAT1/3) as well as corresponding enzymatic activities in kernels were stimulated, which was negatively associated with lipid peroxidation. Overall, these results indicate that HEW irrigation is a promising, eco-friendly strategy that can be efficiently used to improve sweet corn yield and nutritional value. Full article

Photoperiod-sensitive sweet sorghum (Sorghum bicolor L. Moench) accumulates biomass and sugars during vegetative growth, making it a silage candidate where water limits maize production. This study examined how harvest date and nitrogen (N) rate affect its forage quality and in vitro rumen gas production under rain-fed conditions. In a randomized complete block design with three replications, we evaluated dry matter (DM) yield, morphology, and chemical composition of sweet sorghum harvested at 80 and 110 days after planting (DAP) under five N rates (0, 75, 150, 225, and 300 kg N/ha). Each treatment was ensiled in laboratory-scale bag silos for 90 days. Silage was analyzed for silage quality and 48-h in vitro rumen gas production and fermentation parameters. Delaying harvest from 80 to 110 DAP increased DM yield and fiber fractions (NDF, ADF, lignin), but reduced crude protein (CP), water-soluble carbohydrates (WSC), and in vitro dry matter digestibility (IVDMD) in fresh forage (p < 0.001). Increasing the N rate up to 225 kg N/ha enhanced DM yield, CP, and WSC at both harvest dates. A harvest date × N rate interaction occurred for WSC (p < 0.05). After ensiling, CP and IVDMD were higher in 80-DAP silage. Butyric acid (BA) and ammonia-N (NH₃-N) increased with N rate, but at ≥225 kg N/ha both were lower in 80 DAP silage. The highest 48-h gas production (71.2 and 61.0 mL/200 mg DM) occurred in forage and silage from 110 DAP with 150 kg N/ha. Ruminal pH remained optimal range (6.2–6.8) across treatments. Harvest date and N rate interactively influence sweet sorghum silage quality and rumen fermentability. Under rain-fed conditions, 80 DAP with 225 kg N/ha optimizes silage quality, while 110 DAP with 150 kg N/ha maximizes rumen fermentation potential. These findings support sweet sorghum as a viable silage option where maize production is constrained by water availability. Full article

Taste strongly influences food acceptance and purchase intention. Beyond the five basic tastes, oral sensations such as astringency or koku modulate overall taste perception. Both umami and koku act as taste enhancers, increasing mouthfeel and savoriness. While the taste of most proteogenic amino acids is well established, non-proteogenic amino acids and related protein derivatives remain insufficiently characterized. This study analyzes the taste profile of seventeen underexplored amino acids and protein derivatives using the PredMol in silico tool and quantitative descriptive analysis (QDA), with particular emphasis on their umami and koku potential. In silico evaluation identified bitterness and sweetness as the predominant tastes and predicted carnosine, theanine, citrulline, and ornithine to have koku potential with values higher than 0.44. Principal Component Analysis of the QDA revealed that sweetness, bitterness, and sourness were the main drivers of sample differentiation. Ornithine, glutamine, citrulline, pyroglutamic acid, and theanine exhibited a positive dose–response in umami perception, with potential synergistic effects observed in the presence of 0.5 mmol/L IMP. Additionally, theanine, citrulline, and ornithine enhanced koku-related attributes, particularly aftertaste and continuity, in aqueous model solutions. Overall, these findings suggest that these compounds can have a taste influence in food products and potential to be used as taste enhancers. Full article

The objective of this study was to evaluate the effects of dietary Allium mongolicum Regel essential oil (AMO) supplementation on growth performance, carcass traits, meat quality, and muscle amino acid profile in finishing lambs. A total of twenty male Dorper × Han crossbred lambs (body weight = 32.5 ± 2.5 kg, 4–4.5 months old) were randomly allocated into two dietary treatments (n = 10 per group): a control group fed a basal diet (roughage to concentrate ratio of 45:55) or an AMO group supplemented with 56 mg/d of AMO per lamb. The trial consisted of a 15-day adaptation period followed by a 60-day experimental period. At the end of the trial, six lambs were randomly selected from each group for slaughter. Samples of the longissimus thoracis (LT) muscle were collected to determine meat quality traits, proximate composition, and amino acid profiles. Supplementation increased average daily gain by 6.6% and improved feed conversion ratio by 4.6% (p < 0.05), whereas feed intake and final body weight were not affected (p > 0.05). In LT, GR tissue depth and loin muscle area were increased (p < 0.05). Drip loss was reduced (p < 0.05), whereas proximate composition, cooking loss, and shear force remained unchanged (p > 0.05). The hydrolyzed amino acid composition and protein nutritional value of LT were not affected (p > 0.05). However, total free amino acid (FAA), total essential FAA, and the concentrations of free leucine, isoleucine, lysine, valine, phenylalanine, tyrosine, alanine, glutamic acid, glycine, and cysteine were increased by supplementation (p < 0.05). Moreover, flavor-related FAA, including umami-, sweet-, and bitter/sweet/sulfurous-related FAA were also increased by supplementation (p < 0.05). These results indicate that AMO improves growth efficiency and enhances LT meat quality, particularly by increasing flavor-related FAA, without altering protein nutritional characteristics. Full article

Fermented soybean paste, a traditional high-salt condiment, faces challenges in standardization and quality control due to its reliance on natural fermentation. This study systematically evaluated the effects of a defined starter culture, Tetragenococcus halophilus CICC 10286, on soybean paste fermentation by comparing natural fermentation (NF) and fortified fermentation (FF). Compared with NF, FF maintained a higher moisture in the later stage (NF-LS: 50.30%; FF-LS: 60.08%) and lower total acid levels in the middle and later stages (NF-MS: 1.58 g/100 g; FF-MS: 0.96 g/100 g; NF-LS: 2.23 g/100 g; FF-LS: 1.11 g/100 g). Although protein degradation was more pronounced in the FF group at the midpoint (p < 0.0001), the lower accumulation of amino acid nitrogen suggests a potential shift in nitrogen metabolism, possibly toward enhanced transamination or deamination processes. Free amino acid profiling indicated that FF facilitated earlier accumulation of umami and sweet amino acids, but the total free amino acid content in the later stage was lower. Specifically, Glu and Asp reached 724.47 nmol/L and 305.52 nmol/L, respectively, in NF-LS, whereas the corresponding values in FF-LS were 397.16 nmol/L and 275.46 nmol/L. Meanwhile, Pro reached 337.81 nmol/L in FF-MS, indicating earlier accumulation of some amino acids under FF. Notably, the proportion of bitter amino acids in the FF group was reduced in the later stage. Microbial community analysis showed that FF promoted the enrichment of Tetragenococcus and halotolerant bacteria, such as Halomonas, at the midpoint, and increased the relative abundance of the aroma-producing yeast Zygosaccharomyces (NF-MS: 37.73%; FF-MS: 65.11%). Functional prediction based on PICRUSt2 suggested a higher predicted abundance of genes involved in pyruvate metabolism and branched-chain amino acid degradation in the FF group. These findings demonstrate that T. halophilus CICC 10286, as a starter culture, can effectively modulate the fermentation of soybean paste, providing a scientific basis for developing standardized and quality-controlled fermentation processes. Full article

Excessive sugar intake remains a major health challenge, motivating the development of safe and effective alternatives. Thaumatin, a natural high-intensity sweet protein, elicits sweetness through activation of the sweet taste receptor (T1R2/T1R3), yet its molecular recognition mechanism remains understudied. An integrated computational strategy combining comparative modeling, protein–protein docking, and 500 ns molecular dynamics simulations (triplicates) was employed to elucidate the thaumatin–receptor binding. Structural modeling identified the closed conformation of the Venus flytrap domain (VFT) as optimal for ligand engagement. Modeling revealed a stable binding interface characterized by electrostatic complementarity and van der Waals interactions, characterized by interfacial contacts of receptors and hydrogen bonding networks. Residue-level energy decomposition highlighted key residues (W418 and E422 of T1R2; S59 of T1R3) and thaumatin residues (K67, R82, and K137) that contribute substantially to complex stabilization, consistent with experimentally reported sweetness determinants. These findings provide molecular-level insight into sweet protein recognition and establish a structural framework for rational engineering of protein-based sweeteners with enhanced potency and selectivity. Full article

Plant-derived sweet proteins are promising low-calorie natural sweeteners that may reduce dietary sugar intake and prevent non-communicable diseases. Although seven have been identified—thaumatin, miraculin, monellin, mabinlin, brazzein, pentadin, and curculin (neoculin)—only thaumatin is currently approved as a food additive. The development of others requires comprehensive safety assessments, particularly regarding allergenicity. This systematic review aims to investigate and synthesize allergenicity assessment methods (in silico, in vitro, in vivo, and clinical) applied to these seven sweet proteins. The literature searches were conducted following PRISMA guidelines across Scopus, PubMed, and Wiley Online Library databases, up to 30 November 2025, with no time restrictions. The risk of bias in selected studies was evaluated using GRADE. After the selection process, 14 out of 2634 studies met the inclusion criteria. Thaumatin, miraculin, monellin, and brazzein emerged as the most extensively studied proteins. In silico approaches (sequence and structural homology) and in vitro assays (digestibility and cell-based methods) were the most commonly employed methods. In contrast, in vivo studies (animal models) and clinical evaluations (skin prick tests, oral food challenges) were rarely reported. Allergenicity studies on pentadin, mabinlin, and curculin (neoculin) are limited, indicating a research gap that requires further study to support regulatory approval and consumer acceptance. Full article

Milk production in tropical smallholder systems is constrained by limited high-quality roughage during the hot–dry season. Sweet sorghum silage is drought-tolerant and may replace corn stover silage. Twelve Holstein–Friesian crossbred cows were assigned to the same commercial concentrate plus either corn stover silage or sweet sorghum silage as the primary roughage source (n = 6 per diet). Intake, apparent digestibility, milk yield and composition, and feed-use efficiency were evaluated on day 15 and 30 and analyzed using linear mixed-effects models with cow as a random effect. Compared with corn stover silage, sweet sorghum silage increased dry matter intake (p < 0.05) and improved the digestibility of fibre fractions, including crude fibre, NDF and ADF (p ≤ 0.003), while crude protein- and nitrogen-free extract digestibility were not different (p > 0.05). Milk yield, 4% fat-corrected milk, energy-corrected milk, and feed-use efficiency indices were unaffected by silage source (p > 0.05). Milk protein concentration was higher with sweet sorghum silage (treatment effect p < 0.05), whereas milk fat and lactose were unchanged. Sweet sorghum silage can therefore replace corn stover silage in tropical dairy diets, improving intake and fibre utilization without compromising milk output. Full article

Mogrosides, the primary bioactive compounds of Siraitia grosvenorii, are natural, non-caloric sweeteners with promising therapeutic potential for diabetes. They provide a dual advantage: delivering sweetness without impacting blood glucose levels, while simultaneously exerting beneficial antidiabetic effects. This review systematically synthesizes current knowledge on mogrosides, covering their extraction methods, metabolic pathways, and underlying antidiabetic mechanisms. We first detail key extraction techniques and examine their metabolic fate, which is primarily characterized by gut microbiota-mediated deglycosylation leading to the formation of mogrol. Subsequently, the antidiabetic efficacy of mogroside-rich extracts and pivotal monomeric derivatives is critically evaluated, with an emphasis on mechanistic insights such as AMP-activated protein kinase (AMPK) pathway activation, anti-inflammatory and antioxidant activities, immunomodulatory effects, and the regulation of gut microbiota. It is important to note that due to the limitation of clinical trial data, most of the evidence reviewed derives from in vitro studies or animal models. Finally, their emerging role as functional ingredients within the food industry was discussed. Collectively, this review aimed to establish a robust scientific foundation for the development of mogrosides as safe, plant-derived sweeteners endowed with enhanced health-promoting properties for the prevention and management of diabetes. Full article

To address the challenge of depleting traditional feed resources, this study aimed to biovalorize sweet potato waste (SPW), a major byproduct of the Japanese shochu industry, into a high-value functional animal feed. An innovative two-stage solid-state fermentation (SSF) was employed, featuring an initial aerobic stage with Aspergillus oryzae for substrate degradation, followed by an anaerobic stage with Lactobacillus plantarum for nutritional enhancement. To optimize this complex, multi-variable process, the predictive performance of Artificial Neural Network (ANN) and Random Forest (RF) machine learning models was compared based on an augmented experimental dataset (N = 80). To ensure statistical robustness and prevent data leakage, a repeated k-fold cross-validation strategy was implemented. The RF model demonstrated significantly superior accuracy and reliability than the ANN model, particularly in predicting the primary metric, crude protein (R² = 0.61 ± 0.04 vs. R² = 0.12 ± 0.15). Subsequently, the validated RF model was integrated with a Constrained Differential Evolution (CDE) algorithm for global parameter optimization. The optimized process was predicted to yield a final product with a crude protein content of 25.0%, alongside significant increases of 114.1% in total amino acids and 123.9% in essential amino acids. These projections were experimentally validated in vitro, confirming the model’s accuracy with a relative error of less than 5%. Furthermore, comprehensive biochemical assays demonstrated a massive degradation of anti-nutritional factors and significant enhancements in total phenolic content and antioxidant activity. This study provides a scientifically validated, data-driven framework for the valorization of SPW. It confirms the superior efficacy of ensemble learning methods for optimizing complex bioprocesses with limited data, offering a contribution to the development of a circular bioeconomy and sustainable feed resources. Full article

DREB (Dehydration-Responsive Element-Binding Protein) transcription factors are a subfamily of the AP2/ERF transcription factor family and play a crucial role in the regulation of plant responses to abiotic stress. In this study, we successfully cloned the IbDREB1d gene from the leafy sweet potato cultivar Fucaishu18. The open reading frame (ORF) of the IbDREB1d gene comprises 792 base pairs and encodes a protein consisting of 263 amino acids. Protein sequence analysis indicates that IbDREB1d is characterized by acidic, hydrophilic, and unstable properties, with its closest phylogenetic relationships to Ipomoea trifida and Ipomoea triloba. Quantitative real-time PCR (RT-qPCR) analysis revealed that IbDREB1d is expressed in the roots, stems, and leaves of sweet potato, with increased expression under low temperature, hydrogen peroxide (H₂O₂), and drought conditions. Overexpression of IbDREB1d in sweet potato resulted in transgenic plants exhibiting dwarfism, shortened internode lengths, smaller leaf size, and microscopic evidence of impaired vascular tissue development. Hormonal analysis indicated significant reductions in the levels of indole-3-acetic acid, indole-3-butyric acid, salicylic acid, and zeatin in these transgenic plants. These decreases may explain the observed phenotypic changes, such as inhibited growth and reduced leaf size. This study provides novel theoretical insights into the role of IbDREB1d in stress-responsive expression and modulating plant growth in sweet potato. Full article