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Foxtail millet (Setaria italica) is an excellent source of beneficial natural fatty acids and phytosterols. However, the mechanisms underlying the dynamic changes of fatty acids and phytosterols during seed development are unknown. see more In this study, a comprehensive dynamic change analysis of the bioactive compounds during seed development was conducted in two cultivars with different crude fat content (high-fat, JG 35 [5.40%]; and low-fat, JG 39 [2.90%]). GC-FID/MS analysis showed that the proportion of unsaturated fatty acids (UFAs) were higher than the saturated fatty acids (SFAs). UFA content first increased, then decreased during seed development, while SFA content showed the opposite trend. Oil contents continuously increased with seed development, especially at the S2 stage. Phytosterol contents initially increased, then decreased with seed development. Transcriptome analysis revealed that 152 genes were associated with fatty acid metabolism and phytosterol biosynthesis, of which 46 and 62 were related to UFA and phytosterol biosynthesis, respectively. Furthermore, the key genes involved in fatty acid synthesis (ACCase and FATA/B), triacylglycerol biosynthesis (LACS, GPAT, and DGAT), and phytosterols synthesis (CAS1, STM1, EGR6, and DWF1) were overexpressed. This led to maximum UFA, oil, and phytosterol accumulation in JG 35 at the S2 stage. This study reveals the mechanism behind the dynamic changes of fatty acid and phytosterol contents in foxtail millet during seed development.Whole grain polyphenols are associated with structure-specific bioactive properties. However, the phenolic profile of grain ingredients can be significantly altered by processes like fermentation. This study investigated how polyphenol profiles in different cereal grains respond to microbial metabolism during sourdough fermentation. Whole grain wheat (white and red), sorghum (white and lemon-yellow), and teff (white and brown) flours were subjected to natural sourdough fermentation for 48-96 h, and phenolic profiles and their metabolites monitored using UPLC-tandem quadrupole MS. Flavonoid O-glycosides (dominant in sorghum) were rapidly metabolized (66% reduction in 48 h) to release aglycones (2.5 fold increase). O-Glycoside groups in mixed O/C-glycosides (dominant in teff) were selectively hydrolyzed, but more slowly (11-32% reduction in 48 h) than homo-O-glycosides, suggesting steric hindrance from the C-glycoside groups. Flavonoid C-glycosides (dominant in wheat) and aglycones (white sorghum) were generallism during fermentation, and may thus alter phenolic-dependent bioactive properties associated with a specific grain.Tannic acid was loaded into zein nanoparticles using antisolvent precipitation and then these particles were coated by anionic pectin using electrostatic deposition. The resulting core-shell nanoparticles were near spherical and had an average diameter of 166 nm, a particle yield of 95%, a tannic acid content of 5.4%, and a tannic acid loading efficiency of 89%. Circular dichroism revealed that the presence of tannic acid caused little change in the secondary structure of the zein within the nanoparticles. Fluorescence spectroscopy suggested the formation of a molecular complex between the zein and tannic acid molecules. Fourier transform infrared spectroscopy indicated that hydrogen bonding was the main force holding these complexes together. The core-shell nanoparticles remained resistant to flocculation from pH 2 to 8, when heated at 80 °C for 2 h, and when the NaCl concentration was below 30 mM. The encapsulated tannic acid preserved its high antioxidant capacity. The tannic acid was progressively released from the core-shell nanoparticles under simulated gastrointestinal conditions, with the majority of release occurring within the small intestine. Overall, this research suggests that pectin-coated zein nanoparticles may be effective encapsulation and delivery systems for hydrophilic polyphenols in nutraceutical, supplements, or pharmaceutical formulations.Microbial, physicochemical, rheological, and microstructural changes of surimi prepared by pH shift methods and the traditional water-washing method during cold storage were investigated. The starting aerobic mesophilic count (AMC) of pH shift surimi was around 1 log CFU/g lower than water-washed surimi, suggesting antimicrobial effects of the pH shift. All samples could be stored for 5 to 6 days based on the AMC results. Throughout the storage, the gel strength of alkaline-treated surimi increased from 204.2 to 491.9 g, while water-washed surimi decreased from 462.1 to 172.9 g. After the storage, alkaline-treated surimi showed lower total volatile basic nitrogen (TVB-N) value and smaller network hole size that was suitable for incorporation of moisture and starch. It also remained its rheological properties comparing with acid-treated surimi, with better odour properties, less protein degradation, and better network formation. The results indicate that alkaline-treated surimi is more suitable for cold storage.Insects have potential to become food ingredients, but it is necessary to improve the sensory properties of insects to help them to be better accepted by the population. The purpose of this study was to produce and characterize house fly larval meal (FLM) converted to a micro-encapsulated powder to improve appearance and other organoleptic characteristics. FLM showed high protein (54%) and lipid (22%) content, with a microbiological activity compatible for food purposes. Moreover, the high content of essentials amino acids (lysine, cysteine and leucine) and unsaturated fatty acids (oleic, linoleic and palmitoleic) make FLM a valuable nutritional source. Spray drying was selected to encapsulate FLM (0.5-2% w/v) using maltodextrin (20% w/v) and alginate (0.5% w/v). Encapsulation improved the appearance of FLM, creating a white-beige, monodispersed micro-powder (9 µm in size). Micro-powder with 2% FLM is considered a good source of protein (5.1%). Microencapsulation also dramatically reduced the volatile emissions of FLM. In conclusion, novel FLM micro-powders were developed using a simple and scalable encapsulation technique. The micro-powder with 2% FLM is a good source of protein, has a pleasant appearance similar to vegetable meals and has improved odor compared to typical insect meals. Thus, insect-based food ingredients in micro-powders could become more accepted by the general population.

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