The MRS, blueberry and whey protein were used as the medium of lactic acid bacteria.The different protective agents were added after fermentation to explore the effects of spray drying process on the survival rate of bacteria cultured in different medium.The results showed that the mixed culture medium of blueberry whey protein could promote the growth of Lactiplantibacillus plantarum 67 and Lacticaseibacillus paracasei grx701, and the number of viable bacteria was 5×10⁸ CFU/mL which was higher than that of MRS Medium.Blueberry whey protein mixed fermentation sample plus protective agent which was skim milk powder 12%, sodium glutamate 1.5%, trehalose 4%, glycerin 4%.The protection effect on lactic acid bacteria is good, which the survival rate is 91% at the inlet temperature of 120 ℃ and outlet temperature of 60 ℃.At the inlet temperature of 150 ℃ and 180 ℃, the number of viable bacteria can also reach 10⁷ CFU/mL.When the inlet temperature was 150 ℃, the dispersion of blueberry whey protein mixed fermentation powder was better than 120 ℃ and 180 ℃.The bacterial powder surface was smooth.The infrared spectrum showed that the heat resistance of the bacteria was improved by the interaction between the bacteria, whey protein and anthocyanin of blueberry during the fermentation of blueberry mixed whey protein.

Methods such as confocal laser scanning microscopy, SDS-PAGE, size exclusion chromatography and ELISA were employed to compare the effects of 1.4 μm pore size microfiltration and pasteurization at 72 ℃ for 15 s on the in vitro gastrointestinal digestion of camel skim milk under simulated infant conditions.The results showed that the structure and moisture content of gastric clots, percentages of remaining caseins, releasing amounts free amino groups, and molecular weight distribution of protein hydrolysate for microfiltered camel milk in simulated gastric fluids were closer to raw camel milk, while pasteurization reduced the degradation rate of casein of camel milk in simulated gastric fluids, suggesting that pasteurization increased the resistance of casein to digestive enzyme.Additionally, microfiltration retained immunoglobulin G in camel skim milk to a larger extent, and also retained more immunoglobulin G and insulin during digestion.Microfiltered camel milk has gastrointestinal digestion characteristics and bioactive component retention similar to raw camel skim milk.This study provides a theoretical basis for the production of camel milk products with high-bioactivity.

Processed cheese is produced by blending various natural cheeses at different stages of maturation with emulsifying salts and other additives.The mixture undergoes heating, melting, and continuous emulsification to achieve a homogeneous product.In this study, the physicochemical properties and microstructure of processed cheese using texture analysis, rheometry, and scanning electron microscopy (SEM) were characterized to investigate the influence of phospholipids on its quality characteristics.The findings indicated that phospholipids notably enhanced the melting properties, hardness, and chewiness of reconstituted cheese by modifying the emulsification process (P<0.05).Phospholipids and proteins could reduce the elasticity and viscosity of cheese through hydrogen bonding and hydrophobic interactions.Microstructurally, phospholipids decreased the formation of protein voids and promoted a more uniform dispersion of fat globules, resulting in a dense mesh structure that alters the water distribution within the cheese.In conclusion, the addition of phospholipids to processed cheese significantly impacts its emulsification properties, functional attributes, and microstructure.These findings offer valuable insights for optimizing the production process of processed cheese and enhancing overall product quality.

Proteins and polyphenols can interact in reversible or irreversible ways, thus affect the sensory, texture and nutritional properties of foods.To investigate the types of non-covalent interactions between anthocyanins (centaurin-3-O-glucoside (C3G)) and bovine serum albumin (BSA) and their effects on BSA protein properties, multispectral techniques and molecular docking methods were used.The effects of C3G on the properties of BSA protein were also studied.First, Fourier infrared spectroscopy showed that the amide I and A bands were redshifted and their peak intensities weakened after C3G combined with BSA.The results of circular dichroism spectrum showed that the structure of BSA protein became loose and the secondary structure of BSA was changed in the presence of C3G.The α-helix content decreased from 31.8% to 31.1%, and the β-fold content increased from 18.1% to 18.5%.Next, the fluorescence spectra confirmed that the quenching of BSA by C3G is a static quenching caused by the formation of ground state complex.Thermodynamic and molecular docking results showed that the force between BSA and C3G is mainly contributed by electrostatic attraction and hydrogen bond, and C3G entered the BSA cavity structure.Finally, the study on the physical properties of BSA showed that the addition of C3G could expand the BSA domain and increase the particle size from 244.75 nm to 644.70 nm.Interestingly, C3G significantly enhanced the solubility, water holding capacity and oil holding capacity of BSA, as well as improved foam properties and emulsification properties.This study provides an important experimental and theoretical basis for understanding the effects of C3G on the conformation and protein properties of BSA, and provides a theoretical basis and reference for the application of protein-anthocyanin complexes.

Yak milk cheese casein bitter peptides have multiple beneficial bioactivities, including ACE inhibitory activity, antibacterial activity, and anti-glycation activity.HMG-CoA reductase is one of the primary targets for treating hypercholesterolemia (HC) and is the key rate-limiting enzyme in the body’s cholesterol biosynthesis.This study focuses on the yak milk cheese bitter peptides RPKHPIK (RK7) and KVLPVPQ (KQ7) as the research subjects, using atorvastatin, simvastatin, rosuvastatin, and pravastatin as control samples.Using bioinformatics tools, we studied the physicochemical properties of KQ7 and RK7, employed molecular docking and molecular dynamics simulations to reveal the mechanism of HMG-CoA reductase inhibition, and measured the inhibitory activity of RK7 and KQ7 on HMG-CoA reductase through in vitro experiments. The results indicated that the molecular weights of RK7 and KQ7 are 874.90 Da and 779.50 Da, respectively.Both RK7 and KQ7, as well as the four statin drugs, could form ligand-receptor complex conformations with HMG-CoA reductase.After comparing RK7 and KQ7 with the inhibitory peptides in the HMG-CoA reductase peptide database, it was found that KQ7 had a 75% similarity with known inhibitory peptides, and RK7 is a novel inhibitory peptide for HMG-CoA reductase.In vitro experiments showed that the IC₅₀ values of RK7 and KQ7 for HMG-CoA reductase were 1.045 mg/mL and 1.228 mg/mL, respectively. This study efficiently and rapidly identified yak milk-derived HMG-CoA reductase inhibitory peptides through bioinformatics platforms and in vitro validation experiments.It also explored the mechanisms of molecular interactions through molecular docking and molecular dynamics simulations, providing new insights into HMG-CoA reductase inhibitory peptides.

Traditional fermented sufu is a daily condiment and appetizer, acting as a good source of plant-derived protein and bioactive peptides.To explore the angiotensin converting enzyme (ACE) inhibitory tetrapeptide and investigate the structure-activity relationships, the peptides of oil sufu were isolated using ultrafiltration and solid-phase extraction, and identified using Nano-LC-MS/MS.The potential ACE inhibitory peptides were preliminarily screened by online database, and then the peptides with high ACE inhibitory activity potential were further screened and analyzed using molecular docking, quantum chemical calculation, and quantitative structure activity relationship modeling.Their binding modes, distribution of the frontier molecular orbital, active sites, and inhibitory activities were analyzed.The results showed that peptides with molecular weight <3 kDa had the highest inhibitory activity [IC₅₀=(489.6±26.69) μg/mL], and a total of seven high-potential ACE-inhibitory tetrapeptides were screened after sequences identification.The molecular docking results showed that all seven peptides bound tightly to the receptor through hydrogen bonding, hydrophobic, electrostatic, and metal bonding interactions to exert their inhibitory effects.Quantum chemical results showed that the highest occupied molecular orbitals of the tetrapeptide were mainly distributed on the two-terminal proline (P), and they had a high electronegativity and was easy to become an active site;FALP, GWPT and EGWP had lower energy gap and higher molecular reactivity.The results of quantitative structure activity relationship modeling showed that the parametric characteristics of the amino acid residues at two-terminal of the tetrapeptide had a more significant effect on the IC₅₀ value;the smaller hydrophobicity and stereotropism of the amino acid, and larger electrical properties, the stronger the activity of the peptides.In conclusion, computer-assisted screening of ACE inhibitory peptides in furu was feasible, and the electrical properties of the two-terminal and proline were important to its inhibitory activity, which will provide a reference for the subsequent rapid screening of ACE inhibitory peptides and the study of structure-activity relationship.

To investigate the synergistic inhibitory effect of food flavorings alone and in combination with other inhibitors on acrolein (ACR), seven compounds, including disodium 5′-guanylate (GMP), disodium 5′-inosinate (IMP), quercetin (QUE), curcumin (CUR), theanine (THE), propyl gallate (PG) and monosodium glutamate (MSG) were screened from flavor compounds and food additives.The inhibitory effect on ACR at high temperatures was determined by high-performance liquid chromatography-diode array detection, and then the synergistic inhibitory effect of these compounds on ACR was analyzed by using CompuSyn software according to the Chou-Talalay method, the combination with good synergistic inhibitory effect was used in roasted pork patties to verified the inhibitory effect on ACR generated during processing.Our results showed that all seven inhibitors had the ACR-scavenging ability;Secondly, GMP combined with THE, MSG, and QUE in a constant IC₅₀ ratio had a good synergistic inhibitory effect on ACR within a certain concentration range;Thirdly, by adding its compound combination to the actual system of roasted pork patties, it was found that the GMP+THE compound had the best synergistic effect, with an inhibition rate of 62.23% on ACR in roasted pork patties, which was about 1.6 times that of using it alone, in addition, the inhibitory effect of using straw mushrooms containing an equal amount of GMP instead of the combination of GMP and THE in roasted pork cake on ACR is comparable to that of the GMP+THE group.On this basis, the adducts of GMP and THE with ACR, including GMP-ACR, THE-ACR, THE-2ACR-1, and THE-2ACR-2, were detected in pork patties using LC-MS/MS.This indicated that their synergistic inhibition of ACR is due to the formation of their respective adducts, and also proved the feasibility of using mushrooms to replace GMP pure products in food.This article selected the combination of flavor agents GMP and THE, which could synergistically inhibit ACR generated during food processing.This study provided a scientific basis for the development of high-temperature resistant ACR inhibitors, reducing the chemical hazard of ACR in food processing, improving food safety, and preventing chronic diseases caused by ACR.

The primary objective of this study was to delve into the influence of varying concentrations of octenyl succinic anhydride (OSA) on the emulsifying proficiency and stability of tamarind seed polysaccharide (TSP) subsequent to esterification.To accomplish this, TSP and its esterified derivatives underwent rigorous characterization utilizing infrared spectroscopy, scanning electron microscopy, and thermal analysis techniques.Furthermore, the emulsifying potential, emulsion stability, and rheological attributes of OSA-modified TSP were meticulously analyzed.The results indicated that the higher the degree of OSA esterification, the smaller the emulsion particle size becomes, accompanied by an increased absolute value of zeta potential, ultimately enhancing emulsion stability.Optical microscopy analysis underscores that TSP and OSA-TSP emulsions with three specific substitution levels exhibit optimal stability in a pH 7 environment, with stability diminishing as either the pH or substitution degree decreases.This study involved the esterification of tamarind polysaccharide with octenyl succinic anhydride, enabling a comparative assessment of the structural characteristics, emulsifying capacity, and emulsification stability between TSP and OSA-TSP samples with varying degrees of esterification.The outcomes presented herein offer valuable insights and serve as a reference for the modification of novel polysaccharides and their potential industrial applications.

This study presents a low-cost and environmentally friendly method for the green synthesis of silver nanoparticles (AgNPs) using Forsythia suspensa leaf extract as a reducing agent.The optimal green synthesis process was determined through single-factor and orthogonal experiments;The structural characterization of AgNPs was conducted using UV-Vis spectroscopy, scanning electron microscopy, Fourier transform infrared spectroscopy, and X-ray diffraction;The catalytic degradation activity of AgNPs on organic pollutants such as p-nitrophenol (4-NP), methyl orange, methylene blue, and rhodamine B was evaluated;The antibacterial activity against Escherichia coli (E.coli) was preliminarily assessed;The antioxidant activity was evaluated by determining the DPPH radical scavenging ability, with vitamin C used as a positive control.The results showed that the optimal conditions for green synthesis were 40% ethanol concentration, 70 minutes reaction time, and 4 mL of Forsythia suspensa leaf extract. Under these conditions, the synthesized AgNPs had particle sizes mainly ranging from 40 to 70 nm with good crystallinity.The degradation rates of 4-NP, methylene blue, methyl orange, and rhodamine B by AgNPs were 91.08%, 90.03%, 94.64%, and 93.00%, respectively.The minimum inhibitory concentration (MIC) and minimum bactericidal concentration (MBC) of AgNPs against E.coli were determined to be 0.140 6 mg/mL and 0.281 3 mg/mL, respectively;The DPPH radical scavenging rate was 93.5% at an AgNP concentration of 0.55 mg/mL.In summary, AgNPs synthesized using Forsythia suspensa leaf extract demonstrated high catalytic degradation, antibacterial, and antioxidant activities, suggesting their potential applications in wastewater treatment, medical bioactive materials, and other fields.

Heterocyclic amines, a class of mutagenic and carcinogenic polycyclic aromatic compounds, are harmful substances generated from the thermal processing of high-protein foods.This study investigated the effects of mango peel, an industrial by-product, and its main active ingredients, pectin and mangiferin, on the formation of main heterocyclic amines 2-amino-1-methyl-6-phenylimidazo[4,5-b]-pyridine (PHIP) and 2-amino-3,8-dimethyl-imidazo[4,5-f] quinoxaline (MeIQx) in both chemical model systems and food systems (roasted beef patties).The study also explored the efficacy of these ingredients under different compounding conditions and investigates the impact of the mangiferin-pectin compound on the sensory and nutritional qualities of roasted beef patties.The study used solid-phase microextraction technology (Oasis MCX column) to extract heterocyclic amines from roasted beef patty samples, and used high-performance liquid chromatography mass spectrometry to determine the content of heterocyclic amines and analyze them.Sensory and nutritional indicators were assessed using reagent kits, texture analyzers, and colorimeters.The results indicate that when mangiferin and pectin were added to beef patties at different amounts (1%, 2%, 3%,on weight basis), they could significantly inhibit the formation of PhIP and MeIQx in roasted beef samples (P<0.05).The combination of the two has a better inhibitory effect.When the optimal combination ratio was 2∶1, the inhibition rate reached nearly 50%, and the optimal treatment was 3%.In conclusion, mango peel and its main components could significantly inhibit the generation of heterocyclic amines during food thermal processing, and had multiple effects on improving the sensory and nutritional quality of food.This result can provide experimental ideas and theoretical basis for the development of natural additives with multiple effects such as improving food safety and nutrition.

The aim of this study was to investigate the effects of steam explosion (SE) on the structural, physicochemical and functional properties of soluble dietary fiber (SDF) in pomegranate peel.Taken the extraction rate of SDF as index, the optimal technology of SE modification was as follows:the particle size of pomegranate peel residue was 60 mesh, the pressure was 0.60 MPa, and the maintenance pressure time was 140 s.Under these conditions, the extraction rate of SDF was (13.42±0.12)%, which was (5.91±0.04)% higher than that before modification.The analysis of Fourier transform infrared spectroscopy, X-ray diffraction and scanning electron microscopy showed that more chemical groups were exposed, the intermolecular hydrogen bonding was strengthened, and the crystallinity was decreased after SE.The structure of SDF was also changed, and the surface was poriferous, rough and collapsed.The water-holding capacity, oil-holding capacity and swelling capacity of modified SDF were increased to (1.19±0.09) times, (1.60±0.16) times and (1.95±0.03) times of those before SE, respectively.In addition, SE improved the glucose adsorption capacity, alpha-amylase inhibition ability, cholesterol adsorption capacity and antioxidant ability of SDF in pomegranate peel residue.In conclusion, SE technology can effectively improve the physicochemical and functional properties of SDF from pomegranate peel residue, which provides a theoretical basis for the extraction and application of SDF from pomegranate peel residue.

The relationship between changes in volatile compounds and lipid and protein oxidation of chilled beef storage at superchilled temperature (-1.5, -2.5 ℃) was studied.Gas chromatography-mass spectrometry and stoichiometric analysis showed that the main flavor substances of beef samples in superchilled groups were n-hexaldehyde, nonylaldehyde, undecylaldehyde, and dodecylaldehyde.The contents of dimethyl disulfide and 3-methylthiopropionaldehyde which were significantly negatively correlated with odor sensory scores and positively correlated with protein carbonyl content (P<0.001) were relatively high in the control groups (4.0, 0.0 ℃).Beef samples in superchilled groups had a higher content of nonylaldehyde and undecylaldehyde, which were positively correlated with the scores of odor sensory and significantly negatively correlated with the hydrogen peroxide value (P<0.05).No dimethyl disulfide and 3-methylthiopropionaldehyde were detected in -1.5 ℃ (SC1) and -2.5 ℃ (SC2) groups, and the concentration of nonylaldehyde and undecylaldehyde was higher in SC2 group than in SC1 group.During storage period, the carbonyl of beef in superchilled groups was significantly lower than that in control groups, and the active sulfhydryl content was significantly higher than that in control groups (P<0.05).The carbonyl content of beef in SC2 and SC1 groups was only 2.04 and 2.09 nmol/mg on the 24th day, while the active sulfhydryl group content was still 28.94 and 31.24 nmol/mg.The content of hydroperoxide in SC2 group was the lowest only 0.082 g/100 g and had a higher odor perception (3.63 still maintained the normal odor of beef), that was, the -2.5 ℃ (SC2) superchilled group had a better storage effect, indicating that superchilled storage may maintain the good volatile flavor of beef by inhibiting the oxidation of lipid and protein.The research results provide theoretical and data support for the application of superchilled in the storage and preservation of chilled beef.

In this study, deep eutectic solvents (DESs) were used to extract tuna skin collagen (TSCO).Firstly, the TSCO extraction rate and the integrity of the advanced structure were used as evaluation indexes to select the solvent combinations with better extraction effect.Subsequently, the effects of different extraction conditions were discussed, including the proportion of components, extraction speed, temperature and time, and finally the crude extracted TSCO was purified by column chromatography.The extracted collagen was analyzed using Fourier transform infrared spectroscopy, SDS-polyacrylamide gel electrophoresis and scanning electron microscopy.The results showed that the extraction rate of collagen could reach 98.74% under the conditions of 2∶1∶30 molar ratio of betaine, citric acid and water, extraction temperature of 60 ℃, rotational speed of 1 000 r/min and extraction time of 180 min.After purification by column chromatography its purity was 91.4%, which was higher than that of the collagen standard (80.4%).Structural analysis showed that the extracted TSCO maintained an intact triple-helical structure with uniform molecular weight distribution and good microscopic morphology, indicating that DESs could efficiently extract TSCO without destroying its structural integrity.This study demonstrated the high efficiency and feasibility of DESs in TSCO extraction, which can provide a reference for promoting the high-value utilization of tuna skin.

As an emerging processing method, 3D printing has great potential for application in the food industry.The pseudo-plastic fluid behavior of the starch paste makes it easy to extrude from the 3D printing nozzle and quickly deposit into molding.In this paper, the microstructure, gelatinization, rheology, and 3D printing properties of pectin-sweet potato starch flocculation system were studied by adding different contents of pectin (0%, 1%, 3%, 5%, 7%) with sweet potato starch as the main raw material.Results showed that all the samples exhibited elastic gel-like properties and solid-like characteristics, which were conducive to the shape preservation of the samples after 3D printing.Pectin content had significant effects on gelatinization, rheology, texture, and microstructure of sweet potato starch gel (P<0.05).Compared with natural sweet potato starch, the viscosity value, recovery value, and disintegration value of pectin sweet potato starch flocculation system decreased, and the gelatinization temperature increased.Among them, the mixed gel with 3% pectin content had the best printing effect, and the hardness, elasticity, water holding, and adhesive properties are (82.35±3.08) g, 0.98±0.01, (0.79±0.04) g/g, and 58.38±0.02, respectively.Moreover, the network structure was regular and the thermal stability was good.The mixed gel with 7% starch gel and pectin content of raw sweet potato had poor printing effect.In summary, adding a certain amount of pectin could improve the gel characteristics of the coagulation system and improve the 3D printing effect of sweet potato starch gel, so that sweet potato starch has a broader application prospect in the field of 3D printing.

Corn flour was firstly fermented by lactic acid and followed by hydrolyzed using cellulose, and the effects of the compound modification on the rheological properties of corn flour batter were investigated, and its influence on the baking, texture and sensory characteristics of the prepared chiffon cake were also evaluated.The results showed that the modification endows significant improvements in the elastic modulus, viscous modulus, and apparent viscosity of the corn flour dough.Compared with the unmodified corn flour, the weight loss rate of composite modified corn cake was reduced;and the adhesiveness, gumminess, hardness and chewiness of the prepared chiffon cake were decreased by 30.77%, 57.42%, 58.82%, and 60.88%, respectively;The sensory evaluation score also increased by 33.3 points;and the cohesion had no significant changes.In addition, the elasticity of the chiffon cake prepared with compound modified corn flour reached 95.05%, which was similar to the value of the cake prepared by wheat flour chiffon;the quality characteristics of chiffon cake produced by the compound modified corn flour was significantly improved.The results obtained could provide support for the feasibility of applying modified corn flour in chiffon cake.

In this study, cassava starch was used as raw material to improve the 3D printing formability and quality characteristics of the xanthan gum-cassava starch coagulation system by adding different proportions (0%, 2%, 4%, 6%, 8%, and 10%) of xanthan gum.Results showed that the addition of xanthan gum increased the G′, G″, and tanδ values of the starch system, indicating that it had obvious elastic behavior, which was beneficial to the shape stability of the printed object after 3D printing.The amylose content, retrogradation value, relaxation time, and water fluidity of the starch system were reduced.The amylose content was reduced by 4.47 g at most, the retrogradation value was reduced by 339 mPa·s at most, and the relaxation time was reduced by 164.74 ms at most, which made the texture of the 3D printed sample clearer, improved the accuracy of the sample, and further promoted the extrusion smoothness of the starch sample and the smoothness of the printed sample surface.When the addition amount of 8% xanthan gum was 14 min, it showed a good printing appearance and printing height.At this time, the starch gel system had a suitable fluidity and mechanical strength to maintain the sample shape and maintain the sample height.In summary, when the addition amount of xanthan gum was 8%, the starch coagulation system showed the best printing characteristics.

To prolong the shelf life and solve the problem of the sales limitations of fresh wet jelly, the four packaging materials of cast polypropylene (CPP), polyethylene (PE), polyamide/polyethylene (PA/PE), and polyester/polyethylene (PET/PE) were vacuum-packed with fresh wet jelly in this experiment, to investigate the effect of package skin degree on the water loss and freshness preservation quality of fresh wet jelly.Results showed that the package skin degree of the four materials was PE>CPP>PA/PE>PET/PE.PA/PE and PET/PE, due to the poor flexibility of the material, the degree of adhesion after the vacuum was not enough, easily making the fresh wet jelly damage, exacerbating the loss of water, and further promoting the reaggregation of amylopectin during storage.The formation of microcrystals changed the conformation of starch and the retrogradation increased with the prolongation of storage time.CPP and PE were more flexible, which could achieve a high degree of adhesion with the fresh wet jelly, and maintain its high moisture content, thus hindering the recrystallization of amylopectin, inhibiting retrogradation to a certain extent, thereby delaying the increase of hardness, chewiness, relative crystallinity, and ordered structure of starch, inhibiting the decline of the L^* value, to keep the color bright and the sensory quality better.Among them, PE had the best preservation effect.Therefore, the PE packaging material with high fitness could effectively control the water loss of the fresh wet jelly, so that it showed better texture and sensory quality during the 15-day storage period.However, due to the highest oxygen permeability rate of PE, the amount of gas penetrating from the outside to the inside of the packaging was the largest, resulting in the weakening of the skin degree after the 9th day of storage.Although the fresh wet jelly could still maintain the highest moisture content, its decline was significantly increased.Other methods need to be further studied to improve it.

To explore the drying effects of four drying methods, namely microwave vacuum puffing drying (MVPD), hot air drying (HD), microwave-assisted hot air drying (MD-HD), and vacuum freeze drying (VFD), on jujube crisps, a systematic evaluation was conducted on the impact of different drying methods on the texture, microstructure, puffing degree, rehydration ratio, energy consumption, sensory score, color, browning degree, vitamin C, total acid, total phenol, flavonoid, total sugar, and soluble solids of jujube crisps.The results showed that jujube crisps dried by MVPD performed the best in terms of hardness [(1 684.66±49.53) g], crispness [(1 552.16±52.51) g], puffing degree [(33.86±0.45)%], rehydration ratio (2.06±0.09), energy consumption [(0.22±0.01) kW·h/kg], and sensory score (86.93±1.49).It also had a higher retention rate of vitamin C (17.62 mg/100 g), total phenol (1.25 mg GAE/g DW), and flavonoid (1.83 mg rutin/g DW), and increased the total sugar content (685.66 mg/g).Jujube crisps dried by VFD retained better color and nutritional components, but had a longer drying time [16.55±0.51) h] and higher energy consumption [(13.24±0.56) kW·h/kg].Jujube crisps dried by HD and MD-HD had darker color, weaker aroma, and poorer taste due to high-temperature treatment.Microstructural analysis showed that jujube crisps treated by MVPD had a uniform cell structure, high porosity, and less cell wall damage.In conclusion, MVPD has a higher retention rate of nutritional components and lower energy consumption while ensuring the nutritional quality of jujube crisps, making it suitable for industrial production.The research results can provide a theoretical basis for the selection of drying processing techniques for jujube crisps.

In this study, “Bingtian” Phyllanthus emblica L.was used as raw material,the effects of membrane concentration, freeze-thaw concentration and vacuum concentration on physicochemical properties, antioxidant activity, and stability of P.emblica juice were analyzed.The results showed that the thickening times of membrane concentration, freeze-thaw concentration and vacuum concentration were 3.67 times, 5.19 times, and 8.61 times, respectively.The content of vitamin C in membrane concentrated recovery juice, freeze-thaw concentrated recovery juice and vacuum concentrated recovery juice were 86.21%, 94.88%, and 71.69% of the original juice, and the content of total phenol was 70.64%, 91.51%, and 49.61% of the original juice, respectively.The scavenging ability of freeze-thaw concentrated recovery juice on DPPH and ABTS free radicals was obviously stronger than that of vacuum concentrated recovery juice and membrane concentrated recovery juice.The absolute potential of freeze-thaw concentrated recovery juice was the largest, the particle size and polydispersity index were the smallest, and the juice system was the most stable.There were 32 kinds, 22 kinds, 29 kinds and 19 kinds of volatile components in raw juice and three kinds of concentrated restorative juice, mainly esters, aldehydes, and alcohols.

The study investigated the impact of different drying methods, including hot air drying at 40 ℃ (HAD 40 ℃), hot air drying at 50 ℃ (HAD 50 ℃), hot air drying at 60 ℃ (HAD 60 ℃), microwave vacuum drying (MVD), vacuum freeze drying (VFD), and natural air drying, on the drying kinetics and volatile compositions of Strobilanthes tonkinensis Leaves.The drying processes of the six drying methods were simulated using a thin-layer drying model.The impact of these different drying methods on the volatile components was assessed through the utilization of an electronic nose (E-nose) in conjunction with headspace solid-phase microextraction-gas chromatography-mass spectrometry (HS-SPME-GC-MS).Additionally, organoleptic evaluations were conducted to determine the most suitable drying method for S. tonkinensis leaves.The results showed that the drying rate was highest for MVD and lowest for natural drying, with the Page model demonstrating the best fit for simulating the drying kinetics of S. tonkinensis leaves.Significant variations were observed in the types and concentrations of volatile components among different drying methods, aligning closely with the outcomes obtained from the electronic nose analysis.A total of 61 volatile components across 9 types were identified in the six drying methods, with 42, 27, 28, 25, 38, and 49 components detected in HAD 40 ℃, HAD 50 ℃, HAD 60 ℃, MVD, VFD, and natural drying, respectively.Significant losses of volatile components were observed in HAD 50 ℃, HAD 60 ℃, and MVD.HAD 50 ℃, MVD, VFD, and natural drying methods exhibited better preservation of alcohols and ketones.HAD 40 ℃ had the highest nitrogen compound content.In sensory evaluation, HAD 40 ℃ received the highest total sensory score, displaying a bright yellow-green color in the tea broth, a pure aroma with a distinct glutinous rice note, a mellow taste, and a lingering aftertaste.PLS-DA identified 20 distinct volatile components, enabling effective differentiation among the various drying methods applied to S. tonkinensis leaves.The study offers a theoretical foundation for the optimized drying and processing of S. tonkinensis leaves.

The physicochemical indexes and volatile components of Luzhou flavor Baijiu head aged 50, 30, 10, and 7 years were analyzed based on gas chromatography-ion mobility spectrometry (GC-IMS).The physical and chemical analysis results showed that the higher the cellar age, the higher the total acid and ester content of the Luzhou flavor Baijiu head.The GC-IMS analysis results showed that 52 volatile components were identified in 4 Luzhou flavor Baijiu heads with different cellar ages, including 24 esters, 9 alcohols, 9 aldehydes, 5 ketones, 2 furans, 1 acid, 1 sulfide, and 1 aromatic hydrocarbon, of which esters and alcohols were the main contribution components to the liquor body.After partial least squares discrimination analysis, 12 key differential compounds except ethanol were identified to distinguish Luzhou flavour Baijiu head samples of different cellar ages.The head of Luzhou flavor Baijiu was reboiled by seven-tower tower distillation equipment.When the optimal removal amount of distillate was 2 L (the total amount of head entering the tower was 15 L), the head quality of Luzhou flavor Baijiu could be significantly improved, the use standard of Luzhou flavor base liquor could be reached, and the utilization rate of the head could be increased.

Using high-throughput sequencing technology and headspace solid-phase microextraction-gas chromatography-mass spectrometry (HS-SPME-GC-MS), this study analyzed the microbial diversity and volatile flavor components of Xizang yak yogurt.On this basis, the correlation between microbial community structure and flavor substances, as well as related metabolic functions, was explored.The results showed that the dominant bacteria in Xizang yak yogurt were Lactobacillus, Streptococcus, Enterococcus, and Lactococcus, while the dominant fungi were Geotrichum, Kluyveromyces, and Pichia.In the analysis of volatile flavor components, a total of 37 volatile flavor compounds were detected in Xizang yak yogurt.The main flavor substances were ethyl hexanoate, ethyl L-lactate, ethyl octanoate, ethyl decanoate, isoamyl alcohol, 2,3-butanediol, phenylethyl alcohol, 2-methylhexanoic acid, and 2-nonanone.Correlation analysis indicated that Lactobacillus, Streptococcus, Geotrichum, and Pichia were the microorganisms most significantly associated with volatile flavor components. Lactobacillus and Streptococcus showed a positive correlation with most metabolic products.This study explored the correlation between volatile flavor substances in Xizang yak yogurt and microbial community structure, providing a theoretical basis for improving the quality and taste of Xizang yak yogurt。

Temperature is the most critical factor affecting fish preservation.As an emerging preservation technology, superchilling storage has become highly research-worthy in the field of aquatic product preservation due to its ability to effectively delay the quality deterioration of fish.This study aimed to investigate the effects of superchilling storage on the quality of the northern pike (Esox lucius).Sensory evaluation, pH, total viable counts, total volatile base nitrogen (TVB-N), water-holding capacity, and volatile compounds were analyzed as quality indicators during different storage periods.The results showed that sensory scores and water-holding capacity decreased with prolonged storage time, with the sensory score dropping to (51.60±2.16) on the 15^th day.TVB-N values and total viable counts increased over time, although TVB-N remained within acceptable limits, while total viable counts reached (8.20±0.14) lg CFU/g by 15 days.The pH values initially decreased and then gradually increased.Analysis of volatile compounds revealed that propanal, hexanal, (E)-2-heptenal, 3-methyl-1-butanol, and 1-octen-3-ol were present in relatively high concentrations during storage.Based on variable importance in projection values and relative odor activity values, seven key differential compounds-ethyl hexanoate, 3-methyl-1-butanol, heptanal, 1-butanol, ethyl propionate, 2-butanone, propanal, and 2,3-pentanedione were identified as potential markers for quality changes during superchilling storage.A comprehensive analysis of all indicators indicated that the fish became inedible by the 15^th day of superchilling storage.This study provides a valuable reference for the application of preservation techniques in aquatic products.

High-temperature Daqu is a commonly used saccharification starter in the production of sauce-flavor Baijiu, which provides raw materials and a variety of enzymes, functional microorganisms, flavor substances, and their precursors for Baijiu fermentation.Its quality directly affects the quality and yield of Baijiu.In this study, a detailed explanation of high-temperature Daqu of three different colors, including black, yellow, and white, was provided.The factors that may lead to the formation of these different colors were summarized, clarifying the influence of the production environment, manufacturing processes, non-enzymatic browning, enzymatic browning, and the functional microorganisms on the color of Daqu.The study offered guidance for the production regulation of high-temperature Daqu of different colors.Additionally, it analyzed the differences in physical and chemical properties, enzyme activities, microbial compositions, and flavor profiles among the high-temperature Daqu of different colors.This further enriched and enhanced the understanding of high-temperature Daqu and carries significant implications for the development of traditional brewing techniques.

Plant meal is an agricultural byproduct of oil extraction from oilseeds, containing nutrients such as protein and polysaccharides, as well as functional components such as flavones, polyphenols, and active peptides.However, plant meal contains anti nutritional factors, and the oil extraction process may lead to protein denaturation and cause imbalance in amino acid content.In addition, it is easy to be contaminated by Aspergillus flavus if the plant meal is not stored properly.These issues have greatly affected the full utilization of plant meal resources.By utilizing the metabolic characteristics of microorganisms, the nutritional value and utilization rate of plant meal resources can be significantly improved through the fermentation process, promoting the high-value utilization of plant meal.Therefore, this article reviews the research and application progress of microbial fermentation to enhance the nutritional value, flavor, and functional characteristics of plant meal, in order to provide reference for the research and application of microbial fermentation of plant meal.

Black beans contain abundant polyphenolic compounds such as anthocyanins.The inflammatory response is one of the mechanisms of self-protection in the body, used to promote wound healing.A large number of studies have confirmed that anthocyanin extracts from black bean have strong preventive and therapeutic effects against inflammatory diseases, such as anti-obesity, anti-diabetes, anti-fatty liver, anti Alzheimer’s disease, anti inflammatory bowel disease, and neuroprotective effects.In this paper,the extraction of anthocyanins from black beans, the pathways and mechanism of anti-inflammatory effect were summarized, and the future hot spots and applications of black beans’ anti-inflammatory effect were prospected, in order to provide a reference for the development of functional foods based on black bean anthocyanins.

The taste substances present in meat products are mainly water-soluble entities, including free amino acids, nucleotides, organic acids, polypeptides, and inorganic salts.When meat products enter the oral cavity, they are released and perceived through the action of taste receptors on the tongue, the mechanical action of teeth, the secretion of saliva, and the act of swallowing.This process enables the taste substances to interact with the taste receptors in the mouth, initiating a signal cascade that ultimately activates the taste cortex in the brain, resulting in a taste response.The identification of taste substances in meat products can be accomplished through molecular docking technology, which calculates the intensity of interaction between taste receptors and taste-active peptides, thereby selecting peptides with specific taste attributes.This article mainly summarized the formation pathways and influencing factors of taste substances in meat products, further investigates the release and perception of taste during the oral processing of these products, and employs molecular docking technology to explore the enhancement of meat taste and the mechanism of saltiness enhancement based on taste-active peptides.This research provides theoretical references for the regulation of flavor quality and the innovation of sensory technology in meat products.

Selenium polysaccharide (Se-polysaccharide) is a combination of selenium and polysaccharide, which is more easily absorbed and utilized by the body than inorganic selenium.It possesses a variety of biological activities, including antioxidant, anti-tumor, antiviral, immune enhancement and other aspects.Scientific studies suggest that Se-polysaccharide has the potential for future development in the fields of drug research and nutraceutical development.Through combining the relevant studies on selenium polysaccharide domestic and foreign, this article summarizes the synthetic methods and pharmacological activities of Se-polysaccharide, and hope to provide a valuable reference for the in-depth research of selenium polysaccharide.

Litchi, as a popular summer fruit, is highly susceptible to peel browning and fruit rot after harvesting, which severely affects its storage life.Currently, most litchi freshness packaging on the market uses traditional packaging technologies such as foam boxes, cartons, and films, which can solve the aforementioned problems to some extent.However, in recent years, with the continuous development of packaging technology and the growing needs of people for a better life, higher standards have been set for the appearance, freshness, quality, and shelf life of litchis post-harvest.Therefore, this paper sequentially discusses the research and application of traditional freshness packaging, release-activated packaging, and intelligent packaging in the field of litchi freshness, comprehensively analyzes the current status, limitations, and challenges of litchi freshness technology, and aims to provide a direction for future research, with the expectation of supporting the high-quality development of the litchi industry.

As global food safety issues become more severe, the development of rapid and sensitive detection technologies has become increasingly critical.Characterized by efficiency, speed, and simplicity, nucleic acid isothermal amplification technologies are playing an increasingly vital role in the field of food safety detection.This paper systematically explores the applications of various nucleic acid isothermal amplification methods in food safety detection, including loop-mediated isothermal amplification (LAMP), rolling circle amplification (RCA), recombinase polymerase amplification (RPA), enzymatic recombinase amplification (ERA), strand displacement amplification (SDA), and nucleic acid multi-arm primers and circular optimization technologies.The discussion encompasses the main types, basic principles, specific applications, advantages of combining these methods with other technologies, and future development trends.By analyzing recent research advancements, this study aims to provide new perspectives and references in the field of food safety detection.It further seeks to promote the development and application of these emerging technologies.