Recent advances on characterization of protein oxidation in aquatic products: A comprehensive review

Uncovering quality changes in oysters (Crassostrea hongkongensis) during frozen storage based on lipidomics and proteomics

This study investigated quality changes in oysters during frozen storage through physicochemical analysis, quantitative lipidomics, and quantitative proteomics. Results showed that the quality of oysters progressively deteriorated with increasing freezing time and temperature, as evidenced by color darkening, texture softening, reduced water-holding capacity, and increased TVB-N levels. Simultaneously, protein oxidation and lipid oxidation were observed, resulting in increased carbonyl, disulfide bonds, dityrosine, TBARS, and Schiff base content, and decreased free sulfhydryl groups. Lipidomics analysis revealed oxidation and hydrolysis of polyunsaturated lipids in oysters during storage, with PC being preferentially oxidized. Proteomics analysis revealed extensive oxidation and degradation of structural proteins, particularly MHC and filamin-C. Correlation analysis further highlighted oxidative degradation of polyunsaturated lipids and structural proteins as major contributors to the quality decline of oysters during frozen storage. This study sheds light on the mechanisms of quality deterioration in frozen oysters and provides valuable guidance for enhancing their preservation quality.

Unlocking bioavailability: Hydroxyl radical oxidation boosts digestibility and antioxidant capacity in silver carp myofibrillar protein gels

In this study, the effects of oxidized protein on the physicochemical and digestive properties of myofibrillar protein gels were investigated by constructing a fenton oxidation system and simulating an in vitro dynamic digestion model. The results showed that moderate oxidation (≤ 0.5 mM H2O2) enhanced the whiteness, gel strength, and water-holding properties of MP gels. Tricine-SDS-PAGE, amino acid composition, and peptide analysis showed that the digestion of moderately oxidized MP gels released more essential amino acids and small molecule peptides with stronger bioactivity, and the digested products possessed higher antioxidant capacity. And for the first time, it was found that the degree of oxidative modification of A0A3N0XHW1 and A0A3N0ZA05 determined the antioxidant activity of the digested products. Therefore, moderate oxidation is more favourable to the edible quality of myofibrillar proteins gels, but damage to the quality of MP gels by excessive oxidation (> 0.5 mM H2O2) should be avoided as much as possible during storage and transport. This study provides valuable insights into the production and processing of aquatic products and helps to guide the development of aquatic products in the field of functional foods and life sciences.

The synergistic effect of vacuum skin packaging and electrospun film on the quality of grass carp (Ctenopharyngodon idellus) surimi during refrigerated storage

In this study, the synergistic effect of vacuum skin packaging and electrospun film on various quality parameters of grass carp surimi was investigated. Firstly, the cellulose acetate phthalate (CAP) films containing oregano essential oil (OEO) were prepared by electrospinning. The morphological characterization showed that the electrospun CAP fibers were uniform and bead-free. With the addition of OEO, the diameter of the fibers decreased from 1.48 μm to 0.99 μm, and the antioxidant activity of the films ranged from 25.6 % to 52.8 %. The inhibition zone diameters of the films against Escherichia coli and Staphylococcus aureus were 8.2 mm and 9.8 mm, respectively. Subsequently, the electrospun films and vacuum skin packaging were applied to maintain the quality of grass carp surimi. The pressure reduction during vacuum skin packaging and the subsequent re-pressurization to atmospheric pressure due to gas permeation was utilized to accelerate the two-way mass transfer between the dissolved electrospun film and surimi. During refrigerated storage, the whiteness, water holding capacity, and textural properties of surimi treated with the combined packaging method were maintained better than those of the surimi treated with vacuum skin packaging. Moreover, compared with other treatments, the synergistic packaging method led to the lowest level of pH (6.84), total viable counts (7.56 Log CFU/g), total volatile basic nitrogen (25.39 mg N/100 g), and lipid oxidation (0.62 mg MDA/kg) after 8 days of storage. It was concluded that the combination of vacuum skin packaging and electrospun CAP film loaded with OEO could slow down the loss of commercial value and extend the shelf life of grass carp surimi.

Rapid and slow thawing of Takifugu rubripes fillets: TMT-labeled proteomics analysis, biochemical and morphological comparison

This study aimed to investigate how running water (rapid, R) and ice-water (slow, I) thawing methods affect the quality of Takifugu rubripes fillets. Thawing shrinkage and changes in extractable proteins quantified by tandem mass tag (TMT)-labeled quantitative proteomics were compared. The results showed that the rapidly thawed fillets were quickly underwent greater shrinkage, and the smaller gap areas were reduced by 7.5 % compared to slow thawing. Compared with fresh fish fillets, the outflow of proteins such as ATP synthase, NADH dehydrogenase, and aconitase within mitochondria increased in both thawing methods that presents cell membrane damage and significant disruptions in mitochondrial structure. The pyruvate dehydrogenase and cytochrome c were significantly upregulated in slow-thawing group. Whereas myosin and structural proteins including the Z-line related were significantly upregulated in the rapid-thawing group. These differential proteins serve as crucial markers for elucidating mechanism involved in muscle quality deterioration under different thawing conditions.

Northern shrimp (Pandalus borealis) - a review on biology, catch, processing, quality changes, shelf-life and product safety

Pandalus borealis is a commercially important wild-caught shrimp species with more than 250,000 tons/year being processed into a wide range of products. This review discusses the biology of P. borealis in relation to catch, processing and characteristics of seafood products including sensory and safe shelf-life. Biochemical, chemical, physiochemical and microbial spoilage reactions are discussed to establish (i) indices of spoilage for instrumental shelf-life determination, (ii) kinetic models for shelf-life prediction and (iii) preservation procedures for shelf-life extension. Free amino acids in P. borealis confer a unique sweet taste to products and polyunsaturated fatty acids contribute to good nutritional properties. Spoilage of frozen P. borealis products is caused by oxidation of lipids and shelf-life can be markedly extended by glazing with brines containing antioxidants. Spoilage of chilled products is due to high concentrations of bacteria and their formation of volatile amines that can be used as indices of spoilage. Developed predictive growth models facilitate design of new brined shrimp recipes with low salt and high pH to maintain desirable nutritional and flavor properties, while also inhibiting growth of Listeria monocytogenes and Clostridium botulinum during chilled storage. Future research should focus on sustainable processing and optimal use of the entire animal as food.

Exploring the Mechanism of Directional Production of Characteristic Compounds by Interaction between Fish Myofibrillar Protein and Key Lipids with Different Saturations

Lipid saturation and protein oxidation influence the types and amounts of volatile and nonvolatile compounds by affecting lipid oxidation. This study examined three reaction modes: systems containing only fatty acids with three different saturations, only myofibrillar proteins (MPs), or their combinations. Sensomics (including volatilomics) and metabolomics were used to analyze these systems. Results showed that MPs enhanced saturated fatty acid oxidation, suppressed unsaturated fatty acid double-bond oxidation, and adsorbed volatiles from unsaturated fatty acid thermal oxidation. MPs promoted secondary oxidation to generate short-chain volatiles. The volatile products derived from stearic acid (SA) were mainly dominated by C6-C8 compounds, while oleic acid (OA) was mainly dominated by C7-C10 compounds, and linoleic acid (LA) was mainly dominated by C5-C8 compounds. The concentrations of volatile compounds followed the order: LA (14,061.66 ng/g) > OA (11,943.52 ng/g) > MPs-LA (2,224.45 ng/g) > MPs-OA (154.63 ng/g) > MPs-SA (28.00 ng/g) > SA (24.11 ng/g) > MPs (0.73 ng/g). Through multivariate statistical analysis, hexamethylenetetramine was identified as a differential metabolite specifically associated with the reaction between SA and MPs. This compound may act as an intermediate, potentially playing a regulatory role in flavor formation. Additionally, α-methyl-dl-phenylalanine and triethylene glycol were found to be differential metabolites in the reaction between LA and MPs. This study systematically explained how characteristic volatile and nonvolatile compounds were formed and transformed. The research findings provided important theoretical support for the flavor regulation of fish products, promoting innovative development in the food industry regarding flavor quality enhancement.

Effect of protein oxidation on the quality of abalone (Haliotis discus hannai) during frozen storage under different packaging conditions

This study investigated the effects of protein oxidation under vacuum packaging, ice-coating, air-permeable polyvinyl chloride and non-packaging on sensory quality of abalone during 24 weeks at -20 °C. During storage, carbonyl content of protein increased (1.64 to 3.12-4.13 nmol/mg), sulfhydryl content decreased (20.48-29.94 %), surface hydrophobicity increased (19.50-40.24 %) and Ca2+-ATPase activity decreased (21.13-54.93 %). Protein secondary structures was converted into random coils, UV absorption of chromogenic groups reduced indicated tertiary structure and functional degradation. Compared to others, vacuum packaging decreased carbonyl content (3.41-24.46 %) and slowed down the oxidation process among 9 ∼ 19w, while ice-coating increased L* value (4.12-12.75 %) and maintained freshness among 8 ∼ 19w. The L* value (r = -0.89) and centrifugal loss (r = 0.95) were significantly correlated with carbonyl content, and hardness (r = -0.70) was significantly correlated with surface hydrophobicity (p < 0.01). Thus, 0 ∼ 8w is the effective period in protein degradation regulation considering oxidation indicators and quality control by WHC trend.

Protein oxidation and its effect on functional properties of livestock products during the processing and storage: A review

Protein oxidation is a complex chemical process that pervades the entirety of the food domain. It is governed by two primary mechanisms: the direct oxidation by active entities and the indirect oxidation by secondary oxidation byproducts like lipid oxidation, influenced by many factors. The oxidation of proteins in livestock products readily occurs post-processing and storage through techniques such as freezing, cooking, ultrasonication, among others, leading to protein carbonylation and subsequent alterations in structure. Consequently, the purpose of this manuscript is to scrutinize the impacts of conventional processing and storage methodologies on protein oxidation in livestock products, delineating potential mechanisms, action sites, and influential factors implicated in this progression. Additionally, we delve into the ramifications of protein oxidation on the processing attributes of livestock products, while venturing into forthcoming trends and obstacles to set a groundwork for ensuring and regulating the caliber of these commodities.

Effects of atmospheric cold plasma treatment mode on muscle quality and bacterial community of red shrimp during cold storage

Atmospheric cold plasma (ACP), known for its safety, non-thermal processing, and energy efficiency, is especially effective for preserving perishable items such as seafood. However, excessive use of ACP may cause oxidation and sensory quality deterioration, which limits its application in the seafood industry. Thus, optimizing ACP treatment modes to balance sterilization efficiency with minimal oxidative effects is essential. This study aims to explore the impact of different ACP treatment modes (cyclical and one-time treatment) on the muscle quality and bacterial community of red shrimp during cold storage. The results indicated that on day 0 of storage, compared to the blank group and the one-time treatment group, the cyclical treatment significantly reduced the total viable count in red shrimp (p < 0.05). However, no significant differences were observed in centrifugal loss, cooking loss, textural properties, total sulfhydryl content, or Ca2+-ATPase activity (p > 0.05). By day 8, both ACP treatment modes significantly improved the protein quality of red shrimp. Compared with the one-time treatment, cyclical treatment reduced the abundance of Aliivibrio (57.24 %), Pseudoalteromonas (97.34 %), and Psychrobacter (59.07 %) in the bacterial community and delayed bacterial succession (especially Aliivibrio salmonicida, Psychrobacter cibarius, and Pseudoalteromonas nigrifaciens), slowing down the degradation of protein quality. Specifically, in the cyclical treatment group, cooking loss was reduced by 7.01 %, and improvements were observed in hardness, total sulfhydryl content, and Ca2+-ATPase activity, which increased by 8.93 %, 17.54 %, and 5.63 %, respectively. Overall, this study demonstrates that the ACP cyclical treatment mode has greater potential in preserving the freshness of seafood.

Ultrasound improves the digestibility of oxidized silver carp (Hypophthalmichthys molitrix) myofibrillar protein: Changes from structure to peptide release

The objective of this study was to investigate the effect of ultrasound on the digestibility of oxidized silver carp myofibrillar protein (MP). The MP solutions were oxidized with a hydroxyl radical generating system, and subsequently subjected to 100 W, 150 W, 200 W ultrasound treatment, respectively. The results showed that ultrasound effectively recovered the reduction in the digestibility of oxidized MP, especially the 150 W ultrasound achieved the best effect. The 150 W ultrasound reduced the particle size and turbidity of oxidized MP by 26.71 % and 35.49 %, respectively. The analysis of sulfhydryl, disulfide bonds, intrinsic fluorescence, and surface hydrophobicity suggested that ultrasound caused the breakage of disulfide bonds, which promoted the depolymerization oxidized MP. The morphology observed by atomic force microscope further evidenced that ultrasound reduced the degree of oxidized MP aggregation. The results of peptidomics showed that ultrasound treatment largely increased the peptide release of oxidized MP during the gastrointestinal digestion, especially the peptide containing lysine and arginine. Take together, ultrasound promoted the break of disulfide bond, which led to the depolymerization of oxidized MP and thus improved the digestibility of oxidized MP.

Cold Plasma-Induced Modulation of Protein and Lipid Macromolecules: A Review

Nowadays, the food industry is prioritizing many innovative processing technologies that can produce minimally processed foods with superior and higher quality, lower costs, and faster operations. Among these advancements, cold plasma (CP) processing stands out for its remarkable capabilities in food preservation and extending the shelf life. Beyond its established role in microbial inactivation, CP has emerged as a transformative tool for modifying food biomolecules through reactive plasma species, addressing the versatile requirements of food industries for various applications. This review focuses on the interactions between reactive plasma species and essential food macromolecules, including proteins, lipids, and polysaccharides. The novelty lies in its detailed examination of how CP technology triggers structural, functional, and biochemical changes in proteins and lipids and explains the mechanisms involved. It connects fundamental molecular transformations to practical applications, such as enhanced protein functionality, lipid stabilization, and improved oxidative resistance. CP induces alterations in protein structure, especially in amino acid configurations, that can be applicable to the formulation of advanced gel, 3D printing, thermostable emulsions, enhanced solubility, and sensory materials. This review explores the ability of CP to modify protein allergenicity, its different effects on the mechanical and interfacial properties of proteins, and its role in the production of trans-fat-free oils. Despite its potential, a detailed understanding of the mechanism of CP's interactions with food macromolecules is also discussed. Furthermore, this review addresses key challenges and outlines future research opportunities, positioning CP as a sustainable and adaptable approach for innovating next-generation food systems. Further research is crucial to fully understand the potential of CP for food processing, followed by product development.

Investigating the metabolism of four sulfonamides in grass carp via HPLC-MS for screening candidate materials of matrix reference material

An efficient, sensitive, and precise method for investigating the metabolism of four sulfonamides in grass carp has been established using high-performance liquid chromatography-mass spectrometry. By optimizing the experimental conditions, the method achieved a coefficient of determination above 0.999, with detection and quantification limits set at 0.5 μg/kg and 1.0 μg/kg, respectively. Recovery rates were between 92.90 % and 102.84 %, and relative standard deviations ranged from 1.70 % to 9.83 %, enabling the precise detection of these sulfonamides in grass carp tissue. The factors affecting the metabolic rate during the medicated bath process were investigated, and obtained the optimal parameter conditions for screening the candidate materials. The candidate materials screened through this method exhibit good stability when used to prepare matrix standard substances, this work not only provides a scientific basis for screening sulfonamide candidate materials but also offers insights for developing other matrix reference materials.

Insight into the oxidation mechanism of coconut globulin by atmospheric cold plasma focusing on side chain amino acids

Atmospheric cold plasma (ACP), a novel non-thermal processing technology, generates active substances that stimulate protein oxidation in protein-based foods. Nevertheless, the precise mechanism through which ACP initiates amino acid oxidation on protein side chains remains ambiguous. This study primarily aimed to elucidate the mechanism of ACP-induced oxidation of coconut globulin, focusing on the process of amino acid oxidation. Analysis of protein oxidation products indicated a positive correlation between the extent of protein oxidation and the voltage and duration of ACP treatment. By analyzing the composition of amino acids and active ingredients, the study identified that the most significant changes amino acids were methionine, cysteine, and arginine, and •OH was the primary free radicals. The findings from oxidation kinetics and dynamic simulation indicated that •OH predominantly oxidized methionine, followed by L-cysteine and L-arginine. These results offer theoretical framework for understanding protein oxidation by ACP and suggest potential applications in protein-based food.

Super antioxidant and high antibacterial ability bi-functional xylitol/2-hydroxypropyl-β-cyclodextrin carbon dots with hydroxyl-functionalized for rainbow trout preservation

In 2020, Rainbow trout production reached 959,600 tons, representing 4 % of the global trout output. However, microbial contamination and lipid and protein oxidation spoil around 15 % of total aquatic products. Traditional food preservatives, used for their antibacterial or antioxidant properties, often fall short due to the disparity between the radical-scavenging ability of antioxidants and the ROS-generating capability of antimicrobial agents. This study developed bifunctional xylitol-based carbon dots (xβ-CDs) using 2-hydroxypropyl-β-cyclodextrin (2-HP-β-CD), which exhibited both super antioxidant and high antibacterial activities. The incorporation of xylitol into xβ-CDs substantially enhanced their functional performance. The xβ-CDs displaying remarkable inhibition of DPPH (1-Diphenyl-2-trinitrophenylhydrazine), ABTS (2,2'-Azinobis-(3-ethylbenzthiazoline-6-sulphonate), and ·OH radicals (96.31 %, 99.74 %, and 99.72 %, respectively), rivaling the antioxidant capacity of vitamin C (VC). The xβ-CDs also effectively combated spoilage bacteria by compromising the cell wall and membrane integrity, reducing total protein, AKP, and ATP enzyme levels by 51.25 %, 70.08 %, and 57.80 %, respectively. Moreover, storage tests revealed that xβ-CDs extended the shelf life of Rainbow trout fillets by 3 days. These results indicate that xylitol/2-hydroxypropyl-β-cyclodextrin carbon dots offer a promising approach to preventing bacterial infections, protein oxidation, and lipid oxidation in rainbow trout.

The Effects of Packaging Barrier Properties Coupled with Storage Temperatures on the Dominant Spoilage Bacteria Composition and Freshness Quality of Lamb

This study aims to establish a preservation method by coupling certain barrier packaging with storage temperatures suitable for extending the shelf of chilled lamb. Chilled lamb was packaged using three different oxygen permeability packaging materials of high-oxygen-barrier packaging (HORP), medium-oxygen-barrier packaging (MORP), and low-oxygen-barrier packaging (LORP) (1.70, 23.95, and 1631.44 cm3/(m2·24·h·0.1·MPa), respectively, then stored at temperatures of 4 °C and -1 °C for 28 days, respectively. The results of total viable count, pH, color, and volatile basic nitrogen indicate that HORP effectively inhibits the growth rate of surface microorganisms and the oxidation rate of proteins in lamb. The sulfhydryl content, carbonyl value, and electronic nose suggest that the oxidative decomposition rate of lamb during storage at -1 °C is lower compared to storage conditions at 4 °C. The microbial diversity suggests that HORP significantly hinders the growth and reproduction of Pseudomonas and Brochothrix aerobic spoilage bacteria, as well as diminishes the abundance of the dominant microbial community. Herein, utilizing high-barrier packaging with an oxygen permeability of lower than 1.70 cm3/(m2·24·h·0.1·MPa) in conjunction with ice temperature storage at -1 °C is a highly effective preservation method for prolonging the shelf life of chilled lamb to 28 days.

Effect of temperature fluctuations during frozen storage on ice crystal distribution and quality of tilapia (Oreochromis mossambicus)

The study constructed a model of temperature fluctuation (TF, -20 °C ∼ -10 °C) during frozen status to build a link between the tilapia fillets muscle of ice crystal morphology, moisture distribution, protein oxidation index and the edible quality. When TF treatment more than 3 times, the brightness, color and hardness of frozen tilapia fillets decreased significantly, and the cooking loss and thawing loss increased significantly. The free and unconjugated water in frozen fish fillets exceeded 97 % and did not change much after 9 times TF. The K and TVB-N values were within the safety standards (K < 60 %, TVB-N < 30 mg N/100 g). The ice crystals in the tissues were significantly increased. Protein carbonyls and Ca2+-ATPase were significantly reduced, and secondary structures were irregular. Network correlation analysis showed that ice crystal morphology was significantly correlated with the color, texture and protein oxidation index of frozen tilapia fillets. The results would provide theoretical approach for the transportation and sales of tilapia industrial enterprises.

The Beneficial Role of Polysaccharide Hydrocolloids in Meat Products: A Review

Polysaccharide hydrocolloids have garnered increasing attention from consumers, experts, and food processing industries due to their advantages of abundant resources, favorable thickening properties, emulsification stability, biocompatibility, biodegradability, and high acceptance as food additives. This review focuses on the application of polysaccharide hydrocolloids and their beneficial roles in meat products by focusing on several commonly used polysaccharides (i.e., cellulose, chitosan, starch, sodium alginate, pectin, and carrageenan). Firstly, the recent advancements of polysaccharide hydrocolloids used in meat products are briefly introduced, along with their structure and potential application prospects. Then, the beneficial roles of polysaccharide hydrocolloids in meat products are comprehensively summarized and highlighted, including retarding lipid and protein oxidation, enhancing nutritional properties, improving texture and color quality, providing antibacterial activity, monitoring freshness, acting as a cryoprotectant, improving printability, and ensuring security. Finally, the challenges and opportunities of polysaccharide hydrocolloids in meat products are also introduced.

Protein oxidation: The effect of different preservation methods or phenolic additives during chilled and frozen storage of meat/meat products

Lipid and protein oxidation have significant effects on the shelf-life and nutritional value of meat and meat products. While lipid oxidation has been extensively studied, it has been recognized that proteins are also susceptible to oxidation. However, the precise mechanisms of oxygen-induced amino acid and protein modifications in the food matrix remain unclear. This review comprehensively explores the impact of various preservation techniques, including high hydrostatic pressure (HHP), irradiation (IR), and modified atmosphere packaging (MAP), on protein oxidation during chilled or frozen storage of meat products. While these techniques have shown promising results in extending shelf-life, their effects on protein oxidation are dose-dependent and must be carefully controlled to maintain product quality. Preservation techniques involving the use of phenolic additives have demonstrated synergistic effects in mitigating protein oxidation during storage. Notably, natural phenolic additives have shown comparable efficacy compared to artificial antioxidants. Additionally, incorporating phenolic additives into bio-edible films has shown promise in combating protein oxidation.

How lipids, as important endogenous nutrient components, affect the quality of aquatic products: An overview of lipid peroxidation and the interaction with proteins

As the global population continues to grow and the pressure on livestock and poultry supply increases, the oceans have become an increasingly important source of quality food for future generations. However, nutrient-rich aquatic product is susceptible to lipid oxidation during storage and transport, reducing its nutritional value and increasing safety risks. Therefore, identifying the specific effects of lipid oxidation on aquatic products has become particularly critical. At the same time, some lipid oxidation products have been found to interact with aquatic product proteins in various ways, posing a safety risk. This paper provides an in-depth exploration of the pathways, specific effects, and hazards of lipid oxidation in aquatic products, with a particular focus on the interaction of lipid oxidation products with proteins. Additionally, it discusses the impact of non-thermal treatment techniques on lipids in aquatic products and examines the application of natural antioxidants in aquatic products. Future research endeavors should delve into the interactions between lipids and proteins in these products and their specific effects to mitigate the impact of non-thermal treatment techniques on lipids, thereby enhancing the safety of aquatic products and ensuring food safety for future generations.

Effect of Boiling Treatment on Linoleic Acid-Induced Oxidation of Myofibrillar Protein in Grass Carp

The aim of this study was to investigate the promotion of linoleic acid (OLA)-induced myofibrillar protein (MP) oxidation by boiling treatment. The effect of the boiling treatment on grass carp MP oxidation induced by OLA was investigated. The total sulfhydryl content, fluorescence intensity, and amino acid content were reduced with the increasing OLA concentration after the boiling treatment, while the boiled oxidized MP's carbonyl content (4.76 ± 0.14 nmol/mg) was 2.14 times higher than that of the native MP (2.22 ± 0.02 nmol/mg) at an OLA concentration of 10 mM. Additionally, the secondary structure of MP became more disordered, shifting from an α-helix to random coils and β-turns. When the concentration of OLA was higher than 5 mM, both the surface hydrophobicity and water holding capacity (WHC) decreased with the increasing OLA concentration. Furthermore, the boiling treatment led to a reduction in immobile water and an increase in free water content in the MP gel. These findings establish a theoretical basis for regulating MP oxidation to improve fish quality during boiling.

Improvement on gel properties of chicken myofibrillar protein with electron beam irradiation: Based on protein structure, gel quality, water state

This study aimed to investigate the effects of electron beam (E-beam) irradiation at different doses (0-15 kGy) on the solubility, rheological properties, emulsification characteristics, and moisture distribution of chicken myofibrillar proteins (MPs). Irradiation treatment notably increased the solubility, surface hydrophobicity, emulsification properties, and apparent viscosity of MPs, based on conformational changes caused by irradiation-induced oxidative denaturation of proteins. However, high doses of irradiation (15 kGy) induced in excessive cross-linking and aggregation of proteins, reducing the solubility, emulsification properties, and shear stress. Degradation of myosin heavy and light chains in irradiated MPs increased the content of β-turns and random coils. Additionally, the initial relaxation times of T21 and T22 in irradiated protein gels were reduced, and the peak value of P21 was increased, which improved the water-capturing ability of protein gels. Altogether, these results findings suggest that electron beam irradiation can be applied as a potential technique for modifying muscle proteins.

Research Progress on the Mechanism of the Impact of Myofibrillar Protein Oxidation on the Flavor of Meat Products

Myofibrillar proteins primarily consist of myosin, actin, myogenin, and actomyosin. These proteins form complex networks within muscle fibers and are crucial to the physical and chemical properties of meat. Additionally, myofibrillar proteins serve as significant substrates for the adsorption of volatile flavor compounds, including aldehydes, alcohols, ketones, and sulfur and nitrogen compounds, which contribute to the overall flavor profile of meat products. A series of chemical reactions occur during the processing, storage, and transportation of meat products. Oxidation is one of the most significant reactions. Oxidative modification can alter the physical and chemical properties of proteins, ultimately impacting the sensory quality of meat products, including flavor, taste, and color. In recent years, considerable attention has been focused on the effects of protein oxidation on meat quality and its regulation. This study investigates the impact of myofibrillar protein oxidation on the sensory attributes of meat products by analyzing the oxidation processes and the factors that initiate myofibrillar protein oxidation. Additionally, it explores the control of myofibrillar protein oxidation and its implications on the sensory properties of meat products, providing theoretical insights relevant to meat processing methods and quality control procedures.

An Overview of Advanced Antimicrobial Food Packaging: Emphasizing Antimicrobial Agents and Polymer-Based Films

The food industry is increasingly focused on maintaining the quality and safety of food products as consumers are becoming more health conscious and seeking fresh, minimally processed foods. However, deterioration and spoilage caused by foodborne pathogens continue to pose significant challenges, leading to decreased shelf life and quality. To overcome this issue, the food industry and researchers are exploring new approaches to prevent microbial growth in food, while preserving its nutritional value and safety. Active packaging, including antimicrobial packaging, has gained considerable attention among current food packaging methods owing to the wide range of materials used, application methods, and their ability to protect various food products. Both direct and indirect methods can be used to improve food safety and quality by incorporating antimicrobial compounds into the food packaging materials. This comprehensive review focuses on natural and synthetic antimicrobial substances and polymer-based films, and their mechanisms and applications in packaging systems. The properties of these materials are compared, and the persistent challenges in the field of active packaging are emphasized. Specifically, there is a need to achieve the controlled release of antimicrobial agents and develop active packaging materials that possess the necessary mechanical and barrier properties, as well as other characteristics essential for ensuring food protection and safety, particularly bio-based packaging materials.

Gelatin based preservation technologies on the quality of food: a comprehensive review

Gelatin has played a great potential in food preservation because of its low price and superior film forming characteristics. This review provides a comprehensive overview of the latest research progress and application of gelatin preservation technologies (film, coating, antifreeze peptide, etc.), discussing their preservation mechanisms and efficiency through the viewpoints of quality and shelf life of animal and aquatic products as well as fruits and vegetables. It showed that bioactive and intelligent gelatin-based films exhibit antibacterial, antioxidant, water resistance and pH responsive properties, making them excellent for food preservation. In addition, pH responsive properties of films also intuitively reflect the freshness of food by color. Similarly, gelatin and its hydrolysate can be widely used in antifreeze peptides to reduce the mass loss of food during freezing and extend the shelf life of frozen food. However, extensive works are still required to extend their commercial application values.

Effects of electron beam irradiation on protein oxidation and textural properties of shrimp (Litopenaeus vannamei) during refrigerated storage

Protein oxidation leads to changes in shrimp texture, which affects sensory profile and consumer acceptability. This study aimed to evaluate the impact of electron beam irradiation (EBI) on protein oxidation and textural properties of Litopenaeus vannamei during refrigerated storage. Results revealed that EBI treatment and storage increased the protein oxidation level of shrimps. Shrimps irradiated with ≥ 7 kGy exhibited remarkably higher (P < 0.05) reactive oxygen species, turbidity, and carbonyl contents, and remarkably lower (P < 0.05) Ca2+-ATPase activity, surface hydrophobicity, solubility, and total sulfhydryl contents compared to the control group (0 kGy) on the 7th day of storage. Shrimps irradiated with 3 and 5 kGy exhibited remarkably higher (P < 0.05) hardness, springiness, and chewiness compared to the control group (14.99 N, 1.26 mm, and 3.19 mJ). Collectively, suitable EBI doses of 3-5 kGy were recommended in shrimp preservation to inhibit texture softening by inducing moderate protein oxidation.

Effects of different roasting temperatures on rabbit meat protein oxidation and fluorescent carbon nanoparticle formation

This study explores the oxidation of rabbit meat proteins and the physicochemical properties of the resulting fluorescent carbon nanoparticles (CNPs) under various roasting temperatures (180, 210, 240, 270, and 300 °C). The determination of sulfhydryl content, along with the results from UV and fluorescence spectroscopy, indicates that the protein structure undergoes changes during the roasting process, and the degree of oxidation shows an increasing trend with rising roasting temperatures. The CNP solution obtained exhibits a typical blue fluorescence. Moreover, as the roasting temperature increases from 180 °C to 300 °C, the relative content of the three elements in CNPs, namely C, N, and O, increases by 12 %, -3%, and -9 %, respectively. The surface of the obtained rabbit meat CNPs contains hydrophilic and polycyclic groups, such as carbonyl, hydroxyl, and amide bonds. Correlation analysis reveals a significant positive correlation between the degree of protein oxidation and the fluorescence intensities of CNPs.

The impact of ice slurry as a medium on oxidation status and flesh quality of shrimp (Litopenaeus vannamei) during refrigeration storage

Oxidation of lipid and protein is a major reason of flesh quality deterioration during storage. In this work, cold storage (CS) and flake ice (FI) storage, as traditional strategies for live shrimp (Litopenaeus vannamei) sedation and refrigerated storage, showed remarkable oxidation damage of lipid and protein in shrimp flesh during storage. In contrast, ice slurry (IS), with good heat exchange capacity and contactability, stunned shrimp in a sudden and thus relieved antemortem stress, which resulted in reducing the reactive oxygen species and reactive nitrogen species accumulation, and the oxidation damage risk in flesh. Additionally, IS, as a storage medium acted an oxygen barrier, further inhibited the oxidation of lipid and myofibrillar protein (MP), as revealed by the lower thiobarbituric acid reactive substances level, carbonyl (CO) derives content, total disulfide bond (S-S) content, and the higher total sulfhydryl (SH) content in shrimp flesh during storage, compared with CS and FI. The sodium dodecyl sulfate-polyacrylamide gel electrophoresis electrophoretogram pattern of MP also suggested better preservation of myosin heavy chain, myosin light chain, actin, and tropomyosin in IS, whereas these proteins degraded in CS and FI. Consequently, IS prevented the formation of cross-linking caused by oxidation in MP, leading to improved shrimp flesh quality during refrigerated storage, as demonstrated by the better maintained hardness, springiness, and water-holding capacity compared to CS and FI.

Consumer-oriented smart dynamic detection of fresh food quality: recent advances and future prospects

Since fresh foods include a significant amount of water, fat, and protein, it is more likely to become infected by microorganisms causing a major loss of quality. Traditional detection techniques are less able to meet customer expectations owing to the limitations of high cost, slow response time, and inability to permit dynamic monitoring. Intelligent non-destructive detection technologies have emerged in recent years, which offer the advantages of small size and fast response at low cost. However, dynamic monitoring of fresh food quality based on intelligent detection technologies on the consumer side has not been rigorously evaluated yet. This paper discussed the application of intelligent detection technologies based on the consumer side in the dynamic monitoring of fresh food freshness, microorganisms, food additives, and pesticide residues. Furthermore, the application of intelligent detection technologies combined with smartphones for quality monitoring and detection of fresh foods is evaluated. Moreover, the challenges and development trends of intelligent fresh food quality detection technologies are also discussed. Intelligent detection technologies based on the consumer side are designed to detect in real-time the quality of fresh food through visual color changes in combination with smartphones. This paper provides ideas and recommendations for the application of intelligent detection technologies based on the consumer side in food quality detection/monitoring and future research trends.

Effect of lipid oxidation on quality attributes and control technologies in dried aquatic animal products: a critical review

Aquatic animals are viewed as a good source of healthy lipids. Although drying is an effective method for the preservation of aquatic animal products (AAPs), the whole process is accompanied by lipid oxidation. This article reviews the main mechanism of lipid oxidation in the drying process. It also summarizes the effects of lipid oxidation on the quality of dried aquatic animal products (DAAPs), including nutrients, color, flavor, and hazard components, especially for those harmful aldehydes and heterocyclic amines. In addition, it concluded that moderate lipid oxidation contributes to improving the quality of products. Still, excessive lipid oxidation produces hazardous substances and induces health risks. Hence, to obtain high-quality DAAPs, some effective control technologies to promote/prevent lipid oxidation are introduced and deeply discussed, including salting, high-pressure processing, irradiation, non-thermal plasma technology, defatting treatments, antioxidants, and edible coating. A systematic review of the effect of lipid oxidation on quality attributes and control technologies in DAAPs is presented, and some perspectives are made for future research.