Maillard Reaction Products Research Articles

The inhibitory effect of Maillard reaction products on fish and chicken muscle oxidation

The inhibitory effect of Maillard reaction products on fish and chicken muscle oxidation

Contribution of pectin-degrading bacteria to the quality of cigar fermentation: an analysis based on microbial communities and physicochemical components

ObjectiveThis study aims to investigate the effects of pectin-degrading bacteria on the microbial community and physicochemical properties during the fermentation process of cigar tobacco, evaluating its potential in reducing green bitterness and enhancing aroma.MethodsBy isolating and screening pectin-degrading bacteria, high-throughput sequencing and physicochemical analysis were employed to compare the microbial flora and physicochemical component differences in different treatment groups of cigar tobacco. Furthermore, correlation analysis was performed to examine the relationships between these variables.ResultsThe results showed that the strains YX-2 and DM-3, isolated from the cigar tobacco variety “Yunxue No. 1,” exhibited strong pectin-degrading abilities. Phylogenetic analysis revealed that strain YX-2 is highly homologous to Bacillus flexus, while strain DM-3 is highly homologous to Bacillus siamensis. After fermentation, the addition of strains YX-2 and DM-3 significantly reduced the pectin content in the tobacco leaves, increased the total sugar and reducing sugar content, reduced green bitterness, and markedly enhanced the total aroma components. Notably, DM-3 exhibited outstanding performance in the production of Maillard reaction products. Microbial community analysis showed that the addition of pectin-degrading bacteria significantly increased the diversity of both bacteria and fungi, especially in the TDM3 group, where the relative abundance of Pseudomonas was notably elevated. Correlation analysis revealed that Pseudomonas had a significant positive correlation with both reducing sugar and total sugar, and a significant negative correlation with pectin, indicating its important role in sugar metabolism and pectin degradation. Additionally, fungal genera such as Cercospora were significantly negatively correlated with total sugar and total nitrogen, while Eurotium was closely associated with pectin degradation and reducing sugar accumulation.ConclusionThis study found that the addition of Pectin-degrading bacteria YX-2 and DM-3 significantly optimized the microbial community structure during the cigar tobacco fermentation process and improved the physicochemical properties of the tobacco leaves, with notable effects in reducing green bitterness and enhancing aroma.

Effect of Perilla Seeds Pretreatment on the Volatile Profile and Flavor Characteristics of Perilla Oil: Comparison of Oven, Infrared, and Microwave Heating

ABSTRACTThe effects of microwave (MW), infrared (IF), and oven heating (OH) on the volatile profile and flavor of perilla oil were investigated in this study. Physicochemical properties and Maillard reaction products of perilla oil were measured to investigate the potential pathway of flavor formation. Sensory evaluation, combined with headspace‐solid‐phase microextraction‐gas chromatography‐mass spectrometry (HS‐SPME‐GC‐MS) and electronic nose (E‐nose) techniques, was employed to determine the categories and contents of volatile compounds in perilla oil. Three heating treatments all effectively increased the content of odor‐active volatile compounds in perilla oil. Samples treated by MW contained higher concentration of heterocyclics, while samples treated using IF and OH contained more aldehydes. The content of (E,E)‐2,4‐heptadienal were highly correlated to P‐AV. The contents of pyrazines and furans were positively correlated with A420nm, particularly 2,5‐dimethyl‐pyrazine, trimethyl‐pyrazine, and 2‐pentylfuran. The content of hexanal and (E)‐2‐hexenal showed a negative correlation with the content of heterocyclic compounds. Consequently, the volatile compounds in perilla oils were generated through three potential mechanisms: lipid oxidation, the Maillard reaction, and their synergistic effect.

Research Progress of Maillard Reaction and its Application in Processing of Traditional Chinese Medicine

The Maillard reaction, also known as the ‘non-enzymatic browning reaction’, involves a reaction between reducing sugars and amino compounds, including amino acids and proteins. The Maillard reaction has been increasingly used in the production of traditional Chinese medicine and food. This study thoroughly examines the mechanism of the reaction, the factors that influence it and the techniques used for extracting, separating and purifying Maillard reaction products (MRPs) in food and Chinese medicine processing. Additionally, the article explores the physiological functions of MRPs, highlighting their antioxidant, hepato-protective, antibacterial, immune-boosting, anti-mutagenic, anti-inflammatory, health-promoting, detoxifying and antiviral effects. MRPs have diverse outcomes because of various influencing factors; they can contain trace amounts of potentially harmful constituents, such as acrylamide, 5-hydroxymethylfurfural and advanced glycosylation products. The study also includes a comparative analysis of common methods used for the separation and purification of concentrated MRPs. These methods consist of ultrafiltration, macroporous resin, gel chromatography, ion exchange chromatography and dialysis. Results indicate that each method has advantages and disadvantages, and thus careful consideration should be placed on specific applications. Furthermore, a future outlook for the research and development of Maillard reaction and its products is proposed. Given that the physiological activities of MRPs are diverse, thorough qualitative and quantitative analysis of the reaction mechanisms, influencing factors and pharmacologically active ingredients is needed. This study offers valuable insights into the advancement of MRPs for industries involved in food and traditional Chinese medicinal material processing. These insights can be effectively utilised in healthcare and clinical practice, offering innovative ideas for scientific and technological professionals involved in research and development.

Multi-frequency power ultrasound (MFPU) pretreatment of crayfish (Procambarus clarkii): Effect on the enzymatic hydrolysis process and subsequent Maillard reaction

Crayfish, as a new consumer trend, has become one of the most popular freshwater aquatic foods in China, and its processed product output has been increasing year by year. In this study, the effect of multi-frequency power ultrasound (MFPU) pretreatment in various working modes including mono-, dual- and tri-frequency on the enzymatic hydrolysis and Maillard reaction of crayfish was investigated. Additionally, the underlying mechanism was also explored. Results showed that the degree of hydrolysis (DH) of crayfish was 23.89 %, while it increased to 40.78 % after MFPU pretreatment at 20/40 kHz dual-frequency, indicating that MFPU pretreatment significantly (p < 0.05) enhanced the enzymatic hydrolysis of crayfish. The crayfish protein after MFPU pretreatment exhibited a decrease in α-helix and increase in β-fold content, and the occurrence in the unfolding of the protein structure and alteration of tertiary structure. According to scanning electron microscopy (SEM) and atomic force microscopy (AFM) analyses, the MFPU pretreatment resulted in the fragmentation of crayfish protein. During the analyses of subsequent Maillard reaction, the composition and quantity of volatiles detected by the electronic nose and GC–MS indicated that MFPU pretreatment enhanced flavor of the Maillard reaction products. In conclusion, MFPU pretreatment is a promising technology for improving the degree of hydrolysis of crayfish protein and enhancing the flavor of Maillard reaction products.

Antibacterial activity and preservative effect for pork tenderloin of chitosan -glucosamine Maillard reaction products prepared by gamma irradiation

Antibacterial activity and preservative effect for pork tenderloin of chitosan -glucosamine Maillard reaction products prepared by gamma irradiation

Innovative process for improving functional and sensory quality of black garlic

Black garlic (BG) is an aged product high in brown melanoidin pigment and functional quality, however, the long aging process limits its commercial production. The present investigation was undertaken to develop an innovative process for improving the functional quality of BG as well as shortening the aging duration. Peeled garlic was subjected to two pre-treatment steps viz. Freeze-thaw (FT) and blanching (BL) followed by ascorbic acid (AA) infusion and effects were monitored during aging. Non-enzymatic browning, the main visible indicator of MR was significantly (p < 0.05) high in FT garlic due to high infused AA content. The pre-treated garlic showed significantly (p< 0.05) high fructose content (6-7-fold) over the control on the 6th day of aging. The treatment also enhanced the total phenolic content (2.5–3.0-fold) and antioxidant activity (14-fold) while reducing the processing time from 18 to 12 days. The soluble solid content (58.7 °B) and Fast index (fluorescent of advanced Maillard reaction products and soluble tryptophan) was maximum (305.2) in FT garlic on the 12th day. FTIR confirmed a strong peak at 1515 cm−1 depicting the dark nature of the BG subjected to FT. The innovative short process saved 50% of energy in production and was 43% more economical compared to its control counterpart. Overall sensory quality of FT garlic in terms of color, flavour and texture was on par with control except BL sample which showed high stickiness and low score values. Overall results suggest that FT treatment followed by infusion of ascorbic acid accelerated the Maillard reaction (MR), and improved the functional quality of BG.

Screening of Antioxidant Maillard Reaction Products Using HPLC-HRMS and Study of Reaction Conditions for Their Production as Food Preservatives

The Maillard reaction (MR) involves interactions between reducing sugars and amino acids or proteins during heating, producing Maillard reaction products (MRPs) that influence food flavour, aroma, and colour. Some MRPs exhibit antioxidant properties, prompting interest in their potential as natural food preservatives. This study aimed to develop a method for detecting and identifying antioxidant MRPs using high-pressure liquid chromatography (HPLC) coupled with high-resolution mass spectrometry (HRMS). By improving chromatographic conditions, the separation of antioxidant MRPs was optimised using known antioxidant MRPs as reference signals. This work also examined the effects of pH, reaction time, and different sugar–amino acid combinations on the production and composition of antioxidant MRPs. Results indicated that neutral to basic pH facilitated faster reactions, with pH 7 selected as optimal. A library of 50 m/z signals for potential antioxidant MRPs was created, and the best combinations of amino acids and sugars for their production were identified. These findings pave the way for more precise analyses of antioxidant MRPs, with future research focusing on isolating and characterising specific MRPs to understand their structures and mechanisms, ultimately contributing to the development of functional foods with natural antioxidant properties.

Effect of protease reaction conditions on volatile compounds generated in Maillard reaction products from soy protein hydrolysates

Maillard reaction products (MRPs) produced by heating protease-catalyzed soy protein hydrolysates (SPHs) with cysteine and ribose can generate meat-like flavors. However, the impact of protease reaction conditions on the volatile compound composition of MRPs has not been thoroughly investigated. In this study, seven SPHs were prepared using two proteases, flavourzyme and trypsin, over reaction times of 10, 120, and 1440 min. The volatile compound compositions, including sulfur-containing compounds, aldehydes, pyrazines, and furans, of the seven SPHs and the corresponding seven MRPs varied according to the protease reaction conditions and the Maillard reaction. Differences in pH, free amino acid composition, and peptide composition were responsible for these variations. Notably, soy-derived peptides containing unique cysteine sequences, such as PGCPST, DETICT, ECQIQK, and HCQR, were significantly reduced during the Maillard reaction, suggesting that these sequences may serve as precursors to volatile compounds.

Kinetic modelling of Maillard reaction products and protein content during roasting of coffee beans

In this study, the effects of various roasting methods on the α–dicarbonyl compounds (α-DCs), melanoidins, crude proteins, and colour value of roasted coffee beans (Coffea arabica) were analysed. The concentration of α-DCs in the coffee samples significantly changed (p < 0.05) during roasting, while that of melanoidins increased with roasting time in all roasting methods regardless of temperature. Crude protein decreased as roasting time increased. Through kinetic modelling, pan roasting was found to increase the rate constant of α-DCs, melanoidins, and crude proteins by up to 62.6%, 9.3%, and 33.3%, respectively. Air frying was observed to decrease the activation energy of α-DCs, melanoidins, and crude proteins by up to 57.8%, 22.3%, and 12.6%, respectively. The pan roasting method was shown to minimise α-DCs by up to 15% during medium roasting of coffee beans.

Effect of ultrasound-assisted Maillard reaction on functional properties and flavor characteristics of Oyster protein enzymatic hydrolysates

To address the delamination phenomenon during storage and flavor characteristics of Oyster protein hydrolysates (OPH). In this study, xylo-oligosaccharides (XOS) were selected to covalently graft with OPH through ultrasound-assisted Maillard reaction, and the effect of ultrasound-assisted Maillard reaction on the structure, functional properties, and flavor characteristics of OPH were investigated. The results revealed that the ultrasound treatment led to a 1.46-fold increase in the degree of grafting compared with the conventional wet-heat Maillard reaction methods. Structural analyses at various levels indicated substantial alterations in the OPH structure following the ultrasound-assisted Maillard reaction. More ordered α-helical secondary structures were shifting to random coiling, the tertiary structure showed more stretching changes, and the surface structure was characterized by loose and porous features. Compared with OPH, the solubility of the ultrasound-assisted Maillard reaction products (OPH-U-M) increased from 54.67% to 70.14%, leading to a notable enhancement in storage stability. Flavor profile analysis demonstrated a decrease in unsaturated aldehydes and ketones presenting fishy and bitter aromas, while an increase in presenting meat aroma compounds was observed in OPH-U-M. Furthermore, OPH-U-M exhibited superior antioxidant properties with DPPH and ABTS radical scavenging abilities enhancing 46.05% and 42.09% in comparison with OPH, respectively. The results demonstrated that covalently binding with XOS under ultrasonication pretreatment endowed OPH with superior functional properties (including solubility, storage stability, and antioxidant activity), and the improvement of flavor profile. This study can provide theoretical guidance and practical implications for promoting the processing applications of oyster protein.

Maillard reacted wheat gluten and polydextrose complex enhances the emulsifying properties and stability of Pickering emulsion

This study aims to explore the characteristics and stability of Pickering emulsion based on the Maillard reaction products of polydextrose (PDX) and gluten. The effects of the PDX:gluten ratio (from 0.0:1 P0.0G1 to 2.4:1 P2.4G1) during Maillard reaction on Pickering emulsion quality were examined. The degree of PDX grafting to gluten increased from 0.51%±0.05% to 18.99%±0.98% when the PDX:gluten ratio increased from 0.2:1 to 2.2:1. Scanning electron microscopy and infrared spectroscopy confirmed the structural change and covalent interaction of PDX–gluten conjugate. The P2.2G1 conjugate showed a higher emulsification activity (1.82±0.04 m2/g) compared with P0.0G1 (0.97±0.05 m2/g). The particle size, ζ-potential value and confocal laser scanning microscopic image of PDX–gluten conjugate-based emulsion were compared with those of gluten-based emulsion to illustrate the stability role of PDX–gluten conjugate in the interfacial layer of Pickering emulsion. This study demonstrated that the Maillard reacted gluten–PDX conjugate was a potential stabilizer for Pickering emulsions. These findings provided a foundation knowledge for the construction of Pickering emulsion based on PDX–gluten conjugates.

Maillard reaction products inhibit lipid oxidation by regulating myoglobin stability in washed muscle model.

Lipid oxidation significantly contributes to muscle deterioration, with heme protein oxidation playing a crucial role in this process. This study investigated the inhibition of heme protein oxidation by Maillard reaction products (MRPs) using a washed muscle model combining washed carp with myoglobin (Mb). Protein oxidation products, protein texture, and lipid oxidation levels were assessed. Results showed that metmyoglobin (MetMb) is a primary driver of lipid oxidation in meat, likely due to Mb oxidation, exposing hydrophobic groups that bind to lipids. MRPs at concentrations of 0.5% and 1% effectively inhibited Mb oxidation. Specifically, treatment with 1% MRPs reduced MetMb formation by 15.38%, protein carbonyl content by 6.53%, hydroxyl radical content by 20.37%, protein aggregation by 40.81%, and particle size by 36.95% during later storage stages, thereby preserving Mb stability. In the Mb-mediated oxidation model, 1% MRPs inhibited the formation of primary and secondary oxidative metabolites by 59.47% and 68.19%, respectively, while maintaining muscle tissue texture integrity. PRACTICAL APPLICATION: The antioxidation of Maillard reaction products (MRPs) improves the stability of common carp. By inhibiting the autoxidation of myoglobin and lipid, MRPs help preserve the texture and color of fish muscle while extending its shelf life. This study provides a valuable reference for effectively controlling lipid oxidation in refrigerated fish products and enhancing their overall quality.

Effect of tea polyphenols on the formation of advanced glycation end products (AGEs), functional and structural properties of modified protein in Maillard reaction

To improve the solubility and processing properties of gluten protein, Maillard reaction at three temperatures (70 °C, 100 °C and 130 °C) was used to modified gluten, and the effect of tea polyphenols (TPs) on the functional and structural properties of Maillard reaction products (MRPs) were investigated. The results showed that higher temperature and TPs increased significantly (p < 0.05) the antioxidant activity of MRPs and the order was ABTS > TRC > DPPH, which maxima were 72.5%, 61.5% and 44.3%, respectively, when the TPs addition was 0.3 g/100 mL at 130 °C. After undergoing thermal treatment, significant increase of foamability and emulsifying stability was observed, while the foam stability and emulsifying activity decreased with the addition of TPs. TPs altered the maximum UV absorption value and caused a red-shift for MRPs. Additionally, the reduced fluorescence intensity indicated that TPs decreased the amount of Maillard reaction intermediates as well as AGEs. Furthermore, 0.3 g TP/100 mL significantly increased (p < 0.05) hydrophobicity with maximum of 48.6%, while β-sheet content decreased from 45.7% to 40.4% compared to the control. The Maillard reaction improved the processing properties of gluten protein, and TPs effectively inhibited the production of AGEs and 5-hydroxymethylfurfural.

Changes in the flavor formation and sensory attributes of Maillard reaction products by different oxidation degrees of beef tallow via cold plasma

It remains unclear how the oxidation degree of animal fat affects the flavor formation and sensory attributes of Maillard reaction products (MRPs). To oxidize beef tallow differentially under mild conditions, an atmospheric pressure cold plasma (APCP) was applied due to its easy, economical, and controllable manipulation and effectiveness. As the duration of APCP increased after 10 min, the oxidation degree of beef tallow increased significantly (p < 0.05). The beef tallow was incorporated into the cysteine-xylose model system and heated at 120 °C for 90 min. Volatiles from lipid oxidation products increased, whereas sulfur-containing compounds decreased significantly when the model included APCP-treated beef tallow (p < 0.05). MRPs with 10-min APCP-treated beef tallow showed reduced off-odor (p < 0.05). Thus, moderate APCP treatment to beef tallow may be beneficial for sensory attributes of MRPs. It suggests the potential of APCP to improve the flavor of heat-sensitive foods by controlling lipid oxidation.

Integrated HS-SPME-GC–MS and UHPLC-O-TOF-MS-based metabolomics revealed the characteristics flavor and nonvolatile metabolites during the hydrolysis process of Boletus edulis

This research aimed to investigate the flavor characteristic, metabolites and bioactivities of Boletus edulis hydrolysates via HS-SPME-GC-MS and UHPLC-MS/MS. The Maillard reaction (MR) significantly enhanced the sensory qualities of Boletus edulis, including like-meat, caramel, continuity, and complete acceptance. The accumulation of browning precursors during MR was verified through spectral analysis. We also found that the MR enhanced the antioxidant and hypoglycemic activities of Boletus edulis hydrolysates. Furthermore, 11 VOCs were also identified as key aromatic compounds and had important impact on the flavor characteristics of Maillard reaction products (MRPs). Non-targeted metabolomics analyses revealed that the formation of MRPs was affected through amino acid metabolism, lipid metabolism and plant secondary metabolism. Briefly, the flavor and biological activity of Boletus edulis were improved through enzymolysis and MR. The results provided a theoretical foundation for deep processing and resource utilization of Boletus edulis.

Electro-activation for efficient lactulose production: The impact of operational parameters, electrolyte types, and environmental conditions

The electro-activation (EA) process has been employed to convert lactose into lactulose, a potent prebiotic with numerous health benefits. The study identified optimal conditions for lactulose production, including a specific current density, the use of calcium chloride as an efficient electrolyte, and the superiority of a steel cathode over a graphite cathode. The formation of intermediates other than lactulose increased as the temperature increased. The changes in pH and oxidation-reduction potential during the isomerization process were observed, highlighting their vital role in the formation of an ideal alkaline environment for lactulose production. The resultant solution produced by the EA process has significant antioxidant characteristics, likely due to the formation of Maillard Reaction Products during lactulose production. In conclusion, the EA system, with optimal operating conditions, is an energy-efficient, reagent-free, and environmentally friendly alternative for lactulose production.

Spatial distribution of antioxidant activity in baguette and its modulation of proinflammatory cytokines in RAW264.7 macrophages

Baguette is a globally acclaimed bakery staple, composed by a crispy crust and soft crumb, both containing Maillard reaction products (MRPs) with potential bioactivities. However, MRPs’ impacts on the nutritional and health attributes of baguette, particularly in terms of cellular and biological functions, are yet to be clearly elucidated. This study chemically characterizes the crust and crumb of baguettes and investigates the influence of the Maillard reaction on baguette’s nutritional profile, especially in the antioxidant and anti-inflammatory effects. The findings indicate an increase in browning intensity and advanced glycation end products (AGEs) from the baguette’s interior to its exterior, alongside a significant rise in the antioxidant capacity of the crust, suggesting the Maillard reaction’s role in boosting antioxidative properties. Both the crust and crumb demonstrated strong cytocompatibility with immune cells, capable of reducing cellular oxidative stress and regulating intracellular free radical levels. The crust effectively countered peroxyl radical-induced cell membrane hyperpolarization by 91% and completely neutralized the suppression of oxygen respiration in mitochondria, displaying higher efficacy than the crumb. In contrast, crumb extracts were more potent in inhibiting lipopolysaccharide-induced expression of proinflammatory cytokines, such as interleukins-1β (IL-1β) and IL-6, in macrophages. It could provide the fundamental data and cell-based approach for investigating the biological impacts of bread on immune responses, contributing to the refinement and supplementation of nutritional recommendations.

Sensorial flavor characteristics and volatile Maillard reaction products of Tenebrio molitor mealworm based-reaction flavors with beef broth-like flavor

Sensorial flavor characteristics and volatile Maillard reaction products of Tenebrio molitor mealworm based-reaction flavors with beef broth-like flavor

Maillard reaction affecting immunobinding activity and digestibility of tropomyosin in Alectryonella plicatula food matrix

In recent years, the allergy rate of oysters has surged, and daily food processing methods make it hard to reduce heat resistance and digestive allergy such as tropomyosin (TM). In this study, the Maillard reaction with xylose (Xyl) significantly reduced the IgE binding capacity of Alectryonella plicatula food matrix (AFM), that reduced by (77.81 ± 2.68)%. The study found the Maillard reaction changes the structure of the AFM, in which the content of α-helix decreased by (24.64 ± 1.46)%. Structural transformation further explains why the Maillard reaction alters the immunobinding activity of AFM. In addition, the Maillard reaction reduces the digestive stability of the AFM and makes TM in the A. plicatula food matrix Maillard reaction products (AFM-MRPs) more easily digested. Based on the above research, 10 amino acids on the 7 IgE epitopes of TM were modified. This result indicates that the Maillard reaction reduces the immunobinding activity of the AFM by changing the structure and modifying the amino acids on the epitope.