Novel Colloidal Food Ingredients: Protein Complexes and Conjugates

Literature Cited

1. Abdollahi K, Ince C, Condict L, Hung A, Kasapis S 2020. Combined spectroscopic and molecular docking study on the pH dependence of molecular interactions between β-lactoglobulin and ferulic acid. Food Hydrocoll. 101:105461
   [Google Scholar]
2. Aberkane L, Jasniewski J, Gaiani C, Hussain R, Scher J, Sanchez C. 2012. Structuration mechanism of β-lactoglobulin–acacia gum assemblies in presence of quercetin. Food Hydrocoll. 29:9–20
   [Google Scholar]
3. Ach D, Briançon S, Broze G, Puel F, Rivoire A et al. 2015. Formation of microcapsules by complex coacervation. Can. J. Chem. Eng. 93:183–91
   [Google Scholar]
4. Ajandouz EH, Tchiakpe LS, Ore FD, Benajiba A, Puigserver A. 2001. Effects of pH on caramelization and Maillard reaction kinetics in fructose-lysine model systems. J. Food Sci. 66:926–31
   [Google Scholar]
5. Avila Ruiz G, Xi B, Minor M, Sala G, van Boekel M et al. 2016. High-pressure–high-temperature processing reduces Maillard reaction and viscosity in whey protein–sugar solutions. J. Agric. Food Chem. 64:7208–15
   [Google Scholar]
6. Baba WN, McClements DJ, Maqsood S. 2021. Whey protein–polyphenol conjugates and complexes: production, characterization, and applications. Food Chem. 365:130455
   [Google Scholar]
7. Behrouzain F, Razavi SMA, Joyner H. 2020. Mechanisms of whey protein isolate interaction with basil seed gum: influence of pH and protein-polysaccharide ratio. Carbohydr. Polym. 232:115775
   [Google Scholar]
8. Brandao E, Silva MS, Garcia-Estevez I, Williams P, Mateus N et al. 2017. The role of wine polysaccharides on salivary protein-tannin interaction: a molecular approach. Carbohydr. Polym. 177:77–85
   [Google Scholar]
9. Buitimea-Cantua NE, Gutierrez-Uribe JA, Serna-Saldivar SO. 2018. Phenolic–protein interactions: effects on food properties and health benefits. J. Med. Food 21:188–98
   [Google Scholar]
10. Cao Y, Xiong YL, Cao Y, True AD. 2018. Interfacial properties of whey protein foams as influenced by preheating and phenolic binding at neutral pH. Food Hydrocoll. 82:379–87
    [Google Scholar]
11. Carnovale V, Britten M, Couillard C, Bazinet L. 2015. Impact of calcium on the interactions between epigallocatechin-3-gallate and β-lactoglobulin. Food Res. Int. 77:565–71
    [Google Scholar]
12. Carvalho E, Mateus N, Plet B, Pianet I, Dufourc E, de Freitas V. 2006. Influence of wine pectic polysaccharides on the interactions between condensed tannins and salivary proteins. J. Agric. Food Chem. 54:8936–44
    [Google Scholar]
13. Chao D, Aluko RE. 2018. Modification of the structural, emulsifying, and foaming properties of an isolated pea protein by thermal pretreatment. CyTA J. Food 16:357–66
    [Google Scholar]
14. Chen T, Embree HD, Wu LQ, Payne GF. 2002. In vitro protein-polysaccharide conjugation: tyrosinase-catalyzed conjugation of gelatin and chitosan. Biopolymers 64:292–302
    [Google Scholar]
15. Chen W, Ma X, Wang W, Lv R, Guo M et al. 2019. Preparation of modified whey protein isolate with gum acacia by ultrasound Maillard reaction. Food Hydrocoll. 95:298–307
    [Google Scholar]
16. Chen WZ, Ma SB, Wang QK, McClements DJ, Liu XB et al. 2021. Fortification of edible films with bioactive agents: a review of their formation, properties, and application in food preservation. Crit. Rev. Food Sci. Nutr. 62:185029–55
    [Google Scholar]
17. Chen Y, Ma M. 2020. Foam and conformational changes of egg white as affected by ultrasonic pretreatment and phenolic binding at neutral pH. Food Hydrocoll. 102:105568
    [Google Scholar]
18. Cheng H, Khan MA, Xie Z, Tao S, Li Y, Liang L. 2020. A peppermint oil emulsion stabilized by resveratrol-zein-pectin complex particles: enhancing the chemical stability and antimicrobial activity in combination with the synergistic effect. Food Hydrocoll. 103:105675
    [Google Scholar]
19. Cheng J, Zhu M, Liu X. 2020. Insight into the conformational and functional properties of myofibrillar protein modified by mulberry polyphenols. Food Chem. 308:125592
    [Google Scholar]
20. Condezo-Hoyos L, Gazi C, Perez-Jimenez J. 2021. Design of polyphenol-rich diets in clinical trials: a systematic review. Food Res. Int. 149:110655
    [Google Scholar]
21. da Silva CEP, de Oliveira MAS, Simas FF, Riegel-Vidotti IC. 2020. Physical chemical study of zein and arabinogalactans or glucuronomannans polyelectrolyte complexes and their film-forming properties. Food Hydrocoll. 100:105394
    [Google Scholar]
22. Dai T, Li T, Li R, Zhou H, Liu C et al. 2020. Utilization of plant-based protein-polyphenol complexes to form and stabilize emulsions: pea proteins and grape seed proanthocyanidins. Food Chem. 329:127219
    [Google Scholar]
23. Dai T, McClements DJ, Hu T, Chen J, He X et al. 2022. Improving foam performance using colloidal protein–polyphenol complexes: lactoferrin and tannic acid. Food Chem. 377:131950
    [Google Scholar]
24. de Freitas V, Carvalho E, Mateus N. 2003. Study of carbohydrate influence on protein–tannin aggregation by nephelometry. Food Chem. 81:503–9
    [Google Scholar]
25. de Morais FPR, Pessato TB, Rodrigues E, Peixoto Mallmann L, Mariutti LRB, Netto FM. 2020. Whey protein and phenolic compound complexation: effects on antioxidant capacity before and after in vitro digestion. Food Res. Int. 133:109104
    [Google Scholar]
26. de Oliveira FC, Coimbra JS, de Oliveira EB, Zuniga AD, Rojas EE. 2016. Food protein-polysaccharide conjugates obtained via the Maillard reaction: a review. Crit. Rev. Food Sci. Nutr. 56:1108–25
    [Google Scholar]
27. de Souza KC, Correa LG, da Silva TBV, Moreira TFM, de Oliveira A et al. 2020. Soy protein isolate films incorporated with Pinhão (Araucaria angustifolia (Bertol.) Kuntze) extract for potential use as edible oil active packaging. Food Bioprocess Technol. 13:998–1008
    [Google Scholar]
28. Dedhia N, Marathe SJ, Singhal RS. 2022. Food polysaccharides: a review on emerging microbial sources, bioactivities, nanoformulations and safety considerations. Carbohydr. Polym. 287:119355
    [Google Scholar]
29. Dickinson E. 2018. Hydrocolloids acting as emulsifying agents: How do they do it?. Food Hydrocoll. 78:2–14
    [Google Scholar]
30. Dufour C, Loonis M, Delosiere M, Buffiere C, Hafnaoui N et al. 2018. The matrix of fruit & vegetables modulates the gastrointestinal bioaccessibility of polyphenols and their impact on dietary protein digestibility. Food Chem. 240:314–22
    [Google Scholar]
31. Eratte D, Dowling K, Barrow CJ, Adhikari B. 2018. Recent advances in the microencapsulation of omega-3 oil and probiotic bacteria through complex coacervation: a review. Trends Food Sci. Technol. 71:121–31
    [Google Scholar]
32. Falsafi SR, Rostamabadi H, Samborska K, Mirarab S, Rashidinejhad A, Jafari SM. 2022. Protein-polysaccharide interactions for the fabrication of bioactive-loaded nanocarriers: chemical conjugates and physical complexes. Pharmacol. Res. 178:106164
    [Google Scholar]
33. Fang Z, Bhandari B. 2010. Encapsulation of polyphenols—a review. Trends Food Sci. Technol. 21:510–23
    [Google Scholar]
34. Feng T, Wang X, Wang X, Zhang X, Gu Y et al. 2021. High internal phase Pickering emulsions stabilized by pea protein isolate-high methoxyl pectin-EGCG complex: interfacial properties and microstructure. Food Chem. 350:129251
    [Google Scholar]
35. Fu D, Deng S, McClements DJ, Zhou L, Zou L et al. 2019. Encapsulation of β-carotene in wheat gluten nanoparticle-xanthan gum-stabilized Pickering emulsions: enhancement of carotenoid stability and bioaccessibility. Food Hydrocoll. 89:80–89
    [Google Scholar]
36. Ge A, Iqbal S, Chen XD. 2022. Alteration in rheology and microstructure of O/W emulsions using controlled soy protein isolate-polysaccharide aggregation in aqueous phases. J. Food Eng. 317:110872
    [Google Scholar]
37. Ge S, Jia R, Li Q, Liu W, Liu M et al. 2022a. Pickering emulsion stabilized by zein/adzuki bean seed coat polyphenol nanoparticles to enhance the stability and bioaccessibility of astaxanthin. J. Funct. Foods 88:104867
    [Google Scholar]
38. Ge S, Jia R, Liu W, Xie J, Liu M et al. 2022b. Lipid oxidation and in vitro digestion of Pickering emulsion based on zein-adzuki bean seed coat polyphenol covalent crosslinking nanoparticles. Food Chem. 386:132513
    [Google Scholar]
39. Geng JT, Takahashi K, Kaido T, Kasukawa M, Okazaki E, Osako K. 2019. Relationship among pH, generation of free amino acids, and Maillard browning of dried Japanese common squid Todarodes pacificus meat. Food Chem. 283:324–30
    [Google Scholar]
40. Gentile L. 2020. Protein–polysaccharide interactions and aggregates in food formulations. Curr. Opin. Colloid Interface Sci. 48:18–27
    [Google Scholar]
41. Girard AL, Awika JM. 2020. Effects of edible plant polyphenols on gluten protein functionality and potential applications of polyphenol-gluten interactions. Compr. Rev. Food Sci. Food Saf. 19:2164–99
    [Google Scholar]
42. Guo Y, Wei Y, Cai Z, Hou B, Zhang H. 2021. Stability of acidified milk drinks induced by various polysaccharide stabilizers: a review. Food Hydrocoll. 118:106814
    [Google Scholar]
43. Hajji S, Younes I, Affes S, Boufi S, Nasri M. 2018. Optimization of the formulation of chitosan edible coatings supplemented with carotenoproteins and their use for extending strawberries postharvest life. Food Hydrocoll. 83:375–92
    [Google Scholar]
44. Han L, Zhou S, Lu K, Zheng Y, Qi B, Li Y. 2022. Effects of inducer type and concentration on the formation mechanism of W/O/W double emulsion gels. Food Chem. 379:132166
    [Google Scholar]
45. Han Y, Yu M, Wang L. 2018. Preparation and characterization of antioxidant soy protein isolate films incorporating licorice residue extract. Food Hydrocoll. 75:13–21
    [Google Scholar]
46. Hao L, Sun J, Pei M, Zhang G, Li C et al. 2022. Impact of non-covalent bound polyphenols on conformational, functional properties and in vitro digestibility of pea protein. Food Chem. 383:132623
    [Google Scholar]
47. Hasni I, Bourassa P, Hamdani S, Samson G, Carpentier R, Tajmir-Riahi H-A. 2011. Interaction of milk α- and β-caseins with tea polyphenols. Food Chem. 126:630–39
    [Google Scholar]
48. He W, Xiao N, Zhao Y, Yao Y, Xu M et al. 2021. Effect of polysaccharides on the functional properties of egg white protein: a review. J. Food Sci. 86:656–66
    [Google Scholar]
49. He Z, Ma T, Zhang W, Su E, Cao F et al. 2021. Heat-induced gel formation by whey protein isolate-Lycium barbarum polysaccharides at varying pHs. Food Hydrocoll. 115:106607
    [Google Scholar]
50. Ho TM, Bhandari BR, Bansal N. 2021. Functionality of bovine milk proteins and other factors in foaming properties of milk: a review. Crit. Rev. Food Sci. Nutr. 62:174800–20
    [Google Scholar]
51. Hosseini A, Jafari SM, Mirzaei H, Asghari A, Akhavan S. 2015. Application of image processing to assess emulsion stability and emulsification properties of Arabic gum. Carbohydr. Polym. 126:1–8
    [Google Scholar]
52. Hu J, Zhao T, Li S, Wang Z, Wen C et al. 2019. Stability, microstructure, and digestibility of whey protein isolate–Tremella fuciformis polysaccharide complexes. Food Hydrocoll 89379–85
53. Hu Y, Tan Y, McClements DJ, Wang L. 2022. Fabrication, characterization and in vitro digestive behavior of Pickering emulsion incorporated with dextrin. Food Chem. 384:132528
    [Google Scholar]
54. Huang Z, Yang X, Liang S, Chen L, Dong L et al. 2022. Polysaccharides improved the viscoelasticity, microstructure, and physical stability of ovalbumin-ferulic acid complex stabilized emulsion. Int. J. Biol. Macromol. 211:150–58
    [Google Scholar]
55. Jamróz E, Tkaczewska J, Juszczak L, Zimowska M, Kawecka A et al. 2022. The influence of lingonberry extract on the properties of novel, double-layered biopolymer films based on furcellaran, CMC and a gelatin hydrolysate. Food Hydrocoll. 124:107334
    [Google Scholar]
56. Jansen-Alves C, Maia DSV, Krumreich FD, Crizel-Cardoso MM, Fioravante JB et al. 2019. Propolis microparticles produced with pea protein: characterization and evaluation of antioxidant and antimicrobial activities. Food Hydrocoll. 87:703–11
    [Google Scholar]
57. Jian W, Wang L, Wu L, Sun YM. 2018. Physicochemical properties of bovine serum albumin-glucose and bovine serum albumin-mannose conjugates prepared by pulsed electric fields treatment. Molecules 23:570
    [Google Scholar]
58. Jiang J, Zhang Z, Zhao J, Liu Y. 2018. The effect of non-covalent interaction of chlorogenic acid with whey protein and casein on physicochemical and radical-scavenging activity of in vitro protein digests. Food Chem. 268:334–41
    [Google Scholar]
59. Jiang L, Ren Y, Shen M, Zhang J, Yu Q et al. 2021. Effect of acid/alkali shifting on function, gelation properties, and microstructure of Mesona chinensis polysaccharide-whey protein isolate gels. Food Hydrocoll. 117:106699
    [Google Scholar]
60. Jiao B, Shi A, Liu H, Sheng X, Liu L et al. 2018. Effect of electrostatically charged and neutral polysaccharides on the rheological characteristics of peanut protein isolate after high-pressure homogenization. Food Hydrocoll. 77:329–35
    [Google Scholar]
61. Jiménez-Castaño L, Villamiel M, López-Fandiño R. 2007. Glycosylation of individual whey proteins by Maillard reaction using dextran of different molecular mass. Food Hydrocoll. 21:433–43
    [Google Scholar]
62. Jones OG, McClements DJ. 2011. Recent progress in biopolymer nanoparticle and microparticle formation by heat-treating electrostatic protein-polysaccharide complexes. Adv. Colloid Interface Sci. 167:49–62
    [Google Scholar]
63. Jung J, Wicker L. 2012. Laccase mediated conjugation of heat treated β-lactoglobulin and sugar beet pectin. Carbohydr. Polym. 89:1244–49
    [Google Scholar]
64. Kan X, Chen G, Zhou W, Zeng X. 2021. Application of protein-polysaccharide Maillard conjugates as emulsifiers: source, preparation and functional properties. Food Res. Int. 150:110740
    [Google Scholar]
65. Li C, Dai T, Chen J, Li X, Li T et al. 2021. Protein-polyphenol functional ingredients: the foaming properties of lactoferrin are enhanced by forming complexes with procyanidin. Food Chem. 339:128145
    [Google Scholar]
66. Li D, Wu G, Zhang H, Qi X. 2020. The soy protein isolate-octacosanol-polysaccharides nanocomplex for enhanced physical stability in neutral conditions: fabrication, characterization, thermal stability. Food Chem. 322:126638
    [Google Scholar]
67. Li G-Y, Chen Q-H, Su C-R, Wang H, He S et al. 2021. Soy protein-polysaccharide complex coacervate under physical treatment: effects of pH, ionic strength and polysaccharide type. Innov. Food Sci. Emerg. Technol. 68:102612
    [Google Scholar]
68. Li H, Wang T, Hu Y, Wu J, Van der Meeren P. 2022. Designing delivery systems for functional ingredients by protein/polysaccharide interactions. Trends Food Sci. Technol. 119:272–87
    [Google Scholar]
69. Li J, Wang X. 2015. Binding of (−)-epigallocatechin-3-gallate with thermally-induced bovine serum albumin/iota-carrageenan particles. Food Chem. 168:566–71
    [Google Scholar]
70. Li Q, Shi J, Li J, Liu L, Zhao T et al. 2021. Influence of thermal treatment on the physicochemical and functional properties of tea polysaccharide conjugates. LWT 150:111967
    [Google Scholar]
71. Li S, Sun J, Yan J, Zhang S, Shi C et al. 2021. Development of antibacterial nanoemulsions incorporating thyme oil: layer-by-layer self-assembly of whey protein isolate and chitosan hydrochloride. Food Chem. 339:128016
    [Google Scholar]
72. Li T, Hu P, Dai T, Li P, Ye X et al. 2018. Comparing the binding interaction between β-lactoglobulin and flavonoids with different structure by multi-spectroscopy analysis and molecular docking. Spectrochim. Acta A 201:197–206
    [Google Scholar]
73. Li T, Li X, Dai T, Hu P, Niu X et al. 2020. Binding mechanism and antioxidant capacity of selected phenolic acid–β-casein complexes. Food Res. Int. 129:108802
    [Google Scholar]
74. Li X, Fang Y, Al-Assaf S, Phillips GO, Yao X et al. 2012. Complexation of bovine serum albumin and sugar beet pectin: structural transitions and phase diagram. Langmuir 28:10164–76
    [Google Scholar]
75. Li X, Hua Y, Chen Y, Kong X, Zhang C. 2017. Two-step complex behavior between Bowman–Birk protease inhibitor and ι-carrageenan: effect of protein concentration, ionic strength and temperature. Food Hydrocoll. 62:1–9
    [Google Scholar]
76. Li X, Li S, Liang X, McClements DJ, Liu X, Liu F. 2020. Applications of oxidases in modification of food molecules and colloidal systems: laccase, peroxidase and tyrosinase. Trends Food Sci. Technol. 103:78–93
    [Google Scholar]
77. Li Y, He D, Li B, Lund MN, Xing Y et al. 2021. Engineering polyphenols with biological functions via polyphenol-protein interactions as additives for functional foods. Trends Food Sci. Technol. 110:470–82
    [Google Scholar]
78. Li Y, McClements DJ. 2011. Controlling lipid digestion by encapsulation of protein-stabilized lipid droplets within alginate–chitosan complex coacervates. Food Hydrocoll. 25:1025–33
    [Google Scholar]
79. Li Y, Zhong F, Ji W, Yokoyama W, Shoemaker CF et al. 2013. Functional properties of Maillard reaction products of rice protein hydrolysates with mono-, oligo- and polysaccharides. Food Hydrocoll. 30:53–60
    [Google Scholar]
80. Lin D, Kelly AL, Miao S. 2021. The role of mixing sequence in structuring O/W emulsions and emulsion gels produced by electrostatic protein-polysaccharide interactions between soy protein isolate-coated droplets and alginate molecules. Food Hydrocoll. 113:106537
    [Google Scholar]
81. Lin D, Kelly AL, Miao S. 2022. The impact of pH on mechanical properties, storage stability and digestion of alginate-based and soy protein isolate-stabilized emulsion gel beads with encapsulated lycopene. Food Chem. 372:131262
    [Google Scholar]
82. Lin T, Dadmohammadi Y, Davachi SM, Torabi H, Li P et al. 2022. Improvement of lactoferrin thermal stability by complex coacervation using soy soluble polysaccharides. Food Hydrocoll. 131:107736
    [Google Scholar]
83. Lin Y, Chen K, Tu D, Yu X, Dai Z, Shen Q. 2019. Characterization of dietary fiber from wheat bran (Triticum aestivum L.) and its effect on the digestion of surimi protein. LWT 102:106–12
    [Google Scholar]
84. Liu F, Liang X, Yan J, Zhao S, Li S et al. 2022. Tailoring the properties of double-crosslinked emulsion gels using structural design principles: physical characteristics, stability, and delivery of lycopene. Biomaterials 280:121265
    [Google Scholar]
85. Liu F, Ma C, Gao Y, McClements DJ. 2017a. Food-grade covalent complexes and their application as nutraceutical delivery systems: a review. Compr. Rev. Food Sci. Food Saf. 16:76–95
    [Google Scholar]
86. Liu F, Ma C, McClements DJ, Gao Y. 2016. Development of polyphenol-protein-polysaccharide ternary complexes as emulsifiers for nutraceutical emulsions: impact on formation, stability, and bioaccessibility of β-carotene emulsions. Food Hydrocoll. 61:578–88
    [Google Scholar]
87. Liu F, Ma C, McClements DJ, Gao Y. 2017b. A comparative study of covalent and non-covalent interactions between zein and polyphenols in ethanol-water solution. Food Hydrocoll. 63:625–34
    [Google Scholar]
88. Liu F, Ma C, Zhang R, Gao Y, McClements DJ. 2017c. Controlling the potential gastrointestinal fate of β-carotene emulsions using interfacial engineering: impact of coating lipid droplets with polyphenol-protein-carbohydrate conjugate. Food Chem. 221:395–403
    [Google Scholar]
89. Liu F, Sun C, Wang D, Yuan F, Gao Y. 2015. Glycosylation improves the functional characteristics of chlorogenic acid–lactoferrin conjugate. RSC Adv. 5:78215–28
    [Google Scholar]
90. Liu J, Chai J, Zhang T, Yuan Y, Saini RK et al. 2021. Phase behavior, thermodynamic and rheological properties of ovalbumin/dextran sulfate: effect of biopolymer ratio and salt concentration. Food Hydrocoll. 118:106777
    [Google Scholar]
91. Liu R, Yan X, Liu Z, McClements DJ, Liu F, Liu X. 2019. Fabrication and characterization of functional protein-polysaccharide-polyphenol complexes assembled from lactoferrin, hyaluronic acid and (−)-epigallocatechin gallate. Food Funct. 10:1098–108
    [Google Scholar]
92. Livney YD. 2010. Milk proteins as vehicles for bioactives. Curr. Opin. Colloid Interface Sci. 15:73–83
    [Google Scholar]
93. Lopes-da-Silva JA, Monteiro SR. 2019. Gelling and emulsifying properties of soy protein hydrolysates in the presence of a neutral polysaccharide. Food Chem. 294:216–23
    [Google Scholar]
94. Ma C, Jiang W, Chen G, Wang Q, McClements DJ et al. 2021. Sonochemical effects on formation and emulsifying properties of zein-gum Arabic complexes. Food Hydrocoll. 114:106557
    [Google Scholar]
95. Ma X, Chi C, Pu Y, Miao S, Liu D. 2022. Conjugation of soy protein isolate (SPI) with pectin: effects of structural modification of the grafting polysaccharide. Food Chem. 387:132876
    [Google Scholar]
96. Martinez-Alvarenga MS, Martinez-Rodriguez EY, Garcia-Amezquita LE, Olivas GI, Zamudio-Flores PB et al. 2014. Effect of Maillard reaction conditions on the degree of glycation and functional properties of whey protein isolate–maltodextrin conjugates. Food Hydrocoll. 38:110–18
    [Google Scholar]
97. Martins SIFS, Jongen WMF, van Boekel MAJS. 2000. A review of Maillard reaction in food and implications to kinetic modelling. Trends Food Sci. Technol. 11:364–73
    [Google Scholar]
98. Maryam Adilah ZA, Nur Hanani ZA. 2019. Storage stability of soy protein isolate films incorporated with mango kernel extract at different temperature. Food Hydrocoll. 87:541–49
    [Google Scholar]
99. McClements DJ. 2015. Encapsulation, protection, and release of hydrophilic active components: potential and limitations of colloidal delivery systems. Adv. Colloid Interface Sci. 219:27–53
    [Google Scholar]
100. Mihalca V, Kerezsi AD, Weber A, Gruber-Traub C, Schmucker J et al. 2021. Protein-based films and coatings for food industry applications. Polymers 13:5769
     [Google Scholar]
101. Motelica L, Ficai D, Ficai A, Oprea OC, Kaya DA, Andronescu E. 2020. Biodegradable antimicrobial food packaging: trends and perspectives. Foods 9:1438
     [Google Scholar]
102. Naczk M, Towsend M, Zadernowski R, Shahidi F. 2011. Protein-binding and antioxidant potential of phenolics of mangosteen fruit (Garcinia mangostana). Food Chem. 128:292–98
     [Google Scholar]
103. Nasrollahzadeh F, Varidi M, Koocheki A, Hadizadeh F. 2017. Effect of microwave and conventional heating on structural, functional and antioxidant properties of bovine serum albumin-maltodextrin conjugates through Maillard reaction. Food Res. Int. 100:289–97
     [Google Scholar]
104. Nikbakht Nasrabadi M, Goli SAH, Sedaghat Doost A, Van der Meeren P 2020. Characterization and enhanced functionality of nanoparticles based on linseed protein and linseed gum biocomplexes. Int. J. Biol. Macromol. 151:116–23
     [Google Scholar]
105. Oliver CM, Melton LD, Stanley RA. 2006. Creating proteins with novel functionality via the Maillard reaction: a review. Crit. Rev. Food Sci. Nutr. 46:337–50
     [Google Scholar]
106. Ozdal T, Capanoglu E, Altay F. 2013. A review on protein–phenolic interactions and associated changes. Food Res. Int. 51:954–70
     [Google Scholar]
107. Pan T, Wu Y, He S, Wu Z, Jin R 2022. Food allergenic protein conjugation with plant polyphenols for allergenicity reduction. Curr. Opin. Food Sci. 43:36–42
     [Google Scholar]
108. Peng LP, Tang CH. 2020. Outstanding antioxidant Pickering high internal phase emulsions by co-assembled polyphenol-soy β-conglycinin nanoparticles. Food Res. Int. 136:109509
     [Google Scholar]
109. Pham LB, Wang B, Zisu B, Adhikari B. 2019. Covalent modification of flaxseed protein isolate by phenolic compounds and the structure and functional properties of the adducts. Food Chem. 293:463–71
     [Google Scholar]
110. Poon W, Kingston BR, Ouyang B, Ngo W, Chan WCW. 2020. A framework for designing delivery systems. Nat. Nanotechnol. 15:819–29
     [Google Scholar]
111. Prigent SVE, Gruppen H, Visser AJ, van Koningsveld GA, de Jong GA, Voragen AG 2003. Effects of non-covalent interactions with 5-O-caffeoylquinic acid (chlorogenic acid) on the heat denaturation and solubility of globular proteins. J. Agric. Food Chem. 51:5088–95
     [Google Scholar]
112. Prigent SVE, Voragen AGJ, Visser AJWG, van Koningsveld GA, Gruppen H. 2007. Covalent interactions between proteins and oxidation products of caffeoylquinic acid (chlorogenic acid). J. Sci. Food Agric. 87:2502–10
     [Google Scholar]
113. Qin X-S, Gao QY, Luo ZG. 2021a. Enhancing the storage and gastrointestinal passage viability of probiotic powder (Lactobacillus plantarum) through encapsulation with Pickering high internal phase emulsions stabilized with WPI-EGCG covalent conjugate nanoparticles. Food Hydrocoll. 116:106658
     [Google Scholar]
114. Qin X-S, Luo Z-G, Li X-L. 2021b. An enhanced pH-sensitive carrier based on alginate-Ca-EDTA in a set-type W₁/O/W₂ double emulsion model stabilized with WPI-EGCG covalent conjugates for probiotics colon-targeted release. Food Hydrocoll. 113:106460
     [Google Scholar]
115. Qu W, Zhang X, Chen W, Wang Z, He R, Ma H. 2018. Effects of ultrasonic and graft treatments on grafting degree, structure, functionality, and digestibility of rapeseed protein isolate-dextran conjugates. Ultrason. Sonochem. 42:250–59
     [Google Scholar]
116. Quan TH, Benjakul S, Sae-leaw T, Balange AK, Maqsood S. 2019. Protein–polyphenol conjugates: antioxidant property, functionalities and their applications. Trends Food Sci. Technol. 91:507–17
     [Google Scholar]
117. Rambaran TF. 2022. A patent review of polyphenol nano-formulations and their commercialization. Trends Food Sci. Technol. 120:111–22
     [Google Scholar]
118. Rawel HM, Meidtner K, Kroll J. 2005. Binding of selected phenolic compounds to proteins. J. Agric. Food Chem. 53:4228–35
     [Google Scholar]
119. Santos MAS, Okuro PK, Fonseca LR, Cunha RL. 2022. Protein-based colloidal structures tailoring techno- and bio-functionality of emulsions. Food Hydrocoll. 125:107384
     [Google Scholar]
120. Sedaghat Doost A, Nikbakht Nasrabadi M, Wu J, A'Yun Q, Van der Meeren P 2019. Maillard conjugation as an approach to improve whey proteins functionality: a review of conventional and novel preparation techniques. Trends Food Sci. Technol. 91:1–11
     [Google Scholar]
121. Seyrek E, Dubin PL, Tribet C, Gamble EA. 2003. Ionic strength dependence of protein-polyelectrolyte interactions. Biomacromolecules 4:273–82
     [Google Scholar]
122. Shang J, Liao M, Jin R, Teng X, Li H et al. 2020. Molecular properties of Flammulina velutipes polysaccharide–whey protein isolate (WPI) complexes via noncovalent interactions. Foods 10:1
     [Google Scholar]
123. Shen Y, Hong S, Singh G, Koppel K, Li Y. 2022. Improving functional properties of pea protein through “green” modifications using enzymes and polysaccharides. Food Chem. 385:132687
     [Google Scholar]
124. Shen Y, Levin A, Kamada A, Toprakcioglu Z, Rodriguez-Garcia M et al. 2021. From protein building blocks to functional materials. ACS Nano 15:5819–37
     [Google Scholar]
125. Soares S, Mateus N, Freitas V. 2007. Interaction of different polyphenols with bovine serum albumin (BSA) and human salivary α-amylase (HSA) by fluorescence quenching. J. Agric. Food Chem. 55:6726–35
     [Google Scholar]
126. Soares SI, Goncalves RM, Fernandes I, Mateus N, de Freitas V. 2009. Mechanistic approach by which polysaccharides inhibit α-amylase/procyanidin aggregation. J. Agric. Food Chem. 57:4352–58
     [Google Scholar]
127. Souza CJF, Garcia-Rojas EE. 2017. Interpolymeric complexing between egg white proteins and xanthan gum: effect of salt and protein/polysaccharide ratio. Food Hydrocoll. 66:268–75
     [Google Scholar]
128. Spotti MJ, Martinez MJ, Pilosof AMR, Candioti M, Rubiolo AC, Carrara CR. 2014. Influence of Maillard conjugation on structural characteristics and rheological properties of whey protein/dextran systems. Food Hydrocoll. 39:223–30
     [Google Scholar]
129. Stone AK, Cheung L, Chang C, Nickerson MT. 2013. Formation and functionality of soluble and insoluble electrostatic complexes within mixtures of canola protein isolate and (κ-, ι- and λ-type) carrageenan. Food Res. Int. 54:195–202
     [Google Scholar]
130. Sun J, Liu T, Zhang F, Huang Y, Zhang Y, Xu B. 2022. Tea polyphenols on emulsifying and antioxidant properties of egg white protein at acidic and neutral pH conditions. LWT 153:112537
     [Google Scholar]
131. Sun X, Sarteshnizi RA, Udenigwe CC. 2022. Recent advances in protein–polyphenol interactions focusing on structural properties related to antioxidant activities. Curr. Opin. Food Sci. 45:100840
     [Google Scholar]
132. Tang C-H. 2021. Assembly of food proteins for nano-encapsulation and delivery of nutraceuticals (a mini-review). Food Hydrocoll. 117:106710
     [Google Scholar]
133. Tang MX, Zhu YD, Li D, Adhikari B, Wang LJ. 2019. Rheological, thermal and microstructural properties of casein/kappa-carrageenan mixed systems. LWT 113:108296
     [Google Scholar]
134. Wagoner T, Vardhanabhuti B, Foegeding EA. 2016. Designing whey protein–polysaccharide particles for colloidal stability. Annu. Rev. Food Sci. Technol. 7:93–116
     [Google Scholar]
135. Wang H, You S, Wang W, Zeng Y, Su R et al. 2022. Laccase-catalyzed soy protein and gallic acid complexation: effects on conformational structures and antioxidant activity. Food Chem. 375:131865
     [Google Scholar]
136. Wang PP, Wang WD, Chen C, Fu X, Liu RH. 2020. Effect of Fructus Mori. bioactive polysaccharide conjugation on improving functional and antioxidant activity of whey protein. Int. J. Biol. Macromol. 148:761–67
     [Google Scholar]
137. Wang Q, Chen W, Zhu W, McClements DJ, Liu X, Liu F. 2022. A review of multilayer and composite films and coatings for active biodegradable packaging. NPJ Sci. Food 6:18
     [Google Scholar]
138. Wang Q, Tang Y, Yang Y, Zhao J, Zhang Y et al. 2020. Interaction between wheat gliadin and quercetin under different pH conditions analyzed by multi-spectroscopy methods. Spectrochim. Acta. A 229:117937
     [Google Scholar]
139. Wang X, Ho CT, Huang Q. 2007. Investigation of adsorption behavior of (−)-epigallocatechin gallate on bovine serum albumin surface using quartz crystal microbalance with dissipation monitoring. J. Agric. Food Chem. 55:4987–92
     [Google Scholar]
140. Wang X, Zhang J, Lei F, Liang C, Yuan F, Gao Y. 2014. Covalent complexation and functional evaluation of (−)-epigallocatechin gallate and α-lactalbumin. Food Chem. 150:341–47
     [Google Scholar]
141. Wang Y, Xiong YL. 2021. Physicochemical and microstructural characterization of whey protein films formed with oxidized ferulic/tannic acids. Foods 10:1599
     [Google Scholar]
142. Warnakulasuriya SN, Nickerson MT. 2018. Review on plant protein-polysaccharide complex coacervation, and the functionality and applicability of formed complexes. J. Sci. Food Agric. 98:5559–71
     [Google Scholar]
143. Wei Z, Huang Q. 2019. Assembly of protein–polysaccharide complexes for delivery of bioactive ingredients: a perspective paper. J. Agric. Food Chem. 67:1344–52
     [Google Scholar]
144. Wijaya W, Patel AR, Setiowati AD, Van der Meeren P. 2017. Functional colloids from proteins and polysaccharides for food applications. Trends Food Sci. Technol. 68:56–69
     [Google Scholar]
145. Xiao YP, Qi PX, Wickham ED. 2018. Interactions, induced by heating, of whey protein isolate (WPI) with sugar beet pectin (SBP) in solution: comparisons with a dry-state Maillard reaction. Food Hydrocoll. 83:61–71
     [Google Scholar]
146. Xiong WF, Deng QC, Li J, Li B, Zhong QX. 2020. Ovalbumin-carboxymethylcellulose complex coacervates stabilized high internal phase emulsions: comparison of the effects of pH and polysaccharide charge density. Food Hydrocoll. 98:105282
     [Google Scholar]
147. Xiong WF, Ren C, Tian M, Yang XJ, Li J, Li B. 2017. Complex coacervation of ovalbumin-carboxymethylcellulose assessed by isothermal titration calorimeter and rheology: effect of ionic strength and charge density of polysaccharide. Food Hydrocoll. 73:41–50
     [Google Scholar]
148. Xu L, Gong Y, Gern JE, Ikeda S, Lucey JA. 2018. Glycation of whey protein with dextrans of different molar mass: effect on immunoglobulin E-binding capacity with blood sera obtained from patients with cow milk protein allergy. J. Dairy Sci. 101:6823–34
     [Google Scholar]
149. Xu QD, Yu ZL, Zeng WC. 2021. Structural and functional modifications of myofibrillar protein by natural phenolic compounds and their application in pork meatball. Food Res. Int. 148:110593
     [Google Scholar]
150. Xu X, Sun Q, McClements DJ. 2020. Effects of anionic polysaccharides on the digestion of fish oil-in-water emulsions stabilized by hydrolyzed rice glutelin. Food Res. Int. 127:108768
     [Google Scholar]
151. Xu Y, Han M, Huang M, Xu X. 2021. Enhanced heat stability and antioxidant activity of myofibrillar protein-dextran conjugate by the covalent adduction of polyphenols. Food Chem. 352:129376
     [Google Scholar]
152. Xue G, Ren D, Zhou C, Zheng H, Cao W et al. 2020. Comparative study on the functional properties of the pearl oyster (Pinctada martensii) protein isolates and its electrostatic complexes with three hydrophilic polysaccharides. Int. J. Food Prop. 23:1256–71
     [Google Scholar]
153. Yan SZ, Xie FY, Zhang S, Jiang LZ, Qi BK, Li Y. 2021. Effects of soybean protein isolate–polyphenol conjugate formation on the protein structure and emulsifying properties: protein–polyphenol emulsification performance in the presence of chitosan. Colloids Surf. A 609:125641
     [Google Scholar]
154. Yan WJ, Jia X, Zhang QP, Chen HT, Zhu QM, Yin LJ. 2021. Interpenetrating polymer network hydrogels of soy protein isolate and sugar beet pectin as a potential carrier for probiotics. Food Hydrocoll. 113:106453
     [Google Scholar]
155. Yan X, Zhao J, Zeng Z, Ma M, Xia J et al. 2022. Effects of preheat treatment and polyphenol grafting on the structural, emulsifying and rheological properties of protein isolate from Cinnamomum camphora seed kernel. Food Chem. 377:132044
     [Google Scholar]
156. Yan Y, Zhu QM, Diao CR, Wang J, Wu ZJ, Wang H. 2020. Enhanced physicochemical stability of lutein-enriched emulsions by polyphenol-protein-polysaccharide conjugates and fat-soluble antioxidant. Food Hydrocoll. 101:105447
     [Google Scholar]
157. Yang W, Deng C, Xu L, Jin W, Zeng J et al. 2020. Protein-neutral polysaccharide nano- and micro-biopolymer complexes fabricated by lactoferrin and oat β-glucan: structural characteristics and molecular interaction mechanisms. Food Res. Int. 132:109111
     [Google Scholar]
158. Yang W, Xu C, Liu F, Sun C, Yuan F, Gao Y. 2015. Fabrication mechanism and structural characteristics of the ternary aggregates by lactoferrin, pectin, and (−)-epigallocatechin gallate using multispectroscopic methods. J. Agric. Food Chem. 63:5046–54
     [Google Scholar]
159. Yang YX, Cui SW, Gong JH, Guo Q, Wang Q, Hua YF. 2015. A soy protein-polysaccharides Maillard reaction product enhanced the physical stability of oil-in-water emulsions containing citral. Food Hydrocoll. 48:155–64
     [Google Scholar]
160. Ye A. 2008. Complexation between milk proteins and polysaccharides via electrostatic interaction: principles and applications—a review. Int. J. Food Sci. Technol. 43:406–15
     [Google Scholar]
161. Yildiz G, Ding JZ, Andrade J, Engeseth NJ, Feng H. 2018. Effect of plant protein-polysaccharide complexes produced by mano-thermo-sonication and pH-shifting on the structure and stability of oil-in-water emulsions. Innov. Food Sci. Emerg. Technol. 47:317–25
     [Google Scholar]
162. Yu Y, Shen M, Song Q, Xie J. 2018. Biological activities and pharmaceutical applications of polysaccharide from natural resources: a review. Carbohydr. Polym. 183:91–101
     [Google Scholar]
163. Yuan S, Zhang Y, Liu J, Zhao Y, Tan L et al. 2019. Structure-affinity relationship of the binding of phenolic acids and their derivatives to bovine serum albumin. Food Chem. 278:77–83
     [Google Scholar]
164. Zembyla M, Murray BS, Radford SJ, Sarkar A. 2019. Water-in-oil Pickering emulsions stabilized by an interfacial complex of water-insoluble polyphenol crystals and protein. J. Colloid Interface Sci. 548:88–99
     [Google Scholar]
165. Zhang L, McClements DJ, Wei ZL, Wang GQ, Liu XB, Liu FG. 2020. Delivery of synergistic polyphenol combinations using biopolymer-based systems: advances in physicochemical properties, stability and bioavailability. Crit. Rev. Food Sci. Nutr. 60:2083–97
     [Google Scholar]
166. Zhang Q, Cheng Z, Wang Y, Fu L. 2021. Dietary protein-phenolic interactions: characterization, biochemical-physiological consequences, and potential food applications. Crit. Rev. Food Sci. Nutr. 61:3589–615
     [Google Scholar]
167. Zhang Q, Li L, Lan Q, Li M, Wu D et al. 2019. Protein glycosylation: a promising way to modify the functional properties and extend the application in food system. Crit. Rev. Food Sci. Nutr. 59:2506–33
     [Google Scholar]
168. Zhao M, Huang X, Zhang H, Zhang YZ, Ganzle M et al. 2020. Probiotic encapsulation in water-in-water emulsion via heteroprotein complex coacervation of type-A gelatin/sodium caseinate. Food Hydrocoll. 105:105790
     [Google Scholar]
169. Zhao T, Huang L, Luo D, Xie Y, Zhang Y et al. 2021. Fabrication and characterization of anchovy protein hydrolysates-polyphenol conjugates with stabilizing effects on fish oil emulsion. Food Chem. 351:129324
     [Google Scholar]
170. Zhao Y, Wang X, Li D, Tang HL, Yu DY et al. 2020. Effect of anionic polysaccharides on conformational changes and antioxidant properties of protein-polyphenol binary covalently-linked complexes. Process Biochem. 89:89–97
     [Google Scholar]