High Internal Phase Emulsions of Algae Oil Based on Rapeseed Protein via Salt Extraction Combined With Ultrafiltration

Jiyang Cai , Yuqi Mei , Yunyi Yang , Suqiong Fang , Wenrong Chen , Tao Yang , Zhili Wan , Xiaoquan Yang

Food Bioengineering ›› 2024, Vol. 3 ›› Issue (4) : 425 -437.

PDF
Food Bioengineering ›› 2024, Vol. 3 ›› Issue (4) : 425 -437. DOI: 10.1002/fbe2.12109
RESEARCH ARTICLE

High Internal Phase Emulsions of Algae Oil Based on Rapeseed Protein via Salt Extraction Combined With Ultrafiltration

Author information +
History +
PDF

Abstract

Rapeseed protein, as a valuable plant protein, holds great potential as a natural emulsifier for construction of food-grade high internal phase emulsions (HIPEs). In this work, rapeseed protein, obtained through salt extraction combined with ultrafiltration, was employed as a sole stabilizer to formulate algae oil-based HIPEs. The effects of protein concentration and pH changes on the physicochemical properties of HIPEs are systematically evaluated. The results show that a protein concentration of 0.5 wt% is sufficient to form stable and self-supporting HIPEs. As the protein concentration increases, the droplet size of HIPEs gradually decreases, leading to a more robust structure and enhanced stability. Compared to neutral conditions (pH 7.0), the HIPEs under acidic pH 3.5 exhibit more densely packed emulsion droplets with smaller size and more uniform distribution, contributing to superior mechanical properties (higher G′ and yield stress) as well as preferable thixotropic and creep recovery behaviors, which thereby improve their physical stability during storage, thermal processing, and freeze-thaw cycles. Furthermore, the rapeseed protein-stabilized HIPEs inhibit the oxidation of algae oil, especially at pH 3.5. The results of oral lubrication indicate that the reduction in the friction coefficient is mainly associated with an increase in protein concentration, with minor effect from pH variation. These findings suggest that rapeseed protein is an effective emulsifier for preparing stable and processable HIPEs, especially under acidic conditions, which have great potential for applications in semi-solid emulsion foods or edible oil structuring.

Keywords

high internal phase emulsions / natural emulsifier / rapeseed protein / salt extraction / ultrafiltration

Cite this article

Download citation ▾
Jiyang Cai, Yuqi Mei, Yunyi Yang, Suqiong Fang, Wenrong Chen, Tao Yang, Zhili Wan, Xiaoquan Yang. High Internal Phase Emulsions of Algae Oil Based on Rapeseed Protein via Salt Extraction Combined With Ultrafiltration. Food Bioengineering, 2024, 3(4): 425-437 DOI:10.1002/fbe2.12109

登录浏览全文

4963

注册一个新账户 忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within
[1]

Aluko, R., and T. Mcintosh. 2005. “Limited Enzymatic Proteolysis Increases the Level of Incorporation of Canola Proteins Into Mayonnaise.” Innovative Food Science & Emerging Technologies 6: 195–202.
[2]

Bailey, H. M., N. S. Fanelli, and H. H. Stein. 2023. “Effect of Heat Treatment on Protein Quality of Rapeseed Protein Isolate Compared With Non-Heated Rapeseed Isolate, Soy and Whey Protein Isolates, and Rice and Pea Protein Concentrates.” Journal of the Science of Food and Agriculture 103: 7251–7259.
[3]

Cameron, N., and D. Sherrington. 2005. “High Internal Phase Emulsions (HIPEs)—Structure, Properties and Use in Polymer Preparation.” Biopolymers Liquid Crystalline Polymers Phase Emulsion: 163–214. https://doi.org/10.1007/3-540-60484-74.
[4]

Chen, Q., X. Cao, H. Liu, W. Zhou, L. Qin, and Z. An. 2013. “pH-Responsive High Internal Phase Emulsions Stabilized by Core Cross-Linked Star (CCS) Polymers.” Polymer Chemistry 4: 4092–4102.
[5]

Chmielewska, A., M. Kozłowska, D. Rachwał, et al. 2021. “Canola/Rapeseed Protein–Nutritional Value, Functionality and Food Application: A Review.” Critical Reviews in Food Science and Nutrition 61: 3836–3856.
[6]

Degner, B. M., C. Chung, V. Schlegel, R. Hutkins, and D. J. Mcclements. 2014. “Factors Influencing theFreeze-Thaw Stability of Emulsion-Based Foods.” Comprehensive Reviews in Food Science and Food Safety 13: 98–113.
[7]

Guzey, D., and D. J. Mcclements. 2006. “Formation, Stability and Properties of Multilayer Emulsions for Application in the Food Industry.” Advances in Colloid and Interface Science 128-130: 227–248.
[8]

Huang, Z.-X., W.-F. Lin, Y. Zhang, and C.-H. Tang. 2022. “Freeze-Thaw-Stable High Internal Phase Emulsions Stabilized by Soy Protein Isolate and Chitosan Complexes at pH 3.0 as Promising Mayonnaise Replacers.” Food Research International 156: 111309.
[9]

Ikem, V. O., A. Menner, and A. Bismarck. 2008. “High Internal Phase Emulsions Stabilized Solely by Functionalized Silica Particles.” Angewandte Chemie International Edition 47: 8277–8279.
[10]

Li, Q., Q. He, M. Xu, et al. 2020. “Food-Grade Emulsions and Emulsion Gels Prepared by Soy Protein–Pectin Complex Nanoparticles and Glycyrrhizic Acid Nanofibrils.” Journal of Agricultural and Food Chemistry 68: 1051–1063.
[11]

Li, Q., M. Xu, J. Xie, et al. 2021. “Large Amplitude Oscillatory Shear (LAOS) for Nonlinear Rheological Behavior of Heterogeneous Emulsion Gels Made From Natural Supramolecular Gelators.” Food Research International 140: 110076.
[12]

Li, X., X. Xu, L. Song, et al. 2020. “High Internal Phase Emulsion for Food-Grade 3D Printing Materials.” ACS Applied Materials & Interfaces 12: 45493–45503.
[13]

Liu, K., Y. Tian, M. Stieger, E. Van Der Linden, and F. Van De Velde. 2016. “Evidence for Ball-Bearing Mechanism of Microparticulated Whey Protein as Fat Replacer in Liquid and Semi-Solid Multi-Component Model Foods.” Food Hydrocolloids 52: 403–414.
[14]

Liu, W., H. Gao, D. J. Mcclements, L. Zhou, J. Wu, and L. Zou. 2019. “Stability, Rheology, and β-carotene Bioaccessibility of High Internal Phase Emulsion Gels.” Food Hydrocolloids 88: 210–217.
[15]

Liu, X., J. Guo, Z.-L. Wan, Y.-Y. Liu, Q.-J. Ruan, and X.-Q. Yang. 2018. “Wheat Gluten-Stabilized High Internal Phase Emulsions as Mayonnaise Replacers.” Food Hydrocolloids 77: 168–175.
[16]

Manoi, K., and S. S. H. Rizvi. 2009. “Emulsification Mechanisms and Characterizations of Cold, Gel-Like Emulsions Produced From Texturized Whey Protein Concentrate.” Food Hydrocolloids 23: 1837–1847.
[17]

Mao, L., H. Dai, J. Du, et al. 2022. “Gelatin Microgel-Stabilized High Internal Phase Emulsion for Easy Industrialization: Preparation, Interfacial Behavior and Physical Stability.” Innovative Food Science & Emerging Technologies 78: 103011.
[18]

Mei, Y., J. Zheng, Y. Yang, Z. Wan, and X. Yang. 2023. “Rapeseed Protein Preparation by Salt Extraction Combined With Ultrafiltration and Its Functional Properties.” China Food Additives 34: 1. https://doi.org/10.19804/j.issn1006-2513.2023.01.001.
[19]

Michel, S. E. S., R. Scheermeijer, M. Ambühl, and I. Fernández Farrés. 2022. “Novel Plant-Based Cream Cheese: A Tribology Perspective.” Journal of Food Engineering 335: 111172.
[20]

Oppermann, A. K., L. C. Verkaaik, M. Stieger, and E. Scholten. 2017. “Influence of Double (W1/O/W2) Emulsion Composition on Lubrication Properties.” Food & Function 8: 522–532.
[21]

Panya, A., M. Laguerre, J. Lecomte, et al. 2010. “Effects of Chitosan and Rosmarinate Esters on the Physical and Oxidative Stability of Liposomes.” Journal of Agricultural and Food Chemistry 58: 5679–5684.
[22]

Ruan, Q., X. Yang, L. Zeng, and J. Qi. 2019. “Physical and Tribological Properties of High Internal Phase Emulsions Based on Citrus Fibers and Corn Peptides.” Food Hydrocolloids 95: 53–61.
[23]

Sarkar, A., S. Soltanahmadi, J. Chen, and J. R. Stokes. 2021. “Oral Tribology: Providing Insight Into Oral Processing of Food Colloids.” Food Hydrocolloids 117: 106635.
[24]

Sethupathy, P., J. A. Moses, and C. Anandharamakrishnan. 2021. “Food Oral Processing and Tribology: Instrumental Approaches and Emerging Applications.” Food Reviews International 37: 538–571.
[25]

Skelhon, T. S., P. K. Olsson, A. R. Morgan, and S. A. Bon. 2013. “High Internal Phase Agar Hydrogel Dispersions in Cocoa Butter and Chocolate as a Route Towards Reducing Fat Content.” Food & Function 4: 1314–1321.
[26]

Stokes, J. R., M. W. Boehm, and S. K. Baier. 2013. “Oral Processing, Texture and Mouthfeel: From Rheology to Tribology and Beyond.” Current Opinion in Colloid & Interface Science 18: 349–359.
[27]

Tan, S. H., R. J. Mailer, C. L. Blanchard, and S. O. Agboola. 2011. “Canola Proteins for Human Consumption: Extraction, Profile, and Functional Properties.” Journal of Food Science 76: R16–R28.
[28]

Tan, S. H., R. J. Mailer, C. L. Blanchard, and S. O. Agboola. 2014. “Emulsifying Properties of Proteins Extracted From Australian Canola Meal.” LWT-Food Science and Technology 57: 376–382.
[29]

Tan, Y., P. W. Lee, T. D. Martens, and D. J. Mcclements. 2022. “Comparison of Emulsifying Properties of Plant and Animal Proteins in Oil-In-Water Emulsions: Whey, Soy, and Rubisco Proteins.” Food Biophysics 17: 409–421.
[30]

Tripathi, S., A. Bhattacharya, R. Singh, and R. F. Tabor. 2017. “Rheological Behavior of High Internal Phase Water-In-Oil Emulsions: Effects of Droplet Size, Phase Mass Fractions, Salt Concentration and Aging.” Chemical Engineering Science 174: 290–301.
[31]

Turnbull, W. B., and A. H. Daranas. 2003. “On the Value of C: Can Low Affinity Systems be Studied by Isothermal Titration Calorimetry?” Journal of the American Chemical Society 125: 14859–14866.
[32]

Vélez-Erazo, E. M., K. Bosqui, R. S. Rabelo, L. E. Kurozawa, and M. D. Hubinger. 2020. “High Internal Phase Emulsions (HIPE) Using Pea Protein and Different Polysaccharides as Stabilizers.” Food Hydrocolloids 105: 105775.
[33]

Wanasundara, J. P. D., T. C. Mcintosh, S. P. Perera, T. S. Withana-Gamage, and P. Mitra. 2016. “Canola/Rapeseed Protein-Functionality and Nutrition.” OCl 23: D407.
[34]

Wang, Q., Y. Zhu, Z. Ji, and J. Chen. 2021. “Lubrication and Sensory Properties of Emulsion Systems and Effects of Droplet Size Distribution.” Foods 10: 3024.
[35]

Wang, Y., B. Fan, L.-T. Tong, et al. 2022. “High Internal Phase Emulsions Stabilized Solely by Soy Protein Isolate.” Journal of Food Engineering 318: 110905.
[36]

Wei, Z., and Q. Huang. 2019. “Developing Organogel-Based Pickering Emulsions With Improved Freeze-Thaw Stability and Hesperidin Bioaccessibility.” Food Hydrocolloids 93: 68–77.
[37]

Wijaya, W., P. Van Der Meeren, K. Dewettinck, and A. R. Patel. 2018. “High Internal Phase Emulsion (HIPE)-Templated Biopolymeric Oleofilms Containing an Ultra-High Concentration of Edible Liquid Oil.” Food & Function 9: 1993–1997.
[38]

Williams, J. M. 1991. “High Internal Phase Water-In-Oil Emulsions: Influence of Surfactants and Cosurfactants on Emulsion Stability and Foam Quality.” Langmuir 7: 1370–1377.
[39]

Wu, J., F. Xu, Y. Wu, et al. 2020. “Characterization and Analysis of an Oil-In-Water Emulsion Stabilized by Rapeseed Protein Isolate Under pH and Ionic Stress.” Journal of the Science of Food and Agriculture 100: 4734–4744.
[40]

Xiong, Y., Y. Chen, X. Yi, Z. Li, and Y. Luo. 2022. “Effect of Four Plant Oils on the Stability of High Internal Phase Pickering Emulsions Stabilized by Ovalbumin-Tannic Acid Complex.” International Journal of Biological Macromolecules 222: 1633–1641.
[41]

Xu, M., L. Ma, Q. Li, et al. 2022. “Robust and Highly Adaptable High Internal Phase Gel Emulsions Stabilized Solely by a Natural Saponin Hydrogelator Glycyrrhizic Acid.” Food & Function 13: 280–289.
[42]

Zhang, J., S. Zhao, Q. Liu, Q. Chen, H. Liu, and B. Kong. 2023. “High Internal Phase Emulsions Stabilized by Pea Protein Isolate Modified by Ultrasound and pH-Shifting: Effect of Chitosan Self-Assembled Particles.” Food Hydrocolloids 141: 108715.
[43]

Zhao, Q., Q. Gu, X. Hong, Y. Liu, and J. Li. 2021. “Novel Protein-Based Nanoparticles From Perilla Oilseed Residues as Sole Pickering Stabilizers for High Internal Phase Emulsions.” LWT 145: 111340.
[44]

Zhao, Q., F. Zaaboul, Y. Liu, and J. Li. 2020. “Recent Advances on Protein-Based Pickering High Internal Phase Emulsions (Pickering HIPES): Fabrication, Characterization, and Applications.” Comprehensive Reviews in Food Science and Food Safety 19: 1934–1968.
[45]

Zhou, B., S. Drusch, and S. A. Hogan. 2022. “Confined Flow Behavior Under High Shear Rates and Stability of Oil/Water High Internal Phase Emulsions (HIPES) Stabilized by Whey Protein Isolate: Role of Protein Concentration and pH.” Food Research International 160: 111674.

RIGHTS & PERMISSIONS

2024 The Author(s). Food Bioengineering published by John Wiley & Sons Australia, Ltd. on behalf of State Key Laboratory of Bioreactor Engineering, East China University of Science and Technology.

AI Summary AI Mindmap
PDF

506

Accesses

0

Citation

Detail
Sections
Recommended

AI思维导图

/