Interfacial behavior of lupin protein and its complexes with polysaccharides at different oil-water interfaces analyzed by general stress decomposition

IF 8 1区农林科学 Q1 FOOD SCIENCE & TECHNOLOGY

Food Research International Pub Date : 2025-09-17 DOI:10.1016/j.foodres.2025.117526

Xingfa Ma, Mehdi Habibi, Leonard M.C. Sagis

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Abstract

In this study, we studied the interfacial behavior of lupin proteins (LPI) and lupin protein-polysaccharide complexes (LPI-PS) (with sodium alginate, pectin, and κ-carrageenan), at different oil-water interfaces using interfacial dilatational rheology. Interfacial mechanical properties were investigated using large amplitude oscillatory dilatation (LAOD) and analyzed with the general stress decomposition (GSD) method. LPI and LPI-PS complexes adsorbed faster at apolar oil-water interfaces than at more polar oil-water interfaces. A significant change in the GSD parameters, E_τ1L and E_τ4, was observed across different hydrophobic subphases (i.e., more polar oil, apolar oil, and air). At more polar oil-water interfaces, the E_τ4 moduli were highly positive (1.6–5.2 mN/m), and E_τ1L was very low (11.4–17.9 mN/m). At more apolar oil-water interfaces, the E_τ4 moduli became slightly negative (between −2.7 and −3.7 mN/m), and E_τ1L was considerably increased (37.8–51.4 mN/m). At air-water interfaces, the E_τ4 moduli were most negative (between −11.9 mN/m and −13.1 mN/m), and E_τ1L was highest (77.8–150.4 mN/m). These results suggested that the LPI-PS complexes may behave more similar to particles and form soft glass-like structures at polar oil-water interfaces, and more gel-like networks may form at apolar oil- and air-water interfaces. At the air-water interface such networks have previously been observed using atomic force microscopy. LPI showed a more substantial increase in E_d’ with reduced oil polarity than LPI-PS with lower structural flexibility. Emulsions prepared with more polar oils also showed worse emulsion flow stability than the others, due to the lower stiffness of their oil-water interfaces.

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用一般应力分解法分析了罗苹蛋白及其与多糖配合物在不同油水界面上的界面行为

在本研究中，我们利用界面膨胀流变学研究了罗苹蛋白（LPI）和罗苹蛋白-多糖复合物（LPI- ps）（与海藻酸钠、果胶和κ-卡拉胶）在不同油水界面上的界面行为。采用大振幅振荡膨胀法（LAOD）研究界面力学性能，采用广义应力分解法（GSD）分析界面力学性能。LPI和LPI- ps配合物在极性油水界面上的吸附速度快于在极性更强的油水界面上的吸附速度。GSD参数Eτ1L和Eτ4在不同疏水亚相（即极性油、极性油和空气）中有显著变化。在较极性的油水界面，Eτ4模量为高正值（1.6 ~ 5.2 mN/m），而Eτ1L模量很低（11.4 ~ 17.9 mN/m）。在极性较高的油水界面处，Eτ4模量略呈负变化（在- 2.7 ~ - 3.7 mN/m之间），Eτ1L显著增大（37.8 ~ 51.4 mN/m）。在空气-水界面，Eτ4模量为负，介于- 11.9 mN/m ~ - 13.1 mN/m之间，Eτ1L最大，为77.8 ~ 150.4 mN/m。这些结果表明，LPI-PS配合物在极性油水界面可能更接近于颗粒，形成柔软的玻璃状结构，而在极性油水界面可能形成更多的凝胶状网络。在空气-水界面，这种网络以前已经用原子力显微镜观察到。与结构柔韧性较低的LPI- ps相比，油极性降低的LPI- ps的Ed′增加幅度更大。极性油含量高的乳液的流动稳定性也较差，这是由于其油水界面刚度较低。

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来源期刊

Food Research International 工程技术-食品科技

CiteScore

12.50

自引率

7.40%

发文量

1183

审稿时长

79 days

期刊介绍： Food Research International serves as a rapid dissemination platform for significant and impactful research in food science, technology, engineering, and nutrition. The journal focuses on publishing novel, high-quality, and high-impact review papers, original research papers, and letters to the editors across various disciplines in the science and technology of food. Additionally, it follows a policy of publishing special issues on topical and emergent subjects in food research or related areas. Selected, peer-reviewed papers from scientific meetings, workshops, and conferences on the science, technology, and engineering of foods are also featured in special issues.