Phlorizin–diosmetin supramolecular hybrid hydrogel: Structural design, functional properties, and applications in dairy thickening

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

Food Research International Pub Date : 2025-09-18 DOI:10.1016/j.foodres.2025.117534

Qiuru Tan , Jiao Wang , Yuxia Mo , Shuang Tian , Jin Ke , Anguo Hou , Yanni Ma , Wenping Wang

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Abstract

As consumer demand for functional dairy products continues to rise, there is growing interest in formulations that provide both nutritional value and added health benefits. In this study, a novel supramolecular hybrid hydrogel was developed from phlorizin (PHL) and diosmetin (DIO), two natural bioactive flavonoids, to enhance the texture and antioxidant properties of dairy products. The hydrogel was formed via co-assembly through non-covalent interactions such as hydrogen bonding and π-π stacking. Optimized at a 1:2 PHL:DIO molar ratio and 2 % concentration, the hydrogel exhibited improved solubility, thermal stability, and mechanical strength, with a storage modulus exceeding 2.8 kPa, pronounced shear-thinning behavior (viscosity 976,000 to 330 mPa·s at 0.1–10 s⁻¹), and rapid self-healing (103 % recovery). In vitro antioxidant assessments showed significantly enhanced activity compared to individual flavonoids, including 74.43 % DPPH, 57.65 % hydroxyl radical, 80 % ABTS, and 94.92 % superoxide anion scavenging. In vivo experiments using Caenorhabditis elegans demonstrated improved locomotion, a 28.6 % extension in lifespan under oxidative stress, and a 9-fold reduction in ROS levels. When applied in dairy systems, the hydrogel increased milk viscosity by 230-fold at low shear (0.5 % w/v) and improved yogurt texture, achieving 98.89 % water-holding capacity while promoting beneficial Lactobacillus growth. These findings highlight the potential of this dual-function hydrogel as a natural, multifunctional additive for enhancing both the sensory quality and health value of dairy products.

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根连素-薯蓣皂苷超分子杂化水凝胶：结构设计、功能特性及其在乳制品增稠中的应用

随着消费者对功能性乳制品的需求不断上升，人们对既能提供营养价值又能增加健康益处的配方越来越感兴趣。本研究以两种天然生物活性黄酮类化合物——邻苯二酚（PHL）和薯蓣皂苷（DIO）为原料，制备了一种新型的超分子杂交水凝胶，以提高乳制品的质地和抗氧化性能。水凝胶是通过氢键和π-π堆积等非共价相互作用形成的。在PHL:DIO摩尔比为1:2、浓度为2%的条件下优化后，水凝胶的溶解度、热稳定性和机械强度均得到改善，存储模量超过2.8 kPa，具有明显的剪切变薄行为（在0.1-10 s−1范围内粘度为976,000 ~ 330 mPa·s），并具有快速自愈（103%的回收率）。体外抗氧化评估显示，与单一类黄酮相比，其抗氧化活性显著增强，DPPH的清除活性为74.43%，羟基自由基的清除活性为57.65%，ABTS的清除活性为80%，超氧阴离子的清除活性为94.92%。使用秀丽隐杆线虫的体内实验表明，在氧化应激下，秀丽隐杆线虫的运动能力得到改善，寿命延长28.6%，ROS水平降低9倍。当应用于乳制品系统时，水凝胶在低剪切（0.5% w/v）下将牛奶粘度提高230倍，改善酸奶质地，达到98.89%的保水能力，同时促进有益的乳酸菌生长。这些发现突出了这种双功能水凝胶作为一种天然的多功能添加剂的潜力，可以提高乳制品的感官质量和健康价值。

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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.