Dairy and nondairy proteins as nano-architecture structures for delivering phenolic compounds: Unraveling their molecular interactions to maximize health benefits

IF 12 1区农林科学 Q1 FOOD SCIENCE & TECHNOLOGY

Comprehensive Reviews in Food Science and Food Safety Pub Date : 2024-11-12 DOI:10.1111/1541-4337.70053

Cristine Couto de Almeida, Diego dos Santos Baião, Davi Vieira Teixeira da Silva, Lucileno Rodrigues da Trindade, Patricia Ribeiro Pereira, Carlos Adam Conte-Junior, Vania Margaret Flosi Paschoalin

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引用次数: 0

Abstract

Phenolic compounds are recognized for their benefits against degenerative diseases. Clinical and nutritional applications are limited by their low solubility, stability, and bioavailability, compromising their efficacy. Natural macromolecules, such as lipids, polysaccharides, and proteins, employed as delivery systems can efficiently overcome these limitations. In this sense, proteins are attractive due to their biocompatibility and dynamic structure properties, functional adaptability and self-assembly capabilities, offering stability, efficient encapsulation, and controlled release. This review explores the potential use of dairy proteins, caseins, and whey proteins, and, alternatively, nondairy proteins, gelatin, human serum albumin, maize zein, and soybean proteins, in building wall materials for the delivery of phenolic compounds. To optimize performance, aspects, such as protein–phenolic affinity and complex stability/activity, should be considered when designing particle nano-architecture. Molecular interactions between protein–phenolic compound complexes are, thus, further discussed, as well as the effects of temperature and pH and strategies to stabilize and preserve nano-architecture and retain phenolic compound activity. All proteins harbor one or more putative binding sites, shared or not, depending on the phenolic compound. Preservation techniques are still a case-to-case study, as no behavior patterns among different complexes are noted. Safety aspects necessary for the marketing of nanoproducts, such as characterization, toxicity assessments, and post-market monitoring as defined by the European Food Safety Authority and the Food and Drug Administration, are discussed, evidencing the need for a unified regulation. This review broadens our understanding and opens new opportunities for the development of novel protein-based nanocarriers to obtain more effective and stable products, enhancing phenolic compound delivery and health benefits.

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乳制品和非乳制品蛋白质作为输送酚类化合物的纳米结构：揭示其分子相互作用，最大限度地提高健康效益。

酚类化合物被公认为对退行性疾病有益。由于酚类化合物的溶解度、稳定性和生物利用度较低，影响了其功效，因此在临床和营养方面的应用受到限制。天然大分子（如脂质、多糖和蛋白质）作为给药系统可以有效克服这些限制。从这个意义上说，蛋白质因其生物相容性和动态结构特性、功能适应性和自组装能力、稳定性、高效封装和控释性而具有吸引力。本综述探讨了乳制品蛋白质、酪蛋白和乳清蛋白，以及非乳制品蛋白质、明胶、人血清白蛋白、玉米蛋白和大豆蛋白在输送酚类化合物的建筑壁材料中的潜在用途。为了优化性能，在设计颗粒纳米结构时应考虑蛋白质与酚类化合物的亲和力和复合物的稳定性/活性等方面。因此，本文将进一步讨论蛋白质-酚类化合物复合物之间的分子相互作用、温度和 pH 值的影响以及稳定和保存纳米结构并保持酚类化合物活性的策略。所有蛋白质都有一个或多个假定结合位点，是否共享取决于酚类化合物。由于没有发现不同复合物之间的行为模式，因此保存技术仍然是一项个案研究。本综述还讨论了纳米产品上市所需的安全问题，如欧洲食品安全局和美国食品药品管理局规定的特征描述、毒性评估和上市后监测，这表明需要制定统一的法规。这篇综述拓宽了我们的认识，为开发基于蛋白质的新型纳米载体提供了新的机遇，从而获得更有效、更稳定的产品，提高酚类化合物的输送和健康益处。

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来源期刊

Comprehensive Reviews in Food Science and Food Safety 工程技术-食品科技

CiteScore

26.20

自引率

2.70%

发文量

182

期刊介绍： Comprehensive Reviews in Food Science and Food Safety (CRFSFS) is an online peer-reviewed journal established in 2002. It aims to provide scientists with unique and comprehensive reviews covering various aspects of food science and technology. CRFSFS publishes in-depth reviews addressing the chemical, microbiological, physical, sensory, and nutritional properties of foods, as well as food processing, engineering, analytical methods, and packaging. Manuscripts should contribute new insights and recommendations to the scientific knowledge on the topic. The journal prioritizes recent developments and encourages critical assessment of experimental design and interpretation of results. Topics related to food safety, such as preventive controls, ingredient contaminants, storage, food authenticity, and adulteration, are considered. Reviews on food hazards must demonstrate validity and reliability in real food systems, not just in model systems. Additionally, reviews on nutritional properties should provide a realistic perspective on how foods influence health, considering processing and storage effects on bioactivity. The journal also accepts reviews on consumer behavior, risk assessment, food regulations, and post-harvest physiology. Authors are encouraged to consult the Editor in Chief before submission to ensure topic suitability. Systematic reviews and meta-analyses on analytical and sensory methods, quality control, and food safety approaches are welcomed, with authors advised to follow IFIS Good review practice guidelines.