Complex coacervation of proteins and anionic polysaccharides

IF 7.9 2区化学 Q1 CHEMISTRY, PHYSICAL

Current Opinion in Colloid & Interface Science Pub Date : 2004-12-01 DOI:10.1016/j.cocis.2004.09.006

Cornelus G. de Kruif , Fanny Weinbreck , Renko de Vries

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引用次数: 944

Abstract

Coacervation of proteins and anionic polysaccharides is both of practical and theoretical interest. From a large body of literature, it seems that the phase separation is mainly entropically driven, and may most probably be attributed to the delocalisation of the counter ions of the protein and the polysaccharide. The protein and polysaccharide appear to form complexes in solution, which can be viewed as new colloidal entities. These complex particles are neutral and exhibit an attractive interaction, which leads to a phase separation of the gas–liquid type in which a (very) dilute colloidal phase coexists with a very concentrated colloidal phase. In the case of strong poly-acids, usually, a precipitate is formed rather than a liquid coacervate phase. The structure of the concentrated polymer phase seems to resemble a continuous polymer phase in which the protein can diffuse around, as well as the individual polysaccharide molecules. Time scales of diffusion vary from milliseconds to days depending on the strength of the interaction. From a rheological point of view, the concentrated phase is much more viscous than elastic and the rheology resembles the behaviour of a (viscous) concentrated particle dispersion. Theoretical developments are limited probably due to the difficulty to describe the (correlated) charge distribution in the system. There is a strong interest in coacervates for the use of encapsulation. For the same reason, much attention is given to replacing the traditional gelatin by milk and plant proteins.

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蛋白质和阴离子多糖的复杂凝聚

蛋白质和阴离子多糖的凝聚既有实际意义，也有理论意义。从大量文献来看，相分离似乎主要是熵驱动的，并且很可能归因于蛋白质和多糖的反离子的离域。蛋白质和多糖在溶液中形成复合物，可以看作是新的胶体实体。这些复杂的颗粒是中性的，并表现出吸引的相互作用，这导致气液型相分离，其中(非常)稀的胶体相与非常浓的胶体相共存。在强聚酸的情况下，通常形成沉淀而不是液体凝聚相。浓缩的聚合物相的结构似乎类似于一个连续的聚合物相，蛋白质可以在其中扩散，以及单个的多糖分子。扩散的时间尺度从几毫秒到几天不等，取决于相互作用的强度。从流变学的角度来看，浓相的粘性比弹性大得多，流变学类似于(粘性)浓颗粒分散的行为。由于难以描述系统中的(相关)电荷分布，理论发展受到限制。人们对使用封装的凝聚有浓厚的兴趣。出于同样的原因，人们非常关注用牛奶和植物蛋白代替传统的明胶。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Current Opinion in Colloid & Interface Science 化学-物理化学

CiteScore

16.50

自引率

1.10%

发文量

审稿时长

11.3 weeks

期刊介绍： Current Opinion in Colloid and Interface Science (COCIS) is an international journal that focuses on the molecular and nanoscopic aspects of colloidal systems and interfaces in various scientific and technological fields. These include materials science, biologically-relevant systems, energy and environmental technologies, and industrial applications. Unlike primary journals, COCIS primarily serves as a guide for researchers, helping them navigate through the vast landscape of recently published literature. It critically analyzes the state of the art, identifies bottlenecks and unsolved issues, and proposes future developments. Moreover, COCIS emphasizes certain areas and papers that are considered particularly interesting and significant by the Editors and Section Editors. Its goal is to provide valuable insights and updates to the research community in these specialized areas.