迈向肠道黏液的仿生模型。

Towards bioinspired models of intestinal mucus.

作者信息

Sardelli Lorenzo, Pacheco Daniela Peneda, Ziccarelli Anna, Tunesi Marta, Caspani Omar, Fusari Andrea, Briatico Vangosa Francesco, Giordano Carmen, Petrini Paola

机构信息

Department of Chemistry, Materials and Chemical Engineering "Giulio Natta", Politecnico di Milano Milan Italy

出版信息

RSC Adv. 2019 May 21;9(28):15887-15899. doi: 10.1039/c9ra02368b. eCollection 2019 May 20.

DOI:10.1039/c9ra02368b

PMID:35521409

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9064393/

Abstract

Intestinal mucus is a biological structure that acts as a barrier between the external environment and the epithelium. It actively selects nutrient and drug intake, regulates the symbiosis with the intestinal microbiota and keeps the epithelium protected from the attack of pathogens. All these functions are closely connected to the chemical and structural complexity of this biological material, on which its viscoelastic and diffusive properties depend. Many models have been proposed to replicate these characteristics using glycoproteins in solution and possibly the addition of other mucus components, such as lipids and other proteins. In the field of mucus modelling, an overall view of the mucus as a material, having its own viscous, rheological and diffusive characteristics, has been undersized with respect to a pure biological-functional analysis. In this review, we propose a description of the mucus as a biomaterial, including a presentation of its chemical and structural complexity, and of its main viscoelastic-diffusive properties, in order to provide a synthesis of the characteristics necessary for the engineering of more advanced mucus models.

摘要

肠道黏液是一种生物结构，它充当着外部环境与上皮细胞之间的屏障。它积极地选择营养物质和药物的摄入，调节与肠道微生物群的共生关系，并保护上皮细胞免受病原体的攻击。所有这些功能都与这种生物材料的化学和结构复杂性密切相关，而其粘弹性和扩散特性就取决于这种复杂性。已经提出了许多模型，使用溶液中的糖蛋白并可能添加其他黏液成分（如脂质和其他蛋白质）来复制这些特性。在黏液建模领域，相对于纯粹的生物功能分析，将黏液视为一种具有自身黏性、流变学和扩散特性的材料的整体观点尚未得到充分重视。在本综述中，我们提出将黏液描述为一种生物材料，包括介绍其化学和结构复杂性以及主要的粘弹性 - 扩散特性，以便综合出构建更先进黏液模型所需的特性。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/804f/9064393/19c12b05d07c/c9ra02368b-f1.jpg

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迈向肠道黏液的仿生模型。

Towards bioinspired models of intestinal mucus.

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