基于氨基纤维素衍生物的生物功能材料——一种纳米生物技术概念

Biofunctional Materials Based on Amino Cellulose Derivatives--A Nanobiotechnological Concept.

作者信息

Heinze Thomas, Siebert Melanie, Berlin Peter, Koschella Andreas

机构信息

Center of Excellence for Polysaccharide Research, Institute of Organic Chemistry and Macromolecular Chemistry, Friedrich Schiller University of Jena, Humboldtstraße 10, 07743, Jena, Germany.

出版信息

Macromol Biosci. 2016 Jan;16(1):10-42. doi: 10.1002/mabi.201500184. Epub 2015 Jul 30.

DOI:10.1002/mabi.201500184

PMID:26227731

Abstract

This feature article summarizes recent developments in the field of so-called aminodeoxy cellulose derivatives ("amino celluloses") that are applied for functional surface coating of biofunctional materials. After introducing common manufacturing methods for nanostructurized substrates (material surfaces and nanoparticles) biorelevant amino celluloses are described. It could be demonstrated that cellulose is a unique starting material for chemical modification of hydroxyl groups and the adjacent carbon atom. Amino celluloses are proved to be the modifiable polymer of choice for the biofunctionalization of material surfaces. Amino celluloses possess self assembling properties and may form monolayer composites on a variety of substrate materials.

摘要

这篇专题文章总结了所谓氨基脱氧纤维素衍生物（“氨基纤维素”）领域的最新进展，这些衍生物用于生物功能材料的功能表面涂层。在介绍了纳米结构化基材（材料表面和纳米颗粒）的常见制造方法后，描述了与生物相关的氨基纤维素。可以证明，纤维素是羟基和相邻碳原子化学改性的独特起始材料。氨基纤维素被证明是材料表面生物功能化的首选可改性聚合物。氨基纤维素具有自组装特性，可在多种基材上形成单层复合材料。

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基于氨基纤维素衍生物的生物功能材料——一种纳米生物技术概念

Biofunctional Materials Based on Amino Cellulose Derivatives--A Nanobiotechnological Concept.

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