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与壳聚糖低聚物交联的海藻酸盐凝胶——对海藻酸盐嵌段结构和壳聚糖低聚物相互作用的系统研究

Alginate gels crosslinked with chitosan oligomers - a systematic investigation into alginate block structure and chitosan oligomer interaction.

作者信息

Kopplin Georg, Lervik Anders, Draget Kurt I, Aachmann Finn L

机构信息

Norwegian Biopolymer Laboratory (NOBIPOL), Department of Biotechnology, Norwegian University of Science and Technology 7491 Trondheim Norway

Department of Chemistry, Norwegian University of Science and Technology 7491 Trondheim Norway.

出版信息

RSC Adv. 2021 Apr 13;11(23):13780-13798. doi: 10.1039/d1ra01003d.

DOI:10.1039/d1ra01003d
PMID:35423937
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC8697632/
Abstract

Three alginates with fundamentally different block structures, poly-M, poly-G, and poly-MG, have been investigated upon ionic crosslinking with chitosan oligosaccharides (CHOS), using circular dichroism (CD), rheology, and computer simulations, supporting the previously proposed gelling principle of poly-M forming zipper-like junction zones with chitosan (match in charge distance along the two polyelectrolytes) and revealing a unique high gel strength poly-MG chitosan gelling system. CD spectroscopy revealed an increased chiroptical activity exclusively for the poly-M chitosan gelling system, indicative of induced conformational changes and higher ordered structures. Rheological measurement revealed gel strengths (' < 900 Pa) for poly-MG (1%) CHOS (0.3%) hydrogels, magnitudes of order greater than displayed by its poly-M analogue. Furthermore, the ionically crosslinked poly-MG chitosan hydrogel increased in gel strength upon the addition of salt (' < 1600 at 50 mM NaCl), suggesting a stabilization of the junction zones through hydrophobic interactions and/or a phase separation. Molecular dynamics simulations have been used to further investigate these findings, comparing interaction energies, charge distances and chain alignments. These alginates are displaying high gel strengths, are known to be fully biocompatible and have revealed a broad range of tolerance to salt concentrations present in biological systems, proving high relevance for biomedical applications.

摘要

利用圆二色性(CD)、流变学和计算机模拟,研究了三种具有根本不同嵌段结构的藻酸盐——聚-M、聚-G和聚-MG,它们与壳寡糖(CHOS)进行离子交联,支持了先前提出的聚-M与壳聚糖形成拉链状连接区的凝胶化原理(沿两种聚电解质的电荷距离匹配),并揭示了一种独特的高凝胶强度聚-MG壳聚糖凝胶体系。CD光谱显示,仅聚-M壳聚糖凝胶体系的手性光学活性增加,这表明诱导了构象变化和更高阶结构。流变学测量显示,聚-MG(1%)/CHOS(0.3%)水凝胶的凝胶强度('<900 Pa),其量级大于其聚-M类似物所显示的量级。此外,离子交联的聚-MG壳聚糖水凝胶在添加盐后凝胶强度增加(在50 mM NaCl时'<1600),这表明通过疏水相互作用和/或相分离使连接区稳定。分子动力学模拟已用于进一步研究这些发现,比较相互作用能、电荷距离和链排列。这些藻酸盐显示出高凝胶强度,已知具有完全的生物相容性,并已揭示出对生物系统中存在的盐浓度具有广泛的耐受性,证明其在生物医学应用中具有高度相关性。

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