控制自组装二肽水凝胶中的网络类型。

Controlling the network type in self-assembled dipeptide hydrogels.

机构信息

Institute of Medical and Biological Engineering - School of Biomedical Sciences, University of Leeds, Leeds, LS2 9JT, UK.

School of Chemistry, Joseph Black Building, University of Glasgow, Glasgow G12 8QQ, UK.

出版信息

Soft Matter. 2017 Mar 1;13(9):1914-1919. doi: 10.1039/c6sm02666d.

DOI:10.1039/c6sm02666d

PMID:28186211

Abstract

We show that the same low molecular weight gelator can form gels using three different methods. Gels were formed from a high pH solution either by adding a salt or by adding an acid; gels were also formed by adding water to a solution of the gelator in an organic solvent. The mechanical properties for the gels formed by the different methods are different from one another. We link this to the network type that is formed, as well as the fibrous structures that are formed. The salt-triggered gels show a significant number of fibres that tend to align. The acid-triggered gels contain many thin fibres, which form an entangled network. The solvent-triggered gels show the presence of spherulitic domains. We show that it is tractable to vary the trigger mechanism for an established, robust gelator to prepare gels with targeted properties as opposed to synthesising new gelators.

摘要

我们证明了同一种低分子量凝胶剂可以通过三种不同的方法形成凝胶。凝胶可以通过在高 pH 值溶液中添加盐或酸形成，也可以通过向凝胶剂在有机溶剂中的溶液中加水形成。不同方法形成的凝胶的机械性能彼此不同。我们将其与形成的网络类型以及形成的纤维结构联系起来。盐触发的凝胶显示出大量倾向于排列的纤维。酸触发的凝胶含有许多细纤维，形成缠结的网络。溶剂触发的凝胶显示出球晶域的存在。我们表明，可以改变已建立的、坚固的凝胶剂的触发机制，以制备具有目标性质的凝胶，而不是合成新的凝胶剂。

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控制自组装二肽水凝胶中的网络类型。

Controlling the network type in self-assembled dipeptide hydrogels.

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