多功能小分子基元在水中的自组装及生物功能超分子水凝胶的形成。
Versatile small-molecule motifs for self-assembly in water and the formation of biofunctional supramolecular hydrogels.
机构信息
Department of Chemistry, Brandeis University, Waltham, Massachusetts 02453, USA.
出版信息
Langmuir. 2011 Jan 18;27(2):529-37. doi: 10.1021/la1020324. Epub 2010 Jul 7.
Abstract
This feature article introduces new structural motifs (referred as "samogen") that serve as the building blocks of hydrogelators for molecular self-assembly in water to result in a series of supramolecular hydrogels. Using a compound that consists of two phenylalanine residues and a naphthyl group (also abbreviated as NapFF (1) in this text) as an example of the samogens, we demonstrated the ability of the samogens to convert bioactive molecules into molecular hydrogelators that self-assemble in water to result in nanofibers. By briefly summarizing the properties and applications (e.g., wound healing, drug delivery, controlling cell fate, typing bacteria, and catalysis) of these molecular hydrogelators derived from the samogens, we intend to illustrate the basic requirements and promises of the small-molecule hydrogelators for applications in chemistry, materials science, and biomedicine.
摘要
这篇专题文章介绍了新的结构基序(称为“同源基序”),它们可作为水相分子自组装的水凝胶形成剂的构建模块,从而产生一系列超分子水凝胶。本文以由两个苯丙氨酸残基和一个萘基组成的化合物(在本文中也简称为 NapFF(1))为例,展示了同源基序将生物活性分子转化为在水中自组装形成纳米纤维的分子水凝胶形成剂的能力。通过简要总结这些源自同源基序的分子水凝胶形成剂的性质和应用(例如,伤口愈合、药物输送、控制细胞命运、细菌分型和催化),我们旨在说明小分子水凝胶形成剂在化学、材料科学和生物医学中的应用的基本要求和前景。
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