用于分析仿生细胞外基质性质的地形和肽功能化水凝胶阵列。

IF 1.5 4区 工程技术 Q3 ENGINEERING, ELECTRICAL & ELECTRONIC
Michelle J Wilson, Yaming Jiang, Bernardo Yañez-Soto, Sara Liliensiek, William L Murphy, Paul F Nealey
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引用次数: 8

摘要

上皮细胞位于特殊的细胞外基质上,提供指导性线索来调节和支持细胞功能。作者先前已经证明,与天然细胞外基质(亚微米和纳米尺度特征)相似的基质地形显著影响角膜上皮的增殖和迁移。在这项工作中,合成的水凝胶被地形和生化线索修饰,其中特定的肽配体被固定在纳米图案的水凝胶中。然而,对多种指导性线索(肽、肽浓度、地形尺寸)进行有效、系统的研究取决于更高通量平台的发展。为了实现这一目标,作者开发了一个水凝胶阵列平台,以系统地、快速地评估两种不同肽基序的组合和一系列纳米级的地形尺寸。具体来说,合成了不同功能的聚乙二醇化肽配体RGD (GGGRGDSP)和AG73 (GRKRLQVQLSIRT),并将其结合到惰性水凝胶网络中。利用具有毫米级区域阵列的弹性模板,将水凝胶前体溶液空间限制在软光刻生成的纳米级图案的弹性模板上。由此产生的地形和肽功能化的水凝胶阵列被用来表征单细胞迁移。上皮细胞的迁移速度和持久性受底物的生化和地形因素的影响。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Arrays of topographically and peptide-functionalized hydrogels for analysis of biomimetic extracellular matrix properties.

Epithelial cells reside on specialized extracellular matrices that provide instructive cues to regulate and support cell function. The authors have previously demonstrated that substrate topography with dimensions similar to the native extracellular matrix (submicrometer and nanoscale features) significantly impacts corneal epithelial proliferation and migration. In this work, synthetic hydrogels were modified with both topographic and biochemical cues, where specified peptide ligands were immobilized within nanopatterned hydrogels. The efficient, systematic study of multiple instructive cues (peptide, peptide concentration, topographic dimensions), however, is contingent on the development of higher throughput platforms. Toward this goal, the authors developed a hydrogel array platform to systematically and rapidly evaluate combinations of two different peptide motifs and a range of nanoscale topographic dimensions. Specifically, distinct functional pegylated peptide ligands, RGD (GGGRGDSP) and AG73 (GRKRLQVQLSIRT), were synthesized for incorporation into an inert hydrogel network. Elastomeric stencils with arrays of millimeter-scale regions were used to spatially confine hydrogel precursor solutions on elastomeric stamps with nanoscale patterns generated by soft lithography. The resulting topographically and peptide-functionalized hydrogel arrays were used to characterize single cell migration. Epithelial cell migration speed and persistence were governed by both the biochemical and topographical cues of the underlying substrate.

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来源期刊
CiteScore
2.70
自引率
0.00%
发文量
146
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