Emily N. Sevcik, John M. Szymanski, Quentin Jallerat, Adam W. Feinberg
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引用次数: 10
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Abstract
The cell microenvironment plays an important role in many biological processes, including development and disease progression. Key to this is the extracellular matrix (ECM), a complex biopolymer network serving as the primary insoluble signaling network for physical, chemical, and mechanical cues. In vitro, the ability to engineer the ECM at the micro- and nanoscales is a critical tool to systematically interrogate the influence of ECM properties on cellular responses. Specifically, both topographical and chemical surface patterning has been shown to direct cell alignment and tissue architecture on biomaterial surfaces, however, it has proven challenging to independently control these surface properties. This protocol describes a method termed Patterning on Topography (PoT) to engineer 2D nanopatterns of ECM proteins onto topographically complex substrates, which enables independent control of physical and chemical surface properties. Applications include interrogation of fundamental cell-surface interactions and engineering interfaces that can direct cell and/or tissue function. © 2017 by John Wiley & Sons, Inc.
利用独立的纳米尺度控制化学和地形的细胞外基质线索生成细胞培养基质的地形图案
细胞微环境在许多生物过程中起着重要作用,包括发育和疾病进展。关键是细胞外基质(ECM),这是一种复杂的生物聚合物网络,是物理、化学和机械信号的主要不溶性信号网络。在体外,在微观和纳米尺度上设计ECM的能力是系统地询问ECM特性对细胞反应影响的关键工具。具体来说,地形和化学表面图案已被证明可以指导生物材料表面的细胞排列和组织结构,然而,独立控制这些表面特性已被证明是具有挑战性的。该协议描述了一种称为地形图案(PoT)的方法,将ECM蛋白的二维纳米图案设计到地形复杂的底物上,从而能够独立控制物理和化学表面性质。应用包括讯问基本的细胞表面相互作用和工程接口,可以指导细胞和/或组织功能。©2017 by John Wiley &儿子,Inc。
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