在微流道内制备大孔聚乙二醇水凝胶阵列。
Development of macroporous poly(ethylene glycol) hydrogel arrays within microfluidic channels.
机构信息
Department of Chemical and Biological Engineering, University of Wisconsin-Madison, 1415 Engineering Drive, Madison, Wisconsin 53706, United States.
出版信息
Biomacromolecules. 2010 Dec 13;11(12):3316-24. doi: 10.1021/bm100792y. Epub 2010 Oct 28.
Abstract
The mass transport of solutes through hydrogels is an important design consideration in materials used for tissue engineering, drug delivery, and protein arrays used to quantify protein concentration and activity. We investigated the use of poly(ethylene glycol) (PEG) as a porogen to enhance diffusion of macromolecules into the interior of polyacrylamide and PEG hydrogel posts photopatterned within microfluidic channels. The diffusion of GST-GFP and dextran-FITC into hydrogels was monitored and effective diffusion coefficients were determined by fitting to the Fickian diffusion equations. PEG-diacrylate (M(r) 700) with porogen formed a macroporous structure and permitted significant penetration of 250 kDa dextran. Proteins copolymerized in these macroporous hydrogels retained activity and were more accessible to antibody binding than proteins copolymerized in nonporous gels. These results suggest that hydrogel macroporosity can be tuned to regulate macromolecular transport in applications such as tissue engineering and protein arrays.
摘要
水凝胶中溶质的质量传输是用于组织工程、药物输送以及用于定量蛋白质浓度和活性的蛋白质阵列的材料的一个重要设计考虑因素。我们研究了使用聚乙二醇(PEG)作为致孔剂来增强生物大分子向聚丙酰胺和 PEG 水凝胶柱内部的扩散,这些水凝胶柱是在微流道内通过光图案化形成的。通过拟合菲克扩散方程来监测 GST-GFP 和葡聚糖-FITC 向水凝胶中的扩散,并确定有效扩散系数。具有致孔剂的 PEG 二丙烯酸酯(M(r)700)形成了大孔结构,并允许 250 kDa 的葡聚糖显著渗透。在这些大孔水凝胶中共聚物化的蛋白质保留了活性,并且比在非多孔凝胶中共聚物化的蛋白质更容易与抗体结合。这些结果表明,可以调节水凝胶的大孔结构来调节组织工程和蛋白质阵列等应用中的大分子传输。
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