Morphology and Entrapped Enzyme Performance in Inkjet-Printed Sol鈥揋el Coatings on Paper

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• 作者：Jingyun Wang ; Devon Bowie ; Xi Zhang ; Carlos Filipe ; Robert Pelton ; John D. Brennan
• 刊名：Chemistry of Materials
• 出版年：2014
• 出版时间：March 11, 2014
• 年：2014
• 卷：26
• 期：5
• 页码：1941-1947
• 全文大小：407K
• 年卷期：v.26,no.5(March 11, 2014)
• ISSN：1520-5002

文摘

We recently reported on the multilayer printing of sol鈥揼el/enzyme bioinks onto porous filter paper to create bioactive paper test strips. The method involves printing of four inks: a polymer underlayer, a sol鈥揼el-based silica layer, an acetylcholinesterase (AChE) enzyme layer, and finally a top layer of silica. To improve our understanding of the nature of these printed materials, filter paper printed with various ink components was characterized by activity assays (with and without protease treatment), confocal microscopy to assess the location and mixing of layers, and scanning electron microscopy of deposited inks to assess the morphology and ink location. Although the silica and enzyme solutions were printed sequentially, they formed a composite material within the porous paper network and coated only the fibers as a 35 卤 15 nm thin film without filling the macropores. The silica coating on the cellulose fibers was sufficiently flexible to allow bending of the paper substrate, unlike traditional silica thin films. The protease assay results showed that the AChE was more protected as the amount of sol鈥揼el-derived silica printed on paper was increased. The top layer of sol鈥揼el ink was found to play a critical role in protection against proteolysis, while the bottom layer of sol鈥揼el ink was found to be necessary to prevent the potential inhibition of AChE by the cationic polymer (used as a capture agent for the product of the enzymatic reaction). Overall, the data show that inkjet-printed sol鈥揼el materials form thin, protein-entrapping films that are suitable for the production of printed biosensors.