键合微流道的表面图案化。

Surface patterning of bonded microfluidic channels.

机构信息

Ian Wark Research Institute, ARC Special Research Centre for Particle and Material Interfaces, University of South Australia, Mawson Lakes, South Australia 5095, Australia.

出版信息

Biomicrofluidics. 2010 Sep 30;4(3):32206. doi: 10.1063/1.3493643.

DOI:10.1063/1.3493643

PMID:21045927

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC2967238/

Abstract

Microfluidic channels in which multiple chemical and biological processes can be integrated into a single chip have provided a suitable platform for high throughput screening, chemical synthesis, detection, and alike. These microchips generally exhibit a homogeneous surface chemistry, which limits their functionality. Localized surface modification of microchannels can be challenging due to the nonplanar geometries involved. However, chip bonding remains the main hurdle, with many methods involving thermal or plasma treatment that, in most cases, neutralizes the desired chemical functionality. Postbonding modification of microchannels is subject to many limitations, some of which have been recently overcome. Novel techniques include solution-based modification using laminar or capillary flow, while conventional techniques such as photolithography remain popular. Nonetheless, new methods, including localized microplasma treatment, are emerging as effective postbonding alternatives. This Review focuses on postbonding methods for surface patterning of microchannels.

摘要

微流控通道可以将多种化学和生物过程集成到单个芯片上，为高通量筛选、化学合成、检测等提供了合适的平台。这些微芯片通常表现出均匀的表面化学性质，这限制了它们的功能。由于涉及非平面几何形状，局部表面修饰微通道具有挑战性。然而，芯片键合仍然是主要的障碍，许多方法涉及热或等离子体处理，在大多数情况下，会使所需的化学功能失去活性。微通道的键合后修饰受到许多限制，其中一些限制最近已经得到克服。新的技术包括使用层流或毛细管流动的基于溶液的修饰，而传统技术如光刻仍然很流行。尽管如此，新的方法，包括局部微等离子体处理，作为有效的键合后替代方法正在出现。本文综述了用于微通道表面图案化的键合后方法。

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