在通过纳米压印光刻生产的聚合物纳米流体设备中,设计入口结构以增强DNA捕获到纳米通道中

IF 2.8 Q2 ENGINEERING, ELECTRICAL & ELECTRONIC
Jiahao Wu , Junseo Choi , Franklin I. Uba , Steven A. Soper , Sunggook Park
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引用次数: 0

摘要

操作纳米流体生物传感器需要将待分析的单个分子从微流体网络穿入纳米结构,主要是纳米通道或纳米孔。不同的入口结构已被用作提高进入纳米结构的捕获事件的数量的手段。在这里,我们系统地研究了在微/纳米通道界面形成的各种工程入口结构对将单个λ-DNA分子捕获到纳米通道中的影响。对不同的入口几何形状进行了评估,并根据其有效性进行了排名。相对于突变的微/纳米通道界面,在纳米通道之前添加入口结构有效地提高了190–700%的DNA捕获率。从微通道到各种入口的DNA捕获主要由入口结构的捕获体积和入口结构中几何修饰的电场决定。然而,随着入口结构的宽度增加,存在于微通道中的流体动力学流动通过将一些DNA分子深深地拖回到入口结构中而对DNA捕获产生负面影响。我们的研究结果表明,工程化入口结构是控制DNA分子捕获到纳米结构中的有效手段,这对纳米流体生物传感器的操作很重要。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Engineering inlet structures to enhance DNA capture into nanochannels in a polymer nanofluidic device produced via nanoimprint lithography

Engineering inlet structures to enhance DNA capture into nanochannels in a polymer nanofluidic device produced via nanoimprint lithography

Operating nanofluidic biosensors requires threading single molecules to be analyzed from microfluidic networks into nanostructures, mostly nanochannels or nanopores. Different inlet structures have been employed as a means of enhancing the number of the capture events into nanostructures. Here, we systematically investigated the effects of various engineered inlet structures formed at the micro/nanochannel interface on the capture of single λ-DNA molecules into the nanochannels. Different inlet geometries were evaluated and ranked in order of their effectiveness. Adding an inlet structure prior to a nanochannel effectively improved the DNA capture rate by 190–700% relative to that for the abrupt micro/nanochannel interface. The capture of DNA from the microchannel to various inlets was determined mainly by the capture volumes of the inlet structures and the geometrically modified electric field in the inlet structure. However, as the width of the inlet structure increased, the hydrodynamic flow existing in the microchannel negatively influenced the DNA capture by dragging some DNA molecules deep into the inlet structure back to the microchannel. Our results indicate that engineering inlet structures is an effective means of controlling the capture of DNA molecules into nanostructures, which is important for operation of nanofluidic biosensors.

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来源期刊
Micro and Nano Engineering
Micro and Nano Engineering Engineering-Electrical and Electronic Engineering
CiteScore
3.30
自引率
0.00%
发文量
67
审稿时长
80 days
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