Protein nanopore-gated bio-transistor for membrane ionic current recording

69th Device Research Conference Pub Date : 2011-06-20 DOI:10.1109/DRC.2011.5994451

Tae-Sun Lim, D. Jain, P. Burke

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引用次数: 6

Abstract

Although naturally occurring biological nanopores have shortcomings such as a relatively weak structural durability and a limited life-time, they are still intriguing candidates for nanobiosensing applications due to their sensitivity and specificity to analytes as well as various choices of ion channels depending on functionalities. In order to overcome limitations of biological nanopores, man-made solid-state nanopores have been explored. The fabricated solid-state nanopore is structurally durable and suitable for nanofabrication process yet it is still challenging to construct and a low throughput process, and lacks the chemical specificity of natural ion channels[1]. Can bionanotechnology be applied to improve this situation? Recent work has shown that nanomaterials (nanotubes, nanowires) can be gated by electrolyte, and even coated with lipid bilayers allowing charges of either the bilayer themselves[2]. These reports focus on time average changes in source/drain current due to gating by charges near the nanowire/nanotube. Thus, to date, no nanowire/nanotube device has been able to measure the time-dependent single ion channel recording.

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用于膜离子电流记录的蛋白质纳米孔控生物晶体管

尽管天然存在的生物纳米孔具有结构耐久性相对较弱和寿命有限等缺点，但由于其对分析物的敏感性和特异性以及根据功能选择的各种离子通道，它们仍然是纳米生物传感应用的有趣候选者。为了克服生物纳米孔的局限性，人们对人造固体纳米孔进行了探索。所制备的固体纳米孔结构耐用，适合纳米加工工艺，但其构建难度较大，工艺通量低，缺乏天然离子通道的化学特异性[1]。生物纳米技术可以改善这种状况吗?最近的研究表明，纳米材料(纳米管、纳米线)可以被电解质门控，甚至可以被脂质双分子层包裹，允许双分子层本身带电[2]。这些报告的重点是由于纳米线/纳米管附近的电荷门控引起的源极/漏极电流的时间平均变化。因此，到目前为止，还没有纳米线/纳米管设备能够测量随时间变化的单离子通道记录。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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69th Device Research Conference

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