Department of Physics and Astronomy, University of California at Irvine, 210G Rowland Hall, Irvine, CA 92697, USA.
Chem Soc Rev. 2010 Mar;39(3):1115-32. doi: 10.1039/b909105j. Epub 2009 Dec 4.
The creation of synthetic devices that mimic functionality of biological systems is a task of fundamental importance for the future development of bio- and nanotechnology and also an ultimate test of our understanding of the biological systems. Among a plethora of bio-inspired devices, designed nanopores and nanochannels with an embedded functionality are of particular interest because of their potential applications in nanofluidic electronics, biosensing, separation, synthetic biology, and single-molecule manipulation. In this respect, nanopores with built-in stimulus-responsive properties are of special benefit. A transmembrane potential is a particularly useful stimulus as it is non-invasive, tunable, and can act over a short time scale. This critical review considers engineered solid-state and protein nanopores with voltage-responsive properties. The engineered systems show nonlinear current-voltage curves, and/or voltage-dependent switching between discrete conductance states (141 references).
设计具有嵌入式功能的仿生纳米孔和纳米通道是生物启发式设备中的一个研究热点,因为它们在纳流电子学、生物传感、分离、合成生物学和单分子操纵等领域具有潜在的应用。在这方面,具有内置刺激响应特性的纳米孔具有特殊的优势。跨膜电势是一种特别有用的刺激,因为它是非侵入性的、可调的,并且可以在短时间内起作用。这篇综述文章考虑了具有电压响应特性的工程化固态和蛋白纳米孔。这些工程化系统表现出非线性的电流-电压曲线,以及(或)在离散电导状态之间的电压依赖性切换(141 篇参考文献)。