固态纳米孔流体动力学与输运

Solid-state nanopore hydrodynamics and transport.

作者信息

Ghosal Sandip, Sherwood John D, Chang Hsueh-Chia

机构信息

Department of Mechanical Engineering and Engineering Sciences and Applied Mathematics, Northwestern University, Evanston, Illinois 60208, USA.

Department of Applied Mathematics and Theoretical Physics, University of Cambridge, Wilberforce Road, Cambridge CB3 0WA, United Kingdom.

出版信息

Biomicrofluidics. 2019 Jan 30;13(1):011301. doi: 10.1063/1.5083913. eCollection 2019 Jan.

DOI:10.1063/1.5083913

PMID:30867871

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC6404949/

Abstract

The resistive pulse method based on measuring the ion current trace as a biomolecule passing through a nanopore has become an important tool in biotechnology for characterizing molecules. A detailed physical understanding of the translocation process is essential if one is to extract the relevant molecular properties from the current signal. In this Perspective, we review some recent progress in our understanding of hydrodynamic flow and transport through nanometer sized pores. We assume that the problems of interest can be addressed through the use of the continuum version of the equations of hydrodynamic and ion transport. Thus, our discussion is restricted to pores of diameter greater than about ten nanometers: such pores are usually synthetic. We address the fundamental nanopore hydrodynamics and ion transport mechanisms and review the wealth of observed phenomena due to these mechanisms. We also suggest future ionic circuits that can be synthesized from different ionic modules based on these phenomena and their applications.

摘要

基于测量生物分子通过纳米孔时的离子电流迹线的电阻脉冲法，已成为生物技术领域用于表征分子的重要工具。如果要从电流信号中提取相关分子特性，对转运过程进行详细的物理理解至关重要。在这篇综述中，我们回顾了在理解流体动力学流动以及通过纳米尺寸孔隙的传输方面的一些最新进展。我们假定，感兴趣的问题可以通过使用流体动力学和离子传输方程的连续介质版本来解决。因此，我们的讨论仅限于直径大于约十纳米的孔隙：此类孔隙通常是合成的。我们阐述了基本的纳米孔流体动力学和离子传输机制，并回顾了由这些机制所观察到的大量现象。我们还基于这些现象及其应用，提出了未来可由不同离子模块合成的离子电路。

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