利用电场对芯片上的活细胞进行纳米操作:一般概念和微器件

2010 Fifth IEEE International Symposium on Electronic Design, Test & Applications Pub Date : 2010-01-13 DOI:10.1109/DELTA.2010.26

J. Villemejane, G. Mottet, O. Français, B. Pioufle, J. Lefevre, M. Woytasik, E. Dufour-Gergam, L. Mir

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引用次数: 3

摘要

众所周知，直接连续(DC)，脉冲(PEF)或交替(AC)电场可诱导对活细胞或分子(包括DNA和蛋白质)的特定作用，并且通常用于分子或细胞生物学，最近用于临床治疗。药理学工业和医学研究对新工具的开发很感兴趣，这些新工具允许理解与某些疾病有关的生物物理或生化现象。它们将允许更精确地分析蛋白质途径，处理大量细胞或使用相同的设备执行完整的反应或过程。小型化是实现这些目标的最佳途径，它将许多功能集成在同一基板上，并利用其能力并行化某些过程。这里介绍了在微流控装置中主动处理和处理细胞的最新结果。我们特别介绍了最近在细胞融合和电子异常操作方面的成就。

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Nanomanipulation of Living Cells on a Chip Using Electric Field: General Concepts and Microdevices

Direct continuous (DC), pulsed (PEF) or alternative (AC) electric fields are well-known to induce specific effects on living cells or on molecules (including DNA and proteins) and are commonly used in molecular or cellular biology, and more recently for clinical treatment. Pharmacological industries and medical research are interesting in the development of new tools permitting to understand biophysical or biochemical phenomena involved in some diseases. They will permit to analyze more precisely protein pathways, to treat a large number of cells or to perform a complete reaction or process with the same device. Miniaturization is the best way to achieve these goals by integrating a lot of functions on the same substrate and by using the capabilities to parallelize some process.Here are presented recent results on active handling and treatment of cells in a microfluidic device. In particular we present recent achievements concerning cell fusion and electronanomanipulation.

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2010 Fifth IEEE International Symposium on Electronic Design, Test & Applications

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