Micropatterning with different cell types by dielectrophoretic manipulation

2007 International Symposium on Micro-NanoMechatronics and Human Science Pub Date : 2007-11-01 DOI:10.1109/MHS.2007.4420848

T. Yasukawa, Masato Suzuki, H. Shiku, T. Matsue

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引用次数: 1

Abstract

In this paper, a versatile, rapid and reproducible method for patterning different cell types based on negative dielectrophoresis (n-DEP), without any special pretreatment of a culture slide, has been described. An interdigitated array (IDA) electrode with four independent microelectrode subunits was fabricated with indium-tin-oxide (ITO) and used as a template to form cellular micropatterns. A suspension of C2C12 cells was introduced into the device between the upper slide and the bottom IDA. In the present system, the n-DEP force is induced by applying an ac voltage (typically 12 Vpp, 1 MHz) to direct cells toward a weaker region of electric field strength. The cells aligned above one of the bands of IDA within 1 min since the aligned areas on the slide were regions with the lower electric field. The application of an ac voltage for 5 min allows the cells to adsorb onto the cell culture slide. After disassembling the device and removing excess cells, the culture slide was assembled again with the IDA electrode, and was rotated 90deg relative to the previous setup. The second cell type was patterned in lines using the same method as with the first set of cells, forming a grid pattern on the slide.

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介电泳处理不同细胞类型的微图案化

在本文中，描述了一种通用，快速和可重复的方法，用于基于负介电电泳(n-DEP)的不同细胞类型的图案，而无需任何特殊的培养载玻片预处理。用氧化铟锡(ITO)制备了具有四个独立微电极亚基的交错排列电极(IDA)，并将其作为模板形成细胞微图案。将C2C12细胞悬浮液引入上载片和下IDA之间的装置中。在目前的系统中，n-DEP力是通过施加交流电压(通常为12 Vpp, 1 MHz)来诱导细胞向电场强度较弱的区域移动。细胞在1分钟内排列在IDA的一个条带上，因为在玻片上排列的区域是电场较低的区域。施加交流电压5分钟，使细胞吸附到细胞培养载玻片上。拆卸装置并去除多余的细胞后，用IDA电极再次组装培养载片，并相对于先前的设置旋转90度。第二种细胞类型使用与第一组细胞相同的方法成行，在载玻片上形成网格图案。

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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2007 International Symposium on Micro-NanoMechatronics and Human Science

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