利用芯片上的磁驱动微型机器人实现卵母细胞的高速去核

2012 7th IEEE International Conference on Nano/Micro Engineered and Molecular Systems (NEMS) Pub Date : 2012-03-05 DOI:10.1109/NEMS.2012.6196794

M. Hagiwara, A. Ichikawa, T. Kawahara, F. Arai

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引用次数: 2

摘要

我们开发了一种新型微流控芯片，用于磁驱动微型机器人卵母细胞去核。研制了永磁体驱动的硅镍复合材料微型机器人，并将其作为大功率、高速、高精度的微臂用于微流控芯片中猪卵母细胞的输送、旋转和切割。已开发的微型机器人的新颖之处如下。1)微机器人的驱动频率能力比之前开发的微机器人提高了10倍。2)硅镍复合材料微机器人无生物相容性风险。永磁体可以输出千牛顿数量级的力。微流控芯片是通过有限元流体分析专门设计的，用于将卵母细胞从入口稳定地供应到MMT操作区。这种高速微机器人和微流控芯片的集成使得在微流控芯片中实现高通量去核过程。

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High speed enucleation of oocyte using magnetically actuated microrobot on a chip

We have developed novel microfluidic chip for enucleation of oocytes by magnetically actuated microrobots. Si and Ni composite microrobot driven by permanent magnets was developed and used as high power, high speed and high accuracy microarm to transport, rotate and cut swine oocyte in a microfluidic chip. The novelties of developed microrobot are as follows. 1) The drive frequency capability of microrobot improved by 10 times comparing to previously developed microrobot. 2) Si-Ni composite microrobot has no risk of biocompatibility. 3) A force of order of millinewton can be outputted from permanent magnets. The microfluidic chip was specially designed by fluid analysis of FEM for stable supply of the oocytes to the MMT manipulation area from the inlet. The integration of this high speed microrobot and microfluidic chip enables high throughput enucleation process in a microfluidic chip.

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2012 7th IEEE International Conference on Nano/Micro Engineered and Molecular Systems (NEMS)

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