细胞聚焦精度是微流式细胞仪实现精确检测的关键。利用外加电场在可极化平面上生成诱导电荷电渗（ICEO）双漩涡流，可将生物流体中的各类细胞精确聚焦于平面中央，实现高精度聚焦。然而，生物流体的非牛顿流变特性与聚离子效应会显著改变ICEO的流动特性，目前针对这一问题的研究有限。为此，本项目拟研究非牛顿生物流体的ICEO现象，并分析细胞的ICEO聚焦性能。采用幂律流体模型考察流体的非牛顿流变特性，通过考虑离子体积及扩散率的影响，改进泊松-能斯特-普朗克（PNP）方程组，为非牛顿生物流体建立完善的ICEO理论模型。通过理论与实验的双向验证，厘清流体的非牛顿流变特性与聚离子效应对ICEO流动特性与ICEO聚焦机理的作用规律，建立ICEO聚焦芯片的设计及优化准则，为高精度ICEO聚焦芯片的开发提供指导。

A precise cell focusing is the key to achieve an accurate detection of microflow cytometer. Induced-charge electroosmosis (ICEO) generated by the applied electric field forms double eddies on the polarizable plane, which can accurately focus the cells in biofluid to the center of the plane, i.e., achieve a precise focusing. The non-Newtonian rheological properties of and the polyions inside the biofluids change the flow characteristics of ICEO significantly. However, there are limited studies conducted on this issue. Therefore, this project intends to study the ICEO of non-Newtonian biofluids and investigate the ICEO focusing performance. To establish a comprehensive ICEO model of non-Newtonian biofluids, the power-law fluid model is adopted to investigate the non-Newtonian rheological properties of biofluids, and the Poisson-Nernst-Planck (PNP) equations are modified by considering the influences of ion volume and diffusivity. Through a detailed analysis of experimental data and theoretical modeling, the effects of non-Newtonian rheological properties and ion volume and diffusivity on the ICEO flow characteristics and ICEO focusing mechanism will be revealed. The design and optimization criteria of ICEO focusing will be established, which can provide guidance for the development of high-precision ICEO focusers.