Your search keyword '"HOU, Wen-sheng"' showing total 2 results

1. A high-throughput dielectrophoresis-based cell electrofusion microfluidic device.

Author

Hu N, Yang J, Yin ZQ, Ai Y, Qian S, Svir IB, Xia B, Yan JW, Hou WS, and Zheng XL

Subjects

Aluminum chemistry, Equipment Design, HEK293 Cells, High-Throughput Screening Assays, Humans, Microelectrodes, Protoplasts cytology, Nicotiana cytology, Cell Fusion instrumentation, Cell Fusion methods, Electrophoresis instrumentation, Electroporation instrumentation, Microfluidic Analytical Techniques instrumentation

Abstract

A high-throughput cell electrofusion microfluidic chip has been designed, fabricated on a silicon-on-insulator wafer and tested for in vitro cell fusion under a low applied voltage. The developed chip consists of six individual straight microchannels with a 40-μm thickness conductive highly doped Si layer as the microchannel wall. In each microchannel, there are 75 pairs of counter protruding microelectrodes, between which the cell electrofusion is performed. The entire highly doped Si layer is covered by a 2-μm thickness aluminum film to maintain a consistent electric field between different protruding microelectrode pairs. A 150-nm thickness SiO₂ film is subsequently deposited on the top face of each protruding microelectrode for better biocompatibility. Owing to the short distance between two counter protruding microelectrodes, a high electric field can be generated for cell electrofusion with a low voltage imposed across the electrodes. Both mammalian cells and plant protoplasts were used to test the cell electrofusion. About 42-68% cells were aligned to form cell-cell pairs by the dielectrophoretic force. After cell alignment, cell pairs were fused to form hybrid cells under the control of cell electroporation and electrofusion signals. The averaged fusion efficiency in the paired cells is above 40% (the highest was about 60%), which is much higher than the traditional polyethylene glycol method (<5%) and traditional electrofusion methods (∼12%). An individual cell electrofusion process could be completed within 10 min, indicating a capability of high throughput., (Copyright © 2011 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2011

2. Electrophoretic motion of a spherical particle with a symmetric nonuniform surface charge distribution in a nanotube.

Author

Qian S, Joo SW, Hou WS, and Zhao X

Subjects

Algorithms, Biological Transport, Electrolytes, Electromagnetic Fields, Ions, Models, Statistical, Models, Theoretical, Motion, Osmosis, Software, Static Electricity, Surface Properties, Electrophoresis methods, Nanotubes chemistry

Abstract

The electrophoretic motion of a spherical nanoparticle, subject to an axial electric field in a nanotube filled with an electrolyte solution, has been investigated using a continuum theory, which consists of the Nernst-Planck equations for the ionic concentrations, the Poisson equation for the electric potential in the solution, and the Stokes equation for the hydrodynamic field. In particular, the effects of nonuniform surface charge distributions around the nanoparticle on its axial electrophoretic motion are examined with changes in the bulk electrolyte concentration and the surface charge of the tube's wall. A particle with a nonuniform charge distribution is shown to induce a corresponding complex ionic concentration field, which in turn influences the electric field and the fluid motion surrounding the particle and thus its electrophoretic velocity. As a result, contrary to the relatively simple dynamics of a particle with a uniform surface charge, dominated by the irradiating electrostatic force, that with a nonuniform surface charge distribution shows various intriguing behaviors due to the additional interplay of the nonuniform electro-osmotic effects.

Published

2008