系统由一个电化学微电极阵列和两个光寻址电位传感器组成。
It combines an Au microelectrodes array (AuMEA) with two light-addressable potentiometric sensors (LAPS) on a silicon substrate.
综述了目前国际上基于微电极阵列技术的细胞传感器芯片的研究状况。
This paper reports the development of a novel microelectrode array, based cell sensor recording platform with the fabrication of microelectrode array MEA.
该装置包括微电极阵列芯片、信号通路控制部分、刺激信号产生及编码 部分。
The device comprises microelectrode array chip, signal path control part, stimulation signal generation part and coding part.
采用微加工技术将芯片的细胞电融合小室制作成微电极阵列以实现细胞的大量融合,提高细胞的融合效率。
The cell fusion room of chip was completed by MEMS and made into an array of the microelectrode to realize huge cell fusion and to improve the efficiency of cell fusion.
为研究表面型人工视网膜微电极阵列在人眼压力环境下的位移,特别设计了多种微电极阵列,进行了应力仿真。
To study the displacement of MEA under the stress of eye, different kinds of electrodes were designed and stress simulation was carried out in the design process.
各种视觉假体刺激的部位不同,但是基本功能是相同的,都需要将外界的光信号转换为可用的电流脉冲,通过微电极阵列刺激相关部位产生光幻视。
All visual prostheses have the same function: converting outside optical signal to certain current pulses and stimulating the relevant parts by the micro-electrode array to generated phosphenes.
各种视觉假体刺激的部位不同,但是基本功能是相同的,都需要将外界的光信号转换为可用的电流脉冲,通过微电极阵列刺激相关部位产生光幻视。
All visual prostheses have the same function: converting outside optical signal to certain current pulses and stimulating the relevant parts by the micro-electrode array to generated phosphenes.
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