Zobrazeno 1 - 5
of 5
pro vyhledávání: '"Gregory V. Junek"'
Autor:
Adam Y. Wang, Yuguo Sheng, Wanlu Li, Doohwan Jung, Gregory V. Junek, Hangxing Liu, Jongseok Park, Dongwon Lee, Mian Wang, Sushila Maharjan, Sagar Kumashi, Jin Hao, Yu S. Zhang, Kevin Eggan, Hua Wang
Publikováno v:
IEEE Transactions on Biomedical Circuits and Systems, 16 (6)
The article presents a fully integrated multimodal and multifunctional CMOS biosensing/actuating array chip and system for multi-dimensional cellular/tissue characterization. The CMOS chip supports up to 1,568 simultaneous parallel readout channels a
Autor:
Sandra I. Grijalva, Doohwan Jung, Hua Wang, Adam Wang, Hee Cheol Cho, Natasha Fernandez, Jong Seok Park, Gregory V. Junek, Sagar R. Kumashi, Sensen Li
Publikováno v:
IEEE Journal of Solid-State Circuits. 56:2438-2451
This article presents a fully integrated multi-modal CMOS cellular sensor/stimulator array chip with 21 952 pixels and 1568-pixel concurrent readouts, while each array pixel can be independently reconfigured to support three sensing and one stimulati
Publikováno v:
IEEE Transactions on NanoBioscience. 18:248-252
Electrochemical interfaces with low-impedance, high biocompatibility, and long-term stability are of paramount importance for microelectrode arrays (MEAs), that are widely used in numerous cellular sensing/stimulation applications, e.g., brain interf
Autor:
Sensen Li, Hua Wang, Adam Wang, Hee Cheol Cho, Doohwan Jung, Sandra I. Grijalva, Jong Seok Park, Sagar R. Kumashi, Gregory V. Junek
Publikováno v:
VLSI Circuits
This paper presents a fully integrated CMOS multi-modal cellular sensor/stimulator array with 21952 multi-modal pixels, 1568 simultaneous parallel readout channels, 16 μm×16 μm pixel pitch for single cell resolution, and 3.6 mm×1.6 mm tissue-leve
Autor:
Sensen Li, Jong Seok Park, Gregory V. Junek, Hee Cheol Cho, Sandra I. Grijalva, Doohwan Jung, Taiyun Chi, Hua Wang
Publikováno v:
Biosens Bioelectron
Intracellular action potential signals reveal enriched physiological information. Patch clamp techniques have been widely used to measure intracellular potential. Despite their high signal fidelity, they suffer from low throughput. Recently, 3D nanoe