Lopez et al., 2017 - Google Patents
A Neural Probe with Up to 966 Electrodes and Up to 384 Configurable Channels in 0.13$\mu $ m SOI CMOSLopez et al., 2017
View PDF- Document ID
- 4551146455600236222
- Author
- Lopez C
- Putzeys J
- Raducanu B
- Ballini M
- Wang S
- Andrei A
- Rochus V
- Vandebriel R
- Severi S
- Van Hoof C
- Musa S
- Van Helleputte N
- Yazicioglu R
- Mitra S
- Publication year
- Publication venue
- IEEE transactions on biomedical circuits and systems
External Links
Snippet
In vivo recording of neural action-potential and local-field-potential signals requires the use of high-resolution penetrating probes. Several international initiatives to better understand the brain are driving technology efforts towards maximizing the number of recording sites …
- 239000000523 sample 0 title abstract description 80
Similar Documents
| Publication | Publication Date | Title |
|---|---|---|
| Lopez et al. | A Neural Probe with Up to 966 Electrodes and Up to 384 Configurable Channels in 0.13$\mu $ m SOI CMOS | |
| Lopez et al. | An implantable 455-active-electrode 52-channel CMOS neural probe | |
| De Dorigo et al. | Fully immersible subcortical neural probes with modular architecture and a delta-sigma ADC integrated under each electrode for parallel readout of 144 recording sites | |
| Chae et al. | Design optimization for integrated neural recording systems | |
| Lopez et al. | A multimodal CMOS MEA for high-throughput intracellular action potential measurements and impedance spectroscopy in drug-screening applications | |
| Ballini et al. | A 1024-channel CMOS microelectrode array with 26,400 electrodes for recording and stimulation of electrogenic cells in vitro | |
| Lopez et al. | 22.7 A 966-electrode neural probe with 384 configurable channels in 0.13 µm SOI CMOS | |
| Dragas et al. | In vitro multi-functional microelectrode array featuring 59 760 electrodes, 2048 electrophysiology channels, stimulation, impedance measurement, and neurotransmitter detection channels | |
| CN111936044B (en) | Sensor array, method for operating a sensor array and computer program for executing a method for operating a sensor array | |
| Han et al. | A 0.45 V 100-Channel Neural-Recording IC With Sub-$\mu {\rm W} $/Channel Consumption in 0.18$\mu {\rm m} $ CMOS | |
| Guo et al. | A 200-channel area-power-efficient chemical and electrical dual-mode acquisition IC for the study of neurodegenerative diseases | |
| Wendler et al. | A 0.0046-mm 2 two-step incremental delta–sigma analog-to-digital converter neuronal recording front end with 120-mvpp offset compensation | |
| Abbott et al. | The design of a CMOS nanoelectrode array with 4096 current-clamp/voltage-clamp amplifiers for intracellular recording/stimulation of mammalian neurons | |
| Schröder et al. | CMOS-compatible purely capacitive interfaces for high-density in-vivo recording from neural tissue | |
| Cisneros-Fernández et al. | A 1024-Channel 10-Bit 36-$\mu $ W/ch CMOS ROIC for Multiplexed GFET-Only Sensor Arrays in Brain Mapping | |
| Wang et al. | A current-mode capacitively-coupled chopper instrumentation amplifier for biopotential recording with resistive or capacitive electrodes | |
| Shadmani et al. | Stimulation and artifact-suppression techniques for in vitro high-density microelectrode array systems | |
| Pérez-Prieto et al. | Recording strategies for high channel count, densely spaced microelectrode arrays | |
| Kuhl et al. | A 0.01 mm 2 fully-differential 2-stage amplifier with reference-free CMFB using an architecture-switching-scheme for bandwidth variation | |
| CN116963668A (en) | Sensor array, method of operating a sensor array, and computer program for executing a method for operating a sensor array | |
| De Dorigo et al. | A fully immersible deep-brain neural probe with modular architecture and a delta-sigma ADC integrated under each electrode for parallel readout of 144 recording sites | |
| JPWO2019154989A5 (en) | ||
| Lee et al. | A 1-v 4.6-mw/channel fully differential neural recording front-end ic with current-controlled pseudoresistor in 0.18-mm cmos | |
| Anderson et al. | Wireless integrated circuit for the acquisition of electrocorticogram signals | |
| Cha et al. | A CMOS microelectrode array system with reconfigurable sub-array multiplexing architecture integrating 24,320 electrodes and 380 readout channels |