Title :
Long-term cortical recordings with microactuated microelectrodes
Author :
Jackson, Nathan ; Stice, Paula ; Okandan, Murat ; Muthuswamy, Jit
Abstract :
Current microelectrode array technologies often fail over a period of time presumably due to brain tissue reaction and micromotion around the implant site. We report here long-term cortical recordings from our novel microactuated microelectrode array technology. Our technology uses electro-thermal microactuators to move each of the three highly doped thin (~4mum thick) polysilicon microelectrodes in the array. Multi-unit activity in n=2 rodents was monitored for a period of over 12 weeks. High-quality multi-unit data with noise levels less than 10 muV peak-to-peak and signal levels ranging from 100 muV to 5 mV (peak-to-peak) were obtained over the entire duration of study. The results of this study demonstrate the long-term recording capability of the microactuated microelectrodes in rodent models.
Keywords :
biomedical electrodes; brain; elemental semiconductors; microactuators; microelectrodes; neurophysiology; prosthetics; silicon; MEMS; brain implants; brain tissue reaction; cortical recordings; electro-thermal microactuators; microactuated microelectrodes; microelectrode array technology; micromotion; movable microprobes; neural prosthesis; polysilicon microelectrodes; Biological materials; Brain; Condition monitoring; Implants; Microactuators; Microelectrodes; Micromechanical devices; Probes; Rodents; Wire; MEMS; Movable microprobes; brain implants; neural prosthesis; polysilicon;
Conference_Titel :
Neural Engineering, 2007. CNE '07. 3rd International IEEE/EMBS Conference on
Conference_Location :
Kohala Coast, HI
Print_ISBN :
1-4244-0792-3
Electronic_ISBN :
1-4244-0792-3
DOI :
10.1109/CNE.2007.369632
