Stimulation and Recording Electrodes for Neural Prostheses

This book provides readers with basic principles of the electrochemistry of the electrodes used in modern, implantable neural prostheses. The authors discuss the boundaries and conditions in which the electrodes continue to function properly for long time spans, which are required when designing neural stimulator devices for long-term in vivo applications. Two kinds of electrode materials, titanium nitride and iridium are discussed extensively, both qualitatively and quantitatively. The influence of the counter electrode on the safety margins and electrode lifetime in a two electrode system is explained. Electrode modeling is handled in a final chapter.

Provides readers with a concise, single-source reference to electrodes for implantable neural prostheses Discusses a variety of issues relating to the lifetime of the electrodes used for in-vivo applications Includes coverage of electrode modeling

Auteur
Naser Pour Aryan received the B.E. degree in electrical engineering from Ferdowsi University of Mashhad, Iran, in 2005 and the M.Sc. degree in communication technology from the University of Ulm, Germany, in 2008. He received his Ph.D. degree from the University of Ulm in December 2013. He has been working as a researcher on the retinal prosthesis project at the University of Ulm since January 2008, studying and characterizing neural stimulation electrodes. Hehas had several publications on this topic. Dr. Pour Aryan's research interests include mainly electrochemistry, analog and mixed signal circuits, modeling passive electrical structures, image processing and optics.Hans Kaim received the Dipl.-Ing. degree in electrical engineeringfrom the University of Ulm, Germany, in 2013. He has been working as a researcher on the retinal prosthesis project at the University of Ulm since January 2013, investigating and characterizing neural stimulation electrodes. His research interests include electrochemistry, modeling passive electrical structures and analog and mixed signal circuits.Albrecht Rothermel (M'90, SM'95) received the Dipl.-Ing.degree in electrical engineering from the University of Dortmund,and the Dr.-Ing. (Ph.D.) degree from the University of Duisburg, both Germany, in 1984 and 1989, respectively. From 1985 to 1989, he was with the Fraunhofer Institute of Microelectronic Circuits and Systems, Duisburg, Germany, working on integrated digital CMOS and BiCMOS circuits for high-speed applications. From 1990 to 1993, he was with Thomson Consumer Electronics (Thomson multimedia), Corporate Research, Villingen-Schwenningen, Germany. He worked on digital signal processing concepts for present and future TV and HDTV sets. Then as Manager of the IC designlaboratory, he was involved in analog and mixed circuit design for audio and video. Since 1994, he has been with the Institute of Microelectronics, Universityof Ulm, Germany, as a Professor of Electrical Engineering. His research interests include analog and mixed signal circuits for various applications including implantablesensors and stimulators, and digital signal processing algorithms for video applications, mostly in automotive environments. Dr. Rothermel was a guest scientist at Thomson Multimedia in Indianapolis, USA(1997), at the Edith-Cowan University in Perth, WA (2003), and at the Shandong University in Jinan, China (2006). He has published more than 130 papers, book chapters and patents. He received the 1985 outstanding young scientist award of the German VDE, the 1991 outstanding publication award of the German GME, the 2003 award for remarkable cooperation between industry and university, and the 2006 best paper award of the IEEE ICCE. After acting as associate editor of the IEEE JSSC, TPC-Chair of the IEEE ICCE-B, and distinguished lecturer of the IEEE, he now is a member of the program committees of ESSCIRC, and ICCE. He is member of the German Society of Electrical Engineers (VDE), the German TV and Cinema Technology Society (FKTG), and senior member of the IEEE.

Contenu

Stimulation and recording electrodes: General concepts.- Irreversible and reversible redox reactions: Water window.- Charge balance and safe operation conditions.- Primary current distribution and electrode geometry.- Experiments hardware and methods.- Electrode materials: State-of-the-art and experiments.- The effect of the counter electrode on stimulation electrode lifetime.- Electrode modeling for titanium nitride, iridium and iridium oxide microelectrodes.- Summary.