Electrodes

doi:10.1017/CBO9780511979958.002

2 - Electrodes

Published online by Cambridge University Press: 05 October 2012

Thomas Stieglitz

Edited by

Romain Brette and

Alain Destexhe

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Thomas Stieglitz: Affiliation:
Albert-Ludwig-University of Freiburg, Germany
Romain Brette: Affiliation:
Ecole Normale Supérieure, Paris
Alain Destexhe: Affiliation:
Centre National de la Recherche Scientifique (CNRS), Paris

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Summary

Introduction

Electrodes are the first technical interface in a system for recording bioelectrical potentials. The electrochemical and biological processes at the material–tissue interface determine the signal transfer properties and are of utmost importance for the long-term behavior of a chronic implant. Here, “electrode” is used for the whole device that consists of one or multiple active recording sites, a substrate that carries these active sites, as well as interconnections, wires, insulation layers and the connectors to the next stage of a complete recording system, whether it is wire bound or wireless. The application of the electrodes in fundamental neuroscience, diagnosis, therapy, or rehabilitation determines their target specifications. The most important factors are the application site, extracorporal device or implant, acute or chronic contact, size of the electrode (device) and the recording sites, number of active sites on a device, geometrical arrangement of electrodes and type of signal to be recorded. They influence the selection process of electrodes suitable for an envisioned application and help engineers as well as neuroscientists to choose the very best materials for the active sites, substrate and insulation and the most appropriate manufacturing technique. The properties of the recorded signals are also strongly related to this selection process since the tailoring of the transfer characteristics helps to pick up the “right” signal components and to ignore, neglect and reject the “wrong” electrical potentials that might be due to the body itself or the surrounding environment or interference caused by noise from the electrode sites and the amplifier of the recording system.

Type: Chapter
Information: Handbook of Neural Activity Measurement , pp. 8 - 43

DOI: https://doi.org/10.1017/CBO9780511979958.002 [Opens in a new window]

Publisher: Cambridge University Press

Print publication year: 2012

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References

Bai, Q., Wise, K. D. and Anderson, D. J. (2000). A high-yield microassembly structure for three-dimensional microelectrode arrays. IEEE Trans. Biomed. Eng., 47, 281–289.Google Scholar PubMed

Boretius, T., Badia, J., Pascual-Font, A., Schuettler, M., Navarro, X., Yoshida, K. and Stieglitz, T. (2010). A transversal intrafascicular multichannel electrode (TIME) to interface with the peripheral nerve. Biosens. Bioelectron., 26, 62–69.CrossRef Google Scholar

Brumberg, J. S., Nieto-Castanon, A., Kennedy, P. R. and Guenther, F. H. (2010). Brain–computer interfaces for speech communication. Speech Commun., 52 (4), 367–379.CrossRef Google Scholar PubMed

Campbell, P. K., Jones, K. E., Huber, R. J., Horch, K. W. and Normann, R. A. (1991). A silicon-based three-dimensional neural interface: manufacturing process for an intracortical electrode array. IEEE Bio-Med. Eng., 38, 758–768.Google Scholar

Cordeiro, J., Henle, C., Raab, M., Meier, W., Stieglitz, T., Schulze-Bonhage, A. and Rickert, J. (2008). Micromanufactured electrode for cortical field potentials recording: in vivo study. In: J., van der Sloten, P., Verdonck, M., Nyssen and L., Haueisen (editors), ECIFMBE 2008, IFMBE Proceedings 22, pp. 2375–2378.Google Scholar

Delbeke, J. (2004). Biocompatibility. Workshop on Implanted Device Technology, Annual Conference of the International Functional Electrical Stimulation Society, 4 September, Bournemouth, UK.Google Scholar

Fricke, H. (1932). The theory of electrolytic polarization. Philos. Mag., 14, 310–318.CrossRef Google Scholar

Henle, C., Raab, M., Cordeiro, J., Prinz, M., Doostkam, S., Stieglitz, T., Schulze-Bonhage, A. and Rickert, J. (2010). First long term in vivo biocompatibility assessment on subdurally implanted micro-ECoG electrodes, manufactured with a novel laser technology. Biomed. Microdev., DOI 10.1007/s10544-010-9471-9.Google Scholar

Hochberg, L. R., Serruya, M. D., Friehs, G. M., Mukand, J. A., Saleh, M., Caplan, A. H., Branner, A., Chen, D., Penn, R. D. and Donoghue, J. P. (2006). Neuronal ensemble control of prosthetic devices by a human with tetraplegia. Nature, 442, 164–171.CrossRef Google Scholar PubMed

Hoogerwerf, A. C. and Wise, K. D. (1994). A three-dimensional microelectrode array for chronic neural recording. IEEE Trans. BioMed. Eng., 41, 1136–1146.CrossRef Google Scholar PubMed

Kennedy, P. R. (1989). The cone electrode: a long-term electrode that records from neurites grown onto its recording surface. J. Neurosci. Methods, 29, 181–193.CrossRef Google Scholar PubMed

Kim, C. and Wise, K. D. (1996). A 64-site multishank CMOS low-profile neural stimulating probe. IEEE J. Solid-State Circuits, 31, 1230–1238.Google Scholar

Lide, D. R. (2003). CRC Handbook on Chemistry and Physics (83rd edition). Boca Raton, FL: CRC Press.Google Scholar

Loeb, G. E., Peck, R. A. and Martyniuk, J. (1995). Towards the ultimate metal microelectrode. J. Neurosci. Methods, 63, 175–183.CrossRef Google Scholar

McAdams, E. and Jossinet, J. (1994a). The detection of the onset of electrode–electrolyte interface impedance nonlinearity: a theoretical study. IEEE Trans. Biomed. Eng., 41(5), 498–499.CrossRef Google Scholar PubMed

McAdams, E. and Jossinet, J. (1994b). Physical interpretation of Schwan's limit voltage of linearity. Med. Biol. Eng. Comput., 32, 126–130.CrossRef Google Scholar PubMed

McAdams, E. T., McLaughlin, J. A. and Holder, D. S. (1992). Neurosensors: a review of some fundamental electrode parameters. Satellite Symposium on Neuroscience and Technology, Ann. Int. Conf. IEEE Eng. Med. Biol. Soc., 226–234.Google Scholar

McAdams, E., Lackermeier, A., McLaughlin, J. A., Macken, D. and Jossinet, J. (1995). The linear and non-linear electrical properties of the electrode–electrolyte interface. Biosens. Bioelectron., 10, 67–74.CrossRef Google Scholar

Meyer-Waarden, K. (1985). Bioelektrische Signale und ihre Ableitverfahren. Stuttgart: Schattauer-Verlag.Google Scholar

Nagel, J. H. (2000). Biopotential amplifiers. In: J., Bronzino (editor), Biomedical Engineering Handbook, Heidelberg: Springer-Verlag.Google Scholar

Najafi, K. and Wise, K. D. (1986). An implantable multielectrode array with on-chip signal processing. IEEE J. Solid-State Circuits, 21, 1035–1044.CrossRef Google Scholar

Nelson, M. J., Pouget, P., Nilsen, E. A., Patten, C. D. and Schall, J. D. (2008). Review of signal distortion through metal microelectrodes recording circuits and filters. J. Neurosci. Methods, 168, 141–157.Google Scholar

Nicolelis, M. A. L., Dimitrov, D., Carmena, J. M., Crist, R., Lehew, G., Kralik, J. D. and Wise, S. P. (2003). Chronic, multisite,multielectrode recordings in macaque monkeys. Proc. Natl. Acad. Sci. USA, 100, 11041–11046.CrossRef Google Scholar PubMed

Nordhausen, C. T., Maynard, E. M. and Normann, R. A. (1996). Single unit recording capabilities of a 100 microclectrode array. Brain Res., 726, 129–140.CrossRef Google Scholar PubMed

Polikov, V. S., Tresco, P. A. and Reichert, W. M. (2005). Response of brain tissue to chronically implanted neural electrodes. J. Neurosci. Methods, 148, 1–18.CrossRef Google Scholar PubMed

Schwan, H. P. (1992). Linear and nonlinear electrode polarization and biological materials. Ann. Biomed. Eng., 20, 269–288.CrossRef Google Scholar PubMed

Stensaas, S. S. and Stensaas, L. J. (1978). Histopathological evaluation of materials implanted in the cerebral cortex. Acta Neuropathol., 41, 145–155.CrossRef Google Scholar PubMed

Stern, O. (1924). Zur Theorie der Elekrolytischen Doppelschicht. Z. Elektrochem., 30, 508.Google Scholar

Stieglitz, T. (2004). Electrode materials for recording and stimulation. In: K., Horch and G., Dhillon (editors), NEUROPROSTHETICS: Theory and Practice (Series on Bioengineering and Biomedical Engineering, vol 2). Singapore: World Scientific, pp. 471–516.Google Scholar

Stieglitz, T. and Meyer, J.-U. (2006a). Neural implants in clinical practice. In: G. A., Urban (editor), BIOMEMS, Dordrecht: Springer-Verlag, pp. 41–70.Google Scholar

Stieglitz, T. and Meyer, J.-U. (2006b). Biomedical microdevices for neural implants. In: G. A., Urban (editor), BIOMEMS, Dordrecht: Springer-Verlag, pp. 71–138.Google Scholar

Stieglitz, T., Rubehn, B., Henle, C., Kisban, S., Herwik, S., Ruther, P. and Schuettler, M. (2009). Brain–computer interfaces: an overview of the hardware to record neural signals from the cortex. In: J., Verhaagen, E. M., Hol, I., Huitinga, J., Wijnhold, A. B., Bergen, G. J., Boer and D. F., Swaab (editors), Neurotherapy Progress in Restorative Neuroscience and Neurology Prog. Brain Res., 175, 297–315.Google Scholar

Tietze, U. and Schenk, Ch. (2002). Halbleiterschaltungstechnik (12th edition). Berlin: Springer-Verlag.Google Scholar

Williams, D. F. (2008). On the mechanisms of biocompatibility. Biomater., 29, 2841–2953.CrossRef Google Scholar PubMed

Wise, K. D., Angell, J. B. and Starr, A. (1969). An integrated circuit approach to extracellular microelectrodes. 8th ICMBE, Palmer House, Chicago, IL, 20 July 1969. Digest of the 8th ICMBE, vol 1, p. 14.Google Scholar

Wise, K. D., Anderson, D. J., Hetke, J. F., Kipke, D. R. and Najafi, K. (2004). Wireless implantable microsystems: high-density electronic interfaces to the nervous system. Proc. IEEE, 92, 76–96.CrossRef Google Scholar

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