Combined macro-/mesoporous microelectrode arrays for low-noise extracellular recording of neural networks
Combined macro-/mesoporous microelectrode arrays for low-noise extracellular recording of neural networks
Microelectrode arrays (MEAs) are appealing tools to probe large neural ensembles and build neural prostheses. Microelectronics microfabrication technologies now allow building high-density MEAs containing several hundreds of microelectrodes. However, several major problems become limiting factors when the size of the microelectrodes decreases. In particular, regarding recording of neural activity, the intrinsic noise level of a microelectrode dramatically increases when the size becomes small (typically below 20-?m diameter). Here, we propose to overcome this limitation using a template-based, single-scale meso- or two-scale macro-/mesoporous modification of the microelectrodes, combining the advantages of an overall small geometric surface and an active surface increased by several orders of magnitude. For this purpose, standard platinum MEAs were covered with a highly porous platinum overlayer obtained by lyotropic liquid crystal templating possibly in combination with a microsphere templating approach. These porous coatings were mechanically more robust than Pt-black coating and avoid potential toxicity issues. They had a highly increased active surface, resulting in a noise level ?3 times smaller than that of conventional flat electrodes. This approach can thus be used to build highly dense arrays of small-size microelectrodes for sensitive neural signal detection.
electrophysiology, nanotechnology, neural implant, prosthesis, multielectrode, neural probes
1793-1803
Heim, M.
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Rousseau, L.
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Reculusa, S.
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Urbanova, V.
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Mazzocco, C.
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Joucla, S.
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Bouffier, L.
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Vytras, K.
907cb211-31b4-4140-80ca-c29c351c91be
Bartlett, P.
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Kuhn, A.
eb7dff86-1a0b-4e59-a49e-131ecb9bb643
Yvert, B.
00a2d0e3-db7c-4f74-af1c-e19995e7c806
15 September 2012
Heim, M.
c0fc394a-f090-40a7-a93b-dc2b7e31ab6c
Rousseau, L.
c076b5f1-3555-41fe-8679-d8f6891b7d52
Reculusa, S.
44dcf1ff-b794-4a2f-b0bc-8fcb7a2d7270
Urbanova, V.
44801006-22b4-48cd-9d56-0e74a61944d0
Mazzocco, C.
857807db-b238-47c2-a97c-3da52d3ee11a
Joucla, S.
308defff-7ada-41b4-a23d-4b8bcf35bd3a
Bouffier, L.
55db8235-5882-45ce-9346-de1cf674c4cf
Vytras, K.
907cb211-31b4-4140-80ca-c29c351c91be
Bartlett, P.
d99446db-a59d-4f89-96eb-f64b5d8bb075
Kuhn, A.
eb7dff86-1a0b-4e59-a49e-131ecb9bb643
Yvert, B.
00a2d0e3-db7c-4f74-af1c-e19995e7c806
Heim, M., Rousseau, L., Reculusa, S., Urbanova, V., Mazzocco, C., Joucla, S., Bouffier, L., Vytras, K., Bartlett, P., Kuhn, A. and Yvert, B.
(2012)
Combined macro-/mesoporous microelectrode arrays for low-noise extracellular recording of neural networks.
Journal of Neurophysiology, 108 (6), .
(doi:10.1152/jn.00711.2011).
Abstract
Microelectrode arrays (MEAs) are appealing tools to probe large neural ensembles and build neural prostheses. Microelectronics microfabrication technologies now allow building high-density MEAs containing several hundreds of microelectrodes. However, several major problems become limiting factors when the size of the microelectrodes decreases. In particular, regarding recording of neural activity, the intrinsic noise level of a microelectrode dramatically increases when the size becomes small (typically below 20-?m diameter). Here, we propose to overcome this limitation using a template-based, single-scale meso- or two-scale macro-/mesoporous modification of the microelectrodes, combining the advantages of an overall small geometric surface and an active surface increased by several orders of magnitude. For this purpose, standard platinum MEAs were covered with a highly porous platinum overlayer obtained by lyotropic liquid crystal templating possibly in combination with a microsphere templating approach. These porous coatings were mechanically more robust than Pt-black coating and avoid potential toxicity issues. They had a highly increased active surface, resulting in a noise level ?3 times smaller than that of conventional flat electrodes. This approach can thus be used to build highly dense arrays of small-size microelectrodes for sensitive neural signal detection.
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More information
e-pub ahead of print date: 27 June 2012
Published date: 15 September 2012
Keywords:
electrophysiology, nanotechnology, neural implant, prosthesis, multielectrode, neural probes
Organisations:
Electrochemistry
Identifiers
Local EPrints ID: 349757
URI: http://eprints.soton.ac.uk/id/eprint/349757
ISSN: 0022-3077
PURE UUID: d054ef59-03c5-4b1f-bcbc-fa9f1c7eea9d
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Date deposited: 08 Mar 2013 17:34
Last modified: 15 Mar 2024 02:44
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Contributors
Author:
M. Heim
Author:
L. Rousseau
Author:
S. Reculusa
Author:
V. Urbanova
Author:
C. Mazzocco
Author:
S. Joucla
Author:
L. Bouffier
Author:
K. Vytras
Author:
A. Kuhn
Author:
B. Yvert
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