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Hauptverfasser: Greenhorn, Scott, Coizet, Véronique, Dupuit, Victor, Fernandez, Bruno, Bres, Guillaume, Claudel, Arnaud, Gasner, Pierre, Warnking, Jan M., Barbier, Emmanuel L., Delacour, Cécile
Format: Preprint
Veröffentlicht: 2024
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Online-Zugang:https://arxiv.org/abs/2402.04389
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author Greenhorn, Scott
Coizet, Véronique
Dupuit, Victor
Fernandez, Bruno
Bres, Guillaume
Claudel, Arnaud
Gasner, Pierre
Warnking, Jan M.
Barbier, Emmanuel L.
Delacour, Cécile
author_facet Greenhorn, Scott
Coizet, Véronique
Dupuit, Victor
Fernandez, Bruno
Bres, Guillaume
Claudel, Arnaud
Gasner, Pierre
Warnking, Jan M.
Barbier, Emmanuel L.
Delacour, Cécile
contents Current techniques of neuroimaging, including electrical devices, are either of low spatiotemporal resolution or invasive, impeding multiscale monitoring of brain activity at both single cell and network levels. Overcoming this issue is of great importance to assess brain's computational ability and for neurorehabilitation projects that require real-time monitoring of neurons and concomitant networks activities. Currently, that information could be extracted from functional MRI when combined with mathematical models. Novel methods enabling quantitative and long-lasting recording at both single cell and network levels will allow to correlate the MRI data with intracortical activity at single cell level, and to refine those models. Here, we report the fabrication and validation of ultra-thin, optically transparent and flexible intracortical microelectrode arrays for combining extracellular multi-unit and fMRI recordings. The sensing devices are compatible with large-scale manufacturing, and demonstrate both fMRI transparency at 4.7 T, and high electrical performance, and thus appears as a promising candidate for simultaneous multiscale neurodynamic measurements.
format Preprint
id arxiv_https___arxiv_org_abs_2402_04389
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Ultrathin, flexible and MRI-compatible microelectrode array for chronic single units recording within subcortical layers
Greenhorn, Scott
Coizet, Véronique
Dupuit, Victor
Fernandez, Bruno
Bres, Guillaume
Claudel, Arnaud
Gasner, Pierre
Warnking, Jan M.
Barbier, Emmanuel L.
Delacour, Cécile
Neurons and Cognition
Mesoscale and Nanoscale Physics
Current techniques of neuroimaging, including electrical devices, are either of low spatiotemporal resolution or invasive, impeding multiscale monitoring of brain activity at both single cell and network levels. Overcoming this issue is of great importance to assess brain's computational ability and for neurorehabilitation projects that require real-time monitoring of neurons and concomitant networks activities. Currently, that information could be extracted from functional MRI when combined with mathematical models. Novel methods enabling quantitative and long-lasting recording at both single cell and network levels will allow to correlate the MRI data with intracortical activity at single cell level, and to refine those models. Here, we report the fabrication and validation of ultra-thin, optically transparent and flexible intracortical microelectrode arrays for combining extracellular multi-unit and fMRI recordings. The sensing devices are compatible with large-scale manufacturing, and demonstrate both fMRI transparency at 4.7 T, and high electrical performance, and thus appears as a promising candidate for simultaneous multiscale neurodynamic measurements.
title Ultrathin, flexible and MRI-compatible microelectrode array for chronic single units recording within subcortical layers
topic Neurons and Cognition
Mesoscale and Nanoscale Physics
url https://arxiv.org/abs/2402.04389