Optogenetic micro-electrocorticography for modulating and localizing cerebral cortex activity
Objective. Spatial localization of neural activity from within the brain with electrocorticography (ECoG) and electroencephalography remains a challenge in clinical and research settings, and while microfabricated ECoG (micro-ECoG) array technology continues to improve, complementary methods to simu...
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th-mahidol.338282018-11-09T10:07:32Z Optogenetic micro-electrocorticography for modulating and localizing cerebral cortex activity Thomas J. Richner Sanitta Thongpang Sarah K. Brodnick Amelia A. Schendel Ryan W. Falk Lisa A. Krugner-Higby Ramin Pashaie Justin C. Williams University of Wisconsin Madison Mahidol University University of Wisconsin Milwaukee University of Wisconsin Madison, School of Veterinary Medicine Engineering Neuroscience Objective. Spatial localization of neural activity from within the brain with electrocorticography (ECoG) and electroencephalography remains a challenge in clinical and research settings, and while microfabricated ECoG (micro-ECoG) array technology continues to improve, complementary methods to simultaneously modulate cortical activity while recording are needed. Approach. We developed a neural interface utilizing optogenetics, cranial windowing, and micro-ECoG arrays fabricated on a transparent polymer. This approach enabled us to directly modulate neural activity at known locations around micro-ECoG arrays in mice expressing Channelrhodopsin-2. We applied photostimuli varying in time, space and frequency to the cortical surface, and we targeted multiple depths within the cortex using an optical fiber while recording micro-ECoG signals. Main results. Negative potentials of up to 1.5 mV were evoked by photostimuli applied to the entire cortical window, while focally applied photostimuli evoked spatially localized micro-ECoG potentials. Two simultaneously applied focal stimuli could be separated, depending on the distance between them. Photostimuli applied within the cortex with an optical fiber evoked more complex micro-ECoG potentials with multiple positive and negative peaks whose relative amplitudes depended on the depth of the fiber. Significance. Optogenetic ECoG has potential applications in the study of epilepsy, cortical dynamics, and neuroprostheses. © 2014 IOP Publishing Ltd. 2018-11-09T02:14:00Z 2018-11-09T02:14:00Z 2014-02-01 Article Journal of Neural Engineering. Vol.11, No.1 (2014) 10.1088/1741-2560/11/1/016010 17412552 17412560 2-s2.0-84892715139 https://repository.li.mahidol.ac.th/handle/123456789/33828 Mahidol University SCOPUS https://www.scopus.com/inward/record.uri?partnerID=HzOxMe3b&scp=84892715139&origin=inward |
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Engineering Neuroscience Thomas J. Richner Sanitta Thongpang Sarah K. Brodnick Amelia A. Schendel Ryan W. Falk Lisa A. Krugner-Higby Ramin Pashaie Justin C. Williams Optogenetic micro-electrocorticography for modulating and localizing cerebral cortex activity |
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Objective. Spatial localization of neural activity from within the brain with electrocorticography (ECoG) and electroencephalography remains a challenge in clinical and research settings, and while microfabricated ECoG (micro-ECoG) array technology continues to improve, complementary methods to simultaneously modulate cortical activity while recording are needed. Approach. We developed a neural interface utilizing optogenetics, cranial windowing, and micro-ECoG arrays fabricated on a transparent polymer. This approach enabled us to directly modulate neural activity at known locations around micro-ECoG arrays in mice expressing Channelrhodopsin-2. We applied photostimuli varying in time, space and frequency to the cortical surface, and we targeted multiple depths within the cortex using an optical fiber while recording micro-ECoG signals. Main results. Negative potentials of up to 1.5 mV were evoked by photostimuli applied to the entire cortical window, while focally applied photostimuli evoked spatially localized micro-ECoG potentials. Two simultaneously applied focal stimuli could be separated, depending on the distance between them. Photostimuli applied within the cortex with an optical fiber evoked more complex micro-ECoG potentials with multiple positive and negative peaks whose relative amplitudes depended on the depth of the fiber. Significance. Optogenetic ECoG has potential applications in the study of epilepsy, cortical dynamics, and neuroprostheses. © 2014 IOP Publishing Ltd. |
| author2 |
University of Wisconsin Madison |
| author_facet |
University of Wisconsin Madison Thomas J. Richner Sanitta Thongpang Sarah K. Brodnick Amelia A. Schendel Ryan W. Falk Lisa A. Krugner-Higby Ramin Pashaie Justin C. Williams |
| format |
Article |
| author |
Thomas J. Richner Sanitta Thongpang Sarah K. Brodnick Amelia A. Schendel Ryan W. Falk Lisa A. Krugner-Higby Ramin Pashaie Justin C. Williams |
| author_sort |
Thomas J. Richner |
| title |
Optogenetic micro-electrocorticography for modulating and localizing cerebral cortex activity |
| title_short |
Optogenetic micro-electrocorticography for modulating and localizing cerebral cortex activity |
| title_full |
Optogenetic micro-electrocorticography for modulating and localizing cerebral cortex activity |
| title_fullStr |
Optogenetic micro-electrocorticography for modulating and localizing cerebral cortex activity |
| title_full_unstemmed |
Optogenetic micro-electrocorticography for modulating and localizing cerebral cortex activity |
| title_sort |
optogenetic micro-electrocorticography for modulating and localizing cerebral cortex activity |
| publishDate |
2018 |
| url |
https://repository.li.mahidol.ac.th/handle/123456789/33828 |
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1763495103307972608 |