Automated in vivo patch-clamp evaluation of extracellular multielectrode array spike recording capability

Brian D. Allen; Caroline Moore-Kochlacs; Jacob G. Bernstein; Justin P. Kinney; Jorg Scholvin; Luís F. Seoane; Chris Chronopoulos; Charlie Lamantia; Suhasa B. Kodandaramaiah; Max Tegmark; Edward S. Boyden

doi:10.1152/jn.00650.2017

Automated in vivo patch-clamp evaluation of extracellular multielectrode array spike recording capability

Brian D. Allen, Caroline Moore-Kochlacs, Jacob G. Bernstein, Justin P. Kinney, Jorg Scholvin, Luís F. Seoane, Chris Chronopoulos, Charlie Lamantia, Suhasa B. Kodandaramaiah, Max Tegmark, Edward S. Boyden

Mechanical Engineering

Research output: Contribution to journal › Article › peer-review

13 Scopus citations

Abstract

Much innovation is currently aimed at improving the number, density, and geometry of electrodes on extracellular multielectrode arrays for in vivo recording of neural activity in the mammalian brain. To choose a multielectrode array configuration for a given neuroscience purpose, or to reveal design principles of future multielectrode arrays, it would be useful to have a systematic way of evaluating the spike recording capability of such arrays. We describe an automated system that performs robotic patch-clamp recording of a neuron being simultaneously recorded via an extracellular multielectrode array. By recording a patch-clamp data set from a neuron while acquiring extracellular recordings from the same neuron, we can evaluate how well the extracellular multielectrode array captures the spiking information from that neuron. To demonstrate the utility of our system, we show that it can provide data from the mammalian cortex to evaluate how the spike sorting performance of a close-packed extracellular multielectrode array is affected by bursting, which alters the shape and amplitude of spikes in a train. We also introduce an algorithmic framework to help evaluate how the number of electrodes in a multielectrode array affects spike sorting, examining how adding more electrodes yields data that can be spike sorted more easily. Our automated methodology may thus help with the evaluation of new electrode designs and configurations, providing empirical guidance on the kinds of electrodes that will be optimal for different brain regions, cell types, and species, for improving the accuracy of spike sorting. NEW & NOTEWORTHY We present an automated strategy for evaluating the spike recording performance of an extracellular multielectrode array, by enabling simultaneous recording of a neuron with both such an array and with patch clamp. We use our robot and accompanying algorithms to evaluate the performance of multielectrode arrays on supporting spike sorting.

Original language	English (US)
Pages (from-to)	2182-2200
Number of pages	19
Journal	Journal of neurophysiology
Volume	120
Issue number	5
DOIs	https://doi.org/10.1152/jn.00650.2017
State	Published - Nov 2018

Bibliographical note

Funding Information:
S. B. Kodandaramaiah was supported by an MIT McGovern Institute Neurotechnology (MINT) grant, the Minnesota Discovery, Research and Innovation Economy (MnDRIVE) fund, and NIH Grant R21NS103098-01. C. Chronopoulos, C. Lamantia, and J. P. Kinney acknowledge support from NIH Grant 1R43MH101943. M. Tegmark acknowledges NSF 6937191 and the Rothberg Family Foundation. E. S. Boyden acknowledges support from NIH Grants 1R01EY023173, 1R24MH106075, 1R43MH101943, 1R01NS102727, 2R01DA029639, and Director’s Pioneer Award 1DP1NS087724, as well as the MIT Media Laboratory Synthetic Intelligence Project, the IET A. F. Harvey Engineering Research Prize, the Howard Hughes Medical Institute Simons Faculty Scholars Program, gifts from Charles Hieken and John Doerr, and the New York Stem Cell Foundation Robertson Award.

Funding Information:
S. B. Kodandaramaiah was supported by an MIT McGovern Institute Neuro-technology (MINT) grant, the Minnesota Discovery, Research and Innovation Economy (MnDRIVE) fund, and NIH Grant R21NS103098-01. C. Chronopoulos, C. Lamantia, and J. P. Kinney acknowledge support from NIH Grant 1R43MH101943. M. Tegmark acknowledges NSF6937191 and the Rothberg Family Foundation. E. S. Boyden acknowledges support from NIH Grants 1R01EY023173, 1R24MH106075, 1R43MH101943, 1R01NS102727, 2R01DA029639, and Director’s Pioneer Award 1DP1NS087724, as well as the MIT Media Laboratory Synthetic Intelligence Project, the IET A. F. Harvey Engineering Research Prize, the Howard Hughes Medical Institute Simons Faculty Scholars Program, gifts from Charles Hieken and John Doerr, and the New York Stem Cell Foundation Robertson Award.

Publisher Copyright:
© 2018 American Physiological Society. All rights reserved.

Keywords

Action potential
Bursting
Multielectrode array
Patch clamp
Spike sorting

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Allen, B. D., Moore-Kochlacs, C., Bernstein, J. G., Kinney, J. P., Scholvin, J., Seoane, L. F., Chronopoulos, C., Lamantia, C., Kodandaramaiah, S. B., Tegmark, M., & Boyden, E. S. (2018). Automated in vivo patch-clamp evaluation of extracellular multielectrode array spike recording capability. Journal of neurophysiology, 120(5), 2182-2200. https://doi.org/10.1152/jn.00650.2017

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abstract = "Much innovation is currently aimed at improving the number, density, and geometry of electrodes on extracellular multielectrode arrays for in vivo recording of neural activity in the mammalian brain. To choose a multielectrode array configuration for a given neuroscience purpose, or to reveal design principles of future multielectrode arrays, it would be useful to have a systematic way of evaluating the spike recording capability of such arrays. We describe an automated system that performs robotic patch-clamp recording of a neuron being simultaneously recorded via an extracellular multielectrode array. By recording a patch-clamp data set from a neuron while acquiring extracellular recordings from the same neuron, we can evaluate how well the extracellular multielectrode array captures the spiking information from that neuron. To demonstrate the utility of our system, we show that it can provide data from the mammalian cortex to evaluate how the spike sorting performance of a close-packed extracellular multielectrode array is affected by bursting, which alters the shape and amplitude of spikes in a train. We also introduce an algorithmic framework to help evaluate how the number of electrodes in a multielectrode array affects spike sorting, examining how adding more electrodes yields data that can be spike sorted more easily. Our automated methodology may thus help with the evaluation of new electrode designs and configurations, providing empirical guidance on the kinds of electrodes that will be optimal for different brain regions, cell types, and species, for improving the accuracy of spike sorting. NEW & NOTEWORTHY We present an automated strategy for evaluating the spike recording performance of an extracellular multielectrode array, by enabling simultaneous recording of a neuron with both such an array and with patch clamp. We use our robot and accompanying algorithms to evaluate the performance of multielectrode arrays on supporting spike sorting.",

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note = "Funding Information: S. B. Kodandaramaiah was supported by an MIT McGovern Institute Neurotechnology (MINT) grant, the Minnesota Discovery, Research and Innovation Economy (MnDRIVE) fund, and NIH Grant R21NS103098-01. C. Chronopoulos, C. Lamantia, and J. P. Kinney acknowledge support from NIH Grant 1R43MH101943. M. Tegmark acknowledges NSF 6937191 and the Rothberg Family Foundation. E. S. Boyden acknowledges support from NIH Grants 1R01EY023173, 1R24MH106075, 1R43MH101943, 1R01NS102727, 2R01DA029639, and Director{\textquoteright}s Pioneer Award 1DP1NS087724, as well as the MIT Media Laboratory Synthetic Intelligence Project, the IET A. F. Harvey Engineering Research Prize, the Howard Hughes Medical Institute Simons Faculty Scholars Program, gifts from Charles Hieken and John Doerr, and the New York Stem Cell Foundation Robertson Award. Funding Information: S. B. Kodandaramaiah was supported by an MIT McGovern Institute Neuro-technology (MINT) grant, the Minnesota Discovery, Research and Innovation Economy (MnDRIVE) fund, and NIH Grant R21NS103098-01. C. Chronopoulos, C. Lamantia, and J. P. Kinney acknowledge support from NIH Grant 1R43MH101943. M. Tegmark acknowledges NSF6937191 and the Rothberg Family Foundation. E. S. Boyden acknowledges support from NIH Grants 1R01EY023173, 1R24MH106075, 1R43MH101943, 1R01NS102727, 2R01DA029639, and Director{\textquoteright}s Pioneer Award 1DP1NS087724, as well as the MIT Media Laboratory Synthetic Intelligence Project, the IET A. F. Harvey Engineering Research Prize, the Howard Hughes Medical Institute Simons Faculty Scholars Program, gifts from Charles Hieken and John Doerr, and the New York Stem Cell Foundation Robertson Award. Publisher Copyright: {\textcopyright} 2018 American Physiological Society. All rights reserved.",

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AU - Moore-Kochlacs, Caroline

AU - Bernstein, Jacob G.

AU - Kinney, Justin P.

AU - Scholvin, Jorg

AU - Seoane, Luís F.

AU - Chronopoulos, Chris

AU - Lamantia, Charlie

AU - Kodandaramaiah, Suhasa B.

AU - Tegmark, Max

AU - Boyden, Edward S.

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N2 - Much innovation is currently aimed at improving the number, density, and geometry of electrodes on extracellular multielectrode arrays for in vivo recording of neural activity in the mammalian brain. To choose a multielectrode array configuration for a given neuroscience purpose, or to reveal design principles of future multielectrode arrays, it would be useful to have a systematic way of evaluating the spike recording capability of such arrays. We describe an automated system that performs robotic patch-clamp recording of a neuron being simultaneously recorded via an extracellular multielectrode array. By recording a patch-clamp data set from a neuron while acquiring extracellular recordings from the same neuron, we can evaluate how well the extracellular multielectrode array captures the spiking information from that neuron. To demonstrate the utility of our system, we show that it can provide data from the mammalian cortex to evaluate how the spike sorting performance of a close-packed extracellular multielectrode array is affected by bursting, which alters the shape and amplitude of spikes in a train. We also introduce an algorithmic framework to help evaluate how the number of electrodes in a multielectrode array affects spike sorting, examining how adding more electrodes yields data that can be spike sorted more easily. Our automated methodology may thus help with the evaluation of new electrode designs and configurations, providing empirical guidance on the kinds of electrodes that will be optimal for different brain regions, cell types, and species, for improving the accuracy of spike sorting. NEW & NOTEWORTHY We present an automated strategy for evaluating the spike recording performance of an extracellular multielectrode array, by enabling simultaneous recording of a neuron with both such an array and with patch clamp. We use our robot and accompanying algorithms to evaluate the performance of multielectrode arrays on supporting spike sorting.

AB - Much innovation is currently aimed at improving the number, density, and geometry of electrodes on extracellular multielectrode arrays for in vivo recording of neural activity in the mammalian brain. To choose a multielectrode array configuration for a given neuroscience purpose, or to reveal design principles of future multielectrode arrays, it would be useful to have a systematic way of evaluating the spike recording capability of such arrays. We describe an automated system that performs robotic patch-clamp recording of a neuron being simultaneously recorded via an extracellular multielectrode array. By recording a patch-clamp data set from a neuron while acquiring extracellular recordings from the same neuron, we can evaluate how well the extracellular multielectrode array captures the spiking information from that neuron. To demonstrate the utility of our system, we show that it can provide data from the mammalian cortex to evaluate how the spike sorting performance of a close-packed extracellular multielectrode array is affected by bursting, which alters the shape and amplitude of spikes in a train. We also introduce an algorithmic framework to help evaluate how the number of electrodes in a multielectrode array affects spike sorting, examining how adding more electrodes yields data that can be spike sorted more easily. Our automated methodology may thus help with the evaluation of new electrode designs and configurations, providing empirical guidance on the kinds of electrodes that will be optimal for different brain regions, cell types, and species, for improving the accuracy of spike sorting. NEW & NOTEWORTHY We present an automated strategy for evaluating the spike recording performance of an extracellular multielectrode array, by enabling simultaneous recording of a neuron with both such an array and with patch clamp. We use our robot and accompanying algorithms to evaluate the performance of multielectrode arrays on supporting spike sorting.

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Automated in vivo patch-clamp evaluation of extracellular multielectrode array spike recording capability

Abstract

Bibliographical note

Keywords

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