Investigation of the input-output relationship of engineered neural networks using high-density microelectrode arrays

Jens Duru; Benedikt Maurer; Ciara Giles Doran; Robert Jelitto; Joël Küchler; Stephan J. Ihle; Tobias Ruff; Robert John; Barbara Genocchi; János Vörös

doi:10.1016/j.bios.2023.115591

Investigation of the input-output relationship of engineered neural networks using high-density microelectrode arrays

Jens Duru
, Benedikt Maurer
, Ciara Giles Doran
, Robert Jelitto
, Joël Küchler
, Stephan J. Ihle
, Tobias Ruff
, Robert John
, Barbara Genocchi
, János Vörös^*

^*Corresponding author for this work

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

20 Citations (Scopus)

11 Downloads (Pure)

Abstract

Bottom-up neuroscience utilizes small, engineered biological neural networks to study neuronal activity in systems of reduced complexity. We present a platform that establishes up to six independent networks formed by primary rat neurons on planar complementary metal–oxide–semiconductor (CMOS) microelectrode arrays (MEAs). We introduce an approach that allows repetitive stimulation and recording of network activity at any of the over 700 electrodes underlying a network. We demonstrate that the continuous application of a repetitive super-threshold stimulus yields a reproducible network answer within a 15 ms post-stimulus window. This response can be tracked with high spatiotemporal resolution across the whole extent of the network. Moreover, we show that the location of the stimulation plays a significant role in the networks' early response to the stimulus. By applying a stimulation pattern to all network-underlying electrodes in sequence, the sensitivity of the whole network to the stimulus can be visualized. We demonstrate that microchannels reduce the voltage stimulation threshold and induce the strongest network response. By varying the stimulation amplitude and frequency we reveal discrete network transition points. Finally, we introduce vector fields to follow stimulation-induced spike propagation pathways within the network. Overall we show that our defined neural networks on CMOS MEAs enable us to elicit highly reproducible activity patterns that can be precisely modulated by stimulation amplitude, stimulation frequency and the site of stimulation.

Original language	English
Article number	115591
Number of pages	12
Journal	Biosensors and Bioelectronics
Volume	239
DOIs	https://doi.org/10.1016/j.bios.2023.115591
Publication status	Published - 1 Nov 2023
Publication type	A1 Journal article-refereed

Funding

The authors would like to thank Miriam S. Lucas and Falk Lucas from ScopeM at ETH Zürich for their support and assistance in SEM imaging. Further, the authors thank Jan Müller from MaxWell Biosystems for his support regarding the stimulation protocol. This research was supported by ETH Zürich , the Swiss National Science Foundation (SNF) , the Human Frontiers Science Program (HFSP) , the Swiss Data Science Center (SDSC) , the OPO foundation , and a FreeNovation grant . The authors would like to thank Miriam S. Lucas and Falk Lucas from ScopeM at ETH Zürich for their support and assistance in SEM imaging. Further, the authors thank Jan Müller from MaxWell Biosystems for his support regarding the stimulation protocol. This research was supported by ETH Zürich, the Swiss National Science Foundation (SNF), the Human Frontiers Science Program (HFSP), the Swiss Data Science Center (SDSC), the OPO foundation, and a FreeNovation grant.

Keywords

Activity modulation
Bottom-up neuroscience
Controlled neural networks
Electrical stimulation
Microphysiological systems
PDMS microstructures

Publication forum classification

Publication forum level 3

ASJC Scopus subject areas

Biotechnology
Biophysics
Biomedical Engineering
Electrochemistry

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10.1016/j.bios.2023.115591Licence: CC BY

1-s2.0-S095656632300533X-mainFinal published version, 7.62 MBLicence: CC BY

https://urn.fi/URN:NBN:fi:tuni-202309188234Licence: CC BY

Cite this

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title = "Investigation of the input-output relationship of engineered neural networks using high-density microelectrode arrays",

abstract = "Bottom-up neuroscience utilizes small, engineered biological neural networks to study neuronal activity in systems of reduced complexity. We present a platform that establishes up to six independent networks formed by primary rat neurons on planar complementary metal–oxide–semiconductor (CMOS) microelectrode arrays (MEAs). We introduce an approach that allows repetitive stimulation and recording of network activity at any of the over 700 electrodes underlying a network. We demonstrate that the continuous application of a repetitive super-threshold stimulus yields a reproducible network answer within a 15 ms post-stimulus window. This response can be tracked with high spatiotemporal resolution across the whole extent of the network. Moreover, we show that the location of the stimulation plays a significant role in the networks' early response to the stimulus. By applying a stimulation pattern to all network-underlying electrodes in sequence, the sensitivity of the whole network to the stimulus can be visualized. We demonstrate that microchannels reduce the voltage stimulation threshold and induce the strongest network response. By varying the stimulation amplitude and frequency we reveal discrete network transition points. Finally, we introduce vector fields to follow stimulation-induced spike propagation pathways within the network. Overall we show that our defined neural networks on CMOS MEAs enable us to elicit highly reproducible activity patterns that can be precisely modulated by stimulation amplitude, stimulation frequency and the site of stimulation.",

keywords = "Activity modulation, Bottom-up neuroscience, Controlled neural networks, Electrical stimulation, Microphysiological systems, PDMS microstructures",

author = "Jens Duru and Benedikt Maurer and \{Giles Doran\}, Ciara and Robert Jelitto and Jo{\"e}l K{\"u}chler and Ihle, \{Stephan J.\} and Tobias Ruff and Robert John and Barbara Genocchi and J{\'a}nos V{\"o}r{\"o}s",

note = "Funding Information: The authors would like to thank Miriam S. Lucas and Falk Lucas from ScopeM at ETH Z{\"u}rich for their support and assistance in SEM imaging. Further, the authors thank Jan M{\"u}ller from MaxWell Biosystems for his support regarding the stimulation protocol. This research was supported by ETH Z{\"u}rich , the Swiss National Science Foundation (SNF) , the Human Frontiers Science Program (HFSP) , the Swiss Data Science Center (SDSC) , the OPO foundation , and a FreeNovation grant . Funding Information: The authors would like to thank Miriam S. Lucas and Falk Lucas from ScopeM at ETH Z{\"u}rich for their support and assistance in SEM imaging. Further, the authors thank Jan M{\"u}ller from MaxWell Biosystems for his support regarding the stimulation protocol. This research was supported by ETH Z{\"u}rich, the Swiss National Science Foundation (SNF), the Human Frontiers Science Program (HFSP), the Swiss Data Science Center (SDSC), the OPO foundation, and a FreeNovation grant. Publisher Copyright: {\textcopyright} 2023 The Authors",

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doi = "10.1016/j.bios.2023.115591",

language = "English",

volume = "239",

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T1 - Investigation of the input-output relationship of engineered neural networks using high-density microelectrode arrays

AU - Duru, Jens

AU - Maurer, Benedikt

AU - Giles Doran, Ciara

AU - Jelitto, Robert

AU - Küchler, Joël

AU - Ihle, Stephan J.

AU - Ruff, Tobias

AU - John, Robert

AU - Genocchi, Barbara

AU - Vörös, János

N1 - Funding Information: The authors would like to thank Miriam S. Lucas and Falk Lucas from ScopeM at ETH Zürich for their support and assistance in SEM imaging. Further, the authors thank Jan Müller from MaxWell Biosystems for his support regarding the stimulation protocol. This research was supported by ETH Zürich , the Swiss National Science Foundation (SNF) , the Human Frontiers Science Program (HFSP) , the Swiss Data Science Center (SDSC) , the OPO foundation , and a FreeNovation grant . Funding Information: The authors would like to thank Miriam S. Lucas and Falk Lucas from ScopeM at ETH Zürich for their support and assistance in SEM imaging. Further, the authors thank Jan Müller from MaxWell Biosystems for his support regarding the stimulation protocol. This research was supported by ETH Zürich, the Swiss National Science Foundation (SNF), the Human Frontiers Science Program (HFSP), the Swiss Data Science Center (SDSC), the OPO foundation, and a FreeNovation grant. Publisher Copyright: © 2023 The Authors

PY - 2023/11/1

Y1 - 2023/11/1

N2 - Bottom-up neuroscience utilizes small, engineered biological neural networks to study neuronal activity in systems of reduced complexity. We present a platform that establishes up to six independent networks formed by primary rat neurons on planar complementary metal–oxide–semiconductor (CMOS) microelectrode arrays (MEAs). We introduce an approach that allows repetitive stimulation and recording of network activity at any of the over 700 electrodes underlying a network. We demonstrate that the continuous application of a repetitive super-threshold stimulus yields a reproducible network answer within a 15 ms post-stimulus window. This response can be tracked with high spatiotemporal resolution across the whole extent of the network. Moreover, we show that the location of the stimulation plays a significant role in the networks' early response to the stimulus. By applying a stimulation pattern to all network-underlying electrodes in sequence, the sensitivity of the whole network to the stimulus can be visualized. We demonstrate that microchannels reduce the voltage stimulation threshold and induce the strongest network response. By varying the stimulation amplitude and frequency we reveal discrete network transition points. Finally, we introduce vector fields to follow stimulation-induced spike propagation pathways within the network. Overall we show that our defined neural networks on CMOS MEAs enable us to elicit highly reproducible activity patterns that can be precisely modulated by stimulation amplitude, stimulation frequency and the site of stimulation.

AB - Bottom-up neuroscience utilizes small, engineered biological neural networks to study neuronal activity in systems of reduced complexity. We present a platform that establishes up to six independent networks formed by primary rat neurons on planar complementary metal–oxide–semiconductor (CMOS) microelectrode arrays (MEAs). We introduce an approach that allows repetitive stimulation and recording of network activity at any of the over 700 electrodes underlying a network. We demonstrate that the continuous application of a repetitive super-threshold stimulus yields a reproducible network answer within a 15 ms post-stimulus window. This response can be tracked with high spatiotemporal resolution across the whole extent of the network. Moreover, we show that the location of the stimulation plays a significant role in the networks' early response to the stimulus. By applying a stimulation pattern to all network-underlying electrodes in sequence, the sensitivity of the whole network to the stimulus can be visualized. We demonstrate that microchannels reduce the voltage stimulation threshold and induce the strongest network response. By varying the stimulation amplitude and frequency we reveal discrete network transition points. Finally, we introduce vector fields to follow stimulation-induced spike propagation pathways within the network. Overall we show that our defined neural networks on CMOS MEAs enable us to elicit highly reproducible activity patterns that can be precisely modulated by stimulation amplitude, stimulation frequency and the site of stimulation.

KW - Activity modulation

KW - Bottom-up neuroscience

KW - Controlled neural networks

KW - Electrical stimulation

KW - Microphysiological systems

KW - PDMS microstructures

U2 - 10.1016/j.bios.2023.115591

DO - 10.1016/j.bios.2023.115591

M3 - Article

C2 - 37634421

AN - SCOPUS:85169572650

SN - 0956-5663

VL - 239

JO - Biosensors and Bioelectronics

JF - Biosensors and Bioelectronics

M1 - 115591

ER -

Investigation of the input-output relationship of engineered neural networks using high-density microelectrode arrays

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