Interfacing neuron-motor pathways with stretchable and biocompatible electrode arrays

Conspectus: In the field of neuroscience, understanding the complex interactions within the intricate neuron-motor system depends crucially on the use of high-density, physiological multiple electrode arrays (MEAs). In the neuron-motor system, the transmission of biological signals primarily occurs...

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Main Authors: Jiang, Zhi, Zhu, Ming, Chen, Xiaodong
Other Authors: School of Materials Science and Engineering
Format: Article
Language:English
Published: 2024
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Online Access:https://hdl.handle.net/10356/180812
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Institution: Nanyang Technological University
Language: English
id sg-ntu-dr.10356-180812
record_format dspace
institution Nanyang Technological University
building NTU Library
continent Asia
country Singapore
Singapore
content_provider NTU Library
collection DR-NTU
language English
topic Engineering
Biocompatible materials
Motor Neurons
spellingShingle Engineering
Biocompatible materials
Motor Neurons
Jiang, Zhi
Zhu, Ming
Chen, Xiaodong
Interfacing neuron-motor pathways with stretchable and biocompatible electrode arrays
description Conspectus: In the field of neuroscience, understanding the complex interactions within the intricate neuron-motor system depends crucially on the use of high-density, physiological multiple electrode arrays (MEAs). In the neuron-motor system, the transmission of biological signals primarily occurs through electrical and chemical signaling. Taking neurons for instance, when a neuron receives external stimuli, it generates an electrical signal known as the action potential. This action potential propagates along the neuron's axon and is transmitted to other neurons via synapses. At the synapse, chemical signals (neurotransmitters) are released, allowing the electrical signal to traverse the synaptic gap and influence the next neuron. MEAs can provide unparalleled insights into neural signal patterns when interfacing with the nerve systems through their excellent spatiotemporal resolution. However, the inherent differences in mechanical and chemical properties between these artificial devices and biological tissues can lead to serious complications after chronic implantation, such as body rejection, infection, tissue damage, or device malfunction. A promising strategy to enhance MEAs' biocompatibility involves minimizing their thickness, which aligns their bending stiffness with that of surrounding tissues, thereby minimizing damage over time. However, this solution has its limits; the resulting ultrathin devices, typically based on plastic films, lack the necessary stretchability, restricting their use to organs that neither stretch nor grow.For practical deployments, devices must exhibit certain levels of stretchability (ranging from 20 to 70%), tailored to the specific requirements of the target organs. In this Account, we outline recent advancements in developing stretchable MEAs that balance stretchability with sufficient electrical conductivity for effective use in physiological research, acting as sensors and stimulators. By concentrating on the neuron-motor pathways, we summarize how the stretchable MEAs meet various application needs and examine their effectiveness. We distinguish between on-skin and implantable uses, given their vastly different requirements. Within each application scope, we highlight cutting-edge technologies, evaluating their strengths and shortcomings. Recognizing that most current devices rely on elastic films with a Young's modulus value between ∼0.5 and 5 MPa, we delve into the potential for softer MEAs, particularly those using multifunctional hydrogels for an optimizing tissue-device interface and address the challenges in adapting such hydrogel-based MEAs for chronic implants. Additionally, transitioning soft MEAs from lab to fab involves connecting them to a rigid adapter and external machinery, highlighting a critical challenge at the soft-rigid interface due to strain concentration, especially in chronic studies subject to unforeseen mechanical strains. We discuss innovative solutions to this integration challenge, being optimistic that the development of durable, biocompatible, stretchable MEAs will significantly advance neuroscience and related fields.
author2 School of Materials Science and Engineering
author_facet School of Materials Science and Engineering
Jiang, Zhi
Zhu, Ming
Chen, Xiaodong
format Article
author Jiang, Zhi
Zhu, Ming
Chen, Xiaodong
author_sort Jiang, Zhi
title Interfacing neuron-motor pathways with stretchable and biocompatible electrode arrays
title_short Interfacing neuron-motor pathways with stretchable and biocompatible electrode arrays
title_full Interfacing neuron-motor pathways with stretchable and biocompatible electrode arrays
title_fullStr Interfacing neuron-motor pathways with stretchable and biocompatible electrode arrays
title_full_unstemmed Interfacing neuron-motor pathways with stretchable and biocompatible electrode arrays
title_sort interfacing neuron-motor pathways with stretchable and biocompatible electrode arrays
publishDate 2024
url https://hdl.handle.net/10356/180812
_version_ 1814777730144665600
spelling sg-ntu-dr.10356-1808122024-11-01T15:47:11Z Interfacing neuron-motor pathways with stretchable and biocompatible electrode arrays Jiang, Zhi Zhu, Ming Chen, Xiaodong School of Materials Science and Engineering Innovative Centre for Flexible Devices Institute for Digital Molecular Analytics and Science Engineering Biocompatible materials Motor Neurons Conspectus: In the field of neuroscience, understanding the complex interactions within the intricate neuron-motor system depends crucially on the use of high-density, physiological multiple electrode arrays (MEAs). In the neuron-motor system, the transmission of biological signals primarily occurs through electrical and chemical signaling. Taking neurons for instance, when a neuron receives external stimuli, it generates an electrical signal known as the action potential. This action potential propagates along the neuron's axon and is transmitted to other neurons via synapses. At the synapse, chemical signals (neurotransmitters) are released, allowing the electrical signal to traverse the synaptic gap and influence the next neuron. MEAs can provide unparalleled insights into neural signal patterns when interfacing with the nerve systems through their excellent spatiotemporal resolution. However, the inherent differences in mechanical and chemical properties between these artificial devices and biological tissues can lead to serious complications after chronic implantation, such as body rejection, infection, tissue damage, or device malfunction. A promising strategy to enhance MEAs' biocompatibility involves minimizing their thickness, which aligns their bending stiffness with that of surrounding tissues, thereby minimizing damage over time. However, this solution has its limits; the resulting ultrathin devices, typically based on plastic films, lack the necessary stretchability, restricting their use to organs that neither stretch nor grow.For practical deployments, devices must exhibit certain levels of stretchability (ranging from 20 to 70%), tailored to the specific requirements of the target organs. In this Account, we outline recent advancements in developing stretchable MEAs that balance stretchability with sufficient electrical conductivity for effective use in physiological research, acting as sensors and stimulators. By concentrating on the neuron-motor pathways, we summarize how the stretchable MEAs meet various application needs and examine their effectiveness. We distinguish between on-skin and implantable uses, given their vastly different requirements. Within each application scope, we highlight cutting-edge technologies, evaluating their strengths and shortcomings. Recognizing that most current devices rely on elastic films with a Young's modulus value between ∼0.5 and 5 MPa, we delve into the potential for softer MEAs, particularly those using multifunctional hydrogels for an optimizing tissue-device interface and address the challenges in adapting such hydrogel-based MEAs for chronic implants. Additionally, transitioning soft MEAs from lab to fab involves connecting them to a rigid adapter and external machinery, highlighting a critical challenge at the soft-rigid interface due to strain concentration, especially in chronic studies subject to unforeseen mechanical strains. We discuss innovative solutions to this integration challenge, being optimistic that the development of durable, biocompatible, stretchable MEAs will significantly advance neuroscience and related fields. Agency for Science, Technology and Research (A*STAR) National Research Foundation (NRF) Submitted/Accepted version Financial support was provided by the Agency for Science,Technology and Research (A*STAR) under its MTC Programmatic Funding Scheme (project no. M23L8b0049) Scent Digitalization and Computation (SDC) Programme, the National Research Foundation, Singapore (NRF) under NRF’s Medium Sized Centre: Singapore Hybrid-Integrated Next-Generation μ-Electronics (SHINE) Centre Funding Programme, and the Smart Grippers for Soft Robotics (SGSR) Programme under the National Research Foundation, Prime Minister’s Office, Singapore under its Campus of Research Excellence and Technological Enterprise (CREATE) Programme 2024-10-28T07:08:48Z 2024-10-28T07:08:48Z 2024 Journal Article Jiang, Z., Zhu, M. & Chen, X. (2024). Interfacing neuron-motor pathways with stretchable and biocompatible electrode arrays. Accounts of Chemical Research, 57(16), 2255-2266. https://dx.doi.org/10.1021/acs.accounts.4c00215 0001-4842 https://hdl.handle.net/10356/180812 10.1021/acs.accounts.4c00215 39023124 2-s2.0-85199082364 16 57 2255 2266 en M23L8b0049 Accounts of Chemical Research © 2024 American Chemical Society. All rights reserved. This article may be downloaded for personal use only. Any other use requires prior permission of the copyright holder. The Version of Record is available online at http://doi.org/10.1021/acs.accounts.4c00215 application/pdf