Wireless bioresorbable electronic system enables sustained nonpharmacological neuroregenerative therapy

Jahyun Koo; Matthew R. MacEwan; Seung Kyun Kang; Sang Min Won; Manu Stephen; Paul Gamble; Zhaoqian Xie; Ying Yan; Yu Yu Chen; Jiho Shin; Nathan Birenbaum; Sangjin Chung; Sung Bong Kim; Jawad Khalifeh; Daniel V. Harburg; Kelsey Bean; Michael Paskett; Jeonghyun Kim; Zohny S. Zohny; Seung Min Lee; Ruoyao Zhang; Kaijing Luo; Bowen Ji; Anthony Banks; Hyuck Mo Lee; Younggang Huang; Wilson Z. Ray; John A. Rogers

doi:10.1038/s41591-018-0196-2

Wireless bioresorbable electronic system enables sustained nonpharmacological neuroregenerative therapy

Jahyun Koo
, Matthew R. MacEwan
, Seung Kyun Kang
, Sang Min Won
, Manu Stephen
, Paul Gamble
, Zhaoqian Xie
, Ying Yan
, Yu Yu Chen
, Jiho Shin
, Nathan Birenbaum
, Sangjin Chung
, Sung Bong Kim
, Jawad Khalifeh
, Daniel V. Harburg
, Kelsey Bean
, Michael Paskett
, Jeonghyun Kim
, Zohny S. Zohny
, Seung Min Lee

Ruoyao Zhang, Kaijing Luo, Bowen Ji, Anthony Banks, Hyuck Mo Lee, Younggang Huang, Wilson Z. Ray, John A. Rogers^*

^*Corresponding author for this work

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

447 Citations (Scopus)

Abstract

Peripheral nerve injuries represent a significant problem in public health, constituting 2–5% of all trauma cases¹. For severe nerve injuries, even advanced forms of clinical intervention often lead to incomplete and unsatisfactory motor and/or sensory function². Numerous studies report the potential of pharmacological approaches (for example, growth factors, immunosuppressants) to accelerate and enhance nerve regeneration in rodent models^3–10. Unfortunately, few have had a positive impact in clinical practice. Direct intraoperative electrical stimulation of injured nerve tissue proximal to the site of repair has been demonstrated to enhance and accelerate functional recovery^11,12, suggesting a novel nonpharmacological, bioelectric form of therapy that could complement existing surgical approaches. A significant limitation of this technique is that existing protocols are constrained to intraoperative use and limited therapeutic benefits¹³. Herein we introduce (i) a platform for wireless, programmable electrical peripheral nerve stimulation, built with a collection of circuit elements and substrates that are entirely bioresorbable and biocompatible, and (ii) the first reported demonstration of enhanced neuroregeneration and functional recovery in rodent models as a result of multiple episodes of electrical stimulation of injured nervous tissue.

Original language	English
Pages (from-to)	1830-1836
Number of pages	7
Journal	Nature Medicine
Volume	24
Issue number	12
DOIs	https://doi.org/10.1038/s41591-018-0196-2
Publication status	Published - 2018 Dec 1
Externally published	Yes

Bibliographical note

Publisher Copyright:
© 2018, The Author(s), under exclusive licence to Springer Nature America, Inc.

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

SDG 3 Good Health and Well-being

ASJC Scopus subject areas

General Medicine
General Biochemistry,Genetics and Molecular Biology

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Koo, J., MacEwan, M. R., Kang, S. K., Won, S. M., Stephen, M., Gamble, P., Xie, Z., Yan, Y., Chen, Y. Y., Shin, J., Birenbaum, N., Chung, S., Kim, S. B., Khalifeh, J., Harburg, D. V., Bean, K., Paskett, M., Kim, J., Zohny, Z. S., ... Rogers, J. A. (2018). Wireless bioresorbable electronic system enables sustained nonpharmacological neuroregenerative therapy. Nature Medicine, 24(12), 1830-1836. https://doi.org/10.1038/s41591-018-0196-2

Koo, J, MacEwan, MR, Kang, SK, Won, SM, Stephen, M, Gamble, P, Xie, Z, Yan, Y, Chen, YY, Shin, J, Birenbaum, N, Chung, S, Kim, SB, Khalifeh, J, Harburg, DV, Bean, K, Paskett, M, Kim, J, Zohny, ZS, Lee, SM, Zhang, R, Luo, K, Ji, B, Banks, A, Lee, HM, Huang, Y, Ray, WZ & Rogers, JA 2018, 'Wireless bioresorbable electronic system enables sustained nonpharmacological neuroregenerative therapy', Nature Medicine, vol. 24, no. 12, pp. 1830-1836. https://doi.org/10.1038/s41591-018-0196-2

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abstract = "Peripheral nerve injuries represent a significant problem in public health, constituting 2–5\% of all trauma cases1. For severe nerve injuries, even advanced forms of clinical intervention often lead to incomplete and unsatisfactory motor and/or sensory function2. Numerous studies report the potential of pharmacological approaches (for example, growth factors, immunosuppressants) to accelerate and enhance nerve regeneration in rodent models3–10. Unfortunately, few have had a positive impact in clinical practice. Direct intraoperative electrical stimulation of injured nerve tissue proximal to the site of repair has been demonstrated to enhance and accelerate functional recovery11,12, suggesting a novel nonpharmacological, bioelectric form of therapy that could complement existing surgical approaches. A significant limitation of this technique is that existing protocols are constrained to intraoperative use and limited therapeutic benefits13. Herein we introduce (i) a platform for wireless, programmable electrical peripheral nerve stimulation, built with a collection of circuit elements and substrates that are entirely bioresorbable and biocompatible, and (ii) the first reported demonstration of enhanced neuroregeneration and functional recovery in rodent models as a result of multiple episodes of electrical stimulation of injured nervous tissue.",

author = "Jahyun Koo and MacEwan, \{Matthew R.\} and Kang, \{Seung Kyun\} and Won, \{Sang Min\} and Manu Stephen and Paul Gamble and Zhaoqian Xie and Ying Yan and Chen, \{Yu Yu\} and Jiho Shin and Nathan Birenbaum and Sangjin Chung and Kim, \{Sung Bong\} and Jawad Khalifeh and Harburg, \{Daniel V.\} and Kelsey Bean and Michael Paskett and Jeonghyun Kim and Zohny, \{Zohny S.\} and Lee, \{Seung Min\} and Ruoyao Zhang and Kaijing Luo and Bowen Ji and Anthony Banks and Lee, \{Hyuck Mo\} and Younggang Huang and Ray, \{Wilson Z.\} and Rogers, \{John A.\}",

note = "Publisher Copyright: {\textcopyright} 2018, The Author(s), under exclusive licence to Springer Nature America, Inc.",

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month = dec,

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doi = "10.1038/s41591-018-0196-2",

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AU - Gamble, Paul

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AU - Yan, Ying

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AU - Shin, Jiho

AU - Birenbaum, Nathan

AU - Chung, Sangjin

AU - Kim, Sung Bong

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AU - Bean, Kelsey

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AU - Kim, Jeonghyun

AU - Zohny, Zohny S.

AU - Lee, Seung Min

AU - Zhang, Ruoyao

AU - Luo, Kaijing

AU - Ji, Bowen

AU - Banks, Anthony

AU - Lee, Hyuck Mo

AU - Huang, Younggang

AU - Ray, Wilson Z.

AU - Rogers, John A.

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N2 - Peripheral nerve injuries represent a significant problem in public health, constituting 2–5% of all trauma cases1. For severe nerve injuries, even advanced forms of clinical intervention often lead to incomplete and unsatisfactory motor and/or sensory function2. Numerous studies report the potential of pharmacological approaches (for example, growth factors, immunosuppressants) to accelerate and enhance nerve regeneration in rodent models3–10. Unfortunately, few have had a positive impact in clinical practice. Direct intraoperative electrical stimulation of injured nerve tissue proximal to the site of repair has been demonstrated to enhance and accelerate functional recovery11,12, suggesting a novel nonpharmacological, bioelectric form of therapy that could complement existing surgical approaches. A significant limitation of this technique is that existing protocols are constrained to intraoperative use and limited therapeutic benefits13. Herein we introduce (i) a platform for wireless, programmable electrical peripheral nerve stimulation, built with a collection of circuit elements and substrates that are entirely bioresorbable and biocompatible, and (ii) the first reported demonstration of enhanced neuroregeneration and functional recovery in rodent models as a result of multiple episodes of electrical stimulation of injured nervous tissue.

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Wireless bioresorbable electronic system enables sustained nonpharmacological neuroregenerative therapy

Abstract

Bibliographical note

UN SDGs

ASJC Scopus subject areas

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