A wireless spinal stimulation system for ventral activation of the rat cervical spinal cord

Matthew K. Hogan; Sean M. Barber; Zhoulyu Rao; Bethany R. Kondiles; Meng Huang; William J. Steele; Cunjiang Yu; Philip J. Horner

doi:10.1038/s41598-021-94047-1

A wireless spinal stimulation system for ventral activation of the rat cervical spinal cord

Matthew K. Hogan, Sean M. Barber, Zhoulyu Rao, Bethany R. Kondiles, Meng Huang, William J. Steele, Cunjiang Yu, Philip J. Horner

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

7 Scopus citations

Abstract

Electrical stimulation of the cervical spinal cord is gaining traction as a therapy following spinal cord injury; however, it is difficult to target the cervical motor region in a rodent using a non-penetrating stimulus compared with direct placement of intraspinal wire electrodes. Penetrating wire electrodes have been explored in rodent and pig models and, while they have proven beneficial in the injured spinal cord, the negative aspects of spinal parenchymal penetration (e.g., gliosis, neural tissue damage, and obdurate inflammation) are of concern when considering therapeutic potential. We therefore designed a novel approach for epidural stimulation of the rat spinal cord using a wireless stimulation system and ventral electrode array. Our approach allowed for preservation of mobility following surgery and was suitable for long term stimulation strategies in awake, freely functioning animals. Further, electrophysiology mapping of the ventral spinal cord revealed the ventral approach was suitable to target muscle groups of the rat forelimb and, at a single electrode lead position, different stimulation protocols could be applied to achieve unique activation patterns of the muscles of the forelimb.

Original language	English (US)
Article number	14900
Pages (from-to)	14900
Journal	Scientific Reports
Volume	11
Issue number	1
DOIs	https://doi.org/10.1038/s41598-021-94047-1
State	Published - Jul 21 2021

Keywords

Animals
Cervical Vertebrae
Electric Stimulation/methods
Electric Stimulation Therapy/methods
Electrodes, Implanted
Electromyography
Forelimb
Muscle, Skeletal/physiology
Rats
Spinal Cord Injuries/physiopathology
Wireless Technology

ASJC Scopus subject areas

General

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10.1038/s41598-021-94047-1

Cite this

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title = "A wireless spinal stimulation system for ventral activation of the rat cervical spinal cord",

abstract = "Electrical stimulation of the cervical spinal cord is gaining traction as a therapy following spinal cord injury; however, it is difficult to target the cervical motor region in a rodent using a non-penetrating stimulus compared with direct placement of intraspinal wire electrodes. Penetrating wire electrodes have been explored in rodent and pig models and, while they have proven beneficial in the injured spinal cord, the negative aspects of spinal parenchymal penetration (e.g., gliosis, neural tissue damage, and obdurate inflammation) are of concern when considering therapeutic potential. We therefore designed a novel approach for epidural stimulation of the rat spinal cord using a wireless stimulation system and ventral electrode array. Our approach allowed for preservation of mobility following surgery and was suitable for long term stimulation strategies in awake, freely functioning animals. Further, electrophysiology mapping of the ventral spinal cord revealed the ventral approach was suitable to target muscle groups of the rat forelimb and, at a single electrode lead position, different stimulation protocols could be applied to achieve unique activation patterns of the muscles of the forelimb.",

keywords = "Animals, Cervical Vertebrae, Electric Stimulation/methods, Electric Stimulation Therapy/methods, Electrodes, Implanted, Electromyography, Forelimb, Muscle, Skeletal/physiology, Rats, Spinal Cord Injuries/physiopathology, Wireless Technology",

author = "Hogan, {Matthew K.} and Barber, {Sean M.} and Zhoulyu Rao and Kondiles, {Bethany R.} and Meng Huang and Steele, {William J.} and Cunjiang Yu and Horner, {Philip J.}",

note = "Funding Information: This work was funded by a generous Grant provided by the Wings for Life Foundation. The authors would like to thank the Morton Cure Paralysis Fund and Craig H. Neilsen foundation for funding of the post-doctoral fellowship of Dr. Matthew Hogan during the completion of this work. The authors would also like to thank the National Science Foundation (CAREER CMMI-1554499) and National Institute Health grant (R21EB026175) for partial support of the device design and fabrication. Illustration in Figure 2a was created with biorender.com. The authors acknowledge invaluable contributions by Kendrick Lim who designed and conducted experiments on the mechanical properties of silk fibroin as an adhesive for soft electronics in the supplementary section of this work and by Dr. Gillian Hamilton who assisted with preparation and revision of this manuscript. Publisher Copyright: {\textcopyright} 2021, The Author(s).",

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AU - Rao, Zhoulyu

AU - Kondiles, Bethany R.

AU - Huang, Meng

AU - Steele, William J.

AU - Yu, Cunjiang

AU - Horner, Philip J.

N1 - Funding Information: This work was funded by a generous Grant provided by the Wings for Life Foundation. The authors would like to thank the Morton Cure Paralysis Fund and Craig H. Neilsen foundation for funding of the post-doctoral fellowship of Dr. Matthew Hogan during the completion of this work. The authors would also like to thank the National Science Foundation (CAREER CMMI-1554499) and National Institute Health grant (R21EB026175) for partial support of the device design and fabrication. Illustration in Figure 2a was created with biorender.com. The authors acknowledge invaluable contributions by Kendrick Lim who designed and conducted experiments on the mechanical properties of silk fibroin as an adhesive for soft electronics in the supplementary section of this work and by Dr. Gillian Hamilton who assisted with preparation and revision of this manuscript. Publisher Copyright: © 2021, The Author(s).

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N2 - Electrical stimulation of the cervical spinal cord is gaining traction as a therapy following spinal cord injury; however, it is difficult to target the cervical motor region in a rodent using a non-penetrating stimulus compared with direct placement of intraspinal wire electrodes. Penetrating wire electrodes have been explored in rodent and pig models and, while they have proven beneficial in the injured spinal cord, the negative aspects of spinal parenchymal penetration (e.g., gliosis, neural tissue damage, and obdurate inflammation) are of concern when considering therapeutic potential. We therefore designed a novel approach for epidural stimulation of the rat spinal cord using a wireless stimulation system and ventral electrode array. Our approach allowed for preservation of mobility following surgery and was suitable for long term stimulation strategies in awake, freely functioning animals. Further, electrophysiology mapping of the ventral spinal cord revealed the ventral approach was suitable to target muscle groups of the rat forelimb and, at a single electrode lead position, different stimulation protocols could be applied to achieve unique activation patterns of the muscles of the forelimb.

AB - Electrical stimulation of the cervical spinal cord is gaining traction as a therapy following spinal cord injury; however, it is difficult to target the cervical motor region in a rodent using a non-penetrating stimulus compared with direct placement of intraspinal wire electrodes. Penetrating wire electrodes have been explored in rodent and pig models and, while they have proven beneficial in the injured spinal cord, the negative aspects of spinal parenchymal penetration (e.g., gliosis, neural tissue damage, and obdurate inflammation) are of concern when considering therapeutic potential. We therefore designed a novel approach for epidural stimulation of the rat spinal cord using a wireless stimulation system and ventral electrode array. Our approach allowed for preservation of mobility following surgery and was suitable for long term stimulation strategies in awake, freely functioning animals. Further, electrophysiology mapping of the ventral spinal cord revealed the ventral approach was suitable to target muscle groups of the rat forelimb and, at a single electrode lead position, different stimulation protocols could be applied to achieve unique activation patterns of the muscles of the forelimb.

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KW - Electromyography

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KW - Muscle, Skeletal/physiology

KW - Rats

KW - Spinal Cord Injuries/physiopathology

KW - Wireless Technology

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A wireless spinal stimulation system for ventral activation of the rat cervical spinal cord

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