Implantation of Optoelectronic Devices in the Rodent Spinal Cord.

Autor: Shalileh S; School of Biomedical Engineering, University of British Columbia; International Collaborations on Repair Discoveries (ICORD)., Moallemi A; School of Biomedical Engineering, University of British Columbia; International Collaborations on Repair Discoveries (ICORD)., Tsuyuki B; School of Biomedical Engineering, University of British Columbia; International Collaborations on Repair Discoveries (ICORD)., Simard AAP; International Collaborations on Repair Discoveries (ICORD)., Shahriari D; School of Biomedical Engineering, University of British Columbia; International Collaborations on Repair Discoveries (ICORD); Department of Orthopaedics, University of British Columbia; Institute for Computing, Information and Cognitive Systems, University of British Columbia; dena.shahriari@ubc.ca.
Jazyk: angličtina
Zdroj: Journal of visualized experiments : JoVE [J Vis Exp] 2024 Jul 12 (209). Date of Electronic Publication: 2024 Jul 12.
DOI: 10.3791/66992
Abstrakt: Neuromodulation can provide diagnostic, modulatory, and therapeutic applications. While extensive work has been conducted in the brain, modulation of the spinal cord remains relatively unexplored. The inherently delicate and mobile spinal cord tissue imposes constraints that make the precise implantation of neural probes challenging. Despite recent advances in neuromodulation devices, particularly flexible bioelectronics, opportunities to expand their use in the spinal cord have been limited by the surgical complexities of device implantation. Here, we provide a series of surgical protocols tailored specifically for the implantation of a custom-made optoelectronic device that interfaces with the spinal cord in rodents. The steps to place and anchor an optical shank on a specific segment of the spinal cord via two different surgical implantation methods are detailed here. These methods are optimized for a diverse range of devices and applications, which may or may not require direct contact with the spinal cord for optical stimulation. To elucidate the methodology, the vertebral anatomy is referenced first to identify prominent landmarks before making a skin incision. The surgical steps to secure an optical shank over the cervical spine in rodents are demonstrated. Procedures are then outlined for securing the optoelectronic device connected to the optical shank in a subcutaneous space away from the spinal cord, minimizing unnecessary direct contact. Behavioral studies comparing animals receiving the implants to those undergoing sham surgeries indicate that the optical shanks did not adversely affect hindlimb or forelimb function seven days post-implantation. The present work broadens the neuromodulation toolkit for use in future studies aimed at investigating various spinal cord interventions.
Databáze: MEDLINE