New wireless photoelectric implant controls the activity of spinal neurons

Credit: CC0 Public Domain

Grégoire Courtine doesn't hesitate to use the word "revolutionary" when describing the emerging field of optogenetics—a technology that uses pulses of light to control individual neural activity—and what it could mean for neuroscience. Courtine, director of the NeuroRestore research center (with neurosurgeon Jocelyne Bloch), is currently developing an optogenetic implant together with Stéphanie Lacour, who holds the Bertarelli Foundation Chair in Neuroprosthetic Technology. "Our system allows us to control the activity of any neuron in the spinal cord," says Courtine. "In turn, this helps us to understand the role it plays in the overall functioning of the nervous system."

The key to their breakthrough is the new implant technology developed by Lacour's research group. "We found a way to encapsulate miniaturized LEDs in a flexible implant that is thin yet sturdy enough to be applied on the surface of a mouse's by sliding it underneath the vertebrae along the entire lumbar section," she says. "Then we worked with our colleagues at ETH Zurich to create a wireless electronic circuit that can be used to switch on one or more LEDs and control the duration and intensity of the emitted with extreme precision. Finally, through a customized embedded system-on-chip, the light pulses can be managed naturally, for example in response to muscular activity or some other physiological signal." The optoelectronic implantable system is controlled via Bluetooth.

Behaving as naturally as possible

Courtine stresses that the system's ability to run autonomously is crucial. "That frees us from the wire-based systems that are generally needed for this kind of research. Now we can observe mice as they move about freely and examine the role that neurons play in complex movements like walking and swimming, in an ecological environment."

One of the biggest challenges in developing the technology was finding a way to administer light pulses that penetrate into the depth of the spinal cord without being absorbed and reflected by nerve fibers. To solve that problem, the research team modified the LEDs to emit red light—a color that is much less easily impacted by nerve fibers than the blue light typically emitted by the diodes.

On the path to new therapies

Courtine and Lacour's discovery is likely to boost the development of new therapeutic applications for optogenetics. The ability to stimulate or inhibit specific spinal-cord neurons using light pulses will eventually allow doctors to reduce pain, improve autonomic function and even treat paralysis. There may still be a long way to go before their implants are used clinically, but the research team is confident that a version of their will be available for human patients in the not-too-distant future.

More information: Grégoire Courtine et al, Wireless closed-loop optogenetics across the entire dorsoventral spinal cord in mice. Nature Biotechnology(2021). DOI: 10.1038/s41587-021-01019-x

Journal information: Nature Biotechnology
Citation: New wireless photoelectric implant controls the activity of spinal neurons (2021, September 27) retrieved 29 May 2024 from
This document is subject to copyright. Apart from any fair dealing for the purpose of private study or research, no part may be reproduced without the written permission. The content is provided for information purposes only.

Explore further

Joint efforts toward treating paralysis


Feedback to editors