Boosting the Brain’s Control of Prosthetic Devices

Neuro prosthetics, a technology that allows the brain to control external devices such as robotic limbs, is beginning to emerge as a viable option for patients disabled by amputation or neurological conditions such as stroke. Cedars-Sinai investigators, in a study published in the peer-reviewed journal Science Advances, are believed to be the first to show that tapping the power of the cerebellum, a region in the back of the brain, could improve patients’ ability to control these devices.

“Neuro prosthetics have largely tapped the brain’s outermost cerebral cortex. The cerebellum has a well-known role in movement but has been ignored in neuro prosthetic research.” “We are the first to record what is happening in the cerebellum as the brain learns to manipulate these devices, and we found that its involvement is essential for device use.”

-Tanuj Gulati, PhD, assistant professor of Biomedical Sciences and Neurology and researcher in the Center for Neural Science and Medicine at Cedars-Sinai, and senior author of the study

Patients who use neuro prosthetic devices have electrodes permanently implanted in the portion of the brain—usually the cerebral cortex—that controls movement for the function the device is replacing. This technique can be used to help patients control a robotic limb, a motorized wheelchair or a computer keyboard, among other devices.

To learn how the cerebellum helps in learning neuro prosthetic control, Gulati and his team trained laboratory rats to use only their motor cortex activity to move a neuro prosthetic tube that delivered them water. The rats had electrodes implanted in the motor cortex and the cerebellum, and investigators listened in on the activity of neurons in both brain regions during the experiments.

“We found that activity of the neurons in the cerebellum was coordinated with the motor cortex, and that activity in the cerebellum was critical for neuro prosthetic task performance,” said Aamir Abbasi, PhD, a postdoctoral scientist in the Gulati Lab and the first author of the study.

Investigators next used an advanced technology called optogenetics to selectively silence different neuron populations in the laboratory rats’ brains during experiments. Optogenetics delivers light-sensitive proteins into brain cells, allowing light exposure to control these cells’ activity.

“These results could help make neuro prosthetics an option for patients with damage to the motor cortex due to brain injury, stroke or diseases such as Parkinson’s or multiple sclerosis,” said Nancy L. Sicotte, MD, chair of the Department of Neurology and the Women’s Guild Distinguished Chair in Neurology at Cedars-Sinai. “It’s possible that, eventually, implants in the cerebellar region could be used to help these patients manipulate external devices.”

It’s an exciting era for neuro prosthetics, said David Underhill, PhD, chair of the Department of Biomedical Sciences at Cedars-Sinai.

“There is a lot of buzz about neuro prosthetic technology, but there are still many unsolved problems,” Underhill said. “This study suggests that some of those could be resolved by involving the cerebellum as well as the motor cortex to help patients gain use of neuro prosthetic devices more quickly and improve their ability to control them accurately.”

Other Authors

Rohit Rangwani, Daniel W. Bowen, Andrew W. Fealy, and Nathan P. Danielsen.

Funding

This work was supported by American Heart Association postdoctoral fellowship 897265, American Heart Association predoctoral fellowship 1018175, American Heart Association career development award 847486, National Institutes of Health grants R00NS097620 and R01NS128469, National Science Foundation grant 2048231, and a Cedars-Sinai Medical Center’s Center for Neural Science and Medicine postdoctoral fellowship.

No conflicts of interest to disclose.

(Newswise/AP)