News Release

How optogenetics can put the brakes on epilepsy seizures

Researchers at UCSF, UCSC and Berkeley combine gene therapy with optogenetics to curb abnormal neural activity. 

Peer-Reviewed Publication

University of California - San Francisco

In what could one day become a new treatment for epilepsy, researchers at UC San Francisco, UC Santa Cruz and UC Berkeley have used pulses of light to prevent seizure-like activity in neurons.  

The researchers used brain tissue that had been removed from epilepsy patients as part of their treatment.  

Eventually, they hope the technique will replace surgery to remove the brain tissue where seizures originate, providing a less invasive option for patients whose symptoms cannot be controlled with medication. 

The team used a method known as optogenetics, which employs a harmless virus to deliver light-sensitive genes from microorganisms to a particular set of neurons in the brain that can be switched on and off with pulses of light.  

It is the first demonstration that optogenetics can be used to control seizure activity in living human brain tissue, and it opens the door to new treatments for other neurological diseases and conditions. 

“This represents a giant step toward a powerful new way of treating epilepsy and likely other conditions,” said Tomasz Nowakowski, PhD, an assistant professor of neurological surgery and a co-senior author of the study, which appears Nov. 15 in Nature Neuroscience.  

Subduing epilepsy’s spikes 

To keep the tissue alive long enough to complete the study, which took several weeks, the researchers created an environment that mimics conditions inside the skull.  

John Andrews, MD, a resident in neurosurgery, placed the tissue on a nutrient medium that resembles the cerebrospinal fluid that bathes the brain.

David Schaffer, PhD, a biomolecular engineer at UC Berkeley found the best virus to deliver the genes, so they would work in the specific neurons the team was targeting.  

Andrews then placed the tissue on a bed of electrodes small enough to detect the electrical discharges of neurons communicating with each other.

When the brain is acting normally, neurons send signals at different times and frequencies in a predictable, low-level chatter. But during a seizure, the chatter synchronizes into loud bursts of electrical activity that overwhelm the brain’s casual conversation.  

The team hoped to use the light pulses to prevent the bursts by switching off neurons that contained light-sensitive proteins.  

Remote-control experimentation 

First, the team needed to find a way to run their experiments without disturbing the tissue. The tiny electrodes were only 17 microns apart – less than half the width of a human hair – and the smallest movement of the brain slices could skew their results.  

Mircea Teodorescu, PhD, an associate professor of electrical and computer engineering at UCSC and co-senior author of the study, designed a remote-control system to record the neurons’ electrical activity and deliver light pulses to the tissue.  

Teodorescu’s lab wrote software that enabled the scientists to control the apparatus, so the group could direct experiments from Santa Cruz on the tissue in Nowakowski’s San Francisco lab.  

That way, no one needed to be in the room where the tissue was being kept. 

“This was a very unique collaboration to solve an incredibly complex research problem,” Teodorescu said. “The fact that we actually accomplished this feat shows how much farther we can reach when we bring the strengths of our institutions together." 

New insight into seizures 

Optogenetics enables researchers to zoom in on discrete sets of neurons.  

The group could see which types of neurons and how many of them were needed to start a seizure. And they determined the lowest intensity of light needed to change the electrical activity of the neurons in live brain slices.  

The researchers could also see how interactions between neurons inhibited a seizure. 

Edward Chang, MD, the chair of Neurological Surgery at UCSF, said these insights could revolutionize care for people with epilepsy.  

“I believe that in the future, we won’t have to do that if we use this kind of approach,” Chang said who along with Nowakowski is a member of the UCSF Weill Institute for Neurosciences.  

“We’ll be able to give people much more subtle, effective control over their seizures while saving them from such an invasive surgery.”  

 

Authors: Additional authors on the study: David Shinn, Albert Wang, Matthew Keefe,PhD, Kevin Donohue, Hanh Larson, Kurtis Auguste, MD, Vikaas Sohal, MD, PhD, and Cathryn Cadwell, MD, PhD of UCSF, Jinghui Geng, Kateryna Voitiuk, Matthew Elliott, Ash Robbins, Alex Spaeth, Daniel Solis, Jessica Sevetson, PhD, Drew Ehrlich, Sofie Salama, PhD, Tal Sharf, PhD and David Haussler, PhD, of UCSC, and Lin Li and Julio Rivera-de Jesus of UC Berkeley. 

Funding: This research was supported by the National Institutes of Health (grants 5R25NS070680-13, UF1MH130700, R01NS123263, R01MH120295, T32HG012344, K08NS126573, K12GM139185 and LRP0000018281), the National Science Foundation (grants 2034037, CNS-1730158, ACI-1540112, ACI-1541349 and OAC-1826967), the Schmidt Futures Foundation (SF 857), Weill Neurohub grant U01NS132353, the Esther A & Joseph Klingenstein Fund, the Shurl and Kay Curci Foundation, the Sontag Foundation, and a gift from the William K. Bowes Jr Foundation.  
 

About UCSF: The University of California, San Francisco (UCSF) is exclusively focused on the health sciences and is dedicated to promoting health worldwide through advanced biomedical research, graduate-level education in the life sciences and health professions, and excellence in patient care. UCSF Health, which serves as UCSF's primary academic medical center, includes top-ranked specialty hospitals and other clinical programs, and has affiliations throughout the Bay Area. UCSF School of Medicine also has a regional campus in Fresno. Learn more at ucsf.edu, or see our Fact Sheet.

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