A blind woman in Texas is now the first person to undergo therapy based on a technology called optogenetics. The therapy will create light-sensing cells in one of her eyes and enable her to see again. Doctors don’t yet know if it worked, but the implications of an optogenetics trial could be significant for patients suffering from blindness, Parkinson’s, or schizophrenia.
This patient and others being recruited for a clinical trial have a degenerative disease called retinitis pigmentosa. In this disease, the light-sensitive cells of the retina gradually die off. These cells pass electrical signals on to nerves that convey them to the brain.
The therapy uses optogenetics, a technology that uses a combination of gene therapy and light to precisely control nerves. The therapy should make certain nerve cells in the woman’s eye, called ganglion cells, light-sensitive. The eye was injected with viruses carrying DNA from light-sensitive algae. If it works, the cells will do what the healthy retina’s cones and rods do: fire off an electrical signal in response to light, restoring some vision.
The patient was treated in late February in Dallas by doctors led byDavid Birch of the Retina Foundation of the Southwest. The therapy was developed by RetroSense Therapeutics of Ann Arbor, Michigan.
Beyond the implications for treating blind people, this trial is also beingwatched by the neuroscience community. If it’s successful, it suggests that optogenetics has promise not just as a lab tool for studying the brain circuits that underlie diseases like Parkinson’s and schizophrenia, but also as a potential therapy for treating people afflicted with them.
“This is a great early test of optogenetics, because the eye is so easily accessible,” says Todd Sherer, a neuroscientist and CEO of the Michael J. Fox Foundation for Parkinson’s Research. The foundation is funding research on using optogenetics to study the circuits underlying Parkinson’s.
Over the next year, Retina Foundation doctors will monitor the first patient’s eye for light sensitivity as they administer potentially three additional doses of the gene therapy.
They’re following her for any side effects, and also monitoring her for any vision in the treated eye.
The aim is not to get her to see with 20/20, full-color vision, but to endow the eye that currently has zero light perception with some vision. “Small things like being able to know someone is in the room with them, or being able to cross the road, are a big deal,” says Birch.
It’s especially exciting because there are currently no treatments for retinitis pigmentosa except a retinal prosthesis that uses an implanted chip to stimulate cells at the back of the eye, notes Jacque Duncan, professor of clinical ophthalmology at the University of California, San Francisco.
Vision that works through light-sensitive ganglion cells will likely be different than vision that relies on a healthy retina. When you go outside, for instance, it can be about 10,000 times brighter than inside. Healthy retinas rapidly adapt their sensitivity to adjust to this, but the light-sensing cells created by the gene therapy will not likely be able to adapt. For that reason it may be necessary for the RetroSense therapy, if it works, to be coupled with some kind of video-projection glasses that can perform these adjustments and tailor the incoming light to the treated eye, sending a brighter signal indoors than it does outdoors, for example.
Meanwhile, the trial continues to recruit other retinitis pigmentosa patients, with a goal of 15 in total. The foundation is recruiting patients who are not just low vision or legally blind, but profoundly blind, with no-to-little light sensitivity in one or more eyes.
“I tell patients this is like the Apollo mission—it’s potentially a big step forward but it’s entirely experimental,” says Birch. “They are pioneers.”