Welcome to The Chichilnisky Lab
Goal of Research
The goal of our research is to develop an artificial retina -- an electronic implant that will restore vision to people blinded by retinal degeneration. We focus on a combination of basic and applied research to develop an implant that can reproduce the electrical signals that the retina normally transmits to the brain. To accomplish this goal, we work closely with collaborators in fields spanning neurophysiology, electrical engineering, materials science, retinal surgery, visual behavior, and computational neuroscience. This collaboration constitutes the Stanford Artificial Retina Project, funded in part by the Stanford Neurotechnology Initiative.
Design of Implant
The design of the implant is based on knowledge acquired in our unique laboratory setting. We use large-scale multi-electrode recording from the retina to study normal light-evoked activity in hundreds of retinal ganglion cells of multiple types simultaneously, and then evoke similar patterns of activity by electrical stimulation. This approach provides a laboratory prototype for the artificial retina. We focus on several questions:
- what visual signals are normally transmitted by the diverse ganglion cell types to the brain?
- what computational models can accurately reproduce these diverse retinal signals?
- how can we precisely electrically stimulate retinal ganglion cells using an implant?
- how can the distinct cell types be recognized and separately targeted by the implant?
- what are the key constraints and algorithms for the electronic circuitry in the implant?
- how faithfully can the implant reproduce normal visual sensations in blind patients?
Please refer to the Media and Publications sections for detailed information.
Looking Forward
We anticipate that in addition to restoring vision, the artificial retina will allow us to transmit visual information to the brain in ways that are not possible with light stimulation, opening the door to visual augmentation -- creating visual sensations that were never before possible. It will also provide a unique and powerful research instrument for studying the diverse retinal pathways and how they contribute to vision. In the long run, our understanding of the retinal circuitry and how to interface to it effectively will be relevant for developing other interfaces to the brain – for treating disease, and for augmenting human capabilities.
Recent News
How the Brain Works, Curing Blindness & How to Navigate a Career Path
In this interview on the Huberman Lab podcast, Dr. Chichilnisky discusses studying the retina, how this informs our understanding of the brain, the development of artificial retinas, and his own personal journey.
BrainMind Summit 2023: Toward a high-fidelity artificial retina
Dr. E.J. Chichilnisky describes progress toward a high-fidelity artificial retina at the Brain Mind Summit in 2023. This 11-minute presentation is a quick introduction to this unique approach to treating incurable blindness.
BrainMind Summit 2023: Interview with E.J. Chichilnisky
Interview with Dr. E.J. Chichilnisky at the BrainMind Summit 2023, about the science behind the Stanford Artificial Retina Project and the unique environment at Stanford university that makes it possible.
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Building a Bionic Eye
While it sounds like science fiction, the possibility of engineering an artificial retina, a bionic eye, is closer than you might think. EJ Chichilnisky is the John R Adler professor of neurosurgery and a professor of opthalmology here at Stanford, where he leads the Stanford Artificial Retina Project. His team is engineering an electronic implant to restore vision to people blinded by incurable retinal disease. In other words, they are prototyping a bionic eye.
Using machine learning to identify individual variations in the primate retina
What does the eye tell the brain? Stanford researchers have found individual differences in how primate retinas process light stimuli and transmit visual signals to the brain.