The retinal prosthesis would help restore some vision by electrically stimulating the nerve cells that normally carry visual input from the retina to the brain.
Why it matters: The chip would not restore normal vision but could help blind people more easily navigate a room or walk down a sidewalk. “Anything that could help them see a little better and let them identify objects and move around a room would be an enormous help,” says Shawn Kelly, a researcher in MIT’s Research Laboratory for Electronics and member of the Boston Retinal Implant Project.
How it works: Patients who received the implant would wear a pair of glasses with a camera that sends images to a microchip attached to the eyeball. The glasses also contain a coil that wirelessly transmits power to receiving coils surrounding the eyeball. When the microchip receives visual information, it activates electrodes that stimulate nerve cells in the areas of the retina corresponding to the features of the visual scene. The electrodes directly activate optical nerves that carry signals to the brain, bypassing the damaged layers of retina.
Next steps: The research team, led by John Wyatt, MIT professor of electrical engineering and computer science, recently reported a new prototype that they hope to start testing in blind patients within the next three years, after some safety refinements are made. Once human trials begin and blind patients can offer feedback on what they’re seeing, the researchers will learn much more about how to configure the algorithm implemented by the chip to produce useful vision.
Source: “Development and Implantation of a Minimally Invasive Wireless Subretinal Neurostimulator,” Douglas Shire, Joseph Rizzo, et al.
IEEE Transactions on Biomedical Engineering, October 2009
Funding: VA Center for Innovative Visual Rehabilitation, the National Institutes of Health, the National Science Foundation, the Catalyst Foundation and the MOSIS microchip fabrication service.
MIT News Office