Scientists have been able to wake up light-sensing cells in organ donor eyes, a discovery which could help to develop treatments to improve vision.
The researchers were also able to make the cells talk to each other the way they do in the living eye.
The discoveries are part of a series that stand to transform brain and vision research, the experts suggest.
They will allow scientists to study human vision in a way that is not possible with animal eyes.
“In eyes obtained up to five hours after an organ donor’s death, these cells responded to bright light, coloured lights, and even very dim flashes of light.”
While initial experiments revived the cells, they appeared to have lost their ability to communicate with other cells in the retina, and the team identified oxygen deprivation as the reason behind this.
To overcome the challenge, Scripps Research Associate Professor Anne Hanneken, was able to get organ donor eyes in under 20 minutes from the time of death.
And Moran Eye Centre scientist Frans Vinberg, designed a special transportation unit to restore oxygenation and other nutrients to the eyes.
He also built a device to stimulate the retina and measure the electrical activity of its cells.
Dr Vinberg said: “We were able to make the retinal cells talk to each other, the way they do in the living eye to mediate human vision.
“Past studies have restored very limited electrical activity in organ donor eyes, but this has never been achieved in the macula (part of the retina at the back of the eye), and never to the extent we have now demonstrated.”
Researchers suggest the process they demonstrated is a transformative technical advance that can help scientists develop a better understanding of neurodegenerative diseases, including blinding retinal diseases such as age-related macular degeneration.
Dr Vinberg said: “The scientific community can now study human vision in ways that just aren’t possible with laboratory animals.
“We hope this will motivate organ donor societies, organ donors, and eye banks by helping them understand the exciting new possibilities this type of research offers.”
Prof Hanneken explained: “Until now, it hasn’t been possible to get the cells in all of the different layers of the central retina to communicate with each other the way they normally do in a living retina.
“Going forward, we’ll be able to use this approach to develop treatments to improve vision and light signalling in eyes with macular diseases, such as age-related macular degeneration.”
The findings are published in the Nature journal.