Retinal Cells Rewire to Preserve Vision in Retinitis Pigmentosa

Light-induced charge generation in polymeric nanoparticles restores vision in advanced-stage retinitis pigmentosa rats

Retinal dystrophies such as Retinitis pigmentosa are among the most prevalent causes of inherited legal blindness, for which treatments are in demand. Retinal prostheses have been developed to stimulate the inner retinal network that, initially spared by degeneration, deteriorates in the late stages of the disease. We recently reported that conjugated polymer nanoparticles persistently rescue visual activities after a single subretinal injection…

Eye cells 'rewire' themselves when vision begins to fail, study finds

Scientists at the Jules Stein Eye Institute at the David Geffen School of Medicine at UCLA have discovered that certain retinal cells can rewire themselves when vision begins to deteriorate in retinitis pigmentosa, a genetic eye disease that leads to progressive blindness.

Retinal cells rewire to preserve vision in retinitis pigmentosa

Scientists at the Jules Stein Eye Institute at the David Geffen School of Medicine at UCLA have discovered that certain retinal cells can rewire themselves when vision begins to deteriorate in retinitis pigmentosa, a genetic eye disease that leads to progressive blindness.

Eye Cells "Rewire" Themselves When Vision Begins to Fail

Scientists at the Jules Stein Eye Institute at the David Geffen School of Medicine at UCLA have discovered that certain retinal cells can rewire themselves when vision begins to deteriorate in retinitis pigmentosa, a genetic eye disease that leads to progressive blindness.

Gold nanoparticles could help the blind see without surgery

Brown researchers have identified a promising new approach that may one day help to restore vision in people.

Retinal Cells Rewire to Preserve Vision in Degenerative Eye Disease

New research shows that retinal neurons can rewire to preserve vision in retinitis pigmentosa, a genetic disease causing blindness. Using mouse models, scientists found that rod bipolar cells adapt by forming functional connections with cone cells when their usual rod partners degenerate.