The human eye can see with exceptional detail, allowing people to read fine print, recognize faces across the room and take in the features in nature. Scientists have long debated how this sharp vision works at the cellular level and whether the brain and eyes work together to make it possible.
A study from the University of Alabama at Birmingham provides clear answers that could influence future eye care and vision correction. The study, published in Nature Communications , directly reveals the retinal source of human high‑resolution vision, showing how the eye sends precise visual signals to the brain.
The study, led by Lawrence Sincich, Ph.D., shows that a human’s sharpest vision comes from signals isolated to individual cone photoreceptors. These light-sensing cells found in the retina are tiny and highly concentrated in the fovea, which represents our everyday center of gaze. The individualized signals from the fovea are then carried along a dedicated pathway in the brain that preserves visual detail.
“This is the type of result that people think was already nailed down, which is why it may seem surprising to some,” said Sincich, a professor in the UAB Department of Optometry and Vision Science and director of the Graduate Program. “Many anatomical studies have suggested that signals from a single cone cell can travel along a kind of private line to the brain. But there were also reasons to believe those signals mix with neighboring cells, which would reduce our ability to resolve sharp details.”
Previous physiological studies showed that neurons involved in this brain pathway appeared to collect signals from multiple cones. This did not align well with anatomical evidence or with perceptual studies that revealed a concept called hyperacuity, which means that people can detect details even smaller than the individual cells in the eyes that detect light.
“All of this created a real puzzle,” Sincich said. “Once the optics of the eye are corrected, is visual acuity limited by the retina, the brain or some combination of both?”
The new findings help resolve that question. Sincich’s research found that when the eye’s optics are optimally corrected, the visual signals sent to the brain operate at the same spacing of individual cone cells. In other words, the retina can deliver spatially precise information, limited only by the physical array of cone cells, and the brain is able to use it.
The results help reconcile decades of anatomical, physiological and perceptual research to clarify the mechanism that ultimately limits human visual acuity.
For optometrists, the findings reinforce the importance of providing the best optical correction. According to the study, the visual pathway that begins in the retina is always prepared to transmit details set at the level of cone spacing.
“This capability of the neural retina is why patients have that ‘Ahh’ moment when they first get good glasses,” Sincich said. “Their brain hasn’t adapted much to poor vision, and suddenly they’re seeing fine detail clearly. That moment of clarity is incredibly meaningful for patients.”
This discovery deepens scientific understanding of how vision works and affirms the role of the retina in allowing humans to see with high resolution, which is information that could influence further eye care studies.
In addition to Sincich, who was lead author of the study, the research team included Alexander Meadway, Ph.D., and Phillip Tellers, Ph.D., UAB Department of Optometry and Vision Science, School of Optometry; Keaton M. Ramsey, UAB School of Engineering and Marnix E. Heersink School of Medicine ; and Austin Roorda, Ph.D., and Pavan Tiruveedhula, Herbert Wertheim School of Optometry and Vision Science at University of California, Berkeley.
The study was supported by the National Eye Institute, the Air Force Office of Scientific Research, the German Research Foundation, the Eyesight Foundation of Alabama and the National Eye Institute Core grant.
Nature Communications
Physiological basis of resolution acuity in vision
7-Feb-2026