Litcius/Paper detail

Sub-cone visual resolution by active, adaptive sampling in the human foveola

Jenny L. Witten, Veronika Lukyanova, Wolf M. Harmening

2024eLife15 citationsDOIOpen Access PDF

Abstract

The foveated architecture of the human retina and the eye’s mobility enables prime spatial vision, yet the interplay between photoreceptor cell topography and the constant motion of the eye during fixation remains unexplored. With in vivo foveal cone-resolved imaging and simultaneous microscopic photo stimulation, we examined visual acuity in both eyes of 16 participants while precisely recording the stimulus path on the retina. We find that resolution thresholds were correlated with the individual retina’s sampling capacity, and exceeded what static sampling limits would predict by 18%, on average. The length and direction of fixational drift motion, previously thought to be primarily random, played a key role in achieving this sub-cone diameter resolution. The oculomotor system finely adjusts drift behavior towards retinal areas with higher cone densities within only a few hundred milliseconds to enhance retinal sampling.

Topics & Concepts

FovealRetinaFixation (population genetics)RetinalComputer visionEye movementComputer scienceFovea centralisHuman eyePhysicsAdaptive opticsArtificial intelligenceOpticsNeuroscienceBiologyOphthalmologyMedicineGeneBiochemistryVisual perception and processing mechanismsRetinal Development and DisordersNeural dynamics and brain function