In Vivo Cone Photoreceptor Topography of the Human Foveola
In Vivo Cone Photoreceptor Topography of the Human Foveola
Dokument öffnen (3.5MB)Datum der Veröffentlichung
06.08.2025Verlag / herausgebende Einrichtung
ARVOVerlagsort
Rockville, MDMetadaten
Zur Langanzeige
Zitierbarer Link (Handle URI) 
https://hdl.handle.net/20.500.11811/13793
Inhalt
PURPOSE. To study in vivo cone topography of the normal human foveola.
METHODS. The fovea in both eyes of 30 healthy participants was imaged with adaptive optics scanning light ophthalmoscopy. High-resolution image montages spanning two degrees of visual angle were created and cone center locations annotated. Continuous cone density maps were computed by a Voronoi cell area approach to also yield the topographical center, the cone density centroid (CDC). Cone density profiles were extracted and fit with a four-parameter decay function, D = D0 / (1 + (E/a)b)c, with D as cone density (cones/mm2), D0 as cone density at the CDC, and E as eccentricity (µm).
RESULTS. Across eyes, D0 was 175,474 ± 20,543 cones/mm2, on average (range 136,001–216,209 cones/mm2). Density dropped anisotropically along the meridians, shallower horizontally, with average best fit parameters (a, b, c) of 61.95, 2.469, 0.268 for horizontal, and 59.11, 2.012, 0.357, for vertical profiles, respectively. In radially averaged profiles, cone density reached 50% of D0 at 151 ± 17 µm eccentricity (range 128–193 µm). Temporal cone density was slightly higher than nasal. Most topographical metrics were highly correlated between fellow eyes.
CONCLUSIONS. Despite a 1.6-fold range in absolute cone density, foveolar density profiles could be well described by a sigmoidal decay function across all eyes. This established a normative cone density profile of the healthy foveola. It allowed cone density estimation in cases of only partially available data, which alleviates resolution demands for future studies and renders possible retrospective analyses of foveolar cone topography in suboptimal imagery.
METHODS. The fovea in both eyes of 30 healthy participants was imaged with adaptive optics scanning light ophthalmoscopy. High-resolution image montages spanning two degrees of visual angle were created and cone center locations annotated. Continuous cone density maps were computed by a Voronoi cell area approach to also yield the topographical center, the cone density centroid (CDC). Cone density profiles were extracted and fit with a four-parameter decay function, D = D0 / (1 + (E/a)b)c, with D as cone density (cones/mm2), D0 as cone density at the CDC, and E as eccentricity (µm).
RESULTS. Across eyes, D0 was 175,474 ± 20,543 cones/mm2, on average (range 136,001–216,209 cones/mm2). Density dropped anisotropically along the meridians, shallower horizontally, with average best fit parameters (a, b, c) of 61.95, 2.469, 0.268 for horizontal, and 59.11, 2.012, 0.357, for vertical profiles, respectively. In radially averaged profiles, cone density reached 50% of D0 at 151 ± 17 µm eccentricity (range 128–193 µm). Temporal cone density was slightly higher than nasal. Most topographical metrics were highly correlated between fellow eyes.
CONCLUSIONS. Despite a 1.6-fold range in absolute cone density, foveolar density profiles could be well described by a sigmoidal decay function across all eyes. This established a normative cone density profile of the healthy foveola. It allowed cone density estimation in cases of only partially available data, which alleviates resolution demands for future studies and renders possible retrospective analyses of foveolar cone topography in suboptimal imagery.
Schlagwörter
photoreceptors, adaptive optics, cone density, foveal topography, AOSLO
Klassifikation (DDC)
610 Medizin, GesundheitErschienen in
Investigative ophthalmology & visual science. Retina, 2025, vol. 66, iss. 11, 13, S. 1-14Erstpublikation
https://doi.org/10.1167/iovs.66.11.13Ameln, Julius; Witten, Jenny L.; Gutnikov, Aleksandr; Lukyanova, Veronika; Holz, Frank G.; Harmening, Wolf M.: In Vivo Cone Photoreceptor Topography of the Human Foveola. In: Investigative ophthalmology & visual science. Retina. 2025, vol. 66, iss. 11, 13, 1-14.
Online-Ausgabe in bonndoc: https://hdl.handle.net/20.500.11811/13793
Online-Ausgabe in bonndoc: https://hdl.handle.net/20.500.11811/13793
@article{handle:20.500.11811/13793,
author = {{Julius Ameln} and {Jenny L. Witten} and {Aleksandr Gutnikov} and {Veronika Lukyanova} and {Frank G. Holz} and {Wolf M. Harmening}},
title = {In Vivo Cone Photoreceptor Topography of the Human Foveola},
publisher = {ARVO},
year = 2025,
month = aug,
journal = {Investigative ophthalmology & visual science. Retina},
volume = 2025, vol. 66,
number = iss. 11, 13,
pages = 1--14,
note = {PURPOSE. To study in vivo cone topography of the normal human foveola.
METHODS. The fovea in both eyes of 30 healthy participants was imaged with adaptive optics scanning light ophthalmoscopy. High-resolution image montages spanning two degrees of visual angle were created and cone center locations annotated. Continuous cone density maps were computed by a Voronoi cell area approach to also yield the topographical center, the cone density centroid (CDC). Cone density profiles were extracted and fit with a four-parameter decay function, D = D0 / (1 + (E/a)b)c, with D as cone density (cones/mm2), D0 as cone density at the CDC, and E as eccentricity (µm).
RESULTS. Across eyes, D0 was 175,474 ± 20,543 cones/mm2, on average (range 136,001–216,209 cones/mm2). Density dropped anisotropically along the meridians, shallower horizontally, with average best fit parameters (a, b, c) of 61.95, 2.469, 0.268 for horizontal, and 59.11, 2.012, 0.357, for vertical profiles, respectively. In radially averaged profiles, cone density reached 50% of D0 at 151 ± 17 µm eccentricity (range 128–193 µm). Temporal cone density was slightly higher than nasal. Most topographical metrics were highly correlated between fellow eyes.
CONCLUSIONS. Despite a 1.6-fold range in absolute cone density, foveolar density profiles could be well described by a sigmoidal decay function across all eyes. This established a normative cone density profile of the healthy foveola. It allowed cone density estimation in cases of only partially available data, which alleviates resolution demands for future studies and renders possible retrospective analyses of foveolar cone topography in suboptimal imagery.},
url = {https://hdl.handle.net/20.500.11811/13793}
}
author = {{Julius Ameln} and {Jenny L. Witten} and {Aleksandr Gutnikov} and {Veronika Lukyanova} and {Frank G. Holz} and {Wolf M. Harmening}},
title = {In Vivo Cone Photoreceptor Topography of the Human Foveola},
publisher = {ARVO},
year = 2025,
month = aug,
journal = {Investigative ophthalmology & visual science. Retina},
volume = 2025, vol. 66,
number = iss. 11, 13,
pages = 1--14,
note = {PURPOSE. To study in vivo cone topography of the normal human foveola.
METHODS. The fovea in both eyes of 30 healthy participants was imaged with adaptive optics scanning light ophthalmoscopy. High-resolution image montages spanning two degrees of visual angle were created and cone center locations annotated. Continuous cone density maps were computed by a Voronoi cell area approach to also yield the topographical center, the cone density centroid (CDC). Cone density profiles were extracted and fit with a four-parameter decay function, D = D0 / (1 + (E/a)b)c, with D as cone density (cones/mm2), D0 as cone density at the CDC, and E as eccentricity (µm).
RESULTS. Across eyes, D0 was 175,474 ± 20,543 cones/mm2, on average (range 136,001–216,209 cones/mm2). Density dropped anisotropically along the meridians, shallower horizontally, with average best fit parameters (a, b, c) of 61.95, 2.469, 0.268 for horizontal, and 59.11, 2.012, 0.357, for vertical profiles, respectively. In radially averaged profiles, cone density reached 50% of D0 at 151 ± 17 µm eccentricity (range 128–193 µm). Temporal cone density was slightly higher than nasal. Most topographical metrics were highly correlated between fellow eyes.
CONCLUSIONS. Despite a 1.6-fold range in absolute cone density, foveolar density profiles could be well described by a sigmoidal decay function across all eyes. This established a normative cone density profile of the healthy foveola. It allowed cone density estimation in cases of only partially available data, which alleviates resolution demands for future studies and renders possible retrospective analyses of foveolar cone topography in suboptimal imagery.},
url = {https://hdl.handle.net/20.500.11811/13793}
}
Die folgenden Nutzungsbestimmungen sind mit dieser Ressource verbunden:
