Kaccie Y. Li scite author profile

In making noninvasive measurements of the human cone mosaic, the task of labeling each individual cone is unavoidable. Manual labeling is a time-consuming process, setting the motivation for the development of an automated method. An automated algorithm for labeling cones in adaptive optics (AO) retinal images is implemented and tested on real data. The optical fiber properties of cones aided the design of the algorithm. Out of 2153 manually labeled cones from six different images, the automated method correctly identified 94.1% of them. The agreement between the automated and the manual labeling methods varied from 92.7% to 96.2% across the six images. Results between the two methods disagreed for 1.2% to 9.1% of the cones. Voronoi analysis of large montages of AO retinal images confirmed the general hexagonal-packing structure of retinal cones as well as the general cone density variability across portions of the retina. The consistency of our measurements demonstrates the reliability and practicality of having an automated solution to this problem.

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Intersubject Variability of Foveal Cone Photoreceptor Density in Relation to Eye Length

Tiruveedhula

Roorda

2010

Invest. Ophthalmol. Vis. Sci.

173

191

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Comparison of control algorithms for a MEMS-based adaptive optics scanning laser ophthalmoscope

Mishra

Tiruveedhula

et al. 2009

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We compared four algorithms for controlling a MEMS deformable mirror of an adaptive optics (AO) scanning laser ophthalmoscope. Interferometer measurements of the static nonlinear response of the deformable mirror were used to form an equivalent linear model of the AO system so that the classic integrator plus wavefront reconstructor type controller can be implemented. The algorithms differ only in the design of the wavefront reconstructor. The comparisons were made for two eyes (two individuals) via a series of imaging sessions. All four controllers performed similarly according to estimated residual wavefront error not reflecting the actual image quality observed. A metric based on mean image intensity did consistently reflect the qualitative observations of retinal image quality. Based on this metric, the controller most effective for suppressing the least significant modes of the deformable mirror performed the best.

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Anisometropes adapt to different retinal image sizes via post-receptoral mechanisms, not by differences in photoreceptor density

Roorda

Wray

et al. 2009

Journal of Vision

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Analysis of cone packing arrangement in adaptive optics images

Roorda

2010

Journal of Vision

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Kaccie Y. Li

Automated identification of cone photoreceptors in adaptive optics retinal images

Intersubject Variability of Foveal Cone Photoreceptor Density in Relation to Eye Length

Comparison of control algorithms for a MEMS-based adaptive optics scanning laser ophthalmoscope

Anisometropes adapt to different retinal image sizes via post-receptoral mechanisms, not by differences in photoreceptor density

Analysis of cone packing arrangement in adaptive optics images

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