Abstract
The optical quality of an image depends on both the optical properties of the imaging system and the physical properties of the medium in which the light travels from the object to the final imaging sensor. The analysis of the point spread function of the optical system is an objective way to quantify the image degradation. In retinal imaging, the presence of corneal or cristalline lens opacifications spread the light at wide angular distributions. If the mathematical operator that degrades the image is known, the image can be restored through deconvolution methods. In the particular case of retinal imaging, this operator may be unknown (or partially) due to the presence of cataracts, corneal edema, or vitreous opacification. In those cases, blind deconvolution theory provides useful results to restore important spatial information of the image. In this work, a new semi-blind deconvolution method has been developed by training an iterative process with the Glare Spread Function kernel based on the Richardson-Lucy deconvolution algorithm to compensate a veiling glare effect in retinal images due to intraocular straylight. The method was first tested with simulated retinal images generated from a straylight eye model and applied to a real retinal image dataset composed of healthy subjects and patients with glaucoma and diabetic retinopathy. Results showed the capacity of the algorithm to detect and compensate the veiling glare degradation and improving the image sharpness up to 1000% in the case of healthy subjects and up to 700% in the pathological retinal images. This image quality improvement allows performing image segmentation processing with restored hidden spatial information after deconvolution.
Highlights
The eye, as a non-ideal optical system, presents intrinsic optical physiological imperfections throughout the ocular media limiting the quality of the image formed at the retina due to the combined presence of aberrations and scattering [1]
The purpose of this work has been to develop a new semi-blind deconvolution algorithm based on the Richardson-Lucy deconvolution theory incorporating the Glare Spread Function (GSF) to restore retinal images from intraocular straylight
We used a public database of fundus images composed of healthy subjects (15), patients with glaucoma (15), and diabetic retinopathy (15) recorded by a group retinal image analysis of clinicians with a Canon CR-1 fundus camera (Field of view 45o)
Summary
The eye, as a non-ideal optical system, presents intrinsic optical physiological imperfections throughout the ocular media limiting the quality of the image formed at the retina due to the combined presence of aberrations and scattering [1]. If the angular distribution of the IS is wide enough, the sharpness, contrast, and image resolution will be decreased, making the features extraction harder even with advanced post-processing techniques In this sense, different optical methods have been proposed to reduce IS effects such as Fourier analysis [14] or adaptive optics (AO) deep learning techniques [15]. The concept of semi-blind deconvolution was introduced in the implementation of a Richardson-Lucy algorithm, improving the restoration previously reported [20] to incorporate functional forms assuming previous knowledge of the PSF. The purpose of this work has been to develop a new semi-blind deconvolution algorithm based on the Richardson-Lucy deconvolution theory incorporating the Glare Spread Function (GSF) to restore retinal images from intraocular straylight. An image segmentation processing was carried out, revealing hidden blood vessels and retinal structures as well as an improved structural differentiation of the optic disk, drusen, and other retinal fundus findings
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
