Abstract
In this paper, we use Generative Adversarial Networks (GANs) to synthesize high-quality retinal images along with the corresponding semantic label-maps, instead of real images during training of a segmentation network. Different from other previous proposals, we employ a two-step approach: first, a progressively growing GAN is trained to generate the semantic label-maps, which describes the blood vessel structure (i.e., the vasculature); second, an image-to-image translation approach is used to obtain realistic retinal images from the generated vasculature. The adoption of a two-stage process simplifies the generation task, so that the network training requires fewer images with consequent lower memory usage. Moreover, learning is effective, and with only a handful of training samples, our approach generates realistic high-resolution images, which can be successfully used to enlarge small available datasets. Comparable results were obtained by employing only synthetic images in place of real data during training. The practical viability of the proposed approach was demonstrated on two well-established benchmark sets for retinal vessel segmentation—both containing a very small number of training samples—obtaining better performance with respect to state-of-the-art techniques.
Highlights
The retinal microvasculature is the only part of human circulation that can be directly and non-invasively visualized in vivo [1]
We proposed a two-stage procedure to generate synthetic retinal images
The semantic label masks, which correspond to the retinal vessels, were generated by a Progressively Growing Generative Adversarial Networks (GANs)
Summary
The retinal microvasculature is the only part of human circulation that can be directly and non-invasively visualized in vivo [1]. It can be acquired and analyzed by automatic tools. Retinal fundus images have a multitude of applications, including biometric identification, computer-assisted laser surgery, and the diagnosis of several disorders [2,3]. One important processing step in such applications is the proper segmentation of retinal vessels. The segmentation of retinal blood vessels can help the diagnosis, treatment, and monitoring of diseases such as diabetic retinopathy, hypertension, and arteriosclerosis [4,5]
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