Synthetic optical coherence tomography angiographs for detailed retinal vessel segmentation without human annotations

TL;DR

This paper introduces a novel, realistic synthetic OCTA image generation method and contrast adaptation pipelines to improve retinal vessel segmentation without requiring human annotations, outperforming traditional methods.

Contribution

The authors develop a realistic retinal vascular network simulation and contrast adaptation pipelines, enabling effective synthetic data generation for deep learning segmentation without human annotations.

Findings

Synthetic OCTA images improve segmentation accuracy

Contrast adaptation reduces domain gap

Method outperforms traditional algorithms and supervised models

Abstract

Optical coherence tomography angiography (OCTA) is a non-invasive imaging modality that can acquire high-resolution volumes of the retinal vasculature and aid the diagnosis of ocular, neurological and cardiac diseases. Segmenting the visible blood vessels is a common first step when extracting quantitative biomarkers from these images. Classical segmentation algorithms based on thresholding are strongly affected by image artifacts and limited signal-to-noise ratio. The use of modern, deep learning-based segmentation methods has been inhibited by a lack of large datasets with detailed annotations of the blood vessels. To address this issue, recent work has employed transfer learning, where a segmentation network is trained on synthetic OCTA images and is then applied to real data. However, the previously proposed simulations fail to faithfully model the retinal vasculature and do not provide effective domain adaptation. Because of this, current methods are unable to fully segment the retinal vasculature, in particular the smallest capillaries. In this work, we present a lightweight simulation of the retinal vascular network based on space colonization for faster and more realistic OCTA synthesis. We then introduce three contrast adaptation pipelines to decrease the domain gap between real and artificial images. We demonstrate the superior segmentation performance of our approach in extensive quantitative and qualitative experiments on three public datasets that compare our method to traditional computer vision algorithms and supervised training using human annotations. Finally, we make our entire pipeline publicly available, including the source code, pretrained models, and a large dataset of synthetic OCTA images.