OCT segmentation: Integrating open parametric contour model of the retinal layers and shape constraint to the Mumford-Shah functional

TL;DR

This paper introduces a novel method for segmenting retinal layers in OCT images by integrating an open parametric contour model with a shape constraint into the Mumford-Shah functional, improving robustness and accuracy.

Contribution

It combines an open parametric contour model with a shape prior into a Mumford-Shah functional for simultaneous segmentation of all retinal layers in OCT images.

Findings

Method outperforms recent geodesic distance-based segmentation.

Segmentation is robust against low contrast and speckle noise.

Accurate segmentation of 9 retinal layers demonstrated.

Abstract

In this paper, we propose a novel retinal layer boundary model for segmentation of optical coherence tomography (OCT) images. The retinal layer boundary model consists of 9 open parametric contours representing the 9 retinal layers in OCT images. An intensity-based Mumford-Shah (MS) variational functional is first defined to evolve the retinal layer boundary model to segment the 9 layers simultaneously. By making use of the normals of open parametric contours, we construct equal sized adjacent narrowbands that are divided by each contour. Regional information in each narrowband can thus be integrated into the MS energy functional such that its optimisation is robust against different initialisations. A statistical prior is also imposed on the shape of the segmented parametric contours for the functional. As such, by minimising the MS energy functional the parametric contours can be driven towards the true boundaries of retinal layers, while the similarity of the contours with respect to training OCT shapes is preserved. Experimental results on real OCT images demonstrate that the method is accurate and robust to low quality OCT images with low contrast and high-level speckle noise, and it outperforms the recent geodesic distance based method for segmenting 9 layers of the retina in OCT images.