Abstract
The analysis of the choroid in the eye is crucial for our understanding of a range of ocular diseases and physiological processes. Optical coherence tomography (OCT) imaging provides the ability to capture highly detailed cross-sectional images of the choroid yet only a very limited number of commercial OCT instruments provide methods for automatic segmentation of choroidal tissue. Manual annotation of the choroidal boundaries is often performed but this is impractical due to the lengthy time taken to analyse large volumes of images. Therefore, there is a pressing need for reliable and accurate methods to automatically segment choroidal tissue boundaries in OCT images. In this work, a variety of patch-based and fully-convolutional deep learning methods are proposed to accurately determine the location of the choroidal boundaries of interest. The effect of network architecture, patch-size and contrast enhancement methods was tested to better understand the optimal architecture and approach to maximize performance. The results are compared with manual boundary segmentation used as a ground-truth, as well as with a standard image analysis technique. Results of total retinal layer segmentation are also presented for comparison purposes. The findings presented here demonstrate the benefit of deep learning methods for segmentation of the chorio-retinal boundary analysis in OCT images.
Highlights
The choroid is a vascular tissue layer lining the posterior eye situated between the retina and the sclera
The dataset used consists of spectral domain Optical coherence tomography (OCT) (SD-OCT) scans from a longitudinal study that has been described in detail in a number of previous publications[5,6]
This paper has examined a number of supervised deep learning methods for the task of retinal and choroidal segmentation in OCT images
Summary
The choroid is a vascular tissue layer lining the posterior eye situated between the retina and the sclera. Previous analysis approaches for OCT retinal segmentation have utilised methods based on standard image processing techniques[16,17]. Using a method combining a CNN and a graph search (CNN-GS), Fang et al.[20] automatically segmented nine retinal layer boundaries using a patch-based classification approach. Devalla et al.[24] presented their Dilated-Residual U-Net (DRUNET) architecture to segment the various regions in OCT images including the retina, choroid and optic nerve head They combined the benefits of skip connections, residual connections and dilated convolutions by incorporating each into their network. Given the vast range of machine learning model architectures and associated parameters, this work takes an important step towards understanding the optimal architecture and approach for choroidal boundary segmentation in OCT images. The outcomes of the approaches presented here are likely to aid in the future for the design and evaluation of machine learning-based OCT image analysis techniques
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