Abstract
Optical coherence tomography (OCT) is the de facto standard imaging modality for ophthalmological assessment of retinal eye disease, and is of increasing importance in the study of neurological disorders. Quantification of the thicknesses of various retinal layers within the macular cube provides unique diagnostic insights for many diseases, but the capability for automatic segmentation and quantification remains quite limited. While manual segmentation has been used for many scientific studies, it is extremely time consuming and is subject to intra- and inter-rater variation. This paper presents a new computational domain, referred to as flat space, and a segmentation method for specific retinal layers in the macular cube using a recently developed deformable model approach for multiple objects. The framework maintains object relationships and topology while preventing overlaps and gaps. The algorithm segments eight retinal layers over the whole macular cube, where each boundary is defined with subvoxel precision. Evaluation of the method on single-eye OCT scans from 37 subjects, each with manual ground truth, shows improvement over a state-of-the-art method.
Highlights
Optical coherence tomography (OCT) is an interferometric technique that detects reflected or back-scattered light from tissue
Our multiple-object geometric deformable model (MGDM) implementation is written in a generic framework and an optimized method based on a GPU framework could offer 10 to 20 fold speed up [45]
The Dice coefficient and absolute boundary error in conjunction with the comparison to random forest (RF)+GC suggest that our method has very good performance characteristics
Summary
Optical coherence tomography (OCT) is an interferometric technique that detects reflected or back-scattered light from tissue. OCT has contributed to the study of more traditional ophthalmological conditions such as glaucoma [7,8,9,10] and myopia [11], as well as to retinal vasculature [12, 13], and to the exploration of more obliquely related conditions such as Alzheimer’s disease (AD) [14,15,16] and diabetes [17, 18] The study of such a wide assortment of pathologies necessitates automated processing, which in the case of macular retinal OCT starts with segmentation of the various retinal cellular layers
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