Intraretinal Layer Segmentation Using Cascaded Compressed U-Nets.
Sunil Kumar YadavRahele KafiehHanna Gwendolyn ZimmermannJosef Kauer-BoninKouros Nouri-MahdaviVahid MohammadzadehLynn ShiElla Maria KadasFriedemann PaulSeyedamirhosein MotamediAlexander Ulrich BrandtPublished in: Journal of imaging (2022)
Reliable biomarkers quantifying neurodegeneration and neuroinflammation in central nervous system disorders such as Multiple Sclerosis, Alzheimer's dementia or Parkinson's disease are an unmet clinical need. Intraretinal layer thicknesses on macular optical coherence tomography (OCT) images are promising noninvasive biomarkers querying neuroretinal structures with near cellular resolution. However, changes are typically subtle, while tissue gradients can be weak, making intraretinal segmentation a challenging task. A robust and efficient method that requires no or minimal manual correction is an unmet need to foster reliable and reproducible research as well as clinical application. Here, we propose and validate a cascaded two-stage network for intraretinal layer segmentation, with both networks being compressed versions of U-Net (CCU-INSEG). The first network is responsible for retinal tissue segmentation from OCT B-scans. The second network segments eight intraretinal layers with high fidelity. At the post-processing stage, we introduce Laplacian-based outlier detection with layer surface hole filling by adaptive non-linear interpolation. Additionally, we propose a weighted version of focal loss to minimize the foreground-background pixel imbalance in the training data. We train our method using 17,458 B-scans from patients with autoimmune optic neuropathies, i.e., multiple sclerosis, and healthy controls. Voxel-wise comparison against manual segmentation produces a mean absolute error of 2.3 μm, outperforming current state-of-the-art methods on the same data set. Voxel-wise comparison against external glaucoma data leads to a mean absolute error of 2.6 μm when using the same gold standard segmentation approach, and 3.7 μm mean absolute error in an externally segmented data set. In scans from patients with severe optic atrophy, 3.5% of B-scan segmentation results were rejected by an experienced grader, whereas this was the case in 41.4% of B-scans segmented with a graph-based reference method. The validation results suggest that the proposed method can robustly segment macular scans from eyes with even severe neuroretinal changes.
Keyphrases
- optical coherence tomography
- convolutional neural network
- deep learning
- multiple sclerosis
- computed tomography
- diabetic retinopathy
- optic nerve
- electronic health record
- contrast enhanced
- big data
- magnetic resonance imaging
- artificial intelligence
- dual energy
- traumatic brain injury
- early onset
- lipopolysaccharide induced
- white matter
- cognitive impairment
- inflammatory response
- drug induced
- data analysis
- mild cognitive impairment