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Retinal Layer Segmentation in OCT Images With 2.5D Cross-slice Feature Fusion Module for Glaucoma Assessment

Hyunwoo Kim, Heesuk Kim, Wungrak Choi, Jae-Sang Hyun

Abstract

For accurate glaucoma diagnosis and monitoring, reliable retinal layer segmentation in OCT images is essential. However, existing 2D segmentation methods often suffer from slice-to-slice inconsistencies due to the lack of contextual information across adjacent B-scans. 3D segmentation methods are better for capturing slice-to-slice context, but they require expensive computational resources. To address these limitations, we propose a 2.5D segmentation framework that incorporates a novel cross-slice feature fusion (CFF) module into a U-Net-like architecture. The CFF module fuses inter-slice features to effectively capture contextual information, enabling consistent boundary detection across slices and improved robustness in noisy regions. The framework was validated on both a clinical dataset and the publicly available DUKE DME dataset. Compared to other segmentation methods without the CFF module, the proposed method achieved an 8.56% reduction in mean absolute distance and a 13.92% reduction in root mean square error, demonstrating improved segmentation accuracy and robustness. Overall, the proposed 2.5D framework balances contextual awareness and computational efficiency, enabling anatomically reliable retinal layer delineation for automated glaucoma evaluation and potential clinical applications.

Retinal Layer Segmentation in OCT Images With 2.5D Cross-slice Feature Fusion Module for Glaucoma Assessment

Abstract

For accurate glaucoma diagnosis and monitoring, reliable retinal layer segmentation in OCT images is essential. However, existing 2D segmentation methods often suffer from slice-to-slice inconsistencies due to the lack of contextual information across adjacent B-scans. 3D segmentation methods are better for capturing slice-to-slice context, but they require expensive computational resources. To address these limitations, we propose a 2.5D segmentation framework that incorporates a novel cross-slice feature fusion (CFF) module into a U-Net-like architecture. The CFF module fuses inter-slice features to effectively capture contextual information, enabling consistent boundary detection across slices and improved robustness in noisy regions. The framework was validated on both a clinical dataset and the publicly available DUKE DME dataset. Compared to other segmentation methods without the CFF module, the proposed method achieved an 8.56% reduction in mean absolute distance and a 13.92% reduction in root mean square error, demonstrating improved segmentation accuracy and robustness. Overall, the proposed 2.5D framework balances contextual awareness and computational efficiency, enabling anatomically reliable retinal layer delineation for automated glaucoma evaluation and potential clinical applications.
Paper Structure (20 sections, 8 equations, 6 figures, 3 tables)

This paper contains 20 sections, 8 equations, 6 figures, 3 tables.

Table of Contents

  1. Introduction
  2. Related Works
  3. Traditional methods
  4. Deep learning methods
  5. 2.5D segmentation methods
  6. Methods
  7. Overview
  8. Pre-processing
  9. Cross-slice feature fusion (CFF) module
  10. Network architecture
  11. Experiments
  12. Dataset
  13. Our dataset.
  14. DUKE DME dataset.
  15. Comparative methods and evaluation metrics
  16. ...and 5 more sections

Figures (6)

  • Figure 1: Overview of the proposed method.
  • Figure 2: Pre-processing steps for OCT images.
  • Figure 3: Overview of cross-slice feature fusion (CFF) module with input $F$ and output $F_{\text{fused}}$.
  • Figure 4: Example of our dataset. (a) Structure of the macular cube. (b) B-scan from the middle of the macular cube with 5 target retinal layer boundaries annotated by experienced clinicians.
  • Figure 5: Qualitative results of the comparison methods on our dataset. The rows represent three consecutive B-scans. An enlarged region is shown in the upper-right corner of each image.
  • ...and 1 more figures