Retinal Vessel Plexus Differentiation Based on OCT Angiography Using Deep Learning

Jamie L Shaffer; Luis De Sisternes; Anand E Rajesh; Marian S Blazes; Yuka Kihara; Cecilia S Lee; Warren H Lewis; Roger A Goldberg; Niranchana Manivannan; Aaron Y Lee

doi:10.1016/j.xops.2024.100605

Retinal Vessel Plexus Differentiation Based on OCT Angiography Using Deep Learning

Ophthalmol Sci. 2024 Aug 23;5(1):100605. doi: 10.1016/j.xops.2024.100605. eCollection 2025 Jan-Feb.

Authors

Jamie L Shaffer^{1

2}, Luis De Sisternes³, Anand E Rajesh^{1

2}, Marian S Blazes^{1

2}, Yuka Kihara^{1

2}, Cecilia S Lee^{1

2}, Warren H Lewis⁴, Roger A Goldberg⁵, Niranchana Manivannan³, Aaron Y Lee^{1

2}

Affiliations

¹ Department of Ophthalmology, UW Medicine, Seattle, Washington.
² The Roger and Angie Karalis Johnson Retina Center, Seattle, Washington.
³ Research and Development, Carl Zeiss Meditec Inc, Dublin, California.
⁴ Bayside Photonics, Inc, Yellow Springs, Ohio.
⁵ Bay Area Retina Associates, Walnut Creek, California.

Abstract

Purpose: Although structural OCT is traditionally used to differentiate the vascular plexus layers in OCT angiography (OCTA), the vascular plexuses do not always obey the retinal laminations. We sought to segment the superficial, deep, and avascular plexuses from OCTA images using deep learning without structural OCT image input or segmentation boundaries.

Design: Cross-sectional study.

Subjects: The study included 235 OCTA cubes from 33 patients for training and testing of the model.

Methods: From each OCTA cube, 3 weakly labeled images representing the superficial, deep, and avascular plexuses were obtained for a total of 705 starting images. Images were augmented with standard intensity and geometric transforms, and regions from adjacent plexuses were programmatically combined to create synthetic 2-class images for each OCTA cube. Images were partitioned on a per patient basis into training, validation, and reserved test groups to train and evaluate a U-Net based machine learning model. To investigate the generalization of the model, we applied the model to multiclass thin slabs from OCTA volumes and qualitatively observed the resulting b-scans.

Main outcome measures: Plexus segmentation performance was assessed quantitatively using Dice scores on a held-out test set.

Results: After training on single-class plexus images, our model achieved good results (Dice scores > 0.82) and was further improved when using the synthetic 2-class images (Dice >0.95). Although not trained on more complex multiclass slabs, the model performed plexus labeling on slab data, which indicates that the use of only OCTA data shows promise for segmenting the superficial, deep, and avascular plexuses without requiring OCT layer segmentations, and the use of synthetic 2-class images makes a significant performance improvement.

Conclusions: This study presents the use of OCTA data alone to segment the superficial, deep, and avascular plexuses of the retina, confirming that use of structural OCT layer segmentations as boundaries is not required.

Financial disclosures: Proprietary or commercial disclosure may be found in the Footnotes and Disclosures at the end of this article.

Keywords: Deep learning; OCT angiography; Retinal vascular plexus; Retinal vasculature.