Deep learning segmentation of fibrous cap in intravascular optical coherence tomography images

Juhwan Lee; Justin N. Kim; Luis A. P. Dallan; Vladislav N. Zimin; Ammar Hoori; Neda S. Hassani; Mohamed H. E. Makhlouf; Giulio Guagliumi; Hiram G. Bezerra; David L. Wilson

doi:10.1038/s41598-024-55120-7

Scientific Reports (Feb 2024)

Deep learning segmentation of fibrous cap in intravascular optical coherence tomography images

Juhwan Lee,
Justin N. Kim,
Luis A. P. Dallan,
Vladislav N. Zimin,
Ammar Hoori,
Neda S. Hassani,
Mohamed H. E. Makhlouf,
Giulio Guagliumi,
Hiram G. Bezerra,
David L. Wilson

Affiliations

Juhwan Lee: Department of Biomedical Engineering, Case Western Reserve University
Justin N. Kim: Department of Biomedical Engineering, Case Western Reserve University
Luis A. P. Dallan: Harrington Heart and Vascular Institute, University Hospitals Cleveland Medical Center
Vladislav N. Zimin: Brookdale University Hospital Medical Center
Ammar Hoori: Department of Biomedical Engineering, Case Western Reserve University
Neda S. Hassani: Harrington Heart and Vascular Institute, University Hospitals Cleveland Medical Center
Mohamed H. E. Makhlouf: Harrington Heart and Vascular Institute, University Hospitals Cleveland Medical Center
Giulio Guagliumi: Cardiovascular Department, Innovation District, Galeazzi San’Ambrogio Hospital
Hiram G. Bezerra: Interventional Cardiology Center, Heart and Vascular Institute, University of South Florida
David L. Wilson: Department of Biomedical Engineering, Case Western Reserve University

DOI: https://doi.org/10.1038/s41598-024-55120-7
Journal volume & issue: Vol. 14, no. 1
pp. 1 – 13

Abstract

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Abstract Thin-cap fibroatheroma (TCFA) is a prominent risk factor for plaque rupture. Intravascular optical coherence tomography (IVOCT) enables identification of fibrous cap (FC), measurement of FC thicknesses, and assessment of plaque vulnerability. We developed a fully-automated deep learning method for FC segmentation. This study included 32,531 images across 227 pullbacks from two registries (TRANSFORM-OCT and UHCMC). Images were semi-automatically labeled using our OCTOPUS with expert editing using established guidelines. We employed preprocessing including guidewire shadow detection, lumen segmentation, pixel-shifting, and Gaussian filtering on raw IVOCT (r,θ) images. Data were augmented in a natural way by changing θ in spiral acquisitions and by changing intensity and noise values. We used a modified SegResNet and comparison networks to segment FCs. We employed transfer learning from our existing much larger, fully-labeled calcification IVOCT dataset to reduce deep-learning training. Postprocessing with a morphological operation enhanced segmentation performance. Overall, our method consistently delivered better FC segmentation results (Dice: 0.837 ± 0.012) than other deep-learning methods. Transfer learning reduced training time by 84% and reduced the need for more training samples. Our method showed a high level of generalizability, evidenced by highly-consistent segmentations across five-fold cross-validation (sensitivity: 85.0 ± 0.3%, Dice: 0.846 ± 0.011) and the held-out test (sensitivity: 84.9%, Dice: 0.816) sets. In addition, we found excellent agreement of FC thickness with ground truth (2.95 ± 20.73 µm), giving clinically insignificant bias. There was excellent reproducibility in pre- and post-stenting pullbacks (average FC angle: 200.9 ± 128.0°/202.0 ± 121.1°). Our fully automated, deep-learning FC segmentation method demonstrated excellent performance, generalizability, and reproducibility on multi-center datasets. It will be useful for multiple research purposes and potentially for planning stent deployments that avoid placing a stent edge over an FC.

Published in Scientific Reports

ISSN: 2045-2322 (Online)
Publisher: Nature Portfolio
Country of publisher: United Kingdom
LCC subjects: Medicine; Science
Website: https://www.nature.com/srep/

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