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Main Authors: Machta, Yassine, Ali, Omar, Hakkakian, Kevin, Vlasceanu, Ana, Facque, Amaury, Golse, Nicolas, Vignon-Clementel, Irene
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2411.15778
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author Machta, Yassine
Ali, Omar
Hakkakian, Kevin
Vlasceanu, Ana
Facque, Amaury
Golse, Nicolas
Vignon-Clementel, Irene
author_facet Machta, Yassine
Ali, Omar
Hakkakian, Kevin
Vlasceanu, Ana
Facque, Amaury
Golse, Nicolas
Vignon-Clementel, Irene
contents Surgical assessment of liver cancer patients requires identification of the vessel trees from medical images. Specifically, the venous trees - the portal (perfusing) and the hepatic (draining) trees are important for understanding the liver anatomy and disease state, and perform surgery planning. This research aims to improve the 3D segmentation, skeletonization, and subsequent analysis of vessel trees, by creating an automatic pipeline based on deep learning and image processing techniques. The first part of this work explores the impact of differentiable skeletonization methods such as ClDice and morphological skeletonization loss, on the overall liver vessel segmentation performance. To this aim, it studies how to improve vessel tree connectivity. The second part of this study converts a single class vessel segmentation into multi-class ones, separating the two venous trees. It builds on the previous two-class vessel segmentation model, which vessel tree outputs might be entangled, and on connected components and skeleton analyses of the trees. After providing sub-labeling of the specific anatomical branches of each venous tree, these algorithms also enable a morphometric analysis of the vessel trees by extracting various geometrical markers. In conclusion, we propose a method that successfully improves current skeletonization methods, for extensive vascular trees that contain vessels of different calibers. The separation algorithm creates a clean multi-class segmentation of the vessels, validated by surgeons to provide low error. A new, publicly shared high-quality liver vessel dataset of 77 cases is thus created. Finally a method to annotate vessel trees according to anatomy is provided, enabling a unique liver vessel morphometry analysis.
format Preprint
id arxiv_https___arxiv_org_abs_2411_15778
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Enhancing the automatic segmentation and analysis of 3D liver vasculature models
Machta, Yassine
Ali, Omar
Hakkakian, Kevin
Vlasceanu, Ana
Facque, Amaury
Golse, Nicolas
Vignon-Clementel, Irene
Image and Video Processing
Artificial Intelligence
Computer Vision and Pattern Recognition
Surgical assessment of liver cancer patients requires identification of the vessel trees from medical images. Specifically, the venous trees - the portal (perfusing) and the hepatic (draining) trees are important for understanding the liver anatomy and disease state, and perform surgery planning. This research aims to improve the 3D segmentation, skeletonization, and subsequent analysis of vessel trees, by creating an automatic pipeline based on deep learning and image processing techniques. The first part of this work explores the impact of differentiable skeletonization methods such as ClDice and morphological skeletonization loss, on the overall liver vessel segmentation performance. To this aim, it studies how to improve vessel tree connectivity. The second part of this study converts a single class vessel segmentation into multi-class ones, separating the two venous trees. It builds on the previous two-class vessel segmentation model, which vessel tree outputs might be entangled, and on connected components and skeleton analyses of the trees. After providing sub-labeling of the specific anatomical branches of each venous tree, these algorithms also enable a morphometric analysis of the vessel trees by extracting various geometrical markers. In conclusion, we propose a method that successfully improves current skeletonization methods, for extensive vascular trees that contain vessels of different calibers. The separation algorithm creates a clean multi-class segmentation of the vessels, validated by surgeons to provide low error. A new, publicly shared high-quality liver vessel dataset of 77 cases is thus created. Finally a method to annotate vessel trees according to anatomy is provided, enabling a unique liver vessel morphometry analysis.
title Enhancing the automatic segmentation and analysis of 3D liver vasculature models
topic Image and Video Processing
Artificial Intelligence
Computer Vision and Pattern Recognition
url https://arxiv.org/abs/2411.15778