Customizable tubular model for n-furcating blood vessels and its application to 3D reconstruction of the cerebrovascular system

Michal Chlebiej, Anna Zurada, Jerzy Gielecki, Mikolaj A. Pawlak, Maciej Szkulmowski*

*Corresponding author for this work

Research output: Contribution to journalArticleAcademicpeer-review

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Abstract

Understanding the 3D cerebral vascular network is one of the pressing issues impacting the diagnostics of various systemic disorders and is helpful in clinical therapeutic strategies. Unfortunately, the existing software in the radiological workstation does not meet the expectations of radiologists who require a computerized system for detailed, quantitative analysis of the human cerebrovascular system in 3D and a standardized geometric description of its components. In this study, we show a method that uses 3D image data from magnetic resonance imaging with contrast to create a geometrical reconstruction of the vessels and a parametric description of the reconstructed segments of the vessels. First, the method isolates the vascular system using controlled morphological growing and performs skeleton extraction and optimization. Then, around the optimized skeleton branches, it creates tubular objects optimized for quality and accuracy of matching with the originally isolated vascular data. Finally, it optimizes the joints on n-furcating vessel segments. As a result, the algorithm gives a complete description of shape, position in space, position relative to other segments, and other anatomical structures of each cerebrovascular system segment. Our method is highly customizable and in principle allows reconstructing vascular structures from any 2D or 3D data. The algorithm solves shortcomings of currently available methods including failures to reconstruct the vessel mesh in the proximity of junctions and is free of mesh collisions in high curvature vessels. It also introduces a number of optimizations in the vessel skeletonization leading to a more smooth and more accurate model of the vessel network. We have tested the method on 20 datasets from the public magnetic resonance angiography image database and show that the method allows for repeatable and robust segmentation of the vessel network and allows to compute vascular lateralization indices. Graphical abstract: [Figure not available: see fulltext.]

Original languageEnglish
Pages (from-to)1343-1361
Number of pages19
JournalMedical and Biological Engineering and Computing
Volume61
Issue number6
Early online date26 Jan 2023
DOIs
Publication statusPublished - Jun 2023

Bibliographical note

Funding Information: The research was partially supported by the National Science Centre (grant No. 2012/07/D/ST6/02479) and partially by the Foundation for Polish Science project (POIR.04.04.00–00-2070/16–00) carried out within the TEAM TECH program co-financed by the European Union under the European Regional Development Fund.

Publisher Copyright: © 2023, The Author(s).

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