Segmentation of vessels cluttered with cells using a physics based model

Segmentation of vessels in biomedical images is important as it can provide insight into analysis of vascular morphology, topology and is required for kinetic analysis of flow velocity and vessel permeability. Intravital microscopy is a powerful tool as it enables in vivo imaging of both vasculature...

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Published inMedical image computing and computer-assisted intervention : MICCAI ... International Conference on Medical Image Computing and Computer-Assisted Intervention Vol. 11; no. Pt 1; p. 127
Main Authors Schmugge, Stephen J, Keller, Steve, Nguyen, Nhat, Souvenir, Richard, Huynh, Toan, Clemens, Mark, Shin, Min C
Format Journal Article
LanguageEnglish
Published Germany 2008
Subjects
Algorithms
Animals
Artificial Intelligence
Blood Cells - cytology
Blood Vessels - cytology
Computer Simulation
Image Enhancement - methods
Image Interpretation, Computer-Assisted - methods
Microscopy, Video - methods
Models, Biological
Pattern Recognition, Automated - methods
Physics - methods
Rats
Reproducibility of Results
Sensitivity and Specificity
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Summary:Segmentation of vessels in biomedical images is important as it can provide insight into analysis of vascular morphology, topology and is required for kinetic analysis of flow velocity and vessel permeability. Intravital microscopy is a powerful tool as it enables in vivo imaging of both vasculature and circulating cells. However, the analysis of vasculature in those images is difficult due to the presence of cells and their image gradient. In this paper, we provide a novel method of segmenting vessels with a high level of cell related clutter. A set of virtual point pairs ("vessel probes") are moved reacting to forces including Vessel Vector Flow (VVF) and Vessel Boundary Vector Flow (VBVF) forces. Incorporating the cell detection, the VVF force attracts the probes toward the vessel, while the VBVF force attracts the virtual points of the probes to localize the vessel boundary without being distracted by the image features of the cells. The vessel probes are moved according to Newtonian Physics reacting to the net of forces applied on them. We demonstrate the results on a set of five real in vivo images of liver vasculature cluttered by white blood cells. When compared against the ground truth prepared by the technician, the Root Mean Squared Error (RMSE) of segmentation with VVF and VBVF was 55% lower than the method without VVF and VBVF.
DOI:10.1007/978-3-540-78678-8_3