A robust framework for soft tissue simulations with application to modeling brain tumor mass effect in 3D MR images

We present a framework for black-box and flexible simulation of soft tissue deformation for medical imaging and surgical planning applications. Our main motivation in the present work is to develop robust algorithms that allow batch processing for registration of brains with tumors to statistical at...

Full description

Saved in:
Bibliographic Details
Published in:Physics in medicine & biology 2007-12, Vol.52 (23), p.6893-6908
Main Authors: Hogea, Cosmina, Biros, George, Abraham, Feby, Davatzikos, Christos
Format: Article
Language:English
Subjects:
Algorithms
Brain Neoplasms - diagnosis
Brain Neoplasms - physiopathology
Computer Simulation
Connective Tissue - pathology
Connective Tissue - physiopathology
Humans
Image Enhancement - methods
Image Interpretation, Computer-Assisted - methods
Magnetic Resonance Imaging - methods
Models, Neurological
Reproducibility of Results
Sensitivity and Specificity
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:We present a framework for black-box and flexible simulation of soft tissue deformation for medical imaging and surgical planning applications. Our main motivation in the present work is to develop robust algorithms that allow batch processing for registration of brains with tumors to statistical atlases of normal brains and construction of brain tumor atlases. We describe a fully Eulerian formulation able to handle large deformations effortlessly, with a level-set-based approach for evolving fronts. We use a regular grid-fictitious domain method approach, in which we approximate coefficient discontinuities, distributed forces and boundary conditions. This approach circumvents the need for unstructured mesh generation, which is often a bottleneck in the modeling and simulation pipeline. Our framework employs penalty approaches to impose boundary conditions and uses a matrix-free implementation coupled with a multigrid-accelerated Krylov solver. The overall scheme results in a scalable method with minimal storage requirements and optimal algorithmic complexity. We illustrate the potential of our framework to simulate realistic brain tumor mass effects at reduced computational cost, for aiding the registration process towards the construction of brain tumor atlases.
ISSN:0031-9155
1361-6560
DOI:10.1088/0031-9155/52/23/008