Computational Biomechanics for Medicine III
A MICCAI 2008 Workshop, September 10 2008
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Rationale:
Mathematical modelling and computer simulation have
proved tremendously successful in engineering. One of the greatest challenges
for mechanists is to extend the success of computational mechanics to fields
outside traditional engineering, in particular to biology, biomedical sciences,
and medicine. The proposed workshop will provide an opportunity for
computational biomechanics specialists to present and exchange opinions on the
opportunities of applying their techniques to computer-integrated medicine. For
example, continuum mechanics models provide a rational basis for analysing biomedical images by constraining the solution to
biologically reasonable motions and processes. Biomechanical modelling can also provide clinically important information
about the physical status of the underlying biology, integrating information
across molecular, tissue, organ, and organism scales. The main goal of this
workshop is to showcase the clinical and scientific utility of computational
biomechanics in computer-integrated medicine.
The authors of the best papers presented at the Computational Biomechanics for
Medicine workshop will be requested to submit an extended version of their
papers to the special section of the Medical Image Analysis journal.
Program (provisional)
Invited
lectures are planned for 40 min + 20 min discussion
Podium
presentations are planned for 20 min + 10 min discussion
7.30-8.00 Registration
08.00-08.10 Opening remarks (Karol Miller)
Stream 1. Computational
biomechanics of soft tissues
8.10 – 9.10 Invited Lecture 1: Molecular
and Cellular Biomechanics-based Insights into the Pathophysiology
of Human Diseases
Chwee Teck LIM
9.10 – 9.40 Cardiac
motion estimation using multi-scale feature points
Becciu A; van Assen H; Florack L; Janssen
B; ter Haar Romeny B
9.40
– 10.10 Fast image-based model of mitral
valve closure for surgical planning
Hammer P; Vasilyev N; Perrin D; del Nido P; Howe R
10.10 – 10.30 Coffee break
10.30-11.00 Multimodal
Registration of White Matter Brain Data via Optimal Mass Transport
Rehman,
Tauseef; Haber, Eldad; Pohl, Kilian;
Haker, Steven; Halle, Mike; Talos,
Florin; Wald, Lawrence; Kikinis, Ron; Tannenbaum,
Allen
11.00-11.30 Cardiac Motion Recovery by Coupling an Electromechanical Model and Cine-MRI Data: First Steps
Billet F; Sermesant M; Delingette H; Ayache
N
11.30-12.00 Comparison of
Displacement-Based and Force-Based Mapped Meshing
Magnotta V.A, Li W, Grosland N.M.
12.00 – 13.00 Lunch and registration
13.00 – 14.00 Poster Session
Nonlinear
Elastic Registration with Unbiased Regularization in Three Dimensions
Yanovsky I; Le Guyader C; Leow A; Thompson P; Vese L
Coupling Finite Element and Mesh-free Methods for Modelling Brain Deformation in Response to Tumour Growth
Berger, Jamie; Horton, Asley; Joldes, Grand; Wittek
Simulation of Active Cardiac Dynamics with Orthotropic Hyperelastic Material Model
Wong, Ken C.L.; Wang, Linwei; Zhang, Heye; Liu, Huafeng; Shi, Pengcheng
Realistic And Efficient Brain-Skull Interaction Model For Brain Shift Computation
Joldes, Grand Roman; Wittek, Adam;
Miller, Karol; Morriss,
Jonathan Vappou, Ioannis Zervantonakis, Jianwen Luo, and Elisa Konofagou
Stream
2. Computational biomechanics of tissues of musculoskeletal system
14.00 – 15.00 Invited Lecture 2: Computation Biomechanics: Neuromuscular
skeletal modelling to estimate tissue loading in the lower limbs
David
Lloyd
15.00 – 15.30 Coffee break
15.30 – 16.00 Assessment of
Peri-Articular Implant Fitting Based on Statistical
Finite Element Modeling
Bonaretti S; Reimers N; Reyes M; Nikitsin A; Joensson A; Nolte L
16.00 – 16.30 Orientation definition
of anisotropy is important to finite element simulation
of bone material properties
16.30 – 16.40 Close