The finite element method is applied to the biomechanics of brain tissue deformation.
Emphasis is given to the deformations induced by the growth of tumors, and to the …

A biomechanical model of the brain is presented, using a finite-element formulation.
Emphasis is given to the modeling of the soft-tissue deformations induced by the growth of …

Motivated by the need for methods to aid the deformable registration of brain tumor images,
we present a three-dimensional (3D) mechanical model for simulating large non-linear …

In the present study, fully nonlinear (ie accounting for both geometric and material
nonlinearities) patient specific finite element brain model was applied to predict deformation …

A framework for modeling and predicting anatomical deformations is presented, and tested
on simulated images. Although a variety of deformations can be modeled in this framework …

An approach to the deformable registration of three-dimensional brain tumor images to a
normal brain atlas is presented. The approach involves the integration of three components …

The objective of our research is to create a system computing brain deformations. We have
in view both clinical and training applications, such as" brain shift" calculation, prognosis …

Patient-specific biomechanical models implemented using specialized nonlinear (ie taking
into account material and geometric nonlinearities) finite element procedures were applied …

Simulating the brain tissue deformation caused by tumor growth has been found to aid the
deformable registration of brain tumor images. In this paper, we evaluate the impact that …

Long computation times of non-linear (ie accounting for geometric and material non-
linearity) biomechanical models have been regarded as one of the key factors preventing …