The Johns
Hopkins University
Whiting School of Engineering
Department of
Electrical and Computer Engineering
HYBRID DEFORMABLE IMAGE REGISTRATION --
WITH APPLICATION TO BRAINS, PELIVSES, AND STATISTICAL ATLASES
A
Dissertation Defense by
Lotta Ellingsen
Graduate Research Assistant
Electrical and Computer Engineering
Abstract:
Medical
image registration methods have been evolving dramatically over the last two
decades from being perceived as a rather minor precursor to some medical
imaging applications to becoming a major tool itself in medical image analysis. Image registration is a crucial step in many
medical image analysis algorithms such as segmentation and labeling, as well as
being an important step in population studies involving shape, volume, and
functional changes in both health and disease.
This
dissertation makes three major contributions:
First, a new approach to volumetric intersubject deformable image
registration method is proposed for magnetic resonance (MR) images of the human
brain. The method is a significant
extension of the highly successful method HAMMER. The method introduces new image features in
order to better identify anatomical correspondences between subjects. A novel approach to generate a dense
displacement field based upon the weighted diffusion of the automatically
derived feature correspondences is introduced.
An extensive validation of the new algorithm was performed on T1
weighted MR images of the human brain.
The results were compared with results generated by HAMMER and are shown
to yield significant improvements in terms of anatomical alignment,
particularly of the brain cortex, as well as in reduced computation time. In the second contribution, the registration
algorithm has been adapted to register computed tomography (CT) images of the
human pelvis. Furthermore, an approach
is presented to register a statistical atlas comprising a point distribution
model based on a tetrahedral mesh to a subject's CT scan. This new approach comprises a further
augmentation of the core method to maintain the topology of the atlas mesh
after deformation as well as incorporating statistical shape information from
an atlas to make the registration more robust.
Results on CT images of the human pelvis demonstrate the benefits of
incorporating prior shape information from the atlas into a registration framework. The third and final contribution of this
dissertation presents an approach to preserve the topology of multiple
segmented structures as well as their connectivity relationships to each other
during registration by incorporating digital homeomorphism into the
registration framework.
Monday, December 17, 2007
10:00 a.m.
Barton Hall 225
FOR DISABILITY
INFORMATION
CONTACT: Candace Abel (410) 516-7031 cabel@jhu.edu