Nowadays, image processing and 3D shape analysis are an integral part of clinical
practice and have the potentiality to support clinicians with advanced analysis
and visualization techniques. Both approaches provide visual and quantitative information
to medical practitioners, even if from different points of view. Indeed,
shape analysis is aimed at studying the morphology of anatomical structures, while
image processing is focused more on the tissue or functional information provided
by the pixels/voxels intensities levels. Despite the progress obtained by research in
both fields, a junction between these two complementary worlds is missing. When
working with 3D models analyzing shape features, the information of the volume
surrounding the structure is lost, since a segmentation process is needed to obtain
the 3D shape model; however, the 3D nature of the anatomical structure is represented
explicitly. With volume images, instead, the tissue information related to the
imaged volume is the core of the analysis, while the shape and morphology of the
structure are just implicitly represented, thus not clear enough.
The aim of this Thesis work is the integration of these two approaches in order to increase
the amount of information available for physicians, allowing a more accurate
analysis of each patient. An augmented visualization tool able to provide information
on both the anatomical structure shape and the surrounding volume through a
hybrid representation, could reduce the gap between the two approaches and provide
a more complete anatomical rendering of the subject.
To this end, given a segmented anatomical district, we propose a novel mapping of
volumetric data onto the segmented surface. The grey-levels of the image voxels are
mapped through a volume-surface correspondence map, which defines a grey-level
texture on the segmented surface. The resulting texture mapping is coherent to the
local morphology of the segmented anatomical structure and provides an enhanced
visual representation of the anatomical district. The integration of volume-based and
surface-based information in a unique 3D representation also supports the identification
and characterization of morphological landmarks and pathology evaluations.
The main research contributions of the Ph.D. activities and Thesis are:
\u2022 the development of a novel integration algorithm that combines surface-based
(segmented 3D anatomical structure meshes) and volume-based (MRI volumes)
information. The integration supports different criteria for the grey-levels mapping
onto the segmented surface;
\u2022 the development of methodological approaches for using the grey-levels mapping
together with morphological analysis. The final goal is to solve problems
in real clinical tasks, such as the identification of (patient-specific) ligament
insertion sites on bones from segmented MR images, the characterization of
the local morphology of bones/tissues, the early diagnosis, classification, and
monitoring of muscle-skeletal pathologies;
\u2022 the analysis of segmentation procedures, with a focus on the tissue classification
process, in order to reduce operator dependency and to overcome the
absence of a real gold standard for the evaluation of automatic segmentations;
\u2022 the evaluation and comparison of (unsupervised) segmentation methods, finalized
to define a novel segmentation method for low-field MR images, and for
the local correction/improvement of a given segmentation.
The proposed method is simple but effectively integrates information derived from
medical image analysis and 3D shape analysis. Moreover, the algorithm is general
enough to be applied to different anatomical districts independently of the segmentation
method, imaging techniques (such as CT), or image resolution. The volume
information can be integrated easily in different shape analysis applications, taking
into consideration not only the morphology of the input shape but also the real
context in which it is inserted, to solve clinical tasks. The results obtained by this
combined analysis have been evaluated through statistical analysis