A new geodesic-based feature for characterization of 3D shapes: application to soft tissue organ temporal deformations

Makki, Karim; Bohi, Amine; Ogier, Augustin C.; Bellemare, Marc Emmanuel

doi:10.1109/icpr48806.2021.9412922

Cited by 2 publications

(2 citation statements)

References 35 publications

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“…Besides, future studies will be conducted with the ethical authorization to inject extrageneous liquid into the rectal and vaginal cavities in order to segment all pelvic organs and study the complete pelvic dynamics. The ability to now obtain dynamic 3D volumes allows the development of more advanced 3D shape descriptors [41] to better characterize the degree of severity of a pathology for diagnostic assistance. These studies are a 3D extension of descriptors such as we already proposed for 2D dynamic pelvic acquisitions [8].…”

Section: Discussionmentioning

confidence: 99%

Four-dimensional reconstruction and characterization of bladder deformations

Ogier

Rapacchi

Bellemare

2023

Computer Methods and Programs in Biomedicine

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Section: Discussionmentioning

confidence: 99%

Four-dimensional reconstruction and characterization of bladder deformations

Ogier

Rapacchi

Bellemare

2023

Computer Methods and Programs in Biomedicine

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“…Promising results were obtained, showing the bladder in its 3D complexity during deformation due to strain conditions with an estimation of the most deformed tissue areas. These high-resolution temporal data are then employed to introduce a compact characterization of bladder surfaces in [30].…”

Section: Related Workmentioning

confidence: 99%

Characterization of surface motion patterns in highly deformable soft tissue organs from dynamic MRI: An application to assess 4D bladder motion

Makki¹,

Bohi²,

Ogier³

et al. 2020

Preprint

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In this work, we present a pipeline for characterization of bladder surface dynamics during deep respiratory movements from dynamic Magnetic Resonance Imaging (MRI). Dynamic MRI may capture temporal anatomical changes in soft tissue organs with high-contrast but the obtained sequences usually suffer from limited volume coverage which makes the high resolution reconstruction of organ shape trajectories a major challenge in temporal studies. For a compact shape representation, the reconstructed temporal data with full volume coverage are first used to establish a subject-specific dynamical 4D mesh sequences using the large deformation diffeomorphic metric mapping (LDDMM) framework. Then, we performed a statistical characterization of organ shape changes from mechanical parameters such as mesh elongations and distortions. Since shape space is curved, we have also used the intrinsic curvature changes as metric to quantify surface evolution. However, the numerical computation of curvature is strongly dependant on the surface parameterization (i.e. the mesh resolution). To cope with this dependency, we propose a non-parametric level set method to evaluate spatio-temporal surface evolution. Independent of parameterization and minimizing the length of the geodesic curves, it shrinks smoothly the surface curves towards a sphere by minimizing a Dirichlet energy. An Eulerian PDE approach is used for evaluation of surface dynamics from the curve-shortening flow. Results demonstrate the numerical stability of the derived descriptor throughout smooth continuous-time organ trajectories. Intercorrelations between individuals' motion patterns from different geometric features are computed using the Laplace-Beltrami Operator (LBO) eigenfunctions for spherical mapping.

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A new geodesic-based feature for characterization of 3D shapes: application to soft tissue organ temporal deformations

Cited by 2 publications

References 35 publications

Four-dimensional reconstruction and characterization of bladder deformations

Four-dimensional reconstruction and characterization of bladder deformations

Characterization of surface motion patterns in highly deformable soft tissue organs from dynamic MRI: An application to assess 4D bladder motion

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