Virtual image correlation of magnetic resonance images for 3D geometric modelling of pelvic organs

Jiang, Zhifan; Mayeur, Olivier; Witz, Jean‐François; Lecomte‐Grosbras, Pauline; Dequidt, Jérémie; Cosson, Michel; Duriez, Christian; Brieu, Mathias

doi:10.1111/str.12305

Cited by 7 publications

(8 citation statements)

References 38 publications

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“…We assume that the material is homogeneous. Based on the semi‐automatic detection on MRI, a FE model is generated thanks to shell elements for the organs (vagina, bladder and rectum) and pelvic floor . Ligaments are also considered with truss elements to mimic the sustainable structures, as they play a key role in the organ's mobility …”

Section: Resultsmentioning

confidence: 99%

“…Results were reported with respect to pelvic organ prolapse quantification system (POP‐Q). In parallel with the previous contributions, dealt with the issue of geometric modelling of pelvic organs that had not been treated in these contributions. Bay et al presented a method to reconstruct hollow organs with a thickness from pre‐segmented points cloud.…”

Section: Related Workmentioning

confidence: 99%

“…Bay et al presented a method to reconstruct hollow organs with a thickness from pre‐segmented points cloud. In Jiang et al, a more efficient approach was proposed to generate readily usable computer‐assisted design (CAD) pelvic geometries for FE simulations. The geometry construction was validated by using a controlled physical model .…”

Section: Related Workmentioning

confidence: 99%

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Three‐dimensional physics‐based registration of pelvic system using 2D dynamic magnetic resonance imaging slices

Courtecuisse

Jiang

Mayeur

et al. 2020

Strain

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This paper introduces a method for dynamic 3D registration of female pelvic organs using 2D dynamic magnetic-resonance images (MRIs). The aim is to provide a better knowledge and understanding of pathologies such as prolapsus or abnormal mobility of tissues. 2D dynamic MRI sequences are commonly used in nowadays clinical routines in order to evaluate the dynamic of organs, but due to the limited view, subjectivity related to human perception cannot be avoided in the diagnoses. A novel method for 2D/3D registration is proposed combining 3D finite element models with a priori knowledge of boundary conditions, in order to provide a 3D extrapolation of the dynamic of the organs observed in a single 2D MRI slice. The method is applied to the four main structures of the female pelvic floor (bladder, vagina, uterus and rectum), providing a full 3D visualisation of the organs' displacements. The methodology is evaluated with two patient-specific data sets of volunteers presenting no pelvic pathology, and a sensitivity study is performed using synthetic data. The resulting simulations provide an estimation of the dynamic 3D shape of the organs facilitating diagnosis compared with 2D sequences. Moreover, the method follows a protocol compatible with current clinical constraints presenting this way potential short term medical applications.

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Section: Resultsmentioning

confidence: 99%

Section: Related Workmentioning

confidence: 99%

Section: Related Workmentioning

confidence: 99%

See 1 more Smart Citation

Three‐dimensional physics‐based registration of pelvic system using 2D dynamic magnetic resonance imaging slices

Courtecuisse

Jiang

Mayeur

et al. 2020

Strain

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“…[51][52][53]57 The VIC variant reviewed in this section seems to be the most modern one. 55,56 It achieves a good compromise between simplicity and efficiency.…”

Section: Algorithmmentioning

confidence: 99%

Image‐based isogeometric twins of lattices with virtual image correlation for varying cross‐section beams

Passieux

Bouclier

Weeger

2023

Numerical Meth Engineering

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Cellular materials, in particular metal or polymer foams and beam lattices, are characterized by a complex architecture where the material is concentrated in slender struts. This study is concerned with the construction of numerically efficient sample-specific digital twin for the analysis and characterization of the mechanical behavior of such meta-materials. A method to build an explicit, light, and analysis-suitable isogeometric beam model directly from digital images is proposed. More precisely, as a main contribution, the virtual image correlation method is extended to the case of multiple interconnected beams with varying cross-sections. Special care is also given to the initialization for better efficiency and robustness. Synthetic and real examples of increasing complexity, that is, curved beams, lattices, and foams, are presented to account for the performance of the developed workflow from digital images to an isogeometric twin for mechanical modeling and simulation. K E Y W O R D Scellular materials, digital twin, image-based models, isogeometric analysis, lattices INTRODUCTIONCellular materials are currently gathering an important momentum in both the scientific and industrial communities. 1 They rely upon a simple idea: mimicking nature, such as bones and wood, which allows to achieve, in particular, unprecedented stiffness-to-weight ratios. 2 In practice, cellular materials are characterized by a complex micro-architecture. Most of times, the material is concentrated in small struts connected in different ways, at an intermediate scale between the constituents and the structure. Originally consisting of foams, 3,4 that is, exhibiting a random distribution of cells, the advent of additive manufacturing (AM) now pushes these materials to a new stage: it becomes possible to produce so-called lattices where well-designed unit-cells are periodically (or quasi-periodically 5 ) repeated all over a macro shape to obtain exceptional specific performances. Among others, lattices can be made highly stretchable, 6 auxetic, 7 and multi-functional, and therefore, besides being attractive for lightweight components, they appear of crucial interest for energy absorption, thermal management, design of medical implants, to name a few. [8][9][10][11] However, due to the coexistence of two very different scales, the prediction of the mechanical behavior of such materials remains an issue, especially in non-linear regimes. [12][13][14][15] Their global response is actually intimately related to the local architecture, which may not be perfectly known a priori, either because of the random aspect in foams, or because of the strut-level process-induced defects and uncertainties in lattices. [16][17][18] In view of characterizing the mechanical behavior of such materials, it thus appears of paramount importance to build a digital mechanical twin for each individual tested

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“…The idea behind is to parameterize the reconstructed organ surface with a reduced number of points representing the vertices of a temporal quadrilateral mesh in order to use the generated (3D+time) smooth mesh sequence for finite element simulations. This configuration is then required for establishing a robust biomechanical model of organ dynamics [12]. This clinical context is the primary motivation of this work, the results of which go beyond this framework and can be generalized to any 3D shapes.…”

Section: Introductionmentioning

confidence: 99%

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

Makki¹,

Bohi²,

Ogier³

et al. 2021

2020 25th International Conference on Pattern Recognition (ICPR)

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In this paper, we propose a method for characterizing 3D shapes from point clouds and we show a direct application on a study of organ temporal deformations. As an example, we characterize the behavior of a bladder during a forced respiratory motion with a reduced number of 3D surface points: first, a set of equidistant points representing the vertices of quadrilateral mesh for the surface in the first time frame are tracked throughout a long dynamic MRI sequence using a Large Deformation Diffeomorphic Metric Mapping (LDDMM) framework. Second, a novel geometric feature which is invariant to scaling and rotation is proposed for characterizing the temporal organ deformations by employing an Eulerian Partial Differential Equations (PDEs) methodology. We demonstrate the robustness of our feature on both synthetic 3D shapes and realistic dynamic MRI data portraying the bladder deformation during forced respiratory motions. Promising results are obtained, showing that the proposed feature may be useful for several computer vision applications such as medical imaging, aerodynamics and robotics.

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Virtual image correlation of magnetic resonance images for 3D geometric modelling of pelvic organs

Cited by 7 publications

References 38 publications

Three‐dimensional physics‐based registration of pelvic system using 2D dynamic magnetic resonance imaging slices

Three‐dimensional physics‐based registration of pelvic system using 2D dynamic magnetic resonance imaging slices

Image‐based isogeometric twins of lattices with virtual image correlation for varying cross‐section beams

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

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