Improving the Realism of White Matter Numerical Phantoms: A Step toward a Better Understanding of the Influence of Structural Disorders in Diffusion MRI

Ginsburger, Kévin; Poupon, Fabrice; Beaujoin, Justine; Estournet, Delphine; Matuschke, Felix; Mangin, Jean‐François; Axer, Markus; Poupon, Cyril

doi:10.3389/fphy.2018.00012

Cited by 29 publications

(28 citation statements)

References 33 publications

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“…This decrease of the ICVF is an effect of the presence of dispersion and deformation of the fibre bundles. However, even in the lowest resolution, the intra-axonal volume fraction achieved was over 48%, which is considerably higher than the icvf (of 20%) of a previously presented framework for generating realistic numerical phantoms for crossing fascicles [20]. By optimizing the penalization term of the strands' curvature in our framework, we expect to be able to achieve even higher packing densities-closer to the expected ones from the brain's white matter tissue.…”

Section: Discussionmentioning

confidence: 71%

“…In addition, the intracellular compartment is usually idealised as a collection of parallel hollow cylinders with constant radii or radii sampled from a distribution estimated from histological data [38,17,2,21,2]. Recent studies have suggested that such simplification cannot capture the complexity of the axonal structures of white matter, and thus its diffusion characteristics [31,20].…”

Section: Introductionmentioning

confidence: 99%

“…Because of the aforementioned problems, a number of works proposed experiments where non-trivial structures were used as intracellular substrates, e.g. dispersed axons [20], the presence of abutting cylinders [49] and arbitrarily generated meshes [33]. However, to this day, such approaches have not been thoroughly adopted by the DW-MRI community because of the high computational burden they demand and the lack of available tools.…”

Section: Introductionmentioning

confidence: 99%

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Robust Monte-Carlo Simulations in Diffusion-MRI: Effect of the Substrate Complexity and Parameter Choice on the Reproducibility of Results

Rafael-Patiño

Romascano

Ramírez-Manzanares

et al. 2020

Front. Neuroinform.

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Monte-Carlo Diffusion Simulations (MCDS) have been used extensively as a ground truth tool for the validation of microstructure models for Diffusion-Weighted MRI. However, methodological pitfalls in the design of the biomimicking geometrical configurations and the simulation parameters can lead to approximation biases. Such pitfalls affect the reliability of the estimated signal, as well as its validity and reproducibility as ground truth data. In this work, we first present a set of experiments in order to study three critical pitfalls encountered in the design of MCDS in the literature, namely, the number of simulated particles and time steps, simplifications in the intra-axonal substrate representation, and the impact of the substrate's size on the signal stemming from the extra-axonal space. The results obtained show important changes in the simulated signals and the recovered microstructure features when changes in those parameters are introduced. Thereupon, driven by our findings from the first studies, we outline a general framework able to generate complex substrates. We show the framework's capability to overcome the aforementioned simplifications by generating a complex crossing substrate, which preserves the volume in the crossing area and achieves a high packing density. The results presented in this work, along with the simulator developed, pave the way towards more realistic and reproducible Monte-Carlo simulations for Diffusion-Weighted MRI.

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Section: Discussionmentioning

confidence: 71%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Robust Monte-Carlo Simulations in Diffusion-MRI: Effect of the Substrate Complexity and Parameter Choice on the Reproducibility of Results

Rafael-Patiño

Romascano

Ramírez-Manzanares

et al. 2020

Front. Neuroinform.

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“…Dispersion can occur not only in regions of fiber crossing, fiber kissing, but also in regions traditionally expected to be unidirectional such as the corpus callosum [33]. However, 3D models are hard to construct, not only because of the lack of 3D EM data (that could represent a ground truth), but also because of the complexity of 3D axon packing [34]. Also, it could be the case that the 2D axon shapes, used in our realistic WM modeling, are elongated due to being obtained from cutting through axons that were not perpendicular to the surface.…”

Section: Model Parameters Dictionarymentioning

confidence: 99%

Decoding the microstructural properties of white matter using realistic models

Hédouin

Metere

Chan

et al. 2020

Preprint

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The multi-echo gradient echo (ME-GRE) magnetic resonance signal evolution in white matter has a strong dependence on the orientation of myelinated axons in respect to the main static field. Although analytical solutions, based on the Hollow Cylinder Model have been able to predict some of the behaviour the hollow cylinder model, it has been shown that realistic models of white matter offer a better description of the signal behaviout observed.In this work, we present a pipeline to (i) generate realistic 2D white matter models with its microstructure based on real axon but with arbitrary fiber volume fraction (FVF) and g-ratio. We (ii) simulate their interaction with the static magnetic field to be able to simulate their MR signal. For the first time, we (iii) demonstrate that realistic 2D models can be used to simulate an MR signal that provides a good approximation of the signal obtained from a real 3D white matter model obtained using electron microscopy. We then (iv) demonstrate in silico that 2D WM models can be used to predict microstructural parameters in a robust way if multi-echo multi-orientation data is available and the main fiber orientation in each pixel is known using DTI. A Deep Learning Network was trained and characterized in its ability to recover the desired microstructural parameters such as FVF, g-ratio, free and bound water transverse relaxation and magnetic susceptibility. Finally, the network was trained to recover these micro-structural parameters from an ex-vivo dataset acquired in 9-orientations in respect to the magnetic field and 12 echo times. We demonstrate that this is an overdetermined problem and that as few as 3 orientations can already provide comparable results for some of the decoded metrics.[Highlights] -A pipeline to generate realistic white matter models of arbitrary fiber volume fraction and g-ratio is presented; -We present a methodology to simulated the gradient echo signal from segmented 2D and 3D models of white matter, which takes into account the interaction of the static magnetic field with the anisotropic susceptibility of the myelin phospholipids; -Deep Learning Networks can be used to decode microstructural white matter parameters from the signal of multi-echo multi-orientation data;

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“…The most common approach to this is the packing of fibres into densely packed configurations (Close et al, 2009;Ginsburger et al, 2019Ginsburger et al, , 2018Rafael-Patino et al, 2018).…”

Section: Introductionmentioning

confidence: 99%

Contextual Fibre Growth to Generate Realistic Axonal Packing for Diffusion MRI Simulation

Callaghan

Alexander

Zhang

et al. 2019

Lecture Notes in Computer Science

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This paper presents Contextual Fibre Growth (ConFiG), an approach to generate white matter numerical phantoms by mimicking natural fibre genesis. ConFiG grows fibres one-byone, following simple rules motivated by real axonal guidance mechanisms. These simple rules enable ConFiG to generate phantoms with tuneable microstructural features by growing fibres while attempting to meet morphological targets such as user-specified density and orientation distribution. We compare ConFiG to the state-of-the-art approach based on packing fibres together by generating phantoms in a range of fibre configurations including crossing fibre bundles and orientation dispersion. Results demonstrate that ConFiG produces phantoms with up to 20% higher densities than the state-of-the-art, particularly in complex configurations with crossing fibres. We additionally show that the microstructural morphology of ConFiG phantoms is comparable to real tissue, producing diameter and orientation distributions close to electron microscopy estimates from real tissue as well as capturing complex fibre cross sections. Signals simulated from ConFiG phantoms match real diffusion MRI data well, showing that ConFiG phantoms can be used to generate realistic diffusion MRI data. This demonstrates the feasibility of ConFiG to generate realistic synthetic diffusion MRI data for developing and validating microstructure modelling approaches.

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Improving the Realism of White Matter Numerical Phantoms: A Step toward a Better Understanding of the Influence of Structural Disorders in Diffusion MRI

Cited by 29 publications

References 33 publications

Robust Monte-Carlo Simulations in Diffusion-MRI: Effect of the Substrate Complexity and Parameter Choice on the Reproducibility of Results

Robust Monte-Carlo Simulations in Diffusion-MRI: Effect of the Substrate Complexity and Parameter Choice on the Reproducibility of Results

Decoding the microstructural properties of white matter using realistic models

Contextual Fibre Growth to Generate Realistic Axonal Packing for Diffusion MRI Simulation

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