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This project aims to create and simulate a realistic phantom for susceptibility separation algorithm validation.

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Open In Colab launch binder

Susceptibility-separation-phantom

🚀 New Update Available! 🚀

đź”´ The latest version introduces an all-new, user-friendly GUI for an enhanced experience!

Get started with our updated GUI for streamlined phantom creation and data simulation, making your workflow faster and more accessible!


Theory:

This repository can create an in-silico brain phantom containing positive and negative magnetic susceptibility ($\chi^+$ and $\chi^-$) values, where $\chi^+$ and $\chi^-$ represent the iron and myelin susceptibility contribution to the total susceptibility. The code to simulate $\chi^+$ and $\chi^-$ maps is based on an extension to the QSM validation phantom $^1$ developed for the second QSM reconstruction challenge $^1$. Our phantom offers the option of considering the anisotropic nature of WM susceptibility, i.e., its orientation-dependent behavior relative to the main magnetic field.

Phantom creation:

Simulated $\chi^+$ and $\chi^-$ maps were generated by assigning susceptibility values from the literature $^{2–4}$ to respective tissue segments (Table 1). Subsequently, $\chi^+$ and $\chi^-$ were adjusted to ensure that their sum aligns with the $\chi^{tot}$ values specified in the QSM challenge 2.0, which represents the total magnetic susceptibility.

Region $\chi^{total}$ (ppm) $\chi^{positive}$ (ppm) $\chi^{negative}$ (ppm)
Caudate nucleus 0.044 0.0527 -0.0087
Globus pallidus 0.131 0.1437 -0.0132
Putamen 0.038 0.0471 -0.0091
Red nucleus 0.1 0.01109 -0.0109
Dentate nucleus 0.152 0.1684 -0.0164
Substantia nigra 0.111 0.1224 -0.0114
Thalamus 0.02 0.0509 -0.0309
White matter -0.03 0.0059 -0.0359
Grey matter 0.02 0.0392 -0.0192
CSF 0.019 0.0275 -0.0085

Table 1: Simulated average $\chi^{tot}$, $\chi^{+}$, and $\chi^{-}$ values (“ground truth” ) for different regions of the brain.

Pre-scanned $R_{1}$ and $R^{*}_ {2}$ maps (from the original QSM phantom) were used to create an anatomically valid intensity modulation for susceptibility values using the same approach as that of Marques et al. $^1$:

$$ \bar{\chi}^{\pm}_ {\text{tissue}}(r) = \bar{\chi}^{\pm}_ {\text{tissue}}(r) + a_{\text{tissue}}(R^{*}_ {2}(r) - \bar{R}^{*}_ {2}) + b_{\text{tissue}}(R_{1}(r) - \bar{R}_{1}) $$

where $\bar{\chi}^{\pm}_ {\text{tissue}}$ are the values from Table 1, $R_{1}$ and $R^{*}_ {2}$ are the longitudinal and observed transverse relaxation maps with $\bar{R}_ {1}$ and $\bar{R}^{*}_ {2}$ being their mean value for a given brain region and $a_{\text{tissue}}$ and $b_{\text{tissue}}$ are weighting factors. Our custom phantom offers the possibility of including WM’s susceptibility anisotropy by modeling $\chi^-$ as:

$$ (\chi_{||} - \chi_{\perp}) \cos^2 \theta + \chi_{0} $$

Where $\chi_{||}$ and $\chi_{\perp}$ are the susceptibility of myelinated fibers along and perpendicular to their principal axis, $\theta$ is the fiber-to-field angle, and $\chi_{0}$ represents any orientation-independent susceptibility. $\chi_{||}$, $\chi_{\perp}$, and $\chi_{0}$ maps were generated from literature values $^{5–7}$ (Table 2) that were subsequently weighted using the $R_{1}$ map and subjected to Gaussian noise in order to add texture to the tissue regions.

Region $\delta\chi(\chi_{||} - \chi_{\perp}) (ppm)$ $\chi_{0} (ppm)$
Body of the corpus callosum 0.032 -0.0512
Splenium of the corpus callosum 0.024 -0.0522
Genu of the corpus callosum 0.014 -0.0382
Anterior limb of the internal capsule 0.016 -0.0512
Posterior thalamic radiations 0.016 -0.0592
Superior corona radiata 0.005 -0.0442
Posterior corona radiata 0.008 -0.0542
Anterior corona radiata 0.006 -0.0462
Posterior limb of the internal capsule -0.015 -0.0382
Superior longitudinal fascicle -0.015 -0.0372

Table 2: Simulated average anisotropy values, $\delta\chi(\chi_{||} - \chi_{\perp})$, and isotropic susceptibility, $\chi_{0}$, derived from the literature for different white matter regions.

Finally, our phantom allows us to simulate a transversal relaxation time $R_2$ map $(\frac{1}{T_2})$. This map was also simulated based on literature values $^{8,9}$ (Table 3) and then weighed using $R^{*}_ {2}$ and $M_0$ to create realistic tissue textures.

Region $T_2$ (ms)
Caudate nucleus 57.46
Globus pallidus 41.47
Putamen 50.44
Red nucleus 44.07
Dentate nucleus 71.71
Substantia nigra 47.26
Thalamus 56.62
White matter 45.54
Grey matter 84.71
CSF 1029

Table 3: Simulated average $T_2$ values derived from the literature for different regions of the brain.

Gradient echo simulation:

The created phantom can be used to simulate gradient-echo (GRE) data (3T or 7T) using the following equation:

$$S=M_0\sin(\alpha)\frac{1-e^{-TR.R_1}}{1-\cos(\alpha)e^{-TR.R_1}}e^{-TE.(R_2+D_r(|\chi^+|+|\chi^-|))+i(\Phi_0+2\pi{\gamma}TE.B_0(D(\chi^++\chi^-)))}$$

where D is the magnetic dipole kernel, $\alpha$ is the flip angle, TR is the repetition time, TE is the echo time, $\Phi_0$ is a phase offset, $M_0$ is the net magnetization, $B_0$ is the field strength, ${\gamma}$ is the gyromagnetic ratio, and $D_r$ maps represents the proportionality between $R^{'}_ {2}$ $(=R^{*}_ {2}-R_ 2)$ and absolute susceptibility. $D_r$ was modeled as $\tfrac{2\pi}{9\sqrt{3}}{\gamma}B_0$ in gray matter and as $\tfrac{1}{2}\gamma B_0sin^2(\theta)$ in white matter.

The phantom and accompanying code can be used to simulate MR signals and evaluate various magnetic susceptibility-separation techniques, such as χ-separation $^{10}$, APART-QSM $^{11}$, or DECOMPOSE QSM $^{12}$.

Requirements:

Pre-Usage:

After downloading the QSM challenge 2.0 repository and this repository, replace the following files from the QSM Challenge 2.0 repository with the corresponding files from this repository:

     QSM Challenge 2.0 version                                      Our version               
 -------------------------------                                ---------------------      
 MacroCreateSusceptibilityPhantom.m           ------->            PhantomCreation.m          
 CreateOwnRealisticPhantom.m                  ------->            PhantomCreationFunction.m 
 MacroCreateSimulationData.m                  ------->            DataSimulation.m           
 CreateSimulatedData.m                        ------->            DataSimulationFunction.m   
 DataSimulation.m                             ------->            GRESimulation.m            
 parameters.mat                               ------->            SusceptibilityValues.mat   

In addition, make sure to add these files to the main QSM challenge file directory: Mask.m, Anisotropy.m, T2_star.nii.gz, white_matter_mask.nii.gz.

Usage:

Once you have all of the required files, follow these steps to create positive and negative susceptibility maps and simulate gradient-echo data:

  1. To create susceptibility phantoms: run PhantomCreation.m
  • This script will create susceptibility phantoms: $\chi^{tot}$ from QSM challenge 2.0 and additionally $\chi^{+}$ and $\chi^{-}$ phantoms with and without anisotropy. In addition, it will simulate an $R_2$ map $(\frac{1}{T_2})$. This script will also generate spatially variable and constant $D_r$ maps (to include or exclude anisotropy)
  1. To simulate GRE magnitude and phase data: run DataSimulation.m When simulating consider checking the input of the Anisotropy.m function
  • if you want to simulate data with anisotropy select Asotropy as “true”.
  • if you want to simulate without anisotropy select Anisotropy as “ false”.

Recommendations:

  1. We recommend using this phantom for validating susceptibility separation algorithms.

For this you will need the following script:

  • CalculateR2prime.m: Calculate $R^{'}_ {2}$ map from $R_2$ and $R^{*}_ {2}$. At this point, an $R_2$ map is already simulated. To obtain an $R^{*}_ {2}$ map, we recommend applying a mono-exponential fitting to the simulated magnitude data using qMRLab software.
  1. To visualize a color-coded white matter fiber orientation map run the script: GenerateRgbMap.m

Results:

All the resulting maps are available in the repository as essential reference points for anyone seeking to reproduce the work.

Screenshot 2023-12-17 145333

GUI

Picture1

Features

  1. Phantom Creation and Map Generation:

    • Easily create susceptibility phantoms and generate maps using an intuitive interface.
    • Select between 3T and 7T for $( B_0 )$ field strength.
    • Option to include or exclude susceptibility anisotropy with a simple checkbox.
  2. Data Simulation:

    • Customize TR (Repetition Time), Flip Angle, Number of Echoes, and TE (Echo Time).
    • Visualize simulated data across different echoes with a dropdown menu.
  3. Visualization:

    • Change the color scheme of all maps through an accessible dropdown list.
    • Adjust the intensity range for better contrast.
    • Display all slices in the maps for detailed examination.

The GUI facilitates faster workflows. Ideal for users interested in experimenting with different settings and visualizing results directly.

Question:

If you have any questions or encounter issues, please don't hesitate to open an issue, and we will respond as soon as possible to assist you.

References:

  1. Marques, J. P. et al. QSM reconstruction challenge 2.0: A realistic in silico head phantom for MRI data simulation and evaluation of susceptibility mapping procedures. Magn. Reson. Med. 86, 526–542 (2021).
  2. Deistung, A. et al. Toward in vivo histology: a comparison of quantitative susceptibility mapping (QSM) with magnitude-, phase-, and R2*-imaging at ultra-high magnetic field strength. Neuroimage 65, 299–314 (2013).
  3. Buch, S. et al. Susceptibility mapping of air, bone, and calcium in the head. Magn. Reson. Med. 73, 2185–2194 (2015).
  4. Hallgren, B. & Sourander, P. The effect of age on the non-haemin iron in the human brain. J. Neurochem. 3, 41–51 (1958).
  5. Li, X. et al. Mapping magnetic susceptibility anisotropies of white matter in vivo in the human brain at 7 T. Neuroimage 62, 314–330 (2012).
  6. Sibgatulin, R., GĂĽllmar, D., Deistung, A., Ropele, S. & Reichenbach, J. R. In vivo assessment of anisotropy of apparent magnetic susceptibility in white matter from a single orientation acquisition. Neuroimage 241, 118442 (2021).
  7. Sibgatulin, R. et al. Magnetic susceptibility anisotropy in normal-appearing white matter in multiple sclerosis from single-orientation acquisition. Neuroimage Clin 35, 103059 (2022).
  8. Kumar, R., Delshad, S., Macey, P. M., Woo, M. A. & Harper, R. M. Development of T2-relaxation values in regional brain sites during adolescence. Magn. Reson. Imaging 29, 185–193 (2011).
  9. Kumar, R., Delshad, S., Woo, M. A., Macey, P. M. & Harper, R. M. Age-related regional brain T2-relaxation changes in healthy adults. J. Magn. Reson. Imaging 35, 300–308 (2012).
  10. Shin, H.-G. et al. χ-separation: Magnetic susceptibility source separation toward iron and myelin mapping in the brain. Neuroimage 240, 118371 (2021).
  11. Li, Z. et al. APART-QSM: An improved sub-voxel quantitative susceptibility mapping for susceptibility source separation using an iterative data fitting method. Neuroimage 274, 120148 (2023).
  12. Chen, J., Gong, N.-J., Chaim, K. T., Otaduy, M. C. G. & Liu, C. Decompose quantitative susceptibility mapping (QSM) to sub-voxel diamagnetic and paramagnetic components based on gradient-echo MRI data. Neuroimage 242, 118477 (2021).

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This project aims to create and simulate a realistic phantom for susceptibility separation algorithm validation.

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