Differences between revisions 18 and 202 (spanning 184 versions)

WARNING: This tutorial uses an old version of SimNIBS, which includes the segmentation pipeline headreco. Please see instead the new version of this tutorial, based on SimNIBS 4 and the CHARM pipeline. However, we recommned to use the current version with SimNibs3 headreco. We are working with SimNibs team to keep the Headreco availble for the users [headreco is available on all releases prior to v4.0].

FEM tutorial with MEG/EEG median nerve stimulation (headreco)

Authors: Takfarinas Medani, Juan Garcia-Prieto, Wayne Mead, Michael Funke, Francois Tadel

This tutorial introduces the most advanced FEM modeling options available in the Brainstorm environment, applied to MEG+EEG recordings of a median nerve stimulation. The pipeline presented here includes: FEM mesh reconstruction with SimNIBS3/CAT12, FEM head model including DTI tensors for modeling anisotropic conductivities (using BrainSuite), FEM forward model estimation with DUNEuro. This pipeline requires many third-party programs and very long computation times. For a simpler FEM pipeline, please refer to the tutorial: Realistic head model: FEM with DUNEuro.

Note that the operations used here are not detailed, the goal of this tutorial is not to introduce Brainstorm to new users. For in-depth explanations of the interface and theoretical foundations, please refer to the introduction tutorials.

Contents

Dataset description
Download and installation
Import the anatomy
FEM head model
Access the recordings
Forward model
Source estimation
Additional documentation
Scripting

Dataset description

Experiment

The experiment consists of an unilateral median nerve stimulation conducted in a MEG laboratory with an Elekta Triux (Megin, Finland) scanner.

The stimulation signal was a square-wave pulse with 2Hz frequency and duration of 0.2ms.
An ISI (inter-stimulus interval) of 500ms with a variation of ±20ms in order to be able to average out time-locked noise to the stimulation, while remaining unnoticeable by the subject.
The stimulation was performed on the left hand/wrist, for two minutes, with a Digitimer DS7A stimulator. An electrode was placed on the hand/wrist while current value was tuned to match the motor threshold of the subject on the stimulated hand, with a result of 10~12mA approximately.
Recordings were performed with a 1kHz sampling rate. Continuous HPI was disabled during these recordings. High-pass filters were set to DC for MEG channels and 0.03Hz for EEG channels.
All MEG files underwent a MaxFilter (version 2.3.13) tsss post-processing.

MRI imaging scanning (Philips Medical Systems):

T1w image without contrast: 3T field strength, flip angle 8°, TR 7.9s, dimensions 512 × 512 × 200, and voxel dimensions of 0.469 × 0.469 × 0.939 millimeters
T2w spin-echo image: 3T field strength, 78.57% phase FOV, 90° flip angle, SAR 0.327, voxel dimensions 560 × 560 × 55, dimensions of 0.429 × 0.429 × 3 millimeters
DWI sequences: voxel dimensions 512 x 512 x 200 and dimensions of 0.469 × 0.469 × 0.939 millimeters, diffusion-sensitizing gradients in 32 non-collinear directions

Files

The dataset we distribute with this tutorial follows the Brain Imaging Data Structure (BIDS) standard for neuroimaging data organization. The files that will be imported in this tutorial are the following:

sample_fem/sub-fem01/: Raw data for subject fem01

ses-meg/: Simultaneous recordings of MEG and EEG.
- sub-fem01_ses-meg_task-mediannerve_run-01_proc-tsss_meg.fif
ses-mri/: Imaging exams.
- anat/sub-fem01_ses-mri_T1w.nii.gz: T1-weighted MRI
- anat/sub-fem01_ses-mri_T2w.nii.gz: T2-weighted MRI
- dwi/sub-fem01_ses-mri_dwi.*: Diffusion-Weighted Imaging (DWI)

License

Creative Commons CC0 1.0 Universal. This dataset is distributed in the public domain.

Download and installation

Requirements

You have already followed all the introduction tutorials.
You have a working copy of Brainstorm installed on your computer.

Additional programs

You need to install the following programs (listed by order of appearance):

SimNIBS 3.x: See tutorial: FEM mesh generation
BrainSuite: See tutorial: FEM tensors estimation
MATLAB Runtime: Follow the instructions on the BrainSuite download page
SPM12: Install as Brainstorm plugins
CAT12: Install as Brainstorm plugins
Iso2mesh: Install as Brainstorm plugins
DUNEuro: See tutorial: Realistic head model: FEM with DUNEuro

Download the dataset

Go to the Download page and get the file: sample_fem.zip
Unzip it outside of any of the Brainstorm folders (program folder or database folder).
Start Brainstorm (Matlab scripts or stand-alone version)
Select the menu File > Create new protocol. Name it "TutorialFem" and select:
- No, use individual anatomy
- No, use one channel file per condition

Import the anatomy

T1 MRI

Switch to the "anatomical data" view, the left button in the toolbar above the database explorer.
Right-click on the TutorialFem folder > New subject > Subject01
- Keep the default options you set for the protocol.
Right-click on the subject node > Import MRI:
- Set the file format: All MRI files (subject space)
- Select the T1 file: sub-fem01/ses-mri/anat/sub-fem01_ses-mri_T1w.nii.gz
Click on the link "Click here to compute MNI normalization": option "maff8".
This estimates an affine transformation to the MNI space and sets default positions for the anatomical fiducials. Because we will use the digitized head shape of the subject to refine the MRI/MEG registration, we don't need the position of the fiducials to be very accurate.

T2 MRI

Right-click on the subject node > Import MRI:
- Set the file format: All MRI files (subject space)
- Select the T2 file: sub-fem01/ses-mri/anat/sub-fem01_ses-mri_T2w.nii.gz
Brainstorm asks about registering the new T2 with the reference T1 image:
- Select the option: SPM
- Reslice the volume: Yes
This process will take few minutes, just be patient.

Diffusion imaging

The FEM has the ability to incorporate anisotropic conductivity from MRI diffusion imaging, which is particularly interesting for the modeling of the white matter. Brainstorm can load the Diffusion-Weighted Images (DWI), and compute the tensors (DTI) using the BrainSuite Diffusion Pipeline (BDP). This requires BrainSuite to be installed on your computer, with the bdp program available in the system path.

Right-click on Subject01 > Convert DWI to DTI
Select the DWI file: sub-fem01/ses-mri/dwi/sub-fem01_ses-mri_dwi.nii.gz
The associated files *dwi.bvec and *dwi.bval must be in the same folder.
The process can take up to 30min. At the end, a new file DTI-EIG appears in the database. This file contains 12 volumes, ie. 12 values for each voxel. From 1 to 9: components of the three eigenvectors; from 10 to 12: the values of their norm to the eigenvalue.

FEM head model

The FEM approach requires a segmentation of the head volume in different tissues, represented as hexahedral or tetrahedral 3D meshes. The methods available within Brainstorm are listed in the tutorial FEM mesh generation. Here we illustrate only the use of SimNIBS.

FEM mesh with SimNIBS

Running SimNIBS:

Select both the T1 and the T2 MRIs, using the mouse and the SHIFT or CTRL keys.
Right-click on the selected files > MRI segmentation > Generate FEM mesh > SimNIBS. Keep the default options.
This process can take 2-5 hours.
The output of SimNIBS is saved in the temporary folder $HOME/.brainstorm/tmp/simnibs, and then imported into the Brainstorm database.

At the end of this computation, new files are available in the database:

tissues: Segmentation of the head volume in 6 different tissues
head mask: Outer surface of the scalp
cortex_280000V: Pial surface generated by CAT12 within the SimNIBS process
cortex_15002V: Low-resolution version of the pial surface
cortex_fem: Outer surface mesh of the gray matter, extracted from the FEM mesh
FEM 70000V: Tetrahedral FEM mesh with 5 layers (gm, wm, CSF, skull, scalp).

At the end of the process, make sure that the file "cortex_15002V" is selected (downsampled pial surface, which will be used for the source estimation). If it is not, double-click on it to select it as the default cortex surface.

Remesh with Iso2mesh

This step is optional, to be considered only when the DUNEuro FEM computation fails. In some cases, the FEM mesh generated with SimNIBS causes issues with the DUNEuro FEM solver, due to the air cavities that are not tesselated. In order to avoid these possible issues in the next steps, we will correct the mesh using the Iso2mesh functions integrated within Brainstorm.

Right-click on the FEM mesh > Extract surfaces.
Hold the CTRL key to select all the extracted surfaces (white, gray, csf, skull, scalp).
Right-click > Generate FEM mesh > Iso2mesh-2021 > MergeMesh > Max volume = 0.001, Percentage kept = 100. Note that the higher the resolution leads to higher accuracy but also higher memory requirements and longer computation times.

The following figure shows the two model, left is the initial model obtained with SimNibs, right is the second model obtained from the Iso2Mesh remesh: the air cavity in the bottom-right corner is now fully tesselated. Note that you can also use this process to generate FEM models with higher mesh densities.

FEM tensors

We can now incorporate the diffusion information into the FEM model, and compute anisotropic conductivity tensors for the tetrahedral elements of the white matter (we consider the other tissues to have isotropic conductivities).

Right-click on the FEM mesh > Compute FEM tensors. Select the options as illustrated below, and refer to the tutorial FEM tensors for more information.
This process can take up to 5min, depending on the resolution of the FEM mesh.

Visualization

Brainstorms include the possibilities to display the FEM head models and the tensors, users can also overlay the display with the MRI as well as with the different surfaces.

Right-click on the FEM mesh > Display FEM tensors: The FEM tensors can be displayed on the mesh or MRI, as arrows on the main eigenvector or as ellipsoids on each FEM element.

To configure the display: right-click on the figure > FEM tensors menu. The keyboard shortcuts for changing the size of the displayed tensors are the Up and Down arrows keys. You can also switch the display mode by using the shortcut "Shift + Space".

Advanced

On the hard drive

The DTI-EIG file as the same structure as any MRI file, with 12 volumes stacked along the 4th dimension. From 1 to 9: components of the three eigenvectors; from 10 to 12: the values of their norm to the eigenvalue.

The FEM mesh contains the following fields:

BEM head model

For the purpose of comparison between the FEM and the BEM, we will generate also the BEM surfaces for this subject and we will follow the same step as explained in the BEM tutorial.

Right-click on Subject01 > MRI segmentation > Generate BEM surfaces > Brainstorm.
Keep the default options: 1922 vertices for all the layers, skull thickness = 4m.
Three new files appear in the database explorer: bem_head_1922V, bem_outerskull_1922V, and bem_innerskull_1922V. These surfaces will be used for the BEM forward computation.
Now we have two head geometry available for this subject, BEM and FEM

Access the recordings

Link the recordings

Switch to the "functional data" view, the middle button in the toolbar above the database explorer.
The folder "eeg_positions" which contains default 10-10 EEG electrodes positions, was generated by the SimNIBS process. We will not use it in this tutorial: delete this folder.
Right-click on the subject folder > Review raw file:
- Select file type: MEG/EEG: Electa-Neuromag(*.fif)
- Select file: sub-fem01/ses-meg/meg/sub-fem01_ses-meg_task-mediannerve_run-01_proc-tsss_meg.fif
- FIF event file: Select Event Channel, this will read the events markers
- Refine registration? YES
A figure is opened to show the registration MRI/MEG.
The new file "Link to raw file" lets you access directly the contents of the MEG/EEG recordings. The "Neuromag channels (374)" contains the name of the channels and the position of the corresponding sensors (MEG/EEG).

Channel file

The recordings contain signals coming from different types of electrodes:
- 306 MEG channels (102 magnetometers and 204 gradiometers )
- 64 EEG channels
- 2 EOG channels: EO1 and EO2
- 1 Stim channel that contain the stimulation signals
Right-click on the channel file > MRI registration > Edit... (EEG)
The white points are the electrodes, the green points are the additional digitized head points. To display the label of the electrodes, click on the [LABEL] button in the toolbar. To see what the other buttons in the toolbar are doing and how to use them, leave your mouse over them for a few seconds and read the description.
The automatic registration based on the head points is already good, therefore we won't apply any additional rotation+translation to the MEG+EEG sensors.
Click on the button "Project electrodes on scalp surface", it will help for the source modeling later. The green points (digitized) stay in place, the white points (electrodes) are now projected on the skin of the subject.
If you feel like you didn't do this correctly, close the figure and cancel the modifications, then try again.
Click on [OK] when done. Answer YES to save the modifications.

Pre-processing

Drag and drop the "Link to raw file" into the Process1 list.
Select the process "Frequency > Power spectrum density", configure it as in the figure
After the computation, double-click on the new PSD file to display it.
The lines on the top represent the EEG electrodes, the lines at the bottom the MEG sensors(MAG and GRAD). If you want to get clearer plots, you can calculate separately the spectrum for the two types of sensors separately, by running twice the process "Power spectrum density", once with sensor types = "MEG" and once with "EEG", instead of running in on both at the same time as we did.
Observations (below 250Hz):
- Peak around 10Hz: Alpha waves from the subject's brain
- Peaks at 60Hz, 120Hz, 180Hz, 240Hz on EEG + MEG: Power lines (60Hz+harmonics)
- Most of the signal looks clean and no bad channel is observed
If we review quickly the EEG and EOG signals, we notice that they are quite clean and no artifacts are observed. The experiment is well designed and the subject was not moving the eyes (blinks and slow movements), maybe because there was a fixation cross for this experiment. However, we will apply at least a high-pass filter to make the signals easier to process (we are not interested in very low frequencies in this experiment).

Frequency filters

In Process1, select the "Link to raw file".
Select process Pre-process > Band-pass filter: Frequency=[20, 250]Hz, Sensors=MEG,EEG
Add process Pre-process > Notch filter: Frequencies=[60 120 180]Hz, Sensors=MEG,EEG
In Process1, select the filtered file "Raw | Band | Notch".
Run the process "Frequency > Power spectrum density", with the same options as before. And compare with the previous figure. You may find that the power line frequency and its harmonics are removed and the data is filtered between 20 and 250Hz.
To keep the interface clean and easy to follow: keep only the last continuous file (Raw|Band|Notch). Delete the link to the original file (which will not delete the original .fif file), and delete the "Raw|Band" file.

EEG: Average reference

Right-click on the filtered file "Raw|band|notch" > EEG > Display time series.
In the Record tab, menu Artifacts > Re-reference EEG > "AVERAGE".
At the end, the window "Select active projectors" is open to show the new re-referencing projector. Just close this window. To get it back, use the menu Artifacts > Select active projectors.

Epoching

In this experiment, the electric stimulation is sent with a frequency of 2Hz, meaning that the inter-stimulus interval is 500ms. We are going to import epochs of 300ms around the stimulation events (-100 to 200ms).

Right-click on the filtered file "Raw|band|notch" > Import in database:
Check "Use events" and select "2", this is the name that brainstorm assigns for the stimulus onset, it may have different name on your computer. Set epoch time: [-100, 200] ms and Apply SSP/ICA in order to apply the average reference.
At the end, you are asked whether you want to ignore one epoch that is shorter than the others. This happens because the acquisition of the MEG signals was stopped less than 300ms after the last stimulus trigger was sent. Therefore, the last epoch cannot have the full [-100,200]ms time definition. This shorter epoch would prevent us from averaging all the trials easily. As we already have enough repetitions in this experiment (240), we can just ignore it. The total number of epochs is then 239.

Averaging

Drag and drop all the Trigger01 trials to the Process1 tab.
Run the process Average > Average files: By trial group (folder average)
Review the average for the MEG and EEG as a topography plot: Right-click on the averaged signal > EEG > 2D disc, repeat for MEG.
At the selected time (21ms), an ERP is visible with a nice dipolar pattern on the sensors, both for the EEG and MEG.

Forward model

We are going to use the realistic FEM model previously generated from the MRI. Go to the "Anatomy" view, and make sure that the FEM head model is highlighted in green color (it should be the case if you have only one model). You may also highlight the cortex to use for the computation (select the cortex_15002V).

You can compute the forward model both for EEG and MEG simultaneously, however, using the high mesh resolution model we recommend to compute separately the head model for each modality (EEG and then MEG). The time required for EEG is around one hour for ~70 channels, for the MEG with 306 sensors it can take up to 4 hours or more (with the integrations points).

The EEG/MEG FEM computation depends on the computation of the FEM transfer matrix, which is related to the resolution of the FEM head mesh (number of vertices) and the number of sensors. In most of the case, the number of EEG sensors is lower than the number of MEG sensors. Furthermore, internally the MEG sensors modeling uses the integrations points, which increase the number of computation points (~ multiplied by 4 for the magnetometers and by 8 for the gradiometers). Therefore, the MEG requires more time than the EEG.

To reduce the MEG computation time, there are some tips:

Use only the inners tissues (wm, gm, and CSF) ==> reduce the number of vertices
Do not use the integration points ==> reduce the number of virtual sensors
These parameters can be tuned from the DUNEuro options panel (see the advanced panel)

EEG with DTI tensors

Go back to the "Functional data" view
Right-click on the channel file (folder with imported epochs) > Compute head model
Select EEG only > DUNEuro FEM, and set the comment to "DUNEuro FEM EEG DTI tensors"
On the DUNEuro options panel: click on "Show details" and set the options as illustrated below
Click OK. Depending on the performance of your computer, the FEM EEG head modeling can last between 30min to 3hrs. Once the computation is done, a new node with the name "DUNEuro FEM EEG DTI tensors" appears in the Brainstorm database navigator, which can be used for the source localization process.

MEG with DTI tensors

Right-click on the channel file > Compute head model
Select MEG only > DUNEuro FEM, and set the comment to "DUNEuro FEM MEG DTI tensors"
On the DUNEuro options panel: click on "Show details" and set the options as illustrated below. To reduce the computation time, we select only the inner layers (white, gray and CSF).
Click OK. Depending on the performance of your computer, the FEM MEG head modeling can last between 1hr to 4hrs. Once the computation is done, a new node with the name "DUNEuro FEM MEG DTI tensors" appears in the Brainstorm database navigator, which can be used for the source localization process.

EEG with isotropic conductivity

If the DTIs are not available, it is possible to use the isotropic conductivities instead. In this tutorial, we will compute another forward model in order to compare the sources obtained with anisotropic or isotropic conductivities.

First you need to make sure that the tensors are not computed. If you have the tensors already computed, you need to clear these values. Go to the "Anatomy" view, right-click on the FEM mesh > Clear FEM tensors.
Go back to "Functional data", right-click on channel file > Compute head model. In this case, you can change the isotropic conductivity for each tissue. Set the options as in the figure below.

MEG with isotropic conductivity

Same as before, first you need to make sure that the tensors are not computed.
Right-click on the channel file > Compute head model, and set the value as in the figure below. In this example keep only the inner tissues (white, gray and CSF).

Source estimation

Noise covariance matrix

We will use the baseline of the single epochs to calculate the noise covariance matrix.
Right-click on the epochs group > Noise covariance > Compute from recordings. Enter the same baseline interval we used for removing the DC offset: [-100, -10] ms

Inverse model

It is recommended to study separately the two modalities because Brainstorm does not offer any reliable method for combining MEG and EEG source imaging yet. More explanations in the Source estimation tutorial.

Repeat the same step for each of the four forward models (EEG/MEG, DTI/isotropic):
Right-click on the head model > Compute sources > Dipole modeling.
Edit the comment to be able to identify the source maps easily: EEG FEM DTI, EEG FEM ISO, MEG FEM DTI, MEG FEM ISO.
For each forward model, this operation creates a shared inversion kernel and one source link for each block of recordings in the folder.

Dipole scanning

Drag and drop the source links for the average in the Process1 tab.
Run the process: Sources > Dipole Scanning > 40ms-60ms. See the Dipole scanning tutorial.
Select and merge the MEG ISO and the MEG DTI dipoles. Repeat for the EEG dipoles.
Rename the merged dipoles with a clearer comment, as illustrated below.

Comparison: DTI vs isotropic

The following figures (left EEG, right MEG), show the localization of the dipoles on the MRI at the 21ms. The ISO model is colored in green whereas the DTI model is colored in red.

In this experiment, the anisotropy does not show a significant effect on the source localization, whereas it shows a slight difference in the orientation.

Comparison: MEG vs EEG

When we compare between the EEG and the MEG, there is a difference of 20mm between the localization between the MEG and the EEG as well as a difference in the orientation in the coronal view.

If we compare the difference between the EEG and MEG dipoles, the following figures (left anisotropy, right isotropic), show the localization of the dipoles on the MRI at the 21ms. The EEG dipole is colored in green whereas the MEG dipole is colored in red.

Aniso: Eeg [-7.5 -35.7 89.8] vs Meg [-0.2 -33.6 88.6] ==> distance = 7.7mm

Iso: Eeg [-7.5 -35.7 89.8] vs Meg [-0.2 -33.6 88.6] ==> distance = 7.7mm

In both modalities, the dipoles are located exactly in the same positions, and there is 7.7mm between the two dipoles. Furthermore, we notice a difference on the orientation on the coronal and sagittal views

Comparison: FEM vs BEM/OS

We will now compare qualitatively the FEM results with the default methods implemented in Brainstorm: Overlapping spheres for MEG, BEM for EEG.

Right-click on the channel file > Compute head model > MEG: Overlapping spheres
Right-click on the channel file > Compute head model > EEG: OpenMEEG BEM
Repeat the same source localization procedure: Compute sources and Dipole scanning.

In the following figures, left is the dipoles computed from the EEG (BEM in red and FEM in green), right are the dipoles computed from the MEG (OS in red and FEM in green)

EEG: fem [-7.5 -35.7 89.8] ; bem [-10.7 -35.0 89.5] ==> 3.3mm

MEG: fem [-0.2 -33.6 88.6] ; os [-10.7 -39.3 83.2] ==> 13.1 mm

As expected, the slight difference on the localization can be explained by the difference on the head shape, the conductivity values as well as the resolution method.

Advanced

Additional documentation

Articles

Medani T, Garcia-Prieto J, Tadel F, Schrader S, Joshi A, Engwer C, Wolters CH, Mosher JC, Leahy RM, Realistic head modeling of electromagnetic brain activity: An integrated Brainstorm pipeline from MRI data to the FEM solution (preprint), SPIE Medical Imaging, Feb 2021

Scripting

The following script from the Brainstorm distribution reproduces the analysis presented in this tutorial page: brainstorm3/toolbox/script/tutorial_fem_headreco.m

function tutorial_fem_headreco(tutorial_dir)
% TUTORIAL_FEM_HEADRECO: Script that reproduces the online tutorial "FEM tutorial: MEG/EEG Median nerve stimulation (headreco)"
%
% REFERENCE:
%     https://neuroimage.usc.edu/brainstorm/Tutorials/FemMedianNerve
%
% INPUTS: 
%     tutorial_dir: Directory where the sample_fem.zip file has been unzipped

% @=============================================================================
% This function is part of the Brainstorm software:
% https://neuroimage.usc.edu/brainstorm
% 
% Copyright (c) University of Southern California & McGill University
% This software is distributed under the terms of the GNU General Public License
% as published by the Free Software Foundation. Further details on the GPLv3
% license can be found at http://www.gnu.org/copyleft/gpl.html.
% 
% FOR RESEARCH PURPOSES ONLY. THE SOFTWARE IS PROVIDED "AS IS," AND THE
% UNIVERSITY OF SOUTHERN CALIFORNIA AND ITS COLLABORATORS DO NOT MAKE ANY
% WARRANTY, EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO WARRANTIES OF
% MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE, NOR DO THEY ASSUME ANY
% LIABILITY OR RESPONSIBILITY FOR THE USE OF THIS SOFTWARE.
%
% For more information type "brainstorm license" at command prompt.
% =============================================================================@
%
% Author: Francois Tadel, 2021


% ===== FILES TO IMPORT =====
% You have to specify the folder in which the tutorial dataset is unzipped
if (nargin == 0) || isempty(tutorial_dir) || ~file_exist(tutorial_dir)
    error('The first argument must be the full path to the tutorial dataset folder.');
end
% Build the path of the files to import
T1Nii  = fullfile(tutorial_dir, 'sample_fem', 'sub-fem01', 'ses-mri', 'anat', 'sub-fem01_ses-mri_T1w.nii.gz');
T2Nii  = fullfile(tutorial_dir, 'sample_fem', 'sub-fem01', 'ses-mri', 'anat', 'sub-fem01_ses-mri_T2w.nii.gz');
DwiNii = fullfile(tutorial_dir, 'sample_fem', 'sub-fem01', 'ses-mri', 'dwi', 'sub-fem01_ses-mri_dwi.nii.gz');
DwiBval = fullfile(tutorial_dir, 'sample_fem', 'sub-fem01', 'ses-mri', 'dwi', 'sub-fem01_ses-mri_dwi.bval');
DwiBvec = fullfile(tutorial_dir, 'sample_fem', 'sub-fem01', 'ses-mri', 'dwi', 'sub-fem01_ses-mri_dwi.bvec');
FifFile = fullfile(tutorial_dir, 'sample_fem', 'sub-fem01', 'ses-meg', 'meg', 'sub-fem01_ses-meg_task-mediannerve_run-01_proc-tsss_meg.fif');
% Check if the folder contains the required files
if ~file_exist(T1Nii) || ~file_exist(FifFile)
    error(['The folder ' tutorial_dir ' does not contain the folder from the file sample_fem.zip.']);
end
% Subject name
SubjectName = 'Subject01';
% Latency of interest
Latency = 0.022;


% ===== CHECK SOFTWARE DEPENDENCIES =====
% Start brainstorm without the GUI
if ~brainstorm('status')
    brainstorm nogui
end
% SimNIBS 3 / headreaco
status = system('headreco --version');
if (status ~= 0)
    error('SimNIBS is not installed or not added to the system path: the command "headreco" could not be found.');
end
% BrainSuite
if ~file_exist(bst_fullfile(bst_get('BrainSuiteDir'), 'bin'))
    error('BrainSuite is not configured in the Brainstorm preferences.');
end
% SPM12
[isInstalled, errMsg] = bst_plugin('Install', 'spm12', 0);
if ~isInstalled
    error(['Could not install plugin: spm12' 10 errMsg]);
end
% CAT12
[isInstalled, errMsg] = bst_plugin('Install', 'cat12', 0);
if ~isInstalled
    error(['Could not install plugin: cat12' 10 errMsg]);
end
% Iso2mesh
[isInstalled, errMsg] = bst_plugin('Install', 'iso2mesh', 0);
if ~isInstalled
    error(['Could not install plugin: iso2mesh' 10 errMsg]);
end


% ===== CREATE PROTOCOL =====
% The protocol name has to be a valid folder name (no spaces, no weird characters...)
ProtocolName = 'TutorialFem';
% Delete existing protocol
gui_brainstorm('DeleteProtocol', ProtocolName);
% Create new protocol
gui_brainstorm('CreateProtocol', ProtocolName, 0, 1);
% Start a new report
bst_report('Start');


%% ===== IMPORT ANATOMY =====
% ===== IMPORT MRI VOLUMES =====
% Create subject
[sSubject, iSubject] = db_add_subject(SubjectName, [], 0, 0);
% Import T1 MRI
T1File = import_mri(iSubject, T1Nii, 'ALL', 0, 0);
% Compute the MNI normalization
bst_normalize_mni(T1File);
% Import T2 MRI
T2File = import_mri(iSubject, T2Nii, 'ALL', 0, 0);
% Volumes are not registered: Register with SPM
mri_coregister(T2File, T1File, 'spm', 1);
% Delete the non-registered T2
file_delete(file_fullpath(T2File), 1);
db_reload_subjects(iSubject);
            
% ===== IMPORT DTI =====
% Process: Convert DWI to DTI (BrainSuite)
bst_process('CallProcess', 'process_dwi2dti', [], [], ...
    'subjectname', SubjectName, ...
    'dwifile',     {DwiNii, 'DWI-NII'}, ...
    'bvalfile',    {DwiBval, 'DWI-BVAL'}, ...
    'bvecfile',    {DwiBvec, 'DWI-BVEC'});

% ===== RUN SIMNIBS =====
% Process: Generate FEM mesh
bst_process('CallProcess', 'process_fem_mesh', [], [], ...
    'subjectname',   SubjectName, ...
    'method',        'simnibs3', ...  % SimNIBS:Call SimNIBS to segment and mesh the T1 (and T2) MRI.
    'vertexdensity', 0.5, ...
    'nvertices',     15000, ...
    'zneck',         0);
% Select default cortex: Low-resolution
[sSubject, iSubject, iCortex] = bst_get('SurfaceFile', bst_fullfile(SubjectName, 'tess_cortex_pial_low.mat'));
db_surface_default(iSubject, 'Cortex', iCortex);

% ===== REMESH WITH ISO2MESH =====
% Part skipped because:
% 1) Not needed: DUNEuro works with cavities in this case
% 2) No process call for: Extract surfaces (import_femlayers)
% 3) Remeshing with iso2mesh doesn't work...

% ===== COMPUTE FEM TENSORS =====
% Process: Compute FEM tensors
bst_process('CallProcess', 'process_fem_tensors', [], [], ...
    'subjectname', SubjectName, ...
    'femcond',     struct(...
         'FemCond',         [0.14, 0.33, 1.79, 0.008, 0.43], ...
         'isIsotropic',     [0, 1, 1, 1, 1], ...
         'AnisoMethod',     'ema+vc', ...
         'SimRatio',        10, ...
         'SimConstrMethod', 'wolters'));

% ===== COMPUTE BEM SURFACES =====
% Process: Generate BEM surfaces
bst_process('CallProcess', 'process_generate_bem', [], [], ...
    'subjectname', SubjectName, ...
    'nscalp',      1922, ...
    'nouter',      1922, ...
    'ninner',      1922, ...
    'thickness',   4, ...
    'method',      'brainstorm');


%% ===== ACCESS THE RECORDINGS =====
% Process: Create link to raw file
sFilesRaw = bst_process('CallProcess', 'process_import_data_raw', [], [], ...
    'subjectname',    SubjectName, ...
    'datafile',       {FifFile, 'FIF'}, ...
    'channelreplace', 0, ...
    'channelalign',   1, ...    % Automatic registration with digitized head points
    'evtmode',        'value');

% Process: Events: Read from channel
sFilesRaw = bst_process('CallProcess', 'process_evt_read', sFilesRaw, [], ...
    'stimchan',  'STI101', ...
    'trackmode', 1, ...  % Value: detect the changes of channel value
    'zero',      0);

% Process: Project electrodes on scalp
bst_process('CallProcess', 'process_channel_project', sFilesRaw, []);

% Process: Snapshot: Sensors/MRI registration
bst_process('CallProcess', 'process_snapshot', sFilesRaw, [], ...
    'target',   1, ...  % Sensors/MRI registration
    'modality', 1, ...  % MEG (All)
    'orient',   1, ...  % left
    'Comment',  'MEG/MRI Registration');
% Process: Snapshot: Sensors/MRI registration
bst_process('CallProcess', 'process_snapshot', sFilesRaw, [], ...
    'target',   1, ...  % Sensors/MRI registration
    'modality', 4, ...  % EEG
    'orient',   1, ...  % left
    'Comment',  'EEG/MRI Registration');


%% ===== PRE-PROCESSING =====
% Process: Power spectrum density (Welch)
sFilesPsd = bst_process('CallProcess', 'process_psd', sFilesRaw, [], ...
    'timewindow',  [18, 148.999], ...
    'win_length',  5, ...
    'win_overlap', 50, ...
    'units',       'physical', ...  % Physical: U2/Hz
    'sensortypes', 'MEG, EEG', ...
    'win_std',     0, ...
    'edit',        struct(...
         'Comment',         'Power', ...
         'TimeBands',       [], ...
         'Freqs',           [], ...
         'ClusterFuncTime', 'none', ...
         'Measure',         'power', ...
         'Output',          'all', ...
         'SaveKernel',      0));
     
% Process: Snapshot: Frequency spectrum
bst_process('CallProcess', 'process_snapshot', sFilesPsd, [], ...
    'target',   10, ...  % Frequency spectrum
    'Comment',  'Power spectrum density');
     
% Process: Band-pass:20Hz-250Hz
sFilesBand = bst_process('CallProcess', 'process_bandpass', sFilesRaw, [], ...
    'sensortypes', 'MEG, EEG', ...
    'highpass',    20, ...
    'lowpass',     250, ...
    'tranband',    0, ...
    'attenuation', 'strict', ...  % 60dB
    'ver',         '2019', ...  % 2019
    'mirror',      0, ...
    'read_all',    0);

% Process: Notch filter: 60Hz 120Hz 180Hz
sFilesClean = bst_process('CallProcess', 'process_notch', sFilesBand, [], ...
    'sensortypes', 'MEG, EEG', ...
    'freqlist',    [60, 120, 180], ...
    'cutoffW',     2, ...
    'useold',      0, ...
    'read_all',    0);

% Process: Delete selected files
bst_process('CallProcess', 'process_delete', [sFilesRaw, sFilesBand], [], ...
    'target', 2);  % Delete selected folders

% Process: Re-reference EEG
bst_process('CallProcess', 'process_eegref', sFilesClean, [], ...
    'eegref',      'AVERAGE', ...
    'sensortypes', 'EEG');


%% ===== IMPORT RECORDINGS =====
% Process: Import MEG/EEG: Events
sFilesEpochs = bst_process('CallProcess', 'process_import_data_event', sFilesClean, [], ...
    'subjectname', SubjectName, ...
    'condition',   '', ...
    'eventname',   '2', ...
    'timewindow',  [18, 148.999], ...
    'epochtime',   [-0.1, 0.2], ...
    'createcond',  0, ...
    'ignoreshort', 1, ...
    'usectfcomp',  1, ...
    'usessp',      1, ...
    'freq',        [], ...
    'baseline',    []);

% Process: Average: By trial group (folder average)
sFilesAvg = bst_process('CallProcess', 'process_average', sFilesEpochs, [], ...
    'avgtype',       5, ...  % By trial group (folder average)
    'avg_func',      1, ...  % Arithmetic average:  mean(x)
    'weighted',      0, ...
    'keepevents',    0);

% Process: Snapshot: Recordings time series
bst_process('CallProcess', 'process_snapshot', sFilesAvg, [], ...
    'target',   5, ...  % Recordings time series
    'modality', 4, ...  % EEG
    'Comment',  'EEG ERP');
% Process: Snapshot: Recordings topography (contact sheet)
bst_process('CallProcess', 'process_snapshot', sFilesAvg, [], ...
    'target',   6, ...  % Recordings topography (ont time)
    'modality', 4, ...  % EEG
    'time',     Latency, ...
    'Comment',  'EEG ERP');
% Process: Snapshot: Recordings time series
bst_process('CallProcess', 'process_snapshot', sFilesAvg, [], ...
    'target',   5, ...  % Recordings time series
    'modality', 1, ...  % MEG (All)
    'Comment',  'MEG ERF');
% Process: Snapshot: Recordings topography (contact sheet)
bst_process('CallProcess', 'process_snapshot', sFilesAvg, [], ...
    'target',   6, ...  % Recordings topography (ont time)
    'modality', 1, ...  % MEG (All)
    'time',     Latency, ...
    'Comment',  'MEG ERF');


%% ===== NOISE COVARIANCE =====
% Process: Compute covariance (noise or data)
bst_process('CallProcess', 'process_noisecov', sFilesEpochs, [], ...
    'baseline',       [-0.1, -0.01], ...
    'sensortypes',    'MEG, EEG', ...
    'target',         1, ...  % Noise covariance     (covariance over baseline time window)
    'dcoffset',       1, ...  % Block by block, to avoid effects of slow shifts in data
    'replacefile',    1);  % Replace


%% ===== FORWARD: FEM EEG DTI =====
% Process: Compute head model
bst_process('CallProcess', 'process_headmodel', sFilesAvg, [], ...
    'Comment',     'DUNEuro FEM EEG DTI', ...
    'sourcespace', 1, ...  % Cortex surface
    'meg',         1, ...  % 
    'eeg',         4, ...  % DUNEuro FEM
    'ecog',        1, ...  % 
    'seeg',        1, ...  % 
    'duneuro',     struct(...
         'FemCond',             [], ...
         'FemSelect',           [1, 1, 1, 1, 1], ...
         'UseTensor',           1, ...
         'Isotropic',           1, ...
         'SrcShrink',           0, ...
         'SrcForceInGM',        0, ...
         'FemType',             'fitted', ...
         'SolverType',          'cg', ...
         'GeometryAdapted',     0, ...
         'Tolerance',           1e-08, ...
         'ElecType',            'normal', ...
         'MegIntorderadd',      0, ...
         'MegType',             'physical', ...
         'SolvSolverType',      'cg', ...
         'SolvPrecond',         'amg', ...
         'SolvSmootherType',    'ssor', ...
         'SolvIntorderadd',     0, ...
         'DgSmootherType',      'ssor', ...
         'DgScheme',            'sipg', ...
         'DgPenalty',           20, ...
         'DgEdgeNormType',      'houston', ...
         'DgWeights',           1, ...
         'DgReduction',         1, ...
         'SolPostProcess',      1, ...
         'SolSubstractMean',    0, ...
         'SolSolverReduction',  1e-10, ...
         'SrcModel',            'venant', ...
         'SrcIntorderadd',      0, ...
         'SrcIntorderadd_lb',   2, ...
         'SrcNbMoments',        3, ...
         'SrcRefLen',           20, ...
         'SrcWeightExp',        1, ...
         'SrcRelaxFactor',      6, ...
         'SrcMixedMoments',     1, ...
         'SrcRestrict',         1, ...
         'SrcInit',             'closest_vertex', ...
         'BstSaveTransfer',     0, ...
         'BstEegTransferFile',  'eeg_transfer.dat', ...
         'BstMegTransferFile',  'meg_transfer.dat', ...
         'BstEegLfFile',        'eeg_lf.dat', ...
         'BstMegLfFile',        'meg_lf.dat', ...
         'UseIntegrationPoint', 1, ...
         'EnableCacheMemory',   0, ...
         'MegPerBlockOfSensor', 0), ...
    'channelfile', '');
% Process: Compute sources [2018]
sSrcEegFemDti = bst_process('CallProcess', 'process_inverse_2018', sFilesAvg, [], ...
    'output',  1, ...  % Kernel only: shared
    'inverse', struct(...
         'Comment',        'Dipoles: EEG FEM DTI', ...
         'InverseMethod',  'gls', ...
         'InverseMeasure', 'performance', ...
         'SourceOrient',   {{'free'}}, ...
         'Loose',          0.2, ...
         'UseDepth',       1, ...
         'WeightExp',      0.5, ...
         'WeightLimit',    10, ...
         'NoiseMethod',    'median', ...
         'NoiseReg',       0.1, ...
         'SnrMethod',      'rms', ...
         'SnrRms',         1e-06, ...
         'SnrFixed',       3, ...
         'ComputeKernel',  1, ...
         'DataTypes',      {{'EEG'}}));
% Process: Dipole scanning
sDipEegFemDti = bst_process('CallProcess', 'process_dipole_scanning', sSrcEegFemDti, [], ...
    'timewindow', [Latency, Latency], ...
    'scouts',     {});


%% ===== FORWARD: FEM MEG DTI =====
% Process: Compute head model
bst_process('CallProcess', 'process_headmodel', sFilesAvg, [], ...
    'Comment',     'DUNEuro FEM MEG DTI', ...
    'sourcespace', 1, ...  % Cortex surface
    'meg',         5, ...  % DUNEuro FEM
    'eeg',         1, ...  % 
    'ecog',        1, ...  % 
    'seeg',        1, ...  % 
    'duneuro',     struct(...
         'FemCond',             [], ...
         'FemSelect',           [1, 1, 1, 0, 0], ...
         'UseTensor',           1, ...
         'Isotropic',           1, ...
         'SrcShrink',           0, ...
         'SrcForceInGM',        0, ...
         'FemType',             'fitted', ...
         'SolverType',          'cg', ...
         'GeometryAdapted',     0, ...
         'Tolerance',           1e-08, ...
         'ElecType',            'normal', ...
         'MegIntorderadd',      0, ...
         'MegType',             'physical', ...
         'SolvSolverType',      'cg', ...
         'SolvPrecond',         'amg', ...
         'SolvSmootherType',    'ssor', ...
         'SolvIntorderadd',     0, ...
         'DgSmootherType',      'ssor', ...
         'DgScheme',            'sipg', ...
         'DgPenalty',           20, ...
         'DgEdgeNormType',      'houston', ...
         'DgWeights',           1, ...
         'DgReduction',         1, ...
         'SolPostProcess',      1, ...
         'SolSubstractMean',    0, ...
         'SolSolverReduction',  1e-10, ...
         'SrcModel',            'venant', ...
         'SrcIntorderadd',      0, ...
         'SrcIntorderadd_lb',   2, ...
         'SrcNbMoments',        3, ...
         'SrcRefLen',           20, ...
         'SrcWeightExp',        1, ...
         'SrcRelaxFactor',      6, ...
         'SrcMixedMoments',     1, ...
         'SrcRestrict',         1, ...
         'SrcInit',             'closest_vertex', ...
         'BstSaveTransfer',     0, ...
         'BstEegTransferFile',  'eeg_transfer.dat', ...
         'BstMegTransferFile',  'meg_transfer.dat', ...
         'BstEegLfFile',        'eeg_lf.dat', ...
         'BstMegLfFile',        'meg_lf.dat', ...
         'UseIntegrationPoint', 1, ...
         'EnableCacheMemory',   0, ...
         'MegPerBlockOfSensor', 0), ...
    'channelfile', '');
% Process: Compute sources [2018]
sSrcMegFemDti = bst_process('CallProcess', 'process_inverse_2018', sFilesAvg, [], ...
    'output',  1, ...  % Kernel only: shared
    'inverse', struct(...
         'Comment',        'Dipoles: MEG FEM DTI', ...
         'InverseMethod',  'gls', ...
         'InverseMeasure', 'performance', ...
         'SourceOrient',   {{'free'}}, ...
         'Loose',          0.2, ...
         'UseDepth',       1, ...
         'WeightExp',      0.5, ...
         'WeightLimit',    10, ...
         'NoiseMethod',    'median', ...
         'NoiseReg',       0.1, ...
         'SnrMethod',      'rms', ...
         'SnrRms',         1e-06, ...
         'SnrFixed',       3, ...
         'ComputeKernel',  1, ...
         'DataTypes',      {{'MEG GRAD', 'MEG MAG'}}));
% Process: Dipole scanning
sDipMegFemDti = bst_process('CallProcess', 'process_dipole_scanning', sSrcMegFemDti, [], ...
    'timewindow', [Latency, Latency], ...
    'scouts',     {});


%% ===== FORWARD: FEM EEG ISO =====
% Get updated subject structure
sSubject = bst_get('Subject', iSubject);
% Get FEM file
FemFile = file_fullpath(sSubject.Surface(sSubject.iFEM).FileName);
% Remove tensors
process_fem_tensors('ClearTensors', FemFile);
% Process: Compute head model
bst_process('CallProcess', 'process_headmodel', sFilesAvg, [], ...
    'Comment',     'DUNEuro FEM EEG ISO', ...
    'sourcespace', 1, ...  % Cortex surface
    'meg',         1, ...  % 
    'eeg',         4, ...  % DUNEuro FEM
    'ecog',        1, ...  % 
    'seeg',        1, ...  % 
    'duneuro',     struct(...
         'FemCond',             [0.14, 0.33, 1.79, 0.008, 0.43], ...
         'FemSelect',           [1, 1, 1, 1, 1], ...
         'UseTensor',           0, ...
         'Isotropic',           1, ...
         'SrcShrink',           0, ...
         'SrcForceInGM',        0, ...
         'FemType',             'fitted', ...
         'SolverType',          'cg', ...
         'GeometryAdapted',     0, ...
         'Tolerance',           1e-08, ...
         'ElecType',            'normal', ...
         'MegIntorderadd',      0, ...
         'MegType',             'physical', ...
         'SolvSolverType',      'cg', ...
         'SolvPrecond',         'amg', ...
         'SolvSmootherType',    'ssor', ...
         'SolvIntorderadd',     0, ...
         'DgSmootherType',      'ssor', ...
         'DgScheme',            'sipg', ...
         'DgPenalty',           20, ...
         'DgEdgeNormType',      'houston', ...
         'DgWeights',           1, ...
         'DgReduction',         1, ...
         'SolPostProcess',      1, ...
         'SolSubstractMean',    0, ...
         'SolSolverReduction',  1e-10, ...
         'SrcModel',            'venant', ...
         'SrcIntorderadd',      0, ...
         'SrcIntorderadd_lb',   2, ...
         'SrcNbMoments',        3, ...
         'SrcRefLen',           20, ...
         'SrcWeightExp',        1, ...
         'SrcRelaxFactor',      6, ...
         'SrcMixedMoments',     1, ...
         'SrcRestrict',         1, ...
         'SrcInit',             'closest_vertex', ...
         'BstSaveTransfer',     0, ...
         'BstEegTransferFile',  'eeg_transfer.dat', ...
         'BstMegTransferFile',  'meg_transfer.dat', ...
         'BstEegLfFile',        'eeg_lf.dat', ...
         'BstMegLfFile',        'meg_lf.dat', ...
         'UseIntegrationPoint', 1, ...
         'EnableCacheMemory',   0, ...
         'MegPerBlockOfSensor', 0), ...
    'channelfile', '');
% Process: Compute sources [2018]
sSrcEegFemIso = bst_process('CallProcess', 'process_inverse_2018', sFilesAvg, [], ...
    'output',  1, ...  % Kernel only: shared
    'inverse', struct(...
         'Comment',        'Dipoles: EEG FEM ISO', ...
         'InverseMethod',  'gls', ...
         'InverseMeasure', 'performance', ...
         'SourceOrient',   {{'free'}}, ...
         'Loose',          0.2, ...
         'UseDepth',       1, ...
         'WeightExp',      0.5, ...
         'WeightLimit',    10, ...
         'NoiseMethod',    'median', ...
         'NoiseReg',       0.1, ...
         'SnrMethod',      'rms', ...
         'SnrRms',         1e-06, ...
         'SnrFixed',       3, ...
         'ComputeKernel',  1, ...
         'DataTypes',      {{'EEG'}}));
% Process: Dipole scanning
sDipEegFemIso = bst_process('CallProcess', 'process_dipole_scanning', sSrcEegFemIso, [], ...
    'timewindow', [Latency, Latency], ...
    'scouts',     {});


%% ===== FORWARD: FEM MEG ISO =====
% Process: Compute head model
bst_process('CallProcess', 'process_headmodel', sFilesAvg, [], ...
    'Comment',     'DUNEuro FEM MEG ISO', ...
    'sourcespace', 1, ...  % Cortex surface
    'meg',         5, ...  % DUNEuro FEM
    'eeg',         1, ...  % 
    'ecog',        1, ...  % 
    'seeg',        1, ...  % 
    'duneuro',     struct(...
         'FemCond',             [0.14, 0.33, 1.79, 0.008, 0.43], ...
         'FemSelect',           [1, 1, 1, 0, 0], ...
         'UseTensor',           0, ...
         'Isotropic',           1, ...
         'SrcShrink',           0, ...
         'SrcForceInGM',        0, ...
         'FemType',             'fitted', ...
         'SolverType',          'cg', ...
         'GeometryAdapted',     0, ...
         'Tolerance',           1e-08, ...
         'ElecType',            'normal', ...
         'MegIntorderadd',      0, ...
         'MegType',             'physical', ...
         'SolvSolverType',      'cg', ...
         'SolvPrecond',         'amg', ...
         'SolvSmootherType',    'ssor', ...
         'SolvIntorderadd',     0, ...
         'DgSmootherType',      'ssor', ...
         'DgScheme',            'sipg', ...
         'DgPenalty',           20, ...
         'DgEdgeNormType',      'houston', ...
         'DgWeights',           1, ...
         'DgReduction',         1, ...
         'SolPostProcess',      1, ...
         'SolSubstractMean',    0, ...
         'SolSolverReduction',  1e-10, ...
         'SrcModel',            'venant', ...
         'SrcIntorderadd',      0, ...
         'SrcIntorderadd_lb',   2, ...
         'SrcNbMoments',        3, ...
         'SrcRefLen',           20, ...
         'SrcWeightExp',        1, ...
         'SrcRelaxFactor',      6, ...
         'SrcMixedMoments',     1, ...
         'SrcRestrict',         1, ...
         'SrcInit',             'closest_vertex', ...
         'BstSaveTransfer',     0, ...
         'BstEegTransferFile',  'eeg_transfer.dat', ...
         'BstMegTransferFile',  'meg_transfer.dat', ...
         'BstEegLfFile',        'eeg_lf.dat', ...
         'BstMegLfFile',        'meg_lf.dat', ...
         'UseIntegrationPoint', 1, ...
         'EnableCacheMemory',   0, ...
         'MegPerBlockOfSensor', 0), ...
    'channelfile', '');
% Process: Compute sources [2018]
sSrcMegFemIso = bst_process('CallProcess', 'process_inverse_2018', sFilesAvg, [], ...
    'output',  1, ...  % Kernel only: shared
    'inverse', struct(...
         'Comment',        'Dipoles: MEG FEM ISO', ...
         'InverseMethod',  'gls', ...
         'InverseMeasure', 'performance', ...
         'SourceOrient',   {{'free'}}, ...
         'Loose',          0.2, ...
         'UseDepth',       1, ...
         'WeightExp',      0.5, ...
         'WeightLimit',    10, ...
         'NoiseMethod',    'median', ...
         'NoiseReg',       0.1, ...
         'SnrMethod',      'rms', ...
         'SnrRms',         1e-06, ...
         'SnrFixed',       3, ...
         'ComputeKernel',  1, ...
         'DataTypes',      {{'MEG GRAD', 'MEG MAG'}}));
% Process: Dipole scanning
sDipMegFemIso = bst_process('CallProcess', 'process_dipole_scanning', sSrcMegFemIso, [], ...
    'timewindow', [Latency, Latency], ...
    'scouts',     {});


%% ===== FORWARD: BEM EEG =====
% Process: Compute head model
bst_process('CallProcess', 'process_headmodel', sFilesAvg, [], ...
    'Comment',     'OpenMEEG BEM EEG', ...
    'sourcespace', 1, ...  % Cortex surface
    'meg',         1, ...  % 
    'eeg',         3, ...  % OpenMEEG BEM
    'ecog',        1, ...  % 
    'seeg',        1, ...  % 
    'openmeeg',    struct(...
         'BemSelect',    [1, 1, 1], ...
         'BemCond',      [1, 0.0125, 1], ...
         'BemNames',     {{'Scalp', 'Skull', 'Brain'}}, ...
         'BemFiles',     {{}}, ...
         'isAdjoint',    0, ...
         'isAdaptative', 1, ...
         'isSplit',      0, ...
         'SplitLength',  4000), ...
    'channelfile', '');
% Process: Compute sources [2018]
sSrcEegBem = bst_process('CallProcess', 'process_inverse_2018', sFilesAvg, [], ...
    'output',  1, ...  % Kernel only: shared
    'inverse', struct(...
         'Comment',        'Dipoles: EEG BEM', ...
         'InverseMethod',  'gls', ...
         'InverseMeasure', 'performance', ...
         'SourceOrient',   {{'free'}}, ...
         'Loose',          0.2, ...
         'UseDepth',       1, ...
         'WeightExp',      0.5, ...
         'WeightLimit',    10, ...
         'NoiseMethod',    'median', ...
         'NoiseReg',       0.1, ...
         'SnrMethod',      'rms', ...
         'SnrRms',         1e-06, ...
         'SnrFixed',       3, ...
         'ComputeKernel',  1, ...
         'DataTypes',      {{'EEG'}}));
% Process: Dipole scanning
sDipEegBem = bst_process('CallProcess', 'process_dipole_scanning', sSrcEegBem, [], ...
    'timewindow', [Latency, Latency], ...
    'scouts',     {});


%% ===== FORWARD: OS MEG =====
% Process: Compute head model
bst_process('CallProcess', 'process_headmodel', sFilesAvg, [], ...
    'Comment',     'OS MEG', ...
    'sourcespace', 1, ...  % Cortex surface
    'meg',         3, ...  % Overlapping spheres
    'eeg',         1, ...  % 
    'ecog',        1, ...  % 
    'seeg',        1, ...  % 
    'channelfile', '');
% Process: Compute sources [2018]
sSrcMegOs = bst_process('CallProcess', 'process_inverse_2018', sFilesAvg, [], ...
    'output',  1, ...  % Kernel only: shared
    'inverse', struct(...
         'Comment',        'Dipoles: MEG OS', ...
         'InverseMethod',  'gls', ...
         'InverseMeasure', 'performance', ...
         'SourceOrient',   {{'free'}}, ...
         'Loose',          0.2, ...
         'UseDepth',       1, ...
         'WeightExp',      0.5, ...
         'WeightLimit',    10, ...
         'NoiseMethod',    'median', ...
         'NoiseReg',       0.1, ...
         'SnrMethod',      'rms', ...
         'SnrRms',         1e-06, ...
         'SnrFixed',       3, ...
         'ComputeKernel',  1, ...
         'DataTypes',      {{'MEG GRAD', 'MEG MAG'}}));
% Process: Dipole scanning
sDipMegOs = bst_process('CallProcess', 'process_dipole_scanning', sSrcMegOs, [], ...
    'timewindow', [Latency, Latency], ...
    'scouts',     {});


%% ===== MERGE DIPOLES =====
% sDipEegFemDti, sDipMegFemDti, sDipEegFemIso, sDipMegFemIso, sDipEegBem, sDipMegOs
% FEM DTI: EEG vs MEG
% sDipFemDti = dipoles_merge({sDipEegFemDti.FileName, sDipMegFemDti.FileName});


% Save and display report
ReportFile = bst_report('Save', []);
bst_report('Open', ReportFile);




-  ⇤ ← Revision 18 as of 2021-02-04 15:02:31 → 
  Size: 6932
  Editor: ?JuanGarciaPrieto
  Comment:
+   ← Revision 202 as of 2024-08-10 06:16:08 → ⇥
  Size: 29049
  Editor: TakfarinasMedani
  Comment:
-Deletions are marked like this.
+Additions are marked like this.
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-## page was renamed from Tutorials/DuneuroMunsterData
'''[TUTORIAL UNDER CONSTRUCTION]'''

Will be completed soon

In this tutorial we describe the full FEM process as described in the SPIE paper

We may keep the previous tutorial as a basic and this tutorial is an advanced and complete version.

= FEM tutorial: MEG/EEG Median nerve stimulation =
''Authors: Takfarinas Medani, Juan Garcia-Prieto, Wayne Mead.''

This tutorial introduces the FEM modeling in the Brainstorm environment.
+'''WARNING: '''This tutorial uses an old version of SimNIBS, which includes the segmentation pipeline headreco. Please see instead the [[Tutorials/FemMedianNerveCharm|new version of this tutorial]], based on SimNIBS 4 and the CHARM pipeline. However, we recommned to use the current version with SimNibs3 headreco. We are working with SimNibs team to keep the [[https://github.com/simnibs/simnibs/releases|Headreco availble for the users]] [headreco is available on all releases prior to v4.0].

----

= FEM tutorial with MEG/EEG median nerve stimulation (headreco) =
''Authors: Takfarinas Medani, Juan Garcia-Prieto, Wayne Mead, Michael Funke, Francois Tadel ''

This tutorial introduces the most advanced FEM modeling options available in the Brainstorm environment, applied to MEG+EEG recordings of a median nerve stimulation. The pipeline presented here includes: FEM mesh reconstruction with SimNIBS3/CAT12, FEM head model including DTI tensors for modeling anisotropic conductivities (using BrainSuite), FEM forward model estimation with DUNEuro. This pipeline requires many third-party programs and very long computation times. For a simpler FEM pipeline, please refer to the tutorial: [[https://neuroimage.usc.edu/brainstorm/Tutorials/Duneuro|Realistic head model: FEM with DUNEuro]].
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-== License ==
This tutorial dataset (MEG/EEG and MRI data) remains proprietary of Yokogawa Electric Corporation, Japan. Its use and transfer outside the Brainstorm tutorial, e.g. for research purposes, is prohibited without written consent from Yokogawa Electric Corporation.

== Description of the experiment ==
The experiment consists of two stimulation protocols being conducted during a single scanning session in a MEG laboratory with an Elekta Triux (Megin, Finland) scanner. The subject is a a right-handed 46 years old male. The two stimulation protocols consist of a unilateral median nerve stimulation and an eyes-close resting-state recording.

Median nerve stimulation:

 * The stimulation signal was a square-wave pulse with 2Hz frequency and a duration of 0.2ms.
 * An ISI (inter-stimulus interval) of 500ms with a variation of ±20ms in order to be able to average out time-locked noise to the stimulation, while remaining unnoticeable by the subject.
 * The stimulation was performed on both hands/wrists, independently, with a Digitimer DS7A stimulator. An electrode was placed on each current values were tuned to match the motor threshold of the subject on the stimulated hand, with a result of 10~12mA aproximately.
 * Initially, the left wrist was stimulated for aproximately 2 minutes (this corresponds with the file containing L1 in its name). After a 2-minute rest, while sitting in the MSR and with his head in the helmet, the stimulation was repeated (L2 file). After this stimulation the subject was asked to have a 10 minutes rest, during which he was allowed to sit calmly with his head out of the helmet, although remaining hooked to the scanner at all times. Finally, two subsequents runs of right wrist stimulation (R1 and R2 files) with an intermediate 2-minute rest were performed.
 * Recordings were performed with a 1kHz sampling rate. Continuous HPI was disabled during these recordings. And high-pass filters were set to DC for MEG channels and 0.03Hz for EEG channels.
 * All files underwent a MaxFilter (version 2.3.13) tsss post-processing.

Resting-State protocol:

 * The subject was recorded for aproximately 80 minutes. Due to a 2GB maximum-size limitation for FIFF files, this translates into the recording being saved in files 'epi1' to 'epi4'.
 * The subject had his eyes closed.
 * Recordings were performed with a 1kHz sampling rate. Continuos HPI was enabled. High-pass filterse were set to DC for MEG channels and 0.03Hz for EEG channels.
 * All files underwent a MaxFilter (version 2.3.13) tsss post-processing, with motion compensation active.

== Export recordings from fif files? ==
==== Full head shape in the the digitizer file ====
In order to realize a precise MRI registration or for warping the default anatomy, you should collect 100 to 200 points describing the entire head shape in addition to the 8 Yokogawa/KIT standard stylus points. To import additional digitized points, follow the instruction below:

 * When digitizing head points:
  * Pick the 8 standard stylus points
  * Pick additional 100 to 200 head points, so that the selected points cover the entire head
 * Edit the digitizer label file (DigitizeLabel.txt) which is used in "Third-party export" so that it defines the 8 points and the additional points.
+<<Include(DatasetFem, ,    from="\<\<HTML\(\<!-- START-PAGE --\>\)\>\>",    to="\<\<HTML\(\<!-- STOP-SHORT --\>\)\>\>")>>
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- * Requirements: You have already followed all the introduction tutorials and you have a working copy of Brainstorm installed on your computer.
+==== Requirements ====
 * You have  already  followed all the  introduction tutorials.
 * You have a working copy of   Brainstorm  installed on your computer.

==== Additional programs ====
You need to install the following programs (listed by order of appearance):

 * '''SimNIBS 3.x''': See tutorial: [[https://neuroimage.usc.edu/brainstorm/Tutorials/FemMesh#SimNIBS|FEM mesh generation]]
 * '''BrainSuite''': See tutorial: [[https://neuroimage.usc.edu/brainstorm/Tutorials/FemTensors#Brainsuite_Installation|FEM tensors estimation]]
 * '''MATLAB Runtime''': Follow the instructions on the BrainSuite download page
 * '''SPM12''': Install as [[https://neuroimage.usc.edu/brainstorm/Tutorials/Plugins|Brainstorm plugins]]
 * '''CAT12''': Install as [[https://neuroimage.usc.edu/brainstorm/Tutorials/Plugins|Brainstorm plugins]]
 * '''Iso2mesh''': Install as [[https://neuroimage.usc.edu/brainstorm/Tutorials/Plugins|Brainstorm plugins]]
 * '''DUNEuro''': See tutorial: [[https://neuroimage.usc.edu/brainstorm/Tutorials/Duneuro|Realistic head model: FEM with DUNEuro]]

==== Download the dataset ====
 * Go to the [[http://neuroimage.usc.edu/bst/download.php|Download]] page and get the file: '''sample_fem.zip'''
 * Unzip it outside of any of the Brainstorm folders (program   folder or database folder).
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- * * "'''No, use individual anatomy'''",
  * "'''No, use one channel file per condition'''".
+ * Select the menu File > Create new protocol. Name it "'''TutorialFem'''" and select:
  * No, use individual anatomy
  * No, use one channel file per condition
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- * Right-click on the TutorialXXX folder > New subject > '''Subject01'''
  * Leave the default options you set for the protocol
 * Right-click on the subject node > Import anatomy folder:
  * Set the file format: "FreeSurfer folder"
  * Number of vertices of the cortex surface: 15000 (default value)
 * Click on the link "'''Click here to compute MNI transformation'''".
 * Set the 6 required fiducial points (indicated in MRI coordinates). This dataset is a good example of a real-world fiducials setting. Fiducials points not always have to be located where we recommend in our introductory tutorial (link to tutorial!!!). Every patient is different and sometimes things get on the way, and it is not possible to follow canonical recommendations. That is fine! As long as there is a correct correspondence between fiducial points in the fif file and in the MRI, everything works fine. In order to guide in this process, the dataset includes images of the locations with the preauricular fiducials.
  *
 * At the end of the process, make sure that the file "cortex_15000V" is selected (downsampled pial surface, which will be used for the source estimation). If it is not, double-click on it to select it as the default cortex surface.<<BR>><<BR>>
+=== T1 MRI ===
 * Switch to the "anatomical data" view, the left button in the toolbar above the database explorer.
 * Right-click on the TutorialFem folder > New subject > '''Subject01'''
  * Keep the default options you set for the protocol.

 * Right-click on the subject node > '''Import MRI''':
  * Set the file format: '''All MRI files (subject space)'''

  * Select the T1 file: sub-fem01/ses-mri/anat/'''sub-fem01_ses-mri_T1w.nii.gz'''

 * Click on the link "'''Click here to compute MNI normalization'''": option "'''maff8'''".<<BR>>This estimates an affine transformation to the [[https://neuroimage.usc.edu/brainstorm/CoordinateSystems#MNI_coordinates|MNI space]] and sets default positions for the anatomical fiducials. Because we will use the digitized head shape of the subject to [[https://neuroimage.usc.edu/brainstorm/Tutorials/ChannelFile#Automatic_registration|refine the MRI/MEG registration]], we don't need the position of the fiducials to be very accurate.<<BR>><<BR>> {{attachment:importT1.gif}}

=== T2 MRI ===
 * Right-click on the subject node > '''Import MRI''':
  * Set the file format: '''All MRI files (subject space)'''

  * Select the T2 file: sub-fem01/ses-mri/anat/'''sub-fem01_ses-mri_T2w.nii.gz'''

 * Brainstorm asks about registering the new T2 with the reference T1 image:
  * Select the option: '''SPM'''

  * Reslice the volume: '''Yes'''

 * This process will take few minutes, just be patient.<<BR>><<BR>> {{attachment:importT2.gif}}

=== Diffusion imaging ===
The FEM has the ability to incorporate anisotropic  conductivity from MRI diffusion imaging, which is particularly interesting for the modeling of the white matter. Brainstorm can load the Diffusion-Weighted Images (DWI), and compute the tensors (DTI) using the [[Tutorials/FemTensors|BrainSuite Diffusion Pipeline]] (BDP). This requires BrainSuite to be installed on your computer, with the bdp program available in the system path.

 * Right-click on Subject01''' '''> '''Convert DWI to DTI'''

 * Select the DWI file: sub-fem01/ses-mri/dwi/'''sub-fem01_ses-mri_dwi.nii.gz'''

 * The associated files *dwi.bvec and *dwi.bval must be in the same folder.

 * The process can take up to 30min. At the end, a new file '''DTI-EIG''' appears in the database. This file contains 12 volumes, ie. 12 values for each voxel. From 1 to 9: components of the three eigenvectors; from 10 to 12:  the values of their norm to the eigenvalue. <<BR>><<BR>> {{attachment:importDTI.gif}}

== FEM head model ==
The FEM approach requires a segmentation of the head volume in different tissues, represented as hexahedral or tetrahedral 3D meshes. The methods available within Brainstorm are listed in the tutorial [[Tutorials/FemMesh|FEM mesh generation]]. Here we illustrate only the use of SimNIBS.

=== FEM mesh with SimNIBS ===
Running SimNIBS:

 * Select both the T1 and the T2 MRIs, using the mouse and the SHIFT or CTRL keys.
 * Right-click on the selected files > MRI segmentation > '''Generate FEM mesh''' > '''SimNIBS'''. Keep the default options.
 * This process can take 2-5 hours.
 * The output of SimNIBS is saved in the temporary folder $HOME/.brainstorm/tmp/simnibs, and then imported into the Brainstorm database.

At the end of this computation, new files are available in the database:

 * '''tissues''': Segmentation of the head volume in 6 different tissues
 * '''head mask''': Outer surface of the scalp
 * '''cortex_280000V''': Pial surface generated by CAT12 within the SimNIBS process

 * '''cortex_15002V''': Low-resolution version of the pial surface

 * '''cortex_fem''': Outer surface mesh of the gray matter, extracted from the FEM mesh

 * '''FEM 70000V''': Tetrahedral FEM mesh with 5 layers  (gm, wm, CSF, skull, scalp).

At the end of the process, make sure that the file "cortex_15002V" is selected (downsampled pial surface, which will be used for the source estimation). If it is not, double-click on it to select it as the default cortex surface.

{{attachment:simnibs.gif}}

=== Remesh with Iso2mesh ===
This step is '''optional''', to be considered only when the DUNEuro FEM computation fails. In some cases, the FEM mesh generated with SimNIBS causes issues with the DUNEuro FEM solver, due to the air cavities that are not tesselated. In order to avoid these possible issues in the next steps, we will correct the mesh using the Iso2mesh functions integrated within Brainstorm.

 * Right-click on the FEM mesh > '''Extract surfaces'''.
 * Hold the CTRL key to select all the extracted surfaces (white, gray, csf, skull, scalp).
 * Right-click > '''Generate FEM mesh''' > '''Iso2mesh-2021''' > '''MergeMesh''' > Max volume = '''0.001''', Percentage kept = '''100'''. Note that the higher the resolution leads to higher accuracy but also higher memory requirements and longer computation times.<<BR>><<BR>> {{attachment:remeshHeadIso2mesh.jpg||height="150",width="600"}}

The following figure shows the two model, left is the initial model obtained with SimNibs, right is the second model obtained from the Iso2Mesh remesh: the air cavity in the bottom-right corner is now fully tesselated. Note that you can also use this process to generate FEM models with higher mesh densities.

{{attachment:femMeshSimNibsVSiso2mesh2.jpg||height="150",width="600"}}

=== FEM tensors ===
We can now incorporate the diffusion information into the FEM model, and compute anisotropic conductivity tensors for the tetrahedral elements of the white matter (we consider the other tissues to have isotropic conductivities).

 * Right-click on the FEM mesh > '''Compute FEM tensors'''. Select the options as illustrated below, and refer to the tutorial [[Tutorials/FemTensors|FEM tensors]] for more information. <<BR>><<BR>> {{attachment:computeTensors.gif}}
 * This process can take up to 5min, depending on the resolution of the FEM mesh.

=== Visualization ===
Brainstorms include the possibilities to display the FEM head models and the tensors, users can also overlay the display with the MRI as well as with the different surfaces.

{{attachment:overlayModalities.png||height="150",width="600"}}

Right-click on the FEM mesh > '''Display FEM tensors''': The FEM tensors can be displayed on the mesh or MRI, as arrows on the main eigenvector or as ellipsoids on each FEM element.

{{attachment:dispTensorMenu.png||height="150",width="600"}}

{{attachment:tensorsOnBrain.jpg||height="150",width="600"}}

{{attachment:tensorsOnMRI.jpg||height="150",width="600"}}

To configure the display: right-click on the figure > '''FEM tensors''' menu. The keyboard shortcuts for changing the size of the displayed tensors are the '''Up''' and '''Down''' arrows keys. You can also switch the display mode by using the shortcut "Shift + Space".

<<TAG(Advanced)>>

=== On the hard drive ===
The '''DTI-EIG''' file as the same structure as any [[https://neuroimage.usc.edu/brainstorm/Tutorials/ExploreAnatomy#On_the_hard_drive:_MRI|MRI file]], with 12 volumes stacked along the 4th dimension. From 1 to 9: components of the three eigenvectors; from 10 to 12:  the values of their norm to the eigenvalue.

The '''FEM''' mesh contains the following fields:

 * <<BR>><<BR>> {{attachment:femDataOnHardDisc.png||height="150",width="600"}}

=== BEM head model ===
For the purpose of comparison between the FEM and the BEM, we will generate also the BEM surfaces for this subject and we will follow the same step as explained in the [[Tutorials/TutBem|BEM tutorial]].

 * Right-click on Subject01 > MRI segmentation > '''Generate BEM surfaces''' > '''Brainstorm'''.<<BR>>Keep the default options: 1922 vertices for all the layers, skull thickness = 4m.
 * Three new files appear in the database explorer: bem_head_1922V, bem_outerskull_1922V, and bem_innerskull_1922V. These surfaces will be used for the BEM forward computation.
 * Now we have two head geometry available for this subject, BEM and FEM  {{attachment:fem&bemModels.jpg|fem&bemModels.jpg|height="150",width="600"}}
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+ * The folder "eeg_positions" which contains default 10-10 EEG electrodes positions, was generated by the SimNIBS process. We will not use it in this tutorial: '''delete this folder'''.
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-  *

=== Prepare the channel file ===
 *

=== Refine the MRI registration ===
 *
 *

=== Read the stimulation information ===
 *

== Pre-processing ==
=== Evaluate the recordings ===
 *
+  * Select file type: MEG/EEG: Electa-Neuromag(*.fif)
  * Select file: sub-fem01/ses-meg/meg/'''sub-fem01_ses-meg_task-mediannerve_run-01_proc-tsss_meg.fif'''
  * FIF event file: Select '''Event Channe'''l, this will read the events markers
  * Refine registration? '''YES'''
 * A figure is opened to show the registration MRI/MEG.<<BR>><<BR>> {{attachment:registration.gif||height="243",width="305"}}
 * The new file "Link to raw file" lets you access directly the contents of the MEG/EEG recordings. The "Neuromag channels (374)" contains the name of the channels and the position of the corresponding sensors (MEG/EEG).

=== Channel file ===
 * The recordings contain signals coming from different types of electrodes:
  * 306 MEG channels (102 magnetometers and 204 gradiometers )
  * 64 EEG channels
  * 2 EOG channels: EO1 and EO2
  * 1 Stim channel that contain the stimulation signals
 * Right-click on the channel file > '''MRI registration''' > '''Edit... (EEG) '''
 * The white points are the electrodes, the green points are the additional digitized head points. To display the label of the electrodes, click on the [LABEL] button in the toolbar. To see what the other buttons in the toolbar are doing and how to use them, leave your mouse over them for a few seconds and read the description.
 * The automatic registration based on the head points is already good, therefore we won't apply any additional rotation+translation to the MEG+EEG sensors.
 * Click on the button '''"Project electrodes on scalp surface"''', it will help for the source modeling later. The green points (digitized) stay in place, the white points (electrodes) are now projected on the skin of the subject.
 * If you feel like you didn't do this correctly, close the figure and cancel the modifications, then try again.
 * Click on '''[OK]''' when done. Answer '''YES''' to save the modifications.

=== Pre-processing ===
 * Drag and drop the "Link to raw file" into the Process1 list.
 * Select the process "'''Frequency > Power spectrum density'''", configure it as in the figure
 * After the computation, double-click on the new PSD file to display it.<<BR>><<BR>> {{attachment:psd.jpg||height="500",width="600"}}

 * The lines on the top represent the EEG electrodes, the lines at the bottom the MEG sensors(MAG and GRAD). If you want to get clearer plots, you can calculate separately the spectrum for the two types of sensors separately, by running twice the process "Power spectrum density", once with sensor types = "MEG" and once with "EEG", instead of running in on both at the same time as we did.
 * Observations (below 250Hz):
  * Peak around 10Hz: Alpha waves from the subject's brain
  * Peaks at 60Hz, 120Hz, 180Hz, 240Hz on EEG + MEG: Power lines (60Hz+harmonics)
  * Most of the signal looks clean and no bad channel is observed

 * If we review quickly the EEG and EOG signals, we notice that they are quite clean and no artifacts are observed. The experiment is well designed and the subject was not moving the eyes (blinks and slow movements), maybe because there was a fixation cross for this experiment. However, we will apply at least a high-pass filter to make the signals easier to process (we are not interested in very low frequencies in this experiment).
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- *

== Review the recordings ==
=== MEG: Default montages ===
=== MEG: Bad channels ===
 *
+ * In Process1, select the "Link to raw file".
 * Select process '''Pre-process > Band-pass filter''': Frequency='''[20, 250]Hz''', Sensors='''MEG,EEG'''
 * Add process '''Pre-process > Notch filter''': Frequencies='''[60 120 180]Hz''', Sensors='''MEG,EEG'''<<BR>><<BR>> {{attachment:freqFilters.jpg||height="500",width="600"}}

 * In Process1, select the filtered file "Raw | Band | Notch".
 * Run the process "'''Frequency > Power spectrum density'''", with the same options as before. And compare with the previous figure. You may find that the power line frequency and its harmonics are removed and the data is filtered between 20 and 250Hz.<<BR>><<BR>> {{attachment:spectreClean.jpg||height="500",width="600"}}
 * To keep the interface clean and easy to follow: keep only the last continuous file (Raw|Band|Notch). Delete the link to the original file (which will not delete the original .fif file), and delete the "Raw|Band" file.
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- *

== Artifacts cleaning with ICA ==
=== Detect heartbeats and blinks ===
 *

=== EEG: Heartbeats and eye movements ===
 *
 *

=== MEG: Heartbeats and eye movements ===
 *

== Epoching and averaging ==
=== Import the recordings ===
+ * Right-click on the filtered file "Raw|band|notch" > EEG > Display time series.
 * In the Record tab, menu '''Artifacts > Re-reference EEG''' > "AVERAGE".<<BR>><<BR>> {{attachment:avgRef.jpg||height="500",width="600"}}

 * At the end, the window "Select active projectors" is open to show the new re-referencing projector. Just close this window. To get it back, use the menu Artifacts > Select active projectors.

=== Epoching ===
In this experiment, the electric stimulation is sent with a frequency of 2Hz, meaning that the inter-stimulus interval is 500ms. We are going to import epochs of 300ms around the stimulation events (-100 to 200ms).

 * Right-click on the filtered file "Raw|band|notch" > '''Import in database''':
 * Check "'''Use events'''" and select "'''2'''", this is the name that brainstorm assigns for the stimulus onset, it may have different name on your computer. Set epoch time: '''[-100, 200]''' '''ms ''' and Apply SSP/ICA in order to apply the average reference.<<BR>><<BR>> {{attachment:importEpochs.jpg||height="500",width="600"}}

 * At the end, you are asked whether you want to ignore one epoch that is shorter than the others. This happens because the acquisition of the MEG signals was stopped less than 300ms after the last stimulus trigger was sent. Therefore, the last epoch cannot have the full [-100,200]ms time definition. This shorter epoch would prevent us from averaging all the trials easily. As we already have enough repetitions in this experiment (240), we can just ignore it. The total number of epochs is then 239.
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- *
+ * Drag and drop all the Trigger01 trials to the Process1 tab.
 * Run the process '''Average > Average files''': By trial group (folder average)<<BR>><<BR>> {{attachment:avrgEpochs.jpg||height="500",width="600"}}

 * Review the average for the '''MEG''' and '''EEG''' as a topography plot: Right-click on the averaged signal > EEG > 2D disc, repeat for MEG.<<BR>><<BR>> {{attachment:megEegTopography.jpg||height="700",width="800"}}

 * At the selected time (21ms), an ERP is visible with a nice dipolar pattern on the sensors, both for the EEG and MEG.

== Forward model ==
We are going to use the realistic FEM model previously generated from the MRI. Go to the "Anatomy" view, and make sure that the FEM head model is highlighted in green color (it should be the case if you have only one model). You may also highlight the cortex to use for the computation (select the cortex_15002V).

You can compute the forward model both for EEG and MEG simultaneously, however, using the high mesh resolution model we recommend to compute separately the head model for each modality (EEG and then MEG). The time required for EEG is around one hour for ~70 channels, for the MEG with 306 sensors it can take up to 4 hours or more (with the integrations points).

The EEG/MEG FEM computation depends on the computation of the FEM transfer matrix, which is related to the resolution of the FEM head mesh (number of vertices) and the number of sensors. In most of the case, the number of EEG sensors is lower than the number of MEG sensors. Furthermore, internally the MEG sensors modeling uses the integrations points, which increase the number of computation points (~ multiplied by 4 for the magnetometers and by 8 for the gradiometers). Therefore, the MEG requires more time than the EEG.

To reduce the MEG computation time, there are some tips:

 1. Use only the inners tissues (wm, gm, and CSF) ==> reduce the number of vertices
 1. Do not use the integration points ==> reduce the number of virtual sensors
 1. These parameters can be tuned from the DUNEuro options panel (see the advanced panel)

=== EEG with DTI tensors ===
 * Go back to the "Functional data" view
 * Right-click on the channel file (folder with imported epochs) > '''Compute head model'''
 * Select '''EEG only > DUNEuro FEM''', and set the comment to "DUNEuro FEM EEG DTI tensors"
 * On the DUNEuro options panel: click on "Show details" and set the options as illustrated below
 * Click OK. Depending on the performance of your computer, the FEM EEG head modeling can last between 30min to 3hrs.  Once the computation is done, a new node with the name "DUNEuro FEM EEG  DTI tensors" appears in the Brainstorm database navigator, which can be used for the source localization process.<<BR>><<BR>> {{attachment:eegDuneuroPanels.jpg||height="300",width="600"}}

=== MEG with DTI tensors ===
 * Right-click on the channel file > '''Compute head model'''
 * Select '''MEG only > DUNEuro FEM''', and set the comment to "DUNEuro FEM MEG DTI tensors"
 * On the DUNEuro options panel: click on "Show details" and set the options as illustrated below. To reduce the computation time, we select only the inner layers (white, gray and CSF).

 * Click OK. Depending on the performance of your computer, the FEM MEG  head modeling can last between 1hr to 4hrs.  Once the computation is done, a new node with the name "DUNEuro FEM MEG  DTI tensors" appears in the Brainstorm database navigator, which can be  used for the source localization  process.<<BR>><<BR>> {{attachment:megDuneuroPanelsDTI.jpg||height="300",width="600"}}

=== EEG with isotropic conductivity ===
If the DTIs are not available, it is possible to use the isotropic conductivities instead. In this tutorial, we will compute another forward model in order to compare the sources obtained with anisotropic or isotropic conductivities.

 * First you need to make sure that the tensors are not computed. If you have the tensors already computed, you need to clear these values. Go to the "Anatomy" view, right-click on the FEM mesh > '''Clear FEM tensors'''.
 * Go back to "Functional data", right-click on channel file > '''Compute head model'''. In this case, you can change the isotropic conductivity for each tissue. Set the options as in the figure below.<<BR>><<BR>> {{attachment:eegDuneuroPanelsIso.jpg||height="300",width="600"}}

=== MEG with isotropic conductivity ===
 * Same as before, first you need to make sure that the tensors are not computed.

 * Right-click on the channel file > '''Compute head model,''' and set the value as in the figure below. In this example keep only the inner tissues (white, gray and CSF).<<BR>><<BR>> {{attachment:megDuneuroPanelsIso.jpg||height="300",width="600"}}
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-=== Head model ===
 *
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- *
+ * We will use the baseline of the single epochs to calculate the noise covariance matrix.
 * Right-click on the epochs group > Noise covariance > '''Compute from recordings'''. Enter the same baseline interval we used for removing the DC offset: '''[-100, -10] ms''' <<BR>><<BR>> {{attachment:noiseCovariance.jpg||height="300",width="600"}}
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- *
 *
 *

=== Regions of interest ===
 * Create two scouts S1 and S2 to represent the primary and secondary somatosensory cortex of the left hemisphere.
  *
+It is recommended to study separately the two modalities because  Brainstorm does not offer any reliable method for combining MEG and EEG  source imaging yet. More explanations in the [[https://neuroimage.usc.edu/brainstorm/Tutorials/SourceEstimation#Combining_MEG.2B-EEG_for_source_estimation|Source estimation tutorial]].

 * Repeat the same step for each of the four forward models (EEG/MEG, DTI/isotropic):

 * Right-click on the head model > '''Compute sources''' > '''Dipole modeling'''.
 * Edit the comment to be able to identify the source maps easily: EEG FEM DTI, EEG FEM ISO, MEG FEM DTI, MEG FEM ISO.<<BR>><<BR>> {{attachment:computeDipolesInverseAll.jpg||height="300",width="600"}}
 * For each forward model, this operation creates a shared inversion kernel and one source link for each block of recordings in the folder.<<BR>><<BR>> {{attachment:sharedKernelDipolesEegMeg.jpg||height="300",width="600"}}

=== Dipole scanning ===
 * Drag and drop the source links for the average in the Process1 tab.
 * Run the process: Sources > '''Dipole Scanning''' > '''40ms-60ms'''. See the [[https://neuroimage.usc.edu/brainstorm/Tutorials/TutDipScan#Dipole_scanning|Dipole scanning tutorial]]. <<BR>><<BR>> {{attachment:dipoleScanningProcess.jpg||height="300",width="600"}}

 * Select and merge the MEG ISO and the MEG DTI dipoles. Repeat for the EEG dipoles.
 * Rename the merged dipoles with a clearer comment, as illustrated below.<<BR>><<BR>> {{attachment:dipolesMergeEEG&MEG.jpg|dipolesMergeEEG&MEG.jpg|height="300",width="600"}}

=== Comparison: DTI vs isotropic ===
The following figures (left EEG, right MEG), show the localization of the dipoles on the MRI at the 21ms. The ISO model is colored in green whereas the DTI model is colored in red.

{{attachment:eegMegDipolesSagittal.jpg||height="300",width="600"}} {{attachment:eegMegDipolesAxial.jpg||height="300",width="600"}} {{attachment:eegMegDipolesCoronal.jpg||height="300",width="600"}}

In this experiment, the anisotropy does not show a significant effect on the source localization, whereas it shows a slight difference in the orientation.

=== Comparison: MEG vs EEG ===
When we compare between the EEG and the MEG, there is a difference of 20mm between the localization between the MEG and the EEG as well as a difference in the orientation in the coronal view.

If we compare the difference between the EEG and MEG dipoles, the following figures (left anisotropy, right isotropic), show the localization of the dipoles on the MRI at the 21ms. The EEG dipole is colored in green whereas the MEG dipole is colored in red.

{{attachment:eegMegDipolesSagittal2.jpg||height="300",width="600"}} {{attachment:eegMegDipolesAxial2.jpg||height="300",width="600"}} {{attachment:eegMegDipolesCoronal2.jpg||height="300",width="600"}}

Aniso: Eeg [-7.5 -35.7 89.8] vs Meg [-0.2 -33.6 88.6]  ==> '''distance = 7.7mm '''

Iso: Eeg [-7.5 -35.7 89.8] vs Meg [-0.2 -33.6 88.6]  ==> '''distance = 7.7mm '''

In both modalities, the dipoles are located exactly in the same positions, and there is 7.7mm between the two dipoles. Furthermore, we notice a difference on the orientation on the coronal and sagittal views

=== Comparison: FEM vs BEM/OS ===
We will now compare qualitatively the FEM results with the default methods implemented in Brainstorm: Overlapping spheres for MEG, BEM for EEG.

 * Right-click on the channel file > '''Compute head model''' > '''MEG: Overlapping spheres'''
 * Right-click on the channel file > '''Compute head model''' > '''EEG: OpenMEEG BEM'''
 * Repeat the same source localization procedure: '''Compute sources''' and '''Dipole scanning'''.

In the following figures, left is the dipoles computed from the EEG (BEM in red and FEM in green),  right are the dipoles computed from the MEG (OS in red and FEM in green)

{{attachment:eegMegDipolesSagittal3.jpg||height="300",width="600"}} {{attachment:eegMegDipolesAxial3.jpg||height="300",width="600"}} {{attachment:eegMegDipolesCoronal3.jpg||height="300",width="600"}}

EEG: fem [-7.5 -35.7 89.8] ; bem [-10.7 -35.0 89.5] ==> '''3.3mm'''

MEG: fem [-0.2 -33.6 88.6] ; os [-10.7 -39.3 83.2] ==>  '''13.1 mm'''

As expected, the slight difference on the localization can be explained by the difference on the head shape, the conductivity values as well as the resolution method.

<<TAG(Advanced)>>

== Additional documentation ==
==== Related tutorials ====
 * [[https://neuroimage.usc.edu/brainstorm/Tutorials/Duneuro|Realistic head model: FEM with DUNEuro]]
 * [[https://neuroimage.usc.edu/brainstorm/Tutorials/FemMesh|FEM mesh generation]]
 * [[https://neuroimage.usc.edu/brainstorm/Tutorials/FemTensors|FEM tensors estimation]]

==== Articles ====
 * Medani T, Garcia-Prieto J, Tadel F, Schrader S, Joshi A, Engwer C, Wolters CH, Mosher JC, Leahy RM, [[https://www.spiedigitallibrary.org/conference-proceedings-of-spie/11595/1159554/Realistic-head-modeling-of-electromagnetic-brain-activity--an-integrated/10.1117/12.2580935.short?SSO=1|Realistic head modeling of electromagnetic brain activity: An integrated Brainstorm pipeline from MRI data to the FEM solution]] ([[http://arxiv.org/abs/2011.01292|preprint]]), '''SPIE Medical Imaging''', Feb 2021
-Line 131:
+Line 329:
+The following script from the Brainstorm distribution reproduces the analysis presented in this tutorial page: [[https://github.com/brainstorm-tools/brainstorm3/blob/master/toolbox/script/tutorial_fem_headreco.m|brainstorm3/toolbox/script/tutorial_fem_headreco.m]]

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