5727
Comment:
|
21050
|
Deletions are marked like this. | Additions are marked like this. |
Line 2: | Line 2: |
''Authors: Francois Tadel, Elizabeth Bock, Robert Oostenveld.<<BR>>'' The aim of this tutorial is to provide high-quality recordings of a simple auditory stimulation and illustrate the best possible analysis paths with Brainstorm and !FieldTrip. This page presents the workflow in the Brainstorm environment, the equivalent documentation for the !FieldTrip environment is available on the [[http://fieldtrip.fcdonders.nl/|!FieldTrip website]]. <<TableOfContents(2,2)>> |
==== [TUTORIAL UNDER DEVELOPMENT: NOT READY FOR PUBLIC USE] ==== ''Authors: Francois Tadel, Elizabeth Bock, Robert Oostenveld.'' The aim of this tutorial is to provide high-quality recordings of a simple auditory stimulation and illustrate the best analysis paths possible with Brainstorm and !FieldTrip. This page presents the workflow in the Brainstorm environment, the equivalent documentation for the !FieldTrip environment will be available on the [[http://fieldtrip.fcdonders.nl/|FieldTrip website]]. Note that the operations used here are not detailed, the goal of this tutorial is not to teach Brainstorm to a new inexperienced user. For in depth explanations of the interface and the theory, please refer to the 12+3 introduction tutorials. <<TableOfContents(3,2)>> |
Line 9: | Line 12: |
This tutorial dataset (EEG and MRI data) remains a property of the MEG Lab, McConnell Brain Imaging Center, Montreal Neurological Institute, McGill University, Canada. Its use and transfer outside the Brainstorm tutorial, e.g. for research purposes, is prohibited without written consent from the MEG Lab. If you reference this dataset in your publications, please aknowledge its authors (Elizabeth Bock, Peter Donhauser, Francois Tadel and Sylvain Baillet) and cite Brainstorm as indicated on the [[http://neuroimage.usc.edu/brainstorm/CiteBrainstorm|website]]. For questions, please contact us through the forum. |
This tutorial dataset (MEG and MRI data) remains a property of the MEG Lab, !McConnell Brain Imaging Center, Montreal Neurological Institute, !McGill University, Canada. Its use and transfer outside the Brainstorm tutorial, e.g. for research purposes, is prohibited without written consent from the MEG Lab. If you reference this dataset in your publications, please aknowledge its authors (Elizabeth Bock, Peter Donhauser, Francois Tadel and Sylvain Baillet) and cite Brainstorm as indicated on the [[CiteBrainstorm|website]]. For questions, please contact us through the forum. |
Line 15: | Line 18: |
* 1 acquisition run = 200 regular beeps + 40 easy deviant beeps | * One subject, two acquisition runs of 6 minutes each * Subject stimulated binaurally with intra-aural earphones (air tubes+transducers) * Each run contains: * 200 regular beeps (440Hz) * 40 easy deviant beeps (554.4Hz, 4 semitones higher) |
Line 18: | Line 25: |
* We would record three runs (each of them is ~5min long), asking the subject to move a bit between the runs (not too much), if we want to test later some sensor-level co-registration algorithms. * Auditory stim generated with the Matlab Psychophysics Toolbox * Only one subject |
* Auditory stimuli generated with the Matlab Psychophysics toolbox |
Line 23: | Line 28: |
* Acquisition at 2400Hz, with a CTF 275 system at the MNI, subject in seating position * Online 300Hz low-pass filter, files saved with the 3rd order gradient * Recorded Channels: * 2 runs: => To test registration algorithms * run1 - marked a few trials bad => Use for the main example * run2 - saccades, see component screenshot, they are not really detected well with the auto detection => To illustrate how to remove saccades. External file of marked saccades * Noise recordings: 30s |
* Acquisition at '''2400Hz''', with a '''CTF 275''' system at the MNI, subject in seating position * Online 600Hz low-pass filter, files saved with the 3rd order gradient * Recorded channels (340): * 1 Stim channel indicating the presentation times of the audio stimuli: UDIO001 (#1) * 1 Response channel recordings the finger taps in resonse to the deviants: UPPT001 (#2) * 26 MEG reference sensors (#5-#30) * 274 MEG axial gradiometers (#31-#304) * 2 EEG electrodes: Cz, Pz (#305 and #306) * 1 ECG bipolar (#307) * 2 EOG bipolar (vertical #308, horizontal #309) * 1 Audio signal sent to the subject: UADC001 (#316) * 12 Head tracking channels: Nasion XYZ, Left XYZ, Right XYZ, Error N/L/R (#317-#328) * 20 Unused channels (#3, #4, #310-#315, #329-340) * 3 datasets: * '''S01_AEF_20131218_01.ds''': Run #1, 360s, 200 standard + 41 deviants * '''S01_AEF_20131218_02.ds''': Run #2, 360s, 202 standard + 40 deviants * '''S01_Noise_20131218_01.ds''': Empty room recordings, 30s long * File name: S01=Subject01, AEF=Auditory evoked field, 20131218=date(Dec 18 2013), 01=run |
Line 33: | Line 49: |
* 3D digitization using a Polhemus Fastrak device driven by Brainstorm (http://neuroimage.usc.edu/brainstorm/Tutorials/TutDigitize) | * 3D digitization using a Polhemus Fastrak device driven by Brainstorm ('''S01_20131218_*.pos''')<<BR>>More information: [[Tutorials/TutDigitize|Digitize EEG electrodes and head shape]] |
Line 35: | Line 51: |
* - the position of the center of CTF coils * - the position of the anatomical references we use in Brainstorm (nasion and connections tragus/helix - the red point I placed on that ear image we have on both websites) |
* The position of the center of CTF coils * The position of the anatomical references we use in Brainstorm: <<BR>>Nasion and connections tragus/helix, as illustrated [[http://neuroimage.usc.edu/brainstorm/CoordinateSystems#Pre-auricular_points_.28LPA.2C_RPA.29|here]]. |
Line 45: | Line 61: |
* Requirements: You have already followed all the basic tutorials and you have a working copy of Brainstorm installed on your computer. | * '''Requirements''': You have already followed all the basic tutorials and you have a working copy of Brainstorm installed on your computer. |
Line 54: | Line 70: |
* Switch to the "anatomy" view. | |
Line 57: | Line 74: |
* Set the file format: "FreeSurfer folder" | * Set the file format: "!FreeSurfer folder" |
Line 61: | Line 78: |
* NAS: x=135, y=222, z=75 * LPA: x=57, y=118, z=68 * RPA: x=204, y=119, z=76 * AC: x=131, y=145, z=110 * PC: x=130, y=119, z=111 * IH: x=128, y=134, z=170 (anywhere on the midsagittal plane) |
* NAS: x=127, y=213, z=139 * LPA: x=52, y=113, z=96 * RPA: x=202, y=113, z=91 * AC: x=127, y=119, z=149 * PC: x=128, y=93, z=141 * IH: x=131, y=114, z=206 (anywhere on the midsagittal plane) |
Line 68: | Line 85: |
=> SCREEN CAPTURE ==== Without the individual MRI ==== If you do not have access to an individual MR scan of the subject (or if its quality is too low to be processed with FreeSurfer), but if you have digitized the head shape of the subject using a tracking system, you have an alternative: deform one of the Brainstorm templates (Colin27 or ICBM152) to match the shape of the subject's head. For more information, read the following tutorial: [[http://neuroimage.usc.edu/brainstorm/Tutorials/TutWarping|Warping default anatomy]] |
{{attachment:anatomy.gif||height="264",width="335"}} == Access the recordings == === Link the recordings === * Switch to the "functional data" view. * Right-click on the subject folder > Review raw file * Select the file format: "'''MEG/EEG: CTF (*.ds...)'''" * Select all the .ds folders in: '''sample_auditory/data''' {{attachment:raw1.gif||height="156",width="423"}} * Refine registration now? '''YES'''<<BR>><<BR>> {{attachment:raw2.gif||height="224",width="353"}} === Multiple runs and head position === * The two AEF runs 01 and 02 were acquired successively, the position of the subject's head in the MEG helmet was estimated twice, once at the beginning of each run. The subject might have moved between the two runs. To evaluate visually the displacement between the two runs, select at the same time all the channel files you want to compare (the ones for run 01 and 02), right-click > Display sensors > MEG.<<BR>><<BR>> {{attachment:raw3.gif||height="220",width="441"}} * Typically, we would like to group the trials coming from multiple runs by experimental conditions. However, because of the subject's movements between runs, it's not possible to directly compare the sensor values between runs because they probably do not capture the brain activity coming from the same regions of the brain. * You have three options if you consider grouping information from multiple runs: * Method 1: Process all the runs separately and average between runs at the source level: The more accurate option, but requires a lot more work, computation time and storage. * Method 2: Ignore movements between runs: This can be acceptable for commodity if the displacements are really minimal, less accurate but much faster to process and easier to manipulate. * Method 3: Co-register properly the runs using the process Standardize > Co-register MEG runs: Can be a good option for displacements under 2cm. Warning: This method has not be been fully evaluated on our side, to use at your own risk. * In this tutorial, we will illustrate only method 1: runs are not co-registered. === Epoched vs. continuous === * The CTF MEG system can save two types of files: epoched (.ds) or continuous (_AUX.ds). * Here we have an intermediate storage type: continuous recordings saved in an "epoched" file. The file is saved as small blocks of recordings of a constant time length (1 second in this case). All those time blocks are contiguous, there is no gap between them. * Brainstorm can consider this file either as a continuous or an epoched file. By default it imports the regular .ds folders as epoched, but we can change this manually, to process it as a continuous file. * Double-click on the "Link to raw file" for run 01 to view the MEG recordings. You can navigate in the file by blocks of 1s, and switch between blocks using the "Epoch" box in the Record tab. The events listed are relative to the current epoch.<<BR>><<BR>> {{attachment:raw4.gif||height="206",width="575"}} * Right-click on the "Link to raw file" for run 01 > '''Switch epoched/continuous''' * Double-click on the "Link to raw file" again. Now you can navigate in the file without interruptions. The box "Epoch" is disabled and all the events in the file are displayed at once.<<BR>><<BR>> {{attachment:raw5.gif||height="209",width="576"}} * Repeat this operation twice to convert all the files to a continuous mode. * '''Run 02''' > Switch epoched/continuous * '''Noise''' > Switch epoched/continuous == Detect and remove artifacts == === Spectral evaluation === * One of the typical pre-processing steps consist in getting rid of the contamination due to the power lines (50 Hz or 60Hz). Let's start with the spectral evaluation of this file. * Drag '''ALL''' the "Link to raw file" to the Process1 box, or easier, just drag the node "Subject01", it will select recursively all the files in it. * Run the process "'''Frequency > Power spectrum density (Welch)'''": * Time window: '''[0 - 50]s ''' * Window length: '''4s''' * Overlap: '''50%''' * Sensor types or names: '''MEG''' * Selected option "'''Save individual PSD values''' (for each trial)".<<BR>><<BR>> {{attachment:psd1.gif||height="326",width="507"}} * Double-click on the new PSD files to display them. <<BR>><<BR>> {{attachment:psd2.gif||height="175",width="417"}} * We can observe a series of peaks related with the power lines: '''60Hz, 120Hz, 180Hz '''<<BR>>(240Hz and 300Hz could be observed as well depending on the window length used for the PSD) * The drop after '''600Hz''' corresponds to the low-pass filter applied at the acquisition time. === Power line contamination === * Put '''ALL''' the "Link to raw file" into the Process1 box (or directly the Subject01 folder) * Run the process: '''Pre-process > Notch filter''' * Select the frequencies: '''60, 120, 180 Hz''' * Sensor types or names: '''MEG''' * The higher harmonics are too high to bother us in this analysis, plus they are not clearly visible in all the recordings. * In output, this process creates new .ds folders in the same folder as the original files, and links the new files to the database.<<BR>><<BR>> {{attachment:psd3.gif}} * Run again the PSD process "'''Frequency > Power spectrum density (Welch)'''" on those new files, with the same parameters, to evaluate the quality of the correction.<<BR>><<BR>> {{attachment:psd4.gif||height="265",width="493"}} * Double-click on the new PSD files to open them.<<BR>><<BR>> {{attachment:psd5.gif||height="177",width="416"}} * You can zoom in with the mouse wheel to observer what is happening around 60Hz.<<BR>><<BR>> {{attachment:psd6.gif||height="143",width="453"}} * To avoid the confusion later, delete the links to the original files: Select the folders containing the original unfiltered files and press the Delete key (or right-click > File > Delete).<<BR>><<BR>> {{attachment:psd7.gif||height="184",width="356"}} === Heartbeats and eye blinks === * Select the two AEF runs in the Process1 box. * Select successively the following processes, then click on [Run]: * '''Events > Detect heartbeats:''' Select channel '''ECG''', check "All file", event name "cardiac". * '''Events > Detect eye blinks:''' Select channel '''VEOG''', check "All file", event name "blink". * '''Events > Remove simultaneous''': Remove "'''cardiac'''", too close to "'''blink'''", delay '''250ms'''. * '''Compute SSP: Heartbeats''': Event name "cardiac", sensor types="MEG", use existing SSP. * '''Compute SSP: Eyeblinks''': Event name "blink", sensor types="MEG", use existing SSP.<<BR>><<BR>> {{attachment:ssp_pipeline.gif||height="359",width="527"}} * Double-click on '''Run1 '''to open the MEG. * Review the '''EOG '''and '''ECG '''channels and make sure the events detected make sense.<<BR>><<BR>> {{attachment:events.gif||height="369",width="557"}} * In the Record tab, menu SSP > '''Select active projectors'''. * Blink: The first component is selected and looks good. * Cardiac: The category is disabled because no component has a value superior to 12%. * Select the first component of the cardiac category and display its topography. * It looks exactly like a cardiac topography, keep it selected and click on [Save].<<BR>><<BR>> {{attachment:ssp_result.gif||height="172",width="700"}} * Repeat the same operations for '''Run2''': * Review the events. * Select the first cardiac component. === Saccades [TODO] === Run2 contains a few saccades. The automatic detection is not working well. * Provide an external file of marked saccades to be loaded with this dataset. * Work on better algorithms for detecting saccades. {{attachment:beth_saccade.png||height="147",width="201"}} === Bad segments [TODO] === * Provide a list of bad segments * Describe the methodology to define those bad segments == Epoching and averaging == === Import recordings === To import epochs from Run1: * Right-click on the "Link to raw file" > '''Import in database''' * Use events: "'''standard'''" and "'''deviant'''" * Epoch time: '''[-100, +500] ms''' * Apply the existing SSP (make sure that you have 2 selected projectors) * '''Remove DC''' '''offset '''based on time window: '''[-100, 0] ms''' * '''UNCHECK''' the option "Create new conditions for epochs", this way all the epochs are going to be saved in the same Run1 folder, and we will able to separate the trials from Run1 and Run2.<<BR>><<BR>> {{attachment:import1.gif||height="344",width="521"}} * Repeat the same operation for '''Run2'''. === Average responses === * As said previously, it is usually not recommended to average recordings in sensor space across multiple acquisition runs because the subject might have moved between the sessions. Different head positions were recorded for each run, and we will reconstruct the sources separately for each each run to take into account those movements. * However, in the case of event-related studies it makes sense to start our data exploration with an average across runs, just to evaluate the quality of the evoked responses. We have seen that the subject almost didn't move between the two runs, so the error would be minimal. We will compute now an approximate sensor average between runs, and we will run a more formal average in source space later. * Drag and drop the two new folders in Process1, run process "'''Average > Average files'''"<<BR>>Select option "'''By trial group (subject average)'''"<<BR>><<BR>> {{attachment:process_average_data.gif||height="470",width="557"}} * The average for the two conditions "standard" and "deviant" are calculated separately and saved in the folder ''(intra-subject)''.<<BR>><<BR>>{attachment:average_sensor_files.gif} * Display the two averages, "standard" and "deviant": * Right-click on average > MEG > Display time series * Right-click on average > MISC > Display time series (EEG electrodes Cz and Pz) * Right-click on average > MEG > 2D Sensor cap * In the Filter tab, add a '''low-pass filter''' at '''150Hz'''. * Right-click on the 2D topography figures > Snapshot > Time contact sheet. * Here are results for the standard (top) and deviant (bottom) beeps:<<BR>><<BR>> {{attachment:average_sensor.gif||height="351",width="685"}} * '''P50''': Around 50-60ms, first response in auditory cortex. * '''N100''': Around 100ms, clear auditory response in MEG in both conditions. * '''P200''': Around 185ms, auditory response in both conditions. * '''P300''': Around 300ms, clear component in the EEG for the deviant condition. * Standard:<<BR>><<BR>>{attachment:average_sensor_standard.gif} * Deviant:<<BR>><<BR>>{attachment:average_sensor_deviant.gif} == Source estimation == === Head model === * Select the two imported folders at once, right-click > Compute head model<<BR>><<BR>>{attachment:headmodel1.gif} * Use the '''overlapping spheres''' model and keep all of the options at their default values.<<BR>><<BR>>{attachment:headmodel2.gif} {attachment:headmodel3.gif} * For more information: [[Tutorials/TutHeadModel|Head model tutorial]]. === Noise covariance matrix === * We want to calculate the noise covariance from the empty room measurements and use it for the other runs. * In the '''Noise''' folder, right-click on the Link to raw file > Noise covariance > Compute from recordings.<<BR>><<BR>>{attachment: noisecov1.gif} * Leave all the default options and click [OK]. <<BR>><<BR>>{attachment: noisecov2.gif} * Right-click on the noise covariance file > Copy to other conditions.<<BR>><<BR>>{attachment: noisecov3.gif} * You can double-click on one the copied noise covariance files to check what it looks like:<<BR>><<BR>>{attachment: noisecov4.gif} * For more information: [[Tutorials/TutNoiseCov|Noise covariance tutorial]]. === Inverse model === * Select the two imported folders at once, right-click > Compute sources<<BR>><<BR>>{attachment:inverse1.gif} * Select '''minimum norm estimate''' and keep all the default options.<<BR>><<BR>>{attachment:inverse2.gif} * One inverse operator is created in each condition, with one link per data file.<<BR>><<BR>>{attachment:inverse3.gif} * For more information: [[Tutorials/TutSourceEstimation|Source estimation tutorial]]. === Average in source space === * === Z-score noise normalization === * Select at least one source file from each run in the Process1 tab<<BR>>(make sure to select the [Process sources] on the left). * Run process "'''Standardize > Z-score (dynamic)'''": <<BR>>Baseline [-100, -0.4]ms, Use absolue values of source activations<<BR>><<BR>>{attachment:zscore1.gif} * It z-score with baseline [-100,0] sec, abs of sources ==== Regions of interest ==== Scouts over primary auditory cortex (A1) Standard: {{attachment:beth_standard_sources.png||height="357",width="530"}} Deviant: {{attachment:beth_deviant_sources.png||height="356",width="530"}} Deviant-standard: => Averaged the deviant runs from run1 and run2 (76 trials), then averaged 38 standard trials from run1 with 38 standard trials from run 2 (76 files), subtracted the standard from the deviant and computed sources and z-score. => ACC activity around 300ms - this indicates error detection. {{attachment:beth_deviant-standard_acc.png||height="185",width="454"}} == Time-frequency [TODO] == TF over scout 1, z-scored [-100,0] ms Interesting gamma in the deviant: {{attachment:beth_tf.png||height="328",width="224"}} == Coherence [TODO] == * Run1, sensor magnitude-square coherence 1xN * UADC001 vs. other sensors * Time window: [0,150]ms * Sensor types * Remove evoked response: NOT SELECTED * Maximum frequency resolution: 1Hz * Highest frequency of interest: 80Hz * Metric significativity: 0.05 * Concatenate input files: SELECTED * => Coh(0.6Hz,32win)<<BR>><<BR>> {{attachment:beth_coherence_sensor_process.png||height="369",width="292"}} * At 13Hz<<BR>><<BR>> {{attachment:beth_coherence_sensor_200trials_13Hz.png||height="191",width="341"}} * Run1, source magnitude-square coherence 1xN * 50 standard trials * Highest frequency of interest: 40Hz * Same other inputs<<BR>><<BR>> {{attachment:beth_coherence_source_settings_run2_0-150ms.png||height="408",width="262"}} * At 13Hz:<<BR>><<BR>> {{attachment:beth_coherence_source_50trials_[0,150]ms_13Hz.png|beth_coherence_source_50trials_[0,150]ms_13Hz.png|height="304",width="388"}} |
Line 78: | Line 281: |
== Scripting [TODO] == ==== Process selection ==== ==== Graphic edition ==== ==== Generate Matlab script ==== The operations described in this tutorial can be reproduced from a Matlab script, available in the Brainstorm distribution: '''brainstorm3/toolbox/script/tutorial_auditory.m ''' |
Brainstorm-FieldTrip auditory tutorial
[TUTORIAL UNDER DEVELOPMENT: NOT READY FOR PUBLIC USE]
Authors: Francois Tadel, Elizabeth Bock, Robert Oostenveld.
The aim of this tutorial is to provide high-quality recordings of a simple auditory stimulation and illustrate the best analysis paths possible with Brainstorm and FieldTrip. This page presents the workflow in the Brainstorm environment, the equivalent documentation for the FieldTrip environment will be available on the FieldTrip website.
Note that the operations used here are not detailed, the goal of this tutorial is not to teach Brainstorm to a new inexperienced user. For in depth explanations of the interface and the theory, please refer to the 12+3 introduction tutorials.
Contents
License
This tutorial dataset (MEG and MRI data) remains a property of the MEG Lab, McConnell Brain Imaging Center, Montreal Neurological Institute, McGill University, Canada. Its use and transfer outside the Brainstorm tutorial, e.g. for research purposes, is prohibited without written consent from the MEG Lab.
If you reference this dataset in your publications, please aknowledge its authors (Elizabeth Bock, Peter Donhauser, Francois Tadel and Sylvain Baillet) and cite Brainstorm as indicated on the website. For questions, please contact us through the forum.
Presentation of the experiment
Experiment
- One subject, two acquisition runs of 6 minutes each
- Subject stimulated binaurally with intra-aural earphones (air tubes+transducers)
- Each run contains:
- 200 regular beeps (440Hz)
- 40 easy deviant beeps (554.4Hz, 4 semitones higher)
- Random inter-stimulus interval: between 0.7s and 1.7s seconds, uniformly distributed
- The subject presses a button when detecting a deviant
- Auditory stimuli generated with the Matlab Psychophysics toolbox
MEG acquisition
Acquisition at 2400Hz, with a CTF 275 system at the MNI, subject in seating position
- Online 600Hz low-pass filter, files saved with the 3rd order gradient
- Recorded channels (340):
- 1 Stim channel indicating the presentation times of the audio stimuli: UDIO001 (#1)
- 1 Response channel recordings the finger taps in resonse to the deviants: UPPT001 (#2)
- 26 MEG reference sensors (#5-#30)
- 274 MEG axial gradiometers (#31-#304)
- 2 EEG electrodes: Cz, Pz (#305 and #306)
- 1 ECG bipolar (#307)
- 2 EOG bipolar (vertical #308, horizontal #309)
- 1 Audio signal sent to the subject: UADC001 (#316)
- 12 Head tracking channels: Nasion XYZ, Left XYZ, Right XYZ, Error N/L/R (#317-#328)
- 20 Unused channels (#3, #4, #310-#315, #329-340)
- 3 datasets:
S01_AEF_20131218_01.ds: Run #1, 360s, 200 standard + 41 deviants
S01_AEF_20131218_02.ds: Run #2, 360s, 202 standard + 40 deviants
S01_Noise_20131218_01.ds: Empty room recordings, 30s long
- File name: S01=Subject01, AEF=Auditory evoked field, 20131218=date(Dec 18 2013), 01=run
Use of the .ds, not the AUX (standard at the MNI) because they are easier to manipulate in FieldTrip
Head shape and fiducial points
3D digitization using a Polhemus Fastrak device driven by Brainstorm (S01_20131218_*.pos)
More information: Digitize EEG electrodes and head shape- The output file is copied to each .ds folder and contains the following entries:
- The position of the center of CTF coils
The position of the anatomical references we use in Brainstorm:
Nasion and connections tragus/helix, as illustrated here.
- Around 150 head points distributed on the hard parts of the head (no soft tissues)
Subject anatomy
- Subject with 1.5T MRI
- Marker on the left cheek
Processed with FreeSurfer 5.3
Download and installation
Requirements: You have already followed all the basic tutorials and you have a working copy of Brainstorm installed on your computer.
Go to the Download page of this website, and download the file: sample_auditory.zip
- Unzip it in a folder that is not in any of the Brainstorm folders (program folder or database folder). This is really important that you always keep your original data files in a separate folder: the program folder can be deleted when updating the software, and the contents of the database folder is supposed to be manipulated only by the program itself.
- Start Brainstorm (Matlab scripts or stand-alone version)
Select the menu File > Create new protocol. Name it "TutorialAuditory" and select the options:
"No, use individual anatomy",
"No, use one channel file per condition".
Import the anatomy
- Switch to the "anatomy" view.
Right-click on the TutorialAuditory 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"
Select the folder: sample_auditory/anatomy
- Number of vertices of the cortex surface: 15000 (default value)
- Set the 6 required fiducial points (indicated in MRI coordinates):
- NAS: x=127, y=213, z=139
- LPA: x=52, y=113, z=96
- RPA: x=202, y=113, z=91
- AC: x=127, y=119, z=149
- PC: x=128, y=93, z=141
- IH: x=131, y=114, z=206 (anywhere on the midsagittal plane)
- At the end of the process, make sure that the file "cortex_15000V" is selected (downsampled pial surface, that will be used for the source estimation). If it is not, double-click on it to select it as the default cortex surface.
Access the recordings
Link the recordings
- Switch to the "functional data" view.
Right-click on the subject folder > Review raw file
Select the file format: "MEG/EEG: CTF (*.ds...)"
Select all the .ds folders in: sample_auditory/data
Refine registration now? YES
Multiple runs and head position
The two AEF runs 01 and 02 were acquired successively, the position of the subject's head in the MEG helmet was estimated twice, once at the beginning of each run. The subject might have moved between the two runs. To evaluate visually the displacement between the two runs, select at the same time all the channel files you want to compare (the ones for run 01 and 02), right-click > Display sensors > MEG.
- Typically, we would like to group the trials coming from multiple runs by experimental conditions. However, because of the subject's movements between runs, it's not possible to directly compare the sensor values between runs because they probably do not capture the brain activity coming from the same regions of the brain.
- You have three options if you consider grouping information from multiple runs:
- Method 1: Process all the runs separately and average between runs at the source level: The more accurate option, but requires a lot more work, computation time and storage.
- Method 2: Ignore movements between runs: This can be acceptable for commodity if the displacements are really minimal, less accurate but much faster to process and easier to manipulate.
Method 3: Co-register properly the runs using the process Standardize > Co-register MEG runs: Can be a good option for displacements under 2cm. Warning: This method has not be been fully evaluated on our side, to use at your own risk.
- In this tutorial, we will illustrate only method 1: runs are not co-registered.
Epoched vs. continuous
- The CTF MEG system can save two types of files: epoched (.ds) or continuous (_AUX.ds).
- Here we have an intermediate storage type: continuous recordings saved in an "epoched" file. The file is saved as small blocks of recordings of a constant time length (1 second in this case). All those time blocks are contiguous, there is no gap between them.
- Brainstorm can consider this file either as a continuous or an epoched file. By default it imports the regular .ds folders as epoched, but we can change this manually, to process it as a continuous file.
Double-click on the "Link to raw file" for run 01 to view the MEG recordings. You can navigate in the file by blocks of 1s, and switch between blocks using the "Epoch" box in the Record tab. The events listed are relative to the current epoch.
Right-click on the "Link to raw file" for run 01 > Switch epoched/continuous
Double-click on the "Link to raw file" again. Now you can navigate in the file without interruptions. The box "Epoch" is disabled and all the events in the file are displayed at once.
- Repeat this operation twice to convert all the files to a continuous mode.
Run 02 > Switch epoched/continuous
Noise > Switch epoched/continuous
Detect and remove artifacts
Spectral evaluation
- One of the typical pre-processing steps consist in getting rid of the contamination due to the power lines (50 Hz or 60Hz). Let's start with the spectral evaluation of this file.
Drag ALL the "Link to raw file" to the Process1 box, or easier, just drag the node "Subject01", it will select recursively all the files in it.
Run the process "Frequency > Power spectrum density (Welch)":
Time window: [0 - 50]s
Window length: 4s
Overlap: 50%
Sensor types or names: MEG
Selected option "Save individual PSD values (for each trial)".
Double-click on the new PSD files to display them.
We can observe a series of peaks related with the power lines: 60Hz, 120Hz, 180Hz
(240Hz and 300Hz could be observed as well depending on the window length used for the PSD)The drop after 600Hz corresponds to the low-pass filter applied at the acquisition time.
Power line contamination
Put ALL the "Link to raw file" into the Process1 box (or directly the Subject01 folder)
Run the process: Pre-process > Notch filter
Select the frequencies: 60, 120, 180 Hz
Sensor types or names: MEG
- The higher harmonics are too high to bother us in this analysis, plus they are not clearly visible in all the recordings.
In output, this process creates new .ds folders in the same folder as the original files, and links the new files to the database.
Run again the PSD process "Frequency > Power spectrum density (Welch)" on those new files, with the same parameters, to evaluate the quality of the correction.
Double-click on the new PSD files to open them.
You can zoom in with the mouse wheel to observer what is happening around 60Hz.
To avoid the confusion later, delete the links to the original files: Select the folders containing the original unfiltered files and press the Delete key (or right-click > File > Delete).
Heartbeats and eye blinks
- Select the two AEF runs in the Process1 box.
- Select successively the following processes, then click on [Run]:
Events > Detect heartbeats: Select channel ECG, check "All file", event name "cardiac".
Events > Detect eye blinks: Select channel VEOG, check "All file", event name "blink".
Events > Remove simultaneous: Remove "cardiac", too close to "blink", delay 250ms.
Compute SSP: Heartbeats: Event name "cardiac", sensor types="MEG", use existing SSP.
Compute SSP: Eyeblinks: Event name "blink", sensor types="MEG", use existing SSP.
Double-click on Run1 to open the MEG.
Review the EOG and ECG channels and make sure the events detected make sense.
In the Record tab, menu SSP > Select active projectors.
- Blink: The first component is selected and looks good.
- Cardiac: The category is disabled because no component has a value superior to 12%.
- Select the first component of the cardiac category and display its topography.
It looks exactly like a cardiac topography, keep it selected and click on [Save].
Repeat the same operations for Run2:
- Review the events.
- Select the first cardiac component.
Saccades [TODO]
Run2 contains a few saccades. The automatic detection is not working well.
- Provide an external file of marked saccades to be loaded with this dataset.
- Work on better algorithms for detecting saccades.
Bad segments [TODO]
- Provide a list of bad segments
- Describe the methodology to define those bad segments
Epoching and averaging
Import recordings
To import epochs from Run1:
Right-click on the "Link to raw file" > Import in database
Use events: "standard" and "deviant"
Epoch time: [-100, +500] ms
- Apply the existing SSP (make sure that you have 2 selected projectors)
Remove DC offset based on time window: [-100, 0] ms
UNCHECK the option "Create new conditions for epochs", this way all the epochs are going to be saved in the same Run1 folder, and we will able to separate the trials from Run1 and Run2.
Repeat the same operation for Run2.
Average responses
- As said previously, it is usually not recommended to average recordings in sensor space across multiple acquisition runs because the subject might have moved between the sessions. Different head positions were recorded for each run, and we will reconstruct the sources separately for each each run to take into account those movements.
- However, in the case of event-related studies it makes sense to start our data exploration with an average across runs, just to evaluate the quality of the evoked responses. We have seen that the subject almost didn't move between the two runs, so the error would be minimal. We will compute now an approximate sensor average between runs, and we will run a more formal average in source space later.
Drag and drop the two new folders in Process1, run process "Average > Average files"
Select option "By trial group (subject average)"
The average for the two conditions "standard" and "deviant" are calculated separately and saved in the folder (intra-subject).
{attachment:average_sensor_files.gif}- Display the two averages, "standard" and "deviant":
Right-click on average > MEG > Display time series
Right-click on average > MISC > Display time series (EEG electrodes Cz and Pz)
Right-click on average > MEG > 2D Sensor cap
In the Filter tab, add a low-pass filter at 150Hz.
Right-click on the 2D topography figures > Snapshot > Time contact sheet.
Here are results for the standard (top) and deviant (bottom) beeps:
P50: Around 50-60ms, first response in auditory cortex.
N100: Around 100ms, clear auditory response in MEG in both conditions.
P200: Around 185ms, auditory response in both conditions.
P300: Around 300ms, clear component in the EEG for the deviant condition.
Standard:<<BR>><<BR>>{attachment:average_sensor_standard.gif}
Deviant:<<BR>><<BR>>{attachment:average_sensor_deviant.gif}
Source estimation
Head model
Select the two imported folders at once, right-click > Compute head model
{attachment:headmodel1.gif}Use the overlapping spheres model and keep all of the options at their default values.
{attachment:headmodel2.gif} {attachment:headmodel3.gif}For more information: ?Head model tutorial.
Noise covariance matrix
- We want to calculate the noise covariance from the empty room measurements and use it for the other runs.
In the Noise folder, right-click on the Link to raw file > Noise covariance > Compute from recordings.
{attachment: noisecov1.gif}Leave all the default options and click [OK].
{attachment: noisecov2.gif}Right-click on the noise covariance file > Copy to other conditions.
{attachment: noisecov3.gif}You can double-click on one the copied noise covariance files to check what it looks like:
{attachment: noisecov4.gif}For more information: ?Noise covariance tutorial.
Inverse model
Select the two imported folders at once, right-click > Compute sources
{attachment:inverse1.gif}Select minimum norm estimate and keep all the default options.
{attachment:inverse2.gif}One inverse operator is created in each condition, with one link per data file.
{attachment:inverse3.gif}For more information: ?Source estimation tutorial.
Average in source space
Z-score noise normalization
Select at least one source file from each run in the Process1 tab
(make sure to select the [Process sources] on the left).Run process "Standardize > Z-score (dynamic)":
Baseline [-100, -0.4]ms, Use absolue values of source activations
{attachment:zscore1.gif}- It
z-score with baseline [-100,0] sec, abs of sources
Regions of interest
Scouts over primary auditory cortex (A1)
Standard:
Deviant:
Deviant-standard:
=> Averaged the deviant runs from run1 and run2 (76 trials), then averaged 38 standard trials from run1 with 38 standard trials from run 2 (76 files), subtracted the standard from the deviant and computed sources and z-score.
=> ACC activity around 300ms - this indicates error detection.
Time-frequency [TODO]
TF over scout 1, z-scored [-100,0] ms
Interesting gamma in the deviant:
Coherence [TODO]
- Run1, sensor magnitude-square coherence 1xN
- UADC001 vs. other sensors
- Time window: [0,150]ms
- Sensor types
- Remove evoked response: NOT SELECTED
- Maximum frequency resolution: 1Hz
- Highest frequency of interest: 80Hz
- Metric significativity: 0.05
- Concatenate input files: SELECTED
=> Coh(0.6Hz,32win)
At 13Hz
- Run1, source magnitude-square coherence 1xN
- 50 standard trials
- Highest frequency of interest: 40Hz
Same other inputs
At 13Hz:
Discussion
Discussion about the choice of the dataset on the FieldTrip bug tracker:
http://bugzilla.fcdonders.nl/show_bug.cgi?id=2300
Scripting [TODO]
Process selection
Graphic edition
Generate Matlab script
The operations described in this tutorial can be reproduced from a Matlab script, available in the Brainstorm distribution: brainstorm3/toolbox/script/tutorial_auditory.m
Feedback