DTI Tutorial 2 - Normalization and Statistics

Tuesday, October 13, 2015 Do Tromp 0 Comments



In our first tutorial we processed our raw images and calculated tensor images. In this second tutorial we will address how to normalize a set of diffusion tensor images (DTI) and then run statistics on the normalized brain images. First it is important to understand why you have to normalize brain images; lets see what Wikipedia has to say about spatial normalization:

"In neuroimaging, spatial normalization is an image processing step, more specifically an image registration method. Human brains differ in size and shape, and one goal of spatial normalization is to deform human brain scans so one location in one subject's brain scan corresponds to the same location in another subject's brain scan." - Wikipedia
As you see, inter-individual statistics will only be effective when brain images are in the same space, and spatial normalization can take care of that. An important distinction between diffusion tensor imaging and other imaging modality (like T1 anatomicals or fMRI scans), is that DTI allows for a more sophisticated normalization. Where T1 and fMRI scans are normalized based on intensity scales, diffusion tensor images instead offer the ability to register tensors, that have both length and direction. The property thus allows for a better capability to register white matter structures that have highly anisotropic tensors. In this video the developer of a publicly available tensor based normalization toolbox, Gary Zhang, discusses why tensor-based normalization can be better than other normalization methods, what statistical analyses you can run after normalization, and the difference between tract based spatial statistics (TBSS) and tract specific analysis (TSA). The below image details some of the advantages. For example in the area's with the yellow circles, you see areas of the brain where T1 anatomicals would have a hard time effectively registering inter-subjects anatomy for different white matter tracts, because the contrast in that region is equal despite it including multiple tracts with different orientation. Using the tensor information as show on the right will help discriminate between those regions, and allow for a more advanced registration between subjects.
Advantage of tensor specific normalization. Image by DTI-TK
In this tutorial there will be a number of steps that we have to run through in order to test statistical models, these steps are detailed below:
   1. Make sure the tensor files are in the right format for tensor normalization.
   2. Make population template by normalizing tensor images
   3. Register population template to MNI space
   4. Produce scalar images (FA, MD, AD, RD) and check quality
   5. Run whole brain voxel-wise statistics
   6. Share your data.

You can look through slides that go into some of the background of this tutorial here. Throughout the tutorial there will be questions to help with a better understanding of each of the steps and introduce you to the software that is being used. This might require installing said software and downloading example data from my website. At the end of the document you will find a pdf with the answers to the questions in this tutorial, although try to figure things out yourself as much as possible. If you run into issues going through this tutorial please direct your questions to the diffusion imaging forum, where there will likely be someone able to help you out. Please make sure to describe your question as clearly as possible. Remember to please direct software specific questions to their own respective forums or mail lists.

1. Standardize Tensor Images for Normalization

To get the tensor images ready for normalization we will have to make sure that tensors:
   - have the right diffusivity unit,
   - remove extreme outliers,
   - and are symmetric and positive-definite.
These steps are described in detail on the website of DTI-TK; which is the website of the software package that we will use for the tensor normalization. 

Example code:
i=052212_s09_dti_eddy_fm_strip_dt.nii
prefix=052212_s09_dti_eddy_fm_strip
echo ~~~Adjusting Diffusivity Units~~~
TVtool -in $i -scale 1000000000 -out ${prefix}_sdt.nii.gz
echo ~~Checking for and removing Outliers~~
TVtool -in ${prefix}_sdt.nii.gz -norm
SVtool -in ${prefix}_sdt_norm.nii.gz -stats
BinaryThresholdImageFilter ${prefix}_sdt_norm.nii.gz ${prefix}_non_outliers.nii.gz 0 100 1 0
TVtool -in ${prefix}_sdt.nii.gz -mask ${prefix}_non_outliers.nii.gz -out ${prefix}_tmp.nii.gz
mv -f ${prefix}_tmp.nii.gz ${prefix}_sdt.nii.gz
TVtool -in ${prefix}_sdt.nii.gz -norm
echo ~Stats for${prefix} - max should be below 100~
SVtool -in ${prefix}_sdt_norm.nii.gz -stats
echo ~~~Enforcing positive semi-definiteness~~~
TVtool -in ${prefix}_sdt.nii.gz -spd -out ${prefix}_tmp.nii.gz
mv -f ${prefix}_tmp.nii.gz ${prefix}_sdt.nii.gz
echo ~~~Standardizing Voxel Space~~~
TVAdjustVoxelspace -in ${prefix}_sdt.nii.gz -origin 0 0 0 -out ${prefix}_sdt.nii.gz
echo ~~~Resample to isotropic voxels~~~
TVResample -in ${prefix}_sdt.nii.gz -align center -size 256 256 128 -vsize 1 1 1
rm -f ${prefix}_tmp.nii.gz
rm -f ${prefix}_non_outliers.nii.gz
rm -f ${prefix}_sdt_nonSPD.nii.gz
rm -f ${prefix}_sdt_norm.nii.gz
Q1: Go through the DTI-TK preprocessing tutorial, indicate which lines of the above code correspond to which steps in the outline. What is the goal of each step? When you use this code make sure you use the right diffusivity units, the code above is just an example, find out how to convert your own here.

This code uses a number of new tools. One of which will be of interest to take a closer look at.

TVtool by DTI-TK (download here)
http://dti-tk.sourceforge.net/pmwiki/pmwiki.php?n=Documentation.TVtool

Q2: Using TVtool investigate how and then write the code to produce the axial diffusivity (AD) map from the standardized tensor file (download 052212_s09_dti_eddy_fm_strip_sdt.nii.gz here). What other maps can that tool help produce?

 Q3: What are the 4 main diffusion measurements that are often used in DTI? Take a look at the explanation on this page, and describe which measure you would pick if you were selectively interested in white matter?

Additional online resources:

- More info on how to calculate the diffusion tensor here
- Articles demonstrating improved registration when using DTI-TK here and here

2. Normalize Tensors Images

In the next step we will take the standardized tensor images for each individual subject and run a multi-step normalization. The steps of the normalization are detailed on the DTI-TK website, but essentially consists of four steps:
   1. Make initial mean
   2. Run a rigid registration
   3. Run an affine registration
   4. Run a diffeomorphic registration.
Each normalization step iteratively moves each individual image closer to the population mean. As described by DTI-TK:

"Rigid alignment aims to find a rigid transformation, a linear transformation that does not alter objects size and shape, that best aligns two objects in question. (...) Affine alignment improves upon rigid alignment by finding a more general linear transformation that allows objects' global size and shape to be altered. (...) After you've aligned your DTI volumes affinely, you can proceed with the deformable alignment, which is designed to improve alignment quality by removing size or shape differences between local structures." - DTI-TK
The below figure shows how the steps are applied and combined.

Iterative normalization process. Image by DTI-TK
This process starts by averaging all the individual tensor images to create a starting point template, a population template that has yet to be normalized, the example FA from these tensor images may look something like this:
Example of un-normalized average FA of population of images
Then as a next step each individual gets registered to this new population template iteratively. This process consists of rigid, affine and diffeomorphic registrations. A rigid-body transformation in three dimensions (x, y and z) is defined by six parameters: three translations and three rotations (source).
Affine includes 12 parameter transformation: 3 rotations, 3 translations, 3 sheers, 3 zooms
These transformations are a subset of the 12 transformations allowed in an affine registration of a three dimensional volume, which besides the rotation and translation also includes three sheers, and three zooms. Although affine registrations still have the constraint that parallel lines remain parallel after registration, thus it is contained to a linear registration. Or as wiki puts it:
"In geometry, an affine transformation, affine map or an affinity (from the Latin, affinis, "connected with") is a function between affine spaces which preserves points, straight lines and planes. Also, sets of parallel lines remain parallel after an affine transformation. An affine transformation does not necessarily preserve angles between lines or distances between points, though it does preserve ratios of distances between points lying on a straight line." - Wikipedia
Finally the diffeomorphic or deformable registration removes those constraints too and allows for a non-linear higher dimension registration, as long as it is invertible.
Examples of diffeomorphic transformations
Example script: 
echo ~~~Create an initial mean~~~;
for spd in `ls *sdt.nii.gz`;
do
subj_list_file=subj_list;
echo $spd >> subj_list_file.txt;
done
TVMean -in $subj_list_file.txt -out mean_initial.nii.gz;
TVResample -in mean_initial.nii.gz -vsize 1 1 1 -size 256 256 128;
echo ~~~Rigid alignment with initial mean~~~;
sh dti_rigid_population mean_initial.nii.gz ${subj_list_file}.txt EDS 3;
echo ~~~Affine alignment with output from rigid alignment~~~;
sh dti_affine_population mean_rigid3.nii.gz ${subj_list_file}.txt EDS 3;
echo ~~~Diffeomorphic alignment with output from affine alignment~~~;
TVtool -tr -in mean_affine3.nii.gz;
BinaryThresholdImageFilter mean_affine3_tr.nii.gz mask.nii.gz 0 .01 100 1 0;
sh dti_diffeomorphic_population mean_affine3.nii.gz ${subj_list_file}_aff.txt mask.nii.gz 0.002

Q4: Which step do you think will take the most time to run? Note the step where you resample your image to have isotropic voxel size, which line is this? Read this post on the importance, explain why we need isotropic voxels for fiber tracking. Resampling also alters the image dimensions, when you change those, you can read here that DTI-TK needs your image dimensions to be powers of 2. What are most likely often used powers of 2 in neuroimaging volume dimensions?

Additional online resources:

- Courses on fMRI spatial normalization by Wellcome Trust centre here and here
- Courses on fMRI spatial normalization by SPM here
- Advanced normalization tools (ANTS) for normalization of scalar images
- Background documentation on normalization by ANTS
- Further documentation from DTI-TK on tensor normalization 

3. Register population template to MNI-atlas

Below you can see the result of the population mean post-normalization. At this stage you are at a cross-roads of options how to analyze the results. The following steps are but one way, as you get more comfortable with analyses, software and scripting you can try to explore other options.
Example of normalized average FA of population of images
After normalization you can register your population template to MNI space. For this step you can for example use one of the provided atlases in FSL, like the ICBM152, which is an average of 152 T1-weighted MRI scans, linearly and non-linearly (6 iterations) transformed to form a symmetric model (source). The template is shown below.
MNI ICBM152 non-linear 6th generation. Image by FSL.
Registration software is notoriously bad at aligning images across modalities (like registering FA to T1). In this case, after many trial and errors, I have found that using asvDSM from DTI-TK has been best able to register FA files to T1 space, as you can see in the image below.
Template FA (red) after registration to MNI space (gray-scale)
asvDSM by DTI-TK

Example script:
echo ~~~Register population template to MNI~~~
TVtool -in ${population_tensor_mean} -tr -out my_tr.nii.gz 
BinaryThresholdImageFilter my_tr.nii.gz my_mask.nii.gz 0.7 100 1 0
TVtool -in ${population_tensor_mean} -mask my_mask.nii.gz -out ${population_tensor_mean}_strip.nii.gz
TVtool -in ${population_tensor_mean}_strip.nii.gz -fa -out ${population_tensor_mean}_strip_fa.nii.gz 
asvDSM -template ${MNI_T1} -subject ${population_tensor_mean}_strip_fa.nii.gz -outTrans ${dtiToT1Trans} -sep 0.5 0.5 0.5 -ftol 0.0001
echo ~~~Run subject specific loop to warp to T1~~~ 
for i in `cat subjects.txt`;
do
echo ~Compose full warp and apply~
dfRightComposeAffine -aff ${subj}_affineTrans -df ${subj}_diffeoTrans -out ${subj}_combined.df.nii.gz
echo ~Combine full warp with affine to T1 and apply~
dfLeftComposeAffine -df ${subj}_combined.df.nii.gz -aff ${dtiToT1Trans} -out ${subj}_toT1_combined.df.nii.gz
deformationSymTensor3DVolume -in ${subj}_orig -trans ${subj}_toT1_combined.df.nii.gz -target ${T1} -out ${subj}_tensorFile
done
Q5: Open fslview, click "File" -> "Open standard". In this directory and in the directory atlases you can browse all the different atlases that are automatically loaded with FSL. You can also find the atlas images in your installed FSL directory. Find the MNI template that you would like to use for registration. What is the name of that file? Give 1 reason why you would want to register your data to this template.

Additional online resources:

- More on the available atlases in FSL
- More on the atlases by MNI
- White matter atlas by Hermoye et al.
- International consortium of brain mapping (ICBM) DTI-81 atlas
- Cortical association tracts by Mori et al. (2002)
- Fiber tract based atlas of human white matter by Wakana et al. (2004)
- A diffusion tensor tractography atlas by Catani & De Schotten (2008)
- More online atlases by JHU

4. Make scalars and check quality

As a next step we will make diffusion maps (FA, MD, AD, RD) of each individual in template space. These diffusion maps are also known as scalar images; they have magnitude but not direction. When you have those images you can go through them and get an impression of the quality of the normalization and your data. One way of quickly viewing all your images is by concatenating them into one 4 dimensional image using fslmerge.

fslmerge by FSL
http://fsl.fmrib.ox.ac.uk/fsl/fslwiki/Fslutils

Movie of normalized FA images
Example script:
echo ~~~Produce subject specific smoothed scalars~~~ 
for subj in `cat subjects.txt`;
do
echo ~Produce diffusion maps~
TVtool -in ${subj}_tensorFile.nii.gz -fa -out ${subj}_fa.nii.gz
TVtool -in ${subj}_tensorFile.nii.gz -tr -out ${subj}_tr.nii.gz
TVtool -in ${subj}_tensorFile.nii.gz -ad -out ${subj}_ad.nii.gz
TVtool -in ${subj}_tensorFile.nii.gz -rd -out ${subj}_rd.nii.gz
echo ~Smooth diffusion maps~
SVGaussianSmoothing -in ${subj}_fa.nii.gz -fwhm  4 4 4 -out ${subj}_fa4mm.nii.gz
SVGaussianSmoothing -in ${subj}_tr.nii.gz -fwhm  4 4 4 -out ${subj}_tr4mm.nii.gz
SVGaussianSmoothing -in ${subj}_ad.nii.gz -fwhm  4 4 4 -out ${subj}_ad4mm.nii.gz
SVGaussianSmoothing -in ${subj}_rd.nii.gz -fwhm  4 4 4 -out ${subj}_rd4mm.nii.gz
done
echo ~~~Merge FA images for quality control~~~
fslmerge -t all_images_MNI_FA *_fa.nii.gz
Q6: Some of the code in this tutorial uses a "for loop" for the first time. Take a look at a tutorial on loops here. Try to figure out how "for loops" work, then describe what you would put in the subjects.txt file from line 2. HINT: Remember how variables work in bash. Another option is to run the below code, instead of line 2 and 3. Can you describe what this would do? 
for i in `ls *_diffeo_fa.nii.gz`;
do
subj=`echo $i | awk 'BEGIN{FS="_diffeo_fa.nii.gz"}{print $1}'`
Q7: Note that DTI-TK outputs the trace (TR) instead of the MD value. Look up how trace relates to MD here, and write the fslmaths code to convert TR to MD. If you are unsure how to do this, type fslmaths in your command line to see all the help options. 

 Q8: Next describe what lines 10-13 accomplish, if you are unsure read this documentation on spatial smoothing. Finally in line 16 we merge all the individual FA images, describe why you might want to do that.

Additional online resources:

- More info on smoothing your data
- How to convert FWHM to sigma

5. Run whole brain voxel-wise statistics

Now that we have scalar images in normalized space for each individual we can run voxel-wise analyses. There is a plethora of tools that you can use to run your preferred statistical model. A method that is often used in diffusion imaging is tract-based spatial statistics (TBSS) by FSL. Although this method has become the somewhat accidental standard, it has recently come under some scrutiny. Bach et al. (2014) describe some important methodological considerations for using TBSS.  And Swartz et al. (2014) describe how TBSS's skeleton projection step actually reduces algorithm accuracy. This is due to developments in registration tools (e.g. tensor normalization with DTI-TK, and improved algorithms of advanced normalization tools [ANTS]), which has made the methods used in TBSS obsolete. Furthermore, there is the possibility that you miss subtle effects that are in one of the smaller tracts, that may get removed when the data is skeletonized.
Example of tract-based spatial statistics. Image by FSL
Due to these issues, I have a preference for running whole brain voxel-wise analyses. In this case I decided to use FSL's randomise, since it is free and does not depend on software that has to run in MatLab (like SPM and SurfStat). Randomise runs a non-parametric test, which means that it makes no assumptions about the underlying normality of the data, which is a more robust test than ordinary GLM's. If you read the randomise documentation you will also see that you can include covariates like age and sex. Which are important variables to include in anatomical studies.

randomise by FSL
http://fsl.fmrib.ox.ac.uk/fsl/fslwiki/Randomise/UserGuide

Example code:
randomise -i all_merge_fa.nii.gz -o randomise_out -d test.mat -t test.con -m my_mask.nii.gz -T

Q9: Look at the user guide for randomise, and try to get an impression of what the .mat file and .con file contain. Produce an example of both for the imaginary case that you have a patient group (n=3) and healthy control group (n=3), and you want to test where FA is significantly lower in the patient group, and where FA is significantly lower in the control group. What does the option -T stand for in randomise?

 Q10: Open fslview and open a standard 1mm MNI T1 image. Download example t-stat map (test_tstat1.nii.gz here), and add it to the MNI image. What you see is not yet very informative, click on the information dialog button (i in blue circle) and change the Lookup table options. Make the first Red-Yellow, and turn the second one on, and make it Blue-Lightblue. Close the dialog screen. Go to this p-value calculator, and input in the t-ratio boxes that you want a probability that is 0.05 and you have 5 degrees of freedom (number of subjects - 1). What is your 2-tailed significant t-statistic? Input that number in the fslview screen as a minimum brightness value, and make 5 your maximum brightness value. Although this is obviously just test data, you now see what a noisy (when you only test 6 subjects you will most likely only find noise) t-stat map can look like. It is now up to you to start using your own data and improve on this! Remember to correct for multiple comparison when running your data to avoid inflated false discovery rates. You are running a t-tests on each individual voxel, which combine to multiple thousands per brain, and you will have to correct for this. Read more about familywise error rates here. What does the -T option do to help with this issue? HINT: Read this .pdf on the background of threshold-free cluster enhancement (TFCE).

Additional online resources:

- YouTube channel on analysis of neuroimaging data by Jeanette Mumford- Tutorial on including voxel-wise covariates using SurfStat
- Stanford university information on voxel-wise tensor statistics and whole brain diffusion stats
- Wikipedia on false discovery rate (FDR)
- Lecture on Multiple comparison issues from Columbia University
- Genovese et al. (2002) on FDR for neuroimaging
- Brainvoyager software on multiple comparison correction and FDR
- More info on thresholding by the late Keith Worthsley, and the seminal publication on significance testing in MRI by Worthsley et al. (1996)

6. Share your data

When you are done with your analyses and want to share your statistical maps publicly, you can use NeuroVault. Sharing your statistical maps will help improve meta analyses, collaborations and science in general.
Upload your unthresholded statistical map here, and share your URL in your publication

Answers:

DTI Tutorial 2 Answers

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Reference this post as: Do Tromp, DTI Tutorial 2 - Normalization and Statistics, The Winnower 3:e145653.31599 (2016). DOI: 10.15200/winn.145653.31599

The diffusion tensor, and its relation to FA, MD, AD and RD

Thursday, October 08, 2015 Do Tromp 0 Comments


In DTI 101 we described how diffusion tensor imaging estimates brain microstructure by modeling diffusion of water in the brain. We briefly discuss that this is done by using ellipsoid or ball shaped tensors. This leads to the question; what is a tensor? 

"Tensors are simply mathematical objects that can be used to describe physical properties, just like scalars and vectors." - University of Cambridge
Or, more specifically as described by Kahn Academy:

In the scanner the diffusion tensor is measured by imaging the diffusion in individual gradient directions, like in the image below. If you are interested a more in depth mathematical explanation of this principle is provided in our post here.

Example work out for 6 gradient directions, from diffusion image to tensor
Once the water diffusion is measured there are a number of ways you can quantify the shape of the tensors in each voxel. In DTI there are 4 measures that are most commonly used; fractional anisotropy, mean diffusivity, axial diffusivity and radial diffusivity. These measure directly relate to the value of the three main eigenvalues of the tensor, indicated in the figure below with lambda 1lambda 2 and lambda 3. What is an eigenvalue of a tensor? It is the value of the displacement/diffusion for each specific vector. Or, as defined by wikipedia: 

"If a two-dimensional space is visualized as a rubber sheet, a linear map with two eigenvectors and associated eigenvalues λ1 and λ2 may be envisioned as stretching/compressing the sheet simultaneously along the two directions of the eigenvectors with the factors given by the eigenvalues." - Wikipedia
Example of the influence of the transformation (or in our case diffusion) on the eigenvalues  
There are roughly two archetypical examples of diffusion tensors. On the left you see the example where the tensor has roughly equal eigenvalues for each main vector, thus showing an isotropic diffusion profile. On the right an example of diffusion primarily in one direction, thus demonstrating an anisotropic diffusion profile.  
Examples of tensor shapes
Characterization of each eigenvalue in the tensor and combinations of them help constitute the main diffusion measures. Specifically, in axial diffusivity (AD) we only quantify the value of lambda 1. While in radial diffusivity (RD) we take the average of lambda 2 and lambda 3. Mean diffusivity (MD) provides an average of all three, lambda 1, lambda 2, and lambda 3, this measure is sometimes also referred to as trace (TR), which is the sum of lambda 1lambda 2 and lambda 3. And finally fractional anisotropy (FA) provides the relative difference between the largest eigenvalue as compared to the others; it quantifies the fraction of diffusion that is anisotropic. The exact mathematical relations are shown below:

Relation of diffusivity measures to the eigenvalues of the tensor

When you plot the value of each a diffusivity measure in every voxel you can get scalar maps of the quantification of the local tensors. In the image below you see representative examples of each measure. When you look at the MD map it becomes apparent that the mean diffusivity measure is specifically sensitive to cerebral spinal fluid (CSF), which has high values of average diffusion. In voxels with much CSF mean diffusivity is high, and values are thus bright. While AD is only sensitive to diffusion in the longest eigenvalue. Here you see that highly organized structures like white matter pathways are brights. In addition large open cavities like ventricles have general high levels of diffusion which translates to high lambda 1 values. Then RD represents the two shortest eigenvalues and shows dark values in highly organized and dense structures like white matter pathways, intermediate values in gray matter, and high values in regions with CSF. Finally, FA plots the relative length of lambda 1, compared to lambda 2 and lambda 3. This leads to selective brightness in white matter, but not gray matter or CSF.
Examples of each diffusivity measure, FA, MD, AD and RD

DTI Tutorial 1 - From Scanner to Tensor

Sunday, October 04, 2015 Do Tromp 0 Comments



Starting out with data analysis often seems like a daunting task, as there are innumerable software packages with sometimes poor documentation. To make this process easier and help you get started with diffusion imaging analyses I put together this tutorial that will introduce you to the most important processing steps and tools. Always keep in mind that there are many ways of processing your data, and the examples used in this tutorial provide just one way of doing things. As you get more versed with the different steps and software you will be able to try different packages and see which you prefer best.

There will be questions in each section to allow you to actively work with data and tools. These question will sometimes ask you to install software or download example data, you can find the example data for this tutorial here. Most of the publicly available (and thus free) software tools used in neuro-imaging will only work in a bash terminal environment (linux or mac). If you are not already, try to become comfortable in a linux environment. An example of linux tutorials can be found online, for example the "UNIX Tutorial for Beginners" contains explanations of basic commands commonly used to navigate the terminal. If you would like some advanced tutorials that go into scripting in bash you can check out this linux tutorial, as scripting in linux will become an important skill when datasets get large. Finally, this DTI tutorial assumes a basic understanding of diffusion MRI, if you would like to catch up on that first, you can go trough these slides that introduce this tutorial. Beyond that you can check out the post on diffusion imaging 101, and start perusing other posts on this website.

In this first tutorial the overall goal is to demonstrate how to convert raw diffusion data files to tensor images. In order to get to tensor images there are a number of intermediate steps that are essential to go through:
   1. You will have to move the data off the scanner and convert it to a usable format.
   2 & 3. It is important to deal with distortions common to diffusion images, like EPI and eddy currents.
   4. Make sure you remove any non-brain tissues.
   5. Make the gradient directions file.
   6. Fit the tensors.
   7. Check the fit of the tensors.
At the end of the document you will find a pdf with the answers to the questions in this tutorial, although try to figure things out yourself as much as possible. If you run into issues going through this tutorial please direct your questions to the diffusion imaging forum, where there will likely be someone able to help you out. Please make sure to describe your question as clearly as possible. Remember to please direct software specific questions to their own respective forums or mail lists. 

1. From scanner to NifTI

What is the best way to get your scanner data to a format that you can actually look at? It depends on your preferences and your scanner. GE and Siemens scanners output DICOM (which stands for Digital Imaging and COmmunications in Medicine) format. While Philips scanners output PAR/REC format. While it is possible to view DICOM or PAR/REC images using specialized software, they are not suitable for processing. Formats that are more commonly used for processing and viewing is the NifTI format. NifTI stands for Neuroimaging informatics Technology Initiative, started by NIH to help streamline the available tools for neuroimaging research. To convert DICOM or PAR/REC images to NifTI you can use software tools like dcm2nii or others. 

dcm2nii by MRIcron

Q1: In your document write the command code to how show how you would convert your raw scanner image to NifTI, assume your data is in dicom format, and organized like this:
In order to get an impression of the quality of the data that you got off the scanner it will be important to take a closer look at your data. This will be a recurring activity, as you can only really make sure your data is valid and your analysis steps work by looking at your data. An example of a toolbox that can help you with that was developed by the University of Oxford FMRIB software library (FSL). A good way to get familiar with some of their software tools is to go through the FSL tutorial on their website.
One method to investigate the information of your image is to look at the header information. A tool that can help you with that is fslinfo. The image below explains the information that you get when you use fslinfo on a diffusion image. The numbers in blue indicate the image dimensions (256x256x67), in red you see the total number of volumes (49), and in green the voxel dimensions (1x1x2mm). Another good habit is to view your data after it has been collected. This way you can catch any issues  that may have occurred during the scan session. More info on why and how to do this can be found here. A commonly used image visualization tool is fslview.
Image information of the sample data
fslinfo by FSL (download FSL here)
fslview by FSL
http://fsl.fmrib.ox.ac.uk/fsl/fslview/

Q2: Download our example diffusion weighted image (052212_s09_dti.nii) through this link, or use your own data. Open the image in fslview (if you don't know how, look at the fslview documentation, or type fslview in your terminal after installing the software). Scroll through the different volumes. Can you identify how many volumes were acquired without diffusion weighting (b=0)?

Additional online resources:

- A wiki that provides more information on converting diffusion images from the DICOM format
- Video on how to use the graphical user interface of dcm2nii
- Additional information from dcm2nii on data repositories and alternatives tools
- Website dedicated to medical imaging formats
- Other dicom converters: mri_convert by freeserver, dimon by afni, dicom2nifti for SPM
- Other data viewers: 3D Slicer: Image Visualization SoftwareMedINRIA: DTI Analysis and Visualization Software.

2. Distortion correction (eddy)

In the next step we will run an eddy distortion correction. Eddy currents are a natural effect of the changing magnetic field that are commonplace in diffusion scans. If you are interested you can find more background on eddy distortions in our post on distortions corrections. The most common tool to counter eddy currents has been developed by FSL. In addition to correcting eddy currents this tool will correct for simple head motions. It takes each volume from your diffusion image and will apply a rigid registration (using FLIRT under the hood) to align all volumes to the first "reference" volume. It is common practice to set the reference volume to be the first volume that was acquired, thus number 0 (counting starts at 0). All the following volumes will then be registered to that first volume. 

eddy_correct by FSL

Q3: Run the command line code for the eddy correction as shown below. What does the output to the terminal look like? Does it take long to run? Why? 
eddy_correct 052212_s09_dti.nii 052212_s09_dti_eddy.nii 0
(If you'd like to quit before its done; type ctrl-c in your terminal, the output files are available to download: 052212_s09_dti_eddy.ecclog and 052212_s09_dti_eddy.nii)

Additional online resources:

- You can also use the FSL Diffusion Toolbox, which has a graphical user interface
- If you acquired two diffusion scans with opposing polarity, you can use FSL's eddy instead
- Distortion correction and preprocessing tutorial from Stanford 

3. Distortion correction (EPI)

EPI (aka field or B0-susceptibility) distortions are caused by magnetic field inhomogeneities, and are more obvious to spot then eddy currents. You can find more info on EPI distortions in this blog post. An example of EPI distortions is shown in the image below. FSL has great tutorials and tools that help deal with EPI distortions using a field map that you should acquire in addition to your diffusion scan. The process essentially consists of two steps, first compose the field map from the raw phase and magnitude files (acquired as part of the field map sequence), and second apply the field map to your diffusion image. Field maps can be collected in different ways, you may have to talk to your local MRI-guru to figure out how your data is collected, but fear not -- if you instead collected two diffusion-scans with opposing polarity and no field map, you can use the TOPUP tool to combine both.

FUGUE by FSL
http://fsl.fmrib.ox.ac.uk/fsl/fslwiki/FUGUE/Guide?highlight=%28%5CbCategoryFUGUE%5Cb%29

TOPUP by FSL

Example of EPI distortions in the frontal lobe of 052212_s09_dti.nii

Q4: On FSL's FUGUE website find the image that shows a real field map image. Can you get an impression from that image where you would expect most distortion to be localized? Look at the field map from the provided example data (download 052212_s10_fmap.nii here). Does that agree with the distortion that you see in the raw diffusion image (052212_s09_dti.nii)?

Pre and post (green) EPI distortion correction

Q5: Note in the image above how the diffusion image is altered after the field map was applied (in green) and EPI distortion was corrected. Take a close look at the gif and indicate what brain regions show reductions in stretch distortion.

Additional online resources:

- Distortion correction tutorial for TOPUP from UCDavis
- Distortion correction tutorial by Andy's Brain Blog, with video's
- EPI distortion correction using ExploreDTI
- Distortion correction tutorial by MNI

4. Stripping the Skull 

In this step the objective is to isolate the brain and get rid of unwanted skull and tissue from the scan so that further processing occurs solely on brain tissue. FSLs automated brain extraction tool (bet) is a tool that can assist in that process. It is important to check if the output from the automated masking process was effective, if not, then you can alter the bet extraction options or manually edit the mask. It should be noted that bet is optimized for human brain extraction, and manual extraction if often necessary in other species. The image below shows different examples of brain extraction with bet, in red is an example of an output mask of the brain tissue.
FSL BET
Brain extraction using FSL's bet. Image courtesy of FSL

bet by fsl
http://fsl.fmrib.ox.ac.uk/fsl/fslwiki/BET

Q6: Investigate the command options in bet using the help function or the online documentation. Explain what executing the below command would entail. How would you alter these options if your output mask is too small? Run a brain extraction on the sample data (e.g. 052212_s09_dti_eddy_fm.nii) using the code below, add options in the command so that it will output a binary mask, and so that it will run multiple iterations for a robust output.
bet 052212_s09_dti_eddy_fm.nii 052212_s09_dti_eddy_fm_strip -f 0.3

Additional online resources:

BET frequently asked questions
- Other skull stripping tools: 3dSkullStrip by AFNI, SPM, BrainSuite

5. Gradient directions

The gradient information from the scanner is used in order to calculate the tensors models. More information on the mathematics can be found in our post here. The gradient information is sometimes stored in the header of the images, if it is not, talk to your scan tech to get this information. There are two aspects that have to be taken into account, the b-values and the b-vectors. Diffusion-weighted b-values usually range from 750~1500 s/m^2, and is most frequently set at 1000s/m^2. 
“The b-value identifies the measurement’s sensitivity to diffusion and determines the strength and duration of the diffusion gradients.” (Graessner, 2011).
Depending on the used b-value (in below example is: 1000s/m^2), and the number of b=0 volumes (in the example: 6) an abbreviated version of the b-value document can look like this:
0,0,0,0,0,0,1000,1000,1000,1000,1000,1000,1000,1000,1000,1000,1000
In contrast the b-vectors consist out of 3 separate vectors (x, y, z) for each gradient direction acquired. A file containing b-vectors might look like this:
Examples of b-vectors
The format used for the b-vectors and b-values depends on the final program that you are going to use to calculate the tensors. Since we are going to use Camino software to run the tensor calculation in this tutorial, we will have to convert the b-values and b-vectors to a scheme file format that combines both, using fsl2scheme. The abbreviated scheme file will look the image below, where the first three columns indicate the b-vectors, and the 4th shows the b-values.
Example scheme file (left), diffusion weighted volumes (right)

fsl2scheme by Camino (download Camino here)

Q7: Investigate the documentation of fsl2scheme, provide example code of how to convert b-vectors and b-values from an FSL format to a Camino scheme file.

If you ran an eddy correction on you data you will first have to correct your scheme file. This is a necessary step as the rigid registration makes the volumes move, causing the gradient directions to be misaligned. Here are a couple of resources to explain this process further and provide code to run the correction:
    1. Blog on rotating bvecs for DTI fitting
    2. Publication on why you should do this
    3. Github code on how to run this rotation

rotate_bvectors.sh by bernardng
https://github.com/bernardng/codeSync/blob/master/dMRIanalysis/preprocess_batch.sh

Combined example code to rotate and produce scheme file:
prefix=052212_s09
sh rotate_bvectors.sh bvecs.txt ${prefix}.bvecs EDDY/
rm -f ${prefix}*.mat
fsl2scheme -bvecfile ${prefix}.bvecs -bvalfile bval.txt > ${prefix}.scheme

Additional online resources:

Camino website with more details on the scheme file formats and application
FSL forum with more details and code for b-vector rotation 

6. Tensor Fitting

In this step we will use Camino to run the tensor calculation. This tool is currently my preferred software for this step as it regularly implements novel mathematical models and scientific developments in diffusion MRI. In order to use this tool, the NifTI format (.nii) images will have to be converted to Camino format (.Bfloat). To do this you can use Camino's tool image2voxel. Once the data is in .Bfloat format you can use Camino to run the tensor model estimation from the diffusion weighted images, using modelfit. Once this is done, you will have to convert the data back to .nii format, using dt2nii. Which will read the header information from a reference NifTI file and copy that to the new tensor NifTI file.

image2voxel by Camino
http://cmic.cs.ucl.ac.uk/camino//index.php?n=Man.Image2voxel

modelfit by Camino
http://cmic.cs.ucl.ac.uk/camino//index.php?n=Man.Modelfit

dt2nii by Camino
http://cmic.cs.ucl.ac.uk/camino//index.php?n=Man.Dt2nii

Example code:
prefix=052212_s09
export CAMINO_HEAP_SIZE=2000
image2voxel -4dimage ${prefix}_dti_eddy_fm.nii > ${prefix}_DWI.Bfloat
modelfit -inputfile ${prefix}_DWI.Bfloat -schemefile ${prefix}.scheme -outputdatatype float > ${prefix}_DTI.Bfloat
dt2nii -inputfile ${prefix}_DTI.Bfloat -inputdatatype float -header ${prefix}_dti_eddy_fm.nii -outputroot ${prefix}_dti_eddy_fm_strip_

Q8: Download the necessary data from our example data. Using the example code shown above try to run the tensor fitting. Note that ${prefix} indicates a variable in bash, which is defined in line 1, if you are unsure how variables work in bash look it up here. Learning how to work with variables now will make it easier to transition to loops in scripts later on. This code will need a couple of minutes to run. Side note; to avoid a java error message (as shown below) we increased the java RAM usage allowed for Camino with the third line in the example script. Solution came from the camino help list.
Exception in thread "main" java.lang.OutOfMemoryError: Java heap space

Q9: Imagine that due to unforeseen reasons you collected noisy data, and you would like to run a robust tensor estimation as described by Chang, Jones & Pierpaoli (2005). Investigate the Camino list of available commands. What tool would be able to accommodate your aim?

Additional online resources:

- More info from this blog on tensor fitting
- Camino has a comprehensive list of tutorials for their tools here
- Camino can also run higher order models like Q-ball/HARDI

7. Sanity Check

Finally it will be essential to check if your scheme file was applied well, and your tensors were fit correctly. If you have not already go through the tensor fitting quality control post to see why and how. In order to see the tensor fit we will use tools by camino to draw and visualize the main tensor. In principle you should only have to check this for one sample image in your entire dataset.

dteig by Camino

pdview by Camino

Example code:
prefix=052212_s09
dteig -inputmodel dt -inputdatatype float -outputdatatype float < ${prefix}_DTI.Bfloat > ${prefix}_DTI_EIG.Bfloat
pdview -inputdatatype float -inputmodel dteig -inputfile ${prefix}_DTI_EIG.Bfloat -datadims 256 256 67 &
Q10: Run the example code to investigate the tensor fit, compare the results to the examples from the quality control post and the Camino website, were the tensors fit correctly?

Further additional online resources:

- General tutorial on "Diffusion Tensor Imaging Analysis using FSL"
- Overview of other software packages on this blog
- Article on the do's and don'ts of diffusion imaging
- Article that is the hitchhikers guide to diffusion imaging
- Preprocessing tutorial by the Enigma group

Answers:

DTI Tutorial 1 Answers


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Reference this post as: Do Tromp, DTI Tutorial 1 - From Scanner to Tensor, The Winnower 3:e145653.31559 (2016). DOI: 10.15200/winn.145653.31559
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