Difference between revisions of "Projects:dtistatisticsfibers"

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__NOTOC__
 
__NOTOC__
 
= DTI Fiber Tract statistics =
 
= DTI Fiber Tract statistics =
 
Following the complete pipeline using Casey Goodlett's work, we get the fiber files containing DTI data. (The pipeline includes unbiased non-rigid registration of a population, Fiber tractography applied to the average atlas, and finding individual subjects' DTI data by mapping the atlas geometry back to individual subjects.
 
 
 
We are working on a command line tool which takes as input the fiber files generated by the above pipeline. The tool has options to perform kernel based regression on the DTI data (like FA, MD, FRO, AD, RD etc). Each kernel window assumes a noise model within the given cross section of the fiber and then chooses a statistic to represent the information in that window. Currently, the tool implements Gaussian and Beta (only for FA) noise models for data within fiber cross sections. The possible statistics that can be chosen are Mean, Mode and Quantiles. The tool also computes the standard deviations about the regressed curve. The output is saved as a file. All the results can be plotted using Matlab scripts.
 
There are various visualization options available like viewing the data distribution histograms within cross sections (before and after applying the kernels), scatter plots to view the actual distribution of the DTI data, and more. These options will help in further analyzing the best noise models and the best representative statistics to explain the distribution of DTI data along the fiber tract.
 
 
The tool will replace the command line interface that Fiber Viewer tool currently provides to do similar (though very limited) tasks. It will allow us to do comparison of DTI data inter and intra population. We are currently testing the results of the tool on data from neonates, 1 year and 2 year old subjects. Casey's Functional Data Analysis module is also being used to analyze the results generated above.
 
  
 
==Key Investigators==
 
==Key Investigators==
* Utah: Anuja Sharma, Guido Gerig
+
* Utah Algorithms: Anuja Sharma, Sylvain Gouttard, Guido Gerig
 
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* UNC Algorithms: Jean-Baptiste Berger, Benjamin Yvernault, Clement Vachet, Yundi Shi, Aditya Gupta, Martin Styner
<div style="margin: 20px;">
 
<div style="width: 27%; float: left; padding-right: 3%;">
 
  
 
<h3>Objective</h3>
 
<h3>Objective</h3>
  
The aim is to understand probabilistic models that can account for the behavior of water diffusion in white matter tracts. The long term goal is to use this to understand the changes in white matter structure with age, gender or a specific disease.  
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The main aim is to provide statistical information of white matter diffusion associated to fiber tracts, and therefore complements geometric information obtained by tractography with white matter integrity measurements. The tool calculates statistics on parametrized fiber tract data, represented as sets of streamlines. Using arc-length parametrization of streamline bundles, we calculate statistical parameters within cross-sections that are swept along bundles. Kernel regression along tracts provides an aperture function to include diffusion measurements of a spatial neighborhood. Diffusion invariants such as fractional anisotropy (FA), mean diffusivity (MD), Frobenius norm (FRO), axial diffusivity (AD), and transversal diffusivity (RD) are processed.  
  
 +
The long term goal is to use the quantitative diffusion information to understand changes of white matter structure with age, gender or specific disease processes.
  
 +
{| border="0" style="background:transparent;"
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|[[Image:Tract-stats.png|thumb|500px|White matter diffusion properties along fiber tract: Left: Uncinate fasiculus with coordinate origin plane, Right: FA mean and standard deviation as function of arc-length, starting at frontal region. Dots mark location of coordinate origin.]]
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|-
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|}
  
</div>
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<div style="width: 40%; float: left; padding-right: 3%;">
 
 
<div style="width: 27%; float: left; padding-right: 3%;">
 
  
 
<h3>Approach, Plan</h3>
 
<h3>Approach, Plan</h3>
  
 +
We work with DTI data and follow the complete pipeline motivated by Casey Goodlett's work. (The pipeline includes unbiased non-rigid registration of a population, followed by fiber tractography applied to the average atlas and mapping the atlas geometry back to individual subjects to get the individual DTI data.) These individual subject fiber tracts are the input for the command line tool we are working on.
  
Various tract-oriented scalar diffusion measures are treated as a continuous function of fiber arc-length. To analyze the trend along the fiber tract, a command line tool performs kernel regression on this data. The idea is to try out different noise models and maximum likelihood estimates within kernel windows, such that they best represent the data and are robust to noise and Partial Volume effect.
+
In the tool, various tract-oriented scalar diffusion measures are treated as a continuous function of fiber arc-length. To analyze the trend along the fiber tract, the command line tool performs kernel regression on this data. The idea is to try out different noise models and maximum likelihood estimates within kernel windows, such that they best represent the data and are robust to noise and Partial Volume effect.  
 
 
Casey Goodlett's functional data analysis pipeline is then applied to this data. Here, multivariate hypothesis test is used to test for differences between populations.
 
 
 
Our plan for the project week is to try out the complete pipeline for a few datasets and see if we get statistically significant results. We also plan to work on the possibility of integrating this module into the Slicer environment.
 
  
 +
Casey Goodlett's functional data analysis pipeline is then applied to this data. Here, multivariate hypothesis test is used to test for differences between populations and see if we get statistically significant results.
 +
 
</div>
 
</div>
  
<div style="width: 40%; float: left;">
+
<div style="width: 50%; float: left;">
  
 
<h3>Progress</h3>
 
<h3>Progress</h3>
  
The first version of the command line tool is ready. It provides the flexibility to choose the scalar diffusion measure to be tested; a choice between Gaussian and Beta noise models and Mean, median or mode as MLE. It also incorporates several visualization options which help in analyzing the best noise models and the best representative statistics to explain the distribution of DTI data along the fiber tract.  
+
The first version of the command line tool is ready for upload into NITRC. It provides the flexibility to choose the scalar diffusion measure to be tested; a choice between Gaussian and Beta noise models and Mean, median or mode as MLE. It also incorporates several visualization options which help in analyzing the best noise models and the best representative statistics to explain the distribution of DTI data along the fiber tract. We are also working on integrating the tool into the Slicer environment. The tool can now work with UNC/UTAH .fib file format as well as the more popular VTK poly data format. The output is a csv file which can easily be used for further analysis and visualizations. The tool needs a cut-plane to define a reference origin along the fiber tract's length. We now have the option of the user visually choosing a reference plane for a fiber tract (using Fiber Viewer or a similar software) or an auto generation of a reference plane cutting the fiber bundle approximately in the middle.
 
 
This week we figured out all interoperability issues which need to fixed to enable the tool's integration into the Slicer. We discussed with other groups working on DTI and discussed common data structures and file formats for easy interfacing between tools. As a result, we will be moving our files to the VTK format in the near future.
 
 
 
Another discussion with Maddah pointed out ways to minimize the need for manual intervention in our tool. Moreover, we would be collaborating with the University of Iowa in providing tools to process datasets related to Huntington's disease. We might also migrate another medical imaging software Fiber Viewer to Qt4 to enable integration into the Slicer environment.
 
 
 
During this week we also tried running the pipeline on several datasets. We are in the process of analyzing the results now.
 
 
 
<h3>Progress - revised</h3>
 
  
The command line tool is ready for upload into the NITRC. The features available in the tool currently, its use and input / output formats and other relevant details are provided in the first draft of the documentation ([[Media:Tool_documentation_pdf.pdf|PDF]]). The tool is still a work in progress. More features will be added to it, specially the option to plot and visualize the results.  
+
The features available in the tool currently, its use and input / output formats and other relevant details are provided in the first draft of the <font color="red">'''documentation'''</font>. ([[Media:Tool_documentation_pdf.pdf|PDF]]). The document is comprehensive and also includes the concepts and the algorithm behind the tool, limitations of this approach and various visual results.
 +
The tool is still a work in progress. More features will be added to it, specially more options to plot and visualize the results. The tool will also replace the command line interface that Fiber Viewer tool currently provides to do similar (though very limited) tasks.  
  
 +
We are currently using the tool and the complete pipeline to study population differences longitudinally, in Autism and Cocaine related studies.
 
</div>
 
</div>
</div>
 
 
<div style="width: 97%; float: left;">
 
  
 
=Images=
 
=Images=
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<h3>Updates (August 2012)</h3>
 +
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A revised version of the command line tool has been incorporated in a GUI based tool [http://www.nitrc.org/projects/dti_tract_stat DTIAtlasFiberAnalyzer] available via [http://www.nitrc.org NITRC]. For details on the complete pipeline for DTI processing which makes use of this tool's functionality, please refer to the [http://www.na-mic.org/Wiki/index.php/Projects:AtlasBasedDTIFiberAnalyzerFramework UNC Algorithm page].
  
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<h3> References </h3>
 +
* Casey B. Goodlett, P. Thomas Fletcher, John H. Gilmore, Guido Gerig. Group Analysis of DTI Fiber Tract Statistics with Application to Neurodevelopment. NeuroImage 45 (1) Supp. 1, 2009. p. S133-S142.
  
 
[[Category:Diffusion MRI]]
 
[[Category:Diffusion MRI]]

Latest revision as of 10:21, 19 August 2012

Home < Projects:dtistatisticsfibers

Statistics on DTI data

Back to NA-MIC Collaborations, Utah2 Algorithms, MIT Algorithms, UNC Algorithms

DTI Fiber Tract statistics

Key Investigators

  • Utah Algorithms: Anuja Sharma, Sylvain Gouttard, Guido Gerig
  • UNC Algorithms: Jean-Baptiste Berger, Benjamin Yvernault, Clement Vachet, Yundi Shi, Aditya Gupta, Martin Styner

Objective

The main aim is to provide statistical information of white matter diffusion associated to fiber tracts, and therefore complements geometric information obtained by tractography with white matter integrity measurements. The tool calculates statistics on parametrized fiber tract data, represented as sets of streamlines. Using arc-length parametrization of streamline bundles, we calculate statistical parameters within cross-sections that are swept along bundles. Kernel regression along tracts provides an aperture function to include diffusion measurements of a spatial neighborhood. Diffusion invariants such as fractional anisotropy (FA), mean diffusivity (MD), Frobenius norm (FRO), axial diffusivity (AD), and transversal diffusivity (RD) are processed.

The long term goal is to use the quantitative diffusion information to understand changes of white matter structure with age, gender or specific disease processes.

White matter diffusion properties along fiber tract: Left: Uncinate fasiculus with coordinate origin plane, Right: FA mean and standard deviation as function of arc-length, starting at frontal region. Dots mark location of coordinate origin.

Approach, Plan

We work with DTI data and follow the complete pipeline motivated by Casey Goodlett's work. (The pipeline includes unbiased non-rigid registration of a population, followed by fiber tractography applied to the average atlas and mapping the atlas geometry back to individual subjects to get the individual DTI data.) These individual subject fiber tracts are the input for the command line tool we are working on.

In the tool, various tract-oriented scalar diffusion measures are treated as a continuous function of fiber arc-length. To analyze the trend along the fiber tract, the command line tool performs kernel regression on this data. The idea is to try out different noise models and maximum likelihood estimates within kernel windows, such that they best represent the data and are robust to noise and Partial Volume effect.

Casey Goodlett's functional data analysis pipeline is then applied to this data. Here, multivariate hypothesis test is used to test for differences between populations and see if we get statistically significant results.

Progress

The first version of the command line tool is ready for upload into NITRC. It provides the flexibility to choose the scalar diffusion measure to be tested; a choice between Gaussian and Beta noise models and Mean, median or mode as MLE. It also incorporates several visualization options which help in analyzing the best noise models and the best representative statistics to explain the distribution of DTI data along the fiber tract. We are also working on integrating the tool into the Slicer environment. The tool can now work with UNC/UTAH .fib file format as well as the more popular VTK poly data format. The output is a csv file which can easily be used for further analysis and visualizations. The tool needs a cut-plane to define a reference origin along the fiber tract's length. We now have the option of the user visually choosing a reference plane for a fiber tract (using Fiber Viewer or a similar software) or an auto generation of a reference plane cutting the fiber bundle approximately in the middle.

The features available in the tool currently, its use and input / output formats and other relevant details are provided in the first draft of the documentation. (PDF). The document is comprehensive and also includes the concepts and the algorithm behind the tool, limitations of this approach and various visual results. The tool is still a work in progress. More features will be added to it, specially more options to plot and visualize the results. The tool will also replace the command line interface that Fiber Viewer tool currently provides to do similar (though very limited) tasks.

We are currently using the tool and the complete pipeline to study population differences longitudinally, in Autism and Cocaine related studies.

Images

Visually understanding the command line tool and the complete pipeline

Visual explanation of the data processing happening through the tool (Image 1)
Visual explanation of the data processing happening through the tool (Image 2 ...continuation of Image 1)

More intuitive visual images and results

Fiber Viewer results showing color-coded distribution of FA values in a fiber cross section. This image shows (using color coding) how the distribution of FA varies within a cross section of the fiber bundle as we move along the length of the fiber tract.
Sub plots generated by the command line tool as intermediate results, showing FA distributions within various cross-sections along the fiber tract length. These visualizations helps in choosing a noise model and maximum likelihood estimate which would best represent the variation in the scalar diffusion measure along the fiber tract.


Updates (August 2012)

A revised version of the command line tool has been incorporated in a GUI based tool DTIAtlasFiberAnalyzer available via NITRC. For details on the complete pipeline for DTI processing which makes use of this tool's functionality, please refer to the UNC Algorithm page.

References

  • Casey B. Goodlett, P. Thomas Fletcher, John H. Gilmore, Guido Gerig. Group Analysis of DTI Fiber Tract Statistics with Application to Neurodevelopment. NeuroImage 45 (1) Supp. 1, 2009. p. S133-S142.