Difference between revisions of "AHM2009:PNL"

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__NOTOC__
 
__NOTOC__
 
==PNL Roadmap Project==
 
==PNL Roadmap Project==
 
 
{|
 
{|
|[[Image:screenshotBlank.png|thumb|280px|Caption 1]]
+
|[[Image:Helix.png|thumb|Stochastic Tractography on helix phantom]]
|[[Image:screenshotBlank.png|thumb|280px|Caption 2]]
+
|[[Image:Wmm.png|thumb|White Matter Mask generated from phantom]]
|[[Image:screenshotBlank.png|thumb|280px|Caption 3]]
+
|[[Image:STArcuate.png|thumb|Stochastic Tractography of Arcuate Fasciculus]]
 +
|[[Image:Step1.png|thumb|56px|Stochastic Tractography Module]]
 +
|[[Image:Step2.png|thumb|152px|Stochastic Tractography Module]]
 
|}
 
|}
  
 
== Overview ==
 
== Overview ==
* What problem does the pipeline solve?
+
;*What problem does the pipeline solve?
Most tractography methods (Deterministic/Principal Diffusion Direction) estimate fibers by tracing the maximum direction of diffusion. A limitation of this approach is that, in practice, several factors introduce uncertainty in the tracking procedure, including, noise, splitting and crossing fibers, head motion and image artifacts.  
+
Most tractography methods (Deterministic/Principal Diffusion Direction) estimate fibers by tracing the maximum direction of diffusion.  
Stochastic tractography attempts to quantify the uncertainty associated with estimated fibers, by using a propagation model based on stochastics and regularization, which allows paths originating at one point to branch and return a probability distribution of possible paths.  
+
 
 +
A limitation of this approach is that, in practice, several factors introduce uncertainty in the tracking procedure, including, noise, splitting and crossing fibers, head motion and image artifacts.  
 +
 
 +
Stochastic tractography attempts to quantify the uncertainty associated with estimated fibers, by using a propagation model based on stochastics and regularization, which allows paths originating at one point to branch and return a probability distribution of possible paths.
 +
 
Based on probability functions, using a sequential importance sampling technique ([http://lmi.bwh.harvard.edu/papers/pdfs/2002/bjornemoMICCAI02.pdf Bjornemo et al., 2002]), one can generate thousands of fibers starting in the same point by sequentially drawing random step directions. This gives a very rich model of the fiber distribution, as contrasted with single fibers produced by conventional tractography methods. Moreover, from a large number of sampled paths, probability maps can be generated, providing better estimates of connectivity between several anatomical locations.  
 
Based on probability functions, using a sequential importance sampling technique ([http://lmi.bwh.harvard.edu/papers/pdfs/2002/bjornemoMICCAI02.pdf Bjornemo et al., 2002]), one can generate thousands of fibers starting in the same point by sequentially drawing random step directions. This gives a very rich model of the fiber distribution, as contrasted with single fibers produced by conventional tractography methods. Moreover, from a large number of sampled paths, probability maps can be generated, providing better estimates of connectivity between several anatomical locations.  
* Who is the targeted user?
+
;* Who is the targeted user?
 
Since diffusion direction uncertainty within the gray matter is quite significant; principal diffusion direction approaches usually do not work for tracking between two gray matter regions. Thus if one requires finding connections between a priori selected anatomical gray matter regions, defined either by anatomical segmentations (in case of using structural ROI data), or functional activations (in case of megring DTI with fMRI), stochastic tractography seems to be the method of choice.  
 
Since diffusion direction uncertainty within the gray matter is quite significant; principal diffusion direction approaches usually do not work for tracking between two gray matter regions. Thus if one requires finding connections between a priori selected anatomical gray matter regions, defined either by anatomical segmentations (in case of using structural ROI data), or functional activations (in case of megring DTI with fMRI), stochastic tractography seems to be the method of choice.  
 
Stochastic Tractography is also comparable, if not better, in defining large white matter fiber bundles, especially those traveling through white matter regions characterized by increased diffusion uncertainty (fiber crossings).  
 
Stochastic Tractography is also comparable, if not better, in defining large white matter fiber bundles, especially those traveling through white matter regions characterized by increased diffusion uncertainty (fiber crossings).  
* How does the pipeline compare to state of the art?
+
;* How does the pipeline compare to state of the art?
To date, there are two popular toolboxes that include probabilistic/stochastic tractography modules. Functionality of both modules (FSL and PICO) is limited, and software is not open source.  
+
To date, there are two popular toolboxes that include probabilistic/stochastic tractography modules. Functionality of both modules (FSL and PICO) is limited, and software is not open source.
  
 
==Detailed Information about the Pipeline==
 
==Detailed Information about the Pipeline==
 +
Stochastic Tractography pipeline has been written in Python, and is part of current Slicer3 release.
 +
 +
Functionality of Python Stochastic Tractography module in Slicer 3.0 includes:
 +
;*Preprocessing
 +
 +
Reading DWI and ROI files in nhdr format
 +
 +
Smoothing DWI data
 +
 +
Creating brain and white mater masks
  
* Illustrate the components and workflow of the pipeline using your own data
+
Removing artifacts in WM masks by comparing this mask with FA map
  
* Demonstrate parameters/steps that need to be adjusted using someone else's data
+
Producing diffusion indices (FA, Mode, Trace)
 +
 
 +
;*Creating probability maps (parameters involve number of tracts per seed, tract length, step size, stopping criteria)
 +
 
 +
Probability maps can be saved as ROIs, and either used directly, or thresholded (at certain probability, step claimed by few publications to remove noise) in slicer to mask and compute average FA, Mode, Trace for entire connection. Diffusion indices can be also weighted by the probability of connection for each voxel.
 +
 
 +
;* Parameters/steps that need to be adjusted using someone else's data
 +
Software was tested on 3 sets of data (1.5T anisotropic Siemens, 3T anisotropic GE, 3T isotropic GE), and works for all of them without major modifications.
  
 
==Software & documentation==
 
==Software & documentation==
* url for downloading all the software
+
* Download Slicer 3.0 [http://www.slicer.org/pages/Downloads here].
* url for the end-user tutorial
 
  
==Team==
+
:* Module documentation can be found here:
[[Image:PnllogoworkNEW.png|left|50px]]
+
:**[[Media:IJdata.tar.gz|Training Dataset]]
* DBP: Marek Kubicki, MD, PhD, Sylvain Bouix, PhD, Julien Von Siebenthal, PhD, Doug Terry, BS
+
:**[[Media:PNLStochasictNew.ppt|Training Presentation]]
Psychiatry Neuroimaging Laboratory, Department of Psychiatry, Brigham and Women's Hospital, Harvard Medical School
+
:**[[Media:Helix.zip|Sample Helix Dataset]]
Boston, MA
 
  
 +
:* Software that you will also need to launch:
 +
:**[http://www.python.org/download/releases/2.5.4/ Python 2.5 Software]
 +
:**[http://sourceforge.net/project/showfiles.php?group_id=1369&package_id=175103 NumPy Software]
 +
:**[http://pnl.bwh.harvard.edu/NAMIC/Slicer3-build.zip Slicer 3 Build for Windows]
 +
:**[http://pnl.bwh.harvard.edu/NAMIC/Slicer3-lib.zip Slicer 3 Lib for Windows]
  
[[Image:csail.jpg|left|50px]]
+
==Team==
* Core 1: Polina Gollard, MIT
 
  
 
+
{|
[[Image: Kitware.png|left|80px]]
+
|[[Image:Logo_pnl2.png|75px]]
* Core 2: Brad Davis, Steve Pieper, Kitware Affiliation
+
|valign="top"| DBP: Marek Kubicki, MD, PhD, Sylvain Bouix, PhD, Julien De Siebenthal, PhD, Doug Terry, BS,
* Contact: name, email
+
[http://pnl.bwh.harvard.edu/ Psychiatry Neuroimaging Laboratory]
 +
|-
 +
|[[Image:csail.jpg|75px]]
 +
|valign="top"|Core 1: Polina Golland, [http://www.csail.mit.edu/ CSAIL MIT]
 +
|-
 +
|[[Image: Kitware.png|75px]]
 +
|valign="top"| Core 2: Brad Davis, Steve Pieper, [http://www.kitware.com/ Kitware]
 +
|}
  
 
==Outreach==
 
==Outreach==
* Publication Links to the PubDB.
+
;* Visit our [http://pnl.bwh.harvard.edu/pub/all.html publication database.]
* Planned outreach activities (including presentations, tutorials/workshops) at conferences
+
;* Planned outreach activities (including presentations, tutorials/workshops) at conferences
 +
:1. Method of stochastic tractography, along with the module functionality will be presented at the DTI symposium during World Biological Psychiatry Symposium in Florence, Italy in April 2009.
 +
:2. Clinical applications, including results of arcuate fasciculus study in schizophrenia will be presented at the Biological Psychiatry Congress in Vancouver, Canada in May 2009.

Latest revision as of 17:33, 17 February 2009

Home < AHM2009:PNL

Back to AHM 2009 Agenda


PNL Roadmap Project

Stochastic Tractography on helix phantom
White Matter Mask generated from phantom
Stochastic Tractography of Arcuate Fasciculus
Stochastic Tractography Module
Stochastic Tractography Module

Overview

  • What problem does the pipeline solve?

Most tractography methods (Deterministic/Principal Diffusion Direction) estimate fibers by tracing the maximum direction of diffusion.

A limitation of this approach is that, in practice, several factors introduce uncertainty in the tracking procedure, including, noise, splitting and crossing fibers, head motion and image artifacts.

Stochastic tractography attempts to quantify the uncertainty associated with estimated fibers, by using a propagation model based on stochastics and regularization, which allows paths originating at one point to branch and return a probability distribution of possible paths.

Based on probability functions, using a sequential importance sampling technique (Bjornemo et al., 2002), one can generate thousands of fibers starting in the same point by sequentially drawing random step directions. This gives a very rich model of the fiber distribution, as contrasted with single fibers produced by conventional tractography methods. Moreover, from a large number of sampled paths, probability maps can be generated, providing better estimates of connectivity between several anatomical locations.

  • Who is the targeted user?

Since diffusion direction uncertainty within the gray matter is quite significant; principal diffusion direction approaches usually do not work for tracking between two gray matter regions. Thus if one requires finding connections between a priori selected anatomical gray matter regions, defined either by anatomical segmentations (in case of using structural ROI data), or functional activations (in case of megring DTI with fMRI), stochastic tractography seems to be the method of choice. Stochastic Tractography is also comparable, if not better, in defining large white matter fiber bundles, especially those traveling through white matter regions characterized by increased diffusion uncertainty (fiber crossings).

  • How does the pipeline compare to state of the art?

To date, there are two popular toolboxes that include probabilistic/stochastic tractography modules. Functionality of both modules (FSL and PICO) is limited, and software is not open source.

Detailed Information about the Pipeline

Stochastic Tractography pipeline has been written in Python, and is part of current Slicer3 release.

Functionality of Python Stochastic Tractography module in Slicer 3.0 includes:

  • Preprocessing

Reading DWI and ROI files in nhdr format

Smoothing DWI data

Creating brain and white mater masks

Removing artifacts in WM masks by comparing this mask with FA map

Producing diffusion indices (FA, Mode, Trace)

  • Creating probability maps (parameters involve number of tracts per seed, tract length, step size, stopping criteria)

Probability maps can be saved as ROIs, and either used directly, or thresholded (at certain probability, step claimed by few publications to remove noise) in slicer to mask and compute average FA, Mode, Trace for entire connection. Diffusion indices can be also weighted by the probability of connection for each voxel.

  • Parameters/steps that need to be adjusted using someone else's data

Software was tested on 3 sets of data (1.5T anisotropic Siemens, 3T anisotropic GE, 3T isotropic GE), and works for all of them without major modifications.

Software & documentation

  • Download Slicer 3.0 here.

Team

Logo pnl2.png DBP: Marek Kubicki, MD, PhD, Sylvain Bouix, PhD, Julien De Siebenthal, PhD, Doug Terry, BS,

Psychiatry Neuroimaging Laboratory

Csail.jpg Core 1: Polina Golland, CSAIL MIT
Kitware.png Core 2: Brad Davis, Steve Pieper, Kitware

Outreach

  • Visit our publication database.
  • Planned outreach activities (including presentations, tutorials/workshops) at conferences
1. Method of stochastic tractography, along with the module functionality will be presented at the DTI symposium during World Biological Psychiatry Symposium in Florence, Italy in April 2009.
2. Clinical applications, including results of arcuate fasciculus study in schizophrenia will be presented at the Biological Psychiatry Congress in Vancouver, Canada in May 2009.