Difference between revisions of "DBP2:UNC:Regional Cortical Thickness Pipeline"

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Back to [[DBP2:UNC:Cortical_Thickness_Roadmap | UNC Cortical Thickness Roadmap]]
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Back to [[DBP2:UNC:Cortical_Thickness_Roadmap | UNC Cortical Thickness Roadmap]]
__NOTOC__
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 +
[[Image:ArcticLogo.png|thumb|400px|ARCTIC Logo|right]]
  
<center>
 
{|
 
|[[Image:Screenshot_Slicer.jpg|thumb|250px|Screenshot of the application]]
 
|valign="center"|[[Image:Schema_pipeline.jpg|thumb|600px|Pipeline description]]
 
|}
 
</center>
 
  
 
== Objective ==
 
== Objective ==
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We would like to create an end-to-end application within Slicer3 allowing individual and group analysis of regional cortical thickness.
 
We would like to create an end-to-end application within Slicer3 allowing individual and group analysis of regional cortical thickness.
  
This page describes the related pipeline with its basic components.
+
This page describes the related pipeline with its basic components, as well as its validation.
  
== General information ==
 
  
Two modules have been developped:
+
== Pipeline overview ==
:* ARCTIC
 
:* ARCTICA
 
  
=== Main pipeline description (steps) ===
+
A Slicer3 high-level module for individual cortical thickness analysis has been developed: ARCTIC (Automatic Regional Cortical ThICkness)  
  
 
Input: RAW images (T1-weighted, T2-weighted, PD-weighted images)
 
Input: RAW images (T1-weighted, T2-weighted, PD-weighted images)
  
 
:* '''1. Tissue segmentation'''
 
:* '''1. Tissue segmentation'''
 +
:** Probabilistic atlas-based automatic tissue segmentation via an Expectation-Maximization scheme
 
:** Tool: itkEMS (UNC Slicer3 external module)
 
:** Tool: itkEMS (UNC Slicer3 external module)
:* '''2. Skull stripping'''
+
:* '''2. Regional atlas deformable registration'''
:** Tool: SegPostProcess (UNC Slicer3 external module)
+
:** 2.1 Skull stripping using previously computed tissue segmentation label image
:* '''3. Deformable registration of pediatric regional atlas'''
+
:*** Tool: SegPostProcess (UNC Slicer3 external module)  
:** 3.1 Deformable registration of T1-weighted pediatric atlas
+
:** 2.2 T1-weighted atlas deformable registration
:***Tool: RegisterImages (Slicer3 module)  
+
:*** B-spline pipeline registration
:** 3.2. Applying transformation to the parcellation map
+
:*** Tool: RegisterImages (Slicer3 module)  
 +
:** 2.3. Applying transformation to the parcellation map
 
:*** Tool: ResampleVolume2 (Slicer3 module)
 
:*** Tool: ResampleVolume2 (Slicer3 module)
:* '''4. Cortical Thickness'''
+
:* '''3. Cortical thickness measurement'''
:** Tool: CortThick (UNC Slicer3 module)
+
:** Sparse asymmetric local cortical thickness
 +
:** Tool: CortThick (UNC Slicer3 external module)
 +
:* '''4. Statistics'''
 +
:** Volume information (WM, GM, CSF, lobes) stored in spreadsheet
 +
:** Tools: ImageMath, ImageStat (UNC Slicer3 external modules)
 +
:* '''5. Mesh creation'''
 +
:** White matter and grey matter meshes creation
 +
:** Tool: ModelMaker (Slicer3 module)
 +
:* '''6. MRML scene creation for quality control'''
 +
:** MRML scene creation allowing quality control for each step of the pipeline
 +
:** Output images and surfaces are automatically displayed
  
 
All the tools used in the current pipeline are Slicer3 modules, some of them being UNC external modules.
 
All the tools used in the current pipeline are Slicer3 modules, some of them being UNC external modules.
The user can thus compute an individual regional cortical thickness analysis by running the 'RegionalCortThickPipeline' module, either within Slicer3 or as a command line.
+
The user can thus compute an individual regional cortical thickness analysis by running the 'ARCTIC' module, either within Slicer3 or as a command line.
  
 +
== Download ==
  
 +
=== ARCTIC download ===
  
=== Before using the pipeline ===
+
Source code, executables and tutorial are available on [http://www.nitrc.org/projects/arctic NITRC]
  
Add the executables in the PATH.
+
=== Complementary downloads ===
  -tcsh usage : setenv PATH ARCTIC-Executables-Directory:Slicer3D-Plugins-Directory:Batchmake-Drectory:${PATH}
 
  -bash usage : export PATH=ARCTIC-Executables-Directory:Slicer3D-Plugins-Directory:Batchmake-Drectory:${PATH}
 
  notice : For an execution within Slicer3D, it is not necessary to add "Slicer3D-Plugins-Directory" in the PATH.
 
  
Set the pipeline environment variable
+
==== Brain atlases ====
  -tcsh usage : setenv BatchmakeWrapper_Dir Batchmake-Wrapper-Directory
+
Four brain atlases are available on MIDAS:
  -bash usage : export BatchmakeWrapper_Dir=Batchmake-Wrapper-Directory
+
:* [http://www.insight-journal.org/midas/item/view/2277 Pediatric atlas]
 +
:* [http://www.insight-journal.org/midas/item/view/2328 Adult atlas]
 +
:* [http://www.insight-journal.org/midas/item/view/2330 Elderly atlas]
 +
:* [http://www.insight-journal.org/midas/item/view/2283 Primate atlas]
  
Set the pipeline as a Slicer3D module
+
==== Pediatric Brain MRI data ====
  Within Slicer3D : View->Applications Settings->Add a preset and then select the ARCTIC-Executables-Directory/
+
[http://insight-journal.org/midas/community/view/24 Data of 2 autistic children and 2 normal controls] (male, female) scanned at 2 years with follow up at 4 years from a 1.5T Siemens scanner. Files include structural data, tissue segmentation label map and subcortical structures segmentation.
  
=== Usage (Command Line) ===
+
==== Tutorials ====
 +
*'''ARCTIC tutorial''' : end-to-end Slicer3 module to perform automatic regional cortical thickness analysis[[Media:ARCTIC-Slicer3-Tutorial.ppt|‏ [ppt]]][[Media:ARCTIC-Slicer3-Tutorial.pdf|‏ [pdf]]]
 +
**1st Prize: NAMIC tutorial contest AHM 2009
 +
**2nd Prize: NAMIC tutorial contest summer project week 2009
 +
*'''UNC Modules tutorial''' : UNC Slicer3 modules to perform regional cortical thickness analysis step by step[[Media:UNC_Modules-Slicer3-Tutorial.ppt| [ppt]‏]][[Media:UNC_Modules-Slicer3-Tutorial.pdf| [pdf]‏]]
  
Inputs: T1-weighted image, T1-weigthed atlas, regional atlas (parcellation map)
+
*'''[https://www.slicer.org/wiki/Modules:ARCTIC-Documentation-3.6 Online documentation within Slicer 3.6]'''
  
'''A. Pipeline command line'''
+
<center>
  RegionalCortThickPipeline --T1 Image_T1.gipl --segAtlasDir TissueSegmentationAtlasDirectory/
+
{|
  --atlas Atlas.gipl --atlasParcellation Parcellation.gipl --SaveWM  WMCorticalThicknessMap  --SaveGM GMCorticalThicknessMap
+
|[[Image:T1Image.jpg|thumb|250px|T1-weighted skull-stripped image]]
 +
|valign="center"|[[Image:Parcellation.jpg|thumb|250px|Parcellation image]]
 +
|valign="center"|[[Image:WMThickness.jpg|thumb|250px|Cortical thickness on WM surface]]
 +
|valign="center"|[[Image:ThicknessInformation.jpg|thumb|250px|Cortical thickness information]]
 +
|}
 +
</center>
  
'''B. Step by step command line'''
+
== Pipeline validation ==
:* '''1. Tissue segmentation'''
 
:**Input: EMSparam.xml
 
:**Output: Image_Corrected_EMS.gipl, Label.gipl
 
  itkEMSCLP --XMLFile EMSparam.xml
 
:* '''2. Skull stripping'''
 
:**Input: Label.gipl,  Image_Corrected_EMS.gipl
 
:**Output: Image_Corrected_EMS_Stripped.gipl, BinaryMask.gipl (optional)
 
  SegPostProcessCLP Label.gipl  Image_Corrected_EMS_Stripped.gipl --skullstripping  Image_Corrected_EMS.gipl
 
:* '''3. Deformable registration of pediatric regional atlas'''
 
:** 3.1 Deformable registration of T1-weighted pediatric atlas
 
:***Input: Atlas.gipl, Image_Corrected_EMS_Stripped.gipl
 
:***Output: Atlas_Registered.gipl, Atlas_Registered_Transform.txt
 
  RegisterImages Image_Corrected_EMS_Stripped.gipl Atlas.gipl –resampledImage  Atlas_Registered.gipl –saveTransform Atlas_Registered_Transform.txt –registration PipelineBSpline
 
:** 3.2. Applying transformation to the parcellation map
 
:***Input: Parcellation.gipl,  Atlas_Registered_Transform.txt, Image_Corrected_EMS_Stripped.gipl
 
:***Output:  Parcellation_Registered.gipl
 
  ResampleVolume2 Parcellation.gipl Parcellation_Registered.gipl -f Atlas_Registered_Transform.txt -i nn -R Image_Corrected_EMS_Stripped.gipl
 
:* '''4. Cortical Thickness'''
 
:**Input: Parcellation_Registered.gipl, Label.gipl
 
:**Output: CortThick_Result_Dir/, WMCorticalThicknessMap, GMCorticalThicknessMap
 
  CortThickCLP CortThick_Result_Dir/ --par  Parcellation_Registered.gipl --inputSeg Label.gipl --SaveWM  WMCorticalThicknessMap  --SaveGM GMCorticalThicknessMap
 
  
 
=== Analysis on a small pediatric dataset ===
 
=== Analysis on a small pediatric dataset ===
  
Tests have been computed on a small pediatric dataset, including 2 years old and 4 years old cases
+
Tests have been computed on a small pediatric dataset which includes 2 year-old and 4 year-old cases.
:* 16 Autistic cases  
+
:* 16 autistic cases  
 
:* 1 developmental delay
 
:* 1 developmental delay
 
:* 3 normal control
 
:* 3 normal control
  
=== Pearson correlation analysis ===
+
=== Comparison to state of the art ===
 
 
We would like to perform a regional statistical analysis (Pearson correlation analysis) to compare our method with FreeSurfer.
 
 
 
The study is in progress and the dataset includes 90 cases (2 and 4 years old).
 
 
 
Two studies will be done : 1 for the 2 years old cases and 1 for the 4 ones.
 
 
 
 
 
 
 
  
 +
We would like to compare our pipeline with FreeSurfer. We have thus performed a [[DBP2:UNC:Cortical_Thickness_Comparison | regional statistical analysis]] based on Pearson's correlation on an adult dataset (FreeSurfer's publicly available dataset) including 40 cases. We also performed [[DBP2:UNC:Cortical_Thickness_Comparison#Tests_on_a_longitudinal_pediatric_autism_study | tests on a longitudinal autism study]] of 86 subject aged 2-4 years.
  
<center>
+
== Planning ==
{|
 
|[[Image:T1Image.jpg|thumb|250px|T1-weighted skull-stripped image]]
 
|valign="center"|[[Image:Parcellation.jpg|thumb|250px|Parcellation image]]
 
|}
 
{|
 
|valign="center"|[[Image:WMThickness.jpg|thumb|250px|Cortical thickness on WM surface]]
 
|valign="center"|[[Image:ThicknessInformation.jpg|thumb|250px|Cortical thickness information]]
 
|}
 
</center>
 
  
 
=== Done ===
 
=== Done ===
 
:* Workflow for individual analysis (Slicer3 external module using BatchMake)
 
:* Workflow for individual analysis (Slicer3 external module using BatchMake)
 
:* 2 Tutorials with application example on a small dataset : "How to use the UNC modules to compute the regional cortical thickness" and "How to use ARCTIC"
 
:* 2 Tutorials with application example on a small dataset : "How to use the UNC modules to compute the regional cortical thickness" and "How to use ARCTIC"
 +
:* Pediatric and adult brain atlases available to the community via MIDAS
 +
:* ARCTIC available to the community via NITRC: executables (UNC external modules for Slicer3) and Tutorial dataset
 +
:** New version including quality control through MRML scene, and WM, GM models generation
 +
:** Mac and windows executables also available on to the community through NITRC
 +
:** Input images orientation automatically managed by ARCTIC
 +
:* ARCTIC source code (SVN, CVS) available to the community
 +
:* ARCTIC executable can be downloaded directly within Slicer3 using the extension wizard
 +
:* Comparison to FreeSurfer (40 cases dataset): pearson correlation analysis
  
=== In progress ===
+
== References ==
:* Pediatric atlases (T1-weighted image, parcellation map, probability maps) available to the community (MIDAS : NAMIC stuff)
 
:* Regional analysis to compare our method with results from FreeSurfer
 
:* ARCTIC executables (UNC external modules for Slicer3D), Source code (SVN) and Tutorial dataset available on NITRC
 
  
=== Future work ===
+
*Hazlett HC, Poe MD, Gerig G, Styner M, Chappell C, Smith RG, Vachet, C., & Piven, J., Early brain overgrowth in autism results from an increase in cortical surface area before age 2, Arch Gen Psychiatry. 2011;68(5):1-10
:* Workflow for group analysis (KWWidgets application using BatchMake)
+
*H.C. Hazlett, C. Vachet, C. Mathieu, M. Styner, J. Piven, Use of the Slicer3 Toolkit to Produce Regional Cortical Thickness Measurement of Pediatric MRI Data, presented at the 8th Annual International Meeting for Autism Research (IMFAR) Chicago, IL 2009.
 +
*C. Mathieu, C. Vachet, H.C. Hazlett, G. Geric, J. Piven, and M. Styner, ARCTIC – Automatic Regional Cortical ThICkness Tool, UNC Radiology Research Day 2009 abstract

Latest revision as of 17:46, 10 July 2017

Home < DBP2:UNC:Regional Cortical Thickness Pipeline
Back to  UNC Cortical Thickness Roadmap
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Objective

We would like to create an end-to-end application within Slicer3 allowing individual and group analysis of regional cortical thickness.

This page describes the related pipeline with its basic components, as well as its validation.


Pipeline overview

A Slicer3 high-level module for individual cortical thickness analysis has been developed: ARCTIC (Automatic Regional Cortical ThICkness)

Input: RAW images (T1-weighted, T2-weighted, PD-weighted images)

  • 1. Tissue segmentation
    • Probabilistic atlas-based automatic tissue segmentation via an Expectation-Maximization scheme
    • Tool: itkEMS (UNC Slicer3 external module)
  • 2. Regional atlas deformable registration
    • 2.1 Skull stripping using previously computed tissue segmentation label image
      • Tool: SegPostProcess (UNC Slicer3 external module)
    • 2.2 T1-weighted atlas deformable registration
      • B-spline pipeline registration
      • Tool: RegisterImages (Slicer3 module)
    • 2.3. Applying transformation to the parcellation map
      • Tool: ResampleVolume2 (Slicer3 module)
  • 3. Cortical thickness measurement
    • Sparse asymmetric local cortical thickness
    • Tool: CortThick (UNC Slicer3 external module)
  • 4. Statistics
    • Volume information (WM, GM, CSF, lobes) stored in spreadsheet
    • Tools: ImageMath, ImageStat (UNC Slicer3 external modules)
  • 5. Mesh creation
    • White matter and grey matter meshes creation
    • Tool: ModelMaker (Slicer3 module)
  • 6. MRML scene creation for quality control
    • MRML scene creation allowing quality control for each step of the pipeline
    • Output images and surfaces are automatically displayed

All the tools used in the current pipeline are Slicer3 modules, some of them being UNC external modules. The user can thus compute an individual regional cortical thickness analysis by running the 'ARCTIC' module, either within Slicer3 or as a command line.

Download

ARCTIC download

Source code, executables and tutorial are available on NITRC

Complementary downloads

Brain atlases

Four brain atlases are available on MIDAS:

Pediatric Brain MRI data

Data of 2 autistic children and 2 normal controls (male, female) scanned at 2 years with follow up at 4 years from a 1.5T Siemens scanner. Files include structural data, tissue segmentation label map and subcortical structures segmentation.

Tutorials

  • ARCTIC tutorial : end-to-end Slicer3 module to perform automatic regional cortical thickness analysis‏ [ppt]‏ [pdf]
    • 1st Prize: NAMIC tutorial contest AHM 2009
    • 2nd Prize: NAMIC tutorial contest summer project week 2009
  • UNC Modules tutorial : UNC Slicer3 modules to perform regional cortical thickness analysis step by step [ppt]‏ [pdf]‏
T1-weighted skull-stripped image
Parcellation image
Cortical thickness on WM surface
Cortical thickness information

Pipeline validation

Analysis on a small pediatric dataset

Tests have been computed on a small pediatric dataset which includes 2 year-old and 4 year-old cases.

  • 16 autistic cases
  • 1 developmental delay
  • 3 normal control

Comparison to state of the art

We would like to compare our pipeline with FreeSurfer. We have thus performed a regional statistical analysis based on Pearson's correlation on an adult dataset (FreeSurfer's publicly available dataset) including 40 cases. We also performed tests on a longitudinal autism study of 86 subject aged 2-4 years.

Planning

Done

  • Workflow for individual analysis (Slicer3 external module using BatchMake)
  • 2 Tutorials with application example on a small dataset : "How to use the UNC modules to compute the regional cortical thickness" and "How to use ARCTIC"
  • Pediatric and adult brain atlases available to the community via MIDAS
  • ARCTIC available to the community via NITRC: executables (UNC external modules for Slicer3) and Tutorial dataset
    • New version including quality control through MRML scene, and WM, GM models generation
    • Mac and windows executables also available on to the community through NITRC
    • Input images orientation automatically managed by ARCTIC
  • ARCTIC source code (SVN, CVS) available to the community
  • ARCTIC executable can be downloaded directly within Slicer3 using the extension wizard
  • Comparison to FreeSurfer (40 cases dataset): pearson correlation analysis

References

  • Hazlett HC, Poe MD, Gerig G, Styner M, Chappell C, Smith RG, Vachet, C., & Piven, J., Early brain overgrowth in autism results from an increase in cortical surface area before age 2, Arch Gen Psychiatry. 2011;68(5):1-10
  • H.C. Hazlett, C. Vachet, C. Mathieu, M. Styner, J. Piven, Use of the Slicer3 Toolkit to Produce Regional Cortical Thickness Measurement of Pediatric MRI Data, presented at the 8th Annual International Meeting for Autism Research (IMFAR) Chicago, IL 2009.
  • C. Mathieu, C. Vachet, H.C. Hazlett, G. Geric, J. Piven, and M. Styner, ARCTIC – Automatic Regional Cortical ThICkness Tool, UNC Radiology Research Day 2009 abstract