Difference between revisions of "DBP2:MIND:Roadmap"

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==Objective==
 
==Objective==
We would like to create an end-to-end application within NA-MIC Kit allowing individual and group analysis of white matter lesions. Such a workflow applied to lupus patients is one goals of the MIND DBP. This page describes the technology roadmap for lesion analysis in the NA-MIC Kit. The basic components necessary for this end-to-end application are:
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We would like to create an end-to-end application within NA-MIC Kit allowing individual analysis of white matter lesions. Such a workflow applied to lupus patients is one goals of the MIND DBP. This page describes the technology roadmap for lesion analysis in the NA-MIC Kit. The basic components necessary for this end-to-end application are:
 
* '''Registration''': co-registration of T1-weighted, T2-weighted, and FLAIR images
 
* '''Registration''': co-registration of T1-weighted, T2-weighted, and FLAIR images
 
* '''Tissue segmentation''': Should be multi-modality, correcting for intensity inhomogeneity and work on non-skull-stripped data.
 
* '''Tissue segmentation''': Should be multi-modality, correcting for intensity inhomogeneity and work on non-skull-stripped data.
 
* '''Lesion Localization''':  Each unique lesion should be detacted and anatomical location summarized  
 
* '''Lesion Localization''':  Each unique lesion should be detacted and anatomical location summarized  
 
* '''Lesion Load Measurement''': Measure volume of each lesion, summarize lesion load by regions
 
* '''Lesion Load Measurement''': Measure volume of each lesion, summarize lesion load by regions
* '''Statistical analysis/Hypothesis testing''': Lesion Measurements need to be compared and tested locally incorporating multiple-comparison correction, correlative analysis would be necessary too.
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* '''Tutorial''': Documentation will be written for a tutorial and sample data sets will be provided
  
  
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=== Performance characterization and validation ===
 
=== Performance characterization and validation ===
* Characterize response based on signal noise, patient motion, etc.
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:* Data will be collected at both 1.5 and 3T. Data at 1.5T will be obtained with the protocol utilized for current project on lupus at UNM.
* Comparison to other tools (FreeSurfer, itkEMS, UNC cortical thickness).  
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:* Data at 3T will be obtained with sequences optimized for segmentation by the group at Utah.
 
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:* Comparisons will be based on the approach developed by Martin-Fernandez et al.
 
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:* The algorithm with the best performance will be incorporated into the NA-MIC kit.
 
 
 
 
 
 
 
 
 
1) The tools developed by the UNC group (marcel)
 
 
2) The tools developed by the BWH group (EM-segment with lesion segmentation)
 
 
 
3) Tools within Medx (automated lesion classification package)
 
 
4) BRAINS2 (automated lesion classification package)
 
 
5) manual tracing
 
 
   
 
   
Data will be collected at both 1.5 and 3T. Data at 1.5T will be obtained with the protocol utilized for current project on lupus at UNM.
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=== Schedule ===
 
 
Data at 3T will be obtained with sequences optimized for segmentation by the group at Utah.
 
 
 
Comparisons will be based on the approach developed by Martin-Fernandez et al.
 
 
 
Incorporation into NA-MIC Kit
 
 
The algorithm with the best performance will be incorporated in Slicer3.
 
 
 
Tutorial
 
Documentation will be written for a tutorial and sample data sets will be provided
 
 
 
Hypothesis Testing
 
 
 
 
 
Performance characterization and validation
 
 
 
 
 
Schedule
 

Revision as of 09:52, 27 September 2007

Home < DBP2:MIND:Roadmap

Brain Lesion Analysis in Neuropsychiatric Systemic Lupus Erythematosus

Objective

We would like to create an end-to-end application within NA-MIC Kit allowing individual analysis of white matter lesions. Such a workflow applied to lupus patients is one goals of the MIND DBP. This page describes the technology roadmap for lesion analysis in the NA-MIC Kit. The basic components necessary for this end-to-end application are:

  • Registration: co-registration of T1-weighted, T2-weighted, and FLAIR images
  • Tissue segmentation: Should be multi-modality, correcting for intensity inhomogeneity and work on non-skull-stripped data.
  • Lesion Localization: Each unique lesion should be detacted and anatomical location summarized
  • Lesion Load Measurement: Measure volume of each lesion, summarize lesion load by regions
  • Tutorial: Documentation will be written for a tutorial and sample data sets will be provided


Roadmap

Starting with several MRI images (weighted-T1, weighted-T2, FLAIR...) we want to obtain lesion maps for each subject. Ultimately, the NA-MIC Kit will provide a workflow for individual and group analysis of lesions. It will be implemented as a set of Slicer3 modules that can be used interactively within the Slicer3 application as well as in batch on a computing cluster using BatchMake.

Next we discuss the main modules and details of current status and development work:

Registration

  • ITK has mutual information registration
  • BRAINS2 has AIR package wrapped

Lesion segmentation

A number of algorithms for fully or semi-automated lesion analysis will be evaluated on brain images from subjects in a study on lupus erythematosis. These include:

  • UNC has a tool called itkEMS Compare Lesion Analysis Tools (marcel)
  • EM-segment (sandy wells)
  • MedX (commercial package)
  • BRAINS2 (magnotta)
  • manual tracing by clinically trained rater

Lesion Localization

  • Freesurfer has tools for labelling
  • BRAINS2

Lesion Load Measurement

  • Freesurfer has tools for measurement of labelled lesions
  • BRAINS2 has tools for measurement of lesions and regional summaries

Performance characterization and validation

  • Data will be collected at both 1.5 and 3T. Data at 1.5T will be obtained with the protocol utilized for current project on lupus at UNM.
  • Data at 3T will be obtained with sequences optimized for segmentation by the group at Utah.
  • Comparisons will be based on the approach developed by Martin-Fernandez et al.
  • The algorithm with the best performance will be incorporated into the NA-MIC kit.

Schedule