Diffusion Tensor Imaging (DTI) is becoming a routine technique to study white matter properties and...
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Transcript of Diffusion Tensor Imaging (DTI) is becoming a routine technique to study white matter properties and...
Diffusion Tensor Imaging (DTI) is becoming a routine technique to study white matter properties and alterations of fiber integrity due to pathology. The advanced MRI technique needs post processing by adequate image analysis and visualization tools. We have developed an integrated software package for efficient processing, fiber* tracking, and interactive visualization of DTI data. This allows even non-expert to explore DTI data and to obtain results that so far were exclusive to research teams with strong computer science support.
The tool guides a user through the various processing stages including tensor calculation, calculation of fractional anisotropy (FA) and apparent diffusion coefficient (ADC), extraction of fiber* bundles between source and target regions of interest (ROI), and 2-D and 3-D visualization of diffusion images and fibers*.
* The term “fiber” is used to describe streamlines extracted from tensor fields. These
streamlines represent diffusion properties of wm bundles but not individual fibers.
MotivationMotivation::
Analysis Analysis ToolTool For Diffusion Tensor MRI For Diffusion Tensor MRIPierre FillardPierre Fillard11 and Guido Gerig and Guido Gerig1,21,2
11Depts. of CS, Depts. of CS, 22Psychiatry, University of North Carolina at Chapel HillPsychiatry, University of North Carolina at Chapel Hill
Program features:Program features:
Result of the reconstruction of 4 major fibers tracts (blue: cortico-spinal tract, red: splenium and genu tracts, yellow: longitudinal fasciculi,
green: cingulate)
The DTI processing tool is freely The DTI processing tool is freely
available atavailable at http://midag.cs.unc.edu http://midag.cs.unc.edu
This software has been developed in ITK (NLM sponsored Insight Toolkit), a powerful C++ library dedicated to medical image processing.
Currently, the DTI tool is available for Windows® PC, Linux and UNIX Sun Solaris.
What’s behind:What’s behind:
STEP 1: STEP 1: Loading of the DTI Loading of the DTI dataset into the tooldataset into the tool
The user can switch between the diffusion tensor images through a simple list. In the
example, the B0 image is displayed as orthogonal cuts and a 3D view by three
orthogonal slices.
STEP 2: STEP 2: FA and ADC mapsFA and ADC mapscalculation with a simple clickcalculation with a simple click
The Processing tab allows to choose between FA (Fractional Anisotropy) and
ADC (Apparent Diffusion Coefficient) maps calculation. These maps can be
stored as 3D image data.
STEP 3: STEP 3: Manual ROI definitionManual ROI definition with IRIS/SNAP with IRIS/SNAP
The FA map has been loaded into IRIS/SNAP and a ROI has been manually
placed, here at the top of the corpus callosum. This ROI is then stored as a 3D
image data set.
Fiber Reconstruction Step by Step:Fiber Reconstruction Step by Step:
Full screen viewFull screen viewOutput formatsOutput formats
Binary image: a voxel is set to 1 if a fiber passes through, 0 otherwise.
Fiber file format: list of spatial coordinates of the center line of the reconstructed fibers (ITK data format for
curvilinear structures).
Example of a fiber-label image overlapped on the FA map. The surface defined by the fiber bundle has been rendered in 3D.
Cumulative mode: bright areas of the image correspond to high density fiber regions.
The DTI Processing tool GUI showing 2-D and 3-D visualization options (ROIs, streamlines and FA level surface).
The ROI is finally loaded into the tool and the resulting tracking is shown in a 3D
window. The fibers are represented by 3D poly-tubes (ITK format).
Top right: 3-D vector field view (axial plane).
STEP 4: STEP 4: LoadingLoading of theof the ROI and ROI and fiber reconstructionfiber reconstruction
Cumulative image: voxel values are directly related to the “density” of fibers.
• Loading input DTI data (7 volumetric images, GIPL, Analyze or DICOM-META format).
• Estimation of the Tensor field and calculation of ADC and FA maps.
• 2-D orthogonal slice visualization of DTI data and of ADC and FA images.
• 3-D vector field visualization.
• Loading label image with user-defined Regions Of Interest (ROIs).
• Fiber tracking:
• a) from target to source ROIs
• b) from full brain to source ROI.
• 3-D interactive visualization of fiber bundles, FA isosurface, source and target ROIs, and of user-selected image channels.
• Storing of fiber bundles as sets of poly-lines or as binary fiber-tract label images.
• Storing of FA, ADC image data and of 3-D displays. MICCAI 2003, Nov. 2003