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The MITK Diffusion application [1,2] offers a selection of image analysis algorithms for the processing of diffusion-weighted MR images. It encompasses the research of the Division Medical Image Computing at the German Cancer Research Center (DKFZ).

Features & Highlights

Support for most established image formats

  • Images: DICOM, NIFTI, NRRD (peak and SH images compatible with MRtrix)
  • Tractograms: fib/vtk, tck and trk.

Image preprocessing

  • Registration
  • Head-motion correction
  • Denoising
  • Skull stripping and brain mask segmentation (Linux only)
  • Resampling, cropping, flipping and merging
  • Header modifications
  • Single volume extraction

Diffusion gradient/b-value processing

  • b-value rounding
  • Gradient direction flipping
  • Gradient direction subsampling
  • Averaging of gradient directions/volumes
  • Gradient direction and b-value visualization

ODF reconstruction and signal modelling

  • Tensor and Q-ball reconstruction
  • Other reconstructions via Dipy wrapping (CSD, 3D SHORE, SFM) (Linux only)
  • ODF peak calculation
  • MRtrix or camino results can be imported

Quantification of diffusion-weighted/tensor/ODF images

  • Intravoxel Incoherent Motion (IVIM) and diffusion kurtosis analysis
  • Calculation of many other derived indices such as ADC, MD, GFA, FA, RA, AD, RD
  • Image statistics


  • Automatic white matter bundle segmentation (TractSeg) [3] (Linux only)
  • Automatic brain mask segmentation (Linux only)
  • Manual image segmentation and operations on segmentations
  • SOON: automatic brain tissue segmentation

Fiber tractography

  • Global tractography [4]
  • Streamline tractography
    • Interactive (similar to [5]) or seed image based
    • Deterministic or probabilistic
    • Peak, ODF, tensor and raw dMRI based. The latter one in conjunction with machine learning based tractography [6]
    • Various possibilities for anatomical constraints.
    • Tractography priors in form of additional peak images, e.g. obtained using TractSeg

Fiber processing

  • Tract dissection (parcellation or ROI based)
  • Tract filtering by
    • length
    • curvature
    • direction
    • weight
    • density
  • Tract resampling and compression
  • Tract transformation
    • Mirroring
    • Rotating and translating
    • Registration (apply transform of previously performed image registration)
  • Tract coloring
    • Curvature
    • Length
    • Weight
    • Scalar map (e.g. FA)
  • Other operations
    • Join
    • Subtract
    • Copy
  • Fiber clustering [7]
  • Fiber fitting and weighting similar to SIFT2 and LiFE [8,9]
  • Principal direction extraction (fibers --> peaks)
  • Tract derived images:
    • Tract density images
    • Tract endpoint images
    • Tract envelopes

Fiberfox dMRI simulations [10]

  • Multi-compartment signal modeling
  • Simulation of the k-space acquisition including
    • Compartment specific relaxation effects
    • Artifacts such as noise, spikes, ghosts, aliasing, distortions, signal drift, head motion, eddy currents and Gibbs ringing
    • Definition of important acquisition parameters such as bvalues and gradient directions, TE, TR, dwell time, partial Fourier, ...
  • Manual definition of fiber configurations, e.g. for evaluation purposes
  • Automatic generation of random fiber configurations

Other features

  • Brain network statistics and visualization (connectomics)
  • Interactive Python console (Linux only)
  • Integrated screenshot maker
  • Command line tools for most functionalities

Related Links

Image Gallery


Screenshot of the MITK Diffusion Welcome Screen


Scalar map visualization

Data Tensors.png

Tensor Visualization

Data ODF.png

ODF visualization

Data Peaks.png

Peak visualization (uniform white coloring)


Interactive tractography in MITK Diffusion. The tractogram updates automatically on parameter change and movement of the spherical seed region.

Extraction 1.png

Tract dissection using manually drawn ROIs.


Result of automatic streamline weighting (similar to SIFT2 or LiFE)


Illustration of the dMRI phantom simulation process using Fiberfox.

Eddy.gif Spike and motion.gif Drift.gif

645551 axial motion ghost eddy.gif Ringing.gif 683256 Distortions Sagittal.gif

Illustration of simulated dMRI images with various artifacts (a bit excessive for illustration purposes): eddy current distortions, motion and spike, intensity drift, motion, eddy and noise, motion, B0 inhomogeneity distortions.

RandomFibers Example.png

Automatically generated random fiber configuration for Fiberfox simulations.


Nightly Ubuntu and Windows installers:

Please also have a look at the requirements for running MITK Diffusion with all its features successfully!

The installers come as executable setup wizards that install MITK Diffusion on your system or alternatively as simple .tar.gz or .zip archive where you can execute MITK Diffusion and the command line apps "manually". Should there be no new installer for a while, please contact us and report the issue.

If you encounter any bugs, please report them in our bugtracking system or use the MITK-users mailing list. We are grateful for any feedback!


  • For Windows users:
    • MITK Diffusion requires the Microsoft Visual C++ 2017 Redistributable to be installed on the system. The MITK Diffusion installer automatically installs this redistributable for you if not already present on the system, but it needs administrative privileges to do so. So to install the redistributable, run the MITK Diffusion installer as administrator.
    • Python modules are disabled under Windows!

Building MITK Diffusion from source

  1. Install Qt on your system (>= 5.11.1).
  2. Clone MITK from out git repository using Git version control.
  3. Configure the MITK Superbuild using CMake (>= 3.13).
    1. Choose the source code directory and an empty binary directory.
    2. Click "Configure".
    3. Set the option MITK_BUILD_CONFIGURATION to "DiffusionRelease".
    4. Click "Generate".
    5. macOS specifics:
      1. Use python 3.6, since python 3.7 leads to build errors on macOS.
      2. The cmake variables for python 3 might need to be set manually. It is probably enough to specify PYTHON_EXECUTABLE.
      3. Openmp needs to be installed manually since it is not included in apple clang anymore: "brew install libomp" should do the trick. It might be necessary to set the corresponding make variables later in the MITK build manually:
        1. OpenMP_CXX_FLAGS: -Xpreprocessor -fopenmp -I"/path/to/python3/includes/"
        2. OpenMP_C_FLAGS: -Xpreprocessor -fopenmp -I"/path/to/python3/includes/"
        3. OpenMPCXX_LIB_NAMES: libomp
        4. OpenMPC_LIB_NAMES: libomp
        5. OpenMP_libomp_LIBRARY: /path/to/libomp.dylib
  4. Build the project
    1. Linux/maxOS: Open a console window, navigate to the build folder and type "make -j8" (optionally supply the number threads to be used for a parallel build with -j).
    2. Windows (requires visual studio): Open the MITK Superbuild solution file and build all projects.
  5. The build may take some time and should yield the binaries in "your_build_folder/MITK-build/bin"

More detailed build instructions can be found in the documentation.

Continuous integration:


All publications of the Division of Medical Image Computing can be found here.

[1] Fritzsche, Klaus H., Peter F. Neher, Ignaz Reicht, Thomas van Bruggen, Caspar Goch, Marco Reisert, Marco Nolden, et al. “MITK Diffusion Imaging.” Methods of Information in Medicine 51, no. 5 (2012): 441.

[2] Fritzsche, K., and H.-P. Meinzer. “MITK-DI A New Diffusion Imaging Component for MITK.” In Bildverarbeitung Für Die Medizin, n.d.

[3] Wasserthal, Jakob, Peter Neher, and Klaus H. Maier-Hein. “TractSeg - Fast and Accurate White Matter Tract Segmentation.” NeuroImage 183 (August 4, 2018): 239–53.

[4] Neher, P. F., B. Stieltjes, M. Reisert, I. Reicht, H.P. Meinzer, and K. Maier-Hein. “MITK Global Tractography.” In SPIE Medical Imaging: Image Processing, 2012.

[5] Chamberland, M., K. Whittingstall, D. Fortin, D. Mathieu, und M. Descoteaux. „Real-time multi-peak tractography for instantaneous connectivity display“. Front Neuroinform 8 (2014): 59. doi:10.3389/fninf.2014.00059.

[6] Neher, Peter F., Marc-Alexandre Côté, Jean-Christophe Houde, Maxime Descoteaux, and Klaus H. Maier-Hein. “Fiber Tractography Using Machine Learning.” NeuroImage. Accessed July 17, 2017. doi:10.1016/j.neuroimage.2017.07.028.

[7] Garyfallidis, Eleftherios, Matthew Brett, Marta Morgado Correia, Guy B. Williams, and Ian Nimmo-Smith. “QuickBundles, a Method for Tractography Simplification.” Frontiers in Neuroscience 6 (2012).

[8] Smith, Robert E., Jacques-Donald Tournier, Fernando Calamante, and Alan Connelly. “SIFT2: Enabling Dense Quantitative Assessment of Brain White Matter Connectivity Using Streamlines Tractography.” NeuroImage 119, no. Supplement C (October 1, 2015): 338–51.

[9] Pestilli, Franco, Jason D. Yeatman, Ariel Rokem, Kendrick N. Kay, and Brian A. Wandell. “Evaluation and Statistical Inference for Human Connectomes.” Nature Methods 11, no. 10 (October 2014): 1058–63.

[10] Neher, Peter F., Frederik B. Laun, Bram Stieltjes, and Klaus H. Maier-Hein. “Fiberfox: Facilitating the Creation of Realistic White Matter Software Phantoms.” Magnetic Resonance in Medicine 72, no. 5 (November 2014): 1460–70. doi:10.1002/mrm.25045.


If you have questions about the application or if you would like to give us feedback, don't hesitate to contact us using our mailing list or, for questions that are of no interest for the community, directly.

  • This page was last modified on 18 February 2019, at 10:27.
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