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q-Space Deep Learning for Twelve-Fold Shorter and Model-Free Diffusion MRI Scans

V. Golkov, Alexey Dosovitskiy, P. Sämann, J. Sperl, T. Sprenger, M. Czisch, M. Menzel, P. Gómez, A. Haase, Thomas Brox, D. Cremers
Medical Image Computing and Computer-Assisted Intervention (MICCAI), 2015
Abstract: Diffusion MRI uses a multi-step data processing pipeline. With certain steps being prone to instabilities, the pipeline relies on considerable amounts of partly redundant input data, which requires long acquisition time. This leads to high scan costs and makes advanced diffusion models such as diffusion kurtosis imaging (DKI) and neurite orientation dispersion and density imaging (NODDI) inapplicable for children and adults who are uncooperative, uncomfortable or unwell. We demonstrate how deep learning, a group of algorithms in the field of artificial neural networks, can be applied to reduce diffusion MRI data processing to a single optimized step. This method allows obtaining scalar measures from advanced models at twelve-fold reduced scan time and detecting abnormalities without using diffusion models.


Other associated files : MICCAI2015.pdf [280KB]  

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BibTex reference

@InProceedings{BD15,
  author       = "V. Golkov and A. Dosovitskiy and P. S{\"a}mann and J.I. Sperl and T. Sprenger and M. Czisch and M.I. Menzel and P.A. G{\'o}mez and A. Haase and T. Brox and D. Cremers",
  title        = "q-Space Deep Learning for Twelve-Fold Shorter and Model-Free Diffusion MRI Scans",
  booktitle    = "Medical Image Computing and Computer-Assisted Intervention (MICCAI)",
  year         = "2015",
  url          = "http://lmbweb.informatik.uni-freiburg.de/Publications/2015/BD15"
}

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