Motion Is Inevitable: The Impact of Motion Correction Schemes on HARDI Reconstructions

Diffusion weighted imaging (DWI) is known to be prone to artifacts related to motion originating from subject movement, cardiac pulsation and breathing, but also to mechanical issues such as table vibrations. Given the necessity for rigorous quality control and motion correction, users are often left to use simple heuristics to select correction schemes, but do not fully understand the consequences of such choices on the final analysis, moreover being at risk to introduce confounding factors in population studies. This paper reports work in progress towards a comprehensive evaluation framework of HARDI motion correction to support selection of optimal methods to correct for even subtle motion. We make use of human brain HARDI data from a well controlled motion experiment to simulate various degrees of motion corruption. Choices for correction include exclusion or registration of motion corrupted directions, with different choices of interpolation. The comparative evaluation is based on studying effects of motion correction on three different metrics commonly used when using DWI data, including similarity of fiber orientation distribution functions (fODFs), global brain connectivity via Graph Diffusion Distance (GDD), and reproducibility of prominent and anatomically defined fiber tracts. Effects of various settings are systematically explored and illustrated, leading to the somewhat surprising conclusion that a best choice is the alignment and interpolation of all DWI directions, not only directions considered as corrupted.

[1]  Martin Styner,et al.  DTIPrep: quality control of diffusion-weighted images , 2014, Front. Neuroinform..

[2]  Brian B. Avants,et al.  Symmetric diffeomorphic image registration with cross-correlation: Evaluating automated labeling of elderly and neurodegenerative brain , 2008, Medical Image Anal..

[3]  Maxime Descoteaux,et al.  Dipy, a library for the analysis of diffusion MRI data , 2014, Front. Neuroinform..

[4]  Derek K. Jones Diffusion MRI: Theory, methods, and applications , 2011 .

[5]  Rachid Deriche,et al.  Motion Detection in Diffusion MRI via Online ODF Estimation , 2013, Int. J. Biomed. Imaging.

[6]  Jacques-Donald Tournier,et al.  Diffusion tensor imaging and beyond , 2011, Magnetic resonance in medicine.

[7]  Yi Wang,et al.  Quality control of diffusion weighted images , 2010, Medical Imaging.

[8]  David K. Hammond,et al.  Graph diffusion distance: A difference measure for weighted graphs based on the graph Laplacian exponential kernel , 2013, 2013 IEEE Global Conference on Signal and Information Processing.

[9]  Arthur W. Toga,et al.  Atlas-based whole brain white matter analysis using large deformation diffeomorphic metric mapping: Application to normal elderly and Alzheimer's disease participants , 2009, NeuroImage.

[10]  Tobias Kober,et al.  Prospective and retrospective motion correction in diffusion magnetic resonance imaging of the human brain , 2012, NeuroImage.

[11]  Carlo Pierpaoli,et al.  Estimating intensity variance due to noise in registered images: Applications to diffusion tensor MRI , 2005, NeuroImage.

[12]  Chun-Hung Yeh,et al.  Resolving crossing fibres using constrained spherical deconvolution: Validation using diffusion-weighted imaging phantom data , 2008, NeuroImage.

[13]  J. R. Landis,et al.  The measurement of observer agreement for categorical data. , 1977, Biometrics.

[14]  Arthur W. Toga,et al.  Atlas-guided tract reconstruction for automated and comprehensive examination of the white matter anatomy , 2010, NeuroImage.

[15]  Michael Brady,et al.  Improved Optimization for the Robust and Accurate Linear Registration and Motion Correction of Brain Images , 2002, NeuroImage.

[16]  Julien Cohen-Adad,et al.  Quality assessment of high angular resolution diffusion imaging data using bootstrap on Q‐ball reconstruction , 2011, Journal of magnetic resonance imaging : JMRI.

[17]  Carlo Pierpaoli,et al.  Artifacts in Diffusion MRI , 2010 .