An Evaluation of Regularization Strategies for Subsampled Single-Shell Diffusion MRI

Conventional single-shell diffusion MRI experiments acquire sampled values of the diffusion signal from the surface of a sphere in q-space. However, to reduce data acquisition time, there has been recent interest in using regularization to enable q-space undersampling. Although different regularization strategies have been proposed for this purpose (i.e., sparsity-promoting of the spherical ridgelet representation and Laplace-Beltrami Tikhonov regularization), there has not been a systematic evaluation of the strengths, weaknesses, and potential synergies of the different regularizers. In this work, we use real diffusion MRI data to systematically evaluate the performance characteristics of these different approaches and determine whether one approach is fundamentally more powerful than the other. Results from retrospective subsampling experiments suggest that both regularization strategies offer largely similar reconstruction performance (though with different levels of computational complexity) with some degree of synergy (albeit, relatively minor).

[1]  Yogesh Rathi,et al.  High‐resolution in vivo diffusion imaging of the human brain with generalized slice dithered enhanced resolution: Simultaneous multislice (gSlider‐SMS) , 2018, Magnetic resonance in medicine.

[2]  Justin P. Haldar,et al.  Linear transforms for Fourier data on the sphere: Application to high angular resolution diffusion MRI of the brain , 2013, NeuroImage.

[3]  Marc Teboulle,et al.  A Fast Iterative Shrinkage-Thresholding Algorithm for Linear Inverse Problems , 2009, SIAM J. Imaging Sci..

[4]  Duan Xu,et al.  Q‐ball reconstruction of multimodal fiber orientations using the spherical harmonic basis , 2006, Magnetic resonance in medicine.

[5]  Anand A. Joshi,et al.  Improved B0‐distortion correction in diffusion MRI using interlaced q‐space sampling and constrained reconstruction , 2014, Magnetic resonance in medicine.

[6]  Yogesh Rathi,et al.  On Approximation of Orientation Distributions by Means of Spherical Ridgelets , 2008, IEEE Transactions on Image Processing.

[7]  Yogesh Rathi,et al.  High‐fidelity, accelerated whole‐brain submillimeter in vivo diffusion MRI using gSlider‐spherical ridgelets (gSlider‐SR) , 2020, Magnetic resonance in medicine.

[8]  Kawin Setsompop,et al.  Fast submillimeter diffusion MRI using gSlider‐SMS and SNR‐enhancing joint reconstruction , 2019, Magnetic resonance in medicine.

[9]  Carl-Fredrik Westin,et al.  A joint compressed-sensing and super-resolution approach for very high-resolution diffusion imaging , 2016, NeuroImage.

[10]  Lawrence L. Wald,et al.  High‐fidelity, high‐isotropic‐resolution diffusion imaging through gSlider acquisition with B1+ and T1 corrections and integrated ΔB0/Rx shim array , 2018, Magnetic resonance in medicine.

[11]  R. Deriche,et al.  Regularized, fast, and robust analytical Q‐ball imaging , 2007, Magnetic resonance in medicine.

[12]  Jan Sijbers,et al.  Super‐resolution reconstruction of diffusion parameters from diffusion‐weighted images with different slice orientations , 2016, Magnetic resonance in medicine.