English

Dictionary-Free MRI PERK: Parameter Estimation via Regression with Kernels

Machine Learning 2019-06-14 v1 Signal Processing Medical Physics

Abstract

This paper introduces a fast, general method for dictionary-free parameter estimation in quantitative magnetic resonance imaging (QMRI) via regression with kernels (PERK). PERK first uses prior distributions and the nonlinear MR signal model to simulate many parameter-measurement pairs. Inspired by machine learning, PERK then takes these parameter-measurement pairs as labeled training points and learns from them a nonlinear regression function using kernel functions and convex optimization. PERK admits a simple implementation as per-voxel nonlinear lifting of MRI measurements followed by linear minimum mean-squared error regression. We demonstrate PERK for T1,T2T_1,T_2 estimation, a well-studied application where it is simple to compare PERK estimates against dictionary-based grid search estimates. Numerical simulations as well as single-slice phantom and in vivo experiments demonstrate that PERK and grid search produce comparable T1,T2T_1,T_2 estimates in white and gray matter, but PERK is consistently at least 23×23\times faster. This acceleration factor will increase by several orders of magnitude for full-volume QMRI estimation problems involving more latent parameters per voxel.

Keywords

Cite

@article{arxiv.1710.02441,
  title  = {Dictionary-Free MRI PERK: Parameter Estimation via Regression with Kernels},
  author = {Gopal Nataraj and Jon-Fredrik Nielsen and Clayton Scott and Jeffrey A. Fessler},
  journal= {arXiv preprint arXiv:1710.02441},
  year   = {2019}
}

Comments

submitted to IEEE Transactions on Medical Imaging

R2 v1 2026-06-22T22:05:46.789Z