Title :
Nonlinear Regularization for Per Voxel Estimation of Magnetic Susceptibility Distributions From MRI Field Maps
Author :
Kressler, Bryan ; De Rochefort, Ludovic ; Liu, Tian ; Spincemaille, Pascal ; Jiang, Quan ; Wang, Yi
Author_Institution :
Dept. of Biomed. Eng., Cornell Univ., Ithaca, NY, USA
Abstract :
Magnetic susceptibility is an important physical property of tissues, and can be used as a contrast mechanism in magnetic resonance imaging (MRI). Recently, targeting contrast agents by conjugation with signaling molecules and labeling stem cells with contrast agents have become feasible. These contrast agents are strongly paramagnetic, and the ability to quantify magnetic susceptibility could allow accurate measurement of signaling and cell localization. Presented here is a technique to estimate arbitrary magnetic susceptibility distributions by solving an ill-posed inversion problem from field maps obtained in an MRI scanner. Two regularization strategies are considered: conventional Tikhonov regularization and a sparsity promoting nonlinear regularization using the l 1 norm. Proof of concept is demonstrated using numerical simulations, phantoms, and in a stroke model in a rat. Initial experience indicates that the nonlinear regularization better suppresses noise and streaking artifacts common in susceptibility estimation.
Keywords :
biological tissues; biomagnetism; biomedical MRI; cellular biophysics; diseases; magnetic susceptibility; medical image processing; molecular biophysics; numerical analysis; phantoms; physiological models; MRI field maps; Tikhonov regularization; cell localization; ill-posed inversion problem; labeling stem cells; magnetic resonance imaging; magnetic susceptibility distributions; noise suppression; nonlinear regularization; numerical simulations; phantoms; rat; signaling molecules; sparsity; streaking artifacts; stroke model; tissues; voxel estimation; Imaging phantoms; Labeling; Magnetic field measurement; Magnetic properties; Magnetic resonance imaging; Magnetic susceptibility; Mechanical factors; Numerical simulation; Paramagnetic materials; Stem cells; Deconvolution; inversion; magnetic field; magnetic resonance imaging; magnetic susceptibility; quantification; Algorithms; Animals; Brain; Computer Simulation; Contrast Media; Image Processing, Computer-Assisted; Magnetic Resonance Imaging; Male; Models, Theoretical; Nonlinear Dynamics; Phantoms, Imaging; Rats; Rats, Wistar; Stroke;
Journal_Title :
Medical Imaging, IEEE Transactions on
DOI :
10.1109/TMI.2009.2023787
