Abstract

To develop a nonlinear, model-based parameter estimation method directly from incomplete measurements in k-w space for robust spectral analysis in highly accelerated chemical exchange saturation transfer (CEST) magnetic resonance imaging (MRI). A CEST-specific, separable nonlinear model, which describes spectral decomposition using multi-pool Lorentzian functions (conventional magnetization transfer (MT), direct saturation
of water signals (DS), amide, amine, and nuclear Overhauser effect (NOE)) derived from the steady-state Bloch McConnel equation, is incorporated into a measurement model in CEST MRI. Furthermore, signal drop in saturation transfer experiments is formulated by an additional, separable nonlinear spectral prior indicating that the symmetric z-spectra synthesized using conventional MT and DS always remain higher or equal to the whole z-spectra with all pools. Given the above considerations, linear and nonlinear parameters in the proposed method are estimated in an alternating fashion directly from highly incomplete measurements in k-w space by solving a constrained optimization problem with the physics-constrained
spectral priors while imposing additional sparsity priors on spatial parameter maps. Main
results. Compared with conventional methods, the proposed method yields clearer delineation of tumor-specific CEST maps without apparent artifact and noise. We successfully demonstrated the feasibility of the proposed method for CEST MRI with highly
incomplete measurements thus enabling high-resolution whole brain CEST MRI in clinically reasonable imaging time.

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