Systems and methods for quantitative magnetic resonance imaging

1 . A method for magnetic resonance imaging (MRI) of a patient, comprising: performing a steady-state acquisition to obtain first MR signals of a scan volume; performing a transient-state acquisition to obtain second MR signals of the scan volume; determining, for each voxel of the scan volume, a respective proton density (PD) based on the first MR signals; determining, for each voxel of the scan volume, one or more respective quantitative MR (qMR) parameters based on the second MR signals and the respective PD for that voxel; and outputting one or more parameter maps for display and/or storage based on the one or more respective qMR parameters. 2 . The method of claim 1 , wherein the steady-state acquisition comprises read-out of the first MR signals during steady-state magnetization, and wherein the transient-state acquisition comprises read-out of the second MR signals during transient-state magnetization. 3 . The method of claim 2 , wherein the steady-state acquisition comprises playouts of gradient echo, ultra-short TE, or zero TE pulse sequences. 4 . The method of claim 3 , wherein the gradient echo, ultra-short TE, or zero TE pulse sequences have a flip angle of less than 5° and a repetition time of less than T 1 . 5 . The method of claim 2 , wherein: the transient-state acquisition comprises playouts of RF pulses and magnetic field gradient pulses to generate T 1 contrast and/or T 2 contrast; the transient-state acquisition comprises playouts of inversion pulses and a plurality of read-outs of the MR signals during recovery of longitudinal magnetization; or the transient-state acquisition comprises playouts of read-out of the second MR signals after a T 2 -prep pulse and a plurality of read-outs of the MR signals after a T 1 -prep pulse; or the transient-state acquisition comprises an MR fingerprinting type encoding with modulation of the flip angle and/or the repetition time. 6 . The method of claim 1 , wherein: determining, for each voxel of the scan volume, the respective PD based on the first MR signals comprises determining, for each voxel of the scan volume, a respective first PD based on the first MR signals; and determining, for each voxel of the scan volume, one or more respective qMR parameters based on the second MR signals and the respective PD for that voxel comprises determining, for each voxel of the scan volume, an initial T 1 value based on the second MR signals and the respective first PD for that voxel; and further comprising: correcting each respective first PD based on the initial T 1 value for that voxel to generate a respective second PD for each voxel of the scan volume; and determining, for each voxel of the scan volume, one or more respective refined qMR parameters based on the second MR signals and the respective second PD for that voxel. 7 . The method of claim 6 , wherein outputting one or more parameter maps for display and/or storage based on the one or more respective qMR parameters comprises outputting one or more parameter maps for display and/or storage based on the one or more respective refined qMR parameters. 8 . The method of claim 1 , wherein the first MR signals are spatially encoded with a geometrical-coverage and resolution which encompasses a spatial encoding of the second MR signals. 9 . The method of claim 1 , wherein the second MR signals collectively form a set of measurements, and wherein determining the one or more respective qMR parameters comprises scaling each respective measurement from the set of measurements by a corresponding PD and performing fitting or dictionary-matching in a least-squares sense with each scaled measurement to determine the one or more respective qMR parameters. 10 . The method of claim 9 , wherein each measurement comprises a respective signal evolution, and determining the one or more respective qMR parameters comprises scaling each respective signal evolution by the corresponding PD and performing fitting or dictionary-matching with each scaled signal evolution relative to a precomputed dictionary. 11 . The method of claim 1 , wherein obtaining the first MR signals comprises obtaining a respective set of first MR signals from each of a plurality of receive coil elements, and further comprising performing coil sensitivity calibration based on each respective set of first MR signals. 12 . A system, comprising: a display device; one or more processors; and memory storing instructions executable by the one or more processors to: obtain, for each voxel of a scan volume, first MR signals using a steady-state pulse sequence; obtain, for each voxel of the scan volume, second MR signals using a transient-state pulse sequence; determine, for each voxel of the scan volume, a respective first proton density (PD) based on the first MR signals; determine, for each voxel of the scan volume, one or more respective quantitative MR (qMR) parameters based on the second MR signals and the respective first PD for that voxel, wherein the one or more respective qMR parameters includes a T 1 value for each voxel; correct, for each voxel of the scan volume, the respective first PD based on the T 1 value for that voxel to generate a respective second PD for each voxel; determine, for each voxel of the scan volume, one or more respective refined qMR parameters based on the second MR signals and the respective second PD for that voxel; and output one or more parameter maps for display on the display device and/or for storage based on the one or more respective refined qMR parameters. 13 . The system of claim 12 , wherein the one or more respective qMR parameters further comprise one or more of T 2 and T 2 *. 14 . The system of claim 12 , wherein the steady-state pulse sequence comprises a gradient echo, ultra-short TE, or zero TE pulse sequence. 15 . The system of claim 14 , wherein the steady-state pulse sequence has a flip angle of less than 5° and a repetition time of less than T 1 . 16 . A method for a magnetic resonance imaging (MRI) system, comprising: obtaining, for each voxel of a scan volume imaged with the MRI system, a respective proton density (PD)-normalized signal evolution, each PD-normalized signal evolution generated from first MR signals of the scan volume obtained with the MRI system during a steady-state acquisition and second MR signals of the scan volume obtained with the MRI system during a transient-state acquisition; determining a first parameter value and a second parameter value for each voxel of the scan volume based on each PD-normalized signal evolution using least-squared dictionary fitting; obtaining, for each voxel of the scan volume, a respective corrected PD-normalized signal evolution, each corrected PD-normalized signal evolution generated from the second MR signals of the scan volume and a respective corrected measured PD, each respective corrected measured PD corrected based on the first parameter value for that voxel; determining a refined first parameter value and a refined second parameter value for each voxel of the scan volume based on each corrected PD-normalized signal evolution using least-squared dictionary fitting; generating one or more parameter maps for the refined first parameter value and the refined second parameter value of each voxel of the scan volume; and outputting the one or more parameter maps for display on a display device and/or for storage. 17 . The method of claim 16 , wherein the steady-state acquisition comprises playouts of a gradient echo, ultra-short TE, or zero TE pulse sequence.