System and method for chemical exchange saturation transfer (CEST) magnetic resonance fingerprinting

The invention claimed is: 1. A method for using a magnetic resonance (MR) system to determine quantitative chemical exchange or exchangeable proton information from a subject, the steps of the method comprising: (a) directing the MR system to perform a pulse sequences block in which radio frequency (RF) energy is applied to the subject to substantially saturate magnetization corresponding to an exchangeable proton; (b) following step (a), acquiring data from the subject with the MR system; (c) repeating step (a) a plurality of times where parameters of the pulse sequence sub-blocks differ in at least some of the pulse sequence sub-blocks by at least an amount of RF energy applied to saturate the magnetization corresponding to the exchangeable proton; (d) after each repetition of step (a), repeating step (b) to acquire data representing signal evolutions from the subject; (e) comparing the signal evolutions with a dictionary database comprising a plurality of different signal evolution templates to determine quantitative chemical exchange or exchangeable proton information of the subject; and (f) generating a chemical exchange saturation transfer map using the quantitative chemical exchange or exchangeable proton information determined in step (e); wherein step (e) includes performing a pattern match of a measured trajectory in the signal evolutions with a pre-computed trajectory in the dictionary database to determine the quantitative chemical exchange or exchangeable proton information determined in step (e). 2. The method of claim 1 further comprising estimating optimized acquisition parameters for repetitions of the sub-block of step (a) that are optimized to direct the MR system to generate a plurality of different signal evolutions that maximize discrimination between longitudinal relaxation parameters in a minimized number of repetition time (TR) periods. 3. The method of claim 1 wherein step (c) further includes varying a repetition time associated with each sub-block. 4. The method of claim 1 wherein step (a) includes applying the RF energy applied to the subject to substantially saturate magnetization corresponding to the exchangeable proton at an offset from water. 5. The method of claim 4 wherein step (c) further includes holding the offset from water fixed at each repetition of step (a). 6. The method of claim 4 wherein step (c) further includes varying the offset from water for at least some repetitions of step (a). 7. The system comprising: a magnet system configured to generate a polarizing magnetic field about at least a portion of a subject arranged in the MR system; a magnetic gradient system including a plurality of magnetic gradient coils configured to apply at least one magnetic gradient field to the polarizing magnetic field; a radio frequency (RF) system configured to apply an RF field to the subject and to receive magnetic resonance signals from the subject using a coil array; a computer system programmed to: (a) control the magnetic gradient system and the RF system to perform a pulse sequences block in which radio frequency (RF) energy is applied to the subject to substantially saturate magnetization corresponding to an exchangeable proton; (b) following step (a), control the magnetic gradient system and the RF system acquire data from the subject with the MR system; (c) control the magnetic gradient system and the RF system to repeat step (a) a plurality of times where parameters of the pulse sequence sub-blocks differ in at least some of the pulse sequence sub-blocks by at least an amount of RF energy applied to saturate the magnetization corresponding to the exchangeable proton; (d) after each repetition of step (a), control the magnetic gradient system and the RF system to repeat step (b) to acquire data representing signal evolutions from the subject; (e) compare the signal evolutions with a dictionary database comprising a plurality of different signal evolution templates to determine quantitative chemical exchange or exchangeable proton information of the subject; and (f) generate a chemical exchange saturation transfer map using the quantitative chemical exchange or exchangeable proton information determined in step (e); wherein, to perform step (e), the computer system is further programmed to perform a pattern match of a measured trajectory in the signal evolutions with the pre-computed trajectory in the dictionary database to determine the quantitative chemical exchange or exchangeable proton information determined in step (e). 8. The system of claim 7 wherein the computer system is programmed to use a dot product when performing the pattern match. 9. The system of claim 7 wherein the computer system is programmed to use a subtraction of unnormalized trajectories when performing the pattern match.