Optimal control in a magnetization-prepared rapid acquisition gradient-echo sequence

This article proposes a numerical framework to determine the optimal magnetization preparation in a three-dimensional magnetization-prepared rapid gradient-echo (MP-RAGE) sequence to obtain the best achievable contrast between target tissues based on differences in their relaxation times. The benefit lies in the adaptation of the algorithm of optimal control, GRAdient Ascent Pulse Engineering (GRAPE), to the optimization of magnetization preparation in a cyclic sequence without full recovery between each cycle. This numerical approach optimizes magnetization preparation of an arbitrary number of radio frequency pulses to enhance contrast, taking into account the establishment of a steady state in the longitudinal component of the magnetization. The optimal control preparation offers an optimized mixed T1/T2$$ {T}_1/{T}_2 $$ contrast in this traditional T1$$ {T}_1 $$-weighted sequence. To show the versatility of the proposed method, numerical and in vitro results are described. Examples of contrasts acquired on brain regions of a healthy volunteer are presented for potential applications at 3 T. A numerical framework is used to determine the optimal magnetization preparation in a three-dimensional magnetization-prepared rapid gradient-echo (MP-RAGE) sequence to obtain the best achievable contrast between target tissues based on their relaxation times differences. The benefit of our method lies in the inclusion of the steady state in the optimal control framework. It offers great contrast versatility that is illustrated in vitro and in vivo on brain regions of a healthy volunteer on a clinical scanner at 3 T.image