Abstract
PURPOSE: To perform dynamic T(1) mapping using a 2D variable flip angle (VFA) method, a correction for the slice profile effect is needed. In this work we investigated the impact of flip angle selection and excitation RF pulse profile on the performance of slice profile correction when applied to T(1) mapping over a range of T(1) values. METHODS: A correction of the slice profile effect is proposed, based on Bloch simulation of steady-state signals. With this correction, Monte Carlo simulations were performed to assess the accuracy and precision of 2D VFA T(1) mapping in the presence of noise, for RF pulses with time-bandwidth products of 2, 3 and 10 and with flip angle pairs in the range [1°-90°]. To evaluate its performance over a wide range of T(1) , maximum errors were calculated for six T(1) values between 50 ms and 1250 ms. The method was demonstrated using in vitro and in vivo experiments. RESULTS: Without corrections, 2D VFA severely underestimates T(1) . Slice profile errors were effectively reduced with the correction based on simulations, both in vitro and in vivo. The precision and accuracy of the method depend on the nominal T(1) values, the FA pair, and the RF pulse shape. FA pairs leading to <5% errors in T(1) can be identified for the common RF shapes, for T(1) values between 50 ms and 1250 ms. CONCLUSIONS: 2D VFA T(1) mapping with Bloch-simulation-based correction can deliver T(1) estimates that are accurate and precise to within 5% over a wide T(1) range.