A Statistical Framework for Optimizing and Evaluating MRI of T1 and T2 Relaxometry Approaches

Abstract

This paper proposes a statistical framework to optimize and evaluate the MR parameter T1 and T2 mapping capabilities for quantitative MRI relaxometry approaches. This analysis explores the intrinsic MR parameter estimate precision per unit scan time, termed the T1,2-to-noise ratio (TNR) efficiency, for different ranges of biologically realistic relaxation times. The TNR efficiency is defined in terms of the Cramer-Rao bound (CRB), a statistical lower bound on the parameter estimate variance. Geometrically interpreting the new TNR efficiency definition reveals a more complete model describing the factors controlling the T1/T2 mapping capabilities. This paper compares T1 mapping approaches including the inversion recovery (IR) family sequences and the Look-Locker (LL) sequence and simultaneous T1 and T2 mapping approaches including the spin-echo inversion recovery (SEIR) and driven equilibrium single pulse observation of T1/T2 (DESPOT) sequences. All pulse parameters are optimized to maximize the TNR efficiency within different T1 and T2 ranges of interest. Monte Carlo simulations with non-linear least square estimation (NLSE) of T1/T2 validated the theoretical predictions on the estimator performances.