Purpose To introduce non‐rigid cardiac motion correction into a novel free‐running
framework for the simultaneous acquisition of 3D whole‐heart myocardial T 1 T _1 and T 2 T …

Purpose To develop a free-running framework for 3D isotropic simultaneous myocardial
T1/T2 mapping and cine imaging. Methods Continuous data acquisition with 3D golden …

Purpose To develop a free‐running (free‐breathing, retrospective cardiac gating) 3D
myocardial T1 mapping with isotropic spatial resolution. Methods The free‐running …

Purpose To provide high‐resolution cardiac T1 mapping of various cardiac phases and cine
imaging within a single breath‐hold using continuous golden ratio‐based radial acquisition …

Purpose To develop an accelerated motion corrected 3D whole‐heart imaging approach
(qBOOST‐T2) for simultaneous high‐resolution bright‐and black‐blood cardiac MR imaging …

Purpose To enable free‐breathing whole‐heart 3D T2 mapping with high isotropic
resolution in a clinically feasible and predictable scan time. This 3D motion‐corrected …

Purpose To allow for T1 mapping of the myocardium within 2.3 s for a 2D slice utilizing
cardiac motion‐corrected, model‐based image reconstruction. Methods Golden radial data …

Purpose To develop a cardiac T1 mapping method for free‐breathing 3D T1 mapping of the
whole heart at 3 T with transmit B1 () correction. Methods A free‐breathing …

Background Cardiovascular magnetic resonance (CMR) T1ρ mapping can be used to detect
ischemic or non-ischemic cardiomyopathy without the need of exogenous contrast agents …

Purpose To improve the efficiency of native and postcontrast high‐resolution cardiac T1
mapping by utilizing cardiac motion correction. Methods Common cardiac T1 mapping …