MR Multitasking‐based multi‐dimensional assessment of cardiovascular system (MT‐MACS) with extended spatial coverage and water‐fat separation
Purpose To extend the MR M ulti T asking‐based M ultidimensional A ssessment of C
ardiovascular S ystem (MT‐MACS) technique with larger spatial coverage and water‐fat …
ardiovascular S ystem (MT‐MACS) technique with larger spatial coverage and water‐fat …
Magnetic resonance multitasking for multidimensional assessment of cardiovascular system: development and feasibility study on the thoracic aorta
Purpose To develop an MR multitasking‐based multidimensional assessment of
cardiovascular system (MT‐MACS) with electrocardiography‐free and navigator‐free data …
cardiovascular system (MT‐MACS) with electrocardiography‐free and navigator‐free data …
Free‐breathing, non‐ECG, simultaneous myocardial T1, T2, T2*, and fat‐fraction mapping with motion‐resolved cardiovascular MR multitasking
Purpose To develop a free‐breathing, non‐electrocardiogram technique for simultaneous
myocardial T1, T2, T2*, and fat‐fraction (FF) mapping in a single scan. Methods The MR …
myocardial T1, T2, T2*, and fat‐fraction (FF) mapping in a single scan. Methods The MR …
Alternating low‐rank tensor reconstruction for improved multiparametric mapping with cardiovascular MR Multitasking
Purpose To develop a novel low‐rank tensor reconstruction approach leveraging the
complete acquired data set to improve precision and repeatability of multiparametric …
complete acquired data set to improve precision and repeatability of multiparametric …
3D joint reconstruction of non-contrast and contrast-enhanced CMR multitasking
Cardiovascular MR (CMR) is used to acquire function, morphology, and composition of the
heart which aids in clinical diagnosis and management. While measures such as ejection …
heart which aids in clinical diagnosis and management. While measures such as ejection …
Free‐breathing, motion‐corrected, highly efficient whole heart T2 mapping at 3T with hybrid radial‐cartesian trajectory
Purpose To develop and test a time‐efficient, free‐breathing, whole heart T2 mapping
technique at 3.0 T. Methods ECG‐triggered three‐dimensional (3D) images were acquired …
technique at 3.0 T. Methods ECG‐triggered three‐dimensional (3D) images were acquired …
Comparison of fast acquisition strategies in whole‐heart four‐dimensional flow cardiac MR: Two‐center, 1.5 Tesla, phantom and in vivo validation study
P Garg, JJM Westenberg… - Journal of Magnetic …, 2018 - Wiley Online Library
Purpose To validate three widely‐used acceleration methods in four‐dimensional (4D) flow
cardiac MR; segmented 4D‐spoiled‐gradient‐echo (4D‐SPGR), 4D‐echo‐planar‐imaging …
cardiac MR; segmented 4D‐spoiled‐gradient‐echo (4D‐SPGR), 4D‐echo‐planar‐imaging …
Clinical feasibility of 3D-QALAS–Single breath-hold 3D myocardial T1-and T2-mapping
Purpose To investigate the in-vivo precision and clinical feasibility of 3D-QALAS-a novel
method for simultaneous three-dimensional myocardial T1-and T2-mapping. Methods Ten …
method for simultaneous three-dimensional myocardial T1-and T2-mapping. Methods Ten …
Free‐breathing, non‐ECG, continuous myocardial T1 mapping with cardiovascular magnetic resonance multitasking
Purpose To evaluate the accuracy and repeatability of a free‐breathing, non‐
electrocardiogram (ECG), continuous myocardial T1 and extracellular volume (ECV) …
electrocardiogram (ECG), continuous myocardial T1 and extracellular volume (ECV) …
3D whole‐heart isotropic‐resolution motion‐compensated joint T1/T2 mapping and water/fat imaging
Purpose To develop a free‐breathing isotropic‐resolution whole‐heart joint T1 and T2
mapping sequence with Dixon‐encoding that provides coregistered 3D T1 and T2 maps and …
mapping sequence with Dixon‐encoding that provides coregistered 3D T1 and T2 maps and …