3D whole-heart free-breathing isotropic joint T1/T2 quantification: preliminary clinical evaluation

Accelerated 3-Tesla Cardiac T2-Mapping at End-Systole for Improved Transmural Map Consistency and Accuracy

Accelerating 2D Chemical Shift Encoded MRI with Simultaneous Multislice Imaging

The application of B1 corrected VFA T1-mapping in staging of liver fibrosis

Comparison of lung T1 mapping using variable flip angle and Look-Locker techniques

A comparison of two B1+ mapping methods for 3D VFA T1 mapping in the liver at 3T

Correlation between multi-echo ultrashort TE and mDIXON-quant imaging for R2* mapping in liver cirrhosis

Distinction of T2 quantitative measurementsbetween the nucleus pulposus and anulus fibrosus using Gaussian-fitted histogram analysis

Efficient Phase Cycling Strategy for High Resolution Three-Dimensional GRE Quantitative Mapping

Efficient T2 mapping of the Abdomen with low SAR Variable Flip Angle Radial Turbo Spin Echo

Fast T2-mapping in prostate cancer based on echo-time domain compressed sensing

Fat-insensitive T2water measurement using multiple Dixon turbo spin-echo acquisitions with effective echo time increments

Feasibility and insights into transient state phase-based mapping for rapid T2 quantification in the myocardium

Feasibility of high resolution quantitative magnetic resonance imaging using variable flip angle and spoiling phase angle

The feasibility of T1? magnetic resonance fingerprinting with a random design of T1? preparationat 11.7T

Free-Breathing, Confounder Corrected T1 Mapping in the Liver with Stack-of-Stars Inversion Recovery MRI

Hepatic iron quantification using a Free-breathing 3D Radial Dixon technique and validation with a 2D GRE biopsy calibration

Improved Slice Coverage in Inversion Recovery Radial Balanced-SSFP using Deep Learning

In vivo $$$T_1$$$ quantification at 0.1 T using a fast, interleaved Look-Locker based $$$T_1$$$ mapping sequence.

Inter-vendor 3T R2* mapping evaluation on a standardized R2* phantom with and without a human subject

Author:Justin Yu  Anshuman Panda  Alvin Silva  

Session Type:Digital Poster  

Session Date:Wednesday, 19 May 2021  

Topic:Quantitative Relaxation Parameter Mapping in the Body  

Session Name:Relaxometry in the Body: MSK & More  

Program Number:3317  

Room Session:Concurrent 1  

Institution:Mayo Clinic Arizona  

A method to rapidly quantify whole-organ metabolic rate of O2 with interleaved background-suppressed T2-oximetry and blood flow measurement

Multiband Multitasking for Cardiac T1 Mapping

Multi-component T2 Modeling for Improved Characterization of Abdominal Neoplasms

Optimization of Spoiled GRE-based IR Acquisition Scheme for 3D Cardiac T1 Mapping at 3T

Prospective Accelerated Cartesian 3D-T1rho Mapping of Knee Joint using Data-Driven Optimized Sampling Patterns and Compressed Sensing

Pseudo-T2 mapping of T2-weighted MRI­ of the prostate: Comparison to gold standard

Rapid high resolution simultaneous mapping of composite T1, water-only T1 and PDFF in the abdomen with dual-echo IR-radSPGR pulse sequence

Reliability and reproducibility of synthetic spine MRI with different coils

Simultaneous arterial and venous imaging and 3D quantitative parameter mapping with RF-spoiled gradient echo

Simultaneous Fat- and B1-Corrected T1 Mapping Using Chemical-Shift Encoded MRI

Six-Dimensional, Free-Breathing Multitasking Multi-Echo (MT-ME) MRI for Whole-Liver T1, PDFF, and R2* Quantification

SuperMAP: Superfast MR Mapping with Joint Under-sampling using Deep Combined Network

Survey of water proton longitudinal relaxation in liver in vivo.

SyntheticMRIwith quantitative mappingsas biomarkersfor prediction of prognostic factors and molecular subtypes of breast cancer

Syntheticrelaxometry and diffusion measures in the differentiation of breastlesions: a contrast-free alternative to BI-RADS?

T1rho Dispersion Imaging ofIntervertebral Discs

Towards in-vivo myeloarchitecture: optimising T1 maps point spread function by very high resolution multi-shot inversion-recovery EPI

Transversal Relaxometry of a Mixture of Iron Compounds at Different Concentrations

Why You Should Fit Signal Intensity, Not Relaxivity, for Quantitative DCE-MRI