Ultrashort Echo Time Magnetic Resonance Fingerprinting (UTE-MRF) for Simultaneous Quantification of Long and Ultrashort T2 Tissues
Qing Li, Xiaozhi Cao, Huihui Ye, Congyu Liao, Hongjian He, Jianhui, Zhong

TL;DR
This paper introduces UTE-MRF, a novel MRI technique capable of simultaneously quantifying T1, T2, and proton density in tissues with long and ultrashort T2 values, enabling pseudo-CT image synthesis.
Contribution
The study presents a new UTE-MRF method with sinusoidal TE variation that improves quantification of short T2 tissues and produces pseudo-CT images, advancing musculoskeletal and brain tissue imaging.
Findings
Achieved minimal TE of 0.05 ms in UTE-MRF.
Accurate T1/T2 measurements in phantoms compared to standard methods.
Successful in vivo detection of cortical bone, tendons, and scalp images.
Abstract
Purpose: To demonstrate an ultrashort echo time magnetic resonance fingerprinting (UTE-MRF) method that can simultaneously quantify tissue relaxometries for muscle and bone in musculoskeletal systems and tissue components in brain and therefore can synthesize pseudo-CT images. Methods: A FISP-MRF sequence with half pulse excitation and half spoke radial acquisition was designed to sample fast T2 decay signals. Sinusoidal echo time (TE) pattern was applied to enhance MRF sensitivity for tissues with short and ultrashort T2 values. The performance of UTE-MRF was evaluated via simulations, phantoms, and in vivo experiments. Results: A minimal TE of 0.05 ms was achieved in UTE-MRF. Simulations indicated that extension of TE sampling increased T2 quantification accuracy in cortical bone and tendon, and had little impact on long T2 muscle quantifications. For a rubber phantom, an average…
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