High‐quality FLORET UTE imaging for clinical translation

Purpose To develop a robust 3D ultrashort‐TE (UTE) protocol that can reproducibly provide high‐quality images, assessed by the ability to yield clinically diagnostic images, and is suitable for clinical translation. Theory and Methods Building on previous work, a UTE sampled with Fermat looped ortho...

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Bibliographic Details
Published in:Magnetic resonance in medicine 2025-01, Vol.93 (1), p.276-288
Main Authors: Willmering, Matthew M., Krishnamoorthy, Guruprasad, Robison, Ryan K., Rosenberg, Jens T., Woods, Jason C., Pipe, James G.
Format: Article
Language:English
Subjects:
clinical
GTF
Image acquisition
Image processing
Image quality
Image reconstruction
Medical imaging
MSK
pulmonary
Robustness
Scanners
spiral
Translation
UTE
Waveforms
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Summary:Purpose To develop a robust 3D ultrashort‐TE (UTE) protocol that can reproducibly provide high‐quality images, assessed by the ability to yield clinically diagnostic images, and is suitable for clinical translation. Theory and Methods Building on previous work, a UTE sampled with Fermat looped orthogonally encoded trajectories (FLORET) was chosen as a starting point due to its shorter, clinically reasonable scan times. Modifications to previous FLORET implementations included gradient waveform frequency limitations, a new trajectory ordering scheme, a balanced SSFP implementation, fast gradient spoiling, and full inline reconstruction. FLORET images were collected in phantoms and humans on multiple scanners and sites to demonstrate these improvements. Results The updates to FLORET provided high‐quality images in phantom, musculoskeletal, and pulmonary applications. The gradient waveform modifications and new trajectory ordering scheme significantly reduced visible artifacts. Fast spoiling reduced acquisition time by 20%–28%. Across the various scanners and sites, the inline image quality was consistent and of diagnostic quality. Total image acquisition plus reconstruction time was less than 4 min for musculoskeletal and pulmonary applications with reconstructions taking less than 1 min. Conclusion Recently developed improvements for the FLORET sequence have enabled robust, high‐quality UTE acquisitions with short acquisition and reconstruction times. This enables clinical UTE imaging as demonstrated by the implementation of the sequence and acquisition on five MRI scanners, at three different sites, without the need for any additional system characterization or measurements.
ISSN:0740-3194
1522-2594
1522-2594
DOI:10.1002/mrm.30277