Erschienen in:
12.06.2023 | Research Article
Concomitant field compensation of spiral turbo spin-echo at 0.55 T
verfasst von:
Rajiv Ramasawmy, John P. Mugler III, Ahsan Javed, Zhixing Wang, Daniel A. Herzka, Craig H. Meyer, Adrienne E. Campbell-Washburn
Erschienen in:
Magnetic Resonance Materials in Physics, Biology and Medicine
|
Ausgabe 3/2023
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Abstract
Objective
Diagnostic-quality neuroimaging methods are vital for widespread clinical adoption of low field MRI. Spiral imaging is an efficient acquisition method that can mitigate the reduced signal-to-noise ratio at lower field strengths. As concomitant field artifacts are worse at lower field, we propose a generalizable quadratic gradient-field nulling as an echo-to-echo compensation and apply it to spiral TSE at 0.55 T.
Materials and methods
A spiral in–out TSE acquisition was developed with a compensation for concomitant field variation between spiral interleaves, by adding bipolar gradients around each readout to minimize phase differences at each refocusing pulse. Simulations were performed to characterize concomitant field compensation approaches. We demonstrate our proposed compensation method in phantoms and (n = 8) healthy volunteers at 0.55 T.
Results
Spiral read-outs with integrated spoiling demonstrated strong concomitant field artifacts but were mitigated using the echo-to-echo compensation. Simulations predicted a decrease of concomitant field phase RMSE between echoes of 42% using the proposed compensation. Spiral TSE improved SNR by 17.2 ± 2.3% compared to reference Cartesian acquisition.
Discussion
We demonstrated a generalizable approach to mitigate concomitant field artifacts for spiral TSE acquisitions via the addition of quadratic-nulling gradients, which can potentially improve neuroimaging at low-field through increased acquisition efficiency.