A comparison of static and dynamic ∆B0 mapping methods for correction of CEST MRI in the presence of temporal B0 field variations

Esau Poblador Rodriguez; Philipp Moser; Barbara Dymerska; Simon Robinson; Benjamin Schmitt; Andre van der Kouwe; Stephan Gruber; Siegfried Trattnig; Wolfgang Bogner

doi:10.1002/mrm.27750

A comparison of static and dynamic ∆B₀ mapping methods for correction of CEST MRI in the presence of temporal B₀ field variations

Magn Reson Med. 2019 Aug;82(2):633-646. doi: 10.1002/mrm.27750. Epub 2019 Mar 28.

Authors

Esau Poblador Rodriguez¹, Philipp Moser¹, Barbara Dymerska², Simon Robinson¹, Benjamin Schmitt³, Andre van der Kouwe⁴, Stephan Gruber¹, Siegfried Trattnig^{1

5}, Wolfgang Bogner¹

Affiliations

¹ High Field MR Center, Department of Biomedical Imaging and Image-Guided Therapy, Medical University Vienna, Vienna, Austria.
² Medical Physics and Bioengineering, University College London, London, United Kingdom.
³ Siemens Healthineers, Sydney, Australia.
⁴ Athinoula A. Martinos Center for Biomedical Imaging, Department of Radiology, Massachusetts General Hospital, Harvard Medical School, Boston, Massachusetts.
⁵ Christian Doppler Laboratory for Clinical Molecular MR Imaging, Vienna, Austria.

Abstract

Purpose: To assess the performance, in the presence of scanner instabilities, of three dynamic correction methods which integrate ∆B₀ mapping into the chemical exchange saturation transfer (CEST) measurement and three established static ∆B₀ -correction approaches.

Methods: A homogeneous phantom and five healthy volunteers were scanned with a CEST sequence at 7 T. The in vivo measurements were performed twice: first with unaltered system frequency and again applying frequency shifts during the CEST acquisition. In all cases, retrospective voxel-wise ∆B₀ -correction was performed using one intrinsic and two extrinsic [prescans with dual-echo gradient-echo and water saturation shift referencing (WASSR)] static approaches. These were compared with two intrinsic [using phase data directly generated by single-echo or double-echo GRE (gradient-echo) CEST readout (CEST-GRE-2TE)] and one extrinsic [phase from interleaved dual-echo EPI (echo planar imaging) navigator (NAV-EPI-2TE)] dynamic ∆B₀ -correction approaches [allowing correction of each Z-spectral point before magnetization transfer ratio asymmetry (MTR_asym₎ analysis].

Results: All three dynamic methods successfully mapped the induced drift. The intrinsic approaches were affected by the CEST labeling near water (∆ω < |0.3| ppm). The MTR_asym contrast was distorted by the frequency drift in the brain by up to 0.21%/Hz when static ∆B₀ -corrections were applied, whereas the dynamic ∆B₀ corrections reduced this to <0.01%/Hz without the need of external scans. The CEST-GRE-2TE and NAV-EPI-2TE resulted in highly consistent MTR_asym values with/without drift for all subjects.

Conclusion: Reliable correction of scanner instabilities is essential to establish clinical CEST MRI. The three dynamic approaches presented improved the ∆B₀ -correction performance significantly in the presence of frequency drift compared to established static methods. Among them, the self-corrected CEST-GRE-2TE was the most accurate and straightforward to implement.

Keywords: chemical exchange saturation transfer (CEST); dynamic ∆B0 correction; frequency drift; scanner instabilities; ∆B0 mapping.

Publication types

Comparative Study
Research Support, Non-U.S. Gov't

MeSH terms

Adult
Brain / diagnostic imaging
Echo-Planar Imaging
Female
Humans
Image Processing, Computer-Assisted / methods*
Magnetic Resonance Imaging / methods*
Male
Phantoms, Imaging

Grants and funding

KLI 718/FWF_/Austrian Science Fund FWF/Austria