Multiple interleaved mode saturation (MIMOSA) for B1+ inhomogeneity mitigation in chemical exchange saturation transfer

Liebert A, Gumbrecht R, Tkotz K, Linz P, Schmitt B, Dörfler A, Uder M, Nagel AM, Zaiss M, Laun FB (2019)

Publication Type: Journal article

Publication year: 2019

Journal

Magnetic Resonance in Medicine Wiley

DOI: 10.1002/mrm.27762

Abstract

Purpose: To mitigate (Formula presented.) inhomogeneity in quantitative CEST MRI at ultra-high magnetic field strengths (B 0 ≥ 7 Tesla) using a parallel transmit system. Methods: Multiple interleaved mode saturation employs interleaving of 2 complementary phase sets during the saturation pulse train. Phase differences of 45° (first mode) and 90° (second mode) between 2 adjacent transmitter coil channels are used. The influence of the new saturation scheme on the CEST contrast was analyzed using Bloch-McConnell simulations. The presented method was verified in phantom and in vivo measurements of the healthy human brain. The relayed nuclear Overhauser effect was evaluated, and the inverse magnetic transfer ratio metric was calculated. Results were compared to a published (Formula presented.) correction method. All measurements were conducted on a whole-body 7 Tesla MRI system using an 8 transmitter and 32 receiver channel head coil. Results: Simulations showed that the inverse magnetic transfer ratio metric contrast of relayed nuclear Overhauser effect shows a smaller dependency on the relative amplitudes of the 2 different modes than the contrasts of Cr and amide proton transfer. Measurements of an egg white phantom showed markedly improved homogeneity compared to the uncorrected inverse magnetic transfer ratio metric (relayed nuclear Overhauser effect) images and slightly improved results compared to (Formula presented.) corrected images. In vivo multiple interleaved mode saturation images showed similar contrast compared to (Formula presented.) corrected images. Conclusion: Multiple interleaved mode saturation can be used as a simple method to mitigate (Formula presented.) inhomogeneity effects in CEST MRI at ultra-high magnetic field strengths. Compared to previous (Formula presented.) correction methods, acquisition time can be reduced because an additional scan, usually required for (Formula presented.) correction, can be omitted.

Authors with CRIS profile

Andrzej Liebert Professur für metabolische und funktionelle MR-Bildgebung Peter Linz Institute of Radiology Arnd Dörfler Department of Neuroradiology Michael Uder Lehrstuhl für Diagnostische Radiologie Armin Michael Nagel Professur für metabolische und funktionelle MR-Bildgebung Moritz Zaiß
Frederik Bernd Laun Professur für quantitative MR-Bildgebung (Heisenberg-Professur)

Involved external institutions

Max-Planck-Institut für biologische Kybernetik / Max Planck Institute for Biological Cybernetics DE Germany (DE)

How to cite

APA:

Liebert, A., Gumbrecht, R., Tkotz, K., Linz, P., Schmitt, B., Dörfler, A.,... Laun, F.B. (2019). Multiple interleaved mode saturation (MIMOSA) for B1+ inhomogeneity mitigation in chemical exchange saturation transfer. Magnetic Resonance in Medicine. https://doi.org/10.1002/mrm.27762

MLA:

Liebert, Andrzej, et al. "Multiple interleaved mode saturation (MIMOSA) for B1+ inhomogeneity mitigation in chemical exchange saturation transfer." Magnetic Resonance in Medicine (2019).

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