Rosette spectroscopic imaging for whole-brain metabolite mapping at 7T:   acceleration potential and reproducibility

Zhiwei Huang (1,2); Uzay Emir (4,5,6); Andre Doring (1,2); Antoine; Klauser (7); Ying Xiao (1,2,3); Mark Widmaier (1,2,3); Lijing Xin (1,2,3); ((1) Center for Biomedical Imaging (CIBM); Switzerland; (2) Animal Imaging; and Technology; Ecole Polytechnique F\'ed\'erale de Lausanne (EPFL),; Lausanne; Switzerland; (3) Institute of Physics (IPHYS); Ecole Polytechnique; F\'ed\'erale de Lausanne (EPFL); Lausanne; Switzerland; (4) University of; North Carolina at Chapell Hill; Department of Radiology; (5) University of; North Carolina at Chapell Hill; Biomedical Research Imaging Center (BRIC),; (6) University of North Carolina at Chapell Hill; Joint Department of; Biomedical Engineering; (7) Advanced Clinical Imaging Technology; Siemens; Healthineers International AG; Lausanne; Switzerland)

arXiv:2410.05245·physics.med-ph·October 8, 2024

Rosette spectroscopic imaging for whole-brain metabolite mapping at 7T: acceleration potential and reproducibility

Zhiwei Huang (1,2), Uzay Emir (4,5,6), Andre Doring (1,2), Antoine, Klauser (7), Ying Xiao (1,2,3), Mark Widmaier (1,2,3), Lijing Xin (1,2,3), ((1) Center for Biomedical Imaging (CIBM), Switzerland, (2) Animal Imaging, and Technology

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TL;DR

This study develops and validates a fast, reproducible 2D and 3D 1H-MRSI method at 7T using rosette trajectories, optimized water suppression, and compressed sensing, enabling rapid whole-brain metabolite mapping.

Contribution

It introduces a novel rosette trajectory-based 1H-MRSI sequence with optimized suppression and demonstrates its high reproducibility and potential for accelerated imaging at 7T.

Findings

01

Metabolic maps obtained within approximately 5-6 minutes.

02

Reproducibility with CVs below 6% for key metabolites.

03

Compressed sensing suggests possible reduction of acquisition time to around 2 minutes.

Abstract

Whole-brain proton magnetic resonance spectroscopic imaging (1H-MRSI) is a non-invasive technique for assessing neurochemical distribution in the brain, offering valuable insights into brain functions and neural diseases. It greatly benefits from the improved SNR at ultrahigh field strengths ( $\geq$ 7T). However, 1H-MRSI still faces several challenges, such as long acquisition time and severe signal contaminations from water and lipids. In this study, 2D and 3D short TR/TE 1H-FID-MRSI sequences using rosette trajectories were developed with spatial resolutions of 4.48 $\times$ 4.48 mm $^{2}$ and 4.48 $\times$ 4.48 $\times$ 4.50 mm $^{3}$ , respectively. Water signals were suppressed using an optimized Five-variable-Angle-gaussian-pulses-with-ShorT-total-duration of 76 ms (FAST) water suppression scheme, and lipid signals were removed using the L2 regularization method. Metabolic maps of major 1H…

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Taxonomy

TopicsMetabolomics and Mass Spectrometry Studies · Spectroscopy Techniques in Biomedical and Chemical Research · Advanced MRI Techniques and Applications