Ultra-high resolution brain metabolite mapping at 7 T by short-TR Hadamard-encoded FID-MRSI Article Swipe

View

Related Concepts

Magnetic resonance spectroscopic imaging Voxel Hadamard transform Nuclear medicine White matter Imaging phantom Nuclear magnetic resonance Physics Computer science Magnetic resonance imaging Medicine Artificial intelligence Radiology Quantum mechanics

Gilbert Hangel , Bernhard Strasser , Michal Považan , Eva Hečková , Lukas Hingerl , Roland N. Boubela , Stephan Gruber , Siegfried Trattnig , Wolfgang Bogner ·

YOU? · · 2016 · Open Access · · DOI: https://doi.org/10.1016/j.neuroimage.2016.10.043 · OA: W2547763569

MRSI in the brain at ≥7 T is a technique of great promise, but has been limited mainly by low B0/B1+-homogeneity, specific absorption rate restrictions, long measurement times, and low spatial resolution. To overcome these limitations, we propose an ultra-high resolution (UHR) MRSI sequence that provides a 128×128 matrix with a nominal voxel volume of 1.7×1.7×8mm3 in a comparatively short measurement time. A clinically feasible scan time of 10-20min is reached via a short TR of 200 ms due to an optimised free induction decay-based acquisition with shortened water suppression as well as parallel imaging (PI) using Controlled Aliasing In Parallel Imaging Results IN Higher Acceleration (CAIPIRINHA). This approach is not limited to a rectangular region of interest in the centre of the brain, but also covers cortical brain regions. Transversal pulse-cascaded Hadamard encoding was able to further extend the coverage to 3D-UHR-MRSI of four slices (100×100×4 matrix size), with a measurement time of 17min. Lipid contamination was removed during post-processing using L2-regularisation. Simulations, phantom and volunteer measurements were performed. The obtained single-slice and 3D-metabolite maps show the brain in unprecedented detail (e.g., hemispheres, ventricles, gyri, and the contrast between grey and white matter). This facilitates the use of UHR-MRSI for clinical applications, such as measurements of the small structures and metabolic pathologic deviations found in small Multiple Sclerosis lesions.