In vivo investigation of the multi-exponential T2 decay in human white matter at 7T: Implications for myelin water imaging at UHF

TL;DR

This study investigates multi-exponential T2 decay in human white matter at 7T, demonstrating shortened T2 times, improved SNR, and the need to adjust T2 thresholds for accurate myelin water imaging at ultra-high field strengths.

Contribution

It provides in vivo characterization of T2 relaxation times at 7T and adapts analysis parameters for improved myelin water imaging accuracy at UHF.

Findings

Shorter T2 times at 7T compared to 3T.

Enhanced SNR at 7T improves T2 estimation.

Adjusted T2 thresholds align 7T data with 3T results.

Abstract

Multicomponent T2-mapping using a gradient and spin-echo (GraSE) acquisition has become standard for myelin water imaging at 3T. Higher magnetic field strengths promise SNR benefits but face specific absorption rate limits and shortened T2 times. This study investigates compartmental T2 times in vivo and addresses advantages and challenges of multi-component T2-mapping at 7T. We acquired 3D multi-echo GraSE data in seven healthy adults at 7T, with three subjects scanned also at 3T. Stimulated echoes arising from B+1 inhomogeneities were accounted for by the extended phase graph (EPG) algorithm. We used the computed T2 distributions to determine T2 times that identify different water pools and assessed signal-to-noise and fit-to-noise characteristics of the signal estimation. We compared short T2 fractions and T2 properties of the intermediate water pool at 3T and 7T. Flip angle mapping confirmed that EPG accurately determined the larger inhomogeneity at 7T. Multi-component T2 analysis demonstrated shortened T2 times at 7T compared to 3T. Fit-to-noise and signal-to-noise ratios were improved at 7T but depended on B1 homogeneity. Lowering the shortest T2 to 8 ms and adjusting the T2 threshold that separates different water compartments to 20 ms, yielded short T2 fractions at 7T that conformed to 3T data. Short T2 fractions in myelin-rich white matter regions were lower at 7T than at 3T, and higher in iron-rich structures. Adjusting the T2 compartment boundaries was required due to the shorter T2 relaxation times at 7T. Shorter echo spacing would better sample the fast decaying signal but would increase peripheral nerve stimulation. We used a multi-echo 3D-GraSE sequence to characterize the multi-exponential T2 decay at 7T. We adapted T2 parameters for evaluation of the short T2 fraction. Obtained 7T multicomponent T2-maps were in good agreement with 3T data.