MC BTS: simultaneously resolving magnetization transfer effect and relaxation for multiple components
Abstract
We propose a signal acquisition and modeling framework for multi-component tissue quantification that encompasses transmit field inhomogeneity, multi-component relaxation and magnetization transfer (MT) effects. By applying off-resonance irradiation between excitation and acquisition within an RF-spoiled gradient-echo scheme, in combination with multiple echo-time acquisitions, both Bloch-Siegert shift and magnetization transfer effects are simultaneously induced while relaxation and spin exchange processes occur concurrently. Simulation results showed excellent agreement with the derived analytical signal equation across a wide range of flip angles and echo times. Monte Carlo analyses further validated that the three-pool parameter estimation pipeline performed robustly over various signal-to-noise ratio conditions. Multi-parameter fitting results from in vivo brain and knee studies yielded values consistent with previously reported literature. Collectively, these findings confirm that the proposed method can reliably characterize multi-component tissue parameters in macromolecule-rich environments while effectively compensating for inhomogeneity.
Keywords
Cite
@article{arxiv.2510.06022,
title = {MC BTS: simultaneously resolving magnetization transfer effect and relaxation for multiple components},
author = {Albert Jang and Hyungseok Jang and Nian Wang and Alexey Samsonov and Fang Liu},
journal= {arXiv preprint arXiv:2510.06022},
year = {2025}
}