Travelling Wave Magnetic Resonance Imaging at 3 Tesla

TL;DR

This study demonstrates the feasibility of traveling-wave MRI at 3 Tesla using a parallel-plate waveguide, showing comparable performance to conventional methods through simulations and in vivo experiments.

Contribution

It introduces a novel traveling-wave MRI technique at 3 T with a simple parallel-plate waveguide, enabling whole-body imaging without specialized coil arrays.

Findings

Traveling-wave MRI at 3 T is feasible with a parallel-plate waveguide.

Performance comparable to conventional MRI methods.

Successful in vivo imaging of human leg at 3 T.

Abstract

Waveguides have been successfully used to generate magnetic resonance images at 7 T with whole-body systems. The bore limits the magnetic resonance signal transmitted because its specific cut-off frequency is greater than the majority of resonant frequencies. This restriction can be overcome by using a parallel-plate waveguide whose cut-off frequency is zero for the transversal electric modes and it can propagate any frequency. To investigate the potential benefits for whole-body imaging at 3 T, we compare numerical simulations at 1.5 T, 3 T, 7 T, and 9 T via the propagation of the parallel-plate waveguide principal mode filled with a cylindrical phantom and two surface coils. B1 mapping was computed to investigate the feasibility of this approach at 3T. The point spread function method was used to measure the imager performance for the traveling-wave magnetic resonance imaging experiment. Human leg images were acquired to experimentally validate this approach. The principal mode shows very little field magnitude variations along the propagation direction at 3 T when compared to other higher resonant frequencies. The B1 mapping showed that it is possible to conduct experiments using the traveling-wave approach at 128 MHz. The point spread function results showed a good scanner performance for these type of experiments. Leg images were obtained with the whole-body birdcage coil and the waveguide with two circular coils for comparison purposes. The simulated and in vivo traveling-wave results correspond very well for both magnetic field and specific absorption rate. A pretty similar performance was observed for the traveling-wave approach and the conventional one. We have demonstrated the feasibility of traveling-wave magnetic resonance imaging at 3T for whole-body magnetic resonance systems, using a parallel-plate waveguide with standard pulse sequences and only one coil array.