A coupled planar transmit RF array for ultrahigh field spine MR imaging

TL;DR

This paper introduces a novel coupled planar RF array for ultrahigh-field spine MRI, demonstrating improved B1 efficiency, SAR, and high-frequency operation over conventional coils through modeling, measurements, and empirical testing.

Contribution

The paper presents a new coupled planar array design that enhances RF coil performance for ultrahigh-field spine MRI, combining electromagnetic coupling with multimodal resonator functionality.

Findings

Superior B1 efficiency compared to conventional coils

Enhanced SAR performance at high frequencies

Effective operation at 7 Tesla for spine imaging

Abstract

Ultrahigh-field MRI, such as those operating at 7 Tesla, enhances diagnostic capabilities but also presents unique challenges, including the need for advanced RF coil designs to achieve an optimal signal-to-noise ratio and transmit efficiency, particularly when imaging large samples. In this work, we introduce the coupled planar array, a novel technique for high-frequency, large-size RF coil design with enhanced the RF magnetic field (B1) efficiency and transmit performance for ultrahigh-field spine imaging applications. This array comprises multiple resonators that are electromagnetically coupled to function as a single multimodal resonator. The field distribution of its highest frequency mode is suitable for spine imaging applications. Based on the numerical modeling and calculation, a prototype of the coupled planar array was constructed and its performance was evaluated through comprehensive numerical simulations, rigorous RF measurements, empirical tests, and a comparison against a conventional surface coil with the same size and geometry. The results of this study demonstrate that the proposed coupled planar array exhibits superior performance compared to conventional surface coils in terms of B1 efficiency for both transmit (B1+) and receive (B1-) fields, specific absorption rate (SAR), and the ability to operate at high frequencies. This study suggests a promising and efficient approach to the design of high-frequency, large-size RF coils for spine MR imaging at ultrahigh magnetic fields.