Coaxial Dipole Array with Switching Transmit Sensitivities for ultrahigh field MRI

TL;DR

This paper introduces a coaxial dipole array with electronically switchable transmit field patterns for ultra-high field MRI, aiming to enhance flip angle homogeneity by dynamically altering the $B_{1}^{+}$ field during excitation.

Contribution

It presents a novel coaxial dipole array with switchable transmit sensitivities, enabling improved flip angle uniformity without increasing the number of transmit channels.

Findings

Simulations show a 30% change in $B_{1}^{+}$ field with current modulation.

Rapid switching during excitation can improve flip angle homogeneity by over twofold.

Prototype array demonstrated observable switching effects, though weaker than simulations.

Abstract

Purpose: To investigate dipole antennas with electronically switchable transmit field patterns to improve flip angle homogeneity in ultra-high field MRI Methods: An array of eight coaxial dipoles with electronically switchable $B_{1}^{\!+}$ field profiles was constructed. Alteration of the field profiles was accomplished by modulating the currents along the dipoles using a combination of PIN diodes and lumped inductances. The behavior of these reconfigurable elements was studied in numerical electromagnetic simulations and 9.4T MRI measurements, investigating rapid switching of transmit sensitivities during excitation pulses in both single-channel and pTx mode operation. Results: For the simulated dipole elements, modulating the current densities along the dipole's axis causes a $\sim$30% change of the $B_{1}^{\!+}$ field between superior and inferior regions of the brain. When rapidly switched during excitation pulses, this degree of freedom can improve flip angle homogeneity, e.g. by a factor of $\sim$2.2 for a two kT points pTx pulse. For the constructed prototype array, the switching effect was observable but weaker, causing $\sim$10% superior-inferior $B_{1}^{\!+}$ variation. Conclusion: The proposed coaxial dipole array with switchable transmit sensitivities offers a novel degree of freedom for designing excitation pulses. The approach has the potential to improve flip angle homogeneity without necessitating an expensive increase in the number of independent transmit channels.