Improvement of Brain MRI at 7T Using an Inductively Coupled RF Resonator Array

It is well known that magnetic resonance imaging (MRI) at 7 Tesla (7T) and higher magnets can provide much better signal sensitivity compared with lower field strengths. However, variety of commercially available ultra-high-field MRI coils are still limited, due to the technical challenges associated with wavelength effect, such as flip angle inhomogeneity and asymmetric transmit and receive RF field patterns. We aimed to develop a passive RF shimming technique using an inductively coupled RF resonator array to improve brain MRI at 7T, focusing of cerebellum. Method: an inductively coupled RF resonator array was designed for placing inside the commercial head coil to enhance the transmit field homogeneity and to improve the receive signal sensitivity. Each element of the array is a coupled-split-ring resonator (CSRR), which they are decoupled for each other using critical overlap technique. Phantom and ex-vivo MRI experiments were performed to evaluate the transmit efficiency and signal sensitivity in the presence of the array. Results: MRI experiments showed 2 to 4-fold improvement in Signal-to-noise ratio (SNR) and 2-fold improvement in contrast-to-noise ratio (CNR) in cerebellum. Conclusion: We modeled a wireless RF resonator array that can improve the transmit efficiency of the standard head coil and enhance the signal sensitivity at brain MRI without compromising RF safety.