Title :
Multichannel Double-Row Transmission Line Array for Human MR Imaging at Ultrahigh Fields
Author :
Xinqiang Yan ; Ole Pedersen, Jan ; Long Wei ; Xiaoliang Zhang ; Rong Xue
Abstract :
Objective: In microstrip transmission line (MTL) transmit/receive (transceive) arrays used for ultrahigh field MRI, the array length is often constrained by the required resonant frequency, limiting the image coverage. The purpose of this study is to increase the imaging coverage and also improve its parallel imaging capability by utilizing a double-row design. Methods: A 16-channel double-row MTL transceive array was designed, constructed, and tested for human head imaging at 7 T. Array elements between two rows were decoupled by using the induced current elimination or magnetic wall decoupling technique. In vivo human head images were acquired, and g-factor results were calculated to evaluate the performance of this double-row array. Results: Testing results showed that all coil elements were well decoupled with a better than -18 dB transmission coefficient between any two elements. The double-row array improves the imaging quality of the lower portion of the human head, and has low g-factors even at high acceleration rates. Conclusion: Compared with a regular single-row MTL array, the double-row array demonstrated a larger imaging coverage along the z-direction with improved parallel imaging capability. Significance: The proposed technique is particularly suitable for the design of large-sized transceive arrays with large channel counts, which ultimately benefits the imaging performance in human MRI.
Keywords :
array signal processing; biomedical MRI; coils; medical image processing; microstrip lines; transceivers; transmission lines; 16-channel transceive array; MTL transmit array; array element decoupling; array element transmission coefficient; array length-limited image coverage; decoupled array elements; decoupled coil elements; double-row MTL transceive array; double-row array imaging coverage; double-row array performance evaluation; double-row array-improved image quality; double-row design; double-row line array; g-factor calculation; high imaging acceleration rates; human MRI imaging performance; human head imaging; human magnetic resonance imaging performance; improved imaging capability; improved parallel imaging capability; in vivo human head image acquisition; increased imaging coverage; induced current elimination; large-sized transceive array channel count; large-sized transceive array design; low g-factors; lower human head portion image quality; magnetic flux density 7.00 T; magnetic wall decoupling technique; microstrip transmission line transceive array; microstrip transmission line transmit array; multichannel line array; regular MTL array; regular microstrip transmission line array; resonant frequency-constrained array length; single-row MTL array; single-row microstrip transmission line array; transceive array testing; ultrahigh field MRI; ultrahigh field human MR imaging; ultrahigh field human magnetic resonance imaging; ultrahigh field magnetic resonance imaging; z-direction imaging coverage; Arrays; Coils; Head; Magnetic heads; Magnetic resonance imaging; Radio frequency; Decouple; Microstrip; RF coil array; RF shimming; decouple; head; high field MRI; high-field MRI; induced current elimination (ICE); microstrip; multiple row; multiple-row; parallel imaging; parallel transmission; parallel transmission (pTx); radio frequency (RF) coil array;
Journal_Title :
Biomedical Engineering, IEEE Transactions on
DOI :
10.1109/TBME.2015.2401976
