Title :
RF technology for human MRI at 10.5T
Author :
Vaughan, John Thomas ; DelaBarre, Lance ; Jinfeng Tian ; Sungmin Sohn ; Shrivastava, Devashish ; Adriany, Gregor ; Ugurbil, K.
Author_Institution :
Center for Magn. Resonance Res., Univ. of Minnesota, Minneapolis, MN, USA
Abstract :
The objective of this work is to develop and apply the world´s highest field strength, whole-body MRI system for biomedical research of the human body in health, disease, and therapeutic intervention. Due to the better than linear proportion of signal-to-noise to field strength, this system has the inherent potential of being the most power instrument yet, for noninvasive investigation, In-vivo. However, because the 450 MHz Larmor wavelength of the energy stimulating and receiving the nuclear magnetic signal response in high water content human tissues is on the order of 7cm, conventional MRI technology and methods used at lower field strengths and frequencies will not realize the full potential of this system. RF field non-uniformities and losses associated with current approaches will compromise both the success and the safety of 10.5T studies. New solutions to these short-wave problems must be found to realize the full benefit of this MRI at this unprecedented field strength. These new solutions for RF technology for MRI at 10.5T is the topic of this work.
Keywords :
biological tissues; biomedical MRI; biomedical equipment; diseases; patient treatment; prototypes; superconducting coils; superconducting magnets; water; 10.5T MRI system application; 10.5T MRI system safety studies; 10.5T MRI system success studies; H2O; Larmor wavelength; RF field losses; RF field nonuniformities; RF technology; biomedical research; disease intervention; frequency 450 MHz; health intervention; high field strength MRI system; high water content human tissues; human MRI system development; low field strengths; low frequencies; magnetic flux density 10.5 T; noninvasive investigation instrument; nuclear magnetic signal response; short-wave problems; signal-to-noise to field strength; size 7 cm; therapeutic intervention; whole-body MRI system; Arrays; Coils; Magnetic domains; Magnetic resonance imaging; Power amplifiers; Radio frequency; Superconducting magnets; EM modeling; MRI; RF coils; high field magnets; power amplifiers;
Conference_Titel :
Microwave Workshop Series on RF and Wireless Technologies for Biomedical and Healthcare Applications (IMWS-BIO), 2013 IEEE MTT-S International
Conference_Location :
Singapore
DOI :
10.1109/IMWS-BIO.2013.6756143
