P M Robitaille1, A Kangarlu, A M Abduljalil. 1. Center for Advanced Biomedical Imaging, Department of Radiology, Ohio State University, Columbus 43210, USA.
Abstract
PURPOSE: The purpose of this work is to discuss radio frequency (RF) penetration and its relevance to imaging the human head and to acquire images containing intricate structures located at the center of the brain with ultra high field MRI (UHFMRI). METHOD: A simple plane wave analysis of RF penetration was performed based on Maxwell equations as a function of frequency up to 900 MHz. Gradient-recalled images were acquired at 8 T (340 MHz) using an RF resonator operating in quadrature. Typical acquisition parameters were as follows: TR = 750 ms, TE = 17 ms, slice thickness = 2 mm, FOV = 20 x 20 cm, matrix = 1,024 x 1,024. The specific absorption rate was well below 1 W/kg. RESULTS: A simple analytical treatment, for a plane wave up to 900 MHz, reveals a lack of decreasing penetration depth with frequency beyond 200 MHz. Gradient-recalled echo images acquired from the human head displayed good contrast, homogeneity, and resolution. Importantly, excellent structural detail was observed on the resulting MR images, demonstrating that RF penetration is not a problem at 8 T. Images reveal excellent detail including the red nucleus, anterior commissure, fornix, mamillary body, pineal gland, and ependymal lining of the fourth ventricle. CONCLUSION: Structures located at the center of the human brain can be clearly visualized at 8 T with no detectable loss in signal intensity arising from RF penetration. The ability to examine these structures with UHFMRI will provide a powerful new modality for diagnostic radiology.
PURPOSE: The purpose of this work is to discuss radio frequency (RF) penetration and its relevance to imaging the human head and to acquire images containing intricate structures located at the center of the brain with ultra high field MRI (UHFMRI). METHOD: A simple plane wave analysis of RF penetration was performed based on Maxwell equations as a function of frequency up to 900 MHz. Gradient-recalled images were acquired at 8 T (340 MHz) using an RF resonator operating in quadrature. Typical acquisition parameters were as follows: TR = 750 ms, TE = 17 ms, slice thickness = 2 mm, FOV = 20 x 20 cm, matrix = 1,024 x 1,024. The specific absorption rate was well below 1 W/kg. RESULTS: A simple analytical treatment, for a plane wave up to 900 MHz, reveals a lack of decreasing penetration depth with frequency beyond 200 MHz. Gradient-recalled echo images acquired from the human head displayed good contrast, homogeneity, and resolution. Importantly, excellent structural detail was observed on the resulting MR images, demonstrating that RF penetration is not a problem at 8 T. Images reveal excellent detail including the red nucleus, anterior commissure, fornix, mamillary body, pineal gland, and ependymal lining of the fourth ventricle. CONCLUSION: Structures located at the center of the human brain can be clearly visualized at 8 T with no detectable loss in signal intensity arising from RF penetration. The ability to examine these structures with UHFMRI will provide a powerful new modality for diagnostic radiology.
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