Titlebook: Ultra High Field Magnetic Resonance Imaging; Pierre-Marie Robitaille,Lawrence Berliner Book 2006 Springer-Verlag US 2006 biochemistry.brai

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The Challenges of Integrating A 9.4T MR Scanner for Human Brain Imaging,as been enhanced as field strengths have migrated upward to 3.0 Tesla. It is appropriate to consider the technical challenges of further improving sensitivity by moving from 3.0 to 9.4T, the highest magnetic field scanner now available for human MRI that became operational in 2004.

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Magnetic Susceptibility Effects in High Field MRI,s high as 14 Tesla. With these in vivo studies, the enhanced image contrast produced by the increased field strength and the improved image quality by the artifact reduction methods provide strong and stimulating evidence for exciting potential scientific applications of high field MRI.

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Ultra High Field Magnetic Resonance Imaging: A Historical Perspective,e in this discipline over the past 30 years [.]–[.]. Early coarse and grainy results [.] have given way to exquisite anatomical and functional images [.]–[.]. The availability of MRI is now synonymous with quality of medical care, even within the rural hospital setting, and the 1.5 Tesla scanner has

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Design Considerations for Ultra High Field MRI Magnet Systems,l to Noise Ratio (SNR) is approximately proportional to magnetic field strength [.,.], although other more subtle effects, such as chemical shift dispersion and susceptibility, also scale with field strength and can cause problems for good anatomical imaging. However, it is no surprise to learn that

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Aspects of Clinical Imaging at 7 T,. ., has spurred the development of MR technology from its very first application to clinical imaging. With maturing magnet, RF, and gradient technology, the clinical community has seen the static magnetic field of clinical systems increase from 0.2 to 1.5 to 3.0 T. Today, the “high field” label for