2019
DOI: 10.1002/mrm.28131
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First in‐vivo human imaging at 10.5T: Imaging the body at 447 MHz

Abstract: Purpose To investigate the feasibility of imaging the human torso and to evaluate the performance of several radiofrequency (RF) management strategies at 10.5T. Methods Healthy volunteers were imaged on a 10.5T whole‐body scanner in multiple target anatomies, including the prostate, hip, kidney, liver, and heart. Phase‐only shimming and spoke pulses were used to demonstrate their performance in managing the B1+ inhomogeneity present at 447 MHz. Imaging protocols included both qualitative and quantitative acqui… Show more

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Cited by 68 publications
(66 citation statements)
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“…This limitation is a major impediment to expanding the spatiotemporal scale of fMRI applications as well as the utility, interpretation, and ultimate impact of fMRI data. One strategy to alleviate this limitation is to pursue even higher magnetic fields [11][12][13] . Another simple and commonly used approach is the implementation of longer scan sessions, though this approach is not always optimal, since cognitive responses are modulated by attention and internal mental states, which likely change over long scan sessions.…”
Section: Introductionmentioning
confidence: 99%
“…This limitation is a major impediment to expanding the spatiotemporal scale of fMRI applications as well as the utility, interpretation, and ultimate impact of fMRI data. One strategy to alleviate this limitation is to pursue even higher magnetic fields [11][12][13] . Another simple and commonly used approach is the implementation of longer scan sessions, though this approach is not always optimal, since cognitive responses are modulated by attention and internal mental states, which likely change over long scan sessions.…”
Section: Introductionmentioning
confidence: 99%
“…However, 7-T MRI was more prone to artefacts due to B 1 inhomogeneities, radiofrequency (RF) penetration depth and susceptibility effects around periarticular calcifications. Even magnetic fields higher than 7 T have been explored for hip MRI, as demonstrated by He et al [ 14 ] reporting a detailed depiction of fine structures with a 0.7-mm isotropic voxel and excellent contrast at 10.5 T. Thanks to RF management strategies developed for 7-T magnets and phase shimming techniques, they obtained suitable bilateral hip images at 10.5 T with even better results when unilateral imaging was performed.…”
Section: Cartilagementioning
confidence: 99%
“…However, the short wavelength in the human body at such frequencies contributes to a significantly non-uniform field distribution [10][11][12]. Upon expanding the highest MR field strength from 4 tesla (T) [13] to 7 T [5], [12] then to 10.5 T [14], [15], it became apparent that more control over the transmit field was required to achieve acceptable imaging uniformity in the human body. Considering an average relative permittivity (εr) of 50 for water dominated tissue types at UHF for 10.5 T proton based imaging, the resulting shortened wavelength (~95 mm) leads to the type of non-uniform field distribution in the head at 10.5 T previously experienced in the torso at 7 T [16], [17].…”
Section: Introductionmentioning
confidence: 99%