First in‐vivo human imaging at 10.5T: Imaging the body at 447 MHz

He, Xiaoxuan; Ertürk, Mehmet; Grant, Andrea; Wu, Xiaoping; Lagore, Russell; DelaBarre, Lance; Eryaman, Yiğitcan; Adriany, Gregor; Auerbach, Edward J.; Moortele, Pierre-François Van de; Uğurbil, Kâmil; Metzger, Gregory J.

doi:10.1002/mrm.28131

Cited by 58 publications

(66 citation statements)

References 72 publications

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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%

Lowering the Thermal Noise Barrier in Functional Brain Mapping with Magnetic Resonance Imaging

Vizioli

Moeller

Dowdle

et al. 2020

Preprint

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Functional magnetic resonance imaging (fMRI) has become one of the most powerful tools for investigating the human brain. However, virtually all fMRI studies have relatively poor signal-to-noise ratio (SNR). We introduce a novel fMRI denoising technique, which removes noise that is indistinguishable from zero-mean Gaussian-distributed noise. Thermal noise, falling in this category, is a major noise source in fMRI, particularly, but not exclusively, at high spatial and/or temporal resolutions. Using 7-Tesla high-resolution data, we demonstrate remarkable improvements in temporal-SNR, the detection of stimulus-induced signal changes, and functional maps, while leaving stimulus-induced signal change amplitudes, image spatial resolution, and functional point-spread-function unaltered. We also provide supplementary data demonstrating that the method is equally applicable to supra-millimeter resolution 3- and 7-Tesla fMRI data, different cortical regions, stimulation/task paradigms, and acquisition strategies. The proposed denoising approach is expected to have a transformative impact on the scope and applications of fMRI to study the brain.

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Section: Introductionmentioning

confidence: 99%

Lowering the Thermal Noise Barrier in Functional Brain Mapping with Magnetic Resonance Imaging

Vizioli

Moeller

Dowdle

et al. 2020

Preprint

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“…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%

Musculoskeletal MRI at 7 T: do we need more or is it more than enough?

Aringhieri

Zampa

Tosetti³

2020

Eur Radiol Exp

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Ultra-high field magnetic resonance imaging (UHF-MRI) provides important diagnostic improvements in musculoskeletal imaging. The higher signal-to-noise ratio leads to higher spatial and temporal resolution which results in improved anatomic detail and higher diagnostic confidence. Several methods, such as T2, T2*, T1rho mapping, delayed gadolinium-enhanced, diffusion, chemical exchange saturation transfer, and magnetisation transfer techniques, permit a better tissue characterisation. Furthermore, UHF-MRI enables in vivo measurements by low-γ nuclei ( 23 Na, 31 P, 13 C, and 39 K) and the evaluation of different tissue metabolic pathways. European Union and Food and Drug Administration approvals for clinical imaging at UHF have been the first step towards a more routinely use of this technology, but some drawbacks are still present limiting its widespread clinical application. This review aims to provide a clinically oriented overview about the application of UHF-MRI in the different anatomical districts and tissues of musculoskeletal system and its pros and cons. Further studies are needed to consolidate the added value of the use of UHF-MRI in the routine clinical practice and promising efforts in technology development are already in progress.

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“…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%

Evaluation of a 16-Channel Transceiver Loop + Dipole Antenna Array for Human Head Imaging at 10.5 Tesla

et al. 2020

Self Cite

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We evaluated a 16-channel loop + dipole (LD) transceiver antenna array with improved specific absorption rate (SAR) efficiency for 10.5 Tesla (T) human head imaging applications. Three different array designs with equal inner dimensions were considered: an 8-channel dipole antenna, an 8channel loop, and a 16-channel LD antenna arrays. Signal-to-noise ratio (SNR) and B1 + efficiency (in units of µT per √W) were simulated and measured in 10.5 T magnetic resonance imaging (MRI) experiments. For the safety validation, 10 g SAR and SAR efficiency (defined as the B1 + over √ (peak 10 g SAR)) were calculated through simulation. Finally, high resolution porcine brain images were acquired with the 16channel LD antenna array, including a fast turbo-spin echo (TSE) sequence incorporating B1 shimming techniques. Both the simulation and experiments demonstrated that the combined 16-channel LD antenna array showed similar B1 + efficiency compared to the 8-channel dipole antenna and the 8-channel loop arrays in a circular polarized (CP) mode. In a central 2 mm × 2 mm region of the phantom, however, the 16-channel LD antenna array showed an improvement in peak 10 g SAR of 27.5 % and 32.5 % over the 8channel dipole antenna and the 8-channel loop arrays, respectively. We conclude that the proposed 16channel head LD antenna array design is capable of achieving ~7% higher SAR efficiency at 10.5 T compared to either the 8-channel loop-only or the 8-channel dipole-only antenna arrays of the same dimensions. INDEX TERMS dipole antenna array, human head array, loop array, magnetic resonance imaging, RF coil, ultra-high field

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First in‐vivo human imaging at 10.5T: Imaging the body at 447 MHz

Cited by 58 publications

References 72 publications

Lowering the Thermal Noise Barrier in Functional Brain Mapping with Magnetic Resonance Imaging

Lowering the Thermal Noise Barrier in Functional Brain Mapping with Magnetic Resonance Imaging

Musculoskeletal MRI at 7 T: do we need more or is it more than enough?

Evaluation of a 16-Channel Transceiver Loop + Dipole Antenna Array for Human Head Imaging at 10.5 Tesla

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