Key designs of a short-bore and cryogen-free high temperature superconducting magnet system for 14 T whole-body MRI

The progress of ultrahigh-field magnetic resonance (UHF-MR) provides meaningful technologies for the advancement of biomedical and diagnostic MRI. The argument for moving 7 T MRI into clinical applications is more compelling than ever. Images from these instruments have revealed new aspects of anatomy, function and physio-metabolic characteristics of the neuro, neurovascular, cardiovascular, musculoskeletal, renal, hepatic and ocular systems, as well as other organs and tissues with unparalleled detail. UHF-MR has shown an amazing spectrum of potential clinical uses, with implications for neuroscience, neurology, radiology, neuroradiology, cardiology, internal medicine, oncology, nephrology, ophthalmology and many other clinical fields [1][2][3][4][5][6][7].

Section: About Magnets and Mountainsmentioning

confidence: 99%

Section: About Magnets and Mountainsmentioning

confidence: 99%

Scaling the mountains: what lies above 7 Tesla magnetic resonance?

Schmidt

Keban

Bollmann

et al. 2023

“…The most important element of the system is undoubtedly the magnet. Following a lengthy consultation and evaluation process a high temperature superconducting (HTS) magnet was selected [ 22 ] to be manufactured by Neoscan Solutions GmbH (Magdeburg, DE). In [ 22 ] it was proposed to use a first generation HTS wire, the ceramic (and rare-earth-free) superconducting compound consisting of bismuth strontium calcium copper oxide (BSCCO, pronounced ‘bisko’) embedded within a silver-containing matrix, which has a critical field of 28 T. Stable magnets of 25 T have previously been constructed using BSCCO tape [ 23 ].…”

Section: Methodology and Hardware Configurationmentioning

confidence: 99%

“…Following a lengthy consultation and evaluation process a high temperature superconducting (HTS) magnet was selected [ 22 ] to be manufactured by Neoscan Solutions GmbH (Magdeburg, DE). In [ 22 ] it was proposed to use a first generation HTS wire, the ceramic (and rare-earth-free) superconducting compound consisting of bismuth strontium calcium copper oxide (BSCCO, pronounced ‘bisko’) embedded within a silver-containing matrix, which has a critical field of 28 T. Stable magnets of 25 T have previously been constructed using BSCCO tape [ 23 ]. As compared to a magnet based on a low temperature superconductor (LTS), an HTS magnet has the following generic advantages: HTS wire has a high current-carrying capacity, enabling a compact and relatively light magnet design.…”

Section: Methodology and Hardware Configurationmentioning

confidence: 99%

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A vision of 14 T MR for fundamental and clinical science

Bates

Dumoulin

Folkers

et al. 2023

Self Cite

Objective We outline our vision for a 14 Tesla MR system. This comprises a novel whole-body magnet design utilizing high temperature superconductor; a console and associated electronic equipment; an optimized radiofrequency coil setup for proton measurement in the brain, which also has a local shim capability; and a high-performance gradient set. Research fields The 14 Tesla system can be considered a ‘mesocope’: a device capable of measuring on biologically relevant scales. In neuroscience the increased spatial resolution will anatomically resolve all layers of the cortex, cerebellum, subcortical structures, and inner nuclei. Spectroscopic imaging will simultaneously measure excitatory and inhibitory activity, characterizing the excitation/inhibition balance of neural circuits. In medical research (including brain disorders) we will visualize fine-grained patterns of structural abnormalities and relate these changes to functional and molecular changes. The significantly increased spectral resolution will make it possible to detect (dynamic changes in) individual metabolites associated with pathological pathways including molecular interactions and dynamic disease processes. Conclusions The 14 Tesla system will offer new perspectives in neuroscience and fundamental research. We anticipate that this initiative will usher in a new era of ultra-high-field MR.

Radiofrequency antenna concepts for human cardiac MR at 14.0 T

Nurzed

Kuehne²,

Aigner

et al. 2023

Objective To examine the feasibility of human cardiac MR (CMR) at 14.0 T using high-density radiofrequency (RF) dipole transceiver arrays in conjunction with static and dynamic parallel transmission (pTx). Materials and methods RF arrays comprised of self-grounded bow-tie (SGBT) antennas, bow-tie (BT) antennas, or fractionated dipole (FD) antennas were used in this simulation study. Static and dynamic pTx were applied to enhance transmission field (B1+) uniformity and efficiency in the heart of the human voxel model. B1+ distribution and maximum specific absorption rate averaged over 10 g tissue (SAR10g) were examined at 7.0 T and 14.0 T. Results At 14.0 T static pTx revealed a minimum B1+ROI efficiency of 0.91 μT/√kW (SGBT), 0.73 μT/√kW (BT), and 0.56 μT/√kW (FD) and maximum SAR10g of 4.24 W/kg, 1.45 W/kg, and 2.04 W/kg. Dynamic pTx with 8 kT points indicate a balance between B1+ROI homogeneity (coefficient of variation < 14%) and efficiency (minimum B1+ROI > 1.11 µT/√kW) at 14.0 T with a maximum SAR10g < 5.25 W/kg. Discussion MRI of the human heart at 14.0 T is feasible from an electrodynamic and theoretical standpoint, provided that multi-channel high-density antennas are arranged accordingly. These findings provide a technical foundation for further explorations into CMR at 14.0 T.