Tesla Engineering Ltd., Water Lane, Storrington, West Sussex, RH20 3EA, UK.
Spinoza Centre for Neuroimaging, Amsterdam, The Netherlands.
MAGMA. 2023 Apr;36(2):211-225. doi: 10.1007/s10334-023-01081-3. Epub 2023 Apr 10.
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.
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.
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.
我们概述了对 14 特斯拉磁共振系统的展望。这包括利用高温超导体的新型全身磁体设计;控制台和相关电子设备;优化的用于大脑中质子测量的射频线圈设置,该线圈还具有局部匀场能力;以及高性能梯度集。
14 特斯拉系统可以被视为一种“中观设备”:一种能够在生物学相关尺度上进行测量的设备。在神经科学中,更高的空间分辨率将在解剖学上解析大脑皮层、小脑、皮质下结构和内核的所有层。光谱成像将同时测量兴奋和抑制活性,描述神经回路的兴奋/抑制平衡。在医学研究(包括脑疾病)中,我们将可视化结构异常的细粒度模式,并将这些变化与功能和分子变化联系起来。显著提高的光谱分辨率将使我们能够检测与病理途径相关的(动态变化的)单个代谢物,包括分子相互作用和动态疾病过程。
14 特斯拉系统将为神经科学和基础研究提供新的视角。我们预计,这一举措将开启超高场磁共振的新时代。
