Sarty Gordon E, Vidarsson Logi
Department of Psychology and Division of Biomedical Engineering, University of Saskatchewan, Saskatoon, Saskatchewan, Canada.
LT Imaging, Toronto, Ontario, Canada.
Magn Reson Imaging. 2018 Feb;46:47-55. doi: 10.1016/j.mri.2017.10.007. Epub 2017 Nov 4.
While the idea of using spatial encoding fields (SEM) for image formation has been proven, conventional wisdom still holds that a magnetic resonance imaging (MRI) system begins with a highly uniform magnetic field. In particular, radio frequency (RF) encoding MRIs designed and tested to date have largely used uniform magnetic fields. Here we demonstrate magnetic resonance imaging in a magnetic field with a built-in gradient that gives non-planar slices - curved surfaces - when the nuclear spins are excited with narrow band RF pulses. Image encoding on these naturally occurring non-planar slices was accomplished with RF encoding using a non-linear spatially varying B phase gradient. The imaging methods were demonstrated on a small prototype MRI instrument. The MRI has no switched magnetic field gradients - it is "gradient-free". A low field gradient-free MRI with low mass permanent magnets and simple, low power, RF encoding hardware is ideal for deployment on the International Space Station for the study of astronaut muscle and bone mass loss. Gradient-free natural slice encoding MRI designs would also be portable enough for application in remote terrestrial locations, in emergency rooms and in operating rooms where they can be used with minimally invasive and robotic surgery.
虽然利用空间编码场(SEM)进行图像形成的想法已得到证实,但传统观念仍然认为磁共振成像(MRI)系统始于高度均匀的磁场。特别是,迄今为止设计和测试的射频(RF)编码MRI在很大程度上都使用了均匀磁场。在此,我们展示了在具有内置梯度的磁场中进行磁共振成像,当用窄带RF脉冲激发核自旋时,该磁场会产生非平面切片——曲面。利用非线性空间变化的B相梯度通过RF编码在这些自然产生的非平面切片上完成图像编码。这些成像方法在小型MRI原型仪器上得到了验证。该MRI没有切换磁场梯度——它是“无梯度的”。具有低质量永磁体和简单、低功耗RF编码硬件的低场无梯度MRI非常适合部署在国际空间站上,用于研究宇航员的肌肉和骨质流失。无梯度自然切片编码MRI设计也将足够便携,可应用于偏远的地面地点、急诊室和手术室,在这些地方可与微创和机器人手术配合使用。
