Permanent magnet for "gradient-free" MRI

用于“无梯度”MRI 的永磁体

• 批准号: RGPIN-2020-04414
• 负责人: Tomanek, Boguslaw
• 金额: $ 2.48万
• 依托单位: University of Alberta
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2021
• 资助国家: 加拿大
• 起止时间: 2021-01-01 至 2022-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=739816
• 关键词: Permanent; magnet; gradient; free; MRI

MRI is a well-established non-invasive diagnostic technique used in most modern hospitals that provides high quality images of the entire body. However, there are deficiencies that prevent faster growth and broader application of this valuable technique. Among them are high costs, claustrophobic geometry of the magnet and its substantial weight requiring special site preparation. We propose to address these weaknesses by designing and constructing a compact lightweight magnet specifically for the "gradient free" MRI technique called TRASE. While standard MRI requires time-variable strong gradients of the magnetic field, the TRASE technique, developed with the participation of the applicant, replaces spatial encoding using gradients of the magnetic field with the radiofrequency (RF) field, thus eliminating the magnetic field gradient components, namely the gradient coils and amplifiers used in current MRI systems. The TRASE technique also lessens the high homogeneity requirement for the magnetic field. It is therefore possible to produce inexpensive, light and silent MRI systems that can be made broadly available and used for new imaging applications. We have already collected MR images using magnets that are currently available. We now propose to design and construct a light, "slice selective" magnet comprising 3 coaxial rings that generate a homogenous magnetic field within a narrow cylinder which allows slice selection using non-selective RF pulses. This design will allow slice selection in one direction and 2D TRASE in the perpendicular plane. The design of the magnet is the result of advances in application of genetic algorithms to magnets construction, development of TRASE and our unique magnet design. To design the magnet, we will use Opera 3D software which performs finite element analysis. A Matlab script will provide magnet geometries and block specifications that will be optimized by generic algorithm. This data will be transferred to Opera to calculate the field distribution and provide feedback to Matlab for the subsequent iterations. Whereas current standard MRI magnets weigh thousands of kilograms, the estimated weight of the new magnet for imaging of the human wrist is 10kg. We intend to use an existing 3D printer to fabricate support for the magnetic blocks. The magnetic blocks will be purchased from Newland, China. The homogeneity of the magnet will be measured over a cylinder using a 3D Hall probe attached to an automated robotic arm and analyzed using cylindrical harmonics. Field inhomogeneities will be minimized by correcting the positions of the magnetic blocks and by fine shimming using small compensating magnets to bring homogeneity and distribution of the magnetic field to the target value. The magnet will allow construction of a prototype of the light TRASE MRI system in our laboratory.

MRI是一种成熟的非侵入性诊断技术，用于大多数现代医院，可提供全身的高质量图像。然而，存在的缺陷阻碍了这种有价值的技术的更快发展和更广泛的应用。其中包括高成本、磁体的幽闭几何形状及其需要特殊场地准备的巨大重量。我们建议通过设计和构建专门用于称为TRASE的“无梯度”MRI技术的紧凑型轻质磁体来解决这些弱点。 虽然标准MRI需要磁场的时变强梯度，但是在申请人的参与下开发的TRASE技术用射频（RF）场代替了使用磁场梯度的空间编码，从而消除了磁场梯度组件，即当前MRI系统中使用的梯度线圈和放大器。TRASE技术还降低了对磁场的高均匀性要求。因此，有可能生产出廉价、轻便和安静的MRI系统，这些系统可以广泛使用并用于新的成像应用。 我们已经使用目前可用的磁体收集了MR图像。我们现在提出设计和构造一种轻的“切片选择性”磁体，其包括3个同轴环，所述3个同轴环在窄圆柱内产生均匀磁场，所述均匀磁场允许使用非选择性RF脉冲进行切片选择。该设计将允许在一个方向上选择切片，并在垂直平面上选择2D TRASE。 磁体的设计是遗传算法在磁体构造中的应用、TRASE的开发和我们独特的磁体设计的结果。为了设计磁体，我们将使用Opera 3D软件进行有限元分析。Matlab脚本将提供将通过通用算法优化的磁体几何形状和块规格。这些数据将被传输到Opera以计算场分布，并为后续迭代提供反馈给Matlab。目前的标准MRI磁铁重达数千公斤，而用于人体手腕成像的新磁铁的估计重量为10公斤。 我们打算使用现有的3D打印机来制造磁性块的支撑。磁块将从中国纽兰购买。将使用连接到自动机械臂的3D霍尔探头在圆柱体上测量磁体的均匀性，并使用圆柱谐波进行分析。通过校正磁块的位置和使用小补偿磁体进行精细匀场以使磁场的均匀性和分布达到目标值，将磁场不均匀性降至最低。该磁铁将允许在我们的实验室中构建光TRASE MRI系统的原型。