在低场（<100 mT）永磁体磁共振成像系统中存在无源医疗植入物的情况下，对位移力和图像伪影进行特征描述，并与临床磁共振成像系统进行比较。

Characterization of displacement forces and image artifacts in the presence of passive medical implants in low-field (<100 mT) permanent magnet-based MRI systems, and comparisons with clinical MRI systems.

机构信息

CJ Gorter Center for High Field MRI, Department of Radiology, Leiden University Medical Center, Leiden, the Netherlands.

Department of Neurosurgery, Carle Foundation Hospital, Urbana. IL 61801, USA.

出版信息

Phys Med. 2021 Apr;84:116-124. doi: 10.1016/j.ejmp.2021.04.003. Epub 2021 Apr 21.

DOI:10.1016/j.ejmp.2021.04.003

PMID:33894581

Abstract

PURPOSE

To investigate the displacement forces and image artifacts associated with passive medical implants for recently-developed low-field (<100 mT) MRI systems, and to compare these with values from higher field strengths used for clinical diagnosis.

METHODS

Setups were constructed to measure displacement forces in a permanent magnet-based Halbach array used for in vivo MRI at 50 mT, and results compared with measurements at 7 T. Image artifacts were assessed using turbo (fast) spin echo imaging sequences for four different passive medical implants: a septal occluder, iliac stent, pedicle screw and (ferromagnetic) endoscopic clip. Comparisons were made with artifacts produced at 1.5, 3 and 7 T. Finally, specific absorption rate (SAR) simulations were performed to determine under what operating conditions the limits might be approached at low-field.

RESULTS

Displacement forces at 50 mT on all but the ferromagnetic implant were between 1 and 10 mN. Image artifacts at 50 mT were much less than at clinical field strengths for all passive devices, and with the exception of the ferromagnetic clip. SAR simulations show that very long echo train (>128) turbo spin echo sequences can be run with short inter-pulse times (5-10 ms) within SAR limits.

CONCLUSIONS

This work presents the first evaluation of the effects of passive implants at field strengths less than 100 mT in terms of displacement forces, image artifacts and SAR. The results support previous claims that such systems can be used safely and usefully in challenging enviroments such as the intensive care unit.

摘要

目的

研究与最近开发的低场（<100 mT）MRI 系统相关的无源医疗植入物的位移力和图像伪影，并将其与用于临床诊断的更高场强的值进行比较。

方法

构建了用于在 50 mT 下进行体内 MRI 的基于永久磁铁的 Halbach 阵列的位移力测量设置，并将结果与 7 T 的测量结果进行了比较。使用涡轮（快速）自旋回波成像序列评估了四种不同无源医疗植入物（隔瓣器、髂支架、椎弓根螺钉和（铁磁性）内窥镜夹）的图像伪影。与在 1.5、3 和 7 T 产生的伪影进行了比较。最后，进行了比吸收率（SAR）模拟，以确定在低场下可能达到限制的操作条件。

结果

除铁磁性植入物外，所有植入物在 50 mT 下的位移力均在 1 至 10 mN 之间。所有无源设备在 50 mT 时的图像伪影都远小于临床场强，除铁磁性夹外。SAR 模拟表明，非常长的回波链（>128）涡轮自旋回波序列可以在 SAR 限制内使用短的脉冲间时间（5-10 ms）运行。

结论

这项工作首次评估了在低于 100 mT 的场强下，无源植入物在位移力、图像伪影和 SAR 方面的影响。结果支持了先前的说法，即在重症监护室等具有挑战性的环境中，此类系统可以安全且有用地使用。

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在低场（<100 mT）永磁体磁共振成像系统中存在无源医疗植入物的情况下，对位移力和图像伪影进行特征描述，并与临床磁共振成像系统进行比较。

Characterization of displacement forces and image artifacts in the presence of passive medical implants in low-field (<100 mT) permanent magnet-based MRI systems, and comparisons with clinical MRI systems.

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出版信息

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