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用于3T和7T磁共振成像扫描仪中器官特异性插入物的正电子发射断层显像探测器模块的磁共振成像兼容性评估。

Evaluation of the MRI compatibility of PET detectors modules for organ-specific inserts in a 3T and 7T MRI scanner.

作者信息

Schmidt Fabian P, Allen Magdelena S, Ladebeck Ralf, Breuer Johannes, Judenhofer Martin, Schmand Matthias, Catana Ciprian, Pichler Bernd J

机构信息

Department of Preclinical Imaging and Radiopharmacy, Werner Siemens Imaging Center, Eberhard-Karls University Tuebingen, Tuebingen, Germany.

Department of Radiology, Athinoula A. Martinos Center for Biomedical Imaging, Massachusetts General Hospital, Charlestown, USA.

出版信息

Med Phys. 2024 Feb;51(2):991-1006. doi: 10.1002/mp.16923. Epub 2023 Dec 27.

DOI:10.1002/mp.16923
PMID:38150577
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC10923015/
Abstract

BACKGROUND

Simultaneous positron emission tomography (PET)/magnetic resonance imaging (MRI) scanners and inserts are valuable tools for accurate diagnosis, treatment planning, and monitoring due to their complementary information. However, the integration of a PET system into an MRI scanner presents technical challenges for a distortion-free operation.

PURPOSE

We aim to develop a PET insert dedicated to breast imaging in combination with the 3T PET/MRI scanner Biograph mMR (Siemens Healthineers) as well as a brain PET insert for the 7T MRI scanner MAGNETOM Terra (Siemens Healthineers). For this development, we selected as a basis the C13500 series PET modules (Hamamatsu Photonics K.K.) as they offer an all-in-one solution with a scalable, modular design for compact integration with state-of-the-art performance. The original PET modules were not designed to be operated with an MRI scanner, therefore we implemented several modifications such as signal transmission via plastic optical fiber, radio frequency (RF) shielding of the front-end electronics, and filter for the power supply lines. In this work, we evaluated the mutual MRI compatibility between the modified PET modules and the 3T and 7T MRI scanner.

METHODS

We used a proof-of-concept setup with two detectors to comprehensively evaluate a potential distortion of the performance of the modified PET modules whilst exposing them to a variety of MR sequences up to the peak operation conditions of the Biograph mMR. A method using the periodicity of the sequences to identify distortions of the PET events in the phase of RF pulse transmission was introduced. Vice versa, the potential distortion of the Biograph mMR was evaluated by vendor proprietary MRI compatibility test sequences. Afterwards, these studies were extended to the MAGNETOM Terra.

RESULTS

No distortions were introduced by gradient field switching (field strength up to 20 mT/m at a slew rate of 66.0 T/ms ). However, RF pulse transmission induced a reduction of the single event rate from 33.0 kcounts/s to 32.0 kcounts/s and a degradation of the coincidence resolution time from 251 to 299 ps. Further, the proposed method revealed artifacts in the energy and timing histograms. Finally, by using the front-end filters it was possible to prevent any RF pulse induced distortion of event rate, energy, or time stamps even for a 700° flip angle (45.5 μT) sequence. The evaluations to assess potential distortions of the MRI scanner showed that carefully designed RF shielding boxes for the PET modules were required to prevent distortion of the RF spectra. The increase in B field inhomogeneity of 0.254 ppm and local changes of the B field of 12.5% introduced by the PET modules did not qualitatively affect the MR imaging with a spin echo and MPRAGE sequence for the Biograph mMR and the MAGNETOM Terra, respectively.

CONCLUSION

Our study demonstrates the feasibility of using a modified version of the PET modules in combination with 3T and 7T MRI scanners. Building upon the encouraging MRI compatibility results from our proof-of-concept detectors, we will proceed to develop PET inserts for breast and brain imaging using these modules.

摘要

背景

正电子发射断层扫描(PET)/磁共振成像(MRI)同步扫描仪及插入件因其互补信息,是精确诊断、治疗规划和监测的宝贵工具。然而,将PET系统集成到MRI扫描仪中会带来无失真运行方面的技术挑战。

目的

我们旨在开发一款与3T PET/MRI扫描仪Biograph mMR(西门子医疗)结合用于乳腺成像的PET插入件,以及一款用于7T MRI扫描仪MAGNETOM Terra(西门子医疗)的脑部PET插入件。在此开发过程中,我们选择C13500系列PET模块(浜松光子株式会社)作为基础,因为它们提供了一体化解决方案,具有可扩展的模块化设计,便于紧凑集成且具备先进性能。原始的PET模块并非设计用于与MRI扫描仪配合使用,因此我们进行了多项改进,如通过塑料光纤进行信号传输、对前端电子设备进行射频(RF)屏蔽以及对电源线设置滤波器。在本研究中,我们评估了经过改进的PET模块与3T和7T MRI扫描仪之间的相互MRI兼容性。

方法

我们使用了一个带有两个探测器的概念验证装置,在将经过改进的PET模块暴露于各种MR序列直至Biograph mMR的峰值运行条件下,全面评估其性能的潜在失真情况。引入了一种利用序列周期性来识别RF脉冲传输阶段PET事件失真的方法。反之,通过供应商专有的MRI兼容性测试序列评估Biograph mMR的潜在失真情况。之后,这些研究扩展到了MAGNETOM Terra。

结果

梯度场切换(场强高达20 mT/m, slew速率为66.0 T/ms)未引入失真。然而,RF脉冲传输导致单事件率从33.0 k计数/秒降至32.0 k计数/秒,符合时间分辨率从251 ps降至299 ps。此外,所提出的方法在能量和时间直方图中显示出伪影。最后,通过使用前端滤波器,即使对于700°翻转角(45.5 μT)序列,也能够防止RF脉冲引起的事件率、能量或时间戳的任何失真。评估MRI扫描仪潜在失真情况的结果表明,需要为PET模块精心设计RF屏蔽盒,以防止RF频谱失真。PET模块引入的B场不均匀性增加0.254 ppm以及B场局部变化12.5%,分别对Biograph mMR和MAGNETOM Terra使用自旋回波和MPRAGE序列进行的MR成像没有定性影响。

结论

我们的研究证明了使用经过改进的PET模块与3T和7T MRI扫描仪结合的可行性。基于我们概念验证探测器令人鼓舞的MRI兼容性结果,我们将继续使用这些模块开发用于乳腺和脑部成像的PET插入件。

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