Institute of Medical Physics, University of Erlangen-Nürnberg, Erlangen, Germany.
Med Phys. 2012 Jul;39(7):4306-15. doi: 10.1118/1.4729716.
In simultaneous positron emission tomography/magnetic resonance (PET/MR) imaging, local receiver surface radiofrequency (RF) coils are positioned in the field-of-view (FOV) of the PET detector during PET/MR data acquisition and potentially attenuate the PET signal. For flexible body RF surface coils placed on top of the patient's body, MR-based attenuation correction (AC) is an unsolved problem since the RF coils are not inherently visible in MR images and their individual position in the FOV is patient specific and not known a priori. The aim of this work was to quantify the effect of local body RF coils used in the Biograph mMR hybrid PET/MR system on PET emission data and to present techniques for MR-based position determination of these specific local RF coils.
Acquisitions of a homogeneous phantom were performed on a whole-body PET/MRI scanner. Two different PET emission scans were performed, with and without the local body matrix RF coil placed on the top of the phantom. For position determination of the coil, two methods were applied. First, cod liver oil capsules were attached to the surface of the coil and second, an ultrashort echo time (UTE) sequence was used. PET images were reconstructed in five different ways: (1) PET reference scan without the coil, (2) PET scan with the coil, but omitting the coil in AC (PET/MR scanning conditions), (3) AC of the coil using a CT scan of the same phantom setup and registration via capsules, (4) same setup as 3, but registration was done using UTE images, neglecting the capsules, and (5) registration using the capsules, but the CT was performed with the coil placed flat on the CT table and the outer regions of the coil were cropped. The activity concentrations were then compared to the reference scan. For clinical evaluation of the concept, the presented methods were also evaluated on a patient.
The oil capsules were visible in the MR and CT images and image registration was straightforward. The UTE images show only parts of the coil's plastic housing and image registration was more difficult. The overall loss of true counts due to the presence of the surface coil is 4.7%. However, a spatially dependent analysis shows larger deviation (10%-15% attenuation) of the activity concentration in the top part of the phantom close to the coil. When accounting for the RF coil for PET AC, attenuation due to the RF coil could mostly be corrected. These results of the phantom studies were confirmed by the patient measurements.
Disregarding local coils in PET AC can lead to a bias of the AC PET images that is regional dependent. The closer the analyzed region is located to the coil, the higher the bias. Cod liver oil capsules or the UTE sequence can be used for RF coil position determination. The middle part of the examined RF coil hosting the preamplifiers and electronic components provides the highest attenuating part. Consequently, emphasis should be put on correcting for this portion of the RF coils with the suggested methods.
在正电子发射断层扫描/磁共振(PET/MR)成像中,局部接收表面射频(RF)线圈在 PET/MR 数据采集期间放置在 PET 探测器的视场(FOV)内,并且可能会衰减 PET 信号。对于放置在患者身体顶部的灵活体 RF 表面线圈,由于 RF 线圈在 MR 图像中不可见,并且其在 FOV 中的位置是特定于患者的并且事先未知,因此基于 MR 的衰减校正(AC)是一个未解决的问题。这项工作的目的是量化在 Biograph mMR 混合 PET/MR 系统中使用的局部体 RF 线圈对 PET 发射数据的影响,并介绍用于确定这些特定局部 RF 线圈位置的技术。
在全身 PET/MRI 扫描仪上进行均匀体模的采集。进行了两次不同的 PET 发射扫描,一次是在体模顶部放置局部体矩阵 RF 线圈,另一次是不放置线圈。为了确定线圈的位置,应用了两种方法。首先,在线圈表面附着鱼肝油胶囊,其次,使用超短回波时间(UTE)序列。以五种不同方式重建 PET 图像:(1)没有线圈的 PET 参考扫描,(2)带有线圈的 PET 扫描,但在 AC 中省略了线圈(PET/MR 扫描条件),(3)使用相同体模设置的 CT 扫描对线圈进行 AC,并通过胶囊进行注册,(4)与 3 相同的设置,但使用 UTE 图像进行注册,忽略胶囊,(5)使用胶囊进行注册,但在 CT 中线圈放置在 CT 台上并裁剪线圈的外部区域。然后将活性浓度与参考扫描进行比较。为了临床评估该概念,还在患者身上评估了所提出的方法。
鱼肝油胶囊在 MR 和 CT 图像中可见,图像注册很简单。UTE 图像仅显示线圈塑料外壳的一部分,图像注册更加困难。由于表面线圈的存在而导致的真实计数的总损失为 4.7%。然而,基于空间的分析显示,在靠近线圈的体模顶部,活性浓度的偏差较大(10%-15%衰减)。当在 PET AC 中考虑 RF 线圈时,RF 线圈引起的衰减可以得到大部分纠正。这些体模研究的结果得到了患者测量的证实。
在 PET AC 中忽略局部线圈可能会导致 AC PET 图像产生与区域相关的偏差。分析区域越靠近线圈,偏差越大。鱼肝油胶囊或 UTE 序列可用于 RF 线圈位置确定。容纳前置放大器和电子元件的线圈的中间部分提供了衰减最高的部分。因此,应强调使用建议的方法来纠正 RF 线圈的这部分。
