Department of Radiology, University of California, Davis, CA, United States of America.
Phys Med Biol. 2020 Dec 17;65(24):245028. doi: 10.1088/1361-6560/abc5ca.
Standard dual-energy computed tomography (CT) uses two different x-ray energies to obtain energy-dependent tissue attenuation information to allow quantitative material decomposition. The combined use of dual-energy CT and positron emission tomography (PET) may provide a more comprehensive characterization of disease states in cancer and other diseases. However, the integration of dual-energy CT with PET is not trivial, either requiring costly hardware upgrades or increasing radiation exposure. This paper proposes a different dual-energy CT imaging method that is enabled by PET. Instead of using a second x-ray CT scan with a different energy, this method exploits time-of-flight PET image reconstruction via the maximum likelihood attenuation and activity (MLAA) algorithm to obtain a 511 keV gamma-ray attenuation image from PET emission data. The high-energy gamma-ray attenuation image is then combined with the low-energy x-ray CT of PET/CT to provide a pair of dual-energy CT images. A major challenge with the standard MLAA reconstruction is the high noise present in the reconstructed 511 keV attenuation map, which would not compromise the PET activity reconstruction too much but may significantly affect the performance of the gamma-ray attenuation image for material decomposition. To overcome the problem, we further propose a kernel MLAA algorithm to exploit the prior information from the available x-ray CT image. We conducted a computer simulation to test the concept and algorithm for the task of material decomposition. The simulation results demonstrate that this PET-enabled dual-energy CT method is promising for quantitative material decomposition. The proposed method can be readily implemented on time-of-flight PET/CT scanners to enable simultaneous PET and dual-energy CT imaging.
标准的双能计算机断层扫描(CT)使用两种不同的 X 射线能量来获取能量相关的组织衰减信息,以实现定量物质分解。双能 CT 与正电子发射断层扫描(PET)的联合使用可能为癌症和其他疾病的状态提供更全面的特征描述。然而,双能 CT 与 PET 的集成并非易事,要么需要昂贵的硬件升级,要么增加辐射暴露。本文提出了一种不同的双能 CT 成像方法,该方法由 PET 实现。这种方法不是使用具有不同能量的第二套 X 射线 CT 扫描,而是利用时间-of-flight PET 图像重建通过最大似然衰减和活性(MLAA)算法,从 PET 发射数据中获得 511keV 伽马射线衰减图像。然后,将高能伽马射线衰减图像与 PET/CT 的低能 X 射线 CT 结合,提供一对双能 CT 图像。标准 MLAA 重建的一个主要挑战是重建的 511keV 衰减图中存在高噪声,这不会对 PET 活性重建造成太大影响,但可能会显著影响伽马射线衰减图像在物质分解中的性能。为了解决这个问题,我们进一步提出了一种核 MLAA 算法,利用来自可用 X 射线 CT 图像的先验信息。我们进行了计算机模拟,以测试材料分解任务的概念和算法。模拟结果表明,这种基于 PET 的双能 CT 方法在定量物质分解方面很有前途。该方法可以很容易地在时间-of-flight PET/CT 扫描仪上实现,以实现同时进行 PET 和双能 CT 成像。