Van Audenhaege Karen, Van Holen Roel, Vanhove Christian, Vandenberghe Stefaan
Department of Electronics and Information Systems, Ghent University-iMinds Medical IT, MEDISIP-IBiTech, De Pintelaan 185 block B/5, Ghent B-9000, Belgium.
Med Phys. 2015 Nov;42(11):667989. doi: 10.1118/1.4934371.
Brain single photon emission computed tomography (SPECT) imaging is an important clinical tool, with unique tracers for studying neurological diseases. Nowadays, most commercial SPECT systems are combined with x-ray computed tomography (CT) in so-called SPECT/CT systems to obtain an anatomical background for the functional information. However, while CT images have a high spatial resolution, they have a low soft-tissue contrast, which is an important disadvantage for brain imaging. Magnetic resonance imaging (MRI), on the other hand, has a very high soft-tissue contrast and does not involve extra ionizing radiation. Therefore, the authors designed a brain SPECT insert that can operate inside a clinical MRI.
The authors designed and simulated a compact stationary multipinhole SPECT insert based on digital silicon photomultiplier detector modules, which have shown to be MR-compatible and have an excellent intrinsic resolution (0.5 mm) when combined with a monolithic 2 mm thick LYSO crystal. First, the authors optimized the different parameters of the SPECT system to maximize sensitivity for a given target resolution of 7.2 mm in the center of the field-of-view, given the spatial constraints of the MR system. Second, the authors performed noiseless simulations of two multipinhole configurations to evaluate sampling and reconstructed resolution. Finally, the authors performed Monte Carlo simulations and compared the SPECT insert with a clinical system with ultrahigh-resolution (UHR) fan beam collimators, based on contrast-to-noise ratio and a visual comparison of a Hoffman phantom with a 9 mm cold lesion.
The optimization resulted in a stationary multipinhole system with a collimator radius of 150.2 mm and a detector radius of 172.67 mm, which corresponds to four rings of 34 diSPM detector modules. This allows the authors to include eight rings of 24 pinholes, which results in a system volume sensitivity of 395 cps/MBq. Noiseless simulations show sufficient axial sampling (in a Defrise phantom) and a reconstructed resolution of 5.0 mm (in a cold-rod phantom). The authors compared the 24-pinhole setup with a 34-pinhole system (with the same detector radius but a collimator radius of 156.63 mm) and found that 34 pinholes result in better uniformity but a worse reconstruction of the cold-rod phantom. The authors also compared the 24-pinhole system with a clinical triple-head UHR fan beam system based on contrast-to-noise ratio and found that the 24-pinhole setup performs better for the 6 mm hot and the 16 mm cold lesions and worse for the 8 and 10 mm hot lesions. Finally, the authors reconstructed noisy projection data of a Hoffman phantom with a 9 mm cold lesion and found that the lesion was slightly better visible on the multipinhole image compared to the fan beam image.
The authors have optimized a stationary multipinhole SPECT insert for MRI and showed the feasibility of doing brain SPECT imaging inside a MRI with an image quality similar to the best clinical SPECT systems available.
脑单光子发射计算机断层扫描(SPECT)成像是一种重要的临床工具,拥有用于研究神经疾病的独特示踪剂。如今,大多数商用SPECT系统与X射线计算机断层扫描(CT)相结合,形成所谓的SPECT/CT系统,以获取功能信息的解剖学背景。然而,虽然CT图像具有高空间分辨率,但软组织对比度低,这对于脑成像来说是一个重要缺点。另一方面,磁共振成像(MRI)具有非常高的软组织对比度,且不涉及额外的电离辐射。因此,作者设计了一种可在临床MRI设备内运行的脑SPECT插件。
作者基于数字硅光电倍增管探测器模块设计并模拟了一种紧凑型固定式多孔径SPECT插件,该探测器模块已证明与MRI兼容,并且与2毫米厚的单片LYSO晶体结合时具有出色的固有分辨率(0.5毫米)。首先,考虑到MR系统的空间限制,作者优化了SPECT系统的不同参数,以在视野中心给定7.2毫米的目标分辨率下最大化灵敏度。其次,作者对两种多孔径配置进行了无噪声模拟,以评估采样和重建分辨率。最后,作者进行了蒙特卡罗模拟,并基于对比度噪声比以及对带有9毫米冷区病变的霍夫曼体模的视觉比较,将SPECT插件与具有超高分辨率(UHR)扇形束准直器的临床系统进行了比较。
优化后得到一个固定式多孔径系统,其准直器半径为150.2毫米,探测器半径为172.67毫米,这对应于由34个数字硅光电倍增管探测器模块组成的四个环。这使得作者能够设置由24个针孔组成的八个环,从而使系统体积灵敏度达到395 cps/MBq。无噪声模拟显示(在德弗里斯体模中)轴向采样充足,(在冷棒体模中)重建分辨率为5.0毫米。作者将24针孔设置与34针孔系统(探测器半径相同,但准直器半径为156.63毫米)进行比较,发现34针孔可实现更好的均匀性,但对冷棒体模的重建效果较差。作者还基于对比度噪声比将24针孔系统与临床三头UHR扇形束系统进行比较,发现24针孔设置对6毫米热区和16毫米冷区病变的成像效果更好,而对8毫米和10毫米热区病变的成像效果更差。最后,作者重建了带有9毫米冷区病变的霍夫曼体模的噪声投影数据,发现与扇形束图像相比,多孔径图像上的病变稍更清晰可见。
作者对用于MRI的固定式多孔径SPECT插件进行了优化,并证明了在MRI设备内进行脑SPECT成像的可行性,其图像质量与现有的最佳临床SPECT系统相当。
