Department of Surgical Sciences, Uppsala University, Uppsala, Sweden.
Department of Medical Physics, Uppsala University Hospital, Uppsala, Sweden.
J Neurosci Res. 2020 Nov;98(11):2208-2218. doi: 10.1002/jnr.24707. Epub 2020 Aug 6.
Aromatase, the enzyme that in the brain converts testosterone and androstenedione to estradiol and estrone, respectively, is a putative key factor in psychoneuroendocrinology. In vivo assessment of aromatase was performed to evaluate tracer kinetic models and optimal scan duration, for quantitative analysis of the aromatase positron emission tomography (PET) ligand [ C]cetrozole. Anatomical magnetic resonance and 90-min dynamic [ C]cetrozole PET-CT scans were performed on healthy women. Volume of interest (VOI)-based analyses with a plasma-input function were performed using the single-tissue and two-tissue (2TCM) reversible compartment models and plasma-input Logan analysis. Additionally, the simplified reference tissue model (SRTM), Logan reference tissue model (LRTM), and standardized uptake volume ratio model, with cerebellum as reference region, were evaluated. Parametric images were generated and regionally averaged voxel values were compared with VOI-based analyses of the reference tissue models. The optimal reference model was used for evaluation of a decreased scan duration. Differences between the plasma-input- and reference tissue-based methods and comparisons between scan durations were assessed by linear regression. The [ C]cetrozole time-activity curves were best described by the 2TCM. SRTM nondisplaceable binding potential (BP ), with cerebellum as reference region, can be used to estimate [ C]cetrozole binding and generated robust and quantitatively accurate results for a reduced scan duration of 60 min. Receptor parametric mapping, a basis function implementation of SRTM, as well as LRTM, produced quantitatively accurate parametric images, showing BP at the voxel level. As PET tracer, [ C]cetrozole can be employed for relatively short brain scans to measure aromatase binding using a reference tissue-based approach.
芳香酶,即脑内将睾酮和雄烯二酮分别转化为雌二醇和雌酮的酶,是神经精神内分泌学中的一个假定关键因素。本研究旨在评估芳香酶 PET 示踪剂 [¹¹C] 他莫昔芬的示踪动力学模型和最佳扫描时间,以进行定量分析。对健康女性进行了解剖磁共振成像和 90 分钟动态 [¹¹C] 他莫昔芬 PET-CT 扫描。使用单组织和双组织(2TCM)可逆室模型以及血浆输入 Logan 分析,基于感兴趣区(VOI)的分析和血浆输入函数进行了分析。此外,评估了简化参考组织模型(SRTM)、Logan 参考组织模型(LRTM)和标准化摄取值比模型(以小脑为参考区)。生成了参数图像,并将区域平均体素值与参考组织模型的 VOI 分析进行了比较。使用最佳参考模型评估了较短的扫描时间。通过线性回归评估了血浆输入和参考组织方法之间的差异以及不同扫描时间之间的差异。[¹¹C] 他莫昔芬的时间-活性曲线最适合用 2TCM 描述。以小脑为参考区的 SRTM 不可置换结合潜能(BP )可用于估计 [¹¹C] 他莫昔芬结合,并且在 60 分钟的较短扫描时间内生成了稳健且定量准确的结果。受体参数图,即 SRTM 的基函数实现,以及 LRTM,生成了定量准确的参数图像,显示了体素水平的 BP。作为 PET 示踪剂,[¹¹C] 他莫昔芬可用于相对较短的脑扫描,以使用参考组织方法测量芳香酶结合。
