Wu Jing, Liu Hui, Ye Qing, Gallezot Jean-Dominique, Naganawa Mika, Miao Tianshun, Lu Yihuan, Chen Ming-Kai, Esserman Denise A, Kyriakides Tassos C, Carson Richard E, Liu Chi
Center for Advanced Quantum Studies and Department of Physics, Beijing Normal University, Beijing, China.
Department of Radiology and Biomedical Imaging, Yale University, New Haven, CT, USA.
Med Phys. 2021 Sep;48(9):5219-5231. doi: 10.1002/mp.15113. Epub 2021 Aug 13.
The net uptake rate constant (K ) derived from dynamic imaging is considered the gold standard quantification index for FDG PET. In this study, we investigated the feasibility and assessed the clinical usefulness of generating K images for FDG PET using only two 5-min scans with population-based input function (PBIF).
Using a Siemens Biograph mCT, 10 subjects with solid lung nodules underwent a single-bed dynamic FDG PET scan and 13 subjects (five healthy and eight cancer patients) underwent a whole-body dynamic FDG PET scan in continuous-bed-motion mode. For each subject, a standard K image was generated using the complete 0-90 min dynamic data with Patlak analysis (t* = 20 min) and individual patient's input function, while a dual-time-point K image was generated from two 5-min scans based on the Patlak equations at early and late scans with the PBIF. Different start times for the early (ranging from 20 to 55 min with an increment of 5 min) and late (ranging from 50 to 85 min with an increment of 5 min) scans were investigated with the interval between scans being at least 30 min (36 protocols in total). The optimal dual-time-point protocols were then identified. Regions of interest (ROI) were drawn on nodules for the lung nodule subjects, and on tumors, cerebellum, and bone marrow for the whole-body-imaging subjects. Quantification accuracy was compared using the mean value of each ROI between standard K (gold standard) and dual-time-point K , as well as between standard K and relative standardized uptake value (SUV) change that is currently used in clinical practice. Correlation coefficients and least squares fits were calculated for each dual-time-point protocol and for each ROI. Then, the predefined criteria for identifying a reliable dual-time-point K estimation for each ROI were empirically determined as: (1) the squared correlation coefficient (R ) between standard K and dual-time-point K is larger than 0.9; (2) the absolute difference between the slope of the equality line (1.0) and that of the fitted line when plotting standard K versus dual-time-point K is smaller than 0.1; (3) the absolute value of the intercept of the fitted line when plotting standard K versus dual-time-point K normalized by the mean of the standard K across all subjects for each ROI is smaller than 10%. Using Williams' one-tailed t test, the correlation coefficient (R) between standard K and dual-time-point K was further compared with that between standard K and relative SUV change, for each dual-time-point protocol and for each ROI.
Reliable dual-time-point K images were obtained for all the subjects using our proposed method. The percentage error introduced by the PBIF on the dual-time-point K estimation was smaller than 1% for all 36 protocols. Using the predefined criteria, reliable dual-time-point K estimation could be obtained in 25 of 36 protocols for nodules and in 34 of 36 protocols for tumors. A longer time interval between scans provided a more accurate K estimation in general. Using the protocol of 20-25 min plus 80-85 or 85-90 min, very high correlations were obtained between standard K and dual-time-point K (R = 0.994, 0.980, 0.971 and 0.925 for nodule, tumor, cerebellum, and bone marrow), with all the slope values with differences ≤0.033 from 1 and all the intercept values with differences ≤0.0006 mL/min/cm from 0. The corresponding correlations were much lower between standard K and relative SUV change (R = 0.673, 0.684, 0.065, 0.246). Dual-time-point K showed a significantly higher quantification accuracy with respect to standard K than relative SUV change for all the 36 protocols (p < 0.05 using Williams' one-tailed t test).
Our proposed approach can obtain reliable K images and accurate K quantification from dual-time-point scans (5-min per scan), and provide significantly higher quantification accuracy than relative SUV change that is currently used in clinical practice.
动态成像得出的净摄取率常数(K)被认为是FDG PET的金标准量化指标。在本研究中,我们探讨了仅使用两次5分钟扫描及基于人群的输入函数(PBIF)生成FDG PET的K图像的可行性,并评估了其临床实用性。
使用西门子Biograph mCT,10例肺实性结节患者进行了单床位动态FDG PET扫描,13例受试者(5例健康者和8例癌症患者)以连续床位移动模式进行了全身动态FDG PET扫描。对于每位受试者,使用完整的0 - 90分钟动态数据及Patlak分析(t* = 20分钟)和个体患者的输入函数生成标准K图像,同时基于Patlak方程在早期和晚期扫描时使用PBIF从两次5分钟扫描生成双时间点K图像。研究了早期扫描(起始时间范围为20至55分钟,增量为5分钟)和晚期扫描(起始时间范围为50至85分钟,增量为5分钟)的不同起始时间,扫描间隔至少为30分钟(共36种方案)。然后确定最佳双时间点方案。在肺结节受试者的结节上以及全身成像受试者的肿瘤、小脑和骨髓上绘制感兴趣区(ROI)。使用标准K(金标准)和双时间点K之间每个ROI的平均值,以及标准K和临床实践中当前使用的相对标准化摄取值(SUV)变化之间比较定量准确性。计算每个双时间点方案和每个ROI的相关系数和最小二乘法拟合。然后,根据经验确定每个ROI可靠双时间点K估计的预定义标准为:(1)标准K与双时间点K之间的平方相关系数(R²)大于0.9;(2)绘制标准K与双时间点K时,等号线斜率(1.0)与拟合线斜率的绝对差值小于小于0.1;(3)绘制标准K与双时间点K时,拟合线截距的绝对值除以每个ROI所有受试者标准K的平均值小于10%。使用Williams单尾t检验,进一步比较每个双时间点方案和每个ROI的标准K与双时间点K之间的相关系数(R)以及标准K与相对SUV变化之间的相关系数。
使用我们提出的方法为所有受试者获得了可靠的双时间点K图像。对于所有36种方案,PBIF在双时间点K估计上引入的百分比误差小于1%。根据预定义标准,在36种方案中的25种方案可获得结节的可靠双时间点K估计,在36种方案中的34种方案可获得肿瘤的可靠双时间点K估计。一般来说,扫描之间较长的时间间隔可提供更准确的K估计。使用20 - 25分钟加80 - 85或85 - 90分钟的方案,标准K与双时间点K之间获得了非常高的相关性(结节、肿瘤、小脑和骨髓的R²分别为0.994、0.980、0.971和0.925),所有斜率值与1的差值≤0.033,所有截距值与0的差值≤0.0006 mL/min/cm。标准K与相对SUV变化之间的相应相关性要低得多(R²分别为0.673、0.684、0.065、0.246)。对于所有36种方案,双时间点K相对于标准K显示出比相对SUV变化显著更高的定量准确性(使用Williams单尾t检验,p < 0.05)。
我们提出的方法可以从双时间点扫描(每次扫描5分钟)获得可靠的K图像和准确的K定量,并且提供比临床实践中当前使用的相对SUV变化显著更高的定量准确性。
