Kim Su Jin, Lee Jae Sung, Im Ki Chum, Kim Seog-Young, Park Soo-Ah, Lee Seung Jin, Oh Seung Jun, Lee Dong Soo, Moon Dae Hyuk
Department of Nuclear Medicine, College of Medicine, Seoul National University, Seoul, Korea.
J Nucl Med. 2008 Dec;49(12):2057-66. doi: 10.2967/jnumed.108.053215. Epub 2008 Nov 7.
3'-Deoxy-3'-(18)F-fluorothymidine ((18)F-FLT) is a thymidine analog that was developed for measuring tumor proliferation with PET. The aim of this study was to establish a kinetic modeling analysis method for quantitative (18)F-FLT PET studies in subcutaneous tumor models in mice.
To explore the validity of an image-derived left ventricular input function, we measured equilibrium constants for plasma and whole blood and metabolite fractions in blood after (18)F-FLT injection. In parallel, dynamic (18)F-FLT PET scans were acquired in 24 mice with a small-animal dedicated PET scanner to compare arterial blood activities obtained by PET and blood sampling. We then investigated kinetic models for (18)F-FLT in human epithelial carcinoma (A431) and Lewis lung carcinoma tumor models in mice. Three-compartment models with reversible phosphorylation (k(4) not equal 0, 3C5P) and irreversible phosphorylation (k(4) = 0, 3C4P) and a 2-compartment model (2C3P) were examined. The Akaike information criterion and F statistics were used to select the best model for the dataset. Gjedde-Patlak graphic analysis was performed, and standardized uptake values in the last frame were calculated for comparison purposes. In addition, quantitative PET parameters were compared with Ki-67 immunostaining results.
(18)F-FLT equilibrated rapidly (within 30 s) between plasma and whole blood, and metabolite fractions were negligible during PET scans. A high correlation between arterial blood sampling and PET data was observed. For 120-min dynamic PET data, the 3C5P model best described tissue time-activity curves for tumor regions. The net influx of (18)F-FLT (K(FLT)) and k(3) obtained with this model showed reasonable intersubject variability and discrimination ability for tumor models with different proliferation properties. The K(FLT) obtained from the 60- or 90-min data correlated well with that obtained from the 120-min data as well as with the Ki-67 results.
The image-derived arterial input function was found to be feasible for kinetic modeling studies of (18)F-FLT PET in mice, and kinetic modeling analysis with an adequate compartment model provided reliable kinetic parameters for measuring tumor proliferation.
3'-脱氧-3'-(18)F-氟代胸苷((18)F-FLT)是一种胸苷类似物,开发用于通过正电子发射断层扫描(PET)测量肿瘤增殖。本研究的目的是建立一种动力学建模分析方法,用于小鼠皮下肿瘤模型中(18)F-FLT PET定量研究。
为了探讨图像衍生的左心室输入函数的有效性,我们测量了(18)F-FLT注射后血浆和全血的平衡常数以及血液中的代谢物分数。同时,使用小动物专用PET扫描仪对24只小鼠进行动态(18)F-FLT PET扫描,以比较PET获得的动脉血活性和血样采集结果。然后,我们研究了(18)F-FLT在人上皮癌(A431)和小鼠Lewis肺癌肿瘤模型中的动力学模型。研究了具有可逆磷酸化(k(4)≠0, 3C5P)和不可逆磷酸化(k(4)=0, 3C4P)的三室模型以及两室模型(2C3P)。使用赤池信息准则和F统计量为数据集选择最佳模型。进行了Gjedde-Patlak图形分析,并计算了最后一帧中的标准化摄取值以作比较。此外,将PET定量参数与Ki-67免疫染色结果进行比较。
(18)F-FLT在血浆和全血之间迅速平衡(30秒内),PET扫描期间代谢物分数可忽略不计。观察到动脉血样采集与PET数据之间具有高度相关性。对于120分钟的动态PET数据,3C5P模型最能描述肿瘤区域的组织时间-活性曲线。用该模型获得的(18)F-FLT净流入量(K(FLT))和k(3)显示出合理的个体间变异性以及对具有不同增殖特性的肿瘤模型的区分能力。从60分钟或90分钟数据获得的K(FLT)与从120分钟数据获得的K(FLT)以及Ki-67结果具有良好的相关性。
发现图像衍生的动脉输入函数对于小鼠(18)F-FLT PET的动力学建模研究是可行的,并且使用适当的房室模型进行动力学建模分析为测量肿瘤增殖提供了可靠的动力学参数。
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