Larson K B, Markham J, Raichle M E
J Cereb Blood Flow Metab. 1987 Aug;7(4):443-63. doi: 10.1038/jcbfm.1987.88.
All tracer-kinetic models currently employed with positron-emission tomography (PET) are based on compartmental assumptions. Our first indication that a compartmental model might suffer from severe limitations in certain circumstances when used with PET occurred when we implemented the Kety tissue-autoradiography technique for measuring CBF and observed that the resulting CBF estimates, rather than remaining constant (to within predictable statistical uncertainty) as expected, fell with increasing scan duration T when T greater than 1 min. After ruling out other explanations, we concluded that a one-compartment model does not possess sufficient realism for adequately describing the movement of labeled water in brain. This article recounts our search for more realistic substitute models. We give our derivations and results for the residue-detection impulse responses for unit capillary-tissue systems of our two candidate distributed-parameter models. In a sequence of trials beginning with the simplest, we tested four progressively more detailed candidate models against data from appropriate residue-detection experiments. In these, we generated high-temporal-resolution counting-rate data reflecting the history of radiolabeled-water uptake and washout in the brains of rhesus monkeys. We describe our treatment of the data to yield model-independent empirical values of CBF and of other parameters. By substituting these into our trial-model functions, we were able to make direct comparisons of the model predictions with the experimental dynamic counting-rate histories, confirming that our reservations concerning the one-compartment model were well founded and obliging us to reject two others. We conclude that a two-barrier distributed-parameter model has the potential of serving as a substitute for the Kety model in PET measurements of CBF in patients, especially when scan durations for T greater than 1 min are desired.
目前正电子发射断层扫描(PET)所采用的所有示踪动力学模型均基于房室假设。当我们采用凯蒂组织自显影技术测量脑血流量(CBF),并观察到所得的CBF估计值并非如预期那样保持恒定(在可预测的统计不确定性范围内),而是在扫描持续时间T大于1分钟时随着T的增加而下降时,我们首次意识到房室模型在与PET一起使用时,在某些情况下可能存在严重局限性。在排除其他解释后,我们得出结论,单房室模型对于充分描述标记水在大脑中的移动缺乏足够的真实性。本文讲述了我们寻找更现实替代模型的过程。我们给出了两个候选分布参数模型的单位毛细血管 - 组织系统残留检测脉冲响应的推导和结果。在一系列从最简单的开始的试验中,我们针对来自适当残留检测实验的数据测试了四个越来越详细的候选模型。在这些实验中,我们生成了反映恒河猴大脑中放射性标记水摄取和洗脱历史的高时间分辨率计数率数据。我们描述了对数据的处理,以得出CBF和其他参数的与模型无关的经验值。通过将这些值代入我们的试验模型函数,我们能够直接比较模型预测与实验动态计数率历史,证实我们对单房室模型的保留意见是有充分根据的,并且迫使我们拒绝另外两个模型。我们得出结论,双屏障分布参数模型有潜力在PET测量患者脑血流量时替代凯蒂模型,特别是当需要T大于1分钟的扫描持续时间时。
