Estimating Live-Time for New PET Scanner Configurations.

Lawrence R Macdonald, Ruth E Schmitz, Adam M Alessio, Robert L Harrison, Thomas K Lewellen, Paul E Kinahan
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引用次数: 2

Abstract

We present the derivation of a live-time model for predicting count rates in computer simulations of PET scanners. Computer models are frequently used to investigate new PET scanner configurations, but they typically do not account for the count losses caused by scanner-specific electronics and processing. The live-time fraction depends strongly on the photon flux incident on the detector. We modeled the live-time of a clinical PET scanner by relating measured and simulated single photon fluxes. Our model used data from a specific scanner, but the approach is generally applicable.We applied the live-time model to partial collimation on a PET scanner; in particular, a scanner with septa positioned between every third detector ring ("2.7D" acquisition mode). The photon flux was measured and simulated for conventional acquisition modes (2D, 3D), and simulated for partial collimation (2.7D). These data were used in the model to predict live-time for partial collimation. The model was then validated against measurements in 2.7D mode. At low activity the model was very accurate at predicting the live-time fraction. Over-estimation of count-rates by the simulations lead to an uncertainly in the live-model. The uncertainty increased with activity concentration, reaching 0.9% and 2.2% at 20 kBq/mL for singles and coincidence live-time, respectively. When applied to 2.7D mode, the model predicted coincidence live-time accurate to 2.2% and 10% at 5 kBq/mL and 20 kBq/mL in the phantom, respectively. The 2.7D singles-counting live-time was predicted to within 0.2% of the measured value for up to 20 kBq/mL in the phantom.

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估计新的PET扫描仪配置的实时时间。
我们提出了一个实时模型的推导,用于预测PET扫描仪的计算机模拟计数率。计算机模型经常用于研究新的PET扫描仪配置,但它们通常不能解释由扫描仪特定电子设备和处理引起的计数损失。活时间分数在很大程度上取决于入射到探测器上的光子通量。我们通过测量和模拟的单光子通量来模拟临床PET扫描仪的寿命。我们的模型使用来自特定扫描仪的数据,但该方法通常适用。我们将实时模型应用于PET扫描仪的部分准直;特别是,在每三个检测器环之间放置隔片的扫描仪(“2.7D”采集模式)。对传统采集模式(2D、3D)和部分准直模式(2.7D)下的光子通量进行了测量和模拟。这些数据在模型中用于预测部分准直的实时时间。然后在2.7D模式下对模型进行验证。在低活动时,该模型在预测活时间分数方面非常准确。模拟对计数率的过高估计导致了实际模型的不确定性。不确定性随着活性浓度的增加而增加,在20 kBq/mL时,单个和重合存活时间分别达到0.9%和2.2%。当应用于2.7D模式时,该模型在5 kBq/mL和20 kBq/mL时预测的吻合时间分别精确到2.2%和10%。2.7D的单次计数寿命预测为20kbq /mL,与实测值相差0.2%以内。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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