通过基于 CT 的正电子射程校正来提高小动物 [Ga]DOTA 标记 PET/CT 研究的 PET 定量。

Improving PET Quantification of Small Animal [Ga]DOTA-Labeled PET/CT Studies by Using a CT-Based Positron Range Correction.

机构信息

QIMP group, Center for Medical Physics and Biomedical Engineering, Medical University of Vienna, Vienna, Austria.

Grupo de Física Nuclear, Dpto. Física Atómica, Molecular y Nuclear, Universidad Complutense de Madrid, CEI Moncloa, Madrid, Spain.

出版信息

Mol Imaging Biol. 2018 Aug;20(4):584-593. doi: 10.1007/s11307-018-1161-7.

DOI:10.1007/s11307-018-1161-7

PMID:29352372

Abstract

PURPOSE

Image quality of positron emission tomography (PET) tracers that emits high-energy positrons, such as Ga-68, Rb-82, or I-124, is significantly affected by positron range (PR) effects. PR effects are especially important in small animal PET studies, since they can limit spatial resolution and quantitative accuracy of the images. Since generators accessibility has made Ga-68 tracers wide available, the aim of this study is to show how the quantitative results of [Ga]DOTA-labeled PET/X-ray computed tomography (CT) imaging of neuroendocrine tumors in mice can be improved using positron range correction (PRC).

PROCEDURES

Eighteen scans in 12 mice were evaluated, with three different models of tumors: PC12, AR42J, and meningiomas. In addition, three different [Ga]DOTA-labeled radiotracers were used to evaluate the PRC with different tracer distributions: [Ga]DOTANOC, [Ga]DOTATOC, and [Ga]DOTATATE. Two PRC methods were evaluated: a tissue-dependent (TD-PRC) and a tissue-dependent spatially-variant correction (TDSV-PRC). Taking a region in the liver as reference, the tissue-to-liver ratio values for tumor tissue (TLR), lung (TLR), and necrotic areas within the tumors (TLR) and their respective relative variations (ΔTLR) were evaluated.

RESULTS

All TLR values in the PRC images were significantly different (p < 0.05) than the ones from non-PRC images. The relative differences of the tumor TLR values, respect to the case with no PRC, were ΔTLR 87 ± 41 % (TD-PRC) and 85 ± 46 % (TDSV-PRC). TLR decreased when applying PRC, being this effect more remarkable for the TDSV-PRC method, with relative differences respect to no PRC: ΔTLR = - 45 ± 24 (TD-PRC), - 55 ± 18 (TDSV-PRC). TLR values also decreased when using PRC, with more noticeable differences for TD-PRC: ΔTLR = - 52 ± 6 (TD-PRC), - 48 ± 8 (TDSV-PRC).

CONCLUSION

The PRC methods proposed provide a significant quantitative improvement in [Ga]DOTA-labeled PET/CT imaging of mice with neuroendocrine tumors, hence demonstrating that these techniques could also ameliorate the deleterious effect of the positron range in clinical PET imaging.

摘要

目的

发射高能正电子的正电子发射断层扫描（PET）示踪剂的图像质量受到正电子射程（PR）效应的显著影响，如 Ga-68、Rb-82 或 I-124。PR 效应在小动物 PET 研究中尤为重要，因为它们会限制图像的空间分辨率和定量准确性。由于发生器的可及性使得 Ga-68 示踪剂广泛可用，本研究的目的是展示如何使用正电子射程校正（PRC）来改善小鼠神经内分泌肿瘤的[Ga]DOTA 标记的 PET/计算机断层扫描（CT）成像的定量结果。

方法

在 12 只小鼠中评估了 18 次扫描，使用了三种不同的肿瘤模型：PC12、AR42J 和脑膜瘤。此外，使用了三种不同的[Ga]DOTA 标记的放射性示踪剂来评估不同示踪剂分布的 PRC：[Ga]DOTANOC、[Ga]DOTATOC 和[Ga]DOTATATE。评估了两种 PRC 方法：组织依赖性（TD-PRC）和组织依赖性空间变化校正（TDSV-PRC）。以肝脏中的一个区域为参考，评估了肿瘤组织（TLR）、肺（TLR）和肿瘤内坏死区域（TLR）的组织与肝脏的比值（TLR）及其各自的相对变化（ΔTLR）。

结果

PRC 图像中的所有 TLR 值均与非 PRC 图像的 TLR 值显著不同（p<0.05）。与未进行 PRC 校正的情况相比，肿瘤 TLR 值的相对差异为ΔTLR 87±41%（TD-PRC）和 85±46%（TDSV-PRC）。应用 PRC 时，TLR 值降低，而 TDSV-PRC 方法的影响更为显著，与未进行 PRC 校正的情况相比，相对差异为ΔTLR=-45±24（TD-PRC），-55±18（TDSV-PRC）。使用 PRC 时，TLR 值也降低，TD-PRC 的差异更为明显：ΔTLR=-52±6（TD-PRC），-48±8（TDSV-PRC）。

结论

所提出的 PRC 方法为小鼠神经内分泌肿瘤的[Ga]DOTA 标记的 PET/CT 成像提供了显著的定量改善，因此证明这些技术还可以改善临床 PET 成像中正电子射程的有害影响。

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通过基于 CT 的正电子射程校正来提高小动物 [Ga]DOTA 标记 PET/CT 研究的 PET 定量。

Improving PET Quantification of Small Animal [Ga]DOTA-Labeled PET/CT Studies by Using a CT-Based Positron Range Correction.

机构信息

出版信息

PURPOSE

PROCEDURES

RESULTS

CONCLUSION

目的

方法

结果

结论

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