Department of Radiology, University of California Davis Medical Center, Sacramento, California.
Department of Biomedical Engineering, University of California, Davis, Davis, California.
J Nucl Med. 2024 May 1;65(5):714-721. doi: 10.2967/jnumed.123.267036.
The lungs are supplied by both the pulmonary arteries carrying deoxygenated blood originating from the right ventricle and the bronchial arteries carrying oxygenated blood downstream from the left ventricle. However, this effect of dual blood supply has never been investigated using PET, partially because the temporal resolution of conventional dynamic PET scans is limited. The advent of PET scanners with a long axial field of view, such as the uEXPLORER total-body PET/CT system, permits dynamic imaging with high temporal resolution (HTR). In this work, we modeled the dual-blood input function (DBIF) and studied its impact on the kinetic quantification of normal lung tissue and lung tumors using HTR dynamic PET imaging. Thirteen healthy subjects and 6 cancer subjects with lung tumors underwent a dynamic F-FDG scan with the uEXPLORER for 1 h. Data were reconstructed into dynamic frames of 1 s in the early phase. Regional time-activity curves of lung tissue and tumors were analyzed using a 2-tissue compartmental model with 3 different input functions: the right ventricle input function, left ventricle input function, and proposed DBIF, all with time delay and dispersion corrections. These models were compared for time-activity curve fitting quality using the corrected Akaike information criterion and for differentiating lung tumors from lung tissue using the Mann-Whitney test. Voxelwise multiparametric images by the DBIF model were further generated to verify the regional kinetic analysis. The effect of dual blood supply was pronounced in the high-temporal-resolution time-activity curves of lung tumors. The DBIF model achieved better time-activity curve fitting than the other 2 single-input models according to the corrected Akaike information criterion. The estimated fraction of left ventricle input was low in normal lung tissue of healthy subjects but much higher in lung tumors (∼0.04 vs. ∼0.3, < 0.0003). The DBIF model also showed better robustness in the difference in F-FDG net influx rate [Formula: see text] and delivery rate [Formula: see text] between lung tumors and normal lung tissue. Multiparametric imaging with the DBIF model further confirmed the differences in tracer kinetics between normal lung tissue and lung tumors. The effect of dual blood supply in the lungs was demonstrated using HTR dynamic imaging and compartmental modeling with the proposed DBIF model. The effect was small in lung tissue but nonnegligible in lung tumors. HTR dynamic imaging with total-body PET can offer a sensitive tool for investigating lung diseases.
肺部由肺动脉和支气管动脉供应,肺动脉携带来自右心室的脱氧血液,支气管动脉携带来自左心室的含氧血液。然而,这种双重血液供应的影响从未通过 PET 进行过研究,部分原因是传统动态 PET 扫描的时间分辨率有限。具有长轴向视野的 PET 扫描仪的出现,如 uEXPLORER 全身 PET/CT 系统,允许使用高时间分辨率(HTR)进行动态成像。在这项工作中,我们构建了双血输入函数(DBIF)模型,并使用 HTR 动态 PET 成像研究了其对正常肺组织和肺肿瘤的动力学定量的影响。13 名健康受试者和 6 名患有肺肿瘤的癌症受试者接受了 uEXPLORER 进行的 1 小时动态 F-FDG 扫描。数据被重建为早期 1 秒的动态帧。使用具有 3 种不同输入功能的 2 组织室分模型(右心室输入功能、左心室输入功能和提出的 DBIF)分析肺组织和肿瘤的区域时间-活性曲线,所有模型均具有时间延迟和弥散校正。使用校正后的 Akaike 信息准则比较了这些模型的时间-活性曲线拟合质量,并使用 Mann-Whitney 检验比较了区分肺肿瘤和肺组织的效果。进一步生成了基于 DBIF 模型的体素多参数图像,以验证区域动力学分析。双重血液供应的影响在肺肿瘤的高时间分辨率时间-活性曲线中表现明显。根据校正后的 Akaike 信息准则,DBIF 模型比其他 2 种单输入模型的时间-活性曲线拟合效果更好。健康受试者正常肺组织中的左心室输入分数较低,但在肺肿瘤中要高得多(约 0.04 比约 0.3, < 0.0003)。DBIF 模型在肺肿瘤和正常肺组织之间的 F-FDG 净流入率[公式:见文本]和输送率[公式:见文本]的差异方面也表现出更好的稳健性。基于 DBIF 模型的多参数成像进一步证实了正常肺组织和肺肿瘤之间示踪剂动力学的差异。使用 HTR 动态成像和提出的 DBIF 模型的室分建模证明了肺部双重血液供应的影响。在肺组织中影响较小,但在肺肿瘤中不容忽视。全身 PET 的 HTR 动态成像可以提供一种敏感的工具来研究肺部疾病。
