呼吸运动导致 CT 衰减校正 PET 图像肿瘤定量和勾画误差：肿瘤大小、位置和呼吸轨迹的影响：使用 4D XCAT 体模的模拟研究。

Respiratory-induced errors in tumor quantification and delineation in CT attenuation-corrected PET images: effects of tumor size, tumor location, and respiratory trace: a simulation study using the 4D XCAT phantom.

机构信息

Faculty of Nuclear Engineering and Physics, Amirkabir University of Technology, Tehran, Iran.

出版信息

Mol Imaging Biol. 2013 Dec;15(6):655-65. doi: 10.1007/s11307-013-0656-5.

DOI:10.1007/s11307-013-0656-5

PMID:23780352

Abstract

PURPOSE

We investigated the magnitude of respiratory-induced errors in tumor maximum standardized uptake value (SUVmax), localization, and volume for different respiratory motion traces and various lesion sizes in different locations of the thorax and abdomen in positron emission tomography (PET) images.

PROCEDURES

Respiratory motion traces were simulated based on the common patient breathing cycle and three diaphragm motions used to drive the 4D XCAT phantom. Lesions with different diameters were simulated in different locations of lungs and liver. The generated PET sinograms were subsequently corrected using computed tomography attenuation correction involving the end exhalation, end inhalation, and average of the respiratory cycle. By considering respiration-averaged computed tomography as a true value, the lesion volume, displacement, and SUVmax were measured and analyzed for different respiratory motions.

RESULTS

Respiration with 35-mm diaphragm motion results in a mean lesion SUVmax error of 24 %, a mean superior inferior displacement of 7.6 mm and a mean lesion volume overestimation of 129 % for a 9-mm lesion in the liver. Respiratory motion results in lesion volume overestimation of 50 % for a 9-mm lower lung lesion near the liver with just 15-mm diaphragm motion. Although there are larger errors in lesion SUVmax and volume for 35-mm motion amplitudes, respiration-averaged computed tomography results in smaller errors than the other two phases, except for the lower lung region.

CONCLUSIONS

The respiratory motion-induced errors in tumor quantification and delineation are highly dependent upon the motion amplitude, tumor location, tumor size, and choice of the attenuation map for PET image attenuation correction.

摘要

目的

我们研究了不同呼吸运动轨迹和不同位置的胸腹部正电子发射断层扫描（PET）图像中不同大小的病变的肿瘤最大标准化摄取值（SUVmax）、定位和体积的呼吸诱导误差的幅度。

过程

根据常见的患者呼吸周期和用于驱动 4D XCAT 体模的三个膈肌运动模拟呼吸运动轨迹。在不同位置的肺部和肝脏模拟了不同直径的病变。随后使用包括呼气末、吸气末和呼吸周期平均值的计算机断层扫描衰减校正校正生成的 PET 正弦图。通过将呼吸平均计算机断层扫描视为真实值，测量和分析了不同呼吸运动的病变体积、位移和 SUVmax。

结果

35-mm 膈肌运动的呼吸导致肝脏中 9-mm 病变的平均病变 SUVmax 误差为 24%，平均上下位移为 7.6mm，病变体积高估 129%。肝脏附近的下肺病变，即使只有 15-mm 的膈肌运动，也会导致病变体积高估 50%。尽管 35-mm 运动幅度的病变 SUVmax 和体积误差较大，但呼吸平均计算机断层扫描的误差小于其他两个阶段，除了下肺区域。

结论

肿瘤定量和勾画的呼吸运动诱导误差高度依赖于运动幅度、肿瘤位置、肿瘤大小以及 PET 图像衰减校正的衰减图选择。

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呼吸运动导致 CT 衰减校正 PET 图像肿瘤定量和勾画误差：肿瘤大小、位置和呼吸轨迹的影响：使用 4D XCAT 体模的模拟研究。

Respiratory-induced errors in tumor quantification and delineation in CT attenuation-corrected PET images: effects of tumor size, tumor location, and respiratory trace: a simulation study using the 4D XCAT phantom.

机构信息

出版信息

PURPOSE

PROCEDURES

RESULTS

CONCLUSIONS

目的

过程

结果

结论

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