二维和三维82Rb心肌灌注正电子发射断层显像的比较
Comparison of 2-dimensional and 3-dimensional 82Rb myocardial perfusion PET imaging.
作者信息
Knesaurek Karin, Machac Josef, Krynyckyi Borys R, Almeida Orlandino D
机构信息
Division of Nuclear Medicine, Mount Sinai Medical Center, Box 1141, One Gustave L. Levy Place, New York, NY 10029, USA.
出版信息
J Nucl Med. 2003 Aug;44(8):1350-6.
UNLABELLED
We compared 2-dimensional (2D) and 3-dimensional (3D) (82)Rb PET imaging in 3 different experiments: in a realistic heart-thorax phantom, in a uniformity-resolution phantom, and in 14 healthy volunteers.
METHODS
A nonuniform heart-thorax phantom was filled with 111 MBq of (82)Rb injected into the left ventricular (LV) wall. In the LV wall of the cardiac phantom, 3 inserts-1, 2, and 3 cm in diameter-were placed to simulate infarcts. A standard rest cardiac PET imaging protocol in 2D and 3D modes was used. Following the same protocol, a uniformity-resolution phantom with uniformly distributed activity of 1,998 MBq and 740 MBq of (82)Rb in water was used to obtain 2D PET images and 3D PET images, respectively. All 2D volunteer studies were performed by injecting 2,220 MBq of (82)Rb intravenously. For half the volunteers, 3D studies were performed with a high dose (HD) (2,220 MBq) of (82)Rb; for the remainder of the 3D studies, a low dose (LD) (740 MBq) of (82)Rb was used. In the 2D and LD 3D studies, there was a delay of 2 min and 3 min, respectively, followed by a 6-min acquisition. In the HD 3D volunteer studies, there was a delay of 5 min followed by a 6-min acquisition. Circumferential profiles of the short-axis slices and the contrast of the inserts were used to evaluate the cardiac phantom PET images. The transaxial slices from the uniformity-resolution phantom were evaluated by visual inspection and by measuring uniformity. The human studies were evaluated by measuring the contrast between LV wall and LV cavity, using linear profiles and visual analysis.
RESULTS
In the cardiac phantom study, circumferential profiles for the 2D and 3D images were similar. The contrast values for the 1-, 2-, and 3-cm inserts in the 2D study were 0.19 +/- 0.03, 0.34 +/- 0.05, and 0.61 +/- 0.03, respectively. The respective contrast values in the 3D study were 0.15 +/- 0.02, 0.36 +/- 0.04, and 0.52 +/- 0.05. In the uniformity-resolution phantom study, the coefficients of variation, calculated for a representative uniform slice, were 5.3% and 7.6% for the 2D and 3D studies, respectively. For the 7 volunteers on whom HD 3D was used, the mean 2D contrast was 0.33 +/- 0.08 and the mean HD 3D contrast was 0.35 +/- 0.08 (P = not statistically significant). For the other 7 volunteers, on whom LD 3D was used, the mean 2D contrast was 0.39 +/- 0.06 and the mean LD 3D contrast was 0.39 +/- 0.10 (P = not statistically significant). In the tomographic slices, the 2D and 3D images and polar plots were similar.
CONCLUSION
When obtained with a PET system having a high counting-rate performance, 2D and 3D (82)Rb PET cardiac images are comparable. LD 3D imaging can make (82)Rb PET cardiac imaging more affordable.
未标注
我们在3个不同实验中比较了二维(2D)和三维(3D)(82)Rb正电子发射断层显像(PET)成像:在一个逼真的心脏-胸部模型、一个均匀性-分辨率模型以及14名健康志愿者中。
方法
一个不均匀的心脏-胸部模型通过向左心室(LV)壁注射111 MBq的(82)Rb来填充。在心脏模型的LV壁中,放置了3个直径分别为1、2和3 cm的插入物以模拟梗死灶。使用了标准的静息心脏PET成像方案,分别以2D和3D模式进行。按照相同方案,使用一个在水中具有均匀分布的1998 MBq和740 MBq(82)Rb活度的均匀性-分辨率模型,分别获取2D PET图像和3D PET图像。所有2D志愿者研究通过静脉注射2220 MBq的(82)Rb进行。对于一半的志愿者,3D研究使用高剂量(HD)(2220 MBq)的(82)Rb进行;对于其余的3D研究,使用低剂量(LD)(740 MBq)的(82)Rb。在2D和LD 3D研究中,分别延迟2分钟和3分钟,随后进行6分钟采集。在HD 3D志愿者研究中,延迟5分钟,随后进行6分钟采集。短轴切片的圆周轮廓和插入物的对比度用于评估心脏模型PET图像。通过视觉检查和测量均匀性来评估来自均匀性-分辨率模型的断层切片。人体研究通过使用线性轮廓和视觉分析测量LV壁与LV腔之间的对比度来评估。
结果
在心脏模型研究中,2D和3D图像的圆周轮廓相似。2D研究中1、2和3 cm插入物的对比度值分别为0.19±0.03、0.34±0.05和0.61±0.03。3D研究中相应的对比度值分别为0.15±0.02、0.36±0.04和0.52±0.05。在均匀性-分辨率模型研究中,对于一个代表性均匀切片计算的变异系数,2D和3D研究分别为5.3%和7.6%。对于使用HD 3D的7名志愿者,平均2D对比度为0.33±0.08,平均HD 3D对比度为0.35±0.08(P = 无统计学显著性)。对于使用LD 3D的其他7名志愿者,平均2D对比度为0.39±0.06,平均LD 3D对比度为0.39±0.10(P = 无统计学显著性)。在断层切片中,2D和3D图像以及极坐标图相似。
结论
当使用具有高计数率性能的PET系统获取时,2D和3D(82)Rb PET心脏图像具有可比性。LD 3D成像可使(82)Rb PET心脏成像成本更低。
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