Riegler Georg, Karanikas Georgios, Rausch Ivo, Hirtl Albert, El-Rabadi Karem, Marik Wolfgang, Pivec Christopher, Weber Michael, Prosch Helmut, Mayerhoefer Marius
Medical University of Vienna, Department of Biomedical Imaging and Image-guided Therapy, Währingergürtel 18-20, 1090 Vienna, Austria.
Medical University of Vienna, Department of Biomedical Imaging and Image-guided Therapy, Währingergürtel 18-20, 1090 Vienna, Austria.
Eur J Radiol. 2017 May;90:20-26. doi: 10.1016/j.ejrad.2017.02.023. Epub 2017 Feb 20.
To evaluate the influence of point spread function (PSF)-based reconstruction and matrix size for PET on (1) lung lesion detection and (2) standardized uptake values (SUV).
This prospective study included oncological patients who underwent [18F]-FDG-PET/CT for staging. PET data were reconstructed with a 2D ordered subset expectation maximization (OSEM) algorithm, and a 2D PSF-based algorithm (TrueX), separately with two matrix sizes (168×168 and 336×336). The four PET reconstructions (TrueX-168; OSEM-168; TrueX-336; and OSEM-336) were read independently by two raters, and PET-positive lung lesions were recorded. Blinded to the PET findings, a third independent rater assessed lung lesions with diameters of >4mm on CT. Subsequently, PET and CT were reviewed side-by side in consensus. Multi-factorial logistic regression analyses and two-way repeated measures analyses of variance (ANOVA) were performed.
Thirty-seven patients with 206 lung lesions were included. Lesion-based PET sensitivities differed significantly between reconstruction algorithms (P<0.001) and between reconstruction matrices (P=0.022). Sensitivities were 94.2% and 88.3% for TrueX-336; 88.3% and 85.9% for TrueX-168; 67.8% and 66.3% for OSEM-336; and 67.0% and 67.9% for OSEM-168; for rater 1 and rater 2, respectively. SUV and SUV were significantly higher for images reconstructed with 336×336 matrices than for those reconstructed with 168×168 matrices (P<0.001).
Our results demonstrate that PSF-based PET reconstruction, and, to a lesser degree, higher matrix size, improve detection of metabolically active lung lesions. However, PSF-based PET reconstructions and larger matrix sizes lead to higher SUVs, which may be a concern when PET data from different institutions are compared.
评估基于点扩散函数(PSF)的重建和PET矩阵大小对(1)肺部病变检测和(2)标准化摄取值(SUV)的影响。
这项前瞻性研究纳入了接受[18F]-FDG-PET/CT分期检查的肿瘤患者。PET数据分别采用二维有序子集期望最大化(OSEM)算法和基于二维PSF的算法(TrueX)进行重建,矩阵大小分别为两种(168×168和336×336)。四位PET重建图像(TrueX-168;OSEM-168;TrueX-336;和OSEM-336)由两名评估者独立阅片,并记录PET阳性的肺部病变。在不知PET检查结果的情况下,第三位独立评估者对CT上直径>4mm的肺部病变进行评估。随后,PET和CT进行联合一致性复查。进行多因素逻辑回归分析和双向重复测量方差分析(ANOVA)。
纳入37例患者,共206个肺部病变。基于病变的PET敏感性在重建算法之间(P<0.001)和重建矩阵之间(P=0.022)存在显著差异。对于评估者1和评估者2,TrueX-336的敏感性分别为94.2%和88.3%;TrueX-168的敏感性分别为88.3%和85.9%;OSEM-336的敏感性分别为67.8%和66.3%;OSEM-168的敏感性分别为67.0%和67.9%。采用336×336矩阵重建的图像的SUV和SUVmax显著高于采用168×168矩阵重建的图像(P<0.001)。
我们的结果表明,基于PSF的PET重建,以及在较小程度上更高的矩阵大小,可提高代谢活跃肺部病变的检测率。然而,基于PSF的PET重建和更大的矩阵大小会导致更高的SUV值,在比较不同机构的PET数据时这可能是一个问题。
