Noise-aware Dynamic Image Denoising and Positron Range Correction for Rubidium-82 Cardiac PET Imaging via Self-supervision

Huidong Xie, Liang Guo, Alexandre Velo, Zhao Liu, Qiong Liu, Xueqi Guo, Bo Zhou, Xiongchao Chen, Yu-Jung Tsai, Tianshun Miao, Menghua Xia, Yi-Hwa Liu, Ian S. Armstrong, Ge Wang, Richard E. Carson, Albert J. Sinusas, Chi Liu
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Abstract

Rb-82 is a radioactive isotope widely used for cardiac PET imaging. Despite numerous benefits of 82-Rb, there are several factors that limits its image quality and quantitative accuracy. First, the short half-life of 82-Rb results in noisy dynamic frames. Low signal-to-noise ratio would result in inaccurate and biased image quantification. Noisy dynamic frames also lead to highly noisy parametric images. The noise levels also vary substantially in different dynamic frames due to radiotracer decay and short half-life. Existing denoising methods are not applicable for this task due to the lack of paired training inputs/labels and inability to generalize across varying noise levels. Second, 82-Rb emits high-energy positrons. Compared with other tracers such as 18-F, 82-Rb travels a longer distance before annihilation, which negatively affect image spatial resolution. Here, the goal of this study is to propose a self-supervised method for simultaneous (1) noise-aware dynamic image denoising and (2) positron range correction for 82-Rb cardiac PET imaging. Tested on a series of PET scans from a cohort of normal volunteers, the proposed method produced images with superior visual quality. To demonstrate the improvement in image quantification, we compared image-derived input functions (IDIFs) with arterial input functions (AIFs) from continuous arterial blood samples. The IDIF derived from the proposed method led to lower AUC differences, decreasing from 11.09% to 7.58% on average, compared to the original dynamic frames. The proposed method also improved the quantification of myocardium blood flow (MBF), as validated against 15-O-water scans, with mean MBF differences decreased from 0.43 to 0.09, compared to the original dynamic frames. We also conducted a generalizability experiment on 37 patient scans obtained from a different country using a different scanner.
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通过自我监督实现铷-82 心脏正电子发射计算机断层成像的噪声感知动态图像去噪和正电子范围校正
Rb-82 是一种广泛用于心脏 PET 成像的放射性同位素。尽管 82-Rb 有诸多优点,但有几个因素限制了它的成像质量和定量准确性。首先,82-Rb 的半衰期短,导致动态帧噪声大。低信噪比会导致图像量化不准确和有偏差。噪声动态帧还会导致高噪声参数图像。由于放射性示踪剂衰变和半衰期短,不同动态帧中的噪声水平也有很大差异。由于缺乏成对的训练输入/标签,现有的去噪方法无法在不同的噪声水平下通用,因此不适用于这项任务。其次,82-Rb 发射高能正电子。与 18-F 等其他示踪剂相比,82-Rb 在湮灭前的飞行距离更长,这会对图像的空间分辨率产生负面影响。本研究的目的是提出一种自我监督方法,用于同时对 82-Rb 心脏 PET 成像进行(1)噪声感知动态图像去噪和(2)正电子射程校正。通过对一系列正常志愿者的正电子发射计算机断层扫描进行测试,发现该方法生成的图像具有极佳的视觉质量。为了证明图像量化的改进,我们将图像衍生输入函数(IDIF)与连续动脉血样本的动脉输入函数(AIF)进行了比较。与原始动态帧相比,由建议方法得出的 IDIF 降低了 AUC 差异,平均从 11.09% 降至 7.58%。根据 15-O 水扫描的验证,提出的方法还改善了心肌血流(MBF)的量化,与原始动态帧相比,平均 MBF 差值从 0.43 降至 0.09。我们还对使用不同扫描仪从不同国家获得的 37 个病人扫描结果进行了通用性实验。
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