基于深度学习并结合计算机断层扫描先验信息的低计数全身正电子发射断层扫描去噪

Deep learning-based low count whole-body positron emission tomography denoising incorporating computed tomography priors.

作者信息

Peng Zhengyu, Zhang Fanwei, Jiang Han, Liu Guichao, Sun Jingzhang, Du Yu, Lu Zhonglin, Wang Ying, Mok Greta S P

机构信息

Biomedical Imaging Laboratory (BIG), Department of Electrical and Computer Engineering, Faculty of Science and Technology, University of Macau, Macau, China.

Department of Nuclear Medicine, The Fifth Affiliated Hospital of Sun Yat-sen University, Zhuhai, China.

出版信息

Quant Imaging Med Surg. 2024 Dec 5;14(12):8140-8154. doi: 10.21037/qims-24-489. Epub 2024 Nov 21.

DOI:10.21037/qims-24-489

PMID:39698633

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11652058/

Abstract

BACKGROUND

Deep-learning-based denoising improves image quality and quantification accuracy for low count (LC) positron emission tomography (PET). Conventional deep-learning-based denoising methods only require single LC PET image input. This study aims to propose a deep-learning-based LC PET denoising method incorporating computed tomography (CT) priors to further reduce the dose level.

METHODS

Fifty patients who underwent their routine whole-body 2-deoxy-2-[F]fluoro-D-glucose (F-FDG) PET/CT scans in March 2022 were retrospectively and non-consecutively recruited. For full count (FC) PET, patients were injected with 3.7 MBq/kg FDG and scanned for 5 bed positions with 2 min/bed. LC PET of 1/10 (LC-10) and 1/20 (LC-20) count levels of FC PET were obtained by randomly down-sampling the FC list mode data, which were then paired with FC PET for training U-Net (U-Net-1) and cGAN (cGAN-1). Networks incorporated CT images as input (U-Net-2 and cGAN-2) were also implemented. Quantitative analysis of physical and clinical indices was performed and statistically assessed with Wilcoxon sign-rank test with Bonferroni correction.

RESULTS

Mean square error and structural similarity index were the best for cGAN-2, followed by U-Net-2, cGAN-1 and U-Net-1. The errors of mean standardized uptake value (SUV) and maximum SUV were lowest for cGAN-2, followed by cGAN-1, U-Net-2 and U-Net-1. For cGAN-2, image quality and lesion detectability scores were 3.71±0.94 and 4.25±0.83 for LC-10, 3.57±0.79 and 3.61±1.21 for LC-20, while they were 3.49±0.92 and 4.42±0.08 for FC. Notably, some small lesions were "masked out" on cGAN/U-Net-1 but can be retrieved on cGAN/U-Net-2 denoised PET for LC-20.

CONCLUSIONS

Deep-learning-based LC PET denoising incorporating CT priors is more effective than conventional deep-learning-based denoising with single LC PET input, especially at lower dose levels.

摘要

背景

基于深度学习的去噪可提高低计数（LC）正电子发射断层扫描（PET）的图像质量和定量准确性。传统的基于深度学习的去噪方法仅需要单个LC PET图像输入。本研究旨在提出一种结合计算机断层扫描（CT）先验的基于深度学习的LC PET去噪方法，以进一步降低剂量水平。

方法

回顾性非连续招募了50例于2022年3月接受常规全身2-脱氧-2-[F]氟-D-葡萄糖（F-FDG）PET/CT扫描的患者。对于全计数（FC）PET，患者注射3.7 MBq/kg FDG，并以2分钟/床位扫描5个床位位置。通过对FC列表模式数据进行随机下采样获得FC PET的1/10（LC-10）和1/20（LC-20）计数水平的LC PET，然后将其与FC PET配对以训练U-Net（U-Net-1）和cGAN（cGAN-1）。还实现了将CT图像作为输入的网络（U-Net-2和cGAN-2）。进行了物理和临床指标的定量分析，并采用带Bonferroni校正的Wilcoxon符号秩检验进行统计评估。

结果

cGAN-2的均方误差和结构相似性指数最佳，其次是U-Net-2、cGAN-1和U-Net-1。cGAN-2的平均标准化摄取值（SUV）和最大SUV误差最低，其次是cGAN-1、U-Net-2和U-Net-1。对于cGAN-2，LC-10的图像质量和病变可检测性评分分别为3.71±0.94和4.25±0.83，LC-20的分别为3.57±0.79和3.61±1.21，而FC的分别为3.49±0.92和4.42±0.08。值得注意的是，一些小病变在cGAN/U-Net-1上被“掩盖”，但在cGAN/U-Net-2去噪后的LC-20 PET上可以找回。

结论

结合CT先验的基于深度学习的LC PET去噪比传统的基于单个LC PET输入的深度学习去噪更有效，尤其是在较低剂量水平下。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/cd65/11652058/014a9cf8a6be/qims-14-12-8140-f1.jpg

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基于深度学习并结合计算机断层扫描先验信息的低计数全身正电子发射断层扫描去噪

Deep learning-based low count whole-body positron emission tomography denoising incorporating computed tomography priors.

作者信息

机构信息

出版信息

BACKGROUND

METHODS

RESULTS

CONCLUSIONS

背景

方法

结果

结论

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