Zhang Qiyang, Zhou Chao, Zhang Xu, Fan Wei, Zheng Hairong, Liang Dong, Hu Zhanli
Research Center for Medical AI, Shenzhen Institute of Advanced Technology, Chinese Academy of Sciences, Shenzhen, 518055, China.
Department of Nuclear Medicine, Sun Yat-sen University Cancer Center, Guangzhou, 510060, China.
EJNMMI Phys. 2024 Dec 18;11(1):103. doi: 10.1186/s40658-024-00706-3.
This study aimed to implement high-end positron emission tomography (PET) equipment to assist conventional PET equipment in improving image quality via a distribution learning-based diffusion model.
A diffusion model was first trained on a dataset of high-quality (HQ) images acquired by a high-end PET device (uEXPLORER scanner), and the quality of the conventional PET images was later improved on the basis of this trained model built on null-space constraints. Data from 180 patients were used in this study. Among them, 137 patients who underwent total-body PET/computed tomography scans via a uEXPLORER scanner at the Sun Yat-sen University Cancer Center were retrospectively enrolled. The datasets of 50 of these patients were used to train the diffusion model. The remaining 87 cases and 43 PET images acquired from The Cancer Imaging Archive were used to quantitatively and qualitatively evaluate the proposed method. The nonlocal means (NLM) method, UNet and a generative adversarial network (GAN) were used as reference methods.
The incorporation of HQ imaging priors derived from high-end devices into the diffusion model through network training can enable the sharing of information between scanners, thereby pushing the limits of conventional scanners and improving their imaging quality. The quantitative results showed that the diffusion model based on null-space constraints produced better and more stable results than those of the methods based on NLM, UNet and the GAN and is well suited for cross-center and cross-device imaging.
A diffusion model based on null-space constraints is a flexible framework that can effectively utilize the prior information provided by high-end scanners to improve the image quality of conventional scanners in cross-center and cross-device scenarios.
本研究旨在应用高端正电子发射断层扫描(PET)设备,通过基于分布学习的扩散模型辅助传统PET设备提高图像质量。
首先在由高端PET设备(uEXPLORER扫描仪)获取的高质量(HQ)图像数据集上训练扩散模型,随后基于该建立在零空间约束上的训练模型来提高传统PET图像的质量。本研究使用了180例患者的数据。其中,回顾性纳入了137例在中山大学肿瘤防治中心通过uEXPLORER扫描仪进行全身PET/计算机断层扫描的患者。这些患者中的50例数据集用于训练扩散模型。其余87例以及从癌症影像存档库获取的43例PET图像用于对所提出的方法进行定量和定性评估。非局部均值(NLM)方法、UNet和生成对抗网络(GAN)用作参考方法。
通过网络训练将源自高端设备的HQ成像先验信息纳入扩散模型,可以实现扫描仪之间的信息共享,从而突破传统扫描仪的极限并提高其成像质量。定量结果表明,基于零空间约束的扩散模型比基于NLM、UNet和GAN的方法产生了更好且更稳定的结果,并且非常适合跨中心和跨设备成像。
基于零空间约束的扩散模型是一个灵活的框架,能够有效利用高端扫描仪提供的先验信息,在跨中心和跨设备场景中提高传统扫描仪的图像质量。
