低剂量SPECT谱图去噪的泊松扩散概率模型。

IF 3.2 2区医学 Q1 RADIOLOGY, NUCLEAR MEDICINE & MEDICAL IMAGING

Medical physics Pub Date : 2025-03-19 DOI:10.1002/mp.17760

Peng Lai, Ruifan Wu, Woliang Yuan, Haiying Li, Ying Jiang

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引用次数: 0

摘要

背景：低剂量单光子发射计算机断层扫描（SPECT）图在成像过程中由于光子衰减而产生噪声。因此，开发有效的低剂量SPECT图像去噪方法已成为一个重要的研究课题。传统的图像去噪方法难以平衡降噪与保留重要的图像细节，特别是在精确的图像结构至关重要的医疗应用中。目的：提出一种基于泊松噪声的扩散概率模型，称为泊松扩散概率模型（Poisson diffusion probabilistic model， PDPM），用于低剂量SPECT图的去噪。考虑到低剂量SPECT图形成背后的物理原理，PDPM用泊松噪声取代了扩散模型中传统使用的高斯噪声，分别以低剂量和正常剂量SPECT图作为去噪过程的起点和终点。方法：我们提出了PDPM的初步框架，包括两个正向和反向过程。随后，我们对该初步框架进行了两项改进：放弃前向过程，使用基于理想反向过程的方法生成训练数据集，以及在反向过程中引入我们提出的时间预测聚合模块（TPAM）以增强模型的图像去噪性能。结果：在模拟SPECT数据集上进行的实验表明，PDPM有效地提高了正弦图图像的质量。其中，图的峰值信噪比（PSNR）和结构相似度（SSIM）分别从19.3156和0.7531增加到35.3446 （p 0.0001 $p）和0.9791 （p 0.0001 $p）。对于由图重构的图像，PSNR和SSIM分别从25.7511提高到35.1335 （p 0.0001 $p）和0.9286提高到0.9817 （p 0.0001 $p）。实验结果表明，PDPM在低剂量SPECT的去噪任务中优于竞争对手的方法，包括一种传统的去噪算法和四种深度学习方法。在临床SPECT数据集上的实验进一步表明，该方法有效地降低了重构图像感兴趣区域（ROI）的变异系数（COV），通过对SPECT图去噪，提高了重构图像的质量。结论：该方法对低剂量SPECT图像的去噪效果良好。我们提出了PDPM的初步框架，并对其进行了改进，以创建PDPM的最终版本，该版本设计用于低剂量SPECT sinogram去噪任务。我们的PDPM在模拟和临床数据集上都取得了良好的去噪结果。

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Poisson diffusion probabilistic model for low-dose SPECT sinogram denoising

Background

Low-dose single photon emission computed tomography (SPECT) sinograms often suffer from noise due to photon attenuation during the imaging process. As a result, developing effective denoising methods for low-dose SPECT images has become an essential research topic. Traditional image denoising methods struggle to balance noise reduction with the preservation of important image details, especially in medical applications where accurate image structures are critical.

Purpose

This paper proposes a diffusion probabilistic model based on Poisson noise, named the Poisson diffusion probabilistic model (PDPM), for denoising low-dose SPECT sinograms. Considering the physical principles behind the formation of low-dose SPECT sinograms, PDPM replaces the Gaussian noise traditionally used in diffusion models with Poisson noise, utilizing low-dose and normal-dose SPECT sinograms as the starting and ending points of the denoising process, respectively.

Methods

We present a preliminary framework for PDPM that encompasses both the forward and reverse processes. Subsequently, we refine this preliminary framework by implementing two improvements: discarding the forward process and generating the training dataset using a method based on the ideal reverse process, as well as introducing our proposed Temporal Prediction Aggregation Module (TPAM) into the reverse process to enhance the model's image denoising performance.

Results

Experiments conducted on the simulated SPECT dataset demonstrate that PDPM effectively improves the quality of sinogram images. Specifically, the peak signal-to-noise ratio (PSNR) and structural similarity (SSIM) of the sinograms increased from 19.3156 to 35.3446 ( $p < 0.0001$ ) and from 0.7531 to 0.9791 ( $p < 0.0001$ ), respectively. For the reconstructed images from the sinograms, the PSNR and SSIM improved from 25.7511 to 35.1335 ( $p < 0.0001$ ) and from 0.9286 to 0.9817 ( $p < 0.0001$ ), respectively. The experiments show that PDPM outperforms competitive methods in the task of low-dose SPECT sinogram denoising, including one traditional denoising algorithm and four deep learning methods. Experiments on clinical SPECT datasets further indicate that our method effectively reduces the coefficient of variation (COV) in the regions of interest (ROI) of the reconstructed images, enhancing the quality of the reconstructed images by denoising the SPECT sinograms.

Conclusions

The proposed PDPM demonstrates promising performance in the denoising of low-dose SPECT sinograms. We presented a preliminary framework for PDPM and refined it to create the final version of PDPM, which is designed for the task of low-dose SPECT sinogram denoising. Our PDPM achieved favorable denoising results on both simulated and clinical datasets.

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来源期刊

Medical physics 医学-核医学

CiteScore

6.80

自引率

15.80%

发文量

660

审稿时长

1.7 months

期刊介绍： Medical Physics publishes original, high impact physics, imaging science, and engineering research that advances patient diagnosis and therapy through contributions in 1) Basic science developments with high potential for clinical translation 2) Clinical applications of cutting edge engineering and physics innovations 3) Broadly applicable and innovative clinical physics developments Medical Physics is a journal of global scope and reach. By publishing in Medical Physics your research will reach an international, multidisciplinary audience including practicing medical physicists as well as physics- and engineering based translational scientists. We work closely with authors of promising articles to improve their quality.