Emulating Low-Dose PCCT Image Pairs with Independent Noise for Self-Supervised Spectral Image Denoising.

Sen Wang, Yirong Yang, Grant M Stevens, Zhye Yin, Adam S Wang
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Abstract

Photon counting CT (PCCT) acquires spectral measurements and enables generation of material decomposition (MD) images that provide distinct advantages in various clinical situations. However, noise amplification is observed in MD images, and denoising is typically applied. Clean or high-quality references are rare in clinical scans, often making supervised learning (Noise2Clean) impractical. Noise2Noise is a self-supervised counterpart, using noisy images and corresponding noisy references with zero-mean, independent noise. PCCT counts transmitted photons separately, and raw measurements are assumed to follow a Poisson distribution in each energy bin, providing the possibility to create noise-independent pairs. The approach is to use binomial selection to split the counts into two low-dose scans with independent noise. We prove that the reconstructed spectral images inherit the noise independence from counts domain through noise propagation analysis and also validated it in numerical simulation and experimental phantom scans. The method offers the flexibility to split measurements into desired dose levels while ensuring the reconstructed images share identical underlying features, thereby strengthening the model's robustness for input dose levels and capability of preserving fine details. In both numerical simulation and experimental phantom scans, we demonstrated that Noise2Noise with binomial selection outperforms other common self-supervised learning methods based on different presumptive conditions.

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利用独立噪声模拟低剂量 PCCT 图像对,实现自监督光谱图像去噪。
光子计数 CT(PCCT)可获取光谱测量数据并生成物质分解(MD)图像,在各种临床情况下具有明显的优势。然而,MD 图像中会出现噪声放大现象,通常需要进行去噪处理。临床扫描中很少有干净或高质量的参考图像,这往往使得监督学习(Noise2Clean)变得不切实际。Noise2Noise 是一种自我监督的对应方法,使用的是噪声图像和相应的零均值、独立噪声参考。PCCT 对传输的光子进行单独计数,并假定原始测量值在每个能量分区中遵循泊松分布,从而为创建与噪声无关的数据对提供了可能。我们的方法是使用二项式选择,将计数分成两个具有独立噪声的低剂量扫描。我们通过噪声传播分析证明,重建的光谱图像继承了计数域的噪声独立性,并在数值模拟和实验幻影扫描中进行了验证。该方法可灵活地将测量结果分成所需的剂量水平,同时确保重建图像具有相同的基本特征,从而增强了模型对输入剂量水平的鲁棒性和保留精细细节的能力。在数值模拟和实验幻影扫描中,我们都证明了采用二叉选择的 Noise2Noise 优于其他基于不同推定条件的常见自监督学习方法。
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