用于减少 CT 中金属伪影的去噪扩散概率模型。

Grigorios M. Karageorgos;Jiayong Zhang;Nils Peters;Wenjun Xia;Chuang Niu;Harald Paganetti;Ge Wang;Bruno De Man
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引用次数: 0

摘要

金属物体的存在会破坏 CT 投影测量,导致重建的 CT 图像中出现金属伪影。人工智能有望提供更好的解决方案来估计缺失的正弦曲线数据,以减少金属伪影(MAR),正如之前卷积神经网络(CNN)和生成对抗网络(GAN)所显示的那样。最近,去噪扩散概率模型(DDPM)在图像生成任务中显示出了巨大的潜力,有可能超越 GANs。本研究提出了一种基于 DDPM 的方法,用于对缺失的正弦曲线数据进行内绘,以改善 MAR。所提出的模型是无条件训练的,不受金属物体信息的影响,与有条件训练的方法相比,这有可能增强其对不同类型金属植入物的泛化能力。对所提出技术的性能进行了评估,并与最先进的归一化 MAR(NMAR)方法以及基于 CNN 和基于 GAN 的 MAR 方法进行了比较。与 NMAR(SSIM:p < 10-26;PSNR:p < 10-21)、CNN(SSIM:p < 10-25;PSNR:p < 10-9)和 GAN(SSIM:p < 10-6;PSNR:p < 0.05)方法相比,基于 DDPM 的方法提供了明显更高的 SSIM 和 PSNR。根据临床相关的图像质量指标,在实际引入金属物体和金属伪影的临床 CT 图像上对 DDPM-MAR 技术进行了进一步评估,结果显示其质量优于其他三种模型。总体而言,与非基于人工智能的 NMAR 方法相比,基于人工智能的技术显示出更高的 MAR 性能。所提出的方法有望提高 MAR 的有效性,从而提高 CT 诊断的准确性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
A Denoising Diffusion Probabilistic Model for Metal Artifact Reduction in CT
The presence of metal objects leads to corrupted CT projection measurements, resulting in metal artifacts in the reconstructed CT images. AI promises to offer improved solutions to estimate missing sinogram data for metal artifact reduction (MAR), as previously shown with convolutional neural networks (CNNs) and generative adversarial networks (GANs). Recently, denoising diffusion probabilistic models (DDPM) have shown great promise in image generation tasks, potentially outperforming GANs. In this study, a DDPM-based approach is proposed for inpainting of missing sinogram data for improved MAR. The proposed model is unconditionally trained, free from information on metal objects, which can potentially enhance its generalization capabilities across different types of metal implants compared to conditionally trained approaches. The performance of the proposed technique was evaluated and compared to the state-of-the-art normalized MAR (NMAR) approach as well as to CNN-based and GAN-based MAR approaches. The DDPM-based approach provided significantly higher SSIM and PSNR, as compared to NMAR (SSIM: p $\lt 10^{-{26}}$ ; PSNR: p $\lt 10^{-{21}}$ ), the CNN (SSIM: p $\lt 10^{-{25}}$ ; PSNR: p $\lt 10^{-{9}}$ ) and the GAN (SSIM: p $\lt 10^{-{6}}$ ; PSNR: p <0.05) methods. The DDPM-MAR technique was further evaluated based on clinically relevant image quality metrics on clinical CT images with virtually introduced metal objects and metal artifacts, demonstrating superior quality relative to the other three models. In general, the AI-based techniques showed improved MAR performance compared to the non-AI-based NMAR approach. The proposed methodology shows promise in enhancing the effectiveness of MAR, and therefore improving the diagnostic accuracy of CT.
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