Wanyu Bian, Albert Jang, Liping Zhang, Xiaonan Yang, Zachary Stewart, Fang Liu
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引用次数: 0
摘要
本研究介绍了一种基于以原始数据域为条件的扩散模型的新型图像重建技术。我们的方法适用于多线圈磁共振成像和定量磁共振成像(qMRI)重建,利用频率域和参数域内的域条件扩散模型。先验核磁共振物理学被用作扩散模型中的嵌入,加强数据一致性以指导训练和采样过程,在核磁共振重建中描述核磁共振 k 空间编码,并利用核磁共振信号建模进行 qMRI 重建。此外,还在扩散步骤中加入了梯度下降优化,从而加强了特征学习并改善了去噪效果。所提出的方法前景广阔,尤其适用于高加速度系数下的图像重建。值得注意的是,它在各种解剖结构的静态和定量 MRI 重建中保持了极高的重建精度。除了直接应用,该方法还具有潜在的通用能力,使其能够适应各种领域的逆问题。
Diffusion Modeling with Domain-conditioned Prior Guidance for Accelerated MRI and qMRI Reconstruction.
This study introduces a novel image reconstruction technique based on a diffusion model that is conditioned on the native data domain. Our method is applied to multi-coil MRI and quantitative MRI (qMRI) reconstruction, leveraging the domain-conditioned diffusion model within the frequency and parameter domains. The prior MRI physics are used as embeddings in the diffusion model, enforcing data consistency to guide the training and sampling process, characterizing MRI k-space encoding in MRI reconstruction, and leveraging MR signal modeling for qMRI reconstruction. Furthermore, a gradient descent optimization is incorporated into the diffusion steps, enhancing feature learning and improving denoising. The proposed method demonstrates a significant promise, particularly for reconstructing images at high acceleration factors. Notably, it maintains great reconstruction accuracy for static and quantitative MRI reconstruction across diverse anatomical structures. Beyond its immediate applications, this method provides potential generalization capability, making it adaptable to inverse problems across various domains.