PIMA-CT:物理模型感知循环仿真与超低剂量CT恢复去噪。

Peng Liu, Linsong Xu, Garrett Fullerton, Yao Xiao, James-Bond Nguyen, Zhongyu Li, Izabella Barreto, Catherine Olguin, Ruogu Fang
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引用次数: 0

摘要

大量的研究建议通过低剂量和噪声的计算机断层扫描(CT)来获得高质量的图像,以减少辐射。然而,这些研究是针对人群水平的数据而设计的,没有考虑CT设备和个体的差异,限制了当前方法的性能,特别是对于超低剂量CT成像。在这里,我们提出了PIMA-CT,一种集成无监督学习框架的物理拟人化幻影模型,使用一种称为循环模拟和去噪(CSD)的新型深度学习技术来解决这些限制。我们首先获得了配对的低剂量和标准剂量CT扫描的幻影,然后开发了两个生成神经网络:噪声模拟器和去噪器。该模拟器从两个独立的图像空间(例如,低剂量幻影模型扫描和标准剂量患者扫描)中提取真实的低剂量噪声和组织特征到统一的特征空间中。同时,去噪器向模拟器反馈产生的噪声的质量。通过这种方式,模拟器和去噪器循环交互,优化网络学习,减轻去噪器,同时去除噪声和恢复组织特征。我们全面评估了我们的方法去除真实低剂量噪声和高斯模拟低剂量噪声。结果表明,CSD在不使用任何标记数据(实际患者的低剂量CT扫描)或模拟低剂量CT扫描的情况下,优于最先进的去噪算法之一。该研究可能为医学成像,特别是超低剂量CT扫描的恢复,引入物理模型提供启示。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

PIMA-CT: Physical Model-Aware Cyclic Simulation and Denoising for Ultra-Low-Dose CT Restoration.

PIMA-CT: Physical Model-Aware Cyclic Simulation and Denoising for Ultra-Low-Dose CT Restoration.

PIMA-CT: Physical Model-Aware Cyclic Simulation and Denoising for Ultra-Low-Dose CT Restoration.

PIMA-CT: Physical Model-Aware Cyclic Simulation and Denoising for Ultra-Low-Dose CT Restoration.

A body of studies has proposed to obtain high-quality images from low-dose and noisy Computed Tomography (CT) scans for radiation reduction. However, these studies are designed for population-level data without considering the variation in CT devices and individuals, limiting the current approaches' performance, especially for ultra-low-dose CT imaging. Here, we proposed PIMA-CT, a physical anthropomorphic phantom model integrating an unsupervised learning framework, using a novel deep learning technique called Cyclic Simulation and Denoising (CSD), to address these limitations. We first acquired paired low-dose and standard-dose CT scans of the phantom and then developed two generative neural networks: noise simulator and denoiser. The simulator extracts real low-dose noise and tissue features from two separate image spaces (e.g., low-dose phantom model scans and standard-dose patient scans) into a unified feature space. Meanwhile, the denoiser provides feedback to the simulator on the quality of the generated noise. In this way, the simulator and denoiser cyclically interact to optimize network learning and ease the denoiser to simultaneously remove noise and restore tissue features. We thoroughly evaluate our method for removing both real low-dose noise and Gaussian simulated low-dose noise. The results show that CSD outperforms one of the state-of-the-art denoising algorithms without using any labeled data (actual patients' low-dose CT scans) nor simulated low-dose CT scans. This study may shed light on incorporating physical models in medical imaging, especially for ultra-low level dose CT scans restoration.

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