Patient-specific noise power spectrum measurement via generative adversarial networks (Conference Presentation)

Medical Imaging 2019: Physics of Medical Imaging Pub Date : 2019-03-14 DOI:10.1117/12.2513207

Chengzhu Zhang, D. Gomez-Cardona, Yinsheng Li, J. Montoya, Guang-Hong Chen

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引用次数: 1

Abstract

A deep learning Generative Adversarial Networks (GANs) were developed and validated to provide an accurate way of direct NPS estimation from a single patient CT scan. GANs were utilized to map a white noise input to a CT noise realization with correct CT noise correlations specific to a single local uniform ROI. To achieve this, a two-stage strategy was developed. In the pre-training stage, ensembles of 64x64 MBIR noise-only images of a quality assurance phantom were used as training samples to jointly train the generator and discriminator. They were fined-tuned using training samples from a single 101x101 ROI of an abdominal anthropomorphic phantom. Results from GANs and physical scans were compared in terms of its mean frequency and radial averaged NPS. This workflow was extended to a patient case where reference dose and 25% of reference dose CT scans were provided for fine-tuning. GANs generated noise-only image samples that are indistinguishable from physical measurement. The overall mean frequency discrepancy between NPS generated from GANs and those from physically acquired data was 0.2% for anthropomorphic phantom validation. The KL divergence for 1D radial averaged NPS profile of these two NPS acquisitions was 2.2×10^(-3). Statistical test indicates trained GANs generated equivalent NPS to physical scans. In clinical patient-specific NPS studies, it showed a distinction between the reference dose case and 25% of reference dose case. It was demonstrated the GANs characterized the properties of CT noise in terms of its mean frequency and 1D NPS profile shape.

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基于生成对抗网络的患者噪声功率谱测量(会议报告)

开发并验证了深度学习生成对抗网络(gan)，以提供从单个患者CT扫描中直接估计NPS的准确方法。利用gan将白噪声输入映射到具有特定于单个局部均匀ROI的正确CT噪声相关性的CT噪声实现。为实现这一目标，制定了一个分两阶段的战略。在预训练阶段，以质量保证模型的64x64 MBIR纯噪声图像集合作为训练样本，共同训练生成器和鉴别器。使用来自单个101x101 ROI的腹部拟人化幻影的训练样本对它们进行微调。GANs和物理扫描的结果比较了其平均频率和径向平均NPS。该工作流程扩展到一个患者病例，其中提供了参考剂量和25%的参考剂量CT扫描以进行微调。gan生成的图像样本只有噪声，与物理测量结果无法区分。拟人幻像验证中，GANs生成的NPS与物理获取数据生成的NPS之间的总体平均频率差异为0.2%。这两个NPS采集的1D径向平均NPS剖面的KL散度为2.2×10^(-3)。统计测试表明，经过训练的gan产生的NPS与物理扫描相当。在临床患者特异性NPS研究中，它显示了参考剂量病例和25%参考剂量病例之间的区别。结果表明，gan在平均频率和一维NPS曲线形状方面表征了CT噪声的特性。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Medical Imaging 2019: Physics of Medical Imaging

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