用于受控数据增强的主动外观模型诱导的生成对抗性网络。

Jianfei Liu, Christine Shen, Tao Liu, Nancy Aguilera, Johnny Tam
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引用次数: 13

摘要

在基于深度学习的医学图像分析中,数据扩充是扩充训练数据集的重要策略。这是因为大型带注释的医学数据集不仅难以生成且成本高昂,而且由于成像技术的快速进步,它们很快就会过时。图像到图像条件生成对抗性网络(C-GAN)为数据扩充提供了一种潜在的解决方案。然而,用作C-GAN的输入的注释通常仅基于形状信息,这可能在所产生的人工创建的图像中导致不期望的强度分布。在本文中,我们介绍了一种可以测量形状和强度的统计分布的活动细胞外观模型(ACAM),并使用该ACAM模型来指导C-GAN生成更逼真的图像,我们称之为A-GAN。A-GAN为向C-GAN传递各向异性强度信息提供了一种有效的手段。A-GAN结合了一个统计模型(ACAM)来确定如何将变换应用于数据扩充。基于任意变换的传统数据扩充方法可能会导致扩充数据集中不现实的形状变化,而这些变化不能代表真实数据。A-GAN旨在改善这种情况。为了验证使用A-GAN进行数据增强的有效性,我们评估了其在自适应光学视网膜成像中的细胞分析性能,这是一种快速变化的医学成像模式。与C-GAN相比,A-GAN在较少的迭代中实现了稳定性。A-GAN增强辅助下的细胞检测和分割精度高于C-GAN。这些发现证明了A-GAN在医学图像分析中显著改进现有数据增强方法的潜力。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Active Appearance Model Induced Generative Adversarial Network for Controlled Data Augmentation.

Data augmentation is an important strategy for enlarging training datasets in deep learning-based medical image analysis. This is because large, annotated medical datasets are not only difficult and costly to generate, but also quickly become obsolete due to rapid advances in imaging technology. Image-to-image conditional generative adversarial networks (C-GAN) provide a potential solution for data augmentation. However, annotations used as inputs to C-GAN are typically based only on shape information, which can result in undesirable intensity distributions in the resulting artificially-created images. In this paper, we introduce an active cell appearance model (ACAM) that can measure statistical distributions of shape and intensity and use this ACAM model to guide C-GAN to generate more realistic images, which we call A-GAN. A-GAN provides an effective means for conveying anisotropic intensity information to C-GAN. A-GAN incorporates a statistical model (ACAM) to determine how transformations are applied for data augmentation. Traditional approaches for data augmentation that are based on arbitrary transformations might lead to unrealistic shape variations in an augmented dataset that are not representative of real data. A-GAN is designed to ameliorate this. To validate the effectiveness of using A-GAN for data augmentation, we assessed its performance on cell analysis in adaptive optics retinal imaging, which is a rapidly-changing medical imaging modality. Compared to C-GAN, A-GAN achieved stability in fewer iterations. The cell detection and segmentation accuracy when assisted by A-GAN augmentation was higher than that achieved with C-GAN. These findings demonstrate the potential for A-GAN to substantially improve existing data augmentation methods in medical image analysis.

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