Deep learning has shown promising results in medical image analysis, however, the lack of very large annotated datasets confines its full potential. Although transfer learning with ImageNet pre-trained classification models can alleviate the problem, constrained image sizes and model complexities can lead to unnecessary increase in computational cost and decrease in performance. As many common morphological features are usually shared by different classification tasks of an organ, it is greatly beneficial if we can extract such features to improve classification with limited samples. Therefore, inspired by the idea of curriculum learning, we propose a strategy for building medical image classifiers using features from segmentation networks. By using a segmentation network pre-trained on similar data as the classification task, the machine can first learn the simpler shape and structural concepts before tackling the actual classification problem which usually involves more complicated concepts. Using our proposed framework on a 3D three-class brain tumor type classification problem, we achieved 82% accuracy on 191 testing samples with 91 training samples. When applying to a 2D nine-class cardiac semantic level classification problem, we achieved 86% accuracy on 263 testing samples with 108 training samples. Comparisons with ImageNet pre-trained classifiers and classifiers trained from scratch are presented.
翻译:然而,深层次的学习在医学图像分析方面显示出了令人乐观的结果,但是,缺乏大量附加说明的数据集限制了它的全部潜力。虽然通过图像网预先培训的分类模型进行转移学习可以缓解问题,但受限制的图像大小和模型复杂性可能导致计算成本的不必要增加和性能下降。由于许多共同的形态特征通常由器官的不同分类任务共同分担,因此如果我们能够利用有限的样本提取这些特征来改进分类,将大有裨益。因此,在课程学习理念的启发下,我们提出了一个战略,用分层网络的特征来建立医疗图像分类器。通过使用对分类任务类似数据的预先培训,机器可以首先学习更简单的形状和结构概念,然后处理通常涉及更复杂概念的实际分类问题。在3D三层脑肿瘤类型分类问题上使用我们提议的框架,我们用91个培训样本在191个测试样品上实现了82%的精确度。在应用2D级9级心脏精度的精度分类问题时,我们用108个培训样品的263的精确度测试样品实现了86%的精确度。与经过训练的分类师前的分类师和从头部进行了比较。