Chromosome karyotype analysis is of great clinical importance in the diagnosis and treatment of diseases, especially for genetic diseases. Since manual analysis is highly time and effort consuming, computer-assisted automatic chromosome karyotype analysis based on images is routinely used to improve the efficiency and accuracy of the analysis. Due to the strip shape of the chromosomes, they easily get overlapped with each other when imaged, significantly affecting the accuracy of the analysis afterward. Conventional overlapping chromosome segmentation methods are usually based on manually tagged features, hence, the performance of which is easily affected by the quality, such as resolution and brightness, of the images. To address the problem, in this paper, we present an adversarial multiscale feature learning framework to improve the accuracy and adaptability of overlapping chromosome segmentation. Specifically, we first adopt the nested U-shape network with dense skip connections as the generator to explore the optimal representation of the chromosome images by exploiting multiscale features. Then we use the conditional generative adversarial network (cGAN) to generate images similar to the original ones, the training stability of which is enhanced by applying the least-square GAN objective. Finally, we employ Lovasz-Softmax to help the model converge in a continuous optimization setting. Comparing with the established algorithms, the performance of our framework is proven superior by using public datasets in eight evaluation criteria, showing its great potential in overlapping chromosome segmentation


翻译:在诊断和治疗疾病,特别是遗传疾病方面,染色体的卡约型分析具有极大的临床重要性。由于人工分析耗费大量的时间和精力,基于图像的计算机辅助自动染色体卡约型分析通常被用来提高分析的效率和准确性。由于染色体的条状形状,它们很容易在图像上相互重叠,从而大大影响分析的准确性。常规重叠染色体分离方法通常以人工标记特征为基础,因此,其性能很容易受到图像质量(如分辨率和亮度)的影响。为了解决这个问题,我们在本文件中提出了一个对抗性多尺度特征学习框架,以提高重叠染色体分解的准确性和适应性。具体地说,我们首先采用带有密集跳动连接的嵌套 U 形状网络作为发电机,探索染色体图像的最佳代表性,利用多尺度特征。然后,我们使用有条件的血色谱对调对口网络(cGAN) 来生成与原始图像(如分辨率和亮亮度)相似的图像。为了解决问题,我们提出了一个对抗多尺度的高级特征学习框架,通过不断升级的Gam 标准来提高我们Gam 的稳定性。

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在机器学习中,表征学习或表示学习是允许系统从原始数据中自动发现特征检测或分类所需的表示的一组技术。这取代了手动特征工程,并允许机器学习特征并使用它们执行特定任务。在有监督的表征学习中,使用标记的输入数据来学习特征,包括监督神经网络,多层感知器和(监督)字典学习。在无监督表征学习中,特征是与未标记的输入数据一起学习的,包括字典学习,独立成分分析,自动编码器,矩阵分解和各种形式的聚类。
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