Institute of Computing Technology, Chinese Academy of Sciences, Beijing, 100190, China; School of Computer Science and Technology, University of Chinese Academy of Sciences, Beijing, 100190, China.
Institute of Computing Technology, Chinese Academy of Sciences, Beijing, 100190, China.
Comput Methods Programs Biomed. 2024 Dec;257:108352. doi: 10.1016/j.cmpb.2024.108352. Epub 2024 Aug 22.
As the global incidence of cancer continues to rise rapidly, the need for swift and precise diagnoses has become increasingly pressing. Pathologists commonly rely on H&E-panCK stain pairs for various aspects of cancer diagnosis, including the detection of occult tumor cells and the evaluation of tumor budding. Nevertheless, conventional chemical staining methods suffer from notable drawbacks, such as time-intensive processes and irreversible staining outcomes. The virtual stain technique, leveraging generative adversarial network (GAN), has emerged as a promising alternative to chemical stains. This approach aims to transform biopsy scans (often H&E) into other stain types. Despite achieving notable progress in recent years, current state-of-the-art virtual staining models confront challenges that hinder their efficacy, particularly in achieving accurate staining outcomes under specific conditions. These limitations have impeded the practical integration of virtual staining into diagnostic practices. To address the goal of producing virtual panCK stains capable of replacing chemical panCK, we propose an innovative multi-model framework. Our approach involves employing a combination of Mask-RCNN (for cell segmentation) and GAN models to extract cytokeratin distribution from chemical H&E images. Additionally, we introduce a tailored dynamic GAN model to convert H&E images into virtual panCK stains, integrating the derived cytokeratin distribution. Our framework is motivated by the fact that the unique pattern of the panCK is derived from cytokeratin distribution. As a proof of concept, we employ our virtual panCK stains to evaluate tumor budding in 45 H&E whole-slide images taken from breast cancer-invaded lymph nodes . Through thorough validation by both pathologists and the QuPath software, our virtual panCK stains demonstrate a remarkable level of accuracy. In stark contrast, the accuracy of state-of-the-art single cycleGAN virtual panCK stains is negligible. To our best knowledge, this is the first instance of a multi-model virtual panCK framework and the utilization of virtual panCK for tumor budding assessment. Our framework excels in generating dependable virtual panCK stains with significantly improved efficiency, thereby considerably reducing turnaround times in diagnosis. Furthermore, its outcomes are easily comprehensible even to pathologists who may not be well-versed in computer technology. We firmly believe that our framework has the potential to advance the field of virtual stain, thereby making significant strides towards improved cancer diagnosis.
随着全球癌症发病率的持续快速上升,快速准确诊断的需求变得越来越迫切。病理学家通常依赖 H&E-panCK 染色对癌症诊断的各个方面进行诊断,包括隐匿性肿瘤细胞的检测和肿瘤芽的评估。然而,传统的化学染色方法存在明显的缺点,例如耗时的过程和不可逆的染色结果。虚拟染色技术,利用生成对抗网络(GAN),已经成为化学染色的一种有前途的替代方法。这种方法旨在将活检扫描(通常是 H&E)转换为其他染色类型。尽管近年来取得了显著进展,但目前最先进的虚拟染色模型面临着一些挑战,这些挑战阻碍了它们的效果,特别是在特定条件下实现准确的染色结果。这些局限性阻碍了虚拟染色在诊断实践中的实际应用。为了实现生成能够替代化学 panCK 的虚拟 panCK 染色的目标,我们提出了一种创新的多模型框架。我们的方法涉及使用 Mask-RCNN(用于细胞分割)和 GAN 模型的组合从化学 H&E 图像中提取细胞角蛋白分布。此外,我们引入了一个定制的动态 GAN 模型,将 H&E 图像转换为虚拟 panCK 染色,同时整合了所得到的细胞角蛋白分布。我们的框架的动机是 panCK 的独特模式是由细胞角蛋白分布衍生而来的。作为概念验证,我们使用虚拟 panCK 染色来评估 45 张来自乳腺癌侵袭性淋巴结的 H&E 全切片图像中的肿瘤芽。通过病理学家和 QuPath 软件的全面验证,我们的虚拟 panCK 染色显示出了很高的准确性。相比之下,最先进的单周期 GAN 虚拟 panCK 染色的准确性可以忽略不计。据我们所知,这是第一个多模型虚拟 panCK 框架和利用虚拟 panCK 进行肿瘤芽评估的实例。我们的框架在生成可靠的虚拟 panCK 染色方面表现出色,显著提高了效率,从而大大缩短了诊断的周转时间。此外,即使对于不太熟悉计算机技术的病理学家来说,其结果也很容易理解。我们坚信,我们的框架有可能推动虚拟染色领域的发展,从而为癌症诊断的改进迈出重要一步。
