An Immunofluorescence-Guided Segmentation Model in Hematoxylin and Eosin Images Is Enabled by Tissue Artifact Correction Using a Cycle-Consistent Generative Adversarial Network

IF 7.1 1区 医学 Q1 PATHOLOGY Modern Pathology Pub Date : 2024-08-13 DOI:10.1016/j.modpat.2024.100591
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Abstract

Despite recent advances, the adoption of computer vision methods into clinical and commercial applications has been hampered by the limited availability of accurate ground truth tissue annotations required to train robust supervised models. Generating such ground truth can be accelerated by annotating tissue molecularly using immunofluorescence (IF) staining and mapping these annotations to a post-IF hematoxylin and eosin (H&E) (terminal H&E) stain. Mapping the annotations between IF and terminal H&E increases both the scale and accuracy by which ground truth could be generated. However, discrepancies between terminal H&E and conventional H&E caused by IF tissue processing have limited this implementation. We sought to overcome this challenge and achieve compatibility between these parallel modalities using synthetic image generation, in which a cycle-consistent generative adversarial network was applied to transfer the appearance of conventional H&E such that it emulates terminal H&E. These synthetic emulations allowed us to train a deep learning model for the segmentation of epithelium in terminal H&E that could be validated against the IF staining of epithelial-based cytokeratins. The combination of this segmentation model with the cycle-consistent generative adversarial network stain transfer model enabled performative epithelium segmentation in conventional H&E images. The approach demonstrates that the training of accurate segmentation models for the breadth of conventional H&E data can be executed free of human expert annotations by leveraging molecular annotation strategies such as IF, so long as the tissue impacts of the molecular annotation protocol are captured by generative models that can be deployed prior to the segmentation process.

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通过 CycleGAN 的组织伪影校正功能,在 H&E 图像中实现了免疫荧光引导的分割模型。
尽管最近取得了一些进展,但计算机视觉方法在临床和商业应用中的采用一直受到阻碍,原因是训练稳健的监督模型所需的准确的基本真实组织注释有限。通过使用免疫荧光染色(IF)对组织进行分子注释,并将这些注释映射到 IF 后的 H&E(终端 H&E),可以加速生成此类基本事实。在免疫荧光染色和终端 H&E 之间映射注释可提高生成基本事实的规模和准确性。然而,中频组织处理造成的终端 H&E 与传统 H&E 之间的差异限制了这种实施。我们试图利用合成图像生成技术来克服这一难题,并实现这些并行模式之间的兼容性。在合成图像生成技术中,我们采用了周期一致性生成对抗网络(CycleGAN)来转换传统 H&E 的外观,使其模拟终端 H&E。通过这些合成仿真,我们可以训练出一个深度学习(DL)模型,用于在终末 H&E 中分割上皮,该模型可通过基于上皮的细胞角蛋白的 IF 染色进行验证。该分割模型与 CycleGAN 染色转移模型相结合,可在传统 H&E 图像中进行上皮分割。该方法证明,只要在分割过程之前通过生成模型捕捉到分子注释协议对组织的影响,就可以利用分子注释策略(如 IF),在没有人类专家注释的情况下,为常规 H&E 数据的广泛性训练精确的分割模型。
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来源期刊
Modern Pathology
Modern Pathology 医学-病理学
CiteScore
14.30
自引率
2.70%
发文量
174
审稿时长
18 days
期刊介绍: Modern Pathology, an international journal under the ownership of The United States & Canadian Academy of Pathology (USCAP), serves as an authoritative platform for publishing top-tier clinical and translational research studies in pathology. Original manuscripts are the primary focus of Modern Pathology, complemented by impactful editorials, reviews, and practice guidelines covering all facets of precision diagnostics in human pathology. The journal's scope includes advancements in molecular diagnostics and genomic classifications of diseases, breakthroughs in immune-oncology, computational science, applied bioinformatics, and digital pathology.
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