Data-driven nucleus subclassification on colon hematoxylin and eosin using style-transferred digital pathology.

IF 1.9 Q3 RADIOLOGY, NUCLEAR MEDICINE & MEDICAL IMAGING
Journal of Medical Imaging Pub Date : 2024-11-01 Epub Date: 2024-11-05 DOI:10.1117/1.JMI.11.6.067501
Lucas W Remedios, Shunxing Bao, Samuel W Remedios, Ho Hin Lee, Leon Y Cai, Thomas Li, Ruining Deng, Nancy R Newlin, Adam M Saunders, Can Cui, Jia Li, Qi Liu, Ken S Lau, Joseph T Roland, Mary K Washington, Lori A Coburn, Keith T Wilson, Yuankai Huo, Bennett A Landman
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引用次数: 0

Abstract

Purpose: Cells are building blocks for human physiology; consequently, understanding the way cells communicate, co-locate, and interrelate is essential to furthering our understanding of how the body functions in both health and disease. Hematoxylin and eosin (H&E) is the standard stain used in histological analysis of tissues in both clinical and research settings. Although H&E is ubiquitous and reveals tissue microanatomy, the classification and mapping of cell subtypes often require the use of specialized stains. The recent CoNIC Challenge focused on artificial intelligence classification of six types of cells on colon H&E but was unable to classify epithelial subtypes (progenitor, enteroendocrine, goblet), lymphocyte subtypes (B, helper T, cytotoxic T), and connective subtypes (fibroblasts). We propose to use inter-modality learning to label previously un-labelable cell types on H&E.

Approach: We took advantage of the cell classification information inherent in multiplexed immunofluorescence (MxIF) histology to create cell-level annotations for 14 subclasses. Then, we performed style transfer on the MxIF to synthesize realistic virtual H&E. We assessed the efficacy of a supervised learning scheme using the virtual H&E and 14 subclass labels. We evaluated our model on virtual H&E and real H&E.

Results: On virtual H&E, we were able to classify helper T cells and epithelial progenitors with positive predictive values of 0.34 ± 0.15 (prevalence 0.03 ± 0.01 ) and 0.47 ± 0.1 (prevalence 0.07 ± 0.02 ), respectively, when using ground truth centroid information. On real H&E, we needed to compute bounded metrics instead of direct metrics because our fine-grained virtual H&E predicted classes had to be matched to the closest available parent classes in the coarser labels from the real H&E dataset. For the real H&E, we could classify bounded metrics for the helper T cells and epithelial progenitors with upper bound positive predictive values of 0.43 ± 0.03 (parent class prevalence 0.21) and 0.94 ± 0.02 (parent class prevalence 0.49) when using ground truth centroid information.

Conclusions: This is the first work to provide cell type classification for helper T and epithelial progenitor nuclei on H&E.

使用样式转移数字病理学对结肠苏木精和伊红进行数据驱动的细胞核亚分类。
目的:细胞是人体生理的基石;因此,要进一步了解人体在健康和疾病时的功能,就必须了解细胞交流、共处和相互关系的方式。血色素和伊红(H&E)是临床和研究机构对组织进行组织学分析时使用的标准染色剂。虽然 H&E 无处不在并能显示组织的微观解剖结构,但细胞亚型的分类和绘图通常需要使用专用染色剂。最近的 CoNIC 挑战赛重点关注结肠 H&E 上六种类型细胞的人工智能分类,但无法对上皮亚型(祖细胞、肠内分泌细胞、鹅口疮细胞)、淋巴细胞亚型(B 细胞、辅助 T 细胞、细胞毒性 T 细胞)和结缔组织亚型(成纤维细胞)进行分类。我们建议使用跨模态学习来标记 H&E 上以前无法标记的细胞类型:我们利用多重免疫荧光(MxIF)组织学中固有的细胞分类信息,为 14 个亚类创建了细胞级注释。然后,我们对 MxIF 进行了样式转移,合成了逼真的虚拟 H&E。我们使用虚拟 H&E 和 14 个子类标签评估了监督学习方案的效果。我们在虚拟 H&E 和真实 H&E 上评估了我们的模型:在虚拟 H&E 上,当使用地面实况中心点信息时,我们能够对辅助性 T 细胞和上皮祖细胞进行分类,阳性预测值分别为 0.34 ± 0.15(流行率为 0.03 ± 0.01)和 0.47 ± 0.1(流行率为 0.07 ± 0.02)。在真实 H&E 数据集上,我们需要计算有界度量而不是直接度量,因为我们的细粒度虚拟 H&E 预测类别必须与真实 H&E 数据集中较粗标签中最接近的可用父类别相匹配。对于真实的 H&E,当使用地面实况中心点信息时,我们可以对辅助性 T 细胞和上皮祖细胞进行有界度量分类,阳性预测值上限分别为 0.43 ± 0.03(父类流行率为 0.21)和 0.94 ± 0.02(父类流行率为 0.49):这是首次在 H&E 上对辅助 T 细胞和上皮祖细胞核进行细胞类型分类。
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来源期刊
Journal of Medical Imaging
Journal of Medical Imaging RADIOLOGY, NUCLEAR MEDICINE & MEDICAL IMAGING-
CiteScore
4.10
自引率
4.20%
发文量
0
期刊介绍: JMI covers fundamental and translational research, as well as applications, focused on medical imaging, which continue to yield physical and biomedical advancements in the early detection, diagnostics, and therapy of disease as well as in the understanding of normal. The scope of JMI includes: Imaging physics, Tomographic reconstruction algorithms (such as those in CT and MRI), Image processing and deep learning, Computer-aided diagnosis and quantitative image analysis, Visualization and modeling, Picture archiving and communications systems (PACS), Image perception and observer performance, Technology assessment, Ultrasonic imaging, Image-guided procedures, Digital pathology, Biomedical applications of biomedical imaging. JMI allows for the peer-reviewed communication and archiving of scientific developments, translational and clinical applications, reviews, and recommendations for the field.
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