Segmentation of cellular ultrastructures on sparsely labeled 3D electron microscopy images using deep learning

IF 2.8 Q2 MATHEMATICAL & COMPUTATIONAL BIOLOGY Frontiers in bioinformatics Pub Date : 2023-12-15 DOI:10.3389/fbinf.2023.1308708
Archana Machireddy, Guillaume Thibault, Kevin G. Loftis, Kevin Stoltz, Cecilia Bueno, Hannah R. Smith, J. Riesterer, Joe W. Gray, Xubo Song
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Abstract

Focused ion beam-scanning electron microscopy (FIB-SEM) images can provide a detailed view of the cellular ultrastructure of tumor cells. A deeper understanding of their organization and interactions can shed light on cancer mechanisms and progression. However, the bottleneck in the analysis is the delineation of the cellular structures to enable quantitative measurements and analysis. We mitigated this limitation using deep learning to segment cells and subcellular ultrastructure in 3D FIB-SEM images of tumor biopsies obtained from patients with metastatic breast and pancreatic cancers. The ultrastructures, such as nuclei, nucleoli, mitochondria, endosomes, and lysosomes, are relatively better defined than their surroundings and can be segmented with high accuracy using a neural network trained with sparse manual labels. Cell segmentation, on the other hand, is much more challenging due to the lack of clear boundaries separating cells in the tissue. We adopted a multi-pronged approach combining detection, boundary propagation, and tracking for cell segmentation. Specifically, a neural network was employed to detect the intracellular space; optical flow was used to propagate cell boundaries across the z-stack from the nearest ground truth image in order to facilitate the separation of individual cells; finally, the filopodium-like protrusions were tracked to the main cells by calculating the intersection over union measure for all regions detected in consecutive images along z-stack and connecting regions with maximum overlap. The proposed cell segmentation methodology resulted in an average Dice score of 0.93. For nuclei, nucleoli, and mitochondria, the segmentation achieved Dice scores of 0.99, 0.98, and 0.86, respectively. The segmentation of FIB-SEM images will enable interpretative rendering and provide quantitative image features to be associated with relevant clinical variables.
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利用深度学习在稀疏标记的三维电子显微镜图像上分割细胞超微结构
聚焦离子束扫描电子显微镜(FIB-SEM)图像可提供肿瘤细胞超微结构的详细视图。深入了解肿瘤细胞的组织结构和相互作用可以揭示癌症的发生机制和发展过程。然而,分析的瓶颈在于细胞结构的划分,以便进行定量测量和分析。我们利用深度学习,在转移性乳腺癌和胰腺癌患者的肿瘤活检组织的三维 FIB-SEM 图像中分割细胞和亚细胞超微结构,从而缓解了这一限制。细胞核、核小叶、线粒体、内体和溶酶体等超微结构的定义相对于其周围环境要好得多,因此可以使用使用稀疏人工标签训练的神经网络进行高精度分割。另一方面,由于组织中的细胞缺乏清晰的分界,细胞分割的难度要大得多。我们采用了一种多管齐下的方法,将检测、边界传播和跟踪结合起来进行细胞分割。具体来说,我们采用了神经网络来检测细胞内空间;利用光流从最近的地面实况图像出发,在z-stack上传播细胞边界,以促进单个细胞的分离;最后,通过计算z-stack上连续图像中检测到的所有区域的交集大于联合度量,并将重叠度最大的区域连接起来,将丝状突起追踪到主细胞。所提出的细胞分割方法的平均 Dice 得分为 0.93。对于细胞核、核小球和线粒体,分割的 Dice 分数分别为 0.99、0.98 和 0.86。对 FIB-SEM 图像进行分割后,就能进行解释性渲染,并提供与相关临床变量相关联的定量图像特征。
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