利用低层次特征和拓扑自相似性对 ION 进行精确分割

Jiaxing Huang, Yaoru Luo, Yuanhao Guo, Wenjing Li, Zichen Wang, Guole Liu, Ge Yang
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引用次数: 0

摘要

动因:细胞内细胞器网络(IONs),如内质网(ER)网络和线粒体(MITO)网络,具有重要的生理功能。这些网络的形态在介导其功能方面发挥着关键作用。分析这些网络的形态和拓扑结构需要精确的图像分割,以用于分子机制分析和药物靶点筛选等应用。然而,迄今为止,这些网络结构的复杂性和密度阻碍了研究的进展:在这项研究中,我们首先通过优化基线 U-Net 模型,为从荧光显微镜图像中准确分割这些细胞器网络建立了严格的性能基线。然后,我们开发了多分辨率编码器(MRE)和分层融合损失(ℓhf),它们基于两个归纳成分,即低级特征和拓扑自相似性,以帮助模型更好地适应IONs的分割任务。在 MRE 和 ℓhf 的帮助下,U-Net 和 Pyramid Vision Transformer (PVT) 在 ER 网络和 MITO 网络的定制数据集上,以及在另一个生物网络(视网膜血管网络)的公共数据集上,表现都优于 U-Net ++、HR-Net、nnU-Net 和 TransUNet 等竞争的一流模型。此外,将 MRE 和 ℓhf 与 HR-Net 和 TransUNet 等模型集成也提高了它们的分割性能。这些实验结果证实了我们方法的通用能力和潜力。此外,对 ER 网络的准确分割还有助于进行分析,从而对其动态形态和拓扑特性提供新的见解:代码和数据可通过 https://github.com/cbmi-group/MRE.Supplementary 信息公开获取:补充信息可在 Bioinformatics online 上获取。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Accurate segmentation of intracellular organelle networks using low-level features and topological self-similarity.

Motivation: Intracellular organelle networks (IONs) such as the endoplasmic reticulum (ER) network and the mitochondrial (MITO) network serve crucial physiological functions. The morphology of these networks plays a critical role in mediating their functions. Accurate image segmentation is required for analyzing the morphology and topology of these networks for applications such as molecular mechanism analysis and drug target screening. So far, however, progress has been hindered by their structural complexity and density.

Results: In this study, we first establish a rigorous performance baseline for accurate segmentation of these organelle networks from fluorescence microscopy images by optimizing a baseline U-Net model. We then develop the multi-resolution encoder (MRE) and the hierarchical fusion loss (Lhf) based on two inductive components, namely low-level features and topological self-similarity, to assist the model in better adapting to the task of segmenting IONs. Empowered by MRE and Lhf, both U-Net and Pyramid Vision Transformer (PVT) outperform competing state-of-the-art models such as U-Net++, HR-Net, nnU-Net, and TransUNet on custom datasets of the ER network and the MITO network, as well as on public datasets of another biological network, the retinal blood vessel network. In addition, integrating MRE and Lhf with models such as HR-Net and TransUNet also enhances their segmentation performance. These experimental results confirm the generalization capability and potential of our approach. Furthermore, accurate segmentation of the ER network enables analysis that provides novel insights into its dynamic morphological and topological properties.

Availability and implementation: Code and data are openly accessible at https://github.com/cbmi-group/MRE.

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