Deep learning detection of dynamic exocytosis events in fluorescence TIRF microscopy.

IF 3.6 2区生物学 Q1 BIOCHEMICAL RESEARCH METHODS

PLoS Computational Biology Pub Date : 2025-10-14 eCollection Date: 2025-10-01 DOI:10.1371/journal.pcbi.1013556

Hugo Lachuer, Emmanuel Moebel, Anne-Sophie Macé, Arthur Masson, Kristine Schauer, Charles Kervrann

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引用次数: 0

Abstract

Segmentation and detection of biological objects in fluorescence microscopy is of paramount importance in cell imaging. Deep learning approaches have recently shown promise to advance, automatize and accelerate analysis. However, most of the interest has been given to the segmentation of static objects of 2D/3D images whereas the segmentation of dynamic processes obtained from time-lapse acquisitions has been less explored. Here we adapted DeepFinder, a U-Net originally designed for 3D noisy cryo-electron tomography (cryo-ET) data, for the detection of rare dynamic exocytosis events (termed ExoDeepFinder) observed in temporal series of 2D Total Internal Reflection Fluorescence Microscopy (TIRFM) images. ExoDeepFinder achieved good absolute performances with a relatively small training dataset of 12000 events in 60 cells. We rigorously compared deep learning performances with unsupervised conventional methods from the literature. ExoDeepFinder outcompeted the tested methods, but also exhibited a greater plasticity to the experimental conditions when tested under drug treatments and after changes in cell line or imaged reporter. This robustness to unseen experimental conditions did not require re-training demonstrating generalization capability of our deep learning model. ExoDeepFinder, as well as the annotated training datasets, were made transparent and available through an open-source software as well as a Napari plugin and can directly be applied to custom user data. The apparent plasticity and performances of ExoDeepFinder to detect dynamic events open new opportunities for future deep learning guided analysis of dynamic processes in live-cell imaging.

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荧光TIRF显微镜下动态胞吐事件的深度学习检测。

荧光显微镜中生物物体的分割和检测在细胞成像中至关重要。深度学习方法最近显示出推进、自动化和加速分析的前景。然而，大多数的兴趣已经给予了二维/三维图像的静态目标的分割，而从延时采集获得的动态过程的分割已经很少探索。在这里，我们改编了DeepFinder，一个最初为3D噪声冷冻电子断层扫描（cryo-ET）数据设计的U-Net，用于检测在2D全反射荧光显微镜（TIRFM）图像的时间序列中观察到的罕见的动态胞漏事件（称为ExoDeepFinder）。ExoDeepFinder在60个单元中12000个事件的相对较小的训练数据集上取得了良好的绝对性能。我们严格比较了深度学习与文献中无监督的传统方法的性能。ExoDeepFinder优于测试方法，但在药物治疗和细胞系或成像报告细胞变化后测试时，也表现出更大的实验条件可塑性。这种对未知实验条件的鲁棒性不需要重新训练，证明了我们的深度学习模型的泛化能力。ExoDeepFinder以及带注释的训练数据集都是透明的，可以通过开源软件和Napari插件使用，可以直接应用于自定义用户数据。ExoDeepFinder在检测动态事件方面的明显可塑性和性能为未来深度学习指导下的活细胞成像动态过程分析开辟了新的机会。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

PLoS Computational Biology BIOCHEMICAL RESEARCH METHODS-MATHEMATICAL & COMPUTATIONAL BIOLOGY

CiteScore

7.10

自引率

4.70%

发文量

820

审稿时长

2.5 months

期刊介绍： PLOS Computational Biology features works of exceptional significance that further our understanding of living systems at all scales—from molecules and cells, to patient populations and ecosystems—through the application of computational methods. Readers include life and computational scientists, who can take the important findings presented here to the next level of discovery. Research articles must be declared as belonging to a relevant section. More information about the sections can be found in the submission guidelines. Research articles should model aspects of biological systems, demonstrate both methodological and scientific novelty, and provide profound new biological insights. Generally, reliability and significance of biological discovery through computation should be validated and enriched by experimental studies. Inclusion of experimental validation is not required for publication, but should be referenced where possible. Inclusion of experimental validation of a modest biological discovery through computation does not render a manuscript suitable for PLOS Computational Biology. Research articles specifically designated as Methods papers should describe outstanding methods of exceptional importance that have been shown, or have the promise to provide new biological insights. The method must already be widely adopted, or have the promise of wide adoption by a broad community of users. Enhancements to existing published methods will only be considered if those enhancements bring exceptional new capabilities.