增强微观生理学模型的高通量高内容分析能力:用于自动图像分析微血管形成和细胞侵袭的开源软件。

IF 2.3 4区 医学 Q3 BIOPHYSICS
Cellular and molecular bioengineering Pub Date : 2024-10-10 eCollection Date: 2024-10-01 DOI:10.1007/s12195-024-00821-2
Noah Wiggin, Carson Cook, Mitchell Black, Ines Cadena, Salam Rahal-Arabi, Chandler L Asnes, Yoanna Ivanova, Marian H Hettiaratchi, Laurel E Hind, Kaitlin C Fogg
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引用次数: 0

摘要

目的:本研究的主要目的是开发一款基于 Python 的开源软件,用于使用非聚焦显微镜自动分析微生理学模型中的动态细胞行为。这项研究旨在解决目前在体外内皮管形成和细胞侵袭高通量分析工具方面存在的空白,从而促进药物敏感性的快速评估:我们的方法包括标注 1000 多张癌症和内皮细胞共培养模型的 2 毫米 Z 叠图,并训练机器学习模型来自动计算细胞覆盖面积、癌症侵袭深度和微血管动态。具体来说,细胞覆盖面积是通过聚焦堆叠和高斯混合模型计算得出的,以生成阈值化的 Z 投影。使用 ResNet-50 二元分类模型确定癌症侵袭深度,识别哪些 Z 平面包含侵袭细胞,并测量总侵袭深度。最后,通过 U-Net Xception 式血管预测分割模型评估微血管动态,使用 DisPerSE 算法提取嵌入图,然后通过图分析量化微血管长度和连通性。为了进一步验证我们的软件,我们在三维宫颈和内皮共培养模型上重新分析了涉及化疗药物的高通量药物筛选图像集。最后,我们将该软件应用于来自共培养管腔和微血管片段模型的两个天真图像数据集:结果:与人工计算相比,该软件准确测量了细胞覆盖率、癌症侵袭和微血管长度,得出的药物敏感性 IC50 值置信度达到 95%。此外,该软件还能从另外两个用共聚焦显微镜成像的微观生理模型中计算细胞覆盖率、微血管长度和侵袭深度,突出了该软件的多功能性:我们的免费开源软件为量化使用非共焦点显微镜评估的微生理学模型中的三维细胞行为提供了自动化解决方案,为更广泛的细胞与分子生物工程社区提供了标准共焦点显微镜与专有软件搭配的替代方案。该软件可在我们的 GitHub 存储库中找到:https://github.com/fogg-lab/tissue-model-analysis-tools.Supplementary information:在线版本包含补充材料,可查阅 10.1007/s12195-024-00821-2。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Empowering High-Throughput High-Content Analysis of Microphysiological Models: Open-Source Software for Automated Image Analysis of Microvessel Formation and Cell Invasion.

Purpose: The primary aim of this study was to develop an open-source Python-based software for the automated analysis of dynamic cell behaviors in microphysiological models using non-confocal microscopy. This research seeks to address the existing gap in accessible tools for high-throughput analysis of endothelial tube formation and cell invasion in vitro, facilitating the rapid assessment of drug sensitivity.

Methods: Our approach involved annotating over 1000 2 mm Z-stacks of cancer and endothelial cell co-culture model and training machine learning models to automatically calculate cell coverage, cancer invasion depth, and microvessel dynamics. Specifically, cell coverage area was computed using focus stacking and Gaussian mixture models to generate thresholded Z-projections. Cancer invasion depth was determined using a ResNet-50 binary classification model, identifying which Z-planes contained invaded cells and measuring the total invasion depth. Lastly, microvessel dynamics were assessed through a U-Net Xception-style segmentation model for vessel prediction, the DisPerSE algorithm to extract an embedded graph, then graph analysis to quantify microvessel length and connectivity. To further validate our software, we reanalyzed an image set from a high-throughput drug screen involving a chemotherapy agent on a 3D cervical and endothelial co-culture model. Lastly, we applied this software to two naive image datasets from coculture lumen and microvascular fragment models.

Results: The software accurately measured cell coverage, cancer invasion, and microvessel length, yielding drug sensitivity IC50 values with a 95% confidence level compared to manual calculations. This approach significantly reduced the image processing time from weeks down to h. Furthermore, the software was able to calculate cell coverage, microvessel length, and invasion depth from two additional microphysiological models that were imaged with confocal microscopy, highlighting the versatility of the software.

Conclusions: Our free and open source software offers an automated solution for quantifying 3D cell behavior in microphysiological models assessed using non-confocal microscopy, providing the broader Cellular and Molecular Bioengineering community with an alternative to standard confocal microscopy paired with proprietary software.This software can be found in our GitHub repository: https://github.com/fogg-lab/tissue-model-analysis-tools.

Supplementary information: The online version contains supplementary material available at 10.1007/s12195-024-00821-2.

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来源期刊
CiteScore
5.60
自引率
3.60%
发文量
30
审稿时长
>12 weeks
期刊介绍: The field of cellular and molecular bioengineering seeks to understand, so that we may ultimately control, the mechanical, chemical, and electrical processes of the cell. A key challenge in improving human health is to understand how cellular behavior arises from molecular-level interactions. CMBE, an official journal of the Biomedical Engineering Society, publishes original research and review papers in the following seven general areas: Molecular: DNA-protein/RNA-protein interactions, protein folding and function, protein-protein and receptor-ligand interactions, lipids, polysaccharides, molecular motors, and the biophysics of macromolecules that function as therapeutics or engineered matrices, for example. Cellular: Studies of how cells sense physicochemical events surrounding and within cells, and how cells transduce these events into biological responses. Specific cell processes of interest include cell growth, differentiation, migration, signal transduction, protein secretion and transport, gene expression and regulation, and cell-matrix interactions. Mechanobiology: The mechanical properties of cells and biomolecules, cellular/molecular force generation and adhesion, the response of cells to their mechanical microenvironment, and mechanotransduction in response to various physical forces such as fluid shear stress. Nanomedicine: The engineering of nanoparticles for advanced drug delivery and molecular imaging applications, with particular focus on the interaction of such particles with living cells. Also, the application of nanostructured materials to control the behavior of cells and biomolecules.
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