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基于深度学习的体外获得化疗耐药性的口腔癌细胞自动图像分类。

Deep learning-based automatic image classification of oral cancer cells acquiring chemoresistance in vitro.

机构信息

Institute of Statistics, National Yang Ming Chiao Tung University, Hsinchu, Taiwan.

Institute of Biomedical Informatics, National Yang Ming Chiao Tung University, Taipei, Taiwan.

出版信息

PLoS One. 2024 Nov 1;19(11):e0310304. doi: 10.1371/journal.pone.0310304. eCollection 2024.

DOI:10.1371/journal.pone.0310304
PMID:39485749
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11530068/
Abstract

Cell shape reflects the spatial configuration resulting from the equilibrium of cellular and environmental signals and is considered a highly relevant indicator of its function and biological properties. For cancer cells, various physiological and environmental challenges, including chemotherapy, cause a cell state transition, which is accompanied by a continuous morphological alteration that is often extremely difficult to recognize even by direct microscopic inspection. To determine whether deep learning-based image analysis enables the detection of cell shape reflecting a crucial cell state alteration, we used the oral cancer cell line resistant to chemotherapy but having cell morphology nearly indiscernible from its non-resistant parental cells. We then implemented the automatic approach via deep learning methods based on EfficienNet-B3 models, along with over- and down-sampling techniques to determine whether image analysis of the Convolutional Neural Network (CNN) can accomplish three-class classification of non-cancer cells vs. cancer cells with and without chemoresistance. We also examine the capability of CNN-based image analysis to approximate the composition of chemoresistant cancer cells within a population. We show that the classification model achieves at least 98.33% accuracy by the CNN model trained with over- and down-sampling techniques. For heterogeneous populations, the best model can approximate the true proportions of non-chemoresistant and chemoresistant cancer cells with Root Mean Square Error (RMSE) reduced to 0.16 by Ensemble Learning (EL). In conclusion, our study demonstrates the potential of CNN models to identify altered cell shapes that are visually challenging to recognize, thus supporting future applications with this automatic approach to image analysis.

摘要

细胞形状反映了细胞和环境信号平衡所产生的空间构象,被认为是其功能和生物学特性的高度相关指标。对于癌细胞,各种生理和环境挑战,包括化疗,导致细胞状态发生转变,伴随着持续的形态改变,即使直接通过显微镜检查也往往极难识别。为了确定基于深度学习的图像分析是否能够检测反映关键细胞状态改变的细胞形状,我们使用了对化疗有抗性但细胞形态与非抗性亲本细胞几乎无法区分的口腔癌细胞系。然后,我们通过基于 EfficienNet-B3 模型的深度学习方法以及过采样和欠采样技术来实现自动方法,以确定卷积神经网络 (CNN) 的图像分析是否可以对非癌细胞与具有和不具有化疗抗性的癌细胞进行三分类。我们还研究了基于 CNN 的图像分析对近似化疗抗性癌细胞群体组成的能力。我们表明,通过过采样和欠采样技术训练的 CNN 模型,分类模型的准确率至少达到 98.33%。对于异质群体,通过集成学习 (EL),最佳模型可以将非化疗抗性和化疗抗性癌细胞的真实比例近似到 0.16 的均方根误差 (RMSE)。总之,我们的研究表明了 CNN 模型识别难以识别的细胞形状变化的潜力,从而支持未来使用这种自动图像分析方法的应用。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/1751/11530068/8a913ae837cb/pone.0310304.g007.jpg
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