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GEMA:一种用于微流控装置中哺乳动物细胞生长实时分析的自动分割方法

GEMA-An Automatic Segmentation Method for Real-Time Analysis of Mammalian Cell Growth in Microfluidic Devices.

作者信息

Isa-Jara Ramiro, Pérez-Sosa Camilo, Macote-Yparraguirre Erick, Revollo Natalia, Lerner Betiana, Miriuka Santiago, Delrieux Claudio, Pérez Maximiliano, Mertelsmann Roland

机构信息

CONICET-National Scientific and Technical Research Council, Buenos Aires C1004, Argentina.

Faculty of Informatics and Electronic, ESPOCH-Polytechnic School of Chimborazo, Riobamba 060155, Ecuador.

出版信息

J Imaging. 2022 Oct 14;8(10):281. doi: 10.3390/jimaging8100281.

DOI:10.3390/jimaging8100281
PMID:36286375
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9605644/
Abstract

Nowadays, image analysis has a relevant role in most scientific and research areas. This process is used to extract and understand information from images to obtain a model, knowledge, and rules in the decision process. In the case of biological areas, images are acquired to describe the behavior of a biological agent in time such as cells using a mathematical and computational approach to generate a system with automatic control. In this paper, MCF7 cells are used to model their growth and death when they have been injected with a drug. These mammalian cells allow understanding of behavior, gene expression, and drug resistance to breast cancer. For this, an automatic segmentation method called GEMA is presented to analyze the apoptosis and confluence stages of culture by measuring the increase or decrease of the image area occupied by cells in microfluidic devices. In vitro, the biological experiments can be analyzed through a sequence of images taken at specific intervals of time. To automate the image segmentation, the proposed algorithm is based on a Gabor filter, a coefficient of variation (CV), and linear regression. This allows the processing of images in real time during the evolution of biological experiments. Moreover, GEMA has been compared with another three representative methods such as gold standard (manual segmentation), morphological gradient, and a semi-automatic algorithm using FIJI. The experiments show promising results, due to the proposed algorithm achieving an accuracy above 90% and a lower computation time because it requires on average 1 s to process each image. This makes it suitable for image-based real-time automatization of biological lab-on-a-chip experiments.

摘要

如今,图像分析在大多数科学和研究领域都发挥着重要作用。这个过程用于从图像中提取和理解信息,以便在决策过程中获得模型、知识和规则。在生物领域,通过数学和计算方法获取图像来描述生物主体(如细胞)随时间的行为,从而生成一个具有自动控制功能的系统。在本文中,MCF7细胞被用于模拟注射药物后的生长和死亡情况。这些哺乳动物细胞有助于了解乳腺癌的行为、基因表达和耐药性。为此,提出了一种名为GEMA的自动分割方法,通过测量微流控装置中细胞所占图像面积的增加或减少来分析培养物的凋亡和汇合阶段。在体外,可以通过在特定时间间隔拍摄的一系列图像来分析生物实验。为了实现图像分割的自动化,所提出的算法基于Gabor滤波器、变异系数(CV)和线性回归。这使得在生物实验过程中能够实时处理图像。此外,GEMA还与另外三种代表性方法进行了比较,如金标准(手动分割)、形态学梯度和使用FIJI的半自动算法。实验结果显示出良好的前景,因为所提出的算法准确率超过90%,且计算时间较短,平均处理每张图像只需1秒。这使得它适用于基于图像的生物芯片实验室实验的实时自动化。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/b886/9605644/5b4004cad770/jimaging-08-00281-g013.jpg
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2
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3
Identification of Breast Cancer Subtypes Based on Gene Expression Profiles in Breast Cancer Stroma.
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Clin Breast Cancer. 2022 Aug;22(6):521-537. doi: 10.1016/j.clbc.2022.04.001. Epub 2022 Apr 5.
4
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PLoS One. 2021 Jun 24;16(6):e0253666. doi: 10.1371/journal.pone.0253666. eCollection 2021.
5
DeLTA: Automated cell segmentation, tracking, and lineage reconstruction using deep learning.DELTA:使用深度学习进行自动化细胞分割、跟踪和谱系重建。
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6
Cell segmentation methods for label-free contrast microscopy: review and comprehensive comparison.无标记对比显微镜的细胞分割方法:综述与综合比较。
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7
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8
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9
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10
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