An artificial intelligent platform for live cell identification and the detection of cross-contamination

Ruixin Wang; Dongni Wang; Dekai Kang; Xusen Guo; Chong Guo; Meimei Dongye; Yi Zhu; Chuan Chen; Xiayin Zhang; Erping Long; Xiaohang Wu; Zhenzhen Liu; Duoru Lin; Jinghui Wang; Kai Huang; Haotian Lin

doi:10.21037/atm.2019.07.105

An artificial intelligent platform for live cell identification and the detection of cross-contamination

Ann Transl Med. 2020 Jun;8(11):697. doi: 10.21037/atm.2019.07.105.

Authors

Ruixin Wang¹, Dongni Wang¹, Dekai Kang², Xusen Guo², Chong Guo¹, Meimei Dongye¹, Yi Zhu^{1

3}, Chuan Chen^{1

3}, Xiayin Zhang¹, Erping Long¹, Xiaohang Wu¹, Zhenzhen Liu¹, Duoru Lin¹, Jinghui Wang¹, Kai Huang², Haotian Lin¹

Affiliations

¹ State Key Laboratory of Ophthalmology, Zhongshan Ophthalmic Center, Sun Yat-sen University, Guangzhou, China.
² Key Laboratory of Machine Intelligence and Advanced Computing, Ministry of Education School of Data and Computer Science, Sun Yat-Sen University, Guangzhou, China.
³ Department of Molecular and Cellular Pharmacology, University of Miami Miller School of Medicine, Miami, FL, USA.

Abstract

Background: About 30% of cell lines have been cellular cross-contaminated and misidentification, which can result in invalidated experimental results and unusable therapeutic products. Cell morphology under the microscope was observed routinely, and further DNA sequencing analysis was performed periodically to verify cell line identity, but the sequencing analysis was costly, time-consuming, and labor intensive. The purpose of this study was to construct a novel artificial intelligence (AI) technology for "cell face" recognition, in which can predict DNA-level identification labels only using cell images.

Methods: Seven commonly used cell lines were cultured and co-cultured in pairs (totally 8 categories) to simulated the situation of pure and cross-contaminated cells. The microscopy images were obtained and labeled of cell types by the result of short tandem repeat profiling. About 2 million patch images were used for model training and testing. AlexNet was used to demonstrate the effectiveness of convolutional neural network (CNN) in cell classification. To further improve the feasibility of detecting cross-contamination, the bilinear network for fine-grained identification was constructed. The specificity, sensitivity, and accuracy of the model were tested separately by external validation. Finally, the cell semantic segmentation was conducted by DilatedNet.

Results: The cell texture and density were the influencing factors that can be better recognized by the bilinear convolutional neural network (BCNN) comparing to AlexNet. The BCNN achieved 99.5% accuracy in identifying seven pure cell lines and 86.3% accuracy for detecting cross-contamination (mixing two of the seven cell lines). DilatedNet was applied to the semantic segment for analyzing in single-cell level and achieved an accuracy of 98.2%.

Conclusions: The deep CNN model proposed in this study has the ability to recognize small differences in cell morphology, and achieved high classification accuracy.

Keywords: Cell authentification; biomedical optical imaging; image classification; neural networks.