Towards image-based cancer cell lines authentication using deep neural networks

Although short tandem repeat (STR) analysis is available as a reliable method for the determination of the genetic origin of cell lines, the occurrence of misauthenticated cell lines remains an important issue. Reasons include the cost, effort and time associated with STR analysis. Moreover, there a...

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Veröffentlicht in:	Scientific reports 2020-11, Vol.10 (1), p.19857, Article 19857
Hauptverfasser:	Mzurikwao, Deogratias, Khan, Muhammad Usman, Samuel, Oluwarotimi Williams, Cinatl, Jindrich, Wass, Mark, Michaelis, Martin, Marcelli, Gianluca, Ang, Chee Siang
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Schlagworte:	631/114 631/114/1305 Area Under Curve Automation Cancer Cell Line Authentication - methods Cell Line, Tumor Cell Proliferation - drug effects Cell Survival - drug effects Cisplatin Cisplatin - pharmacology Deep Learning Humanities and Social Sciences Humans Image processing Image Processing, Computer-Assisted Models, Theoretical multidisciplinary Neural networks Neural Networks, Computer Oxaliplatin Oxaliplatin - pharmacology Science Science (multidisciplinary) Tumor cell lines
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description	Although short tandem repeat (STR) analysis is available as a reliable method for the determination of the genetic origin of cell lines, the occurrence of misauthenticated cell lines remains an important issue. Reasons include the cost, effort and time associated with STR analysis. Moreover, there are currently no methods for the discrimination between isogenic cell lines (cell lines of the same genetic origin, e.g. different cell lines derived from the same organism, clonal sublines, sublines adapted to grow under certain conditions). Hence, additional complementary, ideally low-cost and low-effort methods are required that enable (1) the monitoring of cell line identity as part of the daily laboratory routine and 2) the authentication of isogenic cell lines. In this research, we automate the process of cell line identification by image-based analysis using deep convolutional neural networks. Two different convolutional neural networks models (MobileNet and InceptionResNet V2) were trained to automatically identify four parental cancer cell line (COLO 704, EFO-21, EFO-27 and UKF-NB-3) and their sublines adapted to the anti-cancer drugs cisplatin (COLO-704 r CDDP 1000 , EFO-21 r CDDP 2000 , EFO-27 r CDDP 2000 ) or oxaliplatin (UKF-NB-3 r OXALI 2000 ), hence resulting in an eight-class problem. Our best performing model, InceptionResNet V2, achieved an average of 0.91 F1-score on tenfold cross validation with an average area under the curve (AUC) of 0.95, for the 8-class problem. Our best model also achieved an average F1-score of 0.94 and 0.96 on the authentication through a classification process of the four parental cell lines and the respective drug-adapted cells, respectively, on a four-class problem separately. These findings provide the basis for further development of the application of deep learning for the automation of cell line authentication into a readily available easy-to-use methodology that enables routine monitoring of the identity of cell lines including isogenic cell lines. It should be noted that, this is just a proof of principal that, images can also be used as a method for authentication of cancer cell lines and not a replacement for the STR method.
doi_str_mv	10.1038/s41598-020-76670-6
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Reasons include the cost, effort and time associated with STR analysis. Moreover, there are currently no methods for the discrimination between isogenic cell lines (cell lines of the same genetic origin, e.g. different cell lines derived from the same organism, clonal sublines, sublines adapted to grow under certain conditions). Hence, additional complementary, ideally low-cost and low-effort methods are required that enable (1) the monitoring of cell line identity as part of the daily laboratory routine and 2) the authentication of isogenic cell lines. In this research, we automate the process of cell line identification by image-based analysis using deep convolutional neural networks. Two different convolutional neural networks models (MobileNet and InceptionResNet V2) were trained to automatically identify four parental cancer cell line (COLO 704, EFO-21, EFO-27 and UKF-NB-3) and their sublines adapted to the anti-cancer drugs cisplatin (COLO-704 r CDDP 1000 , EFO-21 r CDDP 2000 , EFO-27 r CDDP 2000 ) or oxaliplatin (UKF-NB-3 r OXALI 2000 ), hence resulting in an eight-class problem. Our best performing model, InceptionResNet V2, achieved an average of 0.91 F1-score on tenfold cross validation with an average area under the curve (AUC) of 0.95, for the 8-class problem. Our best model also achieved an average F1-score of 0.94 and 0.96 on the authentication through a classification process of the four parental cell lines and the respective drug-adapted cells, respectively, on a four-class problem separately. 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Reasons include the cost, effort and time associated with STR analysis. Moreover, there are currently no methods for the discrimination between isogenic cell lines (cell lines of the same genetic origin, e.g. different cell lines derived from the same organism, clonal sublines, sublines adapted to grow under certain conditions). Hence, additional complementary, ideally low-cost and low-effort methods are required that enable (1) the monitoring of cell line identity as part of the daily laboratory routine and 2) the authentication of isogenic cell lines. In this research, we automate the process of cell line identification by image-based analysis using deep convolutional neural networks. Two different convolutional neural networks models (MobileNet and InceptionResNet V2) were trained to automatically identify four parental cancer cell line (COLO 704, EFO-21, EFO-27 and UKF-NB-3) and their sublines adapted to the anti-cancer drugs cisplatin (COLO-704 r CDDP 1000 , EFO-21 r CDDP 2000 , EFO-27 r CDDP 2000 ) or oxaliplatin (UKF-NB-3 r OXALI 2000 ), hence resulting in an eight-class problem. Our best performing model, InceptionResNet V2, achieved an average of 0.91 F1-score on tenfold cross validation with an average area under the curve (AUC) of 0.95, for the 8-class problem. Our best model also achieved an average F1-score of 0.94 and 0.96 on the authentication through a classification process of the four parental cell lines and the respective drug-adapted cells, respectively, on a four-class problem separately. These findings provide the basis for further development of the application of deep learning for the automation of cell line authentication into a readily available easy-to-use methodology that enables routine monitoring of the identity of cell lines including isogenic cell lines. 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Reasons include the cost, effort and time associated with STR analysis. Moreover, there are currently no methods for the discrimination between isogenic cell lines (cell lines of the same genetic origin, e.g. different cell lines derived from the same organism, clonal sublines, sublines adapted to grow under certain conditions). Hence, additional complementary, ideally low-cost and low-effort methods are required that enable (1) the monitoring of cell line identity as part of the daily laboratory routine and 2) the authentication of isogenic cell lines. In this research, we automate the process of cell line identification by image-based analysis using deep convolutional neural networks. Two different convolutional neural networks models (MobileNet and InceptionResNet V2) were trained to automatically identify four parental cancer cell line (COLO 704, EFO-21, EFO-27 and UKF-NB-3) and their sublines adapted to the anti-cancer drugs cisplatin (COLO-704 r CDDP 1000 , EFO-21 r CDDP 2000 , EFO-27 r CDDP 2000 ) or oxaliplatin (UKF-NB-3 r OXALI 2000 ), hence resulting in an eight-class problem. Our best performing model, InceptionResNet V2, achieved an average of 0.91 F1-score on tenfold cross validation with an average area under the curve (AUC) of 0.95, for the 8-class problem. Our best model also achieved an average F1-score of 0.94 and 0.96 on the authentication through a classification process of the four parental cell lines and the respective drug-adapted cells, respectively, on a four-class problem separately. These findings provide the basis for further development of the application of deep learning for the automation of cell line authentication into a readily available easy-to-use methodology that enables routine monitoring of the identity of cell lines including isogenic cell lines. It should be noted that, this is just a proof of principal that, images can also be used as a method for authentication of cancer cell lines and not a replacement for the STR method.</abstract><cop>London</cop><pub>Nature Publishing Group UK</pub><pmid>33199764</pmid><doi>10.1038/s41598-020-76670-6</doi><oa>free_for_read</oa></addata></record>
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subjects	631/114 631/114/1305 Area Under Curve Automation Cancer Cell Line Authentication - methods Cell Line, Tumor Cell Proliferation - drug effects Cell Survival - drug effects Cisplatin Cisplatin - pharmacology Deep Learning Humanities and Social Sciences Humans Image processing Image Processing, Computer-Assisted Models, Theoretical multidisciplinary Neural networks Neural Networks, Computer Oxaliplatin Oxaliplatin - pharmacology Science Science (multidisciplinary) Tumor cell lines
title	Towards image-based cancer cell lines authentication using deep neural networks
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