Industry-scale Application and Evaluation of Deep Learning for Drug Target Prediction

Noe Sturm; Andreas Mayr; Thanh Le Van; Vladimir Chupakhin; Hugo Ceulemans; Jörg Wegner; Jose-Felipe Golib-Dzib; Nina Jeliazkova; Yves Vandriessche; Stanislav Böhm; Vojtech Cima; Jan Martinovic; Nigel Greene; Tom Vander Aa; Thomas J. Ashby; Sepp Hochreiter; Ola Engkvist; Günter Klambauer; Hongming Chen

Industry-scale Application and Evaluation of Deep Learning for Drug Target Prediction

Noe Sturm, Andreas Mayr, Thanh Le Van, Vladimir Chupakhin, Hugo Ceulemans, Jörg Wegner, Jose-Felipe Golib-Dzib, Nina Jeliazkova, Yves Vandriessche, Stanislav Böhm, Vojtech Cima, Jan Martinovic, Nigel Greene, Tom Vander Aa, Thomas J. Ashby, Sepp Hochreiter, Ola Engkvist, Günter Klambauer, Hongming Chen

Research output: Chapter in Book/Report/Conference proceeding › Conference proceedings › peer-review

Abstract

Artificial intelligence (AI) is undergoing a revolution thanks to the breakthroughs of machine learning algorithms in computer vision, speech recognition, natural language processing and generative modelling. Recent works on publicly available pharmaceutical data showed that AI methods are highly promising for Drug Target prediction. However, the quality of public data might be different than that of industry data due to different labs reporting measurements, different measurement techniques, fewer samples and less diverse and specialized assays. As part of a European funded project, that brought together expertise from pharmaceutical industry, machine learning, and high-performance computing, we investigated how well machine learning models obtained from public data can be transferred to internal pharmaceutical industry data. Our results show that machine learning models trained on public data can indeed maintain their predictive power to a large degree when applied to industry data. Moreover, we observed that deep learning derived machine learning models outperformed comparable models, which were trained by other machine learning algorithms, when applied to internal pharmaceutical company datasets. To our knowledge, this is the first large-scale study evaluating the potential of machine learning and especially deep learning directly at the level of industry-scale settings and moreover investigating the transferability of publicly learned target prediction models towards industrial bioactivity prediction pipelines.

Original language	English
Title of host publication	Neural Information Processing Systems Foundation (NeurIPS 2019), 2019
Number of pages	1
Publication status	Published - 2019

Fields of science

305907 Medical statistics
202017 Embedded systems
202036 Sensor systems
101004 Biomathematics
101014 Numerical mathematics
101015 Operations research
101016 Optimisation
101017 Game theory
101018 Statistics
101019 Stochastics
101024 Probability theory
101026 Time series analysis
101027 Dynamical systems
101028 Mathematical modelling
101029 Mathematical statistics
101031 Approximation theory
102 Computer Sciences
102001 Artificial intelligence
102003 Image processing
102004 Bioinformatics
102013 Human-computer interaction
102018 Artificial neural networks
102019 Machine learning
102032 Computational intelligence
102033 Data mining
305901 Computer-aided diagnosis and therapy
305905 Medical informatics
202035 Robotics
202037 Signal processing
103029 Statistical physics
106005 Bioinformatics
106007 Biostatistics

JKU Focus areas

Digital Transformation

Cite this

Sturm, N., Mayr, A., Le Van, T., Chupakhin, V., Ceulemans, H., Wegner, J., Golib-Dzib, J.-F., Jeliazkova, N., Vandriessche, Y., Böhm, S., Cima, V., Martinovic, J., Greene, N., Vander Aa, T., Ashby, T. J., Hochreiter, S., Engkvist, O., Klambauer, G., & Chen, H. (2019). Industry-scale Application and Evaluation of Deep Learning for Drug Target Prediction. In Neural Information Processing Systems Foundation (NeurIPS 2019), 2019

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title = "Industry-scale Application and Evaluation of Deep Learning for Drug Target Prediction",

abstract = "Artificial intelligence (AI) is undergoing a revolution thanks to the breakthroughs of machine learning algorithms in computer vision, speech recognition, natural language processing and generative modelling. Recent works on publicly available pharmaceutical data showed that AI methods are highly promising for Drug Target prediction. However, the quality of public data might be different than that of industry data due to different labs reporting measurements, different measurement techniques, fewer samples and less diverse and specialized assays. As part of a European funded project, that brought together expertise from pharmaceutical industry, machine learning, and high-performance computing, we investigated how well machine learning models obtained from public data can be transferred to internal pharmaceutical industry data. Our results show that machine learning models trained on public data can indeed maintain their predictive power to a large degree when applied to industry data. Moreover, we observed that deep learning derived machine learning models outperformed comparable models, which were trained by other machine learning algorithms, when applied to internal pharmaceutical company datasets. To our knowledge, this is the first large-scale study evaluating the potential of machine learning and especially deep learning directly at the level of industry-scale settings and moreover investigating the transferability of publicly learned target prediction models towards industrial bioactivity prediction pipelines.",

author = "Noe Sturm and Andreas Mayr and \{Le Van\}, Thanh and Vladimir Chupakhin and Hugo Ceulemans and J{\"o}rg Wegner and Jose-Felipe Golib-Dzib and Nina Jeliazkova and Yves Vandriessche and Stanislav B{\"o}hm and Vojtech Cima and Jan Martinovic and Nigel Greene and \{Vander Aa\}, Tom and Ashby, \{Thomas J.\} and Sepp Hochreiter and Ola Engkvist and G{\"u}nter Klambauer and Hongming Chen",

year = "2019",

language = "English",

booktitle = "Neural Information Processing Systems Foundation (NeurIPS 2019), 2019",

}

Sturm, N, Mayr, A, Le Van, T, Chupakhin, V, Ceulemans, H, Wegner, J, Golib-Dzib, J-F, Jeliazkova, N, Vandriessche, Y, Böhm, S, Cima, V, Martinovic, J, Greene, N, Vander Aa, T, Ashby, TJ, Hochreiter, S, Engkvist, O, Klambauer, G & Chen, H 2019, Industry-scale Application and Evaluation of Deep Learning for Drug Target Prediction. in Neural Information Processing Systems Foundation (NeurIPS 2019), 2019.

TY - GEN

T1 - Industry-scale Application and Evaluation of Deep Learning for Drug Target Prediction

AU - Sturm, Noe

AU - Mayr, Andreas

AU - Le Van, Thanh

AU - Chupakhin, Vladimir

AU - Ceulemans, Hugo

AU - Wegner, Jörg

AU - Golib-Dzib, Jose-Felipe

AU - Jeliazkova, Nina

AU - Vandriessche, Yves

AU - Böhm, Stanislav

AU - Cima, Vojtech

AU - Martinovic, Jan

AU - Greene, Nigel

AU - Vander Aa, Tom

AU - Ashby, Thomas J.

AU - Hochreiter, Sepp

AU - Engkvist, Ola

AU - Klambauer, Günter

AU - Chen, Hongming

PY - 2019

Y1 - 2019

N2 - Artificial intelligence (AI) is undergoing a revolution thanks to the breakthroughs of machine learning algorithms in computer vision, speech recognition, natural language processing and generative modelling. Recent works on publicly available pharmaceutical data showed that AI methods are highly promising for Drug Target prediction. However, the quality of public data might be different than that of industry data due to different labs reporting measurements, different measurement techniques, fewer samples and less diverse and specialized assays. As part of a European funded project, that brought together expertise from pharmaceutical industry, machine learning, and high-performance computing, we investigated how well machine learning models obtained from public data can be transferred to internal pharmaceutical industry data. Our results show that machine learning models trained on public data can indeed maintain their predictive power to a large degree when applied to industry data. Moreover, we observed that deep learning derived machine learning models outperformed comparable models, which were trained by other machine learning algorithms, when applied to internal pharmaceutical company datasets. To our knowledge, this is the first large-scale study evaluating the potential of machine learning and especially deep learning directly at the level of industry-scale settings and moreover investigating the transferability of publicly learned target prediction models towards industrial bioactivity prediction pipelines.

AB - Artificial intelligence (AI) is undergoing a revolution thanks to the breakthroughs of machine learning algorithms in computer vision, speech recognition, natural language processing and generative modelling. Recent works on publicly available pharmaceutical data showed that AI methods are highly promising for Drug Target prediction. However, the quality of public data might be different than that of industry data due to different labs reporting measurements, different measurement techniques, fewer samples and less diverse and specialized assays. As part of a European funded project, that brought together expertise from pharmaceutical industry, machine learning, and high-performance computing, we investigated how well machine learning models obtained from public data can be transferred to internal pharmaceutical industry data. Our results show that machine learning models trained on public data can indeed maintain their predictive power to a large degree when applied to industry data. Moreover, we observed that deep learning derived machine learning models outperformed comparable models, which were trained by other machine learning algorithms, when applied to internal pharmaceutical company datasets. To our knowledge, this is the first large-scale study evaluating the potential of machine learning and especially deep learning directly at the level of industry-scale settings and moreover investigating the transferability of publicly learned target prediction models towards industrial bioactivity prediction pipelines.

M3 - Conference proceedings

BT - Neural Information Processing Systems Foundation (NeurIPS 2019), 2019

ER -