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      Deep learning for computational chemistry.

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          Abstract

          The rise and fall of artificial neural networks is well documented in the scientific literature of both computer science and computational chemistry. Yet almost two decades later, we are now seeing a resurgence of interest in deep learning, a machine learning algorithm based on multilayer neural networks. Within the last few years, we have seen the transformative impact of deep learning in many domains, particularly in speech recognition and computer vision, to the extent that the majority of expert practitioners in those field are now regularly eschewing prior established models in favor of deep learning models. In this review, we provide an introductory overview into the theory of deep neural networks and their unique properties that distinguish them from traditional machine learning algorithms used in cheminformatics. By providing an overview of the variety of emerging applications of deep neural networks, we highlight its ubiquity and broad applicability to a wide range of challenges in the field, including quantitative structure activity relationship, virtual screening, protein structure prediction, quantum chemistry, materials design, and property prediction. In reviewing the performance of deep neural networks, we observed a consistent outperformance against non-neural networks state-of-the-art models across disparate research topics, and deep neural network-based models often exceeded the "glass ceiling" expectations of their respective tasks. Coupled with the maturity of GPU-accelerated computing for training deep neural networks and the exponential growth of chemical data on which to train these networks on, we anticipate that deep learning algorithms will be a valuable tool for computational chemistry. © 2017 Wiley Periodicals, Inc.

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          Author and article information

          Journal
          J Comput Chem
          Journal of computational chemistry
          Wiley-Blackwell
          1096-987X
          0192-8651
          Jun 15 2017
          : 38
          : 16
          Affiliations
          [1 ] Advanced Computing, Mathematics, and Data Division, Pacific Northwest National Laboratory, 902 Battelle Blvd, Richland, Washington, 99354.
          Article
          10.1002/jcc.24764
          28272810
          a87379d8-cf1c-4c9a-a041-69eb8f881a4a
          History

          artificial intelligence,cheminformatics,deep learning,machine learning,materials genome,molecular modeling,protein structure prediction,quantitative structure activity relationship,quantum chemistry,toxicology

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