Drug discovery with explainable artificial intelligence

Jiménez-Luna, José; Grisoni, Francesca; Schneider, Gisbert

doi:10.1038/s42256-020-00236-4

Cited by 506 publications

(350 citation statements)

References 128 publications

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“…This fact not only increases the interpretability of the model's predictions, which is a crucial topic of DL methods for drug discovery, but also shows that a GCNN model trained end-to-end on molecular graphs is able to learn meaningful structural representations that are related to compounds' biological effects. [46][47][48] To the best of our knowledge, this is the first time a DL model was used to identify important substructures and infer the signaling pathway signature of a target compound without available experimental GEx data. A possible limitation of our approach might be its resolution capabilities in specific use-cases of compounds with similar chemical structure but different MoA.…”

Section: Signaling Pathway Inference For Target Structurementioning

confidence: 99%

DeepSIBA: chemical structure-based inference of biological alterations using deep learning

et al. 2021

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Section: Signaling Pathway Inference For Target Structurementioning

confidence: 99%

DeepSIBA: chemical structure-based inference of biological alterations using deep learning

et al. 2021

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“…Advances in machine learning, especially deep learning, have provided great opportunities in drug discovery [21][22][23][24] . Studies range from the prediction of compound properties, including on-target activity, de novo design of chemical structures to target-specific property spaces, reaction predictions and retro-synthetic analysis, and the prediction of protein-ligand interactions via convolutional neural networks.…”

Section: Introductionmentioning

confidence: 99%

Efficient Exploration of Chemical Space with Docking and Deep-Learning

Yang

Yao²,

Repasky³

et al. 2021

Preprint

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With the advent of make-on-demand commercial libraries, the number of purchasable compounds available for virtual screening and assay has grown explosively in recent years, with several libraries eclipsing one billion compounds. Today’s screening libraries are larger and more diverse, enabling discovery of more potent hit compounds and unlocking new areas of chemical space, represented by new core scaffolds. Applying physics-based in-silico screening methods in an exhaustive manner, where every molecule in the library must be enumerated and evaluated independently, is increasingly cost-prohibitive. Here, we introduce a protocol for machine learning-enhanced molecular docking based on active learning to dramatically increase throughput over traditional docking. We leverage a novel selection protocol that strikes a balance between two objectives: (1) Identifying the best scoring compounds and (2) exploring a large region of chemical space, demonstrating superior performance compared to a purely greedy approach. Together with automated redocking of the top compounds, this method captures nearly all the high scoring scaffolds in the library found by exhaustive docking. This protocol is applied to our recent virtual screening campaigns against the D4 and AMPC targets that produced dozens of highly potent, novel inhibitors, and a blinded test against the MT1 target. Our protocol recovers more than 80% of the experimentally confirmed hits with a 14-fold reduction in compute cost, and more than 90% of the hit scaffolds in the top 5% of model predictions, preserving the diversity of the experimentally confirmed hit compounds.

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“…Modern deep learning approaches frequently use end-to-end modeling and create own internal representation that makes many of commonly used approaches not applicable. This requires specific interpretation approaches developed for these methods [4]. There are multiple post hoc interpretation approaches developed specifically for neural network models, e.g.…”

Section: Introductionmentioning

confidence: 99%

Benchmarks for interpretation of QSAR models

Matveieva

Polishchuk

2021

Preprint

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Interpretation of QSAR models is useful to understand the complex nature of biological or physicochemical processes, guide structural optimization or perform knowledge-based validation of QSAR models. Highly predictive models are usually complex and their interpretation is non-trivial. This is particularly true for modern neural networks. Various approaches to interpretation of these models exist. However, it is difficult to evaluate and compare performance and applicability of these ever-emerging methods. Herein, we developed several benchmark data sets with end-points determined by pre-defined patterns. These data sets are purposed for evaluation of the ability of interpretation approaches to retrieve these patterns. They represent tasks with different complexity levels: from simple atom-based additive properties to pharmacophore hypotheses. We proposed several quantitative metrics of interpretation performance. Applicability of benchmarks and metrics was demonstrated on a set of conventional models and end-to-end graph convolutional neural networks interpreted by the previously suggested universal ML-agnostic approach for structural interpretation. We anticipate these benchmarks to be useful in evaluation of new interpretation approaches and investigation of decision making of complex “black box” models.

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Drug discovery with explainable artificial intelligence

Cited by 506 publications

References 128 publications

DeepSIBA: chemical structure-based inference of biological alterations using deep learning

DeepSIBA: chemical structure-based inference of biological alterations using deep learning

Efficient Exploration of Chemical Space with Docking and Deep-Learning

Benchmarks for interpretation of QSAR models

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