Evaluation of Deep Learning Architectures for Aqueous Solubility Prediction

Panapitiya, Gihan; Girard, M; Hollas, Aaron; Sepulveda, Jonathan; Vijayakumar, M.; Wang, Wei; Saldanha, Emily

doi:10.1021/acsomega.2c00642

Cited by 26 publications

(23 citation statements)

References 71 publications

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“…These potential outliers could be handled well by tree-based algorithms but may affect the performance of DNN greatly. Many studies using other representations of a molecule, such as weave module, 40 SMILES string, 41 and molecular graph 41,42 achieved generally a performance similar to that of Morgan fingerprint or 2D/3D descriptors on the prediction of solubility or other physicochemical properties. These new representations of molecules were not applied in this study.…”

Section: ■ Resultsmentioning

confidence: 99%

Building Machine Learning Small Molecule Melting Points and Solubility Models Using CCDC Melting Points Dataset

Zhu

Polyakov

Bajjuri

et al. 2023

J. Chem. Inf. Model.

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Predicting solubility of small molecules is a very difficult undertaking due to the lack of reliable and consistent experimental solubility data. It is well known that for a molecule in a crystal lattice to be dissolved, it must, first, dissociate from the lattice and then, second, be solvated. The melting point of a compound is proportional to the lattice energy, and the octanol−water partition coefficient (log P) is a measure of the compound's solvation efficiency. The CCDC's melting point dataset of almost one hundred thousand compounds was utilized to create widely applicable machine learning models of small molecule melting points. Using the general solubility equation, the aqueous thermodynamic solubilities of the same compounds can be predicted. The global model could be easily localized by adding additional melting point measurements for a chemical series of interest.

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Section: ■ Resultsmentioning

confidence: 99%

Building Machine Learning Small Molecule Melting Points and Solubility Models Using CCDC Melting Points Dataset

Zhu

Polyakov

Bajjuri

et al. 2023

J. Chem. Inf. Model.

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“…Indeed, a wide-variety of deep learning architectures have been applied to the problem of predicting solubility, including graph-based neural networks, − recurrent neural networks, transformers, , message-passing neural networks, deep belief networks, and others. Unlike other fields, it is not yet clear that deep learning algorithms offer a significant improvement over traditional machine learning approaches for solubility prediction . This may partly be due to a lack of accurate experimental solubility measurements for training, although strategies such as transfer learning , or multitask learning may help in some cases.…”

Section: Introductionmentioning

confidence: 99%

“…Unlike other fields, it is not yet clear that deep learning algorithms offer a significant improvement over traditional machine learning approaches for solubility prediction . This may partly be due to a lack of accurate experimental solubility measurements for training, although strategies such as transfer learning , or multitask learning may help in some cases.…”

Section: Introductionmentioning

confidence: 99%

“…Most recent research has been informed by the rapid advances in artificial intelligence being made in other fields. Indeed, a wide-variety of deep learning architectures have been applied to the problem of predicting solubility, including graph-based neural networks, − recurrent neural networks, transformers, , message-passing neural networks, deep belief networks, and others. Unlike other fields, it is not yet clear that deep learning algorithms offer a significant improvement over traditional machine learning approaches for solubility prediction .…”

Section: Introductionmentioning

confidence: 99%

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Blinded Predictions and Post Hoc Analysis of the Second Solubility Challenge Data: Exploring Training Data and Feature Set Selection for Machine and Deep Learning Models

Conn

Carter

Conn

et al. 2023

J. Chem. Inf. Model.

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Accurate methods to predict solubility from molecular structure are highly sought after in the chemical sciences. To assess the state of the art, the American Chemical Society organized a “Second Solubility Challenge” in 2019, in which competitors were invited to submit blinded predictions of the solubilities of 132 drug-like molecules. In the first part of this article, we describe the development of two models that were submitted to the Blind Challenge in 2019 but which have not previously been reported. These models were based on computationally inexpensive molecular descriptors and traditional machine learning algorithms and were trained on a relatively small data set of 300 molecules. In the second part of the article, to test the hypothesis that predictions would improve with more advanced algorithms and higher volumes of training data, we compare these original predictions with those made after the deadline using deep learning models trained on larger solubility data sets consisting of 2999 and 5697 molecules. The results show that there are several algorithms that are able to obtain near state-of-the-art performance on the solubility challenge data sets, with the best model, a graph convolutional neural network, resulting in an RMSE of 0.86 log units. Critical analysis of the models reveals systematic differences between the performance of models using certain feature sets and training data sets. The results suggest that careful selection of high quality training data from relevant regions of chemical space is critical for prediction accuracy but that other methodological issues remain problematic for machine learning solubility models, such as the difficulty in modeling complex chemical spaces from sparse training data sets.

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“…The “transfer learning” approach has been extensively tested in studies devoted to the prediction of the properties of small molecules. − Various DNN have appeared to be more accurate if they have been pretrained in advance on large amounts of “synthetic” (i.e., theoretically calculated) data, and only then fine-tuned with other more precise computational or experimental data. − For small molecules, these results were obtained using specifically developed quantum-chemical databases comprising up to hundreds of thousands of compounds and their properties (including, for example, the well-known quantum-chemical QM9 database, the Materials Project database, and the Open Quantum Materials Database).…”

Section: Introductionmentioning

confidence: 99%

Machine Learning with Enormous “Synthetic” Data Sets: Predicting Glass Transition Temperature of Polyimides Using Graph Convolutional Neural Networks

et al. 2022

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In the present work, we address the problem of utilizing machine learning (ML) methods to predict the thermal properties of polymers by establishing "structure−property" relationships. Having focused on a particular class of heterocyclic polymers, namely polyimides (PIs), we developed a graph convolutional neural network (GCNN), being one of the most promising tools for working with big data, to predict the PI glass transition temperature T g as an example of the fundamental property of polymers. To train the GCNN, we propose an original methodology based on using a "transfer learning" approach with an enormous "synthetic" data set for pretraining and a small experimental data set for its fine-tuning. The "synthetic" data set contains more than 6 million combinatorically generated repeating units of PIs and theoretical values of their T g values calculated using the well-established Askadskii's quantitative structure−property relationship (QSPR) computational scheme. Additionally, an experimental data set for 214 PIs was also collected from the literature for training, fine-tuning, and validation of the GCNN. Both "synthetic" and experimental data sets are included into a PolyAskInG database (Polymer Askadskii's Intelligent Gateway). By using the PolyAskInG database, we developed GCNN which allows estimation of T g of PI with a mean absolute error (MAE) of about 20 K, which is 1.5 times lower than in the case of Askadskii QSPR analysis (33 K). To prove the efficiency and usability of the proposed GCNN architecture and training methodology for predicting polymer properties, we also employed "transfer learning" to develop alternative GCNN pretrained on proxy-characteristics taken from the popular quantumchemical QM9 database for small compounds and fine-tuned on an experimental T g values data set from PolyAskInG database. The obtained results indicate that pretraining of GCNN on the "synthetic" polymer data set provides MAE which is almost twice as low as that in the case of using the QM9 data set in the pretraining stage (∼41 K). Furthermore, we address the questions associated with the influence of the differences in the size of the experimental and "synthetic" data sets (so-called "reality gap" problem), as well as their chemical composition on the training quality. Our results state the overall priority of using polymer data sets for developing deep neural networks, and GCNN in particular, for efficient prediction of polymer properties. Moreover, our work opens up a challenge for the theoretically supported generation of large "synthetic" data sets of polymer properties for the training of the complex ML models. The proposed methodology is rather versatile and may be generalized for predicting other properties of different polymers and copolymers synthesized through the polycondensation reaction.

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Evaluation of Deep Learning Architectures for Aqueous Solubility Prediction

Cited by 26 publications

References 71 publications

Building Machine Learning Small Molecule Melting Points and Solubility Models Using CCDC Melting Points Dataset

Building Machine Learning Small Molecule Melting Points and Solubility Models Using CCDC Melting Points Dataset

Blinded Predictions and Post Hoc Analysis of the Second Solubility Challenge Data: Exploring Training Data and Feature Set Selection for Machine and Deep Learning Models

Machine Learning with Enormous “Synthetic” Data Sets: Predicting Glass Transition Temperature of Polyimides Using Graph Convolutional Neural Networks

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