Multi-task learning for pKa prediction

Skolidis, Grigorios; Hansen, Katja; Sanguinetti, Guido; Rupp, Matthias

doi:10.1007/s10822-012-9582-x

Cited by 7 publications

(5 citation statements)

References 31 publications

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“…To convert a p K a value between two solvents, one needs a single additive shift parameter for each molecular family and pair of solvents. Such families of titratable molecular groups are previously used in the context of empirical prediction of p K a values in aqueous solvent, , and family-specific linear functions serve for interconversion between the estimated p K a values.…”

Section: Introductionmentioning

confidence: 99%

“…Subsequently, the measured and ETM p K a values are used to establish the ECM for the five molecular families. The same operation is performed employing the measured p K a values in DMSO and the p K a values in water obtained with the JPM . Here, the quality of the ECM is evaluated by comparing the ECM p K a values in water with the corresponding ETM and JPM p K a values.…”

Section: Introductionmentioning

confidence: 99%

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Empirical Conversion of pK_a Values between Different Solvents and Interpretation of the Parameters: Application to Water, Acetonitrile, Dimethyl Sulfoxide, and Methanol

2018

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An empirical conversion method (ECM) that transforms p K a values of arbitrary organic compounds from one solvent to the other is introduced. We demonstrate the method’s usefulness and performance on p K a conversions involving water and organic solvents acetonitrile (MeCN), dimethyl sulfoxide (Me 2 SO), and methanol (MeOH). We focus on the p K a conversion from the known reference value in water to the other three organic solvents, although such a conversion can also be performed between any pair of the considered solvents. The ECM works with an additive parameter that is specific to a solvent and a molecular family (essentially characterized by a functional group that is titrated). We formally show that the method can be formulated with a single additive parameter, and that the extra multiplicative parameter used in other works is not required. The values of the additive parameter are determined from known p K a data, and their interpretation is provided on the basis of physicochemical concepts. The data set of known p K a values is augmented with p K a values computed with the recently introduced electrostatic transform method, whose validity is demonstrated. For a validation of our method, we consider p K a conversions for two data sets of titratable compounds. The first data set involves 81 relatively small molecules belonging to 19 different molecular families, with the p K a data available in all four considered solvents. The second data set involves 76 titratable molecules from 5 additional molecular families. These molecules are typically larger, and their experimental p K a values are available only in Me 2 SO and water. The validation tests show that the agreement between the experimental p K a data and the ECM predictions is generally good, with absolute errors often on the order of 0.5 pH units. The presence of a few outliers is rationalized, and observed trends with respect to molecular families are discussed.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Empirical Conversion of pK_a Values between Different Solvents and Interpretation of the Parameters: Application to Water, Acetonitrile, Dimethyl Sulfoxide, and Methanol

2018

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“…A wide variety of methods have been developed for p K a prediction − and they have been comprehensively reviewed. − One of the common approaches is the quantitative structure–property relationship (QSPR). QSPR methods are a class of empirical approaches.…”

Section: Introductionmentioning

confidence: 99%

“…RTorsion was introduced before in the design of a fluorinated fragment library by capturing the local structure environments around F/CF3. 53 It was also applied to predict the 19 F NMR chemical shift by a distance-weighted K-nearest neighbor (KNN) algorithm. 54 In this study, we used RTorsion in QSPR modeling for pK a .…”

Section: Introductionmentioning

confidence: 99%

Prediction of pK_a Using Machine Learning Methods with Rooted Topological Torsion Fingerprints: Application to Aliphatic Amines

Anand

Shirley

et al. 2019

J. Chem. Inf. Model.

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The acid–base dissociation constant, pK a, is a key parameter to define the ionization state of a compound and directly affects its biopharmaceutical profile. In this study, we developed a novel approach for pK a prediction using rooted topological torsion fingerprints in combination with five machine learning (ML) methods: random forest, partial least squares, extreme gradient boosting, lasso regression, and support vector regression. With a large and diverse set of 14 499 experimental pK a values, pK a models were developed for aliphatic amines. The models demonstrated consistently good prediction statistics and were able to generate accurate prospective predictions as validated with an external test set of 726 pK a values (RMSE 0.45, MAE 0.33, and R 2 0.84 by the top model). The factors that may affect prediction accuracy and model applicability were carefully assessed. The results demonstrated that rooted topological torsion fingerprints coupled with ML methods provide a promising approach for developing accurate pK a prediction models.

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“…The collocated transfer approach that we employ was investigated on [5] and is based on the IMC approach of [3] and [4], which as discussed in Section III represents an intermediate level of transfer compared with other methods. Although the IMC model has been found useful in real applications such as estimating the molecular properties of compounds [33], or in other forms of transfer learning such as meta-generalizing [34], it should be made clear that we do not claim, NOR do we believe, that the IMC model is necessarily superior to other transfer learning approaches on every data set; the purpose of this paper was to present a methodology for inference in this important model class, and to illustrate and contrast its working on a number of examples and with a number of methods. Continuing, we presented two possible approaches: in the static geometry case, tasks are assumed to have independent geometric structures, so that transfer of geometry can only happen through the correlations between tasks.…”

Section: Discussionmentioning

confidence: 99%

Semisupervised Multitask Learning With Gaussian Processes

Skolidis¹,

Sanguinetti

2013

IEEE Trans. Neural Netw. Learning Syst.

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We present a probabilistic framework for transferring learning across tasks and between labeled and unlabeled data. The approach is based on Gaussian process (GP) prediction and incorporates both the geometry of the data and the similarity between tasks within a GP covariance, allowing Bayesian prediction in a natural way. We discuss the transfer of learning in a multitask scenario in the two cases where the underlying geometry is assumed to be the same across tasks and where different tasks are assumed to have independent geometric structures. We demonstrate the method on a number of real datasets, indicating that the semisupervised multitask approach can result in very significant improvements in performance when very few labeled training examples are available.

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Multi-task learning for pKa prediction

Cited by 7 publications

References 31 publications

Empirical Conversion of pK_a Values between Different Solvents and Interpretation of the Parameters: Application to Water, Acetonitrile, Dimethyl Sulfoxide, and Methanol

Empirical Conversion of pK_a Values between Different Solvents and Interpretation of the Parameters: Application to Water, Acetonitrile, Dimethyl Sulfoxide, and Methanol

Prediction of pK_a Using Machine Learning Methods with Rooted Topological Torsion Fingerprints: Application to Aliphatic Amines

Semisupervised Multitask Learning With Gaussian Processes

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Multi-task learning for pKa prediction

Cited by 7 publications

References 31 publications

Empirical Conversion of pKa Values between Different Solvents and Interpretation of the Parameters: Application to Water, Acetonitrile, Dimethyl Sulfoxide, and Methanol

Empirical Conversion of pKa Values between Different Solvents and Interpretation of the Parameters: Application to Water, Acetonitrile, Dimethyl Sulfoxide, and Methanol

Prediction of pKa Using Machine Learning Methods with Rooted Topological Torsion Fingerprints: Application to Aliphatic Amines

Semisupervised Multitask Learning With Gaussian Processes

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Product

Resources

About

Empirical Conversion of pK_a Values between Different Solvents and Interpretation of the Parameters: Application to Water, Acetonitrile, Dimethyl Sulfoxide, and Methanol

Empirical Conversion of pK_a Values between Different Solvents and Interpretation of the Parameters: Application to Water, Acetonitrile, Dimethyl Sulfoxide, and Methanol

Prediction of pK_a Using Machine Learning Methods with Rooted Topological Torsion Fingerprints: Application to Aliphatic Amines