Greedy and Linear Ensembles of Machine Learning Methods Outperform Single Approaches for QSPR Regression Problems

Kew, Will; Mitchell, John B. O.

doi:10.1002/minf.201400122

Cited by 10 publications

(14 citation statements)

References 61 publications

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“…These methods have been previously discussed in a number of publications 10,19,27,106 and are only briefly outlined below. The workflow is outlined in Scheme 1.…”

Section: Qspr Modelsmentioning

confidence: 99%

“…The fitted equation approach has shown good accuracy, but is limited by requirements for additional experimental input, although promising attempts have been made to predict some of these quantities. 20,[27][28][29][30] There are examples in the literature which utilize predicted melting points and logP (octanol water partition coefficient) values for solubility predictions via the general solubility equation. 20,30,31 The first principles calculation methods have generally been less accurate and more time consuming, but can provide more fundamental understanding of the process via physically meaningful decomposition of the predicted solution free energy.…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Are the Sublimation Thermodynamics of Organic Molecules Predictable?

McDonagh

Palmer

Mourik

et al. 2016

J. Chem. Inf. Model.

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We compare a range of computational methods for the prediction of sublimation thermodynamics (enthalpy, entropy and free energy of sublimation). These include a model from theoretical chemistry that utilizes crystal lattice energy minimization (with the DMACRYS program) and QSPR models generated by both machine learning (Random Forest and Support Vector Machines) and regression (Partial Least Squares) methods. Using these methods we investigate the predictability of the enthalpy, entropy and free energy of sublimation, with consideration of whether such a method may be able to improve solubility prediction schemes. Previous work has suggested that the major source of error in solubility prediction schemes involving a thermodynamic cycle via the solid state is in the modeling of the free energy change away from the solid state. Yet contrary to this conclusion other work has found that the inclusion of terms such as the enthalpy of sublimation in QSPR methods 2 does not improve the predictions of solubility. We suggest the use of theoretical chemistry terms, detailed explicitly in the methods section, as descriptors for the prediction of the enthalpy and free energy of sublimation. A dataset of 158 molecules with experimental sublimation thermodynamics values and some CSD refcodes has been collected from the literature and is provided with their original source references.

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“…These methods have been previously discussed in a number of publications 10,19,27,106 and are only briefly outlined below. The workflow is outlined in Scheme 1.…”

Section: Qspr Modelsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Are the Sublimation Thermodynamics of Organic Molecules Predictable?

McDonagh

Palmer

Mourik

et al. 2016

J. Chem. Inf. Model.

Self Cite

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“…Cao et al (2010) found a better RMSE, 0.731 over 45 compounds, with SVM than with two other machine learning methods. Kew et al (2015) observed SVM to get an RMSE of 1.01 in a 10-fold crossvalidation over 262 compounds taken from Hughes et al (2008), and thus to be essentially joint best with RF of 15 methods for solubility prediction. Boobier et al (2017), however, found SVM to be only the eighth best out of 10 methods for a 75-25 training-test split of the DLS-100 dataset (Mitchell et al, 2017) with an RMSE of 1.280 for 25 test compounds.…”

Section: Support Vector Machinementioning

confidence: 95%

“…RF methods have been applied by Hughes et al (2008), Kovdienko et al (2010), McDonagh et al (2014, and also by Boobier et al (2017) who found that it was the joint second best amongst 10 machine learning predictors tested and of similar quality to the second best of a panel of 22 human predictors. Kew et al (2015) observed RF to generate an RMSE of 1.02 in a 10-fold cross-validation using 262 molecules from Hughes et al (2008), and thus to be essentially joint best alongside Support Vector Machine of 15 methods for solubility prediction.…”

Section: Random Forestmentioning

confidence: 98%

3. In Silico methods to predict solubility

McDonagh¹,

Mitchell²,

Palmer³

et al. 2019

Solubility in Pharmaceutical Chemistry

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A solution is a homogenous mixture of solute(s) and solvent(s) in any physical state, solid, liquid or gas, where the solute is the substance dissolved in the solvent. A substance's solubility describes the extent to which the substance can be dissolved in a given solvent, resulting in a solution. Solubility is a thermodynamic property, related to the equilibrium between the solute and solvent. From these general ideas, we can begin to discuss the finer details of solubility and the process of solvation. Solubility Data and Experimental DeterminationsSolubility data, particularly in the pharmaceutical industry, tend to be of two distinct types: equilibrium solubility measurements, also called thermodynamic solubility, and kinetic solubility measurements. In the following paragraphs we provide a short overview of how solubility data can be measured. A more in-depth discussion of this topic is provided in the chapter "The role of solubility to optimize drug substances -a Medicinal Chemistry perspective" of this book. Equilibrium solubilityEquilibrium solubility is the concentration of solute in equilibrium with its saturated solution. These measurements are often made at the later stages of pharmaceutical development, such as during formulation (Narasimham & Barhate, 2011;Saal & Petereit, 2012).The classical method for determining this is the shake flask method (Jouyban & Fakhree, 2012), which involves mixing a sample of a solute with a buffer solution until saturation. The saturated solution is then shaken until equilibrium is achieved and a final solubility determined by the dissolved concentrations. This is often achieved using high-pressure liquid chromatography. This method relies upon long shaking times, as it is difficult to determine when the solution has reached equilibrium.A more modern approach is the CheqSol (chasing equilibrium solubility) method (Stuart &

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“…MultiDK uses all training molecules as support vector molecules for kernel processing similar to support vector machines. We use the Tanimoto kernel which has been used in a wide range of machine learning applications, such as exploiting binary feature information to recognize white images on a black background 76 as well as a kernel for support vector and Gaussian progress regression in molecular property prediction8,55 .In the MultiDK approach, ensemble learning is employed based on multiple combinational descriptors according to the principle of the 'wisdom of the crowds'77 . The set of descriptors in MultiDK includes the Morgan circular fingerprints 53 , MACCS Keys 46 fingerprints and three non-binary molecular properties.…”

mentioning

confidence: 99%

MultiDK: A Multiple Descriptor Multiple Kernel Approach for Molecular Discovery and Its Application to Organic Flow Battery Electrolytes

Kim

Jinich

Aspuru‐Guzik

2017

J. Chem. Inf. Model.

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We propose a multiple descriptor multiple kernel (MultiDK) method for efficient molecular discovery using machine learning. We show that the MultiDK method improves both the speed and accuracy of molecular property prediction. We apply the method to the discovery of electrolyte molecules for aqueous redox flow batteries. Using multiple-type-as opposed to single-type-descriptors, we obtain more relevant features for machine learning. Following the principle of "wisdom of the crowds", the combination of multiple-type descriptors significantly boosts prediction performance. Moreover, by employing multiple kernels-more than one kernel function for a set of the input descriptors-MultiDK exploits nonlinear relations between molecular structure and properties better than a linear regression approach. The multiple kernels consist of a Tanimoto similarity kernel and a linear kernel for a set of binary descriptors and a set of nonbinary descriptors, respectively. Using MultiDK, we achieve an average performance of r = 0.92 with a test set of molecules for solubility prediction. We also extend MultiDK to predict pH-dependent solubility and apply it to a set of quinone molecules with different ionizable functional groups to assess their performance as flow battery electrolytes.

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Greedy and Linear Ensembles of Machine Learning Methods Outperform Single Approaches for QSPR Regression Problems

Cited by 10 publications

References 61 publications

Are the Sublimation Thermodynamics of Organic Molecules Predictable?

Are the Sublimation Thermodynamics of Organic Molecules Predictable?

3. In Silico methods to predict solubility

MultiDK: A Multiple Descriptor Multiple Kernel Approach for Molecular Discovery and Its Application to Organic Flow Battery Electrolytes

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