In silico prediction of aqueous solubility, human plasma protein binding and volume of distribution of compounds from calculated pKa and AlogP98 values

doi:10.1023/b:modi.0000006562.93049.36

. 2003;7(1):69-87.

doi: 10.1023/b:modi.0000006562.93049.36.

In silico prediction of aqueous solubility, human plasma protein binding and volume of distribution of compounds from calculated pKa and AlogP98 values

Mario Lobell¹, Vinothini Sivarajah

Affiliations

PMID: 14768905
DOI: 10.1023/b:modi.0000006562.93049.36

In silico prediction of aqueous solubility, human plasma protein binding and volume of distribution of compounds from calculated pKa and AlogP98 values

Mario Lobell et al. Mol Divers. 2003.

. 2003;7(1):69-87.

doi: 10.1023/b:modi.0000006562.93049.36.

Authors

Mario Lobell¹, Vinothini Sivarajah

Affiliation

¹ OSI Pharmaceuticals, Watlington Road, Oxford OX4 6LT, UK. mario_lobell@yahoo.co.uk

PMID: 14768905
DOI: 10.1023/b:modi.0000006562.93049.36

Abstract

We have investigated whether three important ADME (absorption, distribution, metabolism, excretion) related properties (aqueous solubility, human plasma protein binding, and human volume of distribution at steady-state) can be predicted from chemical structure alone if only the predicted predominant ionisation state and lipophilicity (calculated logP [P = octanol-water partition coefficient]) are considered. A simple, fast method for the in silico prediction of aqueous solubility of predominantly uncharged compounds has been developed, while some potential is shown for the prediction of predominantly charged or zwitterionic compounds. Ten other known in silico prediction methods for aqueous solubility have also been evaluated. It has furthermore been demonstrated that the molecular weight (MW) profile of training sets for the development of aqueous solubility prediction methods can influence their predictive performance with regard to test sets of either matching or diverging profiles. The same property descriptors which have been found most relevant for the prediction of aqueous solubility have also proved useful for the prediction of human plasma protein binding and human volume of distribution at steady-state.

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In silico prediction of aqueous solubility, human plasma protein binding and volume of distribution of compounds from calculated pKa and AlogP98 values

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In silico prediction of aqueous solubility, human plasma protein binding and volume of distribution of compounds from calculated pKa and AlogP98 values

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