Abstract: A method for computing free energy difference between a reference molecule and a target molecule. The target molecule has the common set of atoms PAB and a set of atoms PB. The method includes applying a potential to restrain an interaction of the additional atomic component from the set of atoms PB with the common set of atoms PAB in the initial state. The method includes determining one or more transition states along a transformation path between the initial state and target state. The method includes scaling the restrain potential correspondingly along the transformation path until the potential becomes zero when a corresponding end state is reached, and calculating the free energy difference between the reference molecule and the target molecule using a value obtained along the transformation path from the initial state to the target state.

Abstract: Structure-based drug design using a computer, includes: identifying a protein target of pharmacological interest; identifying at least three different ligands for binding to the protein; for each of the ligands, determining a relative strength of binding between the ligand and the protein to form a corresponding complex; ranking the different ligands identified as forming complexes with the protein based on the determined relative binding free energies; and identifying one or more of the ranked ligands as candidates for the drug based on the ranking.

Abstract: A system, device, and method for predicting an active set of compounds that bind to a biomolecular target is disclosed. The system and device contain modules allowing for the prediction of an active set of compounds. A core identification module can identify the core of an initial lead compound. A core hopping module is used to identify potential lead compounds having different cores compared to the core of an initial lead compound. A scoring module can use computational techniques to calculate the relative binding free energy of each identified potential lead compound. An activity prediction module can use the relative binding free energy calculations to predict an active set of compounds that bind to the biomolecular target. Empirical analysis can be used to inform the accuracy and completeness of the predicted active set of compounds.

Abstract: A system, device, and method for predicting an active set of compounds that bind to a biomolecular target is disclosed. The system and device contain modules allowing for the prediction of an active set of compounds. A core identification module can identify the core of an initial lead compound. A core hopping module is used to identify potential lead compounds having different cores compared to the core of an initial lead compound. A scoring module can use computational techniques to calculate the relative binding free energy of each identified potential lead compound. An activity prediction module can use the relative binding free energy calculations to predict an active set of compounds that bind to the biomolecular target. Empirical analysis can be used to inform the accuracy and completeness of the predicted active set of compounds.

Abstract: A system, device, and method for predicting an active set of compounds that bind to a biomolecular target is disclosed. The system and device contain modules allowing for the prediction of an active set of compounds. A core identification module can identify the core of an initial lead compound. A core hopping module is used to identify potential lead compounds having different cores compared to the core of an initial lead compound. A scoring module can use computational techniques to calculate the relative binding free energy of each identified potential lead compound. An activity prediction module can use the relative binding free energy calculations to predict an active set of compounds that bind to the biomolecular target. Empirical analysis can be used to inform the accuracy and completeness of the predicted active set of compounds.

Abstract: A method for computing free energy difference between a reference molecule and a target molecule. The target molecule has the common set of atoms PAB and a set of atoms PB. The method includes applying a potential to restrain an interaction of the additional atomic component from the set of atoms PB with the common set of atoms PAB in the initial state. The method includes determining one or more transition states along a transformation path between the initial state and target state. The method includes scaling the restrain potential correspondingly along the transformation path until the potential becomes zero when a corresponding end state is reached, and calculating the free energy difference between the reference molecule and the target molecule using a value obtained along the transformation path from the initial state to the target state.

Abstract: Methods of calculating a free energy of solubility for a compound in a solvent by computer operations include the following steps: (i) establishing, using a computer model, an initial state for a system including an aggregate of multiple molecules of the compound in a solvent; (ii) establishing, using the computer model, a final state of the system including a single molecule from the aggregate fully solvated in the solvent and separate from a transformed aggregate; (iii) transforming, using the computer model, the system from the initial state to the final state, via removing a first molecule of the compound from the aggregate to form the transformed aggregate and replacing the first molecule with solvent at the site of the first molecule; and (iv) calculating the free energy of the transformation between the initial and the final states, which determines the free energy of solubility for the compound.

Abstract: A method for computing free energy difference between a reference molecule and a target molecule. The target molecule has the common set of atoms PAB and a set of atoms PB. The method includes applying a potential to restrain an interaction of the additional atomic component from the set of atoms PB with the common set of atoms PAB in the initial state. The method includes determining one or more transition states along a transformation path between the initial state and target state. The method includes scaling the restrain potential correspondingly along the transformation path until the potential becomes zero when a corresponding end state is reached, and calculating the free energy difference between the reference molecule and the target molecule using a value obtained along the transformation path from the initial state to the target state.

Abstract: Methods of calculating a free energy of solubility for a compound in a solvent by computer operations include the following steps: (i) establishing, using a computer model, an initial state for a system including an aggregate of multiple molecules of the compound in a solvent; (ii) establishing, using the computer model, a final state of the system including a single molecule from the aggregate fully solvated in the solvent and separate from a transformed aggregate; (iii) transforming, using the computer model, the system from the initial state to the final state, via removing a first molecule of the compound from the aggregate to form the transformed aggregate and replacing the first molecule with solvent at the site of the first molecule; and (iv) calculating the free energy of the transformation between the initial and the final states, which determines the free energy of solubility for the compound.

Abstract: Methods for assessing the consistency and reliability of the calculations using cycle closures in relative binding free energy calculation paths. The methods are used for determining relative strength of binding between a receptor and individual members of a set ligands to form complexes between individual ligand set members and the receptor, in which the binding free energy difference with the lowest error is determined by probabilistic determination of the free energy differences and error distributions about those differences along each of the legs of the closed thermodynamic cycle that probabilistically lead to the hysteresis(es) value(s) observed for each closed of the closed thermodynamic cycle.