TY - JOUR T1 - Solvation in mixed aqueous solvents from a thermodynamic cycle approach. AU - Shah,Prateek P, AU - Roberts,Christopher J, Y1 - 2008/01/09/ PY - 2008/1/10/pubmed PY - 2008/4/4/medline PY - 2008/1/10/entrez SP - 1049 EP - 52 JF - The journal of physical chemistry. B JO - J Phys Chem B VL - 112 IS - 4 N2 - A novel approach is presented for interpreting and potentially predicting values of the isothermal, isobaric transfer free energy, entropy, and enthalpy (Deltamicrotr2, Deltastr2, and Deltahtr2) for a solute between water and water-cosolvent mixtures. The approach explicitly accounts for volumetric properties of the solvent and solute (the equation of state, EoS) and casts the overall transfer process as a thermodynamic cycle with two stages: (1) isothermal solvent exchange from pure water to the cosolvent composition of interest at fixed mass density; (2) isothermal expansion or compression at the final solvent composition to recover the pressure of the initial state. Using molecular simulations with methane as the solute, the analysis is illustrated over a wide range of cosolvent concentrations for sorbitol-, ethanol-, and methanol-water binary mixtures. The EoS contribution semiquantitatively or quantitatively captures Deltamicrotr2, Deltastr2, and Deltahtr2 in almost all cases tested, highlighting the importance of considering the effects of changes in solvent density on the overall transfer process. The results also indicate that apolar solvation at these length scales is dominated by the work of cavity formation across a range of cosolvent species and concentrations. SN - 1520-6106 UR - https://www.unboundmedicine.com/medline/citation/18181598/Cyclopropanecarboxylic_acid_esters_as_potential_prodrugs_with_enhanced_hydrolytic_stability_ DB - PRIME DP - Unbound Medicine ER -