Absolv Equations

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Overview

Solvation parameters/hydrogen bonding potential are essential characteristics of solutes that are key determinants of many biological properties. In certain cases a simple model relating the property of interest to solvation descriptors (Abraham type equation) may suffice for a quick estimate of the behavior of new compounds in the relevant system.
The Absolv module is a product of cooperation between Pharma Algorithms and Prof. M. H. Abraham. Absolv Equations panel enables the user to calculate various solvent-solvent or gas-solvent partition coefficients from more than 250 predefined Abraham type equations may be calculated. Alternatively, any custom equations using predicted Abraham solvation parameters of a solute may be entered.

Module interface



  1. Values calculated using selected equations
  2. Toggle the result of a corresponding equation invisible in the Results Pane
  3. All solvation equations are grouped according to their type. Switch between these groups by selecting an appropriate tab
  4. Name of a solvation property
  5. Equation used to calculate a particular property
  6. Comments on a corresponding equation
  7. Literature references
  8. Scroll through all available equations in the selected group
  9. Toggle the result of a corresponding equation visible/invisible in the Results pane
  10. Click to open the Equation Manager window


Equation Manager


Equation Manager allows defining new and editing or deleting the existing custom Abraham type equations as well as viewing all the predefined ones.

Note: The predefined internal equations can be neither altered nor deleted.


  1. Select the equation’s category
  2. Select an individual equation
  3. Edit a custom equation or view the preset one - opens the Edit Equation window (see below)
  4. Create a new custom equation - opens the Edit Equation window (see below)
  5. Delete the created equation
  6. Close the Equation Manager window


After the Edit... (3) or New... (4) button is clicked, the Edit Equation window appears:


  1. Enter the name of the equation
  2. Enter the value of the intercept
  3. Enter a coefficient of the corresponding solute property in the formula
  4. Choose between the available H-Bonding basicity parameters (B or Bo)
  5. Select the appropriate cavity effect and dispersion interactions descriptor (L or V)
  6. Select the category of the equation from the drop-down list or enter a name of the new one
  7. Enter comment
  8. Enter a literature reference


Newly entered equations appear under the corresponding category in the Equation Manager and Equations pane:




Technical information


Calculated quantitative parameters


Absolv equations are commonly used to calculate the following groups of properties:

  • Water-solvent partitions
  • Gas-solvent partitions
  • Rough estimate of solute partitioning in biological systems (water-skin, water-cell permeation, etc.)

General LFER equation relating solute properties (SP) to solvation parameters:

SP = i + a·A + b·B (Bo) + e·E + s·S + v·V (l·L)

The major difference between the equations for estimating water/solvent and gas/solvent partitioning coefficients is the choice of the parameter characterizing dispersion interactions and cavity effect. For the former group of properties McGowan characteristic volume (V) is used for this purpose, while for the latter group it is replaced by hexadecane/gaseous phase partitioning coefficient L.

Reference database


Absolv DB contains a browsable dataset consisting of 7885 compounds with experimental values of solvation parameters determined by Prof. M. H. Abraham and coworkers. The main literature references where the values comprising the Absolv DB were presented include:

  • Abraham, M. H., Grellier, P. L., Prior, D. V., Duce, P. P., Morris, J. J., and Taylor, P. J., J. Chem. Soc. Perkin Trans 2, 1989, 699.
  • Abraham, M. H., Grellier, P. L., Prior, D. V., Morris, J. J., and Taylor, P. J., J. Chem. Soc. Perkin Trans 2, 1990, 521.
  • Abraham, M. H., Whiting, G. S., Doherty, R. M., and Shuely, W. J., J. Chromatogr., 1991 (587), 213-228.