Partition Coefficient

Partition Coefficient

Partition

If two immiscible phases are shook in a separatory funnel they will form two separated layers. The phases can be in the form of gases, liquids and even solids, but for simplicity only the liquid phase will be used in this explanation. Suppose liquid one is water (H2O) and the second one is diethyl ether (CH3-CH2-O-CH2-CH3), the ether will float on top of the water since it has a lower density. A substance called X, soluble in both liquid was put in before the shaking took place. Suppose the particles of X are more soluble in the ether than in the water such that the scenario will resemble the picture below. A dynamic equilibrium will be established which consists of a constant rate of particlescrossing the boundary between the two liquids.  

 

  This information could be interpreted in the following equation:

          X(in solution in water)    X(in solution in ether)

This is a simple equilibrium, hence an equilibrium constant can be found.

Kc = [X in ether] / [X in water]  

This particular equilibrium constant is given the name Kcp, which stands for the partition coefficient.

The partition coefficient is dependent as all equilibrium constants on temperature but they do have specific limitations as well. For example the solutions have to be quite dilute for the constant to be accurate, the solute is required to be in the same molecular state in both solvents. This means that the solute cannot ionise, react or associate.   

Partition Coefficient

The calculations of the partition coefficient is a simple ratio of two separate concentrations. This proposes that the units that are used are irrelevant as long as they are the same in the numerator as in the denominator. The concentration can be expressed as mol dm-3 - moles per cubic decimetre, but more commonly g cm-3 - grams per cubic centimetre is used. The important distinguishing factor between the units is that the square brackets are strictly used for mol dm-3. This is to say that [X] is only to be used for standard concentration units, and in other cases “concentration of X” is a viable way.  

Lipophilicity and log P

To summarise; the partition coefficient is the ratio between the concentration of un-ionized solute in two immiscible solvents. To make this possible the pH of the water is adjusted to make the largest amount of compound un-ionized. The logarithm of the Kcp value is also known as the     log P, which is the measure of Lipophilicity. Lipophilicity is the tendency for molecules to dissolve into fats, lipids, oils and other hydrophobic solvents such as ether.   

log Poctanol/water = log ([solute]octanol / [solute]water)

When calculating the partition coefficient, the compound dissolved must be strictly be un-ionized. The same principle can be applied to a compound that ionizes completely or partially, and in this case it is called the distribution coefficient.  Like the partition coefficient the distribution coefficient is a ratio between the concentration of solutes in two immiscible solvents, but in contrast it takes into account ionized and un-ionized compounds. In practice the aqueous state is buffered to a specific pH, which will be stable when a compound is introduced. The distribution coefficient is the logarithm of the ratio between all the sum of all forms of a solute in two solvents.

log Doctanol/water = log ([solute]octanol / [solute] (ionized) water + [solute] (un-ionized) water)

The distribution coefficient can be seen as an extended form of the partition coefficient, taking more factors into account, which implies that log P = log D when ionization does not occur. As log D is dependent on pH it must be specified at what value of pH the calculations were performed.             

Practical Applications

The application of this method its applications can be seen in the chemical and pharmaceutical sciences. Normally water is chosen as one solvent while the other one is a hydrophobic, such as octanol. This makes it possible to determine how hydrophobic or hydrophilic a substance is by determining the partition coefficient. This in terms of medical studies allows to determine what distribution a drug will have inside the human body. Based on this an appropriate compartments of the human body are chosen to distribute them within. If a drug has a high octanol/water partition coefficient it is preferably distributed in an area that is hydrophobic such as the lipid bilayers. On the contrary, drugs that have a low octanol/water partition coefficient are preferably distributed in a hydrophilic source such as the blood serum.  

Lipophilicity is crucial in pharmacological practice, not only by how easily a drug can dissolve into fats as mentioned in the previous paragraph. It helps determining how strongly it will affect its target and how long it will stay in the body in its active form.   

A reliable way of determining the partition coefficient is by the “shake flask method”. The solute is dissolved by shaking the flask containing the solvents octanol and water. The concentration is then measured in each phase by UV/VIS spectroscopy

Problem Involving Partition Coefficient

Problem I

A solution of 1.56 g of X in 125 cm3 of water was shaken with 12 cm3 of ether, 0.89 g of X was moved to the ether layer. Now calculate the partition coefficient of X between ether and water.

Solution

The question asks to calculate the coefficient of X between ether and water. As the ether is stated first in the question it will come on top in the expression as follows.  

Kcp = concentration of X in ether / concentration of X in water

Concentrations are given in g cm-3 and hence will be calculated with these “non-standard” units.

Concentration of X in ether: 0.89g/12cm3

Concentration of X in water: 0.67g/125cm3

The concentration of water is not directly given, but can easily be calculated from the information that 0.89g was transferred to the ether. Hence (1.56g - 0.89g = 0.67g) is left in the water.

So:

Kcp = concentration of X in etherconcentration of X in water

     = (0.89g/12.0cm3) / (30.67g/125cm3)

     = 13.8  (3 sig fig)

Note that all units cancel in the expression and a unitless number is the result.   

Problem I a)

Now calculate the Lipophilicity (log P) of the previous question.

Solution

The log P value of the previous question is simply the logarithm of the Kcp.

log(13.8) = 1.14 (3 sig fig)

Problem II

In this problem use the same solvents, X and partition coefficient as given or calculated in previous problem.

How much of X would have been extracted to the ether if the original solution (1.56 g of X in 125 cm3 of water) was shaken with half the amount of ether.  

Solution II

Like in the previous equation we represent an expression for the concentration of both solvents.

Concentration of X in ether: m/6 g cm-3

The unknown mass will be represented as m.

Concentration of X in water: (1.56 - m)/ 125 g cm-3

Now, the information can be plotted into the expression for Kcp and solved for m.

Kcp = concentration of X in etherconcentration of X in water

13.8  = m/6 g cm-3(1.56 - m)/ 125 g cm-3        Note that all units cancel

13.8  = m/6 (1.56 - m)/ 125    

13.8(1.56-m) / 125  = m6   

21.528-13.8m / 125  = m6   

         21.528  = 125m6 + 13.8m

             21.528  = 34.633m

          m  = 21.528 / 34.633

          m  = 0.622   (3 sig fig)

Hence the mass of X extracted to the ether is 0.622 grams