Ion Exchange Chromatography:
Many biological
materials for e.g. amino acids and proteins have ionizable groups and the fact
is they carry net positive or negative charge that can be utilized in
separating mixture of such compounds.
Ion exchange may be
defined as a reversible reaction in which pre mobile ions of solid phase ion
exchanger are exchanged for different ions of similar charge present in
solution. In ion exchange chromatography, a reversible exchange of ion is
possible between ions in liquid phase and the solid insoluble substance
containing ionic site.
Ion exchange resins are
porous, synthetic organic polymer containing charged group which are capable of
holding positive or negative ions.
The most common
properties of all ion exchange resins are
A. They are generally
insoluble in water and organic solvent such as benzene, ether and carbon
tetrachloride (CCl4).
B. They are complex in
nature i.e. in fact they are polymeric. The most important resins are
polysterene resins formed by condensation of styrene and divinyl benzene.
Figure
Granular resin swells
in water to give a gel structure due to hydration of ions. Swelling is directly
proportional to the percentage of cross linking. Less the cross linking less is
swelling. Ion exchange resins are mixed with cross linking reagents such as
divinyl resin.
C. They have active
counter ions that will exchange reversibly with other ions in a surrounding
solution without any change in material.
Figure 1: Cation and Anion exchanges
There are four basic
types of resins which are commonly used in ion exchanging.
1. Strong
acidic cation exchange resins
2. Weak
acidic cations exchange resins
3. Strong
basic anion exchange resins
4. Weak
basic anion exchange resins
1. Strong acidic cation exchange resins:
It
contains sulphonic acid group. Sulphonated polystyrene resins belong to this
class. They are useful in pH range 1-14. They are useful mainly in
fractionation of cations, inorganic separation and for separation of vitamins,
peptides and amino acids.
2. Weak acidic cations exchange resins:
It
contains carboxylic acid group. Carboxylic polymetacrylate (Polymethyl
methacrylate) is an example of weak acidic cation exchange resins. They are
useful in pH range 5-14. They are used in biochemical separation, fractionation
of cations, and separation of amino acids, antibiotics and organic bases.
3. Strong basic anion exchange resins:
It
contains quaternary ammonium groups. Quaternary ammonium polystyrene belongs to
this class. And it is effective between pH 0-12. This type of resins is useful
in fractionation of anion and for separation of vitamins and fatty acids.
4. Weak basic anion exchange resins:
It contains
phenol, formaldehyde or polyamines group. Phenol formaldehyde and polystyrene
resins belongs to this class. They are effective in pH range 0-9. It can be useful
in fractionation of anionic complexes of metals and separation of vitamins and
amino acids.
Types of Resin
|
Functional group
|
Nature of Resin
|
Commercial Name
|
Cation Exchanger
|
|||
Strongly acid
|
-CH2SO-H+
|
Sulphonated polystyrene
|
Amberlite
IR-100
IR-105
IR-109
|
Weakly acidic
|
-COOH
|
Carboxylic
polymetacrylate
|
Amberlite
IR-6
IR-50
|
Anion Exchanger
|
|||
Strongly basic
|
-CH2NR2OH
|
Quaternary polysteryrene
|
IRA-40
|
Weakly basic
|
-N(C2H5)
|
Polyamine
Polystyrene
|
De-Acedite E
Amberlite IR48
|
Techniques of Ion
Exchange Chromatography:
1. Preparation of
Column
The ion exchange
chromatography is carried out in a chromatographic column which usually
consists of a burette provided with a glass wool plug at the lower end.
Generally a ratio of 10: 1 or 100:1 between height and diameter is maintained
in most of the experiment. Too narrow or too wide column give uneven flow of
liquid and sometimes poor separation.
2. Preparation of Ion
Exchange
Ion exchange materials
are first allowed to swell in buffer or in HCl or NaOH solution for 2-3 hours
or sometimes overnight. Almost all ion exchange resin swells when placed in
buffer or distilled water and this is due to hydration of their ions. In dry
condition, the pore of resins is restricted so in order to swell the pore of
resin. Resins are suspended in buffer solution or in distilled water.
3. Washing of Ion
Exchangers
The ion exchange
material is obtained in required ionic form by washing with appropriate
solution. For e.g. the H+ form of cation exchange resins is obtained
by washing the material with HCl then with water until the washings are
neutral.
Anionic exchangers are
generally supplied in the form of salt and amines. Similarly, Na+
form is prepared by washing the resins with NaCl or NaOH solution and then with
water.
Figure 2: Ion exchange chromatography
4. Packing of Column
This is one of the most
critical factors in achieving a successful separation. The column is held in vertical
position and the slurry of resins is poured into the column that has its outlet
closed. The column is gently tapped to ensure that no air bubbles are trapped
and that packing material settles evenly.
5. Sample Application
Sample can be loaded by
using pipette or syringe. The amount of sample that can be applied to a column
is dependent upon the size of the column and the capacity of resins, If the
starting buffer is to be used throughout the development of column, the sample
volume be 1 % to 5 % of bed volume.
6. Development an
Elution of bound ions
Bound ions can be
removed by changing the pH of buffer. E.g. separation of amino acid is usually
achieved by using a strong acidic cation exchanger. The sample is introduced
onto the column at pH of 1-2, thus ensuring complete binding of all of the
amino acids.
Gradient elution used
in increasing pH and ionic concentration results in the sequential elution of
amino acid. Then acidic amino acid such as aspartic acid and glutamic acid are
eluted first. The neutral amino acid such as glycine and valine are eluted. The
basic amino acid such as lysine and arginine retain their net positive charge
at pH value of 9 to 11 and are eluted at last.
7. Analysis of eluate
Equal fraction of each
elute are collected at different test tube keeping the flow rate at 1 ml per
minute. The eluate collected in each fraction is mixed with ninhydrin color
reagent. The mixture is then heated to 105°C to develop the
color and intensity of color is determined by colorimeter method or
spectrophotometer method at 540 to 570 nm.
Figure 3: Separation of amino acids by ion exchange chromatography
Requirements:
i.
Strongly acidic resin (e.g. amberlite IR
-120)
ii.
HCl (4 mol / L)
iii.
HCl (0.1 mol/L)
iv.
Tris-HCl buffer (0.2 mol/L)
v.
NaOH (0.1 mol /L)
vi.
Amino acid mixture (Dissolve aspartic
acid, histidine and lysine in 0.2N HCl)
vii.
Acetate buffer (4 mol/L)
viii.
Ninhydrine reagent (store in brown
bottle)
Procedure:
1. Preparation of ion
exchanger
·
Gently stir the resin With HCl (4 mol/L)
until fully swollen.
2. Washing
·
Allow the resin to settle, then decant
the acid and repeat the wasting with 0.1N HCl, and resuspend it in the
solution.
3. Preparation and
packing of column
·
Clamp the column vertical position.
·
Fill
the column with resin suspended with 0.1 N HCl and allow to settle down and
height of which is made 11 cm.
4. Smaple application
·
Add
0.2 ml of amino acid mixture to the top of column wihtout disturbing ion
exchange resins.
·
Add
0.2 ml of 0.1 N HCl, allow it to float into the column and repeat this process
twice.
5. Development of Chromatogram
·
Finely
apply 2 ml of 0.1 N HCl to the top of resin and connect the column to a
reservoir containing 500 ml of 0.1 N HCl.
6. Elution of Amino acid
·
Collect
2 ml of each eluted sample in 40 test tubes keeping flow rate at 1 ml per
minute.
·
Test
five of the tubes at a time for the presence of amino acid by spotting a sample
from each tube onto a filter paper. Dip this in acetone solution of ninhydrin
and heat in an oven at 105°C. If amino acids are present they will show as blue
spot in the filter paper.
7. Detection of Amino acids
·
Adjust
the pH of each tube to five by addition of few drops of acid or alkali. Add 2
ml of ninhydrin reagent and heat in a boiling water bath for 15 minutes.
·
Cool
the tube to room temperature and add 3 ml of 50 % ethanol and read the
absorbance at 570 nm in spectrophotometer.
Figure 4: Elution of amino acids on the basis of charge behavior in different pH medium
Application of IEC
·
It
is used for separation of similar ions from one another because different ion
undergo exchange reaction to different extent.
·
IEC
can be used for removal of inferring radicals. E.g. PO43-
ion interferes in the estimation of calcium or barium ions by oxalate method.
Therefore its removal is achieved by passing a solution of calcium and barium
ions through a sulphonic acid cation exchanger. The Ca2+ or Ba2+
ions held by the resin will be removed by using suitable eluent. Ca2+
or Ba2+ ions will get exchanged with H+ ion while PO43-
will pass as such through the column.
·
IEC
is also used for the softening of hard water. The hardness of water is due to
presence of Ca2+ or Mg2+ or other divalent ions and these
ions can be removed by passing hard water through cation exchangers. Ca2+
and Mg2+ or any divalent ions are retained in clumn, Na+
ions pass into solution. These Na ions are harmless for washing purposes.
ResSO32-(Na+)2 + 2
Ca2+ ® ResSO32-
Ca2+ + 2Na+
·
IEC
is used for separation of amino acids and protein.
·
It
can be used for demineralization of water which requires removal of cations as
well as anions. Water is first passed through an acidic cation exchange where
cation like Na+, Ca2+, Mg2+ are exchanged by H+
ions. It is then passed through basic anion exchanger, where anions like Cl are
exchanged by OH- ions of exchanges. Then, H+ and OH-
which pass into the solution combined to form unionized water.
Protein Purification Protocol
Requirements:
1.
DEAE
Cellulose (Diethyl amino ethyl cellulose)
2. Eluting buffer
i. Sodium Phosphate (0.1 mol/L)
ii. Sodium Phosphate (0.2 mol/L)
iii. Sodium Phosphate (0.3 mol/L)
3. Human Serum
4.
UV
Spectrophotometer
Procedure:
1.
Column
prepared from Cellulose (0.1 mol/L, swelling buffer)
2.
Washing
(0.2 mol/L)
3.
Column
preparation vertically clamp
4.
Resin
solution add 1 L
5.
Sample
Application
6.
Carefully
pipette 0.5 ml of serum sample on the top of the column. Allow the serum to
pass into DEAE cellulose.
7.
Development
and Elution.
8.
Then
, elute slowly with 3 ml of eluting buffer.
9.
Fraction
collection.
10. Analysis of Amino acid
11. Calculate the recovery of protein by determining the
protein content of serum and then take the absornbance at 280 nm in
spectrophotometer.
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