CHROMATOGRAPHY
The term Chromatography is a
relatively new separation technique. In Greek, the term 'Khromatos' means ‘color’ and term 'graphos' means ‘writing’.
The Chromatography-technique was
first discovered by Russian biologist Dr. Micheal Tswett in 1906, for the
separation of color plant pigment on a column of alumina.
Nowadays various types of
Chromatography are in use to separate almost any given mixture whether color or
colorless into it’s as an analytical technique employed for the inorganic substance.
Separation method is used for qualitative identification and quantitative
determination.
Chromatography is a name given
to technique by which members of a group of similar substance are separated by
continuous redistribution between two phases. The first one is stationary phase
and second is mobile phase.
Introduction Principle, Types & Uses
1. Paper
Chromatography
2. Thin
Layer Chromatography
3. Column
Chromatography
4. Lon
Exchange Chromatography
5. Affinity
Chromatography
6. Gel
Chromatography
Chromatographic Method
|
Basis
|
Adsorption
Column Chromatography
|
Distribution of solute between solid and liquid phase on a column
|
Partition
Column Chromatography
|
Distribution of solute between two liquids on a column
|
Paper Chromatography
|
Partition on a sheet of paper
|
Thin
Layer Chromatography
|
Adsorption of partition on thin sheets
|
Ion
Exchange Chromatography
|
Exchange of ion
|
Gel
Permeation Chromatography
|
Size of solute
|
Gas Chromatography
|
Distribution of gaseous solutes between a gas, liquid/solid phase.
|
Electrophoretic Chromatography
|
Separation on a sheet in the presence of an electric field
|
Chromatography – 2 classes
The two classes of
Chromatography are,
1. Gas
2. Liquid
Chromatography
a.
Adsorption
b.
Partition
c.
Ion Exchange
d.
Electrophoretic
Chromatography technique
separates molecule on the basis of difference of size, shape, mass, charge, solubility,
and adsorption properties. There are many different types of chromatography but
they all involve interaction between three components.
a. Mixture
to be separated
b. Stationary
phase (solid phase which supports)
c. Solvent system
(mobile phase which moves over the stationary phase)
Basis of separation
In
chromatography, two immiscible phases (i.e. stationary and mobile phases) are
brought into contact with each other. The mobile phase undergoes a series of
interaction between stationary and mobile phases as it is being carried through
the system by mobile phases. The difference in interaction governs the rate of
migration of individual components under the influence of mobile phase. Under
suitable condition, the resulting different rates of migration can bring about
complete separation of the substance.
Solute property used for
Chromatography separation
Technique Solute
Property
- Adsorption a.
Adsorption of particle
- Partition b.
Solubility
- Ion exchange c.
Ionization
- Gel d.
Size and shape
Based on
nature of stationary phase and mobile phase
Stationary Mobile
Adsorption Chromatography
The technique in which
stationary phase is solid and mobile phase is liquid/gas is adsorption
Chromatography. The solid are absorbed in different parts of adsorbent column.
Then adsorbent component are eluted by passing suitable solvent through column.
Partition Chromatography
The technique in which stationary
phase is liquid, frequently water and mobile phase can be either liquid/gas.
Gas Chromatography
The stationary phase is
solid/liquid and mobile phase is mixture of gas, inert gas, nitrogen, helium,
argon.
Two types of GC are:
- Gas – Solid
Chromatography (Stationary Phase is Solid)
- Gas – Liquid
Chromatography (Stationary Phase is liquid)
Modes of Chromatography
Chromatographic separation may
be achieved by using three modes
- Column Chromatography
- Thin layer Chromatography
- Paper Chromatography
Column Chromatography
Column Chromatography is which
stationary phase is attached to a suitable matrix is packed into a glass or
metal column and the mobile phase is passed through the column either by
gravity feed or by the use of pumping system or applied gas pressure. It is the
most commonly used mode of Chromatography.
Thin Layer Chromatography
Thin Layer Chromatography in
which the stationary phase attached to a suitable matrix which is coated thinly
on to a glass or plastic plate. The mobile liquid phase passes across thin
layer either horizontally or vertically.
Paper Chromatography
In Paper Chromatography, stationary
liquid phase is supported by cellulose fiber of a paper sheet and the mobile
phase passes along the gravity feed or capillary action over the stationary
phase incorporated into a solid supporting material, cellulose.
PAPER CHROMATOGRAPHY
Paper Chromatography is an
example of partition Chromatography.
Paper Chromatography was first
introduced by Schonbein in 1961, but the technique became popular in 1963
through the work of R. Consden, A.H Gordon, A.J Martin and L.M Synege
This technique is a type of
partition Chromatography in which the substance are distributed in two liquid
phases i.e. one is stationary liquid usually water which is held in the fibers
of paper and called the stationary phase. And the other one is mobilizing
liquid or developing solvent and is called mobile phase. Organic solvent are
commonly used as mobile phase.
In paper Chromatography, the
separation of mixture of substance is mainly done by the flow of solvent on Whatmann
Chromatography filter paper. The stationary phase is present in cellulose of
filter paper and mobile phase is an organic solvent. Mobile phase i.e. organic
solvent rises by capillary action and by absorption on the filter paper. Separation
is achieved by the differential migration of different components which occurs
due to difference in partition coefficient.
Procedure
In this technique, a drop of
test solution is applied on small spot on the filter paper and the spot is
dried. The paper is kept in closed chamber containing developing solvent and
edge of filter paper is deepening into the solvent. Then the solvent is drawn out
by capillary action and carries the mixture of the surface. The component of
the mixture be separated migrate at different rates and appear as spots at
different points of the paper. The substances are separated according to their
relative solubility in the water and in organic solvent.
The
component having highest solubility will move rapidly along the strip of filter
paper than the less soluble component.
(FIGURE)
Rf (Relative
fraction) value:
The movement of the substance
relative to the solvent is expressed in terms of R.f value i.e. migration
parameter. Relative fraction is defined as the ratio of the distance travel by
the substance and the distance travel by the solvent front.
Mathematically;
The identification of given
compound may be made on the basis of its distance moved during development of
relative to the distance moved by the solvent. For each compound the value of Rf
is specific and Rf value is always less than one. Thus, an unknown
compound can be identified by comparing its Rf value with its
standard Rf value.
Figure 1: Determination of Rf value
Position coefficient or
distribution coefficient (Kd):
Basis of all form of
Chromatography is partition coefficient. This describes a way in which the two
compounds distribute in between two immiscible phases. For two such immiscible
phases A and B, the value for the coefficient is constant at the given
temperature and is given by the expression.
Partition coefficient can be
defined as total amount of substance present in one phase divided by total
amount of substance present in another phase.
Steps involved in Paper
Chromatography
Various steps involved in paper
chromatography are:
1. Choice of filter paper
The filter paper plays an
important role in the success of paper Chromatography and various types of
filter paper are available. Whatmann filter paper has a composition as a
content 98.99 % of α-cellulose and rest is the mineral content.
Components Percentage
·
α-cellulose 98.99%)
·
β-cellulose 0.3
- 1.0%)
·
Pentosans 0.4
- 0.8%)
·
Ether soluble matter 0.015 –
0.02%
·
Ash 0.01
- 0.07%
Figure:
Structure of cellulose with cross linking of glucose
In general paper is composed of
randomly directed cellulose fiber. The cellulose itself is network of long
chain of carbohydrate having mol. wt. > 10,000 and possessing hydrophilic
character and cross linked by a stable hydrogen bond system. Water or other
polar solvents is slightly held within the hydrophilic cellulose system.
Whatmann No. 1 filter paper is
of great importance and is mostly used for the medium flow rate.
Table 1: Characteristics
of Whatmann chromatographic papers
Rate of Flow
|
|||
Fast
|
Medium
|
Slow
|
|
Thin papers
|
No. 4
|
No. 1
|
No. 2
|
No. 5
|
No. 7
|
No. 20
|
|
No. 54
|
|||
No. 540
|
|||
Thick papers
|
No. 31
|
No. 3
|
|
No. 17
|
Note: Generally
used fast paper is No.4 and No.5
2. Choice of solvent
Paper chromatography is
essential a partition chromatography and there are a wide variety of useful
combination of stationary and mobile phase.
Stationary Phase: Stationary
phase that can be used are classified as,
- Aqueous
stationary phase: Water is rapidly held by paper.
Aqueous stationary phase is stained by suspending a paper in a closed
chamber whose atmosphere is saturated with water.
- Hydrophilic
stationary phase: Ammonia, paraffin, phenol, methanol,
glycerol are common hydrophilic solvent which are used as stationary
phase. The organic solvent is dissolved in a very volatile diluents and
paper is dipped into the solution. Hence, while drying in air, the
volatile diluent evaporates, leaving the stationary phase i.e. liquid,
uniformly distributed throughout the paper.
- Hydrophobic
stationary phase: Solvent such as kerosene, aromatics and
aliphatic hydrocarbon are used as hydrophobic stationary phase.
Mobile phase: Mixture
of two or more solvent is used. Generally, a solvent or solvent mixture which
gives an Rf value of 0.2 to 0.8 as the sample should be selected.
Some typical set of mobile phase
- Isopropanol – ammonia, water
- N butanol – acetic acid - water
- Water - phenol
- Formamide - chloroform
- Formamide – chloroform - benzene
- Formamide - benzene
- Formamide – benzene - cyclohexane
- Kerosene – 70 % isopropanol
- Dimethyl formamide – cyclohexane
3. Saturation of tank
The inner wall of tank is
wrapped by filter paper before running the chromatography.
4. Preparation of sample
Sample that can be used in paper
chromatography are of many types.
a) Biological
materials:
·
Serum
·
Extracts of plants and animal tissue.
·
Fermented broth
·
Culture
·
Food and food products
·
Vitamins
·
Antibiotics
If the sample is in solid form
it may be dissolved in volatile solvent before loading the sample.
Sample should be in concentrated
form. Some of the solid samples are dissolved in their specific solvents. E.g.
Amino acids and sugars are prepared in 10 % isopropanol, lipids are prepared in
chloroform.
5. Sample application / Sample
loading
A horizontal line is drawn on
the filter paper by pencil. This line is called origin line. On the origin
line, cross marks are made with pencil in such a way that each cross is at
least 2 cm away from each other.
Sample can be loaded by
micropipette, Pasteur pipettes, microcap pipettes or by microsyringe. Platinum
Pipette is generally used for qualitative purpose and it is also preferred for
practical use because it can be used again and again by carefully washing and
heating strongly after each application. If a loop is 0.4 mm diameter platinum
wire and a cross section diameter is 1.5 mm a spot of about 10 ml is obtained.
Microsyringe: It can
be used for both qualitative and quantitative purpose. Their capacity is 1-100 ml.
Microcap
pipette: It is used for single use. They are filled by capillary action and
bulb is used to expel the sample.
The sample volume of 10-20 ml is the ideal quantity to be
spotted. With the help of micropipette, the sample is applied on X-marks. The
spot are dried continuously by a stream of hot air. The spots are 0.5 cm to 1.5
cm in diameter.
6. Development of chromatogram
The loaded filter paper is
dipped carefully into the solvent in such a way that it shouldn’t leave more
than 1 cm and left undisturbed for at least 2 hrs until solvent front reaches
upto 15 to 18 cm height from the original line.
The chromatogram can be
developed by different methods:
- Ascending
technique: Movement of mobile phase is in upward
direction and the technique is known as ascending technique. In this
technique, mobile phase is placed in a suitable container at the bottom of
chamber. Then, the lower end of paper containing spots is dipped into the
solvent system without dipping the spots and then allowing it to rise up
the paper by capillary action. The mobile phase i.e. solvent move in the
upper direction against gravitational force.
- Descending
technique: In this technique, a flow of mobile phase is
in downward direction. The solvent is kept in a trough at the top of the
chamber and then allow floating down the paper. The movement of solvent is
caused by capillary action or by the pull of gravitation force. The rate
of flow of mobile phase is rapid as compared to ascending development so
that chromatogram as developed in short time.
- Radial
paper chromatography: The technique is also known as
solvent paper chromatography and this type of development is used in rare
condition. A circular piece of paper is taken and a wick of about 2 cm is
cut parallel to the radius from the edge of a center. The sample is
deposited at the center of the paper at the upper end of the wick. The
paper is then placed on the edge of a circular disc with the wick dipping
into the solvent at the bottom of circular disc. As a result, the liquid
ascends the wick and float radial through paper.
7. Drying the chromatogram
The wet chromatogram after
development is dried in special drying cabinet which has been heated
electrically with temperature control. The chromatogram can be died at 110°C for 5-10 minutes in hot air
oven.
8. Visualization of the spot
Colored compounds are easily located
on the paper but the compounds of biological origin are usually colorless and
hence can’t be located on the chromatogram imply by visible inspection. The
compounds on chromatogram can be located either by physical or biochemical
methods.
a) Physical methods:
- Fluorescence: Some
colorless spots when held under a UV lamp fluorescence and reveal their
existence i.e. if the compound are invisible under ordinary light, UV lamp
can be used to locate the position of the spot. Although several compounds
are relatively stable to UV light yet some compounds like steroids and
vitamins they are destroyed when UV visualization technique is employed
for identification.
- Radioactive
method: The location of substance may also be
carried out by making use of radioactive substance where radioactivity can
be detected by various counter devices.
b) Chemical Methods:
Chemical reagents are used to
visualize spots. Such type of chemical are called chromogenic reagent or
visualizing agent. The chemical reagent for locating spots can be gas, liquid
or solid.
Gas: H2S
Liquid: Methyl, ethyl or butyl alcohols
Solid: Potassium dichromate, aniline
dyes, ninhydrin
Visualizing reagents are applied
either by spraying or by dipping the chromatogram.
Spraying method: Chemical
reagent is sprayed on the chromatogram uniformly by using a glass atomizer
which is held in the position normally at the distance of 1 foot from the
paper, and is moved slowly from top to bottom in a left to right direction.
Dipping method: In this
method, a solvent is first taken in which substances are insoluble and then
dipping is carried out in trough. Volatile solvent e.g. ethyl alcohol and
methyl alcohol can be used because they can be easily evaporate from
chromatogram.
9. Quantitative Estimation
The amount of material in each
spot can be measured either by direct method or elution method.
Direct method:
i)
Comparison of visible spot: A rough quantitative
measurement of a compound in a mixture can be carried out by comparing the
intensity and size of spot with standard substance. For this purpose,
accurately measured volumes of the mixture and known amount of component being
investigated are applied separately on the origin line. Spots are dried,
developed treated with a reagent which will react with the component to produce
color. The size and intensity of colored spot produced by unknown component is
the compared with that of known standard substance by visual inspection or
under UV lamp.
ii) Photo densitometry: A strip of paper
containing the spot is cut and placed between two glass slides. Then the
intensity of each spot is measured with a photoelectric device called photo densitometer.
Elution Method:
The spots from the developed
chromatogram are eluted. The spots are cut off from the paper and then dissolve
in a suitable solvent in a test tube. Generally ethanol is used. The eluate
obtained from chromatogram can be estimated quantitatively by any physical or
chemical methods.
Alternate method that can be
used is spectrophotometry.
5 mg histidine – absorbance 0.08
X mg mixture – absorbance 0.03
Application
- Paper chromatography has been used for quantitative analysis of
inorganic, organic and biochemical substance.
- Paper chromatography can be used for identification of compound
in drugs, biochemical preparation and in natural products.
- It can be used for checking the purity of the sample or compound.
- It can also be used for separation and isolation of number of
compounds such as acid, alcohol, vitamins, amino acids, antibiotics.
- It is also used to detect traces of pollutants in water, food or
in soil. E.g. pesticides.
- It can be used for the separation of amino acids, sugars and many
other compounds.
- It can be used to study several compounds of biological origin
such as carbohydrates, sugars, lipids, acids, hormones, nucleotides.
- It can be used for the separation of inorganic ions.
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