Thin
layer chromatography is used to separate components of a plant extract,
illustrating the experiment with plant pigments that gave its
chromatography name
Chromatography is a laboratory technique for the separation of a mixture.
The mixture is dissolved in a fluid called the mobile phase, which carries it through a structure holding another material called the stationary phase.
The various constituents of the mixture travel at different speeds,
causing them to separate. The separation is based on differential
partitioning between the mobile and stationary phases. Subtle
differences in a compound's partition coefficient result in differential retention on the stationary phase and thus affect the separation.
Chromatography may be preparative or analytical. The purpose of
preparative chromatography is to separate the components of a mixture
for later use, and is thus a form of purification.
Analytical chromatography is done normally with smaller amounts of
material and is for establishing the presence or measuring the relative
proportions of analytes in a mixture. The two are not mutually
exclusive.
Etymology and pronunciation
Chromatography, pronounced /ˌkroʊməˈtɒɡrəfi/, is derived from Greek χρῶμα chroma, which means "color", and γράφειν graphein, which means "to write".
History
Chromatography was first employed in Russia by the Italian-born scientist Mikhail Tsvet in 1900. He continued to work with chromatography in the first decade of the 20th century, primarily for the separation of plant pigments such as chlorophyll, carotenes, and xanthophylls.
Since these components have different colors (green, orange, and
yellow, respectively) they gave the technique its name. New types of
chromatography developed during the 1930s and 1940s made the technique
useful for many separation processes.
Chromatography technique developed substantially as a result of the work of Archer John Porter Martin and Richard Laurence Millington Synge during the 1940s and 1950s, for which they won the 1952 Nobel Prize in Chemistry.
They established the principles and basic techniques of partition
chromatography, and their work encouraged the rapid development of
several chromatographic methods: paper chromatography, gas chromatography, and what would become known as high-performance liquid chromatography.
Since then, the technology has advanced rapidly. Researchers found that
the main principles of Tsvet's chromatography could be applied in many
different ways, resulting in the different varieties of chromatography
described below. Advances are continually improving the technical
performance of chromatography, allowing the separation of increasingly
similar molecules. Chromatography has also been employed as a method to
test the potency of cannabis.
Chromatography terms
- The analyte is the substance to be separated during chromatography. It is also normally what is needed from the mixture.
- Analytical chromatography is used to determine the existence and possibly also the concentration of analyte(s) in a sample.
- A bonded phase is a stationary phase that is covalently bonded to the support particles or to the inside wall of the column tubing.
- A chromatogram is the visual output of the chromatograph. In the case of an optimal separation, different peaks or patterns on the chromatogram correspond to different components of the separated mixture.
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- A chromatograph is equipment that enables a sophisticated separation, e.g. gas chromatographic or liquid chromatographic separation.
- Chromatography is a physical method of separation that distributes components to separate between two phases, one stationary (stationary phase), the other (the mobile phase) moving in a definite direction.
- The eluate is the mobile phase leaving the column. This is also called effluent.
- The eluent is the solvent that carries the analyte.
- The eluite is the analyte, the eluted solute.
- An eluotropic series is a list of solvents ranked according to their eluting power.
- An immobilized phase is a stationary phase that is immobilized on the support particles, or on the inner wall of the column tubing.
- The mobile phase is the phase that moves in a definite direction. It may be a liquid (LC and Capillary Electrochromatography (CEC)), a gas (GC), or a supercritical fluid (supercritical-fluid chromatography, SFC). The mobile phase consists of the sample being separated/analyzed and the solvent that moves the sample through the column. In the case of HPLC the mobile phase consists of a non-polar solvent(s) such as hexane in normal phase or a polar solvent such as methanol in reverse phase chromatography and the sample being separated. The mobile phase moves through the chromatography column (the stationary phase) where the sample interacts with the stationary phase and is separated.
- Preparative chromatography is used to purify sufficient quantities of a substance for further use, rather than analysis.
- The retention time is the characteristic time it takes for a particular analyte to pass through the system (from the column inlet to the detector) under set conditions. See also: Kovats' retention index
- The sample is the matter analyzed in chromatography. It may consist of a single component or it may be a mixture of components. When the sample is treated in the course of an analysis, the phase or the phases containing the analytes of interest is/are referred to as the sample whereas everything out of interest separated from the sample before or in the course of the analysis is referred to as waste.
- The solute refers to the sample components in partition chromatography.
- The solvent refers to any substance capable of solubilizing another substance, and especially the liquid mobile phase in liquid chromatography.
- The stationary phase is the substance fixed in place for the chromatography procedure. Examples include the silica layer in thin layer chromatography
- The detector refers to the instrument used for qualitative and quantitative detection of analytes after separation.
Chromatography is based on the concept of partition coefficient. Any
solute partitions between two immiscible solvents. When we make one
solvent immobile (by adsorption on a solid support matrix) and another
mobile it results in most common applications of chromatography. If the
matrix support, or stationary phase, is polar (e.g. paper, silica etc.)
it is forward phase chromatography, and if it is non-polar (C-18) it is
reverse phase.
Techniques by chromatographic bed shape
Column chromatography
Column chromatography is a separation technique in which the
stationary bed is within a tube. The particles of the solid stationary
phase or the support coated with a liquid stationary phase may fill the
whole inside volume of the tube (packed column) or be concentrated on or
along the inside tube wall leaving an open, unrestricted path for the
mobile phase in the middle part of the tube (open tubular column).
Differences in rates of movement through the medium are calculated to
different retention times of the sample.
In 1978, W. Clark Still introduced a modified version of column chromatography called flash column chromatography (flash).
The technique is very similar to the traditional column chromatography,
except for that the solvent is driven through the column by applying
positive pressure. This allowed most separations to be performed in less
than 20 minutes, with improved separations compared to the old method.
Modern flash chromatography systems are sold as pre-packed plastic
cartridges, and the solvent is pumped through the cartridge. Systems may
also be linked with detectors and fraction collectors providing
automation. The introduction of gradient pumps resulted in quicker
separations and less solvent usage.
In expanded bed adsorption,
a fluidized bed is used, rather than a solid phase made by a packed
bed. This allows omission of initial clearing steps such as
centrifugation and filtration, for culture broths or slurries of broken
cells.
Phosphocellulose
chromatography utilizes the binding affinity of many DNA-binding
proteins for phosphocellulose. The stronger a protein's interaction
with DNA, the higher the salt concentration needed to elute that
protein.
Planar chromatography
Planar chromatography
is a separation technique in which the stationary phase is present as
or on a plane. The plane can be a paper, serving as such or impregnated
by a substance as the stationary bed (paper chromatography) or a layer of solid particles spread on a support such as a glass plate (thin layer chromatography). Different compounds
in the sample mixture travel different distances according to how
strongly they interact with the stationary phase as compared to the
mobile phase. The specific Retention factor (Rf) of each chemical can be used to aid in the identification of an unknown substance.
Paper chromatography
Paper chromatography in progress
Paper chromatography is a technique that involves placing a small dot or line of sample solution onto a strip of chromatography paper. The paper is placed in a container with a shallow layer of solvent
and sealed. As the solvent rises through the paper, it meets the sample
mixture, which starts to travel up the paper with the solvent. This
paper is made of cellulose, a polar substance,
and the compounds within the mixture travel farther if they are
non-polar. More polar substances bond with the cellulose paper more
quickly, and therefore do not travel as far.
Thin layer chromatography (TLC)
Thin layer chromatography (TLC) is a widely employed laboratory
technique used to separate different biochemicals on the basis of their
relative attractions to the stationary and mobile phases. It is similar
to paper chromatography. However, instead of using a stationary phase of paper, it involves a stationary phase of a thin layer of adsorbent like silica gel, alumina, or cellulose on a flat, inert substrate.
TLC is very versatile; multiple samples can be separated simultaneously
on the same layer, making it very useful for screening applications
such as testing drug levels and water purity.
Possibility of cross-contamination is low since each separation is
performed on a new layer. Compared to paper, it has the advantage of
faster runs, better separations, better quantitative analysis, and the
choice between different adsorbents. For even better resolution and faster separation that utilizes less solvent, high-performance TLC
can be used. An older popular use had been to differentiate chromosomes
by observing distance in gel (separation of was a separate step).
Displacement chromatography
The basic principle of displacement chromatography
is:
A molecule with a high affinity for the chromatography matrix (the
displacer) competes effectively for binding sites, and thus displaces
all molecules with lesser affinities.
There are distinct differences between displacement and elution
chromatography. In elution mode, substances typically emerge from a
column in narrow, Gaussian peaks. Wide separation of peaks, preferably
to baseline, is desired for maximum purification. The speed at which any
component of a mixture travels down the column in elution mode depends
on many factors. But for two substances to travel at different speeds,
and thereby be resolved, there must be substantial differences in some
interaction between the biomolecules and the chromatography matrix.
Operating parameters are adjusted to maximize the effect of this
difference. In many cases, baseline separation of the peaks can be
achieved only with gradient elution and low column loadings. Thus, two
drawbacks to elution mode chromatography, especially at the preparative
scale, are operational complexity, due to gradient solvent pumping, and
low throughput, due to low column loadings. Displacement chromatography
has advantages over elution chromatography in that components are
resolved into consecutive zones of pure substances rather than “peaks”.
Because the process takes advantage of the nonlinearity of the
isotherms, a larger column feed can be separated on a given column with
the purified components recovered at significantly higher
concentrations.
Techniques by physical state of mobile phase
Gas chromatography
Gas chromatography (GC), also sometimes known as gas-liquid
chromatography, (GLC), is a separation technique in which the mobile
phase is a gas. Gas chromatographic separation is always carried out in a
column, which is typically "packed" or "capillary". Packed columns are
the routine work horses of gas chromatography, being cheaper and easier
to use and often giving adequate performance. Capillary columns
generally give far superior resolution and although more expensive are
becoming widely used, especially for complex mixtures. Both types of
column are made from non-adsorbent and chemically inert materials.
Stainless steel and glass are the usual materials for packed columns and
quartz or fused silica for capillary columns.
Gas chromatography is based on a partition equilibrium
of analyte between a solid or viscous liquid stationary phase (often a
liquid silicone-based material) and a mobile gas (most often helium).
The stationary phase is adhered to the inside of a small-diameter
(commonly 0.53 – 0.18mm inside diameter) glass or fused-silica tube (a
capillary column) or a solid matrix inside a larger metal tube (a packed
column). It is widely used in analytical chemistry;
though the high temperatures used in GC make it unsuitable for high
molecular weight biopolymers or proteins (heat denatures them),
frequently encountered in biochemistry, it is well suited for use in the petrochemical, environmental monitoring and remediation, and industrial chemical fields. It is also used extensively in chemistry research.
Liquid chromatography
Preparative HPLC apparatus
Liquid chromatography (LC) is a separation technique in which the
mobile phase is a liquid. It can be carried out either in a column or a
plane. Present day liquid chromatography that generally utilizes very
small packing particles and a relatively high pressure is referred to as
high-performance liquid chromatography (HPLC).
In HPLC the sample is forced by a liquid at high pressure (the
mobile phase) through a column that is packed with a stationary phase
composed of irregularly or spherically shaped particles, a porous monolithic layer,
or a porous membrane. HPLC is historically divided into two different
sub-classes based on the polarity of the mobile and stationary phases.
Methods in which the stationary phase is more polar than the mobile
phase (e.g., toluene as the mobile phase, silica as the stationary
phase) are termed normal phase liquid chromatography (NPLC) and the
opposite (e.g., water-methanol mixture as the mobile phase and C18 (octadecylsilyl) as the stationary phase) is termed reversed phase liquid chromatography (RPLC).
Specific techniques under this broad heading are listed below.
Affinity chromatography
Affinity chromatography
is based on selective non-covalent interaction between an analyte and
specific molecules. It is very specific, but not very robust. It is
often used in biochemistry in the purification of proteins bound to tags. These fusion proteins are labeled with compounds such as His-tags, biotin or antigens,
which bind to the stationary phase specifically. After purification,
some of these tags are usually removed and the pure protein is obtained.
Affinity chromatography often utilizes a biomolecule's affinity
for a metal (Zn, Cu, Fe, etc.). Columns are often manually prepared.
Traditional affinity columns are used as a preparative step to flush out
unwanted biomolecules.
However, HPLC techniques exist that do utilize affinity
chromatography properties. Immobilized Metal Affinity Chromatography
(IMAC)
is useful to separate aforementioned molecules based on the relative
affinity for the metal (i.e. Dionex IMAC). Often these columns can be
loaded with different metals to create a column with a targeted
affinity.
Supercritical fluid chromatography
Supercritical fluid chromatography is a separation technique in which
the mobile phase is a fluid above and relatively close to its critical
temperature and pressure.
Techniques by separation mechanism
Ion exchange chromatography
Ion exchange chromatography (usually referred to as ion
chromatography) uses an ion exchange mechanism to separate analytes
based on their respective charges. It is usually performed in columns
but can also be useful in planar mode. Ion exchange chromatography uses a
charged stationary phase to separate charged compounds including anions, cations, amino acids, peptides, and proteins. In conventional methods the stationary phase is an ion exchange resin that carries charged functional groups
that interact with oppositely charged groups of the compound to retain.
There are two types of ion exchange chromatography: Cation-Exchange and
Anion-Exchange. In the Cation-Exchange Chromatography the stationary
phase has negative charge and the exchangeable ion is a cation, whereas,
in the Anion-Exchange Chromatography the stationary phase has positive
charge and the exchangeable ion is an anion. Ion exchange chromatography is commonly used to purify proteins using FPLC.
Size-exclusion chromatography
Size-exclusion chromatography (SEC) is also known as gel permeation chromatography (GPC) or gel filtration chromatography
and separates molecules according to their size (or more accurately
according to their hydrodynamic diameter or hydrodynamic volume).
Smaller molecules are able to enter the pores of the media and,
therefore, molecules are trapped and removed from the flow of the mobile
phase. The average residence time in the pores depends upon the
effective size of the analyte molecules. However, molecules that are
larger than the average pore size of the packing are excluded and thus
suffer essentially no retention; such species are the first to be
eluted. It is generally a low-resolution chromatography technique and
thus it is often reserved for the final, "polishing" step of a
purification. It is also useful for determining the tertiary structure and quaternary structure of purified proteins, especially since it can be carried out under native solution conditions.
Expanded bed adsorption chromatographic separation
An expanded bed chromatographic adsorption (EBA) column for a
biochemical separation process comprises a pressure equalization liquid
distributor having a self-cleaning function below a porous blocking
sieve plate at the bottom of the expanded bed, an upper part nozzle
assembly having a backflush cleaning function at the top of the expanded
bed, a better distribution of the feedstock liquor added into the
expanded bed ensuring that the fluid passed through the expanded bed
layer displays a state of piston flow. The expanded bed layer displays a
state of piston flow. The expanded bed chromatographic separation
column has advantages of increasing the separation efficiency of the
expanded bed.
Expanded-bed adsorption (EBA) chromatography is a convenient and
effective technique for the capture of proteins directly from
unclarified crude sample. In EBA chromatography, the settled bed is
first expanded by upward flow of equilibration buffer. The crude feed, a
mixture of soluble proteins, contaminants, cells, and cell debris, is
then passed upward through the expanded bed. Target proteins are
captured on the adsorbent, while particulates and contaminants pass
through. A change to elution buffer while maintaining upward flow
results in desorption of the target protein in expanded-bed mode.
Alternatively, if the flow is reversed, the adsorbed particles will
quickly settle and the proteins can be desorbed by an elution buffer.
The mode used for elution (expanded-bed versus settled-bed) depends on
the characteristics of the feed. After elution, the adsorbent is cleaned
with a predefined cleaning-in-place (CIP) solution, with cleaning
followed by either column regeneration (for further use) or storage.
Special techniques
Reversed-phase chromatography
Reversed-phase chromatography (RPC) is any liquid chromatography
procedure in which the mobile phase is significantly more polar than the
stationary phase. It is so named because in normal-phase liquid
chromatography, the mobile phase is significantly less polar than the
stationary phase. Hydrophobic molecules in the mobile phase tend to
adsorb to the relatively hydrophobic stationary phase. Hydrophilic
molecules in the mobile phase will tend to elute first. Separating
columns typically comprise a C8 or C18 carbon-chain bonded to a silica
particle substrate.
Hydrophobic interaction chromatography
Hydrophobic
interactions between proteins and the chromatographic matrix can be
exploited to purify proteins. In hydrophobic interaction chromatography
the matrix material is lightly substituted with hydrophobic groups.
These groups can range from methyl, ethyl, propyl, octyl, or phenyl
groups.
At high salt concentrations, non-polar sidechains on the surface on
proteins "interact" with the hydrophobic groups; that is, both types of
groups are excluded by the polar solvent (hydrophobic effects are
augmented by increased ionic strength). Thus, the sample is applied to
the column in a buffer which is highly polar. The eluant is typically an
aqueous buffer with decreasing salt concentrations, increasing
concentrations of detergent (which disrupts hydrophobic interactions),
or changes in pH.
In general, Hydrophobic Interaction Chromatography (HIC) is
advantageous if the sample is sensitive to pH change or harsh solvents
typically used in other types of chromatography but not high salt
concentrations. Commonly, it is the amount of salt in the buffer which
is varied. In 2012, Müller and Franzreb described the effects of
temperature on HIC using Bovine Serum Albumin (BSA) with four different
types of hydrophobic resin. The study altered temperature as to effect
the binding affinity of BSA onto the matrix. It was concluded that
cycling temperature from 50 degrees to 10 degrees would not be adequate
to effectively wash all BSA from the matrix but could be very effective
if the column would only be used a few times. Using temperature to effect change allows labs to cut costs on buying salt and saves money.
If high salt concentrations along with temperature fluctuations
want to be avoided you can use a more hydrophobic to compete with your
sample to elute it. [source] This so-called salt independent method of
HIC showed a direct isolation of Human Immunoglobulin G (IgG) from serum
with satisfactory yield and used Beta-cyclodextrin as a competitor to
displace IgG from the matrix.
This largely opens up the possibility of using HIC with samples which
are salt sensitive as we know high salt concentrations precipitate
proteins.
Two-dimensional chromatograph GCxGC-TOFMS at Chemical Faculty of GUT Gdańsk, Poland, 2016
Two-dimensional chromatography
In
some cases, the chemistry within a given column can be insufficient to
separate some analytes. It is possible to direct a series of unresolved
peaks onto a second column with different physico-chemical (chemical classification) properties.
Since the mechanism of retention on this new solid support is different
from the first dimensional separation, it can be possible to separate
compounds by two-dimensional chromatography that are indistinguishable by one-dimensional chromatography.
The sample is spotted at one corner of a square plate, developed,
air-dried, then rotated by 90° and usually redeveloped in a second
solvent system.
Simulated moving-bed chromatography
The simulated moving bed (SMB) technique is a variant of high
performance liquid chromatography; it is used to separate particles
and/or chemical compounds that would be difficult or impossible to
resolve otherwise. This increased separation is brought about by a
valve-and-column arrangement that is used to lengthen the stationary
phase indefinitely.
In the moving bed technique of preparative chromatography the feed entry
and the analyte recovery are simultaneous and continuous, but because
of practical difficulties with a continuously moving bed, simulated
moving bed technique was proposed. In the simulated moving bed technique
instead of moving the bed, the sample inlet and the analyte exit
positions are moved continuously, giving the impression of a moving bed.
True moving bed chromatography (TMBC) is only a theoretical concept. Its
simulation, SMBC is achieved by the use of a multiplicity of columns in
series and a complex valve arrangement, which provides for sample and
solvent feed, and also analyte and waste takeoff at appropriate
locations of any column, whereby it allows switching at regular
intervals the sample entry in one direction, the solvent entry in the
opposite direction, whilst changing the analyte and waste takeoff
positions appropriately as well.
Pyrolysis gas chromatography
Pyrolysis–gas chromatography–mass spectrometry
is a method of chemical analysis in which the sample is heated to
decomposition to produce smaller molecules that are separated by gas
chromatography and detected using mass spectrometry.
Pyrolysis is the thermal decomposition of materials in an inert
atmosphere or a vacuum. The sample is put into direct contact with a
platinum wire, or placed in a quartz sample tube, and rapidly heated to
600–1000 °C. Depending on the application even higher temperatures are
used. Three different heating techniques are used in actual pyrolyzers:
Isothermal furnace, inductive heating (Curie Point filament), and
resistive heating using platinum filaments. Large molecules cleave at
their weakest points and produce smaller, more volatile fragments. These
fragments can be separated by gas chromatography. Pyrolysis GC
chromatograms are typically complex because a wide range of different
decomposition products is formed. The data can either be used as
fingerprint to prove material identity or the GC/MS data is used to
identify individual fragments to obtain structural information. To
increase the volatility of polar fragments, various methylating reagents
can be added to a sample before pyrolysis.
Besides the usage of dedicated pyrolyzers, pyrolysis GC of solid
and liquid samples can be performed directly inside Programmable
Temperature Vaporizer (PTV) injectors that provide quick heating (up to
30 °C/s) and high maximum temperatures of 600–650 °C. This is sufficient
for some pyrolysis applications. The main advantage is that no
dedicated instrument has to be purchased and pyrolysis can be performed
as part of routine GC analysis. In this case quartz GC inlet liners have
to be used. Quantitative data can be acquired, and good results of
derivatization inside the PTV injector are published as well.
Fast protein liquid chromatography
Fast protein liquid chromatography (FPLC), is a form of liquid
chromatography that is often used to analyze or purify mixtures of
proteins. As in other forms of chromatography, separation is possible
because the different components of a mixture have different affinities
for two materials, a moving fluid (the "mobile phase") and a porous
solid (the stationary phase). In FPLC the mobile phase is an aqueous
solution, or "buffer". The buffer flow rate is controlled by a
positive-displacement pump and is normally kept constant, while the
composition of the buffer can be varied by drawing fluids in different
proportions from two or more external reservoirs. The stationary phase
is a resin composed of beads, usually of cross-linked agarose, packed
into a cylindrical glass or plastic column. FPLC resins are available in
a wide range of bead sizes and surface ligands depending on the
application.
Countercurrent chromatography
An example of a HPCCC system
Countercurrent chromatography (CCC) is a type of liquid-liquid
chromatography, where both the stationary and mobile phases are liquids.
The operating principle of CCC equipment requires a column consisting of
an open tube coiled around a bobbin. The bobbin is rotated in a
double-axis gyratory motion (a cardioid), which causes a variable
gravity (G) field to act on the column during each rotation. This motion
causes the column to see one partitioning step per revolution and
components of the sample separate in the column due to their
partitioning coefficient between the two immiscible liquid phases used.
There are many types of CCC available today. These include HSCCC (High
Speed CCC) and HPCCC (High Performance CCC). HPCCC is the latest and
best performing version of the instrumentation available currently.
Periodic counter-current chromatography
In contrast to Countercurrent chromatography (see above), periodic
counter-current chromatography (PCC) uses a solid stationary phase and
only a liquid mobile phase. It thus is much more similar to conventional
affinity chromatography
than to countercurrent chromatography. PCC uses multiple columns, which
during the loading phase are connected in line. This mode allows for
overloading the first column in this series without losing product,
which already breaks through the column before the resin is fully
saturated. The breakthrough product is captured on the subsequent
column(s). In a next step the columns are disconnected from one another.
The first column is washed and eluted, while the other column(s) are
still being loaded. Once the (initially) first column is
re-equilibrated, it is re-introduced to the loading stream, but as last
column. The process then continues in a cyclic fashion.
Chiral chromatography
Chiral
chromatography involves the separation of stereoisomers. In the case of
enantiomers, these have no chemical or physical differences apart from
being three-dimensional mirror images. Conventional chromatography or
other separation processes are incapable of separating them. To enable
chiral separations to take place, either the mobile phase or the
stationary phase must themselves be made chiral, giving differing
affinities between the analytes. Chiral chromatography HPLC columns (with a chiral stationary phase) in both normal and reversed phase are commercially available.
Aqueous normal-phase chromatography
Aqueous
normal-phase (ANP) chromatography is characterized by the elution
behavior of classical normal phase mode (i.e. where the mobile phase is
significantly less polar than the stationary phase) in which water is
one of the mobile phase solvent system components. It is distinguished
from hydrophilic interaction liquid chromatography (HILIC) in that the
retention mechanism is due to adsorption rather than partitioning.
