Separation and Isolation Techniques + Chromatography (PDF)

Summary

This document discusses separation and isolation techniques, specifically focusing on plant constituents. It details various methods used for extraction and preservation. The methods described are relevant to the field of pharmacognosy. It also explores the use of chromatography for analysis and separation.

Full Transcript

PHARMACOGONOSY-III
SEPARATION AND ISOLATION OF PLANT
CONSTITUENTS
The phytochemical investigation of a plant involves the extraction
of a plant material, separation and isolation of the constituents of
interest; characterisation of the isolated compounds; investigation
of biosynthetic pathways to particular compounds, quantitative
evaluations and pharmacological activities.

The plant material used should be properly authenticated. The
choice of extraction procedure depends on the nature of the plant
material and the components to be isolated. Dried materials are
usually powdered before extraction, whereas fresh plants (e.g
leaves) can be homogenized or macerated with alcohol.

Alcohol is a fixed solvent for many plant constituents, except fixed
oils. Light petroleum (essential and fixed oils, steroids), ether and
chloroform (alkaloids), are used widely for extraction.
SELECTION COLLECTION AND IDENTIFICATION
OF PLANT MATERIAL
Selection of plant material for the study in drug discovery
programs may be performed by different approaches such as,
random selection, selective selection using
ethnopharmacological reports, or by restricting the plant of
interest to groups based on chemotaxonomic or geographical
preferences. Plant selection should normally involve a
literature survey of the floristic diversity of the area of interest
and shoul include the plant medicinal uses in the region where
collection will take place.
During collection of a plant it should be kept in mind that the
specimens to be studied should be healthy, since microbial and
other infections may change the metabolites produced by the
specimen. Variations in the collection sit, altitude, plant age,
climate, and soil type can all influence the concentration levels of
secondary metabolites and even the kinds of compounds
biosynthesized in some cases. Different organs of the plant are
known to produce different profiles of secondary metabolites, e.g.
flavonoids are found in the flowers and leaves of a particular
species, whereas tropane alkaloids occur in the roots and
sesquiterpene lactones and essential oils are restricted to glandular
hairs and other glands.
Once the plant part is collected, at least three herbarium samples
should be prepared, and each specimen should be correctly identified
by a taxonomist. One of these samples should be deposited in a local
herbarium, and the others should be deposited in a specialist
museum or herbarium. All voucher specimens should be kept in an
appropriate place for future reference. A card with details of the
place, altitude, environment and characteristics of each collection
should be attached to the herbarium sample which is very important
in case a recollection of the plant material is necessary.
 PRESERVATION OF PLANT MATERIAL

The plant material must first be preserved so that the active
compounds will remain unchanged during transport and
storage.
The cells of living plants contain not only low
molecular-weight compounds and enzymes, but
they also have many kinds of barriers that keep
these constituents apart. When the plant dies, the
barriers are quickly broken down and the enzymes
then get the opportunity to promote various
chemical changes in the other cell constituents,
e.g. by oxidation or hydrolysis. Preservation aims
A. Drying
The most common method for preserving plant material is drying.
Enzymic processes take place in aqueous solution. Rapid removal
of the water from the cell will, therefore, largely prevent
degradation of the cell constituents.
Drying also decreases the risk of external attack, e.g. by moulds.
Living plant material has a high water content: leaves may
contain 60-90% water, roots and rhizomes 70-85%, and wood
40-50%. The lowest percentage, often no more than 5-10%, is
found in seeds.
To stop the enzymic processes, the water content must be brought
down to about 10 %.
Drying must be done quickly, in other words at raised temperatures
and with rapid and efficient removal of the water vapor.
The most efficient drying is achieved in large driers of the tunnel
type. The plant material is spread out on shallow trays, which are
placed on mobile racks and passed into a tunnel where they meet a
stream of warm air.
The air temperature is kept at 20-40 °C for thin materials such as
leaves, but is often raised to 60-70 °C for plant parts that are harder
to dry, e.g. roots and barks.
When the crude drug has been collected under primitive conditions,
without access to a drier, it must be dried in the open. Even then,
the material should be spread out in shallow layers with good
ventilation to facilitate the drying. The choice of sunshine or shade
is determined by the sensitivity to light of the constituents.
In a dried drug the enzymes are not destroyed but only rendered
inactive due to the low water content. As soon as water is added,
they become active again. Hence, dried drugs must be protected
from moisture during storage
B. Freeze-drying
Freeze-drying (lyophilization) is a very mild method.
Frozen material is placed in an evacuated apparatus which has a
cold surface maintained at -60 to -80 °C. Water vapor from the
frozen material then passes rapidly to the cold surface.
The method requires a relatively complicated apparatus and is much
more expensive than hot-air drying. For this reason, it is not used as
a routine method, but it is very important for drying heat-sensitive
substances, e.g. antibiotics and proteins.
Fermentation
Enzymic transformation of the original plant constituents is
sometimes desirable.
The fresh material is then placed in thick layers, sometimes
covered and often exposed to raised temperatures (30-40 °C) and
humidity, so as to accelerate the enzymic processes. (This
treatment is usually called fermentation).
The fermented product must, of course, be dried afterwards to
prevent attack by microorganisms, e.g. moulds.
Fermentation is mostly used to remove bitter or unpleasant-
tasting substances or to promote the formation of aromatic
compounds with a pleasant smell or taste.
It is mainly applied to drugs used as spices or stimulants, e.g.
vanilla, tea and cacao.
 GRINDING

Regardless of whether the crude drug is to be used for isolation of
a pure compound or for manufacture of a simple preparation, the
first operation that must be performed is grinding of the plant
material to a powder of suitable particle size.
It is important that the particles are of as uniform a size as
possible. Large particles take a longer time for complete
extraction than small ones and large differences in particle size
thus slow down the extraction process.
Several types of machines are available for grinding crude
drugs:
1. Hammer mill; a common type for grinding crude drugs.
2. Knife mill; is useful for production of low-dust powders
of leaves, barks and roots for subsequent percolation or
maceration.
3. Tooth mill; is used for production of very fine powders.
4. Blenders
Grinding produces a certain amount of heat which must be
observed when grinding crude drugs containing heat-sensitive
compounds.

Mills cooled with liquid nitrogen are available for such
purposes.

Cold grinding is also preferable for crude drugs containing
volatile oils.
 EXTRACTS

Extracts can be defined as preparations of crude drugs which
contain all the constituents which are soluble in the solvent used in
making the extract.
In dry extracts all solvent has been removed.
Soft extracts and fluid extracts are prepared with mixtures of water
and ethanol as solvent.
Tinctures are prepared by extraction of the crude drug with five to
ten parts of ethanol of varying concentration, without
concentration of the final product.
For both extracts and tinctures the ratio drug/solvent should always
be stated.
Several factors influence the extraction process.
Plant constituents are usually contained inside the cells. Therefore,
The solvent used for extraction must diffuse into the cell to
dissolve the desired compounds whereupon the solution must pass
the cell wall in the opposite direction and mix with the
surrounding liquid.
An equilibrium is established between the solute inside the cells
and the solvent surrounding the fragmented plant tissues.
The speed with which this equilibrium is established depends on:
1. Temperature
2. pH
3. Particle size
4. The movement of the solvent
 CHOICE OF SOLVENT

The ideal solvent for a certain pharmacologically active constituent
should:
1. Be highly selective for the compound to be extracted.
2. Not react with the extracted compound or with other compounds
in the plant material.
3. Have a low price.
4. Be harmless to man and to the environment.
5. Be completely volatile.
6. According to the pharmacopoeias, ethyl alcohol is the solvent of
choice for obtaining classic extracts such as tinctures and fluid,
soft and dry extracts
The ethanol is usually mixed with water to induce swelling of the
plant particles and to increase the porosity of the cell walls
which facilitates the diffusion of extracted substances from inside
the cells to the surrounding solvent.
For extraction of barks, roots, woody parts and seeds the ideal
alcohol/water ratio is about 7:3 or 8:2. For leaves or aerial green
parts the ratio 1:1 is usually preferred in order to avoid extraction
of chlorophyll.
 PROCESSES FOR THE EXTRACTION
There are many procedures for obtaining extracts such as:
1. Infusion
2. Maceration
3. Percolation
4. Digestion
5. Decoction
6. Continuous hot extraction
7. Solvent-solvent precipitation
8. Liquid-liquid extraction
1. INFUSION
In this method the plant material (herbal tea) is placed in
a pot and wetted with cold water. Immediately afterwards
boiling water is poured over it, then left to stand covered
with a lid, for about fifteen minutes after which the tea is
poured off.
2. MECERATION
This method is used frequently for water soluble active
constituents. It consists of mecerating the plant material in
cold water for several hours.

3. PERCOLATION
In this method the ground plant material is subjected to a
slow flow of fresh solvent.
4. DIGESTION
This method is suitable for hard barks or woods which are
difficult for water to penetrate. Digestion is also considered
as meceration but at a relatively elevated temperature. As a
general rule the temperature of the extracting medium
should be in the range from 35-400 but not exceeding 500.

5. DECOCTION:
If the plant material is boiled for ten minutes or if boiling
water is poured over it and allowed to stand for thirty
minutes the result is called decoction.
6. CONTINUOUS HOT EXTRACTION METHOD
This procedure is considered as the most common method
used for extraction of organic constituents from dried plant
tissue. It can be used both on laboratory andd industrial
scales. In lab the powdered material is continuously extracted
in a Soxhlet apparatus with a range of solvents of
increasingly polarity.
7. SOLVENT-SOLVENT PRECIPITATION
1. The extract dissolved in a suitable solvent is mixed with a less
polar but miscible solvent causing the selective precipitation of
the less soluble plant constituent, e.g. precipitation of
triterpenoid saponins from methanol extract of Phytolacca
dodecandra by the addition of acetone and the precipitation of
gum from aqueous extracts of Olibnum by the addition of
alcohol.
2. By the addition of the extract to a solvent in which the
constituent is insoluble or very sparingly soluble, e.g.
precipitation of resins from the alcoholic extracts by the
8. LIQUID-LIQUID EXTRACTION
This method is also known as Solvent extraction and
Partitioning, and is used to separate compounds based on
their relative solubilities in two different immiscible liquids,
usually water and organic solvent. It is an extraction of a
substance from one liquid phase into another liquid phase.
This is a basic technique in phytochemical laboratories,
where it iss performed using a separating funnel.
 AN INTRODUCTION TO
CHROMATOGRAPHY AND
CHROMATOGRAPHIC TECHNIQUES
The study of chromatography has become prominent as a means
of separating and analyzing organic and inorganic materials.
Large amounts as well as micro quantities may be employed, and
the analyses may be conducted either qualitatively or
quantitatively. Chromatographic methods are often more effective
than other means of separation of drug principles. Such
techniques are of wide application in research in pharmacognosy
involving the determination and purity of drugs and derivatives of
natural origin as well as in pharmaceutical research and
manufacturing processes.
Chromatography is a combination of two words;* Chromo –
Meaning color* Graphy – representation of something on paper

DEFINITION“ It is a physical separation method in which the
components of a mixture are separated by differences in their
distribution between two phases, one of which is stationary
(stationary phase) while the other (mobile phase) moves through
it in a definite direction. The substances must interact with the
stationary phase to be retained and separated by it.
Chromatography is also defined as a method of analysis in
which the flow of solvent or gas promotes the separation of
substances by differential migration from a narrow initial zone in
a porous medium.
 CHROMATOGRAPHY TERMS
Chromatogram: It is the visual output of the chromatograph.
Chromatograph: It is equipment that enables a sophisticated
Separation.
Stationary phase (bounded phase): It is a phase that is
covalently bonded to the support particles or to the inside wall
of the column tubing.
Mobile phase: It is the phase which moves in a definite
direction.
Analyte (Sample): It is the substance to be separated during
chromatography.
Eluate: It is the mobile phase leaving the column.
 Retention time: It 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.
Eluent: It is the solvent that will carry the analyte.
Retardation factor ( R ): Fraction of an analyte in the mobile
phase of a chromatographic system.

R = Quantity of substance in mobile phase
Total quantity of the substance in the system

 Types of Chromatography
According to mechanism of separation chromatography is of four
types
1) Ion-exchange chromatography
2) Affinity chromatography
3) Size-exclusion chromatography
4) Adsorption chromatography
ION-EXCHANGE CHROMATOGRAPHY
It is a process that allows the separation of ions and polar molecules
based on their charge.
DEFINITION: In this type of chromatography, a resin (the stationary
solid phase) is used to covalently attach anions or cations onto it. Solute
ions of the opposite charge in the mobile liquid phase are attracted to the
resin by electrostatic forces. Ion exchange chromatography is performed
in columns but can also be useful in planar mode.
PRINCIPLE: Ion - exchange chromatography retains sample molecules
on the column based on ionic interactions. The surface of stationary
phase displays ionic functional groups (R-X) that interact with analyte
ions of opposite charge.
MECHANISM: 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 which interact with oppositely charged groups of
the compound to be retained. Ion exchange chromatography is
commonly used to purify proteins.
Cation exchange chromatography retains positively charged cations
because the stationary phase displays a negatively charged functional
group.
Anion exchange chromatography retains anions using positively
charged functional group.
APPLICATIONS:
It can be used for almost any kind of charged molecule including
large proteins, small nucleotides and amino acids.
Protein purification
Water analysis
Quality control
AFFINITY CHROMATOGRAPHY
This is the most selective type of control chromatography. It is a method
of separating biochemical mixtures and based on a highly specific
biological interaction such as that between antigen and antibody, enzyme
and substrate, or receptor and ligand.
DEFINITION: “It utilizes the specific interaction between one kind of
solute molecule and a second molecule that is immobilized on a
stationary phase”. For example, the immobilized molecule may be an
antibody to some specific protein. When a solute containing a mixture of
proteins are passed by this molecule, only the specific protein is reacted
to this antibody, binding it to the stationary phase. This protein is later
extracted by changing the ionic strength or pH.
PRINCIPLE:
The stationary phase is typically a gel matrix (often agarose). The
molecule of interest has a known and defined property. The process is an
entrapment in which the target molecule becomes trapped on stationary
phase. The Stationary phase can then be removed from the
Chromatography mixture, washed and then target molecule is released
from the entrapment.
APPLICATIONS:
Purify and concentrate an enzyme solution
Purification of recombinant proteins
Purification of antibodies
SIZE-EXCLUSION CHROMATOGRAPHY The technique was
invented of antibodies by Grant Henry Lathe and Colin R Ruthven. They
later received the John Scott Award for this invention. It is a
chromatographic method in which molecules in solution are separated by
their size, and in some cases molecular weight. It is usually applied to
large molecules or macromolecular complexes such as proteins and
industrial polymers.
DEFINITION: It is also known as gel permeation or gel filtration
chromatography. This type of chromatography lacks an attractive
interaction between the stationary phase and solute. The liquid or
gaseous phase passes through a porous gel which separates the molecules
according to its size. The pores are normally small and exclude the larger
solute molecules, but allows smaller molecules to enter the gel, causing
them to flow through a larger volume. This causes the larger molecules to
pass through the column at a faster rate than the smaller ones.
 PRINCIPLE: 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.
APPLICATIONS: Purification and analysis of synthetic and
biological polymers, such as; Proteins, Polysaccharides, Nucleic acids.
It is also useful for determining the tertiary structure and quaternary
structure of purified proteins. It is generally a low-resolution
chromatography technique and thus it is often reserved for the final
“polishing” step of purification.
ADSORPTION CHROMATOGRAPHY
DEFINITION: “It is a type of chromatography in
which a mobile liquid or gaseous phase is adsorbed onto the
surface of a stationary solid phase. The equilibration between
the mobile and stationary phase accounts for the separation of
different solutes.”
 PRINCIPLE:
Principle involves competition of components of sample mixture
for active site on adsorbent. These active sites are formed in molecule
due to *Cracks and *Edges. The electrostatic forces present in the
molecule, which hold together the crystal lattice, are directed outward.
These forces and electrostatic forces of solute molecule cause
separation. Separation occurs because of the fact that an equilibrium is
established between molecules adsorbed on stationary phase and those
which are flowing freely in mobile phase. The more the affinity of the
molecule of particular component, less will be its movement.
 TYPES:
Adsorption chromatography is of three types
1. Column chromatography
2. Thin layer chromatograph
3. Gas chromatography
ADSORBENTS: “An adsorbent is a substance, usually porous in nature
and with a high surface area that can adsorb substances onto its surface
by intermolecular forces.”

AN IDEAL ADSORBENT: The Ideal adsorbent must fulfill the
following requirements:

Insoluble in mobile phase
Inert to solutes (adsorptive)
Colorless especially when work with colored mixtures
Suitable particle size enough to give good separation and reasonable
flow rate
Column chromatography
Column chromatography has been defined as uniform percolation of
fluid through a column of more or less finely divided substance which
selectively retards certain components of the fluid.
In this method many adsorbents have been used such as sucrose, talc,
calcium or sodium carbonate, silicic acid and activated alumina. Solvents
include petroleum ether, carbon tetrachloride, carbon disulphide, ether
acetone, alcohol, water, and mixtures of acids and bases in water, alcohol
and pyridine. The adsorbent is packed uniformly into a suitable glass
tube and the solution of the drug or substance in a small amount of
solvent is passed through a column.
COMMON ADSORBENTS:
Hydrated silica gel
Silica gel G
Silica gel S
Silica gel GF 254
Silica gel H
Silica gel N
Silica gel HF 254
Silica gel PF 254
Cellulose microcrystalline
In pharmacognosy column chromatography is used where large quantities
of the material to be tested are available. Thin layer and paper
chromatography are preferred for purposes of identification because of
their selectivity, convenience and adaptability, to small quantities of
material.

A modification of the column method is known as a Flowing
chromatogram. In this method the liquid is allowed to flow continuously
through the column until the separated substance appears in the
discharged solution. It is then identified either as the solution or as the
evaporated material.
THIN LAYER CHROMATOGRAPHY
Thin Layer chromatography is a modification of the paper
chromatography and this was originated by a German pharmacognosist
Professor Egon Stahl in 1956. It is characterised by the application of dry
finely powdered adsorbent in a thin uniform layer to a glass plate. This
coated plate is comparable to an open chromatographic column and the
separation of components in the test material is based on adsorption,
partition or a combination of both, depending on the adsorbents and the
solvents used.
For Two dimensional thin layer chromatography the glass plate is
turned at a right angle and again the entire process is repeated using the
second solvent.
PARTITION CHROMATOGRAPHY
In this process two immiscible liquids are used one representing an
immobile phase the other a mobile phase.

It is a process for the separation of mixtures in columns or on filter paper
based on partition of a solute between two solvents one of which is
immobilized by the substance in the column or by the paper. Separation
of components of a sample mixture occurs because of partition.
Stationary phase is coated with a liquid which is immiscible in mobile
phase. Partition of component of sample between sample and liquid/ gas
stationary phase retard some components of sample more as compared to
others. This gives basis for separation. The stationary phase immobilizes
the liquid surface layer, which becomes stationary phase. Mobile phase
passes over the coated adsorbent and depending upon relative solubility
in the coated liquid, separation occurs. The components of sample
mixture appear separated because of differences in their partition
coefficient.
 Gas Chromatography
Gas chromatography is a specific method in which the moving
phase is gas. It is of two types: Gas-liquid chromatography
and Gas-solid chromatography, the difference being the type
of stationary phase over which the gas flows. In gas-liquid
chromatography, the immobile liquid phase consists of a thin
film adhering to a finely divided solid support that does not
retard the drug mixture from passing through. Crushed fire
brick may be employed as the solid support.

In gas-solid chromatography the immobile solid phase is
represented by an active adsorbent, such as aluminia, silica gel,
or carbon which adheres to the support.
PAPER CHROMATOGRAPHY
Paper chromatography is more popular than column chromatography.
Two techniques may be employed: the descending and the Ascending
depending upon whether the mobile phase moves downward or upward
on the chromatographic paper. In paper chromatography, the sample
mixture is applied to a piece of filter paper, the edge of the paper is
immersed in a solvent, and the solvent moves up the paper by capillary
action. Components of the mixture are carried along with the solvent up
the paper to varying degrees. The paper is composed of cellulose to
which polar water molecules are adsorbed, while the solvent is less polar,
usually consisting of a mixture of water and an organic liquid. The paper
is called the stationary phase while the solvent is referred to as the
mobile phase.
Performing a chromatographic experiment is basically a three-step
process:
1.application of the sample,
2. “developing" the chromatogram by allowing the mobile phase to move
up the paper
3. calculating Rf values and making conclusions.
The ratio of the distance travelled on the paper sheets by the test
substance to the distance travelled by the front of the mobile phase from
the point of application of the test substance is termed the Rf value of the
substance. The resulting spots or pattern of distribution on the paper is
called the chromatogram.
A modification of the paper chromatographic method is the two
dimensional separation of a sample by using another solvent on the
same chromatogram. Another chamber is prepared the chromatogram is
turned at a right angle and the entire process is repeated using the
second solvent.
When the substance to be analysed is vaporized and introduced into the
moving gas phase it is carried into the column and is distributed
between the gas and the stationary phase (liquid or solid) on which it is
dissolved or adsorbed. The efficiency of this method depends on the
number of factors: the specific solute, the type of liquid solvent or solid
adsorbent, the temperature at which the procedure is conducted and the
rate of gas flow.