Phyto-I (introduction) 24-25abeeer.pdf

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PHYTOCHEMISTRY- I PGC 504
Prof. Dr. Abeer M. El-Sayed

1
 Pharmacognosy: The knowledge of drugs, which provide
scientific description of drugs of natural origin used in medicine
Drugs are of:
-Natural origin: plants, animals, minerals
-Synthetic origin
Phytochemistry is the study of
phytochemicals. Those derived from
plants, mainly large number of 2ry
metabolites found in plants.
Many of these are known to provide: protection
against insect attacks, plant diseases and exhibit a
number of protective or healing
effects for human consumers.
 Plant constituents
(Organic substances formed & accumulated by plants)

Primary metabolites are commonly present in all organisms and are
essential for life (carbohydrates, proteins, fats, nucleic acid, vitamins)
(* Rare fatty acids or sugars also considered as 2ry metabolites)

Secondary metabolites are
* Found in specific organisms or gp. of organisms
* Pharmacologically active constituents
 Plant constituents
Factors influencing production of 2ry metabolites:
1- Gene composition (Heredity) →
Qualitative & Quantitative changes
2- Stage of development (Ontogeny) →
Quantitative changes
3- Environmental changes → Quantitative changes
Different forms of Plant products supplied based
1- The purpose of use,
2- The nature of the active ingredients,
3- Some economic factors
Different forms of Plant products
1- Fresh plant materials:
In Trad. medicine, used as flavor & perfumery industries
2- Dried plant materials
Used as Flavoring agents, spices & drugs.

3- Acellular products (unorganized drugs)
e.g., gum exudates, resins, balsams, fixed & volatile oils
4- Galenical preparations For direct use
e.g., plant extracts or tinctures
5- Processed extracts i.e., standardized extracts
(with known concn. of the active principle)
6- Pure compounds most desirable for pharm. form.
* Of known quality, safety and efficacy
 Role of Natural Products in Modern Medicine
Nat Prod have significant role in modern medicine due to:
1- Provide useful drugs:
that cannot be commercially produced by synthesis e.g.,
Opium & Ergot alkaloids, * cardiac glyc. * Antibiotics
2- Supply semisynthetic comps:
by modification→more effective or less toxic drugs
e.g., morphine analogues based on SAR
3- Used as template: to produce synthetic analogues
through drug design e.g., procaine & related local
anesthetics
4- As starting materials for production of more potent drugs
(chemically or by biotransformation from less or inactive
one) e.g., -Baccatin III → taxol
-Stigmasterol→ hydrocortisone & related steroids.
 Classification of plant constituents (PC)
Classification is based on:
1→ Biosynthetic origin
2→ Solubility properties
3→ Presence of key functional gps (widely used).
OR 1 and 3
4→Physicochemical properties.
5→Pharmacological activities.
Based on Key functional groups
1.Phenolic compounds
e.g., flavonoids, tannins, quinones, anthocyanins,..
- Precursor → shikimic acid
- Hydrophilic
- with at least one aromatic ring (with 1 or more oxygenation site)
 Classification of plant constituents (PC)

2.Terpenoids
e.g., vol. oils, sterols, carotenoids

- Precursor → isopentenyl pyrophosphate (isoprene)
- Lipophilic

- Sub classified acc. to No. of isopentene units (=isoprene, C = 5):
Monoterpenes (C = 10) in V.O.
Sesquiterpenes (C = 15) in V.O.
Diterpenes (C = 20), in plant families
Triterpenes (C = 30), in plant families
Tetraterpenes (C = 40), carotenoids.
 Classification of plant constituents (PC)
3- Nitrogen containing compounds
Amino acids, peptides, alkaloids
- Precursor → different amino acids
- Basic in nature
- +ve reaction to either ninhydrin or Dragendorff`s reagents
4- Organic acids, lipids and related compounds
e.g., Simple organic acids (citric, malic, etc..) Fatty acids (as FA ester in the
form of fixed oils, fats or waxes)
Other compounds (alkanes, polyacetylenes)
- Precursor → acetate - Of varying solubility

5- Water-soluble carbohydrates & their derivatives:
mono- & oligosaccharides, water soluble glycosides

6- Macromolecules
Of high M. wt., nucleic acids, proteins, polysacch.
Classification according to chemistry & common
physical properties

1. Volatile oils, Resins & Resin combinations
2. Carbohydrates
3. Bitter Principles = Bitters
4. Tannins
5. Alkaloids
6. Glycosides
Based on Pharmacological activity
Analgesics, emetics, diuretics, laxatives, cardiotonics etc….

11
Nomenclature of plant constituents (Trivial)
The root names derived from:
1- Name of discoverer, e.g., Pelletierine
2- Plant common name, e.g., Vinca (vincristine, vinblastine)
Ergot (ergometrine, ergotamine)
3- Plant Latin name, e.g. (Podophyllotoxin, Visnagin, Digitoxin)
4- The pharmacological action, e.g., emetine

Prefixes Suffixes
(indicate compds. Derived from others,) (added to root name, to indicate,
1- hydroxy- , methoxy- , methyl- , 1- -in a “constituent of”
dihydro- , homo-, for added 2- -oside, sugar deriv. (glycoside)
substitutions 3- -genin, aglycone
2- Deoxy- , demethoxy- , demethyl- 4- -toxin,poisonous constituent
, dehydro- , nor-, for removed 5- -one, -al, -ol
substitutions
Phytochemistry concerns with Plant constituents from

Physical, chemical, structure & of 2r metabolites
(Natural drugs)
biosynthesis of phytochemicals

Techniques commonly used in the field of phytochemistry
are extraction, isolation using various chromatographic
techniques (MPLC, HPLC, LC-MS) & structural elucidation
(MS,1D and 2D NMR) of natural products.
 Extraction, isolation, characterization &
quantitative evaluation of plant
constituents

The Role of Phytochemist is to focus on the
Isolation Identification,
Chemical structures, Methods of evaluation
Biosynthesis, Metabolism
Distribution Biological function
OF Phytochemicals
Therefore, Isolation of pure Phytochemical is the
most important step

Extraction of the plant material
There are medicinally desired and undesired plant
constituents (PC) or phytochemicals.
Therefore, extraction & fractionation of
plants guided by biological activity rather
than on chemistry of comps is best
approach.
Extraction could be defined as “the process,
which involves withdrawal of the desired AC from the
crude drugs by the use of selected solvent and
procedure.

Preparation of plant material for extraction
❑Plant material (PM) should be authenticated
❑PM should be free from adulterants or
contaminants.
❑PM should be subjected to deactivation of
enzymes.
❑PM could be extracted fresh or dry.
❑PM should be kept in dry weather till extraction
Selection of: ►Mode of EXTRACTION
►SOLVENT
Role of solvent of choice is to dissolve or extract
Desired or Active PC (?) OR remove Inactive or
Inert PC (?).
❑ Polar solvents extract or dissolve polar comps. e.g.,
sugars, alkaloids, salts.
❑ Non-polar solvents extract or dissolve non-polar
comps. e.g., fats, waxes, oils.
❑ Factors affecting solubilization of PC
Polarity of the solvent H-bonding
Chemical nature of PC Dipole-dipole forces
Less polar: Cyclohexane, hexane, CCl4 Benzene,
CHCl3, EtOAc, acetone, EtOH, MeOH, H2O,
acid. H2O Most polar.

Notes
 Solubilization of certain types of comps is enhanced by their
ability to H-bonding with solvent molecules.
 The affinity of the solute for the org phase may be increased
by using mix of solvents.
 Fractionation between different solvents leads to better
isolation.
 Knowing the chemical nature of PC may help in the choice of
suitable solvent.
 Methods for extraction
Classical extraction :
1- Extraction with organic solvents: percolation,
maceration.
2- Extraction using a Soxhlet apparatus; and
3- Extraction with water: infusion, decoction, and
steam distillation.

Specific old method is the Extraction with cold
fat, called enfleurage, used mainly for the
extraction of fragrances (V.O.) from flowers
Shaking, stirring or homogenization could be
applied to increase efficiency of extraction
 Methods for extraction
1- Mechanical pressing (no solvent)
It is used to extract fixed oils using a hydraulic
press. The yield is affected by the moisture
content of the seeds and temperature.

2-Maceration: PM to be extracted is
immersed in suitable solvent for 3 days
at room temp. with continuous agitation,
then filter.
3–Percolation: It is maceration followed
by a continuous slow flow of fresh
solvent through PM (using percolator).

4-Digestion:Maceration with gentle heat
to increase solvent efficiency and NOT
affect PC.
5-Infusion: It is a maceration for a short period of time with
either cold or boiling water. Used for readily water-
soluble PC.

6-Decoction: It involves boiling PM with water for 15
min, filter. Used for thermostable water-sol PC.
 7-Continuous hot extraction

“Soxhlet extractor”
 The PM is repeatedly extracted with
solvent & the dissolved PC are
concentrated in the extraction flask.
 Used for thermostable PC
 In case of thermolabile PC, a low-
boiling point solvent is used
8- Ultrasound-assisted extraction (UAE)
-High temp from ultrasonic energy increase solubility &
diffusivity of PC in solvent.
-The oxidative energy from radicals created during sonolysis,
increases the extraction power.
-Also, application of pressure could favor penetration and
transport at inter-phase between the solvent & PM.
Application:
Extraction of plant
materials, isolation of
polysaccharides,
volatile oils, fatty
acids and their esters
9- Microwave-assisted extraction (MAE)
Extraction with MAE is based on
❑ Heating of the solvent in contact with sample by means of
microwave energy.
❑ Disruption of H-bonds by MW energy
❑ Heat generated by MW enhances solvent penetration into PM,
allowing better dissolution of the target comps.
Advantages:
Reduced solvent volume
High recoveries
Shorter time
Good reproducibility
Minimal sample manipulation.
Application: extraction of lipids, fixed oil, pigments, glycyrhizic acid
(liquorice), cocaine (coca leaves)& alkamides (Echinacea).
10-Pressurized liquid extraction (PLE)
PLE (= Accelerated solvent extraction, ASE)
It is based on static extraction with superheated liquids
under high pressure using organic solvent
Advantages:
 Higher solubility of solutes in solvent at higher temp
 Higher diffusion rate due to high temp,
 Disruption of the strong solute PM matrix interaction caused by Van
der Waals forces, H-bonding and dipole-dipole attractions between
solute molecules.
Application:
PLE is suited for the extraction of various types of comps from
different materials because you can change type of solvent and
pressure and adapted to the respective matrix.
11 - Supercritical fluid extraction (SFE):
Based on that Gases such as CO2 and N2O become
fluid when certain temp & pressure reached a critical
point called supercritical phase
Above a certain temp & pre, single sub do not condense or
evaporate but exist as a fluid; i.e., both gas & liquid possess
the same density and no division exists between two phases
“the critical state”, Gas become supercritical fluid.
Supercritical fluid is used to extract target subs
From solid samples.

https://youtu.be/oqP6r2RBNy4

Caffeine extraction from green coffee with supercritical CO2 - YouTube
 Advantages of the use of CO2
Available & inexpensive
Non-inflammable
Non-toxic
Has a low critical temp (tc31oC, Pc=74 bar)
Easy to eliminate
Chemically inert
Advantages of SFE technique
Extracted PC are of close composition to natural PC
The temp. & pressure can be changed, to adjust selectivity.
Extraction power can be modified by addition of a modifier
(MeOH) to increase the polarity.
The absence of hydrolysis, decomposition or
rearrangements of the extracted PC.
Alkaloids: Decaffeination of green coffee Caffeine extraction from green coffee
with supercritical CO2 - YouTube
Diterpenes: Extraction of Taxol from Taxus.
Fixed and V. oils: oil of evening primrose
12- Subcritical water extraction (SWE)
(Pressurized hot water extraction (PHWE)superheated water extraction)
It is based on the use of water as extractant in
a dynamic state, at temp 100 to 374°C but
below its critical point (< 374°C) and pressure
high enough to maintain water in liquid state.
https://extractionmagazine.com/2020/12/09/subcritical-water-extraction-of-
ashwagandha/ https://www.youtube.com/watch?v=TgAaI3FqElo

Rise of temp leads to increase in diffusion rate and
decrease in viscosity and surface tension.
Advantages:
Easy manipulation of dielectric constant () of water, which
can be changed within a wide range just by changing the
temp under moderate pressure.
 Subcritical water extraction (SWE)
E.g., at room temp and pre, H2O has a dielectric
constant () ca. 80 (polar solvent). Subcritical water at
250oC and pr over 40 bar, it has  = 27, of similar polarity of
EtOH.
This means we can change property of water to
be non-polar to extract even fixed or V. oils
Application:
❑Extraction of fixed and V.Oils.
❑Subcritical water (pre 125 bar 175ºC) extract rapidly
oxygenated fragrance comps from rosemary, leaving
monoterpenes, waxes and lipids.
13 - Extraction by distillation
Steam distillation (in details in V oils)

14- Spouted bed extraction
Production of annatto powder (coloring matter)
from the seeds of Bixa orellana present in the
pigment layer of seed coat by action of hot air
jet.

Collected seed coat

Seeds
v
Hot air jet
15- Solid Phase MicroExtraction
SPME is an extraction technique used for:
-Analysis of some V.O. containing drugs.
- In GC & LC analysis of dilute samples in both
liquid or gaseous phases.
Adsorptive phase: silicone derivative fibers

Injection
port
Liquid sample Volatile sample
adsorption of the sample
Adsorption and desorption of volatile sample
Advantages of SPME :
It can reduce solvent consumption,
Reduce plant mat., more rapid and reproducible,
Less opportunity for oxidation of vol. comps. 6399

16- Solid Phase Extraction (SPE)
SPE is a physical extraction process involving use of
solid phases, in pre-packed columns containing
stationary phases (of same nature in column) as in
001988

HPLC e.g., Bond ElutTM, Sep-PakTM, ….

The objective: to isolate or purify a sub or sample of
interest from a more complex sample in a pure conc. state, e.g
biological sample (urine, serum,..
 Fractionation of crude extracts by
liquid/liquid fractionation
To facilitate further isolation of their individual
compds.

A- Solvent/solvent precipitation
a)- Addition of less polar miscible solvent
e.g.,-Preparation of Crude saponin mix using
MeOH/acetone
- Purification of gum using water/MeOH.
b) Addition of a more polar miscible solvent,
e.g., Purification of resin using Alc/H2O or acid/H2O
 Fractionation of crude extracts by liquid/liquid fractionation

B- Liquid/liquid extraction:

(partition of solute moles. between two immiscible
solvents) based on: their relative solubility or partition
coefficient constant (K`)& polarity.
In the form:
B-1 Single contact (in a sep. funnel)
B-2 Multiple contact (CCE, DCCC or RLCCC)
 B-2 Multiple contact
B2-1.Counter-current Extraction (CCE):
Used for separation of PC with small differences in their partition coeff.
(K`) using special apparatus called:

Craig's counter-current apparatus“
Based on the same principle of liq/liq extraction (shaking)
Separation occurs in multiple process of partition and separation step-wise process in
hundreds of special tubes (Craig’s unit).

In a countercurrent extraction, the solvent and feed enter from
opposite ends of the system, and these two immiscible phases
pass each other in opposing streams.
Explain the Counter Current Extraction? | Solvent Extraction | Analytical Chemstry (youtube.com)

https://youtu.be/OUMWDLulK64
 B-2 Multiple contact
B-2-2 Droplet Counter Current
Chromatograph (DCCC)

B-2-3 Rotatory Locular Counter
Current Chromatograph (RLCCC)

DCC Principal

Advantages:
-It can be easily applied to separate of saponins (no foaming
due to shaking, cf. from CCE)
-NO solid support used for highly polar PC, e.g alkaloids,
tannins, iridoids, anthraquinones etc….
The Key step in phytochemical
Investigation of a PM is the
isolation and purification steps
of PC

Other methods can be applied to simplify or
isolate PC
See more …………
1)- Sublimation:
- Caffeinefrom tea
- Balsamic acids (benzoic & cinnamic acids)

2)- Fractional distillation: Separation of different components
of volatile oils
3)- Fractional liberation: (through pH gradient)
- Separation of a mixture of basic compounds (alkaloids), and
acidic comps (Phenolic acids and comps containing COOH).

4)- Fractional crystallization: acc. to the difference in
solubility in certain solvent.

5)- Chromatography using different techniques (Column, prep.
PC, TLC, HPLC, GC, & Specific techniques: ion exchange,
gel filtration, etc…..
Identification of plant constituents
Check for homogeneity & purity:
by repeated chromatography (TLC, PC, HPLC, mp)

Determination of the class of compound:
- Its response to color tests, derivatization to common
derivatives
- Its UV spectral analysis (eg. Flavonoids) data.
Identification within the class:
- Melting points (solids), boiling points (liquids)
- Optical rotation “for optically active compounds”
- Spectral characteristics: UV, IR, NMR & MS
Confirmation of identity:
- Direct comparison with an authentic sample (UV, IR, MP, D ) OR -
Comparison of its spectral data with published one
For new compounds → spectral data and degradation & Lab. synthesis
 Quantitative determination of plant constituents
Crude plant exts. shld. be standardized before use in therapy
Determination of total active const. by
(depending on the nature of the constituents)
1- Gravimetric methods (% recovery)

2- Titrimetric methods
* “acid-base det. of alkaloids in aq. or non-aq. media”
* “Redox determination of sugars and peroxides”.
3- Spectrophotometric methods
e.g., colorimetric methods.
4- Biological methods
Special methods for standardization of extracts contain toxic materials &
failed to be accurately evaluated with other methods → cardiac
glycosides.

5- Chromatographic techniques: ideal methods HPLC & GC.
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