Phytochemistry Lecture 3 PDF

Summary

This document provides a lecture on Phytochemistry, focusing on the chemistry of volatile oils. It details the composition of these oils and methods for removing volatile compounds. Chemical structures and diagrams are prominently featured. This would be useful supplementary information on volatile oils.

Full Transcript

Phytochemistry

Lecture 3
Composition of Volatile oil

Volatile oils are a complex of organic compounds

Hydrocarbons (mono & sesquiterpenes),

Oxygenated compounds (alcohols, esters,
aldehydes, ketones)

Aromatic benzenoids

Compounds containing sulfur or nitrogen

Oxygenated compounds are responsible for the
volatile oils’ odor
 Removal of Terpenoid Hydrocarbons (Preparation
of Terpeneless Oil)
Oils with high percentage in terpenoids are:

Liable to rapid deterioration on storage through oxidation
and polymerization to yield bad smelling (turpentine odor)
Having less aroma
Less soluble in low-strength alcohols
Resenify rapidly

Terpene-less oils are expensive because they are:
More stable
More soluble in low strength alcohol
Smaller amount used to give the same strength of aroma
Richer in oxygenated compounds
Thus, a considerable amount of the terpenoid
hydrocarbons could be removed by:

1-Fractional distillation under reduced pressure;
hydrocarbons have lower boiling points and
therefore, distill first and are discarded.

2-Column chromatography on silica gel, by eluting
hydrocarbons with n-hexane then oxygenated
compounds with absolute alcohol.

3-Selective extraction of the oxygenated
components by dilute alcohol followed by distillation.
 Terpenoids
Terpenoids were proved to be synthesized from
Isoprene.

Isoprene is also known as isopentene or 2 methyl-buta-
1: 3-diene

The isoprene units are branched five-carbon units
containing two unsaturated bonds.

Each group of terpenes arises from the head-to-tail
condensation of a variable number of isoprene units
Abbreviated
structure
1 h h=head, t=tail
4
t
2
3
Isoprene, 2-methyl 1:3 butadiene, isopentene
 CH2 h
║
CH2 C
C
CH3

isoprene
t
H= head
T= tail

║
 Metamenthane
Isoprene Acyclic Paramenthane
monoterpenoid C10 Monocyclic
Monoterpenoid C10

Bornane Fenchane iso-
Thujane Carane Pinane
(Camphane) Camphane
Bicyclic monoterpenes (C10)
Isoprene

Isoprene

Isoprene
Acyclic sesquiterpene

Monocyclic sesquiterpene
Sesquiterpenes (C15)
 Terpenoids in essential oils
Monoterpenoids (C10H16) Volatile
Sesquiterpenoids (C15H24) low mol weight

They may be: -Acyclic (aliphatic)
-Alicyclic (cyclic)
-Hydrocarbons (90% of Citrus oil)
-Oxygenated (alcohols, aldehydes,
ketones, esters, ethers, oxides or peroxides)
-They are optically active

Compounds arising from terpenes degradation:

Ionones (from oxidation of carotenes)
Irones (from oxidation of bicyclic triterpenes)
 Phenyl propanoids in essential oils

They are natural products found in various volatile
oils, with 6-carbon aromatic phenyl group & 3-carbon
propene tail
They exhibit pharmacological activities and have
applications in pharmaceutical industry

Volatile oil isolates:

1-Hydrocarbons.
2-Alcohols.
3-Phenols and phenolic ethers.
4-Aldehydes and ketones.
5-Oxides and Peroxides.
6-Esters.
7-Organo-nitrogen and organo-sulphur compounds
 1-Hydrocarbons in volatile oils

Hydrocarbons or unoxygenated constituents detected in
volatile oils belong mainly to the following groups:

1.Acyclic mono-and sesqui-terpenoids.

2.Alicyclic mono-and sesquiterpenoids
✓ Monocyclic monoterpenoids
✓ Bicyclic monoterpenoids
✓ Monocyclic sesquiterpenoids
✓ Bicyclic sesquiterpenoids
✓ Tricyclic sesquiterpenoids

3. Aromatic hydrocarbons
 1. Acyclic terpeniods
A-Acyclic monoterpenoid hydrocarbons

h

t Myrecene Ocimene

oil of hops (Humulus
lupulus, Cannabinaceae). And oil of oils of Ocimum basilicum
bay (Myrcia acris, Myrtaceae) or
Pimenta racemosa
Isolation
Since the oils are rich in phenolic cmpds.
+ NaOH H2O soluble phenates
Then, separate non-phenolic fraction (oily layer)
Fractional distillation individual hydrocarbons
 B-Acyclic Sesquiterpenoids hydrocarbons

Sesquicitronellene
Farnesene
oil of
oil of hops (Humulus citronella (Cymbopogon
lupulus, Cannabinaceae). nardus, Gramineae).

** Farnesene is Considered as the Sesquiterpene
analogue of myrecene

Myrecene KMnO4
& farnesene
Oxidation
 2- Alicyclic terpenoid hydrocarbons

Monoterpenes

Monocyclic Bicyclic
monoterpenoid Monoterpenoid
hydrocarbons Hydrocarbons

Sesquiterpenes

Monocyclic Bicyclic Tricyclic
i-Monocyclic monoterpenoid hydrocarbons
d-Limonene
Occurs in (citrus oils e.g. oils of orange (90%), lime,
grapefruit, bitter orange (oil of neroli), mandarin,
bergamot)

l-limonene
In turpentine oil Limonene and
Dipentene
Dipentene (dl- form) “racemic”
Occurs in oil of turpentine, lemon grass, pepper,
nutmeg, neroli, fennel and turpentine

Limonene could be isolated from orange oil by:

Fractional distillation of the oil, and collection of the
fraction at 176ºC.
Uses:
Limonene & dipentene are widely used as:

1-Flavoring agents for cosmetics, soaps &
pharmaceuticals

2-Substitutes for preparation of orange oil

3- Together with other V.O. constituent in aqua
cool syrup used as antiflatulence and antispasmodic.

* Toxicity: Skin irritant and sensitizer
 Hot mineral
Heat with S acids
isomrization
p-Cymene dehydrogenation
Limonene
& Dipentene ┼

Air & moisture p-Cymene
(in orange oil) α-Terpinene
Cold
mineral
acids
┼

Carvone Carveol
Terpine hydrate Terpineol
*in badly stored orange oil
by auto oxidation Caraway-like odor
ii-Bicyclic monoterpene hydrocarbons
Parent classes

Fenchane
Carane Pinane Bornane
Thujane (Camphane)

Have tendency to undergo:

a)- molecular rearrangement (pinane camphane)
b)- shifting of double bond
c)- oxidation, hydrogenation, dehydrogenation
d)- opening of the rings on treatment with acids
monocyclic monoterpenes
ii-Bicyclic monoterpene hydrocarbons
A-Thujane derivatives
Sabinene: It is obtained from oils
of savin (Juniperus sabina, Pinaceae, 30%) by
fractional distillation
On exposure to air and light, it yields α-thujene due
to shift of the double bond.

On treatment with acids, rapid opening of the second
ring cycle occurs

Cold dilute acids produce terpineol and/or terpin
hydrate.
Boiling with dilute H2SO4 results in formation of α -
terpinene
 (+) Sabinene

bioling with dil. H2SO4
cold dil. acids

α-Terpinene Terpineol

Terpin hydrate
α -Thujene
 B-Pinane derivatives
α-and β-Pinenes

(+)–ß-pinene (+)-α-pinene

α-Pinene
(main constituent in oil of turpentine)
-l-form(French oil of turpentine)
-d-form(American oil of turpentine)
-Obtained from oil by Fractional distillation
Uses: starting material for semi-synthesis of camphor,
borneol and terpineol
 HCl gas
Isomerization

Molecular
-10oC
Rearangement
Bornyl chloride
Pinene Pinene hydrochloride

KOH HNO3

Oxidation

Borneol Camphor

Auto-oxidation

Sobrerol
(Pinol hydrate)
(+)–ß-pinene (+)-α-pinene (Mucolytic)
Derivatives of pharmaceutical importance

Sobrerol or pinol hydrate, used as mucolytic in cough
mixtures
is formed by auto-oxidation of α-pinene in the presence
of water and especially in sunlight.

α-pinene is also incorporated in Bilichol cap
For bile therapy and acts as cholagogue
iii-Monocyclic sesquiterpenoid hydrocarbons

Zingiberene is the main constituent
of ginger oil (Zingiber officinalis,
Zingiberaceae)

Zingeberene
It is obtained from ginger oil by
fractional distillation under vacuum
(due to its high boiling point).

S / Heat

Zingiberene Cadalene
iv-Bicyclic sesquiterpenoid hydrocarbons

Naphthalene derivatives
It is obtained from oils of cade, savin,
cubebs, lemon grass etc…by fractional
distillation under vacuum
ß-Cadinene

S/heat
S/heat

Zingiberene Cadalene (aromatic HC) ß-Cadinene
Uses

It is occasionally used in perfuming soaps to give a
gin-like flavor.
Oil of cade itself has been used as anti-eczematic.

v-Tricyclic sesquiterpenoid hydrocarbons

Santalene

It is obtained by repeated fractional distillation
of Sandal wood oil.
 3. Aromatic Hydrocarbons
A-P-Cymene
Source

This compound is widely spread in essential
oils such as those of lemon, sage, thyme,
Origanum, lavender, nutmeg, cinnamon etc…
p-Cymene
It is probably an artifact formed during Para-cymene
hydro distillation by cyclization, (or Cymol)
dehydrogenation or reduction of
monoterpenoids.

Prepared by fractional steam distillation.
Used for perfuming soaps
 Semi-synthesis

1.
Reduction Se/heat

Or S / heat

Thymol p-Cymene
Limonene

2. Cyclic monoterpenoid hydrocarbons e.g. limonene,
pinene and terpinene yield p-cymene on
dehydrogenation by heating in presence of S or Se.

3. Oxygenated monoterpenoids e.g carvone and citral
yield p-cymene on dehydrogenation and cyclization.
B-Azulene derivatives (C15H18)
They are highly conjugated (colored) found in
pigments of Mushrooms, guaiac wood oil,
some marines
Mostly occur as colorless precursors called pro-azulenes

Isolation: through adduct formation with mineral
acids(≠H2O)

The parent hydrocarbon is azulene, C10H8.

The naturally occurring azulenes are substituted with
alkyl groups and are C15 compounds(closely related to
sesquiterpenes)

Exhibit anti-inflammatory & anti-ulcerative effects
 Azulene
Chamazulene Guaiazulene

gives the blue color From dehydrogenated
From decomposition of of oil of chamomile Guaiacum wood oil
matricin

Uses of Chamazulene:

Chamazulene is widely used in cosmetic preparations, as
anti-inflammatory and mild antiulcerative.
The volatile oil of chamomile is used in GIT disturbances
and has spasmolytic properties.
The ulcer protective properties are mainly attributed to its
bisabolol and bisabolol oxide content.