Subterranean Organs 2024 (Complete) PDF

Summary

This document provides a comprehensive overview of subterranean plant organs, including roots and rhizomes. It details various types of underground organs, their functions, and their structures. Topics covered include different types of roots, zones of roots, their functions, and conditions affecting drugs of roots.

Full Transcript

Underground Organs
 Leaves
 Stems
 Flowers
 Roots
Drugs From Natural Plant Origin:
1. Organized Drugs (definite organs)
 Leaf
 Flowers
 Barks
 Fruits and Seeds
 Herb: when the active constituent distributed in all plant parts.

 Underground: when drugs derived from underground parts e.g.
Root and/or Rhizomes.

2. Unorganised Drugs
 The subterranean organs
comprise two types :
1- Stem origin: such as rhizomes, corms,
bulbs and tubers
2- Root origin: such as roots and root tubers.

Subterranean organs perform as storage organs for the
reserve material which required for the subsequent use of the
plant perenation and production of 2ry metabolites.
❖It is impracticable to classify the drugs of this class
separate roots and rhizomes, as in many herbaceous
plants the rhizome passes gradually into the root e.g.
Dandelion.
❖Many drugs of this class consist of portions of both
stem and root origins.
❖ in other plants as Valerian and Hydrastis both roots
and rhizomes are collected together.
❖Some drugs which are commonly spoken of as roots
consist partly or wholly of rhizome e.g. Gentian and
Rhubarb respectively.
❖ In many cases the transition from stem to root makes
an accurate differentiation of the two parts impossible.
The general characters of roots and rhizomes may
therefore be usefully discussed together.
 The Root
The root is the portion of the plant axis derived from the
radicals and grows towards the soil and water.
The roots are Characterized by:
 It never develops leaves.
 It shows no nodes and internodes.
 It bears no buds.
 Its growing point is covered by special tissue called root-cap or
calyptra.
 Unlike the stem, it shows no chlorophyll and has one kind of
lateral appendage which is similar in structure to the parent root
but differ in direction.
Composition of the root:
Root consists of four zones:
1. Zone of root cap (zone of
growing point).
2. Zone of cell division.
3. Zone of cell elongation.
4. Zone of cell differentiation
(zone of root hairs).
5. In Addition; Zone of lateral
branch.
Functions of the root:

1. Absorption of water, soluble minerals and organic

compounds form the soil and transportation of them

to the stem.

2. It Anchors the plant to the ground.

3. As storage organ and for propagation.
 Type of Roots
3

1. Primary roots: Developing into tap-root e.g.
Senega.
2. Secondary roots: Lateral branches of tap-root
4
e.g. Kremeria.
3. Adventitious roots: Arise from the stem e.g.
Ipecacuanha and Calumba.
4. Prop roots: Adventitious roots but arise from
the stem, above the soil and extending diagonally 5 1&2

into the soil e.g. Maize.
5. Fibrous roots: Very slender as in Grasses.
6. Aerial roots: Adventitious roots hanging
in the air or growing down to anchor in 6

the ground e.g. Ficus Bengalensis.
7. Respiratory roots: Growing from the soil
7
into air for respiration e.g. some plants
growing in water-logged soil.
8. Storage roots: Roots swollened with
reserve food material. It may be primary
8
e.g. Belladonna, secondary e.g.
Umbelliferous roots, adventitious e.g.
Calumba or it may be very swollen
roots and called root tubers
CONDITION:
Drugs of roots occur usually in dry conditions, rarely fresh. They may be:
Entire of rarely so e.g. Senega.
Sliced longitudinally e.g. Althea or transversely e.g. Calumba.
Peeled e.g. Liquorice.

Shape:
Cylindrical e.g. Sarsaparilla.
Subcylindrical e.g. Rauwolfia.
Teret: when tapering gradually.
Twisted e.g. Scammony.
Obconical e.g. Aconite and Carrot.
Fusiform e.g. Jalap.
Napiform globular e.g. Turnip.
Structure and Secondary thickening in root
Secondary thickening takes place in Dicotyledons and

Gymnosperms only.

The cambium is originated in the parenchyma below the

phloem, in the conducting parenchyma and in the pericycle

outside the protoxylem arches forming a stellate ring.

This cambium divides to give secondary phloem outwards

and much xylary tissue, secondary xylem, inwards so the

cambium becoming circular in form.
Opposite each protoxylem group the cambium forms

a primary medullary ray.

At the same time phellogen is formed in the

pericycle dividing to give outer cork and inner

wide pheloderm, thus cutting off the piliferous

layer, primary cortex and endodermis.
 As a result of secondary thickening, the old dicotyledonous root
is formed of the following layers.

1. Cork.
2. Phelloderm.
3. Collapsed primary phloem.
4. Secondary phloem
5. Cambium.
6. Secondary xylem.
7. Primary xylem groups in the center.
8. The pith is usually absent except in Aconite.
Anomalous Secondary Thickening:
Some medicinal roots show abnormal types of secondary
thickening as:
Ipecacuanha:
The vascular cambium yields a small and dense xylem to the
inside and very narrow ring of phloem outwards with short
wedges of sieve tissues. The phellogen produces a very wide
starchy parenchymatous phelloderm.
Senega: The xylem is wedged by the formation of
wide, V-shaped, Furthermore, excessive secondary
phloem is abnormally developed and producing an
external ridge termed the keel.
Aconite:The cambium retains its stellate form and
develops little secondary xylem and wide parenchymatous
phloem with little amount of sieve tissue.
The root shows wide medullary rays and parenchymatous
pith.
The tegumentary tissue in aconite is the metaderm.
 SUBTERRANEAN STEMS
Difference between aerial stem and the
subterranean stem:
1. It bears scale and not foliage leaves.
2. It bears adventitious roots arising generally
from the nodes.
3. It has growing point protected by scale and not
by compactly arranged rudimentary leaves.
Difference between subterranean stem and root:

1. It generally, has nodes and internodes.

2. It bears scale leaves with axillary buds.

3. Numerous adventitious roots are generally arising from the

nodes.

4. It has growing point protected by scale leaves and not by root-

cap.

5. Histologically, it shows a central pith and numerous collateral

not radial vascular bundles
Functions of Subterranean Stem:

1. They function as a mean of perennation

2. They serve as storage organs for reserve food materials e.g.
starch, inulin, sugars etc.

3. May contain 2ry metabolites.
 Mode of Branching

Monopodial: In which the main axis continues growing

and produces the successive yearly portions of the axis

e.g. Filix mas.

Sympodial: In which the main axis stop growing as a

result of destructing of the apical bud. The main axis

continues its growth by the development of axillary buds

in the axil of scale leaves e.g. Ginger.

3In some cases, the rhizome starts its growth

monopodially but, later on continues sympodially e.g. Iris.
CONDITION:
Subterranean stems are usually present in dry conditions,
rarely fresh e.g. Colchicum corm. They are:
Entire or nealy so e.g. Veratrum.
In brocken pieces e.g. Ginger.
In longitudinal slices e.g. Valerian or in transverse slices
e.g. Colchicum.
Peeled or decorticated e.g. Ginger and Rhubarb.
Direction of Growth: may be
Horizontally: It is the usual type in this case, it shows scars of the
aerial shoots or buds with encircling scale leaves on the upper side and
roots or their scars on the lower side e.g. podophyllum and Ginger.
Vertically: In this type, the subterranean stem shows roots and scale
leaves all over the surface with a large bud at the apex. Also, it shows
annulated surface due to the presence of the encircling leaf scars e.g.
Veratrum and Valerian.
Obliquely: It is occasional type in which, the aerial parts leave the
subterranean stem with angles equal to that between the subterranean
stem and the ground level e.g. Filix mas.
 Types of subterranean stem
1Rhizome: It shows nodes and short or long
internodes, terminal bud and arial shoots e.g.
Rhubarb.
2Sobole: It is a rhizome with long slender internodes
e.g. Couch Grass.
3Root Stock: It is composed of the lower modified
subterranean portion of aerial stem attached to the
root. It bears buds e.g. Senega.
4Sucker: It is a branch growing under the ground and
arising either from a stem e.g, Mentha or from the top
of the root e.g. Rose.
5Stem-tuber: It is swollen with reserve food material
and shows small scales, buds as well e.g. Potato.
6. Corm: It is a shortened swollen erect
under ground base of the stem, covered with
scale leaves, have large apical bud and small
axillary ones. It usually produces a daughter
corm e.g. Colocasia and Colchicum.

7. Bulb: It is formed of reduced flattened
discoid stem with crowded fleshy scale leaves
and adventitious roots. It bears a terminal and
axillary buds. There are two kinds of bulbs:
Scaly bulb: The fleshy scales overlap at
their margins e.g. Scilla indica.
Tunicated bulb: The outer scales are
larger and completely encircling the inner
ones e.g. Onion and Squill.
 Structure of Subtarranean Stems:
Subarranean stems generally resemble in structure the aerial
stems. They are almost devoid of sclerenchymatous tissue as they
are not in need of supporting themselves. They are formed of the
following layers :
1. The Tegumentary layer: the outer protective layer and may be:
a) Epidermis: is persistent in some cases as in couch Grass.

b) Cork: is formed of few rows of regular layers of suberised or
lignified cells with no intercellular spaces e.g. Liquorices and
Rauwolfia.
c) Metaderm: consists of few rows of irregularly arranged
suberised cells derived from the outer layers of the cortex, so may
show intercellular spaces.

2. The Cortex: It is formed of thin-walled parenchyma filled
with reserve materials. In Dicotyledons, it is wide showing few
root-or leaf-traces, while in Monocotyledons, it shows numerous
closed vascular bundles. In pteridophyta, the cortex shows
nonlignified sclerenchymatous hypodermis.
3. The Endodermis: is usually indistinguishable in Dicotyledons,
though it may be clear as in Valerian. In Monocotyledons it is
distinct.

4- The Vascular Bundles :

a) Open: showing cambium, widely separated by medullaey rays
forming a single ring around the pith e.g. Podophllum or the
secondary tissues are greatly developed formed continuous ring
around the pith e.g. Dicotyledons like Liquorice and Rauwolfia.
b) Closed: numerous and scattered in both the cortex and the stele being

smaller and more numerous near the endodermis e.g. Ginger and

Monocotyledons. Sometimes, they are restricted to a single layer within the

endodermis surrounding a central pith e.g. Couch grass

Open vascular bundel Closed vascular bundel
 Anomalous Secondary Thickening:
Anomalous structures in subterranean
stems may be present. In Rhubarb,
abnormal bundles are developed in the
pith as radiating stellate structure called
star spot. It is formed by abnormally
developed cambium which results from
activation of parenchyma cells around the
collapsed perimedullary phloem. This
cambium gives phloem to the inside and
xylem to the outside with radiating slightly
curved medullary rays filled with dark
brown contents.
OFFICIAL ROOTS
 1. Ipecacuanha root (Erquel Thahab)

Ipecacuanha is the dried root or the
root and rhizome of Cephaelis
ipecacuanha (Brot) known as Rio or
Brazilian Ipecacuanha,
or of Cephaelis acuminata known
as Cartagena Ipecacuanha, Fam.
Rubiaceae.
Macroscopical characters
❖ The roots of Rio Ipecacuanha are subcylindrical,
slender and tortuous.
❖ It measures 5-7 cm long, 2-4 mm thick.
❖ The colour is dark brick-red to dark-brown.
❖ They are marked by transverse constrictions which
may reach as far as the wood and give an
appearance of about 8 annulations per centimeter.
❖ Some roots have portions of rhizome attached
which cylindrical, the surface is longitudinally
striated, with occasional buds and the annulations
are absent
The transversely cut surface of Rio

Root shows a central core of yellowish-

white dense wood occupying about 1/3

of the diameter, surrounded by the

cambium line and a wide grayish bark,

with a thin cork externally.

While Rhizome is showing a narrow

bark, a dense yellowish-xylem and

definite pith.
C. Ipeca

C. acuminaa
The Cartagena Ipecacuanha differs from the Rio
drug as follows:
1. It is grayish-brown and showing the transverse ridges
at intervals of 1-3 mm. (mainly rhizome)
# dark brick-red to dark-brown. (mainly root)
2. Longer and thicker, 3-9 mm thick.
# usually 5-7 cm long, 2-4 mm thick
3. The ridges (annulaion) extend only about half way the
circumference 0.5-1.0 mm wide.
# about 8 annulations per centimeter
Microscopical Characters: Rio Ipecacuanha: The root:
Cork: narrow, dark brown and is composed of several layers of thin walled cells.
Phelloderm: or secondary cortex: wide parenchymatous containing starch granules and
scattered raphides of calcium oxalate.
The starch grains are muller-shaped (up to 15 u in dimeter). They are usually compound and
formed of two to eight components.
The Pholem: Very narrow with short wedges of sieve tissues embedded in parenchyma with
no sclerenchymatous cells or fibres.
The xylem: All xylem elements are lignified. The primary xylem is triarch and found at the
centre of the root.
The Rhizome:
T.S shows a ring of xylem and a large pith.
The pericycle contains elongated rectangular sclerenchymatous cells
with pitted lignified walls. The number of them per milligram of stem
is constant and may be used to determine the proportion of stem
present in powdered root of Ipecacuanha.
The pith: composed of pitted lignified parenchyma.
 Abundant starch granules, mostly compound (2 to 8 Parenchyma of the phelloderm, filled with starch
components), ovoid to spherical or muller shaped. granules or occasionally, containing bundles of acicular
Cartagena 15 u & in Rio 22 u crystals of calcium oxalate.

The tracheids or traceidal vessels which are found in
groups of small lignified, moderately thick-walled cells
and having numerous bordered pits.

Powder
CONSTITUENTS
1. Isoquinoline alkaloids emetine, cephaetine and
psychotrine.
2. Monoterpinoid isoquinoline glycosides including
ipecoside and alangiside.
3. Iridoid glycosides sweroside and 7-
dehydrologainin.
4. Acid saponin and ipecacuanhic acid
5. Starch and calcium oxalate.
 USES:
1. Expectorant and emetic.

2. diaphoretic and cholagogue.

3. Its most important use is as a remedy for amoebic
dysentry if given in large doses.(emetine
hydrochloride is given by injection)

4. Emetine has antitumour activity.

5. Psychotrine and o-methyl ether are selective inhibitors
of human immunodeficiency virus.
 TEST FOR IDENTITY
Digest about 0.1 g. of powder + 4 cc. of cone. HCL+ 1
Filter add to the filtrate crystals of
potassium chlorate
cc of water yellowish

colour is rapidly produced, which gradually changes

to orange and finally to red within an hour. (test due

to emetine alkaloid).
 2. Liquorice Sweet Wood, Erqusous
Liquorice is the dried peeled or
unpeeled root and rhizome of
Glycrrhiza glabra Linne var. Typica
known as Spanish Liquorices or
Glycyrrhiza glabra var. Glandulifera
known as Russian Liquorice or of
other varieties of Glycyrrhiza glabra
Linne. Fam. Leguminosae
CULTIVATION AND COLLECTION:

Spanish liquorice is cultivated by replanting pieces of the

stolons, having 2-3 buds of aerial shoots. The underground

organs are developed at sufficient extent by the end of 3-4

years, when they are dug-up, washed and cut into short

pieces. Root-lets and buds are removed and the drug is

dried rapidly in the sun and finally in a heated chamber.
1- Spanish liquorice :
Consists chiefly of stolons with few pieces of roots. Mostly cylindrical, 14-20
cm long and 5-20 mm in diameter.

The unpeeled drug is dark-brown or reddish-brown in colour,
longitudinally wrinkled externally and the stolons bear occasional small
buds, scaly leaves and scars of slender side-roots.

The peeled drug shows longitudinal flattish areas (resulting from the use
of knife for peeling).

* The peeled drug has very sweet taste which almost free from bitterness and
acridity.
2- Russian Liquorice:

It consists mainly of roots together with root-stock.

The unpeeled drug occurs in somewhat tapering pieces up to
30 cm in length and 1-5 cm in diameter

*The taste is sweet but usually not entirely free from
bitterness and acridity.
Microscopical Characters:

Rhizomes and roots of liquorice have typical structure

except the absence of pith in the root and presence of the

tetrach primary xylem in the center of the root.
Layers:
1- Cork

2- Cortex and starch.

3-Pericyclic fibers

4-Phloem fibers

5- Cambium

6-Xylem with wood fibers

All fibers with crystal sheath.

In case of Rhizome found Pith
Powder

Fibers with crystal sheath

Xylem vessels. Cork cells
 CONSTITUENTS:
1. A sweet principle Glycyrrhizin, the potassium and calcium salts
of glycyrrhizinic acid.

2. Flavonoid compounds, liquiritin, isoliquirtin rhamnoliquirtin
which on drying is converted into liquiritin, liquiritigenin and
isoliquiritigenin.

3. A coumarin compound, liqcoumarin.

4. Sugars, starch, protein, β-sitosterol and a bitter principle
glycyramarin.
 Uses:
1. Demulcent and mild expectorant.

2.In cough mixtures as expectorant and to mask the taste of
nauseous medicaments.

3. For gastric and duodenal ulcers.

4.In treatment of rheumatoid arthritis and various inflammatory
conditions due to its deoxycorticosterone effect.

5. As gentle laxative.

6. Mouth wash for mouth ulcers.

N.B.: Contraindicated in pregnancy and hypertension.
Tests for Identity:
* Mix a little of powder with 1-2 drops of
sulphuric acid (66% v/v), an orange-red
colour is produced.
* Shake the aqueous decoction of liquorice,
a voluminous froth is produced.
Adulteration:
*Curcuma powder; It can be detected by
presence of gelatinized starch and yellow
masses.
*Olive stone: Its presence is verified by
presence of stone cells.
 3. Senega

It is the dried root and root - stock of Polygala
Senega Linne, Fam. Polygalaceae.

Fragments of smaller vessels and
numerous slit-shaped pits tracheids.
TESTS FOR IDENTITY:
1. The powder is boiled with water, the solution is strongly
shaken voluminous persistent froth is formed.
2. Extract the powder with ether, filter and then evaporate the
ether.
Dissolve the residue in chloroform, transfer to a test-tube and
run in on the side of the tube (carefully) conc. sulphuric acid.
A dark reddish-brown zone is formed between the two liquids
and a faint greenish fluorescence in the acid within 24 hours.
CONSTITUENTS:

Triterpenoid saponins:
Senegin, on hydrolysis it yields glucose presenegenin, senegenin (which is a

chlorine-containing triterpenoid), senegenic acid and polygalic acid.

Senegin II on hydrolysis gives presengenin as the aglycone and a number of

sugars

senegenin
USES:

❖ Senega is used as expectorant in chronic bronchitis. It is often

prescribed with other expectorants such as ipecacuanha and

ammonium citrate.

❖ Emetic.

❖ Relieve spasms

❖ Sialagogue (promotes the flow of saliva)

❖ Traditionally believed to treat snake bites, hence the name)
 4- Aconite )‫)خانق الذئب‬
It is the dried tuberous root of Aconitum napellus Fam.
Ranunculaceae.

Active constituents:
1- Alkaloiods; aconitine, picraconitine and aconine
2- Other alkaloids; hypaconitine, neopelline, napelline, nealine and
mesaconitine
Uses:
1- Externally in neuralgia and rheumatism
2- Internally in case of fever and pain ( now rarely used as it is very
potent poison)
Unofficial Roots
 1- RADIX GINSENG
Ginseng is the dried roots of the cultivated plants of Panax
quinquefolium Linne, known in commerce as American
ginseng and of Panax Shin-seng Nees, known in
commerce as Chinese ginseng, Fam. Araliaceae.
COLLECTION AND PREPARATION:
 The drug is collected from plants of 3 to 6 years old in
autumn or late summer.

 The plant is harvested when 6 years old.

 Sun-drying of the root after cleaning and removal of the
outer layers produces the white ginseng.

 Whereas the red ginseng can be obtained by first
steaming the root, followed by artificial then sun-drying.

 The roots are graded and packed.
CONSTITUENTS:
1. A complex mixture of saponins of both steroidal
and pentacyclic triterpenoidal in nature. They are
termed ginsenoside ( japaness) or Panaxosides (
Russian).
2. Panacene.
3. Volatile oil.
4. Sterols free or in glycosidal form.
5. Polyacetylene derivatives, B-elemene and panxinol.
6. Starch, pectin and simple sugars.
7. Vitamins, choline and flavonoids.
USES:
1. Adaptogenic i.e. increase resistance to adverse
influences and improve physiological functions.
2. Antifatigue (mental and physical).

3. Antistress and antiaging.

4. In treatment of diabetes.

5. Reproductive system enhancement as it promotes
growth of testes and increases sperm formation
(Phytoestrogens and aphrodisiacs).

6. Antioxidant and anticancer.

7. Immune system enhancement.
TESTS FOR IDENTITY:

1- With a drop of sulphuric acid, the powder shows a brick-red
colour changing to red-violet and then violet within 5
minutes.

2. Evaporate few drops of the decoction (boiling herbal or plant
material) in a test tube and add to the residue a benzidine
solution in sulphuric acid (0.01%) where a persistent brick-

red colour appears due to oxidising agents.
 2-Calumba

It is the dried transversely or obliquely sliced root of
Jateorhiza palmata Fam. Menispermaceae.
Constituents:

1- Isoquinoline alkaloids; palmatine, jareorrhizine and
calombamine

2- Non alkaloidal bitter principles, the furanoterpenes,
calumbin, isocalumbin, palmarin, jateorin and isojateorin

3- Mucilage and starch.

Uses:

1-Stomachic and bitter tonic

2- Prescribed in anorexia and flatulent dyspepsia
 3-Rauwolfia (Indian snake root)
It is the dried rhizome and roots of Rouwolfia
serpentina fam. Apocyanaceae
Constituents:

 1-Alkaloids: ajmaline, ajmalinine, ajmalicin, serpintine,
serpintinine, reserpine and rescinnamine

 2- Phytosterols, fatty acids, unsaturated alc. And fumaric
acid.
Uses:
1-Used in hypertension, neuropschyiatric disorders

2- Used in treatment insomnia

3-Ajmaline has a quinoline – like action used in cardiac
arrhythmias

4- It promotes brest cancer from previously initiated cells
 SARSAPARILLA ROOT
Sarsaparilla is the dried root and sometimes also the rhizome of Smilax
ornate, known as Jamaica Sarsaparilla Fam. Lilaceae:

Constituents
❖ Steroidal saponins which are closely related to cortisone and sex
hormones as Sarsaponin, Similagenin and Sarsaparilloside.
❖ Sarsaponin up on hydrolysis gives the genin called
sarsapogenin and sugars.
❖ Similagenin is isomer of Sarsapogenin

Sarsapogenin Similagenin
USES:
❖ Formerly used in treatment of syphilis (is a sexually transmitted infection caused
by the bacterium Treponema pallidum)
❖ Rheumatism.
❖ Certain skin diseases as psoriasis (thick, red, scaly patches with mild itching and
eczema (has intense itching).
❖ The genins are used in the partial synthesis of cortisone and other steroids as
testosterone.
❖ As a general tonic.
OFFICAL RHIZOMES
GINGER
 1- Rhizoma Zingiberis
(Ginger - Ryzomatula Zanjabeel)
Ginger is the fresh or dried rhizome
of Zingiber officinale roscoe Fam.
zingiberaceae, deprived of the dark outer
tissues and known as unbleached Jamaica
Ginger.

The plant is native of South-eastern Asia.
It is cultivated in India, Nigeria, West Africa
and Jamaica.
 Cultivation and Preparation:
 Ginger grows well in well-drained rich loamy soil at
subtropical Temperature and by the presence of abundant
rain-fall. The plants are propagated from cuttings of the
rhizomes, called fingers, each bearing a bud.
The rhizomes are collected then

Cleaned by removal of soil, buds, roots, and soaked overnight in

water. After soaking, the rhizomes are carefully peeled, (removing

the cork and some of the underlying parenchyma) washed and

then dried in the sun for 5 to 6 days. The product is known as

"Unbleached Jamaica Ginger".

Coated or whitened by dusting with lime or calcium carbonate

(Limed Ginger). They are less susceptible to insect attacks.
It occurs in branched pieces known as "hands" or races.
Each piece consists of a horizontal rhizome from which branches about
3-6cm long and known as (fingers) arise vertically, and terminating
with undeveloped bud.
Externally; ginger is pale yellowish-buff, and longitudinally striated or
fibrous.
Oil cell with suberized walls and containing yellowish-brown oleo-resin
thin-walled septate fibres, with
slit-like pits, only the middle
lamella is lignified.
Starch granules Oleoresin cells
Active constituents:

1-Volatile oil which is responsible for the aroma, consisting of
monoterpenes (phellandrene, camphene, cineole, citral and borneol)
and sesquiterpenes (zingiberene and bisabolene).

2- A yellowish oily body, called gingerol and shogaols, which is
odourless but with an intensely pungent taste (phenolic compound).

This pungency is destroyed by boiling with 2% potassium hydroxide
solution.

3- Resin and starch (56%).
USES:
1-Travel and motion sickness (the phenolic compounds responsible for relaxing
the muscles of the stomach), the study indicated that the powdered ginger may
be a more effective antiemetic than dimenhydrinate (Dramamine).

2- Indigestion and nausea; sickness in pregnancy.

3- Sluggish circulation, especially where hands and feet are cold by improving
the circulation, ginger helps high blood pressure, it also increases sweating
and helps reduce body temperature and fever.

4- Ginger is warming and soothing for coughs, cold, flu and other respiratory
problems.

5- High cholesterol levels.
 Adulteration:

1- Japanese ginger:

a) Obtained from Zingiber mioga.

b) Starch grains are compound.

c) The volatile oil differs from the official drug in physical
properties.

d) The taste is less pungent.

2- Exhausted ginger: it can be detected by:

a) Determination of the amount of extractives i.e. matter
extracted by solvents such as water or alcohol (decreased).
b) Presence of gelatinized starch

exhausted ginger may have its pungency increased by the
addition of capsicum which can be detected by heating in a
water bath the liquid extract with caustic alkali. The liquid is
then evaporated, the residue acidified with HCl, and shaken
with ether. Some of the ethereal solution evaporated and the
residue left should not be pungent to taste. (KMNO4)

3- Foreign starches, that is easily detected microscopically.
Precautions from (AHPA)( American Herbal Products
Association)
1. Ginger should not be used by children under 2 years of
age.
2. Ginger intake should not exceed 2 to 4 g per
day(excessive doses of the herb may cause mild
heartburn).
3. It should not be used during pregnancy.
4. People with gallstones should consult a physician
before taking ginger (Why?)
 2- Rhubarb

Dried rhizomes and big roots of Rheum Palmatum,
Rheum officinal, and other species of Rheum except
Rheum rapontecum.(Fam. Polygonaceae).
❖ Rhubarb is propagated by seeds.
❖ It is cultivated in sandy and clay loamy soils.
❖ When it about 6-10 years old deprived of its cork
and dried.
❖ Pieces often show holes indicating that they we
threaded into cords for drying in the shade.
❖ The drug may be also artificially dried.
Rhubarb occurs in subcylindrical,
barrel-shaped, conical plano-convex
or rectangular pieces
If the trimming has been severe there
may be seen upon the surface
numerous groups of radiating dark,
reddish-orange lines known as (Star
spots), which result from sections of
abnormal vascular strands occurring
in the pith.
Microscopical Characters:
T.S. in Rhubarb shows the following layers:
The cortex: If present, is very narrow consisting of polygonal, parenchymatous cells,
containing simple or compound starch granules and large clusters of Caox
The phloem: If present, is parenchymatous, the sieve tissue is in scattered groups, mostly
obliterated and collapsed, it is traversed by reddish-brown medullary rays, 2-5 cells wide with
reddish-brown contents and showing numerous large clusters of Caox., the phloem
parenchyma contains starch granules.
The xylem: It is formed of a narrow ring within the cambium and traversed by
parenchymatous medullary rays, of 2-3 cells wide with brown amorphous contents, the vessels
are non-lignifled, isolated or in small groups.
The pith: It consists mostly of parenchyma and irrigularly traversed by star-shaped,
amphivasal, abnormal vascular bundles called star spots.

There are no sclerenchymatous fibres or cells and the commercial
rhubarb has no cork.
Star spot
 Powdered Rhubarb
Microscopically, it is characterized by:
1-Abundant fragments of parenchyma containing starch
granules.
2-Fragments of medullary ray cells, with brownish contents
3-fragments of non- lignified vessels.
4-Numerous large cluster crystals of calcium oxalate.
5-Numerous starch granules, simple or compound, with a
central cleft hilum.
 non-lignified reticulate cluster crystals of Ca
spiral or annular ox.
vessels.

Starch granules
Active Constituents
I- Anthraquinones derivatives (2-4.5%) of the following types:
 Anthraquinones without a carboxyl group e.g. chrysophanol, aloe-emodin,
emodin and physcion and their glycosides.
 Anthraquinones with a carboxyl group e.g. rhein and glucorhein.
 Anthrones or dianthrones of chrysophanol or emodin or aloe-emodin or physcion
e.g. sennosides A & B and the oxalates of these, sennosides E and F.
 Heterodianthrones e.g. palmidin A, palmidin B and palmidin C. Also sennidin C
and sennoside C, reidin B and C.
 Barbaloin
II- Astringent compounds: glucogallin, free gallic acid, epicatechin gallate and
catechin.
III- Starch and calcium oxalate
Uses:

1. In small doses rhubarb is used as a bitter
stomachic and in large doses it is used in the
treatment of diarrhaea (purgation being followed
by an astringent effect), due to the tannins present.

2. In cases of indigestion with diarrhaea.

3. As a mild laxative.

4. It has been used in jaundice, sores and cancer.
TESTS FOR IDENTITY:
1- Microsublimation:
Powdered rhubarb gives a yellow needle-shaped sublimate, which
dissolves in potassium hydroxide T.S. giving a reddish colouration.

2- Test for anthraquinone derivatives:
Boil 0.1 g powdered rhubarb with 5. ml of 10% sulphuric acid for
two minutes to hydrolyse any glycosides. Filter while hot, cool the
filtrate and shake with benzene. To the clear benzene solution add
half its volume of 10% ammonia, shake and allow to separate when
the ammonical layer will have acquired a rose-pink colour.
TESTS FOR PURITY:

1- When the powder is examined under Ultra Violet light no chiney
blue violet spots or particles (Rhapontic Rhubarb).

2- Place on a slide 2-3 drops of 10% freshly prepared solution of
furfural in alcohol and 3 drops of sulphuric acid, then sprinkle little
of the powder and examine immediately under the microscope: a
bluish-violet colour should not be produced (Rhapontic Rhubarb)
Adulterants:
1- English Rhubarb: two species
a) R. officinale resemble the Chinese drug, but being more spongy, shrink and
wrinkle as they dry, and are softer to cut, the white reticulations are
commonly absent, the star-spots are fewer and more scattered. The
constituents are similar to the Chinese drug.

b) R. rhaponticum much shrunken and usually pinkish in colour, they can be
readily distinguished by the transverse section which shows a diffused circle of
isolated star-spots. It contains traces of emodin, aloe-emodin or rhein, its most
characteristic constituent is a crystalline glycoside, rhaponticin, which fluoresces
blue in Ultra-Violet light.
2- Chinese Rhapontic Rhubarb:
It closely resembles English rhapontic, but is usually darker, often hollow in the
center. Internally, it is yellow, rather than pink. A mixture of both when examined
in Ultra-Violet light shows bright blue specks (rhapontic rhubarb) in a velvety-
brown ground colour (official Chinese Rhubarb).

3- Indian Rhubarb: (Rheum emodi):
It is shrunken, and easily cut. In Ultra-Violet light, it fluorecences deep-violet with
certain amount of velvety-brown patches. It does not contain rhaponticin and gives
positive test for anthraquinone derivatives.

4- Many species of Rumex root: e.g. Rumex. alpinus and R. obtusifolius
have been used as substitutes for Rhubarb. They contain anthraquinone
derivatives.
Hydrastis rhizome.
 3- Rhizoma Hydrastis (Golden Seal)
It is the dried rhizome and root of Hydrastis
canadensis Fam. Ranunculaceae.

Constituents:
1- Isoquinoline alkaloids; hydrastine, berberine
and canadine
2- Resin, starch and traces of V. oils
TEST FOR IDENTITY:

❖ On micro-sublimation of powder yields a yellow crystalline sublimate of

hydrastine.

❖ Shake some powdered hydrastis with chloroform, filter and evaporate the

filtrate. Add to the residue I or 2 ml of sulphuric acid and a small crystal of

ammonium molybdate where a green colour is given which changes to blue.

❖ Boil powder (previously extracted with chloroform) with water, filter and

evaporate the filtrate to dryness. Moisten the residue with H2SO4 and add few

drops of bromine, where a blood red colour is produced.
Uses:
1- Hydrastine constricts the blood vessels and stimulates the autonomic nervous
system.

2- Berberine has antibacterial, amebicidal and it has sedative action on the
central nervous system

3- Canadine stimulates the muscles of the uterus

4- Reduce heavy menstrual bleeding and help to stop bleeding following
childbirth (postpartum hemorrhage)

5- It increase digestive secretion and checks inflamation.

6- Goldenseal is a potent remedy for disorders affecting mucous membranes of
the body. 7- Bitter tonic
 4- Rhizoma Valerianae
(Valerian or Valeriana)
Valerian is the dried rhizome and
roots of Valeriana officinalis Fam,
Valerianaceae.
CONSTITUENTS:

1- 1.4% of volatile oil present in the hypodermis of the root and
in the endodermis of rhizome, containing chiefly bornyl
isovalerianate which decomposes gradually by an enzyme to give
isovalerianic acid (an oily liquid with unpleasant odour).

2- Two alkaloids Chatinine and valerianine.

3- Alcohols terpenes and a sesquiterpene alcohol (Valerianol).

4- Epoxy-iridoid esters called valepotriates
USES:

1-Valerian reduces mental over activity and nervous excitability. It
is beneficial for almost any stress-related.

2- It is a useful remedy for insomnia, whether caused by anxiety or
overexcitement.

3- It relaxes over contracted muscles, and is helpful for shoulder
and neck tension, asthma, colic, irritable bowel syndrome, muscle
spasms, and menstrual pain.

4- It is used with other herbs in remedies for high blood pressure
caused by stress and anxiety
Unofficial rhizomes
 1-Curcuma rhizome
Turmeric
Turmeric is the dried prepared
rhizomes of Curcuma demestica, (C.
longa) family Zingiberaceae.
Constituents:
1- Orange-yellow volatile oil, that
composed mainly of
 Turmerone (60%)
 Zingiberene (25%).

2-Yellow crystalline substance (curcumin).
3- Starch.
4- Resin.
5- Sugar.
USES:

1- As a condiment. Colouring agent, Stimulant and carminative. As
a reagent for the detection of boric acid.

2- Anti-inflammatory, has an even stronger action than
hydrocortisone.

3- Antioxidant, Curcumin is more strongly antioxidant than vitamin
E (choleretic strong antihepatotoxic action).

4- Treatment of jaundice and hepatitis.

5- Curcumin when applied to the skin and exposed to sunlight, it is
strongly antibacterial and is useful in treating a number of
conditions including psoriasis and fungal infections
Tests for Identity:

1- When a small quantity of the powder is sprinkled onto a mixture
of equal parts of cone. H2SO4 and alcohol 95% the particles turn
red and the red colour gradually flows out into the reagent.

2- The yellow stain extracted with a mixture of ether and CHCl3
gives with a hot solution of boric acid an orange-yellow colour
turing to bluish-black then black on the addition of ammonium
hydroxide solution
 2-Garlic

Garlic is the fresh or dehydrated
cloves of Allium sativum L. Fam.
Liliaceae

It is indigenous to central Asia, garlic is
now grown worldwide.
CONSTITUENTS:

1- Volatile oil, composed of sulfur containing compounds:

a) Alliin (S-allyl-cysteine sulfoxide), which is highly sensitive. and
quite unstable, changes rapidly into allicin under the effect of
allinase enzyme.

b) S-methyl-L-cysteine sulfoxide, allylpropyl disulfide, diallyl
disulfide, diallyl trisulfide and other sulfide components.

c) Ajoenes (E. Z- ajoene, E,Z-methylajoene and dimethylajoene).

2- Enzymes; alliinase, peroxidase and myrosinase.

3- Protein (16.8%, dry weight basis).

4- Minerals, particularly selenium, 5- Vitamins A. B and C.
 USES:

1. Garlic has healing powers and before the development of
antibiotics, it used in treatment of infections, from tuberculosis to
typhoid. It was also to dress wounds in the first world war.
Allicin, diallyl disulfide and diallyl trisulfide are generally
considered to be responsible for much of garlic's pharmacological
activities.

2. It has antibiotic, antiseptic, antiviral, antioxidant and antimycotic
effects. Chest infections, coughs, colds and flu.

3. Reduce cholesterol, lower blood pressure, prevent the clotting of
blood in thrombosis and reduce blood sugar levels.
 3- Onion
It is the fleshy bulb of Allium cepa Fam. Liliaceae
Constituents:
1- Onion like garlic, contains organic sulfer compounds as
A- Trans-S-(1-propenyl) cysteine sulfoxide
B- S-methyl cysteine sulfoxide
C- S-propyl cysteine sulfoxide
All these compounds are converted into simpler sulfer
compounds by alliinase persent when the onion cut or
crushed. These simpler compound are unstable and undergo
further decomposion to sulfides which are responsible for
onion flavor
Uses:

❖ It is reported to have many similar pharmacological action as
garlic, including, antihypercholesrolemic, hypoglycemic,
antifungal, antibiotic and antiplatelet aggregation.

❖ It is used as antispasmodic, carminative, diuretic, expectotrant
stomachic and anthelmintic.

❖ Increase consumption of Allium vegetables (onion) reduce
gastric risk.