Medicinal Plants Lecture Notes PDF

Summary

These lecture notes cover the cellular aspects of medicinal plants. It examines cell walls, differing properties, and the characteristics of various tissues.

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Lecture Notes on
MEDICINAL PLANTS

Department of Pharmacognosy
Faculty of Pharmacy
Damanhour university
 THE CELL AND CELL DIFFERENTIATION

The Cell:
Cell is the fundamental unite of a living organism (plants and animals).
The Cell consists of Cell wall and nucleus appears to be suspended
within cell by cytoplasm in which there may be large vacuoles with
their own characteristic contents (crystals and aleurone grains). Other
cytoplasmic inclusions are mitochondira, Golgi bodies, lysosomes, and
plastids. A group of cells with identical form and function is known as
a tissue.

The Cell Wall:
The wall of mature Cell consists of:
 The middle lamella is the intercellular substance, an amorphous,
colloidal layer composed of pectic substance.
 Primary wall or the original cambial wall is composed of cellulose and
pectic substance.
 Secondary wall is formed after the enlargement of the cell has been
ceased. It consists mainly of cellulose associated with polysaccharides.
It undergoes to some modifications as desposition of various chemical
substance as lignin, suberin and cutin.
 Tertiary wall: It is the innermost layer of the cell wall and is usually
thin, highly refractive and formed of cellulose.

Properties of different cell walls:
A. Cellulosic Walls: Formed mainly of cellulose which may be
accompanied with hemicellulose and pectin. Cellulose is
polysaccharide, composed of linear chain of glucose residue.
Chemical Properties:
 Give blue color with iodine and sulphuric acid.
 Give blue color with chloro- Zinc- iodine.
 Give no color with aniline or phloroglucin and HCL.
 They dissolve in ammonical solution of copper oxide
(Cuoxam) and precipitated with dilute sulphuric acid.
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B. Mucilaginous Walls: Certain cellulosic cell walls may be converted
into gums and mucilages. Mucilage is polysaccharides, consisting of
sugar and uronic acid combined with metals.
Chemical Properties:
 They are variably stained with ruthenium red, iodine sulphuric
acid or corallin soda.

C. Lignified Walls: Lignin is a strengthening material. Chemically it is a
complex phenylpropaniod polymer.
Chemical Properties:
 Stain magenta red with phloroglucin and hydrochloric acid.

D. Suberised and cutinized walls: Suberin and cutin are mixture of
polymerized fatty acids and suberic acid
Chemical Properties:
 Stain red with alkanna tincture and sudan III

E. Chitinous walls: Chitin is a polysaccharide derivative containing acetyl
and amino group. It constitutes the organic skeletal substance of
insects and many fungi. When heated with 50 % potash at 160 – 170
o
C for 1 hour, it is converted into chitosan C14H26O16N2, ammonia and
acids such as acetic and oxalic. Chitosan gives a deep violet coloration
when treated with iodine solution followed by dilute sulphuric acid.

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 Cell Differentiation

Plant tissue may be:
 Paranchymatous Tissues: Is the fundamental or ground tissues of the
plant. They are cellulosic, isodiametric orslightly axially elongated cells
with narrow or wide intercellular spaces. The cells show different
contents e.g. starch granules, calcium oxalate crystals. They constitute
most of the pith and cortex of the plant.

 Collenchymatous Tissues: It is a living mechanical tissue, composed of
rounded or elongated cells, with unevenly thickened, nonlignified
walls. The thickening is of cellulose and located commonly in the
angles (angular collenchyma) or chiefly on the tangential walls
(lamellar collenchyma). Collenchyma constitutes the typical
mechanical tissue of the herbaceous stems, and of the petioles and
midribs of leaves.

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 Sclerenchymatous Tissues: They are thick walled; dead, lignified
celled mainly for mechanical functions, consist of sclereids and fibres.
o Sclereids: They are thick, lignified cells with narrow to wide
lumen and isodiametrical in shape or elongated but the length is
never many times as the breadth.
o Fibres: They are dead, very much elongated, thick, lignified,
pitted, polygonal cells usually with tapering pointed ends. They
may have a tortuous irregular outline.

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Secretory Tissues:
They may be:
External: e.g. glandular hair.
Internal: include secretory cells, secretory cavities or glands secretory
ducts or canals and latex tissues.

Secretory Cells:
They occur either isolated or rarely in rows having suberised walls. They
differ from the other cells; by their contents and size. The cells are named
after the secretion they contain. The secretion may be volatile oil (oil cell),
resin (resin cell), gum resin, mucilage, enzyme or tannin.

Secretory Cavities (Glands):
These are internal structures, embedded in a mass of tissue and having
cavities within them in which secretions e.g. volatile oil and oleoresin, etc
are secreted. According to method of formation they may be:
 Schizogenous: Developed by splitting a part of cells thus enclosing
a cavity which then become enlarged and lined by epithelial cells
formed by the division of the surrounding cells e.g. savin.
 Schizolysigenous: Developed at first schizogenously but, later on,
increase in size by breaking down the bounding cells e.g. clove,
Buchu.
 Lysigenous: Developed by breaking down of the cells forming a
cavity. It originates from single cell by the division in different
direction forming a solid mass and then by the gradual
disintigration of the resulting cells starting from the center e.g.
Dictamnus.

Secretory Ducts:
They are tube like structures which may extend through the whole length of
the organ e.g. leaf pinus, or even through the whole of the plant. They are
developed either schizogenously as vitta of Umbelliferse, lysigenously or
schizolysigenously as in Capaifera.

Laticiferous Structures: These include tube-like cells and vessels with a
colorless, milky white, yellowish or reddish viscous emulsion called latex.
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Latex may contain resin, gum-resin, fat wax, proteins etc. suspended in an
aqueous solution of alkaloidal salts, tannins minerals, sugar enzyme etc.
 Latex Cell: Usually in the form of tube, branched as in Euphorbia or
unbranched as in Cannabis but not anastomosing e.g.
Euphorbiaceae and Apocynaceae.

 Latex Vessel: They are long simple or branching tube formed by the
partial or complete fusion of the transverse walls of a longitudinal
series of cells. They are anastomosing with rough walls e.g.
Papaveracea and Compositae.

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 CELL CONTENTS

The cell contents are those substances inside the plant cell and can be
identified by microscopical examination or by chemical and physical tests.
They include:

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  Primary metabolic products. (Food storage products) e.g.
carbohydrates, proteins and lipids.
 Secondary metabolic products (by-products of metabolism) e.g.
alkaloids, glycosides, volatile oils, resins and tannins.
 Crystalline mineral products e.g. calcium oxalate and calcium
carbonate.

Primary metabolites:
I. Carbohydrates: are organic compounds composed of carbon,
hydrogen and oxygen, where the last two elements are present of the
ratio 2: 1 like that of their presence in water. They include starch and
sugar.
 Starch: Are polysaccharides of higher molecular weight, with the
general formula (C6H10O5)n. It is formed as a result of the
photosynthesis process which carried out by the green parts of
the plant. The plant takes carbon dioxide from the air and
absorbs water from soil and in the presence of chloroplasts and
sunlight energy it forms glucose.

sunlight
6 CO2 + 6 H2O C6H12O6 + 6 O2

The formed glucose molecules are condensed together with the
elimination of water to give starch.
It occurs in granules of varying size in almost organs of the plants,
either alone or accompanied with other reserve food particles, e.g.
proteins.

Chemical Composition of Starch:
Starch granules consist of:
 Amylose: It forms the inner layers of the granule and is soluble in
water.
 Amylopectin: It forms the outer layers of the granule and is
insoluble in water.

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Macroscopical Characters:
 Starch occurs in irregular, angular masses or as a white powder.
 It is insoluble in cold water but forms a colloidal solution on
boiling water, the solution forms translucent jelly on cooling.
 Starch granules also undergo gelatinization when treated with
caustic potash, hydrochloric acid, concentrated solutions of
calcium or zinc chlorides or concentrated solution of chloral
hydrate.
 Starch is colored deep blue with solution of iodine; the color
disappears on heating but reappears on cooling.
 When starches are heated with water, the granules first swell
and then undergo gelatinization.

Microscopical Characters:
Starches can be identified by microscopical examination when mounted in
water or lactophenol.
The Shape: vary from polygonal, round to oval.
The hilum: It is starting point of formation of the granule in the leucoplast,
it may be centric or eccentric, the hilum takes the form of a round point
simple, curved or multiple cleft.
The Striation: are alternate layers around the hilum, either concentric rings
or transverse.
The aggregation: may be simple or compound. Some of the more
important microscopic characters of the principal starches are set out in the
following table.

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Comparison between the four important commercial starches in their
microscopical features:

Item Potato Wheat Maize Rice
polyhedral
Oval, rounded,
Oval, rounded, with Polyhedral with
Shape lenticular from side
pyramidal rounded sharp angles
view
angles
Size Large Medium Medium small
Absent, except in
Present, Present,
Present, centric, large, simple
Hilum eccentric, centric, cleft
pointed granules, centric
pointed or fissured
pointed
Distinct,
Striation faint, concentric Absent Absent
concentric
Simple,
Mostly Mostly
compound, Mostly simple, few,
Aggregation simple, few compound, few
semi compound
compound simple
compound

Chemical Tests:
 Starch gives blue color with iodine solution.
 Molische’s Test: suspension of starch and alcoholic α-naphthol in a
test tube gives violet ring at the interface upon addition of
concentrated H2SO4 on the wall of the test tube.
 Starch gives a positive reduction test e.g. Fehling test, after hydrolysis
with acid and neutralization of the solution.
Uses:
 Externally as dusting powder to allay itching or demulcent.
 Internally as:
o Suspending agent for barium meals before x-ray.
o Antidote in the treatment of iodine poisoing.
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 Pharmaceutical as a diluent, lubricant and a tablet disintegrant.

 Commercially:
o It is used for paper and cloth sizing.
o Nutrient.
o Preparation of glucose, dextrose and dextrins.

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II - Protiens:
Proteins are nitrogenous organic compounds formed from polymers
of amino acid units. In plants, protein is stored in the form of
amorphous mass called aleurone grains.

Aleurone Grains:
They are small solid protein particles, commonly present in the seeds.
The typical aleurone grains consist of:
 Ground Substance: is an amorphous protein, usually soluble in water.
 Crystalloid is formed of albumins, usually hardly soluble in water. It is
stained brown with iodine solution, yellow with picric acid and red
with Millons reagent.
 Globoid consists of globulin combined with calcium and magnesium
salts of hexaphosporic acid. It is insoluble in water.
Examination of aleurone Grain:
 The material, either in section or in powder form, is defatted first by
maceration in alcohol-ether mixture or then stained. The defatted
material is placed in picric acid solution for few minutes, washed with
alcohol to remove the excess of stain. Then add alcoholic solution of
eosin and finally wash well with alcohol. The stained aleurone grain
show yellow crystalloid, colorless globoid and red ground substance.
 Proteins give red color with Millons reagent.

III - Lipids:
They include fixed oils, fats and waxes. These substances are widely
distributed in the plant, commonly in the seeds and fruits. Fixed oils are
esters of unsaturated, higher molecular weight fatty acids with glycerols.
(Liquids)
Fats are esters of saturated, higher molecular weight fatty acids with
glycerols. (Solids)
Waxes are esters derived from higher monohydric alcohol combined with
fatty acids.
Fixed oils and fats are hydrolyzed by aqueous caustic alkalis to give soap
and glycerol. (Specification).

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Microscopical Identification of Oils:
 The oil globules are colored black with 1 % solution of osmic acid.
 The oil globules are colored red with sudan III.

Secondary Metabolites
I - Alkaloids:
Alkaloids are naturally occurring organic compounds containing one or
more nitrogen atoms in a heterocyclic ring, usually basic and have marked
physiological action on man or animals. The term alkaloid means originally
alkali-like.
Alkaloids are present in plants either as free bases or as salts of some acids.
Characters:
 Free bases are sparingly soluble in water but soluble in organic
solvents while the alkaloidal salts are soluble in water and sparingly
soluble in organic solvents.
 Most alkaloids are precipitated from neutral or slightly acidic solution
by Mayers reagent giving yellowish precipitate, by Wagners reagent
giving reddish brown precipitate, by Dragendorffs reagent giving
reddish brown precipitate. Caffeine and other purine bases do not
give these precipitates.
II - Glycosides:
Naturally occurring organic compound of plant organ consisting of sugar
part (glycone) and non sugar part (aglycone).
Classification:
There are four different systems for classification of glycosides:
 According to the linkage between glycone and aglycone e.g. O-
glycosides, S-glycosides and C-glycosides.
 According to pharmacologic action e.g. cardiac glycosides, laxative
glycosides etc.
 According to sugar moiety e.g. glucoside, rhamnoside,
glucorhamnoside etc.
 According to aglycones e.g. phenolic, anthracene, flavone etc.

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Properties of glycosides:
 Glycosides are polar compounds soluble in polar solvents.
 Glycosides can be hydrolyzed by acids or enzymes.

III - Volatile Oils:
Volatile or essential oils are volatile in steam. They are secreted in oil cells,
in secretion canals or cavities or in glandular hairs.
They are generally mixtures of hydrocarbons and oxygenated compounds
derived from these hydrocarbons. Volatile oils are used for flavoring, in
perfumery, as spices, and for their therapeutic action as antiseptic,
antispasmodic and carminative. Volatile oils are not saponified by alkalies
and are detected by sudan III.

IV - Tannins:
They are water soluble polyphenol compounds present in plant extracts
which are able to combine with proteins of animal hides to prevent their
putrefaction and convert them into leather. Most true tannins have high
molecular weights.

Uses of drugs containing tannins:
 Astringents in the gastrointestinal tract and on skin abrasions
(hemostatic).
 In the treatment of burns, where proteins of the exposed tissues are
precipitated and form a mildly antiseptic, protective coat under which
regeneration of new tissues may take place.
 Tanning of leather.
 Antidotal treatment of alkaloidal and heavy metals poisoning.
 Preparation of ink.

Tannins are classified into two main groups:
o Hydrolysable Tannins: These may be hydrolyzed by acids or
enzymes such as tannase. They are formed from several
molecules of phenolic acids such as gallic. On dry distillation,
gallic acid and similar components are converted into pyrogallol
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 so they termed pyrogallol tannins. The hydrolysable tannins give
blue black color with ferric chloride.

o Condensed Tannins: these are not hydrolyzed to simpler
molecules and they do not contain a sugar moiety. Condensed
tannins when treated with acids or enzymes are converted into
red insoluble compounds known as phlobaphenes. Condensed
tannins on dry distillation they yield catechol and these tannins
are therefore called catechol tannins. They give green color with
Ferric chloride.

Pseudotannins:
Are compounds of lower molecular weight than true tannins, they also do
not respond to the gold to the gold beater s skin test.

Test of Tannins:
 Gold beater’s Skin test:
o Soak a piece of goldbeater skin (membrane of ox-intestine) in 2%
HCL then rinse with water.
o Place the soaked piece in the solution to be tested for 5 minutes.
o Wash with distilled water and transfer to 1 % solution of ferrous
sulph1ate. A brown or black color on the skin denotes the
presence of tannins.
 Ferric Chloride Test:
o Tannins are extracted from vegetable powdered plant with hot
water; add few drops of ferric chloride solution a blue color is
produced with hydrolysable tannins and green color with
condensed tannins.

Calcium Oxalate
It is a common plant cell content, formed as an end product of metabolism.
It is found in more or less crystalline form. They are usually useful for the
microscopical examination of the drugs as well as detection of adulteration.
Characters:
 Calcium oxalate crystals are insoluble in water.

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  They are not immediately affected by caustic alkalis or chloral hydrate
solutions.
 They are insoluble in acetic acid but dissolve in HCL without
effervescence.
 They are decomposed when present in contact with H2SO4 without
effervescence, the oxalate crystals; disappear with the formation of
new needle-shaped crystals of calcium sulphate.

Forms of Crystals:
 Acicular (Needle shaped):
These are narrow, needle-like, with pointed ends. They may occur
isolated or scattered in cells or more often, they occur in bundles called
Raphides.
 Prisms: May be
o Simple prisms: occur singly or in crystal sheath around fibers.
o Styloids (elongatd prisms): These are very long prisms.
o Twin Prisms: Being formed of two crossing prisms.
 Rosette Crystals:
They are formed of aggregated prisms radiating from a central point in
one plane. This form is not very common.
 Clusters:
They are formed of aggregated crystals (prisms) radiating from a central
point, in all planes and are widely distributed.
 Micro crystals:
They are very minute Ca Ox. They occur in large number usually filling
the cell which appears dark-grey in color and is termed an idioblast of Ca
Ox. The crystals are either microprismatic or microsphenoidal, i.e. arrow
shaped.

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 MORPHOLOGYAND ANATOMYOF THE PLANT BODY

THE STEM
The stem is that part of the plant axis which bears the leaves and
flowers. The stem is formed of segments called internodes jointed at
points at which leaves arises called nodes. Usually the stem arises over
the ground (aerial) occasionally it grows under the ground (subterranean
stem).

Function of the Aerial Stem:
 Support and display of the leaves and flowers in such a manner as
to favour their activities.
 Conducting the water and minerals to the leaves and elaborated
food from the leaves to the root.
Shape:
Cylindrical, angular, triangular, quadrangular.

Kinds of Stem:
According to the nature and texture, it may be
 Herbacceous: it is soft, easily broken
 Succulent: it is fleshy
 Woody: it is hard
 Creeping: with the main axis of the plant lies along the ground
 Climbing: attaches itself to a support.

Branching of Stem:
 Monopodial: where the main axis continues growing from the apical
bud giving off lateral branches never exceed its length. It is also called
racemose, unlimited or indefinite branching.

 Sympodial: where the apical bud of the main axis stop to grow and
one or more axillary buds grow to compose a new part of the main
axis and so on, i.e. the apparent axis of the plant is compounded of
parts of a number of branches. It is also called cymose, limited or
definite branching.
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Structure of the Stem:
The young or herbaceous stem of Dicotyledons usually shows the following
layers from outside inwards:
 Epidermis: is the outermost layer.
 Cortex: limited by an endodermis.
 The Stele: Includes all the tissues within the endodermis the pericycle,
the vascular tissues, the pith and medullary rays.
 The pericyclic: formed of parenchyma or fibers and or sclereids.

Vascular Tissue: Consists of a number of vascular bundles arranged in circle
around the pith and interrupted by medullary rays.
The vascular bundles may be:
 Collateral: Formed of an outer phloem and inner xylem. It may be
open (with cambium) or closed (devoid of cambium)
 Bicollateral: With phloem above and below, the cambium will be
present in between the xylem and the outer phloem.
 Concentric: with no cambium.

Phloem: Consists of sieve tubes and companion cells with or without
phloem parenchyma.
Cambium: Meristematic tissue.
 It is present in open vascular bundles only. It may be restricted in
between the phloem and xylem where it is called intrafascicular or
may be crossing the medullary rays i.e. interfascicular
Xylem: It is generally lignified. It is always endarch i.e. having the
protoxylem directed inwards and the metaxylem outwards. Xylem consists
of vessels of various types of thickening wood fibres, wood parenchyma and
tracheids. Vessels are few and arranged to form Y- shape in case of
Monocotyledons.

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Pith: It consists of parenchyma in the young stem but usually lignified and
pitted in the old stem.
In monocotyledons, a large number of closed vascular bundles scattered
irregularly through the ground tissue, which is not marked off into pith and
cortex.

Secondary Thickening:
Means increase in diameter. This increase is mainly due to formation of
new vascular tissues by the successive division of the cambial cells giving to
the outside secondary phloem and to the inside secondary xylem. But, in
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the Monocotyledons, the enlargement is mainly due to the expansion of
primary elements as there is no cambium or by the increase in the number
of vascular bundles.

In the secondary thickening of Dicotyledones, some cells of the primary
medullary rays are activated to form interfascicular cambium connecting
the intrafascicular cambium to form a continuous ring which starts to give
secondary phloem outwards and secondary xylem inwards forming a
continuous ring of vascular tissues. Occasionally, the interfascicular
cambium divides to give only parenchyma and thus the bundles remain
separated by wide primary medullary rays.

The development of the secondary vascular elements increase in the
diameter of the stem which subjects the outer protective layers to
rupturing and is, therefore, usually accompanied by the formation of cork
cambium, phellogen, and the consequent formation of periderm.

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 SUBTERRANEAN ORGANS

The subterranean organs (the underground organs) of the plant are either
of the stem origin as rhizomes, corms, bulbs and tubers or of root origin
such as roots and root tubers.

A- The Root:
The root is the portion of the plant axis grows down wards into the soil,
characterized by:
 It never develops leaves.
 It shows no nodes and internodes.
 It bears no buds.
 It shows no chlorophyll.

Function of Root:
 Absorption of water and minerals from the soil to the stem.
 Support the plant to the ground.
 Serve as storage organ.

Types of Roots:
1. Primary Roots: Developing into tap-root.
2. Secondary Roots: Lateral branches of tap –root.

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3. Adventitious Roots: Arise from the stem.

4. Fibrous Roots: Very slender.

5. Storage Roots: Roots
swollened with reserve food
material.

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Structure of Root:
 Structure of young Root:
o Piliferous Layer: It is formed of a single row of thin walled cells
showing no stomata, no cuticle and no intercellular spaces. The
cells bear and produce root hairs.
o Cortex: Parenchymatous of an outer layer called exodermis.
o Endodermis: is the innermost layer of the cortex.
o Stele: Consists of pericycle enclosing the vascular bundles.

The vascular bundles are radial formed of alternating groups’
phloem and xylem separated with conducting parenchyma. It shows
no cambium or central pith. The xylem occurs in radial groups or
arches with the protoxylem directed outwards that is called
exarches.

 Structure of old root:
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. The cambium divides to give secondary
phloem outwards and much more xylary tissue, secondary xylem,
inwards. At the same time, phellogen is formed in the pericycle dividing
to give outer cork and inner wide phelloderm (periderm).
As a result of secondary thickening, the old dicotyledonous root is
formed of the following tissues:
o Cork.
o Phelloderm.
o Collapsed primary phloem.
o Secondary phloem.
o Cambium.
o Secondary xylem.
o Primary xylem groups in the center.

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B- Subterranean Stems:
The subterranean stem differs from the aerial stem in the following aspects:
 It bears scale and not foliage leaves.
 It bears adventitious roots arising generally from the nodes.
 It has growing point protected by scale leaves.

Moreover, it differs from the root as follows:
 It generally, has nodes and internodes.
 It bears scale leaves with axillary buds.
 Numerous adventitious roots are generally arising from the nodes.
 It has growing point protected by scale leaves.
 Histologically, it shows a central pith

Function of Subterranean Stem:
 They function as a mean of perennation.
 They serve as storage organs for reserve food materials.

Modes of branching:
 Monopodial: the main axis continues growing and produces the
successive yearly portions of the axis.
 Sympodial: the main axis stops growing as a result of destruction of
the apical bud. The main axis continues its growth by the
development of the axillary bud in the axial of scale leaves.

Types of Subterranean Stems:
 Rhizome: It shows nodes and short or long internodes, terminal bud
and aerial shoot, usually thick and branched.
 Stem-tuber: swollen with reserve food material, shows small scales
and buds.
 Corm: It is a shortened swollen erect under ground base of the stem,
covered with scale leaves and usually have a large apical bud and

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 small axillary ones. It usually produces a daughter stem above the
parent corm.
 Bulb: Reduced flattened discoid under ground stem crowned with
crowded fleshly scale leaves or their bases and having adventitious
roots.

Structure of Subterranean Stems:
Subterranean stems generally resemble in structure the aerial stems:

 The tegumentary Layer: is the outer protective layer and may be:
o Epidermis.
o Cork is few rows of regular layers of suberised or lignified cells
with no intercellular spaces.
o Metaderm consists of few rows of irregularly arranged suberised
cells derived from the outer layers of the cortex so may show
intercellular spaces.

 The Cortex: is parenchymatousfilled with reserve materials.

 The Endodermis: It is usually indistinguishable in Dicotyledones.

 The vascular bundles:
o Open: in Dicotyledones.
o Closed in Monocotyledones and the endodermis is distinct.

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 LEAF (Folium)
Definition:
The leaf may be defined as a lateral outgrowth on the stem, characterized
by its flattened form, thin texture, the presence of chlorophyll and having
buds or branches in its axil.

A complete leaf is composed of three parts:
 Lamina or Blade.
 Petiole or Stalk.
 Base: It is the part of the leaf by which it is attached to the stem and
is slightly enlarged.

Types of leaves:
 Cotyledons (Seed leaves).
 Prophylls (fore leaves): the first leaf born on a branch and it is simple
in form and structure.
 Foliage leaves: the ordinary green leaves.
 Bracts: leaves having a flower in their axils.
 Scale leaves: occur on all subterranean stems and on some aerial
ones. They are thin, membranous and devoid of chlorophyll.
 Floral leaves: include the colored sepals, petals, the stamens and
carpels.

FOLIAGE LEAVES
The foliage leaves are green in color due to the presence of chlorophyll. In
autumn, the leaves may acquire different color. The yellow and the orange
colors are due to the pigments, xanthophyll and carotene respectively. The
red color is due to the pigments xanthocyanins. The leaves may be cauline
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when they are spread apart on elongated aerial stem or radical when they
are crowded together about the top of the root, at the level of the ground
or just above it.

Duration of leaves:
The leaf is described as:
 Persistent: when live for one year or more, thus the plant is
described as evergreen.
 Deciduous: when falling in autumn, thus the plant bears no
expanded leaves during winter.

Phyllotaxis:
It is the distribution of the leaves on the stem. They may be:
 Alternate or Spiral: when the leaves are inserted singly at the node
regularly.
 Opposite: when the leaves are inserted in pairs at each node opposite
to each other.
 Whorled or Verticillate: when 3 or more leaves are inserted at each
node.

Stipules:
They are lateral outgrowth developed in the leaf base for protection of the
young axillary buds, and assist in photosynthesis. When the stipules are
present, the leaf is described as stipulate. When absent, it is exstipulate.

Petiole or leaf-stalk:
It serves to carry the lamina away from the stem and conducts materials to
and from the lamina. When it is present, the leaf is described as petiolate,
while when absent, it is sessile.

The lamina or leaf blade:

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Usually green in color, flattened, rarely needle-shaped. It may be:
 Simple: Consists of a continuous, undivided surface
 Lobed or divided: cut up into a number of lobes, connected together
by an undivided portion.
 Compound: Completely segmented into a number of separate
leaflets.

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37/ 98
 COMPOUND LEAVES
Compound leaves consists of 2 or more leaflets, either coming out from the
top of the petiole or arranged on a central axis called rachis, which is
continuous with the petiole and corresponds to the midrib of the simple
leaf. They may be are:

 Binate: with 2 leaflets only.
 Ternate: with 3 leaflets, 2 lateral and 1 terminal.
 Palmate: with 5 or more leaflets coming out from the top of the
petiole.
 Pinnate: with several leaflets arranged on the rachis. It may be;
o Paripinnate: With even number of leaflets in 2 rows, 1 on either
side of the rachis.
o Imparipinnate: the leaflets are odd in number and terminate
with a single leaflet.

SIMPLE LEAF
Shape:
 When the lamina has nearly the same width:
o Filiform: thread like.
o Acicular: needle-shaped.
o Linear: flat, long and very narrow.
o Oblong: flat and wide with edges parallel near the middle.

 When the lamina has the widest part near the base:
o Lanceolate: like linear but wider below the middle.
o Ovate: like the outline of an egg.
o Cordate: heart-shaped.

 When the lamina has the widest part near the apex:
o Obcordate: reversed heart-shaped.
o Obovate: reversed egg-shaped.
o Spathulate: flat like a spoon.

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Wh
en the lamina is symmetric
 Orbicular: circular.
 Elliptical: wide in the middle and symmetrically narrow and rounded
at base and apex.
 Oval: broadly elliptical.

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Apex:
 Acute: when the 2 sides of the margin form an acute angle at the tip.
 Acuminate: more tapering apex into a point and is longer than in
acute.
 Obtuse: blunt or rounded.
 Recurved: curved backwards.
 Mucronate: acute apex, terminating in a sharp horny point called
apiculus.
 Emarginate: with apical notch or incision.

Margin:
 Entire: even and smooth.
 Revolute: rolled back.
 Crenate: numerous rounded lobes.
 Dentate: having teeth, pointed straight outwards.
 Serrate: having sharp teeth directed towards the apex.

Base:
 Symmetric: equal on both sides of midrib.
 Asymmetric: unequal on both sides of midrib.
 Decurrent: when the base continuous downwards as wings along the
petiole.

Venation:
 Parallel: several veins run side by side parallel with each other.
 Reticulate: veins form network.

Surface:
Upper surface of the leaf is usually dark green while the lower is paler.
Midrib is usually prominent on the lower surface. It may be:
 Smooth: when wrinkled.
 Punctate: when dotted with projections from oil glands.
 Glabrous: when free from hairs.
 Pubescent or hairy: when covered with short hairs.
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Texture:
 Membranous: very thin.
 Papery: thin like paper.
 Coriaceous: thick and leathery.
 Succulent: thick and fleshy.

Microscopical Structure of the Leaf:
 The midrib region consists of the epidermis, cortical tissue, and
vascular system.
 The lamina region consists of epidermises and mesophyll.
 The epidermis is a protective layer; it may contain stomata or
trichomes.
 Trichomes or hairs, they are either covering (nonglandular) or
glandular trichomes.

Non-Glandular (covering) Trichomes:
They may be unicellular or multi-cellular.
 Unicellular: formed of 1 cell
 Multi-cellular: formed of more than 1 cell
o Uniseriate: formed of 1 row of cells
o Biseriate: formed of 2 rows of cells.
o Pluriseriate: formed of many rows of cells.
o Stellate: radiating unicellular.
o Branched: uniseriate body ending in 2 branches.
o Peltate: very short stalk surmounted by a plate-like structure of
closely joined cells.
o Candelabra: uniseriate axis from which arise numerous
unicellular branches of hairs.

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42/ 98
Glandular Trichomes:
 Uniseriate stalk and Unicellular or Multi-cellular head.
 Biseriate stalk and biseriate head or compositae glandular head.
 Pluriseriate stalk and a head with numerous, mostly 8, radiating cells.
 Branched stalk: each branch ending in a head.

Stomata:
According to the characters and arrangement of the surrounding epidermal
cells, stomata are classified into:
 Anomocytic or Ranuculaceous (irregular-celled): the surrounding cells
have no special arrangement.
 Paracytic or Rubiaceous (parallel-celled): the stomata are surrounded
by 2 subsidiary cells, having their long axes parallel to the osteole.
 Diacytic or Caryophyllaceous (cross-celled): the stomata are
surrounded by 2 subsidiary cells having long axes perpendicular to the
osteole.
 Anisocytic or Cruciferous (unequal-celled): the stomata are
surrounded by usually 3 subsidiary cells, 1 of which is distinctly
smaller than the others.

Mesophyll:
It is usually differentiated into:
 Palisade: cylindrical, columnarcells, perpendicular to the epidermis.
 Spongy tissue: closely packed chlorenchyma.

According to the disposition of the mesophyll, the leaf is described as:
 Isobilateral: symmetric mesophyll showing palisade layer abutting on
both upper and lower epidermises.
 Dorsiventral: asymmetric mesophyll, showing only 1 palisade beneath
the upper epidermis.

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45/ 98
Cortical tissue:
Present mainly in the midrib. It may be formed wholly of parenchyma or
collenchyma or of both.

Vascular system:
Vascular system consists of phloem towards the lower surface of the leaf
and xylem towards the upper surface. Medullary rays may be visible,
traversing the xylem and the phloem in the form of radiating lines.

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 The Flower

Definition:
Flower is a compressed fertile shoot (sexual branch) with crowded modified
leaves (floral leaves) and having shortened internodes.
Flowers are highly specialized complex organ adapted for the production of
the fruits and seeds i.e. for the propagation of the individual.
A complete flower is usually formed of four sets of floral leaves arranged on
an expanded apex of shortened axis called receptacle.

Flower is either considered as pedicellate when it is carried on its pedicel
(stalk) or sessile when it is inserted without pedicel.

Floral leaves are attached to the
receptacle from the periphary to its
center in the following order;
1. Non-Reproductive (Sterile) Parts:
a. Calyx, consisting of sepals.
b. Corolla, consisting of petals.

2. Productive (Fertile) Parts:
a. Androecium, male organ,
formed of stamens.
b. Gynaecium or pisitil, female
organ, composed of carpels.

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When the outer floral leaves (calyx and corolla) are alike, they constitute the
perianth. In many flowers, secretary glands or nectaries are present which
secrete sugary fluid called nectar.

In many cases, the flower arises in the axial of a leafy structure called bract
and the flower is described as bracteate. The flower is described as
ebracteate when there is no bract.
Bracts may be crowded in one whorl below the flowers and thus form
aninvolucre.

Kinds of Flowers:
1. According to Presence or Absence of Usual Parts (Calyx and Corolla).
a. Complete: when all the usual parts of the flower are present.
b. Incomplete: when lacking some of these usual parts.

2. According to Symmetry of Floral Leaves.
a. Actinomorphic or Regular: when segments of each whorl are
alike and regularly arranged i.e. the flower can be divided by a
number of radial longitudinal cuts in to equal halves as
Solanum, Rosa and Cloves.

b. Irregular: when the members of each whorl are not alike. In
such case, the flower may be either:
 Asymmetric: when all the segments are irregularly
arranged and not all alike, thus the flower can not be
divided into equal halves as in Cactus.
 Zygomorphic: when it can be divided only in one plane
into
equal
halves.

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3. According to Presence or Absence of both or any of Androecium and
Gynaecium.
a. Hermaphrodite (Bisexual): when both androecium and
gynaecium are present as in Cloves
b. Unisexual: when one of the sexual organs is present and the
second is wanted. The flowers which possess only the male
organ are described as the male flowers, while those possessing
the female organ are described as pistillate or female flowers.
c. Sterile: when both of the sexual organs are absent.

CALYX
Calyx is the outermost whorl of the floral series and functions as a
protective for the essential organs of the flowers and it is formed of sepals.
Cohesion of Sepals:
1. Polysepalous (free sepals)
2. Gamosepalous (united sepals)
The sepals are always green and foliaceous or represented by bristly hairs
forming the pappus as in Arnica.

COROLLA
Corolla is the inner whorl of the non essential floral leaves. It serves with
the calyx to protect the sexual organs and to attract the pollen carrying
insects.
The corolla consists of petals which is coloured modified leaves. Their
colour may be due to anthocyanin pigments responsible for the red, blue
and violet colors or the flavonoids responsible for yellow color as well as
the xanthophyll responsible for orange red color.
The white colour is due to the reflection of the light from the intercellular
spaces, and not to pigments presence.

Cohesion of Petals:
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 1. Polypetalous (free petals)
2. Gamopetalous (united petals)

Insertion of Corolla:
According to the attachment of the petals to the receptacle in relation to
the position of the ovary, corolla may be:
1. Hypogynous: corolla is inserted on the receptacle below the ovary
2. Perigynous: corolla is inserted on the edge of hollow receptacle which
surrounds the ovary but does not fuse with it.
3. Epigynous: corolla is inserted on the receptacle which has fused with
and closed over the ovary.

Forms of Corolla:
Corolla may be tubular when united in tube like structure or ligulate (strap
shaped).
ANDROECIUM
Androecium constitutes the male sexual organ i.e. one of the
essential floral organs. It is formed of stamens arranged
within or above the corolla. The complete fertile
stamen consists of;
anther
1. Filament: slender stalk bears the anther.
2.Anther; It is a swollen pollen-producing
filament
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 structure. It is divided in to two anther-lobes by the connective.
Stamens may be sterile i.e. not producing pollen grains and termed
asstaminode. Filaments may be absent and so anthers are said to be
sessile.

Cohesion of Stamens:

1. Fusion of filaments together with free anthers
a. Monodelphous: filaments fused in one group
b. Diadelphous: filaments fused in two groups
c. Tri, Tetra or Polydelphous: filaments fused in three, four or more
groups.
2. Fusion of anthers together with free filaments (Syngenesious)

Structure of Stamen:
1. Filament: consists of epidermis enclosing parenchymatous ground
tissue traversed by vascular strands.
2. Connective: a continuation of the filament tissues.
3. Anther-Lobes: consists of epidermis followed by parenchymatous
cells, thickened with spiral bands appearing in side view as lignified
bars and in surface view as lignified beads. This is known as a fibrous
layer.
4. PollenGrains: are microscopic in size, vary in
shape, commonly constant for each species and
constitute the most characteristic element in the Polen
grain
examination of powdered flower.

- Pollen Grain consists of a wall of two membranes,
an outer thick cutinized wall called the exine and
a delicate cellulosic inner membrane called the
intine.

- Exine may be either smooth as in Saffron, warty as
in Datura or spiny as in Chamomile.
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fibrous layer
 - Exine may show one, two, commonly three or more minute thin areas
or pits called germ pores from which the pollen-tube protrudes.

- Also, a narrow lanceolate areas or grooves called germinal furrows may
exist to accommodate the expansion and shrinkage of the pollen
grains due to humidity.

-The number of the germ pores and germinal furrows, characters of the
surface of the exine in addition to the shape and size are usually
constant and characteristic for each species.

GYNAECIUM
Gynaecium or pistil (female sexual organ) consists of carpels. According to
the number carpels, gynaecium is described as monocarpellary (one),
bicarpellary (two) or multicarpellary (more).

Cohesion of Carpels:
1. Apocarpous: free carpels.
2. Syncarpous: united carpels.
The typical carpel consists of ovary, style and stigma.
Insertion of Ovary:
1. Superior: when the floral parts are inserted on the receptacle below
or on the same level as the ovary in hypogynous and perigynous
flowers.
2. Inferior: when the floral parts are inserted on the top of the ovary as
in epigynous flowers.

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 PLACENTATION
It is the position of the placenta in the ovary. It may be:
1. Marginal: in simple monocapillary ovary when ovules are arranged on
fused margins of the carpel.
2. Parietal: in multicarpellary ovary when ovules are arranged on fused
margines of unilocular compound ovary.
3. Axile or Central: ovules are arranged on the central axis of the
multilocular ovary.
4. Basal and Apical: when there is one ovule attached at the base or
apex of unilocular ovary.

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 INFLORESCENCE
The flowers are usually aggregated on the plant forming an inflorescence.
The main axis of the inflorescence is called rachis. Inflorescence is classified
according to the method of branching in to the following:

1. Racemose Inflorescence: having monopodial branching and show the
youngest flower at the apex or at the center and the oldest flower at
the base or outside.
2. Cymose Inflorescence: have sympodial branching and show the oldest
flower being at the apex or at the center and the youngest near the
base or to the outside.

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 CAPITULUM

 It is a racemose inflorescence with very short, swollen, flattened or
conical axis on which the sessile florets are inserted. This axis is
wrongly spoken of as a receptacle.
 It is surrounded by involucre of bracts and there are two types of the
florets inserted on it.
 The centeral florets have tubular corolla and called tubular or
discflorets and ligulate corolla and called ligulate or ray florets.

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 TAXONOMY OF MEDICINAL PLANTS

Taxonomy: Is a science includes identification, nomenclature and
classification of object, usually of biological origin when limited to plants; it
is referred to as systematic botany.

Botany: Is the scientific study of plant life. It is called plant science,
phytology or plant biology.

Medicinal Plants:
They are those plants used to cure or prevent a disease. They exert their
action through certain chemical substances called active constituents.

The medicinal herb is collected from annual, biennial and perennial plants.
Annual: that lives for one season or one year and dies after production of
flowers, fruits and seeds.
Biennial: that lives for two seasons but not for more than two years
Perennial: that lives for more than two years or indefinitely.

Naming of Plants:
According to the accepted rule suggested by Linneaus, the binomial system
is used in which each plant is given two names, the first indicates the genus
(generic name) and always starts with a capital letter, and the second
represents the species and always starts with a small letter.

Taxonomical Classification of PlantKingdom:
The classification of this system depends upon the following:
 Individual plants similar in structure and life history are grouped into
species.
 Different species possessing general similarities to one another are
grouped into genus.
 Similar genera are grouped into a family.

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  Closely related families are grouped into an order.
 Related orders are grouped into a class.
 Related classes are grouped into a division.

The plant kingdom is divided into five phyla: Thallophyta, Bryophyta,
Pteridophyta, Gymnospermae and Angiospermae. These five phyla are
usually included under two big divisions; the Cryptogams (flowerless) or
plants with hidden sexual organs which include the first three phyla, and
Spermatophyta (or Phanerogams) including the last two phyla which
PlantKingdom

Cryptogams Phanerogams

allophyta Bryophyta Pteridophyta Gymnospermae Angiospermae

Algae Fungi Lichens Bacteria Monocotyledone Dicotyledones
comprise the flowering plants.

Phylum Thallophyta
The plant body is undifferentiated into stem, root and leaves and it is called
the thallus. They reproduce both sexually and asexually. Most members are
aquatic plants. It includes the sub-phylum algae, fungi, lichens and bacteria.

Phylum Bryophyta
Plants of this phylum show the beginning of alteration of generation both
sporophyte and gametophyte are combined in one plant. The sporophyte is
parasitic on gametophyte.

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 Phylum Pteridophyta
Plants of this phylum show distinct alteration of generation. Sporophyte
stage is larger, segmented into stem, leaves and roots and possesses true
vascular bundles.

Phylum Gymnospermae
Plants of this phylum bear naked ovules (ovules are not enclosed in ovaries
but lie on the surface of the sporophyll). Embryos have two to many
cotyledons.

Phylum Angiospermae
It includes the flowering plants. Ovules are enclosed in ovaries. According to
number of cotyledons, it is divided into Monocotyledoneae and
Dicotyledoneae.

Phylum Thallophyta
 This phylum includes most primitive plants
 Plants are small and many of them live in water (aquatic).
 The plant (thallus) is not differentiated into stem, root and leaves.
 Reproduction may be sexual or asexual (by spores).

Thallophyta includes four subphyla; algae, fungi, lichens and bacteria.

Subphylum Algae
 Algae are thallus plant (not differentiated into stem, leaves and root)
contain chlorophyll and other pigments, live on land or in water.
 They are classified into 3 orders according to their color
 Chrysophytae (green algae) e.g. Diatoms (which is used for
clarification, filtration and decolourization of fluids).
 Pheophytae (brown algae) e.g. Fucus and Laminaria. (which is
used for preparation of alginates which are used as tablet
distintigrants).
 Rhodephytae (red algae) e.g. Carrageen and Agar Agar
(carrageen has demulcent properties, used in pulmonary

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 complaints and chronic diarrhea. Agar used in bacteriologic
cultures and as laxative.

Subphylum Fungi
Fungi are non-vascular plants containing no chlorophyll; hence they cannot
build their own food. They are either parasitic (on living organisms),
saprophytic on dead organisms (living on decaying animal and plant
matters).

Some fungi are unicellular (as yeast) or have their bodies formed of thread
like filaments, known as mycelia. Cell wall is usually built up of a
nitrogenous material known as chitin. Reproduction takes place either
sexually or asexually.

Economic importance of Fungi:
 Some Fungi are used in alcoholic fermentation, alcoholic beverage
industry (beer)
 Some are involved in organic acid production (gluconic, citric, lactic
etc).
 Certain fungi are used in production of antibiotics or vitamins.
 Some are used in synthesis of cortisones and steroidal hormones.

Fungi are classified into the following orders according to the mode of
reproduction:
 Phycomycetes (Algal Fungi) (saprophyte)
 Hyphomycetes (Imperfect Fungi) (devoid of a known sexual stage)
 Ascomycetes (Sac fungi) e.g. penicillium and Ergot.
Penicillium produces penicillin which is antibiotic used for treatment of
some diseases. Ergot contains alkaloid Ergometrine which has oxytocic
action and the alkaloid Ergotamine is used as an analgesic in migraine.
 Basidiomycetes (Club fungi) e.g. Mushrooms.

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 Subphylum Lichen
These are fungi and algae living together in symbiosis with each other.

PHYLUM GYMNOSPERMS
They are group of woody plants. They differ from Angiosperms in several
aspects:
 They bear naked ovules on the edges or flat surfaces of leaves called
carpels, while Angiosperms bear covered ones.
 Each megaspore or embryo sac produces within itself a bulky
prothallus, in the upper portion of which originates one or more
archegonia, while in Angiosperms no recognizable prothallus exists.
 The stored food tissue within their seeds is prothallial tissue loaded
with starch, etc., while in Angiosperms seeds, endosperm is developed
from the endosperm nucleus.
 The mode of growth of their stems is always indefinite, while that of
Angiosperms is either definite or indefinite.
Pollination is by wind; pollen grains are born to micropyle of naked
ovule.

PHYLUM ANGIOSPERMS

Angiosperms are characterized by:
 The ovule are not exposed directly to the air but enclosed in the ovary
of the carpel.
 Pollen grains are received on the stigma and pass through the style to
the ovary to fertilize the ovule (not directly on ovule as in
Gymnosperms).
 The flowers are arranged on a shortened axis to bring the floral leaves
close together and are not separated at different levels along the axis
as in Gymnosperm.
 The stamen and carpels are absolutely essential, the calyx being
largely protective and usually green, the corolla usually serving to
attract insects that help in cross pollination.
 Angiosperms are mostly herbaceous, annual or biennial forms,
whereas Gymnosperms are mostly woody perennials.
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 The embryo may be straight or variously curved, large or small, and
more or less embedded in the endosperm or occupying the whole
seed.
 The vascular bundles of the stem are collateral or bicollateral, open or
closed.
According to the number of cotyledons, this phylum is subdivided into
subphyla; Monocotyledons, with a single cotyledon and dicotyledons
with two cotyledons.

Item Dicotyledones Monocotyledones

Habit Herbaceous or woody. Mostly herbaceous.

Leaves shape commonly
Leaves shape characteristic
oblong or linear, vennation,
for families or species,
Leaves parallel, often sheathing at
venation,reticulate, petiolate
the base, sessile, entire
, stipulate leaf sheath absent.
margin and extipulate.

Roots Tap Root adventitious

Usually consists of a ring of Closed, collateral or
open primary bundles with a concentric of numerous
Vascular
cambium, stem scattered bundles, no
System
differentiated into cortex and differentiation into cortical
stele. and stellar regions in stems.
Parts are usually in tetra or Parts are usually in Trimerous
Flower
penta merous. or multiples of three.

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 Basically tricolpate (having Basically monocolpate
Pollen
three furrows or pores). (having one furrow or pore).

Embryo Two cotyledons. One cotyledon.

Is wanting (if present, they
Secondary Due to activation of
form new closed v.b not due
growth cambium.
to cambium).
The major differences between these two classes are summarized in the
following table:

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63/ 98
 SUBPHYLUM MONOCOTYLEDON
Family Zingiberaceae
They are perennial herbs usually with fleshy rhizome and thickened roots.
The leaves are large elliptical with parallel venation, and may be radical
with a sheath that is folded, giving the appearance of a stem. The flowers
are hermaphrodite, Zygomorphic, trimerous. The perianth is differentiated
into two trimerous whorls that form caylex and corolla. Ovary inferior,
trilocular with axile placenta or unilocular with pariatal placenta.

The fruits are trilocular capsule. Seeds are albuminous with perisperm and
endosperm, rich in starch, show a raphe and arillus. Embryo is small and
embedded in the endosperm. The seed shows sclerenchymatous layer in
the testa.

The presence of aromatic and pungent principles and secretion cells
containing volatile oil is characteristic feature of the family.

Examples of medicinal plants belonging to this family and their use are:
 Cardamom: Used as aromatic, carminative and flavoring agent.
 Ginger: Used as condiment, carminative, aromatic stimulant,
respiratory and gastro intestinal disorders.

SUPHYLUM DICOTYLEDONS
Family SOLANACEAE or Night Family

 Morphological Characters:
They are annual herbs or shrubs with cymose inflorescence.
 The leaves are alternate or opposite, exstipulate and often hairy,
entire or more or less lobed and adnated to stem.
 The flowers are grouped in cymes. They are actinomorphic,
pentamerous and perfect.
The stamen is epipetalous. The ovary is bicarpellary, syncarpous.
Superior, the style is simple and the stigma is simple and
bilobed.

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  The fruit is capsule or berry.
 The seeds are albuminous with curved or coiled embryo.
 Anatomical Characters:
 The stomata are anisocytic.
 The non-glandular trichomes and the characteristic club-shaped
glandular ones (clavate).
 Presence of perimedullary phloem.
 Absence of special internal secretory tissue.
 Presence of calcium oxalate in different forms.
 Plants are rich in mydriatic alkaloids.

Plants belonging to this family are:
 Hyoscyamus: used as an antispasmodic and sedative.
 Capsicum: used as antirheumatic.
 Tobacco: used as insecticide.

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 Chromatography

Chromatography is defined as a physical method of separation, in
which the components to be separated are distributed between two
phases: one phase constitutes the stationary phase and the other is the
mobile phase which moves through the stationary phase in a counter-
current manner. Each phase competes with the other phase for the
components of the mixture. Accordingly, this will result in differential
migration and hence separation of the components of the mixture.

Classification of chromatography:
According to the nature of the mobile phase, chromatography can be
divided into two major divisions, liquid and gas chromatography.
A- Liquid Chromatography:
It is further subdivided into six subdivisions:
1- Adsorption chromatography:
In this type of chromatography, separation depends on the
distribution of the components of the sample mixture between
solid stationary phase and liquid mobile phase.
2- Partition chromatography:
The separation of the components of the mixture is dependent on
the differences in the partition coefficient of the components of
the mixture between an aqueous stationary phase and an
immiscible organic liquid mobile phase (liquid- Liquid).
3- Ion Exchange chromatography:
4- Zone electrophoresis
5- Gel chromatography
6- Affinity chromatography

B- Gas chromatography:
Where the mobile phase is an inert gas as nitrogen or helium.
The stationary phase may be either solid in gas -solid chromatography
(GSC) or may be a liquid in gas- liquid chromatography (GLC).
The first one is an adsorption while the second is partition process.

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 It is mainly used for separation of gases and volatile substances.
The non volatile substances can be analyzed by gas chromatography
after the preparation of their volatile derivatives.

Chromatographic techniques:
A- Planar chromatography:
1- Thin Layer Chromatography (TLC):
In TLC, the stationary phase is a thin layer of solid
coating material (silica, alumina and kieselguhr) on a
suitable supporting surface (glass plates, plastic or
aluminum sheets).
The layer can act as an adsorbing stationary phase in
adsorption chromatography or functioning as an inert
support for a thin liquid film of the liquid stationary phase
in partition chromatography.
According to the nature of the adsorbent, TLC could
be adsorption or partition.

The practical steps of thin layer chromatography may be
summarized as follows:
a- Preparation of the layers.
b- Application of samples. (spotting using micropipettes).
c- Development of the chromatoplate in the proper
solvent(s).
d- Visualization (location and detection of spots) using
universal or specific methods.

2- Paper chromatography:
Based on partitioning, where strips of filter paper are used
( act as support) as carrier for the liquid stationary phase.
The aqueous phase is usually the stationary phase, while
the mobile phase is usually the organic phase.
Similarly, the practical steps of paper
chromatography can be summarized as follows:
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 a- Preparation of the paper.
b- Application of samples (spotting) using micropipettes.
c- Development in the suitable solvent system in a
saturated chamber.
d- Visualization of the developed chromatogram.

Rf values (Rate of Flow):
A value calculated in planner chromatography. It is an indication to
the migration of the components in the chromatographic system. It can be
used for the identification of substances. It is always less than one.

Rf = Distance travelled by the substance from start line
Distance travelled by the solvent from start line

The Rf values are used for identification of compounds.

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B- Column Chromatography:
It could be used for all types of chromatography.

1- Gravity column chromatography:
In column chromatography, glass or metallic tubes are filled with
the packing materials.
It is generally used as a separation technique.

The practical steps of column chromatography may be
summarized as follows:
a- Preparation of the column (Column packing).
b- Application of the sample.
c- Elution of the material.
d- Analysis of collected fractions using TLC and PC.

2- High Performance (Pressure) Liquid Chromatography (HPLC):
Reduction of the particle size of the stationary phase resulted in
an increase of the separation power. However, the flow rate of
the mobile phase will considerably decrease. In HPLC, the used
stationary phase has very small particle size and high pressure is
used to increase the mobile phase flow rate. In such system, the
columns are metallic.

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 The crude drugs which reach the market and pharmaceutical
industries will have passed through different stages that have some
effect in the nature and amount of active constituents responsible
for therapeutic activity.
 Those stages are to be concerned more in order to make a drug
useful to the mankind by all means.

 The quality of each final product is guaranteed by the use of raw
materials of a standard quality, defined process of production, and
validated equipment. Quality control of herbal drugs and herbal
isolates (tinctures, extracts, and essential oils) is done according to the
requirements of Pharmacopoeia and other relevant regulations. The
scope of phytopreparation quality control depends on its
pharmaceutical form.

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 DOCUMENTATION

 The producer should maintain its standard operating procedures for
production and quality management.
 Detailed records for the entire production process of each crude drug
should be documented, and if necessary, photos or images might be
attached, which should include, origin of seeds, strains and
propagation materials, production techniques and process, sowing
time, quantity and area of medicinal plants, seedling, transplantation,
and the type, application schedule, quantity arid usage of fertilizer,
quantity, application schedule and usage of pesticide, microbicide or
herbicide, Collection time and yield, fresh weight and processing,
drying and drying loss, transport and storage of medicinal parts.
 Quality evaluations of crude drugs: description of macroscopic
characters of crude drugs and records of test results. All these
records, production plans and their details, contracts or agreements
etc. should be filed and kept properly by a designated

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