Collection of plant material: Dried leaves were obtained and
authenticated by Dr.
----------------------------------------------. (RRI/ BNG / SMP/
Drug Authentication / 200809 /314) Bangalore.. Pharmacognosy:
Morphological examinations: Organoleptic evaluation: Color, Size,
Odour and taste were studied. Macro morphological evaluation of
leaves or leaflets. Some of characters which are studied include
surface appearance and texture, Lamina Structure: Shape of lamina,
Margin, Apex, Base, Venation. Microscopic evaluation: Preparation
of Crude drug sample for microscopical examination: The microscopic
examination of crude drug aims at determination of the chemical of
the cell wall along with the determination of the form and chemical
nature of the cell contents. Thus it determines the size, shape and
relative structure of the different cells tissues in the plant
drug. Before taking the TS if samples are dried then it requires
softening before preparation for microscopical studies. It may be
done by exposing the samples in moist condition (for leaves and
flowers) or by boiling in water (for bark, root and wood).
Sometimes water soluble components can be removed by soaking in
water e.g., starch grain is gelatinized by heating with water.
Procedure followed to take the sections of Stem: Small piece of
stem was placed in beaker containing water and heated over m a
Bunsen flame for few minutes. This softens the hard drug sample,
then thin TS was taken (Transverse section was obtained by cutting
along the radial plane of a cylindrical portion of the stem).
Staining and mounting of sections: The thin sections are placed in
a watch glass containing chloral hydrate solution. It was boiled to
clear the sections. Then chloral hydrate was removed,
phloroglucinol and concentrated hydrochloric acid were added to
stain the sections. One thin section was taken out and mounted on a
clean glass slide. A drop of glycerin was added and covered with
the covered slip. This slide was observed under microscope.
Procedure followed to take the powder microscopy leaves: Dried
leaves were powdered and sieved to get a fine powder. This fine
powder was placed in a watch glass containing chloral hydrate
solution, boiled to clear the powder. Then it was stained using
phloroglucinol and concentrated hydrochloric acid. After staining,
the powder was taken on a clean slide with the solution, then the
slide was covered with cover slip and excess solution was wiped
with the help of filter paper/tissue paper. This slide was observed
under microscope. Procedure followed to take the leaf sections A
part of the leaf passing through the midrib was cut. The cut
portion of leaf was inserted between the wedge openings of the
potato. The portions of leaf protruding the surface of the pith are
cut. The vertical sides of the pith are tapered off upwards.
Sections are taken by moving the blade back and forth and placed in
watch glass
containing water. Thin sections are selected and placed in
chloral hydrate and are cleared by boiling. Cleared sections are
stained by using phloroglucinol and concentrated hydrochloric acid.
One thin section was taken out and mounted on a clean glass slide.
A drop of glycerin was added and covered with the cover slip. T
This slide was observed under microscope and snaps are taken. Leaf
constants: Determination of Stomatal number Stomatal number is the
average number of stomata per square mm of the epidermis of the
leaf (Table no. 8 page no. 84). Procedure: Piece of leaf (middle
part) was cleared by boiling with chloral hydrate solution. The
upper and lower epidermis was peeled separately. The peeled
epidermis was placed on slide and mounted with glycerin water.
Camera lucida and drawing board was arranged for the drawings. With
the help of stage micrometer 1 sq. mm was drawn. The prepared slide
was placed on the stage, epidermal cells and stomata are traced.
The no. of stomata lying in the area of 1 sq. mm are counted
including the cell if at least half of its area lying with in the
square. Average no. of stomata per sq. mm is calculated by tracing
four different fields. Stomatal number is affected by various
factors like age of the plant, size of the leaf, environmental
conditions etc. Stomatal index is not much affected by these
factors. It is relatively constant. Hence it is more significant in
the evaluation o of a leaf drug. Determination of Stomatal Index:
Stomatal Index: It is the percentage which the numbers of stomata
form to the total number of epidermal cells, each stomata being
counted as one cell. Stomatal i index can be calculated by using
following equation. Stomatal index = S X 100 /E+S Where S= the
number of stomata in a given area of leaf; and E = the number of
epidermal cells (including trichomes) in the same area of leaf.
Procedure The first seven steps are similar as mentioned in the
determination of stomatal number. The no. of stomata and the no. of
epidermal cells in each field was counted. Stomatal index was
calculated using the above formula. V Values for upper and lower
surface (epidermis) were determined separately. Determination of
palisade ratio: Palisade ratio is the average number of palisade
cells beneath one epidermal cell of a leaf. It is determined by
counting the palisade cells beneath four continuous epidermal
cells. Procedure: A piece of leaf was cleared by boiling in chloral
hydrate solution. Camera lucida and drawing board was arranged for
the drawings. The four cells of the epidermis are traced off. By
focusing down to palisade layer, sufficient cells are traced off to
cover the epidermal cells. The no. of palisade cells under the four
epidermal cells is counted. (Including the palisade cells in the
count when more than half is covered in the area of epidermal
cell).
Average no. of cells beneath a single epidermal cell are
calculated which gives the palisade ratio. By focusing different
part of the leaf, the same was traced and the average was c
calculated to get the palisade ratio of the leaf. Determination of
vein-islet number: A vein islet is the small area of green tissue
surrounded by the vein-lets. The vein-islet number is the average
number of vein-islets per square mm of a leaf surface. It is
determined by counting the number of vein-islets in an area of 4
sq. mm of the central part of the leaf between the midrib and the
margin. Procedure: A piece of leaf was cleared by boiling in
chloral hydrate solution. Camera Lucida and drawing board was
arranged for the drawings. With the help of stage micrometer 1 sq.
mm was drawn. The cleared leaf was mounted on the slide and a drop
of glycerin water was added then covered with cover slip. The above
prepared slide was placed on the stage of the microscope. Veins are
traced which are included within the square. The outlines of those
islets which overlap two adjacent sides of the square are also
traced. The no. of vein-islets in the sq. mm is counted. The islets
which are intersected by the sides of square are included on two
adjacent sides and excluded on other two sides. The average no. of
vein islets from four squares are found, and average no. of v vein
islets are calculated. Determination of Vein-let termination
number: It is defined as the no. of vein let termination per sq. mm
of the leaf midway between midrib of the leaf and its margin. A
vein termination is ultimate free termination of vein-let.
Procedure: Same as for the determination of the Vein-islet number.
The average no. terminations present with in the square was counted
from four different get the value for one sq. mm. surface, the
of vein squares to
Physico chemical parameters: Determination of moisturecontent
(Loss on drying ): About 1g Jasminumgrandiflorumpowderwas weighed
and placed in Petri plate. D Dried in an oven at 105 C for 1 hr.
Cooled in desiccator, loss in weight was recorded as moisture. D
Determination of ash values: Ash values: Residue of the crude drugs
after incineration contains mostly inorganic salts known as ash.
Used to determine quality and purity of a crude drug. Ash contains
inorganic radicals like phosphates, carbonates and silicates of
sodium, potassium, magnesium, calcium etc. some times, inorganic
variables like calcium oxalate, silica, carbonate content of the
crude drug affects total ash. Such variables are then removed by
treating with acid and then acid insoluble ash value is d
determined. Types of ash values are Total ash: carbon and organic
matter present in the drug is converted to ash at
temperature 450 C. It mostly contains carbonates, phosphates,
silicates and s silica. Acid insoluble ash: Total ash may be
treated with 2N HCl, which removes many i inorganic salts to yield
mainly silica in the residue of acid insoluble ash. Water soluble
ash: It is produced by separating the water soluble material from
the total ash. In this case most of the water insoluble salts which
may contribute i in total ash are removed to find water soluble ash
content. Procedure for determination of total ash value: Accurately
2g of course powder was weighed in a tared silica crucible. The
drug is incinerated by gradually increasing the heat in a muffle
furnace at 450 C for some hours. After complete incineration, it
was kept in a desiccator. The weight of ash with silica crucible
was noted. Then the total ash was c calculated in terms of
percentage. Procedure for determination of acid insoluble ash
value: Followed procedure as per the steps mentioned in the
procedure for determination of total ash value of a crude drug.
Further Using 25 ml. of dilute hydrochloric acid, total ash was
washed in to a 100 ml beaker. Beaker was boiled for 5 minutes.
Filtered through an ash less filter paper, residue was washed twice
with hot water. Filter paper placed in an silica crucible then,
incinerated by gradually increasing the heat in a muffle furnace at
450 C for some hours. After complete incineration, it was kept in a
desiccator to cool. The weight of acid insoluble ash with silica
crucible was noted. Then the a acidinsoluble ash was calculated in
terms of percentage. Procedure for determination of water soluble
ash value: This is determined in a similar way to acid insoluble
ash, using 25 ml. of water in place of HCl. Determination of
extractive values: Extractive values: Useful for the evaluation of
a crude drug. Gives idea about the nature of the chemical
constituents present in a crude drug. Useful for the estimation of
chemical constituents, soluble in that particular s solvent used
for extraction. Procedure for Determination of alcohol soluble
extractive values: About 5 g of powdered was weighed and
transferred to a conical flask. 100 ml of the 90 % alcohol was
added and closed with the cork. Kept aside for 24 hours with
shaking frequently. Filtered, 25 ml of the filtrate was collected
and transferred to a weighed, thin porcelain dish. Evaporated to
dryness on a water bath and dried completely in an oven at 100 C.
Kept in a desiccator to cool, then percentage w/w of extractive
with reference to a air dried drug was calculated. Procedure for
Determination of water soluble extractive value: Steps are followed
similar to those mentioned in the previous procedure Chloroform w
water was used instead of alcohol. Extraction procedures The
powdered plant material was successively extracted by using Soxhlet
extractor.
Lab scale extraction procedure: 14 g of powdered was charged in
a thimble made of cellulose it was placed in a central compartment
of Soxhlet assembly. 200 ml of solvent was placed in a lower
compartment and a reflux condenser is attached above the central
compartment. Note: Each component of the set up was a separate item
of glass ware which was assembled together with an appropriate
content, to make a complete apparatus. The solvent in the lower
container was heated to boiling. The vapour passes through the
sidearm up into the reflux condenser. Here the vapour liquefied and
drips into the thimble containing the material to be extracted. The
warm solvent percolates through the material and the walls of the
thimble and the extracts gradually collect in the central
compartment. Once the height of the extract reached the top of the
siphon, the entire liquid flowed through this and back to the lower
solvent container. The process is than repeated. The extract
collected in the lower vessel, gradually becoming more and more
concentrated The vapour rising from the heated extract is pure
solvent vapour and so the liquid dripping into the material from
the condenser is essentially pure solvent, though derived from the
extract. After complete extraction the lower vessel was removed,
solvent recovered and the extract is concentrated and percentage
yield was calculated. The solvents were recovered by using simple
distillation method. The charged drug from the central compartment
was removed, dried, recharged and extracted with benzene. By using
Soxhlet extractor exhaustive extraction with a series of solvents
of i increasing polarity was done. Solvents used with increasing
polarity: Petroleum ether, Benzene, Chloroform, ethanol and finally
water. Large scale procedure: Steps are followed similar to those
mentioned in the lab scale procedure, using 470 g of powdered drug.
The percentage yield at lab scale and pilot scale is given in table
no. After extraction phytochemical screening was done and presence
of constituents was d determined. Preliminary phytochemical
screening: The crude extract obtained by successive extraction from
petroleum ether, benzene, chloroform, ethanol and aqueous
extraction are subjected to preliminary p phytochemical
screening.
Q Qualitative chemical examination of extracts General method
followed for screening of the constituents present in the
extract
is as
follows:-----------------------------------------------------------------------------------------------Detection
of carbohydrates: Extracts were dissolved individually in 5ml of
distilled water and filtered. The f filtrates were used to test the
presence of carbohydrates. Molischs test: Filtrates were treated
with 2 drops of alcoholic naphthol solution in a test tube and 2ml
concentrated sulphuric acid was added carefully along the sides of
the test tubes. Formation of violet ring at the junction indicates
the presence of carbohydrates. Benedicts test: Filtrates were
treated with Benedicts reagent and heated on water bath. Formation
of an orange red precipitate indicated the presence of reducing
sugars. Fehlings test: Filtrates were hydrolyzed with dilute
hydrochloric acids, neutralized with alkali and heated with
Fehlings A and B solutions. Formation of red precipitate indicates
the presence of reducing sugars. Detection of alkaloids: Extracts
were dissolved individually in dilute hydrochloride acid and
filtered. The filtrates were tested carefully with alkaloid
reagents. Mayers test: Filtrates were treated with Mayers reagent
(potassium mercuric iodide), formation of a yellow cream
precipitate indicate the presence of alkaloids. Wagners test:
Filtrates were treated with Wagners reagent (iodine in potassium
iodide) and observed. Formation of brown/reddish brown precipitate
indicates the presence of alkaloids. Dragendroffs test: Filtrates
were treated with Dragendroffs reagent (solution of potassium
bismuth iodide). Formation of red precipitate indicates the
presence of alkaloids. Hagers test: Filtrates were treated with
Hagers reagent (saturated picric acid solution) Formation of yellow
colored precipitate indicates the presence of alkaloids. Detection
of phytosterols: Salkowskis test: The extracts were treated with
chloroform and filtered separately. The filtrates were treated with
few drops of concentrated sulphuric acid, shaken and allowed to
stand. If the lower layer turns red, sterols are present. If lower
layer turns golden yellow triterpenes are present. Libermann
Burchard test: The extracts were treated with chloroform solution
and few drops of conc. 1 ml of acetic anhydride solution followed
by sulphuric acid. A blue green colour shows the presence of
phytosterols. Detection of glycosides: Extracts were hydrolyzed
with dilute hydrochloric acid, and the hydrolysate was subjected to
glycosides tests. Test for cardiac glycosides: Legals test: To the
hydrolysate 1 ml of pyridine and few drops of sodium nitroprusside
solution are added and then it is made alkaline with sodium
hydroxide solution. Colour change shows the presence of
glycosides. Liebermannstest:3 ml. of extract with 3 ml. acetic
anhydride was heated, cool then added few drops of conc. sulphuric
acid. Blue color appears in presence of bufadenolide. Test for
deoxysugars (Keller killiani test): To 2 ml. of extract, glacial
acetic acid, one drop of 5% FeCl3 and conc. H2SO4 was added.
Reddish brown color appears at junction of two liquid layers and
upper layer appears bluish green. Test for anthraquinone
glycosides: Borntragers test: Hydrolysate is treated with
chloroform and the chloroform layer is separated. To this, equal
quantity of dilute ammonia solution is added. Colour change in the
ammoniacal layer shows the presence of O glycosides. Modified
Borntragers Test: The extracts were treated with ferric chloride
solution and heated on boiling water bath for about 5 min. The
mixture was cooled and shaken with equal volume of benzene. The
benzene layer was separated and treated with half its volume of
ammonia solution. The formation of pink or cherry red color in the
ammonical layer indicates the presence of C glycoside. Detection of
saponins: Froths test: The extracts were diluted with distilled
water to 20 ml shaken in a graduated cylinder for 15 min. The
formation of 1 cm layer of foam indicates the presence of saponins.
Detection of phenolic and tannins: Ferric chloride test: The
extract was treated with few drops pf neutral ferric chloride
solution. The formation of bluish black color indicates the
presence of phenolic nucleus. Gelatin test: To the extract, 1%
gelatin solution containing sodium chloride was added. The
formation of white precipitate indicates the presence of tannins.
Test for flavonoids: Lead acetate test: The extracts were treated
with few drops of lead acetate solution, formation of yellow
precipitate indicates the presence of flavonoids. Alkaline reagent
test: The extracts were treated with few drops of sodium hydroxide
separately. Formation of intense yellow color, which becomes
colorless on addition of few drops of dilute acid, indicates the
presence of flavonoids. Shinoda test: The extracts were treated
with few fragments of magnesium metal separately, followed by drop
wise addition of concentrated hydrochloric acid. The formation of
magenta color indicates the presence of flavonoid. Detection of
proteins and amino acids: Millons test: The extracts were treated
with 2ml of Millons reagent. The formation of white precipitate,
which turns to red upon heating, indicates the presence of
proteins. Ninhydrin test: To the extracts, 0.25% ninhydrin reagent
was added and boiled for few minutes. Formation of blue color
indicates presence of amino acid. The results of qualitative
chemical analysis of the extracts are tabulated in the Table No.
Optimization of TLC solvent system: Different solvents systems were
tried for developing a TLC system for identification of
constituents in the extract based on the literature survey and
keeping in mind the chemical nature of the constituents. The
details are given in the below table no.
The following solvents were used for the development of the TLC
system: Chloroform Chloroform: Benzene: Ethyl acetate 0.5:0.5:1
Chloroform : methanol (7:3) Chloroform: methanol: Ethyl acetate
0.5:0.5:1 Toluene: acetone: formic acid (6 : 6: 1) Toluene: ethyl
acetate: formic acid (5:5:1) Benzene: acetone (1: 0.1) Benzene :
chloroform (1: 0.1) 85% Acetonitrile T Toluene : Ethyl acetate:
Glacial acetic acid (1.4 : 0.4 : 0.2) Isolation of
phytoconstituents from extracts: The constituents of pet. ether and
chloroform extract were isolated by column chromatography and
identification and purity determination were done by thin layer
chromatographic techniques. Column chromatography The Chloroform
extract was subjected to column chromatography using different
solvent systems. The fractions collected were further
chromatographed, to know the no. of constituents present. Silica
gel G as used as stationary phase. Column chromatography was done
by using a glass column. The dimension of the column was 5X15 cm in
height and 4 cm in diameter. The column was packed with silica gel
by wet packing method wherein a padding of cotton was placed at the
bottom of the column and then it was filled with eluting solvent of
the lowest polarity (pet ether). Then the required amount of
stationary phase (silica gel) was poured into the column to form a
bed of silica. The extract was then poured on to the bed of silica,
a layer of cotton covered it again and more amounts of solvents
were poured over it, the column was then eluted gradiently. The
general principle applied in column chromatography consisted of
following steps: 1.Precolumn preparation: The precolumn preparation
included adsorption of the selected extract/ fraction, charging and
saturation of the column. a. Adsorption of the extract: The extract
selected for fractionation was adsorbed on stationary phase in
ratio 1:1. b. Charging of column: A glass column was selected and
rinsed with the solvent. A cotton layer was placed at the bottom
and the column was charged with the solvent and stationary phase.
The silica gel was used in the ratio (1:2) of the extract to make
the gel bed for complete separation. The solvent was eluted up to
the level of column bed and the dried extract was charged in the
column. Another layer of cotton was placed over the charged matter
to prevent the disturbance of the extract bed while pouring the
eluting solvent from the top. c.Saturation of the column: The
charged column was left for 4 hrs. for complete s saturation and
removal of air bubbles to make the bed static. 2. Elution: The
charged column was then eluted with different mobile phases with
gradual increase in polarity. The fractions collected and the
solvent recovered by simple distillation. All the concentrated
fractions were subjected to TLC for the i identification of the
desired bands. Column Requirements: Stationary phase silica gel G
(60120 mesh) Mobile phase Pet ether, Benzene, Ethyl acetate,
Chloroform, MeOH, EtOH Charged material Chloroform fraction. Volume
of each fraction 100 ml to 500 ml. Visualization Iodine, 10%
Ethanolic sulphuric acid, anisaldehyde sulfuric acid, ferric
chloride reagent, dragendroff reagent. Details of column are
tabulated in table no.12.
Procedure: The column was first eluted with 100% pet ether. The
polarity of mobile phase was gradually increased with Benzene,
Ethyl acetate, MeOH, EtOH. The fraction collected was concentrate.
The desired concentrated fractions were screened for
phytoconstituents. The desired concentrated and dried fractions
were kept in container with suitable label and kept for further
use. The details of collected fraction are given in flow chart no.
1 and 2. Purification of compounds: From column Purification of
compound I: The fraction 7181 of column (ptether: ethyl acetate
80:20 ), after concentration, it has formed crystals, was buff
colored and shown single spot with the mobile phase Toluene:
acetone: formic acid (6 : 6: 1) Purification of compound II: The
fraction 91101 of column (pet. ether : ethyl acetate 80:20), after
concentration, it has formed crystals, remaining solution was
decanted. The decanted solution was solidified and it was buff
colored and shown single spot with the mobile phase Toluene:
acetone: formic acid (6 : 6: 1). Purification of compound III &
IV The ethanolic extract gave four spot which mixed and separate
the all spot by preparative TLC which yielded white coloured
compounds III & IV. Solubility profile of the isolated
compounds: The isolated compounds were analyzed for their
solubility in different solvents. The concentration used for
solubility was 1mg/ml of solvent. Their solubility profile are
tabulated in table no.15. The solvents used were pet ether, CHCl3,
acetone, methanol and distilled water. Determination of melting
points of the isolated compound: Organic chemist not only to
identify it, but also to establish its purity uses the melting
point of a compound. The melting point indicates purity in two
ways. First, the purer the material, the higher its melting point.
Second, the purer the material, the narrower its melting point
range. ApparatusThermonic (liquid paraffin). Sample Compound I,
Compound II, Compound III and Compound IV. Procedure The isolated
compounds were subjected to melting point analysis wherein a
capillary tube, closed at one end, was taken and a small amount of
the sample was placed into it. The capillary tube was then dipped
at the closed end into liquid paraffin along with a thermometer.
The paraffin was then heated and the temperature at which the
sample just started to melt and the temperature at which it
completely melted was taken as the melting point temperature range
for the sample. It was noted down. The results are given in Table
no: 17. UV Spectroscopy of the isolated compound: The UV spectrum
of compound I, II, III and IV is given in Page No. 123124.
Instrument: UV Visible Spectrometer. Shimadzu Screening of plant
extracts for anti-microbial activity: Antibacterial activities of
different extracts were studied by the disc diffusion method.
Preparation of extracts The plant part was powdered and extracted
successively with different solvents by increasing then polarity,
in a Soxhlet extractor. The plant extracts were filtered through
Whatman No. 1 filter paper into beaker. The filtrates were dried
until constant dry weights of each extracts were obtained. The
residues were stored at
4C for further use. Test Organisms The pure cultures of bacteria
maintained in the College Microbiology Laboratory were used for the
microbiological work. The test organisms were maintained on
Nutrient agar medium. The test organisms used for screening are
Bacteria, Staphylococcus aureus. Bacillus subtilis. Escherichia
coli. P Pseudomonas aeruginosa. Common microorganism: 1.
Staphylococcusaureus: Gram positive cocci about 1m in diameter.
They are mainly arranged in group like structure, especially when
examined in pathological specimen may occur as a single or pair of
cells. They are non sporing, non motile, and usually non capsulate
when grown on agar for 24hrs. at 37 C. Individual colonies are
circular, 23mm in diameter with a smooth, shiny surface; colonies
appear opaque and are often pigmented (golden yellow, fawn or
cream), though a few strains are un pigmented. Staphylococci are
salt tolerant and can be selectively isolated from materials such
as faeces and food by use of media containing 710% Nacl.
Pathogenesis: S.aureus present in nose of 30% of healthy people and
may be found on the skin. It causes infection most commonly at
sites of lowered host resistance. E.g.: damaged skin or mucous
membranes. Infections caused by S.aureus: Pyrogenic infections:
Abscesses, Impetigo, Mastitis, Bacteraemia, Osteomyelitis,
Pneumonia Endocarditis. Toxin mediated infections: Penicillinase,
Cephallosporins, Aminoglycosides, Tetracyclins, Macrolides, F
Fluroquinolines, Rifampicin, Trimethoprim, Chloromphenicol Scalded
skin syndrome, Pemphigus neonatorum, Toxic shock syndrome, Food
poisoning. Sensitivity to Antibiotics: 2. Bacillus subtilis:
Bacillus subtilis, known as the hay bacillus or grass bacillus, is
a Gram positive, catalase positive bacterium commonly found in
soil. A member of the genus Bacillus ,B.subtilisis rod shaped, and
has the ability to form a tough, protective endospore, allowing the
organism to tolerate extreme environmental conditions.
Pathogenesis: B. subtilis is not considered a human pathogen; it
may contaminate food but rarely causes food poisoning. B.subtilis
produces the proteolytic enzyme subtilisin. B.subtilis spores can
survive the extreme heating that is often used to cook food, and it
is responsible for causing ropiness a sticky, stringy consistency
caused by bacterial production of long chain polysaccharides in
spoiled bread dough. Uses Colonies of B.subtilis grown on a culture
dish in a molecular biology laboratory. B.subtilis is used as a
soil inoculant in horticulture and agriculture. Enzymes produced by
B.subtilis and B.licheniformisare widely used as additives in
laundry detergents. Its other uses include the following: a model
organism for laboratory studies a strain of B.subtilis formerly
known as Bacillusnatto is used in the commercial production of the
Japanese delicacy natto as well as the similar Korean food
cheonggukjang B.subtilisstra in QST 713 (marketed as QST 713 or
Serenade) has a natural
fungicidal activity, and is employed as a biological control
agent popular worldwide before the introduction of consumer
antibiotics as an immuno stimulatory agent to aid treatment of
gastrointestinal and urinary tract diseases. It is still widely
used in Western Europe and the Middle East as an alternative
medicine can convert explosives into harmless compounds of
nitrogen, carbon dioxide, and water plays a role in safe
radionuclide waste [e.g. Thorium (IV) and Plutonium (IV)] disposal
with the proton binding properties of its surfaces recombinants
B.subtilis str. pBE2C1 and B.subtilis str. pBE2C1AB were used in
production of poly hydroxy alkanoates (PHA) and that they could use
malt waste as carbon source for lower cost of PHA production Used
to create amylase enzymes. Although not considered a human
pathogen, Bacillus subtilis can contaminate food a and cause food
poisoning in rare cases 3. E.coli: Strains of E.coli are usually
motile and some, especially those from extra intestinal infections
may produce a polysaccharide capsule. They grow well as
nonselective media and most strains ferment lactose, producing
large red colonies on Maconkey Agar. They grow over a wide range of
temperature (15 450C) and some strains are more heat resistant than
others members of the enterobacteriaceae and may survive 600C for
15 min. Strains of E.coli Entero-pathogenic strains cause acute
gastroenteritis in newborns and infants up to 2 years of age. E
Entero-invasive strain cause diarrhea in older children and adults.
Entero-toxigenic strain cause diarrhea in adults and infants.
Others strains of E.coli which are usually harmless in their normal
habitat can cause disease when they gain access to other sites or
tissues. Pathogenesis: UTI, septic infection, bacteremia,
meningitis, pulmonary infections, abscesses, skin and wound
infection. Treatment: E.coli is susceptible to a wide range of
Antibiotics Doxycycline, Trimethoprim, Norfloxacin, and other
Fluroquinones. 4. Pseudomonas aeruginosa P. aeruginosais a Gram
negative rod measuring 0.5 to 0.8 m by 1.5 to 3.0 m.. Pseudomonas
aeruginosa is a free living bacterium, commonly found in soil and
water.. Its metabolism is respiratory and never fermentative, but
it will grow in the absence of O2 if NO3 is available as a
respiratory electron acceptor. P. aeruginosa strains produce two
types of soluble pigments, the fluorescent pigment pyoverdin and
the blue pigment pyocyanin. The latter is produced abundantly in
media of low iron content and functions in iron metabolism in the
bacterium. Pyocyanin (from "pyocyaneus") refers to "blue pus",
which is a characteristic of suppurative infections caused by
Pseudomonasaeruginosa. Pathogenes is Pseudomona saeruginosa, the
disease process begins with some alteration or circumvention of
normal host defenses. The pathogenesis of Pseudomonass infections
is multifactorial, include septicemia, urinary tract infections,
pneumonia, chronic lung infections, endocarditis, dermatitis, and
osteochondritis. Endocarditis Respiratory infections. Bacteremia
and septicemia. Central nervous system infections Ear infections
including external otitis. Eye infections.
Bone and joint infections Urinary tract infections.
Gastrointestinal infections S Skin and soft tissue infections,
including wound infections, pyoderma and dermatitis . Resistance to
Antibiotics Pseudomona saeruginosa is notorious for its resistance
to antibiotics and is, therefore, a particularly dangerous and
dreaded pathogen. The bacterium is naturally resistant to many
antibiotics due to the permeability barrier afforded by its Gram
negative outer membrane. Also, its tendency to colonize surfaces in
a bio film form makes the cells impervious to therapeutic
concentrations antibiotics. Since its natural habitat is the soil,
living in association with the bacilli, actinomycetes and molds, it
has developed resistance to a variety of their naturally occurring
antibiotics. Moreover, Pseudomonas maintains antibiotic resistance
plasmids, both R factors and RTFs, and it is able to transfer these
genes by means of the bacterial mechanisms of horizontal gene
transfer (HGT), mainly transduction and conjugation. Treatment:
Only a few antibiotics are effective against Pseudomonas
aeruginosa, including fluoroquinolones, gentamicin and imipenem,
and even these a antibiotics are not effective against all strains.
Preparation of inoculum Stock cultures were maintained at 4C on
slopes of nutrient agar. Active cultures for experiments were
prepared by transferring a loop full of cells from the stock
cultures to test tubes of Nutrient broth for bacteria that were
incubated without agitation for 24 hrs at 37C and 25C respectively.
The cultures were diluted with fresh Nutrient broth and Sabouraud
dextrose broth. Preparation of Media: Nutrient agar medium (NA) was
used for preliminary antibacterial study. The medium was prepared
by dissolving the different ingredients in water and autoclaving at
1210C for 15 minutes. Anti-microbial susceptibility test: The disc
diffusion method was used to screen the antimicrobial activity.
Invitro antimicrobial activity was screened by using Nutrient agar
(NA) obtained from Himedia (Mumbai). The NA plates were prepared by
pouring 15 ml of molten media into sterile petriplates. The plates
were allowed to solidify and 0.1 % inoculum suspension was swabbed
uniformly and the inoculum was allowed to dry for 5 minutes. The
different extracts were loaded on 5mm sterile disc till saturation.
The loaded disc was placed on the surface of medium and the
compound was allowed to diffuse for 5 minutes and the plates were
kept for incubation at 37C for 24 hrs. At the end of incubation,
inhibition zones formed around the disc were measured with
transparent ruler in millimeter. These studies were performed in
triplicate by using standard drugs (10 g /disc Penicillin; 60 g
/disc g gentamicin;). Anti helmentic activity: The anti helmintic
activity was evaluated on adult earthworms (Pheretims posthuma), .
Helminths are recognized as a major constraint to livestock
production throughout the tropics and elsewhere53. The economic
impact of parasitic gastroenteritis (PGE), which is caused by mixed
infection with several species of stomach and intestinal round
worms, as a production disease in ruminants lies not only in direct
losses such as mortality associated with the clinical form of the
disease but also indirect insidious losses as a result of
weaknesses, loss of appetite, decreased feed efficiency, reduced
weight gain and decreased productivity Winrock International (1992)
indicated that over $4 billion is lost in animal productivity as a
result of animal diseases, with over half of this loss due to
internal parasites such as helminthes55 . In an effort to reduce
losses due to effects of helminth parasites on livestock industry,
approximately
$1.7 billion are spent annually worldwide in control measures .
In Nigeria as in many tropical countries, control of helminthosis
is mainly by periodic anthelmintic medication. However, as these
are expensive and often unavailable to farmers in rural areas,
livestock producers have continued to use indigenous plants as
dewormers drawing upon centuries of knowledge of herbal medicines.
Furthermore, some serious disadvantages of using manufactured drugs
have become evident in the western world, such as resistance, food
residues and environmental pollution57 . Albendazole is chemically
methyl5(propylthio)2benzimidazolecarbamate, C12H15N3O2S. It is a
wide58 spectrum anthelmentic drug used for human and animal
infections. When administered orally, it is quickly biotransformed
into its active intermediate metabolite Albendazole sulphoxide
(ABZSO), which is then oxidized to the inactive form of Albendazole
sulphone (ABZSO2). Because of their affinity for the parasite
tubulin, both albendazole and ABZSO show anthelmentic activity61.
It is also widely used as inhibator for protein synthesis and
causes degenerative changes in the intestine and the enveloping
membrane and for treatment of cysticercosis has received
criticisms60, 61 , their use in the cysticidal treatment of
neurocysticercosis has proved efficacious62, 63. Although
neurocysticercosis is widespread in underdeveloped countries with
an important socioeconomical impact, there is a lack of information
about its natural history, treatment and prognosis60, 64 and widely
used for treatment and control of helminthes in cattle65, 66 . The
method was followed for anthelmintic screening nine groups, each
consisting of six earthworms of approximately equal size (71) was
released into 50ml of desired formulation at room temperature. Each
group was treated with one of the following: Vehicle (1%Tween 80 in
normal saline), extract (10, 20 and 50mg/ml) in normal saline
containing 1% Tween 80. Observations were made for the time taken
for paralysis and /or death of individual worms up to four hours of
test period. The mean paralysis time and mean lethal time for each
extract was recorded .paralysis was said to occur when the worms
did not revive even in normal saline. Death was concluded when the
worms lost their motility followed with fading away of their body
colour. Preparation of Extracts: Known weight of the extract was
taken and the emulsion was prepared using Tween 80 and Normal
saline solution (8.7 gm in 1000 ml of distill water) to make
concentration of 20mg/ml, 40mg/ml, 60mg/ml, 100mg/ml.
