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Journal of Medicinal Plants Studies Year : 2013, Volume : 1, Issue : 1 First page : (38) Last page : (46) ISSN: 2320-3862 Online Available at www.plantsjournal.com
Journal of Medicinal Plants Studies
Vol. 1 No. 1 2013 www.plantsjournal.com Page | 38
Pharmacognostic Study and Establishment of Quality Parameters of Leaves, Root and Bark of Ficus retusa. Linn
Shivani Chauhan*1, Lubhan Singh1, Ashish Kr Sharma2
1. Department of Pharmaceutical Technology, M.I.E.T., Meerut, U.P., India- 250005
[E-mail: [email protected]] 2. Adarsh Vijendra Institute of pharmaceutical Sciences, Gangoh, Saharanpur, U.P., India- 247341
Ficus retusa. Linn (Family- Moraceae) is found commonly in India. Ficus species are rich source of polyphenolic compounds, flavonoids which are responsible for strong antioxidant properties that help in prevention & therapy of various oxidative stress related diseases. In present investigation, the detailed comparative pharmacognostic study of Ficus retusa (leaf, root and bark) was carried out to lay down the standards which could be useful in future experimental studies. However, no conclusive pharmacognostic study of its leaves, bark and roots has been performed yet. The study includes macroscopy, microscopy, preliminary phytochemical screening, physicochemical evaluation, fluorescence analysis and chromatographic evaluation. Highest extractive values were found with water and ethanol. The fluorescence analysis under visible light and under UV light by treatment with different chemical reagents showed different colour changes. The presences of alkaloids, steroids, flavonoids, saponins were confirmed during preliminary phytochemical screening. Conclusion: Such a study would serve as a useful gauge in standardization of the plant material, isolation of medicinally important phytoconstituents, performing pharmacological investigations and ensuring quality formulations Keyword: : Ficus retusa, Pharmacognostic, Phytochemical, Fluorescence Analysis.
1. Introduction The Ficus retusa, also known as Chinese banyan, plaksha, pakur and kamarup plant belongs to Moraceae family mainly distributed throughout Western Peninsula and also found in chhota Nagpur, Bihar, Central india, Andamans, Sundribuns, Malaya islands and Australia. It is a huge tropical, decidous, evergreen tree with more than 800 species. It has an evergreen rosette with oval, dark green, shiny leaves, & a chunky trunk with exposed aerial roots (Ajasa A M, 2004 and Arya V, 1997). Leaves are ellipitic, ovate or obovate, 8 to 14 cm long with tapering points, narrowing into a petiole 6 to 12 mm long. The barks are grey to dark brown, fruity in young in odor, taste in bitter, cylindrical shape,
and rough irregularly cracked bark in surface characteristics (Kollipillai B et al, 2010 and Jaya R et al, 2011). It mainly contains sterols, terpenoids, glycoside, flavonoids, polyphenols, proteins and carbohydrates. Leaves and bark used as poultice for rheumatism. Juice of leaves used for abdominal colic and flatulence. Bark juice used for liver diseases. In china, rootlets are used for toothaches (Ravichandra V D et al, 2011 and shrisha N et al, 2011) 2. Materials and Method 2.1 Plant Material The plant material (leaves, roots and barks) were collected from (Gangoh) distt. Saharanpur U.P. India. The plant was identified and authenticated
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by Dr. Anjula Pandey, Principal Scientist, National Bureau of Plant Genetic Resources (Indian council of Agricultural Research), New Delhi. Leaves, Roots and Barks were then washed to remove adhering material, shade dried and powdered (#60) using a blender. The powders were stored in an airtight container. An exhaustive pharmacognosy was carried out using standard methodology. 2.2 Pharmacognostical Studies 2.2.1 Macroscopy Morphological studies of leaf, root and bark such as color, size, odor, taste, surface characteristic and fracture were examined using the terms and outlined given in (Evans, 1989). 2.2.2 Microscopy Free hand transverse sections of fresh leaf, root and bark were taken, cleaned in chloral hydrate solution with gentle warming. A drop of concentrated hydrochloric acid and phloroglucinol were used to detect the lignified cells in the cross sections and in the powder drugs. They were mounted on slide in glycerin and studied under microscope according to the standard method given in the textbook of pharmacognosy by T E.Wallis 1967. Photomicrographic images were taken by using Trino CXR camera. 2.2.3 Chemo-Microscopical Examinations The transverse sections were treated with various chemical reagents to detect the presence or absence of chemical constituents such as starch grains, lignin, mucilage and calcium oxalate crystal. The fluorescence behaviors of the powdered drugs in different chemical solutions towards the ordinary and ultra violate light was also carried out as per method described by Lal, V.K.1980. 2.2.4 Quantitative Evaluation of the Powdered Leaves, Bark and Roots The moisture content of the powdered material was determined by the loss on drying method.
The ash value and the acid insoluble ash value were determined using methods described in the British Pharmacopoeia (British Pharmacopoeia, 1980). The extractive (water and alcohol) values were determined using methods described in Brain and Turner, 1975. Average of three determinations for each procedure was calculated. The preliminary phytochemical screenings of Ficus retusa leaves bark and roots extracts were carried out according to Harbone J.B, 1976. 2.2.5 Fluorescence Characteristics Of Powdered Drug Under Ultra-Violet Light Powdered drug were screened for fluorescence characteristic with and without chemical treatment. The observations pertaining to their color in day light and under ultra-violet light (short and long) were noticed (Kokashi V J et al, 1958). 2.3 Chromatographic Evaluation The chromatographic studies were performed using various solvent systems to confirm the phytochemical studies. Prepared silica gel TLC plates were used for the chromatographic evaluation. Finally Rf values were calculated and shown in table 6, 7 and 8. (Mukherjee P K, 2008, Stahl E, 1985, Wagner and Bladt 1996 and Wallis TE 1984). 3. Result 3.1 Macroscopic And Sensory Characters Leaves: The leaves are pale green, fruity in young in odor, taste in bitter, oblong shape, 8.0 to 14.2 cm in length, 4 to 5 cm in width in size, glabrous in surface characteristics. Root: The root is light brown, fruity odor, taste in bitter, cylindrical shape, and rough irregularly cracked in surface characteristics. Bark: The barks are grey to dark brown, fruity in odor, taste in bitter, cylindrical shape, and rough irregularly cracked bark in surface characteristics as shown in table1.
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Table1: Morphology of Leaves, Root and Bark of Ficus retusa
Characters Description (Leaves) Description (Root) Description (Bark)
Color Pale Green Light brown Grey to dark brown
Odor Fruity in young leaves Fruity Fruity
Taste Bitter Bitter Bitter
Size 8.0 to 14.2 in length, 4 to5 in width
(mature leaves)
-
-
Shape Oblong Cylindrical Cylindrical
Surface
characteristics
Glabrous, shiny appearance Rough irregularly cracked
roots
Rough irregularly cracked
bark
Table 2: Physicochemical Parameters of Ficus Retusa.Linn
Parameter (Mean)n %w/w Leaf) (Mean)n %w/w (Root) (Mean)n %w/w (Bark)
Total ash value 10.25 4.75 6.25
Acid insoluble ash 3.0 2.0 2.5
Water soluble ash 6.5 4.0 4.5
Loss on Drying 8.9 9.2 9.7
* Where n=3 on dry weight basis
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Table3. Extractive values of Ficus retusa. Linn
Parameter (Mean)n %w/w (Leaves) (Mean)n %w/w (Root) (Mean)n %w/w (Bark)
Water soluble extractive values 8.8 4.8 3.2
Alcohol soluble extractive values 13.6 1.6 6.4
* Where n=3 on dry weight basis
3.2 Phytochemical Investigation: Preliminary phytochemical screenings were performed to find out the phytoconstituent present in the leaves, roots and barks of Ficus retusa. Linn (Table 4)
Table4. Preliminary phytochemical screening of leaves, root and bark of Ficus retusa.Linn
Description Leaves Root Bark
Alkaloids + - +
Glycoside - - -
Tannin + - +
Saponin - - -
Steroids - - -
Flavonoids + + +
Carbohydrates + + -
Amino acids - - -
Terpenoids + + -
(+) = Present; (-) = Absent;
3.3 Microscopic Characters 3.3.1 Leaves: The transverse section of leaf showed palisade, epidermis, spongy mesophyll, phloem, xylem and abaxial surface as shown in Fig 1a, 1b and1c. 3.3.2 Root: The transverse section of root shows, vascular bundles, medullary rays, calcium oxalate crystal, cortex region and pith as shown in Fig 2a, 2b, 2c and 2d and powdered sample of root of Ficus retusa showed Trichomes, Starch grain, Lignified cell, fibres and oil globules in Fig 3a. 3.3.3 Bark: The transverse section of barks show fibers showing thick cells of the parenchymatous cells, cork cells, cortex, pigment, vascular bundles and starch grain as shown in Fig 4a 3.4 Physicochemical studies The moisture content was 8.9% (leaves), 9.2% (root) and 9.7% (bark) which were not so high as to facilitate bacterial growth. The other physicochemical parameters which ascertain the quality, purity and also help in evaluating the crude drug, and the total ash value, acid insoluble ash value and water soluble ash value which were determined to be not more than 10.25 %w/w, 3.0 %w/w, 6.5 %w/w (leaves), 4.75 %w/w, 2.0 %w/w, 4.0 %w/w (root), and 6.25 %w/w, 2.5 %w/w, 4.5% w/w (bark) respectively which indicated the presence of the total foreign inorganic matter. While study of extractive values can serve as a valuable source of information and provide suitable standards to determine the quality of plant material in future investigations or application. (Table 2 & 3) 3.5 Fluorescence Analysis: The results are summarized in Table 5.
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Table 5: Fluorescence Analysis of Powdered Ficus Retusa. Linn Leaves Roots and Bark.
Leaves Root Bark
Sr No
Powdered crude drug + reagent
Day Light UV
(Short) 254nm
UV (Long)366nm
Day Light UV
(Short)254 nm
UV (Long) 366 nm
Day Light UV
(Short) 254 nm
UV (Long) 366 nm
1 Powder
Crude Drug as such
Green Dark green Dark green Yellowish
green Dark green Light green
Light yellow green
Dark green
Light yellow green
2 Drug + 1M NaOH Dark green Dark
green Blackish green Dark brown
Blackish green Dark green Dark
brown Blackish
green Dark green
3 Drug + 1M
NaOH +Methanol
Dark green Blackish green Dark green Yellowish
brown Blackish
green Yellowish
green Dark
brown Blackish
green Dark brown
4 Drug + 1M
NaOH + Water
Green Dark green Green Yellowish
brown Blackish
green Yellowish
green Dark
brown Blackish
green Yellowish
brown
5 Drug + 1M HCl
Yellowish brown
Dark brown
Yellowish brown
Yellowish green Dark green Dark green
Light yellow green
Dark green
Yellowish green
6 Drug + dil. HNO3
Yellowish brown
Light brown
Yellowish brown
Yellowish green
Blackish green Dark green
Light yellow green
Dark green
Dark yellowish
green
7 Drug + 5% Iodine
Blackish green
Blackish green Dark green Dark green Blackish
green Blackish
green Dark green Blackish green
Blackish green
8 Drug + 5% FeCl3
Blackish green
Blackish green Dark green Blackish
green Blackish
green Blackish
green Dark green Blackish green
Blackish green
9 Drug + dil. Ammonia Green Dark
green Green Yellowish green Dark green Green Yellowish
green Dark green
Light green
10 Drug + Methanol Pale green Pale green Yellowish
green Light green Dark green
Light yellowish
green Light green Dark
green
Light yellowish
green
11 Drug + dilute HCl
Brownish green
Brownish green Dark green Light
brown Dark green Yellowish green
Light yellow green
Blackish green Dark green
12 Drug + 1M H2SO4
Brownish green
Brownish green
Brownish green
Brownish green
Blackish green Dark green Yellowish
green Dark green
Yellowish green
13 Drug + Conc. HNO3
Reddish brown Brown Brown Reddish
brown Blackish brown
Blackish brown
Reddish brown
Dark brown
Blackish brown
14 Drug + K2Cr2O7 Dark green Blackish
brown Dark green Dark brown Dark green Blackish
brown Dark
brown Blackish brown
Blackish brown
15 Drug + Ethanol Green Green Yellowish
green Yellowish
green Yellowish
green Green Yellowish green
Dark green
Light yellowish
green
16 Drug + Toluene
Light green
Dark green
Yellowish green
Light green Dark green
Light yellowish
green Light green Dark
green
Light yellowish
green
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3.6 Chromatographic Evaluation: Thin layer chromatography was performed using various solvent systems to confirm the phytochemical studies. The Rf values were calculated for the optimum solvent system. TLC analysis of leaves: The observations are shown in Table 6.
Table 6: TLC analysis of methanol extract of leaves
Category Solvent system Ratio No. of spots Spraying reagent Rf
General
Hexane : Ethyl acetate
8 : 2
9
Iodine Chamber/U.V Chamber
0.21,0.23, 0.26, 0.25, 0.28, 0.41, 0.45, 0.8, 0.85
Tannins Ethyl acetate : Benzene 9 : 11 3 Vanillin-Sulphuric Acid Reagent 0.72, 0.69, 0.96
Flavonids Chloroform : Acetone : Formic acid
7.5 : 16.5 : 13.5 5 Iodine Chamber 0.37, 0.39, 0.43, 0.54, 0.87
Alkaloids Chloroform : Diethyl amine 9 : 1 5 Dragendroff’s reagent 0.50, 0.64, 0.79, 0.92, 0.90
Tri-terpenoids Chloroform: Methanol 10:1 4 Iodine Chamber 0.16,0.70,0.32, 0.61,
TLC analysis of root: The observations are shown in Table 7.
Table7. TLC analysis of methanol extract of root
Category Solvent system Ratio No. of spots Spraying reagent Rf
Tannins Ethyl acetate : Benzene 9 : 11 4 Vanillin-Sulphuric
Acid Reagent 0.21, 0.22, 0.55, 0.51
Triterpenoids Chloroform : Methanol 10 : 1 2
Iodine Chamber/U.V
Chamber 0.73, 0.78
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TLC analysis of bark: The observations are shown in Table 8.
Table8. TLC analysis of methanol extract of bark.
Category Solvent system Ratio No. of spots Spraying reagent Rf
General Hexane : Ethyl acetate
8 : 2
6
Iodine Chamber/U.V Chamber 0.16, 0.15, 0.14, 0.39, 0.37,
0.35
Tannins Ethyl acetate : Benzene 9 : 11 3 Vanillin-Sulphuric Acid
Reagent 0.78, 0.79, 0.74
Tri-terpenoids
Chloroform: Methanol 10:1 3 Iodine Chamber 0.81, 0.75, 0.83
4. Discussion The leaves of Ficus retusa was pale green in color, with fruity odour and Bitter taste. The size was 8.0 to 14.2 cm in length and 4 to 5 cm in width. The shape of leaves is oblong with glabrous, shiny surface characteristics.The bark of Ficus retusa was dark brown in color, with fruity odour and bitter taste. The shape was cylindrical with rough irregularly cracked surface. The root of Ficus retusa was light brown in color with fruity odour and bitter taste. The leaves, roots & bark of Ficus retusa were subjected to microscopical studies using transverse section and powder microscopy. The transverse section of bark of Ficus retusa showed cork cells, cork cambium, medullary rays, starch grain and oil globules. Medullary rays were straight. The transverse section of root of Ficus retusa showed cork cells, vascular bundles, medullary rays, calcium oxalate crystals and oil globules. The transverse section of leaves of Ficus retusa showed fibres, starch grain, oil globules. The powder of root of Ficus retusa showed starch grain, Trichomes, fibers and oil globules. The powder of leaves of Ficus retusa showed Fibro-vascular, starch grain and oil globules. Physiochemical parameters and extractive value of leaves, bark & root of Ficus retusa were studied and results were shown in
Table 2 and 3 respectively. Preliminary phytochemical studies on the plants revealed the presence of alkaloids, glycoside, tannins, saponin, steroids, tri-terpenoid and flavonoids. The preliminary phytochemical test results were rationalized by the Thin Layer chromatographic studies. 5. Conclusion The comparatives pharmacognostic standards for the leaves, bark & root of Ficus retusa are laid down for the first time in this study. Morphological and anatomical studies of plant parts will enable to identify the crude drug. The information obtained from preliminary phytochemical screening will be useful in finding out the genuity of the drug. Ash values, extractive values can be used as reliable aid for detecting adulteration. These simple but reliable standards will be useful to a person in using the drug as a home remedy. Also the manufacturers can utilize them for identification and selection of the raw material for drug production. So further study should be carried out in future to isolate the specific chemical constituents as well as detailed pharmacological activity will be carried out in proper scientific way.
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Figure 1a: T.S of leaf of Ficus retusa. (
Figure 1b: Magnified T.S of leaf of Ficus retusa.
Figure 1c: T.S of petiole of Ficus retusa
Figure 2a: T.S of root of Ficus retusa. Linn shows vascular bundles, epidermis, medullary
rays and cortex region.
Figure 2b: T.S of root of Ficus retusa. Linn showing vascular bundles and pith region
Figure 2c: L.S of root of Fcus retusa showing
fusiform cells
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Figure 2d: L.S of root of Ficus retusa showing epidermis, cortex region and fusiform cells.
Figure 3a: Powdered sample of root of Ficus retusa. Linn showed lignified cells, trichomes,
fibres, oil globules and starch grains.
Figure 4a: T.S of bark of Ficus retusa showed vascular bundles, parenchymatous cells, starch
grains and pigment. 3. Reference:
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