This document outlines a study to screen and analyze selected plant species for their antioxidant properties. The objectives are to:
1. Screen 3-4 plant species from forest regions for antioxidant properties.
2. Identify primary and secondary metabolites in plant extracts.
3. Isolate and quantify bioactive antioxidant compounds and determine medicinal value.
4. Compare antioxidant profiles between plant species.
Plants will be extracted using solvent extraction. Phytochemical analysis will test for compounds like alkaloids, flavonoids, tannins. Total phenolic content and flavonoid content will be determined colorimetrically. Antioxidant capacity will be evaluated using DPPH, ABTS, hydroxy
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DETERMINE TOTAL PHENOLIC, FLAVONOID CONTENTS AND ANTIOXIDANT ACTIVITY
1. HOW TO DETERMINE TOTAL PHENOLIC,
FLAVONOID CONTENTS AND IN VITRO
ANTIOXIDANT
ACTIVITY OF SELECTED PLANTS
Vinars Dawane
2. Do
1. Screening of 3-4 plant species from forest region
having antioxidant properties.
2. Identify primary and secondary metabolite profile of
the plant spices of interest.
3. Isolate and quantify the bioactive antioxidant
compound and find out its medicinal values.
4. Determine the Comparative antioxidant profile
between screened plants species.
4. Extract preparation
• washing with tap water,
• shade dried and powdering the sample.
• then soxhelt apparatus with methanol as solvent (different
combinations of solvents) will be used for extraction.
5. Identification of primary and secondary metabolite.
Objective - 2
• Phytochemical Analysis:
• Phytochemical analysis to screen the plants for the presence of
alkaloids, glycosides, saponins tannins, flavonoids and carbohydrates,
will be performed according to the method described by Sofowora (1993)
and Evans (1998).
• Test for Carbohydrates:
• Add few drops of Molisch’s reagent to 2ml of each of the water extract in
two tubes. A small quantity of concentrated sulphuric acid will then add
and allowe to form a lower layer. A purple ring at the interface of the
liquids indicates the presence of carbohydrates. Each mixture will be
then shaken and allowed to stand for 2 minutes and diluted with 5ml of
water. A purple precipitate also showed the presence of carbohydrates
(Evans, 1989).
6. • Test for Alkanoids:
• Five test tubes will be used for each of the different drug sample
(ethanolic extract). Few drops of the following reagents manager’s
reagent, Drangendorff’s reagent. Wanger’s reagent, Hanger’s reagent
and 10% tannic acid solution will be added respectively to each of the
five test tubes. The presence of precipitate in at least 3 or all of the
above reagents indicates the presence of alkaloids (Evans 1989).
• Test for Saponins:
• A small quantity of the ethanolic extract wil be boiled. The mixture will be
filtered and 2.5ml of the filtrate will be added to 10ml of the distilled
water in a test tube. The test tube will be corked and shaken vigorously
for about 30 seconds, then it will be allowed to stand for half an hour. A
honeycomb forth will an indicator of the presence of saponins
(Sofowora, 1993).
7. • Test for Tannins (Ferric chloride test):
• A portion of the water extract will be diluted with distilled water in a ratio
of 1:4 and few drops of 10% ferric chloride solution was added. A blue
or green colour indicates the presence of tannins (Evans,1989).
• Test for Glycosides:
• To a portion of the aqueous extract will be added fehlings reagent and
boiled for 2 minutes. A brick red colouration indicates the presence of
glycosides.
8. Total Phenolic Contents (TPC)
determination
• Folin – Ciocalteu reagent method –
• Method is used for the colorimetric in vitro assay of phenolic
and poly-phenolic antioxidants.
• Reagent - a mixture of phospho-molybdate and phospho -
tungstate.
• Method - Samples (100μL) + 2 ml of 2% Na2CO3 + 100 μL of Folin-
Ciocalteu reagent + absorbance was measured at 743 nm against a
blank.
9. Presence of flavonoid
shinoda test –
• Four pieces of magnesium fillings (ribbon) are added to the
ethanolic extract followed by few drops of
concentrated hydrochloric acid.
If –
• A pink or red colour indicates the presence of flavonoid.
• Colours varying from orange to red indicated flavones.
• crimson to magenta indicated flavonones.
10. Total Flavonoid Content (TFC) Determination
• Aluminium Chloride Method –
• Steps –
• 0.5ml of sample (1mg/ml) mixed with
• 0.1ml of 10% aluminium chloride and 0.1ml of
potassium acetate (1M).
• Addition of 4.3ml of 80% methanol.
• Absorbance measure at 415nm.
12. Antioxidant capacity
• DPPH: Quenching Activity method.
• α, α-diphenyl-β-picrylhydrazyl (DPPH) free radical scavenging method.
• This method is based on the reduction of DPPH in methanol solution in the
presence of a hydrogen donating antioxidant due to the formation of the
non radical form DPPH-H.
• 0.1mM solution of DPPH in methanol + added to 3 ml of extract + mix.
• Absorbance measure at 517 nm. And Ascorbic acid was used as the
reference.
• DPPH scavenging effect (% inhibition) = {(A0 – A1)/A0)*100}.
• Where, A0 is the absorbance of the control reaction.
and A1 is the absorbance in presence of all of the extract samples
and reference.
13. • ABTS – Cation Decolorizing Test.
• ATBS Cation production –
• 7mM ABTS solution + 2.45 mM potassium Per sulphate + mix in
dark room.
• The ABTS + Solution were diluted with ethanol to an absorbance of
0.70+0.02 at 734 nm.
• 100μL of sample + to 3.9 mL of diluted ABTS+ Solution + absorbance
at 734 nm.
• ABTS radical cation activity = {(A0 –A1)/A0)*100}.
where , A0 is the absorbance of the control reaction, and A1 is the
absorbance in presence of all of the extract samples and reference.
14. Hydroxyl Radical ScavengingActivity method.
• Deoxyribose assay was used to determine the hydroxyl radical
scavenging activity in an aqueous medium.
• Extract + FeCl 3 (100 µM) + EDTA (104 µM) + H2O2 (1 mM) and 2-
deoxy- D-ribose (2.8 mM) + mix them + phosphat buffer for makeup.
• Mixture + 95 0 C in water bath for 15 min + 1 ml each of TCA (2.8%)
and TBA (0.5% TBA in 0.025 M NaOH containing 0.02% BHA).
• Mixture will be cooled on ice and centrifuged at 5000 rpm for 15 min.
• Absorbance of supernatant was measured at 532 nm.
15. Potassium Ferricyanide Reduction Method for Reducing
Capacity testing.
• Various concentrations of the extracts and standards (50, 100, 250,
500, 750, 1000 mg/ml) .
• Then add to 2.5 ml of (0.2 M) sodium phosphate buffer (pH 6.6) and
2.5 ml of potassium ferricyanide [K 3Fe 3 (CN) 6 ] (1%) solution and
vortex.
• Incubation at 50°C for 20 min + 2.5 ml of TCA + centrifuged at Χ3000
g for 10 min.
• Mix with deionized water (5 ml) and then 1 ml of FeCl 3 (1%).
• Formation of Perl's Prussian color was measured at 700 nm.
Note - Increased absorbance of the reaction mixture indicated
increasing reducing power.
16. In vitro hemolysis of methanolic extract method for
AntihemolyticActivity testing.
• Inhibition of H 202 induced red blood cell (RBC) haemolysis of
methanolic extract are examined by this method.
• Haemolytic activity of the extract can investigate by measuring the lysis
of a 10% (v/v) human red blood cells suspension in a
spectrophotometric assay.
• In this experiment, method will be used same as -
Naim M, Gestetner B, Bondi A, Birk Y. Antioxidative and antihemolytic activities of soybean
isoflavones. J Agric Food Chem 1976;24:1174-7.
17. References
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mangrove plant Laguncularia racemosa (L.) Gaertn. (Combretaceae): their antimicrobial
potential. Science against Microbial Pathogen: Communicating Current Research and
Technological Advances; 2011, 2:1260-1266).
• Patra JK, Thatoi HN. Metabolic diversity and bioactivity screening of mangrove plants: a
review. Acta Physiol Plant 2011; 33: 1051-1061.
• N. Bunyapraphatsara et al. Pharmecological studies of plants in the mangrove forest. Thai
Journal of Pharmacy; 2003, Vol.10 (2).
• Vagi E, Rapavi E, Hadolin M, Vasarhelyine Peredi K, Balazs A, Blazovics A, et al. Phenolic
and triterpenoid antioxidants from Origanum majorana L. herb and extracts obtained with
different solvents. J Agric Food Chem. 2005; 53:17–21. [PubMed: 15631502].
• Jonathan Yisa. Phytochemical Analysis and Antimicrobial Activity Of Scoparia
Dulcis and Nymphaea Lotus. Australian Journal of Basic and Applied Sciences,
3(4): 3975-3979, 2009.