Total Antioxidant Power And Free Radical

  • Uploaded by: Dr. Varaprasad Bobbarala
  • 0
  • 0
  • May 2020
  • PDF

This document was uploaded by user and they confirmed that they have the permission to share it. If you are author or own the copyright of this book, please report to us by using this DMCA report form. Report DMCA


Overview

Download & View Total Antioxidant Power And Free Radical as PDF for free.

More details

  • Words: 1,908
  • Pages: 4
Biosciences, Biotechnology Research Asia

Vol. 5(2), 837-840 (2008)

Total antioxidant power and free radical scavenging capacity of some medicinal plants P. KOTESWARA RAO¹, VARAPRASAD BOBBARALA², D. BHASKAR RAO¹, CH. RAVI KIRAN¹, K.V. RAGHAVA RAO¹ and T. RAGHAVA RAO¹ ¹Department of Biochemistry, College of Science & Technology, Andhra University Visakhapatnam - 03 (India). ²For U Biosciences, A/4A, Park lane Residency, East point colony, Visakhapatnam, A. P - 530 017 (India). (Received: October 28, 2008; Accepted: December 05, 2008) ABSTRACT Current research is now directed towards finding naturally occurring antioxidants of plant origin. The present study was aimed to assess the In vitro antioxidant activity of methanolic leaf extracts of some medicinal plants by carrying the determination of Total Antioxidant power (FRAP Assay) and Free radical scavenging capacity (DPPH Assay) and results were compared with well established antioxidants like Ascorbic Acid and Butylated Hydroxy Toluene(BHT). Our results clearly showed that all the plants of present study showed potent Total Antioxidant power and Free radical scavenging capacity. Of all the plants tested, the highest total antioxidant power and free radical scavenging capacity was shown by X. mekongensis, B. cylindrica and E. agallocha with nearly equal to antioxidant capacity to stable antioxidants like BHT and Ascorbic acid. This data will be useful in estimating the total pharmacological and phytochemical properties of these plants.

Key words: Reactive oxygen species, DPPH Radical, Ascorbic acid Equivalents, Free radical scavengers

INTRODUCTION Reactive oxygen in particular, free radicals are considered to induce oxidative damage in biomolecules and to play an important role in aging, cardiovascular diseases, cancer, and inflammatory diseases1-3. In addition, they are also well known to be major causers of material degradation and food deterioration4. Consequently, antioxidants are now known to be prospective protective or therapeutic agents. In the past few years, addition of synthetic antioxidants has begun to be restricted because of their health risks and toxicity5. The importance of exploiting natural antioxidants from various sources and replacing synthetic antioxidants with natural ingredients has attracted increasing attention. Several natural compounds from plants exhibit antioxidant / radical scavenger properties are

preferred because they are safe and environmental friendly. It has become clear that the direct free radical scavenging effect and membrane protection play an important role in the action mechanism of several old established drugs. Several herbs and spices have been reported to exhibit antioxidant activity, including rosemary, sage, thyme, nutmeg, turmeric, white pepper, chili pepper, ginger, and several Chinese medicinal plants extracts6-9. The aim of the present work was to prove the phytotherapeutical significance of some popular medicinal plants on the basis of their antioxidant activity due to their influence on pathological free radical reactions. The medicinal plants of present study includes Borreria hispida (BH) belongs Rubiaceae, Bruguiera cylindrica (BC) and Ceriops decandra (CD) belongs to Rhizophoraceae, Eugenia bracteata (EB) belongs to Myrtaceae, Excoecaria

838

Rao et al., Biosci., Biotech. Res. Asia, Vol. 5(2), 837-840 (2008)

agallocha (EA) belongs to Euphorbiaceae, Glycyrrhiza glabra (GG) belongs to Fabaceae, Picrorhiza kurrow (PK) belongs to Scrophulariaceae, Trianthima decandra (TD) belongs to Aizoaceae, Xylocarpus mekongensis (XM) belongs to Meliaceae. The reason for selection is that, these plants have a wide range of applications in traditional medicines and are involved in the treatment of various skin diseases, liver disorders, cancer, HIV, cough, asthma, diarrohea, dysentery, ulcers and controlling of blood pressure etc,. In addition, some of these plants were also reported to be the potent antioxidants. Hence, in the present study, we made an attempt to study the total antioxidant power and radical scavenging capacity of methanolic extracts of these plants. This data will be used to estimate the phytochemical and antioxidant intake of the local population and to understand the therapeutic uses of these plants. MATERIAL AND METHODS Diphenyl picryl hydrazyl (DPPH) was obtained from Himedia laboratories Pvt. Ltd, Mumbai, India. Ferric Chloride, 2,4, 6-tri pyridyl-striazine, Butylated hydroxy toluene (BHT) were obtained from Sisco research laboratories Pvt. Ltd., Mumbai, India. All other chemicals used were of analytical grade obtained from commercial sources. Plant collection and preparation of the extraction The plants are collected from the near by hilly region, Paderu and coastal region of Visakhapatnam, Andhra Pradesh, India and authenticated by Dr. M. Venkayya, Associate professor, Dept. of Botany, Andhra University, Visakhapatnam, Andhrapradesh. Plant leaves were cleaned with deionized water and dried at 50ºC for 24 hours. The dried plants were ground and then sieved 80mesh. The dried leaves were ground to a powder using a milling machine. The dried powder was then weighed and extracted with methanol, with reflux on a water bath at 40°C for three consecutive days. The extracts were filtered and evaporated under vacuum to dryness with a rotary evaporator and then placed in an oven at 60°C until constant weight was obtained and the solutions were prepared with a concentration 1mg/ml using methanol.

Total Antioxidant power Ferric reducing ability of Plasma (FRAP) Assay The total antioxidant potential of a sample was determined using the ferric reducing ability of plasma i.e., FRAP assay as a measure of antioxidant power by Benzie and Strain10. The assay was based on the reducing power of a compound (antioxidant). A potential antioxidant will reduce the ferric ion (Fe3+) to the ferrous ion (Fe2+); the latter forms a blue complex (Fe2+/TPTZ), which increases the absorption at 593 nm. Briefly, the FRAP reagent was prepared by mixing acetate buffer (300µM, pH 3.6), a solution of 10 µM TPTZ in 40 µM HCl, and 20µM FeCl3 at 10:1:1 (v/v/v). The reagent (300 µM) and sample solutions (10 µL) were added to each well and mixed thoroughly. The absorbance was taken at 593 nm after 10 min. Standard curve was prepared using different concentrations of FeCl3. All solutions were used on the day of preparation. The results were corrected for dilution (e.g.1000ml) and expressed as ascorbic acid equivalents (µmoles/ml) or FRAP units. All determinations were performed in triplicates. Free radical scavenging capacity Di Phenyl Picryl Hydrazyl radical scavenging assay (DPPH Assay) The DPPH assay was carried out as described by Cuendet et al., (11). 5.0 ml of DPPH solution (0.004%) in methanol was added to 50 µl of plant extract. After 30 min of incubation at 370C, the absorbance was read against control at 517 nm. Ascorbic acid and BHT were used as positive controls. Percentage of inhibition = (absorbance of control –absorbance of test / absorbance of control) x100. All determinations were performed in triplicate. RESULTS AND DISCUSSION Recently much attention has been focused on reactive oxygen species and free radicals, which play an important role in the genesis of various diseases such as inflammation, cataract, liver cirrhosis and ischemia/reperfusion injury (12). Herbal drugs containing radical scavengers are gaining importance in the prevention and treatment of such diseases¹³. Hence the present study is focused on the determination of Total antioxidant power by FRAP Assay and DPPH Assay.

Rao et al., Biosci., Biotech. Res. Asia, Vol. 5(2), 837-840 (2008) Total Antioxidant power Ferric reducing ability of Plasma (FRAP) Assay The FRAP assay measures the reduction of Fe3+ (ferric iron) to Fe2+ (ferrous iron) in the presence of antioxidants. Because the ferric-toferrous ion reduction occurs rapidly with all reductants with half reaction reduction potentials above that of Fe3+/Fe2+, the values in the FRAP assay will express the corresponding concentration of electron-donating antioxidants (10). We elected to use the FRAP analysis for several reasons. The

839

FRAP assay is the only assay that directly measures antioxidants or reductants in a sample. The other assays are indirect because they measure the inhibition of reactive species (free radicals) generated in the reaction mixture, and these results also depend strongly on the type of reactive species used. The FRAP assay, in contrast, uses antioxidants as reductants in a redox-linked colorimetric reaction. Furthermore, the other assays, but not the FRAP assay, use a lag phase type of measurement. This has been difficult to standardize in previous

Fig.1: Showing the Total Antioxidant power (FRAP Assay)

Fig. 2: Showing the Free radical scavenging capacity (DPPH Assay)

840

Rao et al., Biosci., Biotech. Res. Asia, Vol. 5(2), 837-840 (2008)

experiments and has generated varying results among different laboratories. In the FRAP assay, pretreatment is not required, stoichiometric factors are constant and linearity is maintained over a wide range. The results also indicated that the total antioxidant power of the plant extracts was determined by the FRAP method was observed to be highest in X. mexoeugensis with 1601 FRAP units followed by B. cylindrica(1471 FRAP Units), E. agallocha (1237 FRAP Units), E. bracteata (1140 FRAP Units), G. glabra (862 FRAP Units), T.decandra (720 FRAP Units), P. kurrow (645 FRAP Units), B. hispida (600 FRAP Units) and C. decandra (360 FRAP Units) These results were presented graphically in Fig. 1. Free radical scavenging capacity Di Phenyl Picryl Hydrazyl radical scavenging assay (DPPH Assay) The free radical scavenging capacity of methanolic leaf extracts of the plants of present study were tested by its ability to bleach the stable DPPH radical. Antioxidants react with DPPH, which is a stable free radical, and convert it to 1,1-diphenyl-2(2,4,6- trinitrophenyl) hydrazine14. The degree of decolourization indicates the scavenging potentials of the antioxidant compounds. This assay provided

information on the reactivity of the test compound with a stable free radical, since its odd electron with DPPH gives strong absorption band at 517 nm in visible spectroscopy (deep violet colour). As this electron becomes paired off in the presence of a free radical scavenger, the absorption vanishes and the resulting decolourization is stoichiometric with respect to the number of electrons taken up. All the plant extracts showed significant free radical scavenging activity by inhibiting DPPH radical with the percentage of inhibition was observed to be maximum in stable and well established antioxidant BHT (76.2%) Ascorbic acid (71.2 %) followed by X. mexoeugensis with 70.3% B. cylindrica (62%), E. agallocha (51.4%), E. bracteata (51%), G. glabra (49 %), P. kurrow (46.1%), T.decandra (33.7%), B. hispida (28.4%) and least is observed in C. decandra (24.5 %). These results were presented graphically in Figure.2. We therefore suggest that these plant extracts may act as free radicals scavengers and may react with free radicals to convert them to more stable products and terminate radical chain reaction15. Our results clearly shown that plants with high Total Antioxidant power showed maximum Free radical scavenging capacity which was almost equivalent to well established antioxidants like Ascorbic acid and Butylated Hydroxy Toluene (BHT).

REFERENCES

1. 2. 3. 4. 5. 6. 7. 8. 9.

T. Finkel, N. J. Holbrook., Nature, 408: 239-47 (2000) . K. Bauerova, A. Bezek., Gen. Physiol. Biophys., 18:15 (1999). B. Halliwell., Lancet 322., 721 (1994). D. D. Kathie., Eur. J. Clin. Nutr., 45, 759 (1993). S. Buxiang, M. Fukuhara., Toxicology., 122, 61, (1997). Kikuzaki H, Usuguchi J, Nakatani N., Chem Phar Bull ., 39: 120 (1991). Jitoe A, Masuda T, Tengah IGP., J. Agr Food Chem., 8: 1337(1992). Kikuzaki H, Nakatani N., J Food Sci., 58: 1407-1410 (1993). Lee SE, Hwang HJ, Ha JS. Life Sci., 73:

10. 11. 12. 13.

14.

15.

167-179 (2003). Benzie I.F.F and Strain J.J., Anal Biochem., 239: 70-76 (1996) Cuendet M, Hostettmann K, Potterat O., Helv. Chim. Acta., 80: 1144 -1152(1997). Halliwell B., Nutr. Reviews, 55: 522-544 (1994). Prajakta V Desai, Raju R Wadeka, Girish H Kedar and Kalpana S Patil., Int. J. of Green Pharmacy., 2(1): 31-33(2008). Ozgen, M., Reese, R. N., Tulio Jr., A. Z., Scheerens, J. C., & Miller, R., J. Agr Food Chem., 54: 1151-1157. (2006). Duh PD, Yen GC., Food Chemistry., 60: 639-645 (1997).

Related Documents

One Free Radical
November 2019 5
Free Radical Test
May 2020 10
Antioxidant
June 2020 33
Antioxidant
November 2019 29
Radical
August 2019 30

More Documents from ""