Arokiyaraj A, Perinbam K. Antifungal Activity of Pterocarpus Santalinus an In Vitro Study. Biomed Pharmacol J 2010;3(1)
Manuscript received on :April 20, 2010
Manuscript accepted on :May 30, 2010
Published online on: 21-11-2015
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Arokiyaraj and K. Perinbam

Department of Biomedical Engineering, Sathyabama University, Chennai - 119 (India).

Abstract

In the present study leaves of Pterocarpus santalinus L.f (Fabaceae) were exhaustively extracted with different solvents like hexane, ethyl acetate and methanol in ascending order of polarity. All the three extract was subjected to antifungal screening and phytochemical analysis. The ethyl acetate extract showed significant MIC values against Trichophyton rubrum (62.5 µg/ml), Trichophyton mentagrophytes (500 µg/ml), Trichophyton simmi (125 µg/ml), Epidermophyton floccosum (500 µg/ml) and Scropulariopsis sp (500 µg/ml). Phytochemical screening revealed the presence of terpenoids, steroids, flavonoids, alkaloids, tannins and carbohydrates. The present study validates the traditional use of the medicinal plant and indicates that it can be effective potential candidate for the development of new antifungal drug to treat fungal infections.

Keywords

Antifungal; dermatophytes; Pterocarpus santalinus; minimum inhibitory concentration

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Arokiyaraj A, Perinbam K. Antifungal Activity of Pterocarpus Santalinus an In Vitro Study. Biomed Pharmacol J 2010;3(1)

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Arokiyaraj A, Perinbam K. Antifungal Activity of Pterocarpus Santalinus an In Vitro Study. Biomed Pharmacol J 2010;3(1). Available from: http://biomedpharmajournal.org/?p=1176

Introduction

Microbial infections pose a health problem throughout the world with the alarming increase in the rate of infection by antibiotic resistant microorganism (Davies, 1994). The increasing resistance of most synthetically derived antimicrobial agents is of utmost concern.  In recent years, there has been renewed interest in the treatment against different diseases as herbal drugs are generally known to be non toxic (Rao, 2001). The antimicrobial properties of certain Indian medicinal plants were reported based on folklore information (Perumalsamyet al., 1999), and a few attempts were made on inhibitory activity against certain pathogenic bacteria and fungi. PterocarpussantalinusL.f (Red sanders) belongs to the family Fabaceae and is restricted to part of Andrapradesh. Traditionally it has been used in treatment of headache, skin diseases, fever, boils, and scorpion-sting and to improve sight (Chopra et al., 1956). Previous chemical constituents revealed the presence of triterpene, isoflavoneglucosides, savinin and calocedrin (Krishnaveniet al., 2000). In this study we focused on the in vitro screening of antifungal activity of hexane, ethyl acetate and methanol extracts of Pterocarpussantalinus against dermatophytes and opportunistic pathogens.

Material and Methods

Plant collection and Extraction

Healthy, disease free mature leaves of Pterocarpussantalinus were collected from Andrapradesh, India a specimen was deposited at the department herbarium, St. Joseph’s College, Trichy. Collected materials were washed thoroughly, shade dried in open air and grounded into powder. The powder was extracted by maceration in hexane (6.2 g) during 72 hr. Residuals were further extracted with ethyl acetate (46.2 g) and methanol (35.6 g) following the same procedure.  The plant extracts were concentrated using rotary flash evaporator and preserved at 40C in air tight bottle until assay.

Fungal strains

The following fungi were used for experiments:Trichophytonrubrum MTCC 296, T. mentagrophytes 66/01, T. simii 110/02, Epidermophytonfloccosum 73/01, Scopulariopsis sp. 101/01 Aspergillusniger MTCC 1344, Botyritiscinerea,Curvularialunata46/01, Magnaporthegrisea and Candida albicans MTCC 227.

Preparation of fungal spore

The filamentous fungi were grown on Sabouraud Dextrose Agar (SDA) slants at 28oC for 10 days and the spores were collected using sterile doubled distilled water and homogenized. Yeast wasgrown on Sabouraud Dextrose Broth (SDB) at 28oC for 48 h.

Antifungal assays

The antifungal activity was performed according to the standard reference method (NCCLS, 2002). The extracts were dissolved in 2% dimethyl sulfoxide (DMSO). The initial concentration of extract was 1mg/ml. The initial test concentration was serially diluted two-fold. Each well was inoculated with 5 µl of suspension containing 104 spore/ml of fungi. The antifungal agent Fluconazole was included in the assays as positive controls; the plates were incubated for 24h up to 9 days at 27°C for dermatophytes strains. MIC was defined as the lowest extract concentration, showing no visible fungal growth after incubation time.

Phytochemical Screening

Preliminary phytochemical screening was carried out by using standard procedures (Edeogaet al., 2005).

Results and Discussion

Results of antifungal activity are summarized in Table-1. From this evaluation we found that ethyl acetate extract inhibited large number of fungal growth. Hexane extracts also nearly showed the same level of inhibition against fungal growth. Methanol extract is highly in-active. Ethyl acetate extract of P. santalinus leaves showed activity against tested fungi namely (Fig. 1), T. rubrum296 (62.5 µg/ml), T. mentagrophytes (500 µg/ml), T. simii (125 µg/ml), E. floccosum (500 µg/ml), C. lunata (1000 µg/ml) M.grisea (1000 µg/ml) and Scopulariopsissp (500 µg/ml). The phytochemical analysis of ethyl acetate extract had showed the presence of flavonoids, terpenoids, steroids, alkaloids, tannins and Carbohydrates (Table 2)In the present study T. mentagrophytes, Epidermophytonfloccosum, Trichophytonrubrum, Trichophytonsimii, Magnaporthegriseawere found to be the most sensitive fungal strains. T. mentagrophytes, T. simii and T. rubrum is pathogenic fungi; the dermatophytes have the ability to invade keratinized tissues of animals and humans and cause a disease. Trichophytonrubrumis the main agent isolated in superficial mycosis, corresponding to almost 60% of all clinical cases in Brazil (Esquenaziet al., 2004). The basis of varying degree of sensitivity of test organisms of fungi may be due to the intrinsic tolerance of microorganisms, the nature and combinations of phytocompounds present in the crude extract. In previous findings flavonoids were found to be effective antimicrobial substances against a wide range of microorganisms, probably due to their ability to complex with extra cellular and soluble protein and to complex with bacterial cell wall:  more lipophilic flavonoids may also disrupt microbial membrane (Tsuchiya et al., 1996).

Table 1:  Minimum Inhibitory Concentration (µg/ml) of ethyl acetate extracts of Pterocarpussantalinus

  Extract T.m E.f T.s C.l A.n B.c Tr 296 Mg sp. Scro C.a
Flu <12.5 <12.5 <12.5 <12.5 <12.5 NT <12.5 NT <12.5 <12.5
Pterocarpus He 500 1000
santalinus Ea 500 500 125 1000 62.5 1000 500
Linn (Leaf) Me 500 1000
He – Hexane; Ea – Ethyl acetate; Me – Methanol, Flu – Flucanozole (Standard), NT – Not test
T.m – Trichophytonmentagrophytes; E.f – Epidermophytonfloccosum; T.s – T. simii; C. l – Curvularialunata; A.n – Aspergillusniger; B.c – Botrytis cinerea; T.r – rubrum 296; Mg. – Magnaporthegrisea;  Scro – Scropulariopsissp; C.a- Candida albicans.

 

Table 2:  Preliminary phytochemical analysis of Pterocarpussantalinus

Extracts Terpeonids Steroids Flavonoids Alkaloids Carbohydrates Tannins Saponin
Hexane + + + + +
Ethyl acetate + + + + + +
Methanol + + +
+ Positive, – negative

Conclusion

In conclusion all these findings raised some interesting exceptions about antifungal activity of this plant extract.  Identification and elucidation of the active constituent in this plant may provide useful lead to the development of new and effective drugs.

References

  1. Chopra, R.N., Nayar, S.L., and Chopra, I.C., Glossary of Indian medicinal plants. India,CSIR, 171 (1956).
  2. Davies, J., Inactivation of antibiotics and the dissemination of resistance genes.  Science 264: 375-382 (1994).
  3. Edeoga, H.O., Okwu, D.E., and Baebie, M., Phytochemical constituents of some Nigerian medicinal plants. Afri.J. Biotechnol. 4, 685-688 (2005).
  4. Esquenazi, D., Alviano, C.S., DeSouza, W., Rozental, S., The influence of surface carbohydrates during in vitro infection of mammalian cells by the dermatophyteTrichophytonrubrum. Research in Microbiology155: 144-153 (2004).
  5. Krishnaveni, K.S., and SrinivasaRao, J.V., An isoflavone from PterocarpussantalinusPhytochem3: 605-606 (2000).
  6. National Committee for Clinical Laboratory Standards.Reference method for broth dilution antifungal susceptibility testing of filamentous fungi. Approved standard M38-A. Wayne, Pa, (2002).
  7. PerumalSamy, R., Ignacimuthu, S., Patric Raja, D., Preliminary screening of ethnomedicinal plants from India. Journal of Ethnopharmacology66: 235-240 (1999).
  8. Rao, B.K., Rao, C.H., Hypoglycemic and antihyperglycemic activity of Syzygiumalternifolium (Wt.) Walp. seed extracts in normal and diabetic rats. Phytomedicine8: 88-93 (2001).
  9. Tsuchiya, H., Sato, M., MiyaZaki, T., Fujiwara, S., Tanigaki, S., Ohyama, M., Tanaka, T., and Dinuma, M., JEthnopharmacol., 50, 27-34 (1996).
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