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African Journal of Traditional, Complementary and Alternative Medicines
African Ethnomedicines Network
ISSN: 0189-6016
Vol. 2, Num. 3, 2005, pp. 233-237
African Journal. Traditional, Complementary and Alternative Medicines Vol. 2, Num. 3, 2005, pp. 233-237

 Short communication  

THE ANTIULCER EFFECTS OF THE METHANOL EXTRACT OF THE LEAVES OF ASPILIA AFRICANA (ASTERACEAE) IN RATS

Télesphore Benoît Nguelefack1*, Pierre Watcho1, Sylvie Lea Wansi1, Ngetla Manyineh Mbonuh1, Dieudonne Ngamga2, Pierre Tane2, Albert Kamanyi1

1Department of Animal biology, Faculty of Science, University of Dschang, BP 67 Dschang, Cameroon, 2Department of Chemistry, Faculty of Science, University of Dschang, BP 67 Dschang, Cameroon
E mail: nguelefack@yahoo.fr Tel. (237) 756 43 62, Fax: (237) 345 12 02

Code Number: tc05024

Abstract 

Aspilia africana (Asteraceae) is a plant currently used in Cameroon ethnomedicine for the treatment of stomach ailments. The methanol extract of the leaves of A. africana was investigated against gastric ulcerations induced by HCl/ethanol and pylorus-ligation. With both methods, the extract inhibited gastric ulcerations in a dose-related manner. Oral administration of the plant extract at the doses of 0.5 and 1 g/kg reduced gastric lesions induced by HCl/ethanol by 79 % and 97 % respectively. The extract at the dose of 1 g/kg reduced gastric lesion in the pylorus ligated rats by 52 % although the gastric acidity remained higher as compared to the control. These findings show that methanol extract of the leaves of A. africana possess potent antiulcer properties. 

Key words:  Aspilia africana, antiulcer, rat 

Introduction

Aspilia africana (Pers.)C.D. Adams is a perennial herb which belongs to the family of Asteraceae. It is lignous at the base and can grow up to 1.5 m high. The fruits are quadrangular akenes and the leaves are opposite and hairy. The flowers are composed of floret of a yellow glaring and dazzling colour (Adjanohoun et al., 1996). The plant is a common secondary formation species in cultivated farms and fallow lands, occurring in occidental Africa (from Senegal to Cameroon) (Iwu, 1993). A. africana is widely used in African folk medicine, to stop bleeding, remove corneal opacities, induce delivery and in the treatment of anaemia and various stomach complaints (Iwu, 1993; Adjanohoun et al., 1996)

The present study was undertaken to determine the antiulcer potential of the methanol extract of the leaves of A. africana, using two experimental gastric ulcer models namely, HCl/ethanol-induction and pylorus ligation.

Materials and Methods

Animals

The experiments were carried out on Wistar strain male adult rats, aged 12 to 15 weeks and weighing 170 to 200 g. The rats were raised in the animal house of the Faculty of Science, University of Dschang, Cameroon and fed on normal laboratory rat diet (Granules, Navette) with water given ad libitum.  

Preparation of the plant extract 

The plant material was harvested in Dschang, Cameroon in January and identified at the National Herbarium in Yaounde-Cameroon in comparison with the existing Voucher specimen N° 6555/SRF/CAM. The harvested fresh leaves were sun dried and ground into a fine powder.  430 g of the powder were macerated in methanol for 72 hours. The filtrate was concentrated under reduced pressure at 80° C to give 58.5 g of a green water-soluble residue, corresponding to an extraction yield of 13.6 %.

Phytochemical screening 

The use of the test of Shinoda help to determine the presence of flavonoids (Markham, 1982), Libermann Buchard’s test revealed the existence of sterols and triterpens (Klyne, 1970), while saponins were revealed as described by Hosttetmann et al. (1991).

HCl/ethanol- induced ulcer 

Gastric ulceration was induced in 48 hours starved rats using the method of Hara and Okabe (1985). The rats were given the plant extract at the doses of 0.5 and 1 g/kg orally, the positive controls received cimetidine (p.o.), at the dose of 11.5 mg/kg, while negative control received distilled water. One hour 30 minutes after drug treatment, 1 ml of the necrotizing solution (150 mM HCl in 60 % ethanol) was given per os to each rat. The rats were killed 1 hour later using an over dose of ether, and the stomach removed and observed for ulcers in the glandular region. The surface area of each lesion was measured and scored as described by Tan et al. (1996). The ulcer index for each rat was taken as the mean ulcer score. The percentage ulcerated surface was calculated as the total area covered by all lesions expressed as a proportion of the total corpus mucosal surface area. The percentage of inhibition (% I) was calculated using the following formula:

% I = (USc-USt).100
                USc

Where USc = ulcer surface area of control and USt = ulcer surface area of test animal.

Pylorus ligated ulcer technique 

The rats were given the plant extract (1 g/kg) or cimetidine (11.5 mg/kg) 1 h before pylorus ligation. Six hs after the ligation, the animals were killed and the stomach removed. The gastric contents were collected, centrifuged and the supernatant measured. The ulcer formed in the gastric mucosa were measured and scored as described by Shay et al. (1945). The ulcer index, the percentage ulcerated surface and the percentage of inhibition were estimated as described above.

Measurement of gastric acidity 

One ml of the total centrifuged gastric contents from each pylorus-ligated rat was analysed for hydrogen ion concentration by titrating against a 0.01N solution of NaOH. The experiment was done in triplicate.

Statistical analysis 

Statistical analysis was performed using ANOVA and Duncan’s test and significance of difference between treatments was accepted at p < 0.05. Data were expressed as mean ± standard error of the mean.

Results and discussion

HCl/ethanol-induced ulcer

Oral administration of the HCl/ethanol solution produced characteristic lesions in the glandular portion of the rat stomach, with a total surface of 180.00 ± 7.18 mm2. The leaf methanol extract of A. africana produced a dose-dependent inhibition of gastric ulceration ranging from 79 % at the dose of 0.5 g/kg to 97 % at the dose of 1 g/kg with a respective ulcer surface area of 38.20 ± 9.07 and 5.25 ± 1.05 mm2. The mean ulcer index reduced significantly (p < 0.05) from 3.51 in negative control to 2.97 and 1.75 for rats receiving 0.5 and 1 g/kg of extract respectively (Table 1).           

Table 1. Effects of the leaves methanol extract of Aspilia africana on HCl/ethanol-induced gastric lesions in rats.

Treatment

Dose

(mg/kg)

Ulcer Index

U S area  (mm2)

% I

% US

Control

-

3.5 ± 0.42

180.0 ± 7.1

0

8.06

Cimetidine

11.5

2.7 ± 0.19a

60.0 ± 5.35a

66.67

3.34

Extract

500

2.9 ± 0.32a

38.2 ± 9.07a

78.89

2.02

1000

1.7 ± 0.54b

5.25 ± 1.05b

97.22

0.24

Number of rats per group = 7
I = inhibition
US = ulcerated surface
ap< 0.05 ; bp< 0.01 statistically significant relative to control 

These results show that the methanolic extract of A. africana leaves has protective properties against HCl/ethanol induced ulcers in rats. This method of ulcer induction is being widely used and is a convenient way of assessing anti-ulcer activity of drug (Hara and Okabe, 1985, Tan et al., 1996, 2000). The gastric mucosal protection against irritant substances as HCl/ethanol can be mediated by a number of mechanisms that 

Table 2. Effects of the leaves methanol extract of Aspilia africana on pylorus ligation ulceration

Treatment

Dose (mg/kg)

Ulcer index

US area (mm2)

% I

% US

gastric juice (ml)

Gastric acidity (mEq/l)

Control

-

2.72 ± 0.21

12.00 ± 3.05

0

1.02

8.65 ± 1.41

104 ± 7.01

Cimetidine

11.5

2.29 ± 0.12*

9.00 ± 3.42

25.00

0.66

6.20 ± 0.77*

98.00 ± 12.68

Extract

1000

1.29 ± 0.64*

5.75 ± 2.01*

52.08

0.58

8.13 ± 0.30

113.00 ± 6.41

Number of rats per group = 7
I = inhibition
US = ulcerated surface
*p< 0.05 statistically significant relative to control

include enhanced gastric mucosal defence through increased mucus and/or bicarbonate production, reducing the volume of gastric acid secretion or by simply neutralizing the gastric acidity. It becomes evident that this model of experimental ulcer is unable to indicate the mechanism of action of the extract. In order to have an idea of the possible mechanisms of action of the extract, its antiulcer potency was tested against pylorus ligated – induced ulcer.

Pylorus ligated-induced ulcer 

The macromorphological results obtained when ulceration of the gastric mucosa was provoked using pylorus ligation are shown in Table 2. At the dose of 1 g/kg, the methanol extract of the leaves of A. africana produced a significant (p <  0.05) decrease in ulcer surface area from 12.00 ± 3.05 to 5.75 ± 2.01. The plant extract was unable to affect the volume of gastric juice. The gastric acidity of treated animals (113 mEq/l) was higher than that of the control (104 mEq/l).

This technique revealed that although the methanol leaf extract of A. africana significantly reduced gastric ulceration, it was unable to reduce the volume of gastric juice secreted and even tended to increase the gastric acidity. These results suggest that the extract possesses neither anti-secretory potency nor any neutralizing effect. It is known that the cytoprotective action of some antiulcer drugs is mediated by the action of endogenous prostaglandins which promote mucus secretion and play an important role in maintaining mucosal integrity against the actions of various damaging agents (Miller et al, 1982; Jain et al., 2002). Substances like prostaglandins can thus provide gastric cytoprotection in rats against strong necrotizing irritants without reducing gastric acid secretion. It can be thought that the cytoprotective effect of the extract results from the enhancement of the mucosal barrier through the increase production of prostanglandin. Yamamoto et al. (1992) and Tan et al. (2000) have shown the prostaglandin-like cytoprotective action of some hydroxychalcone and methylene chloride extract of Bidens pilosa respectively and the methanol leaf extract of A. africana might be producing its antiulcer effects through the same mechanism. The anti-ulcer effects of the methanol extract of the leaves of Aspilia africana may be due to the presence of triterpenes in the extract. Some triterpernic compounds such as nimbidin have been shown to possess anti-ulcer activity (Pillai and Santhakumari, 1984). Cimetidine at the dose of 11.5 mg/kg reduced the ulcer lesion induced by HCl/ethanol (67 %) or by pylorus ligation (52 %). Additionally, it was able to reduce the volume of gastric juice. This goes to show its effectiveness in preventing gastric ulcer and also confirm its anti-secretory activity. More work is going on in our laboratory on the bio-guided fractionation of the methylene chloride/ methanol extract of the plant.

References
  1. Adjanohoun, J. E, Aboubakar, N., Dramane, K., Ebot, M. E., Ekpere, J.A., Enow-Orock, E.G., Focho, D., Gbile, Z.O., Kamanyi, A., Kamsu kom, J., Keita, A., Mbenkum, T., Mbi, C.N., Mbielle, A.L., Mbome, I.L., Mubiri, N.K., Nancy, W.L., Nkongmeneck, B., Satabie, B., Sofowa, A., Tamze, V. and Wirmum, C. K. (1996). Traditional Medecine and Pharmacopeia-contribution to ethnobotanical and floristic studies in Cameroon, CNPMS, Porto-novo, Benin.
  2.   Hara, N. and Okabe, S. (1985). Effects of gefernate on acute lesions in rats. Folia Pharmacologica Japonica85 : 443-448
  3. Hosttetmann, K., Hosttetmann, M., and Marston, A. (1991). Saponins. In: Methods in plant Biochemistry, vol. 7 (dey, P. M. and Harborne, J. B., eds.), Academic, New york, pp. 435-471.
  4. Iwu, M. M. (1993). Handbook of African medicinal plants, CRP press. Boca RatonFlorida.
  5. Jain, N. K., Kulkarni, S. K. and Singh, A. (2002). Modulation of NSAID-induced antinociceptive and anti-inflammatory effects by α2 adrenoceptor agonists with gastro protective effects. Life Sciences 70: 2857-2869
  6. Klyne, W. (1970) Quimica de los Esteroides ( Compania editorial Continental S. A., ed.), Barcelona, Spain, pp. 126-149.
  7. Markham, K.R. (1982) Technique of Flavonoid Identification, Academic, New York, pp 1-113.  
  8.   Miller, T.A. (1982). Protective effects of prostaglandin against gastric mucosal damage: current knowledge and proposed mechanisms. Am. J. physiol.245(Gastrointest. Liver physiol. 8): G601-G623
  9. Pillai, N.R and Santhakumari, G. (1984). Effects of nimbidin on acute and chronic gastro-duodenal ulcer models in experimental animals.Planta medica. 50: 143-146
  10. Shay, J.P., Komorov, S.A., Fels, S.S., Meranze, D., Grunstein, M. and Simpler, H. (1945). A simple method for the uniform production of gastric ulceration in the rat. Gastroenterology. 5: 43-61
  11. Tan, P.V., Nditafon, G.N., Yewah, M.P., Dimo, T. and Ayafor, J. F. (1996) Eremomastax speciosa: effects of leaf aqueous extract on ulcer formation and gastric secretion in rats J. Ethnopharmacol. 54: 139-142
  12. Tan PV, Dimo T. and Dongo E (2000). Effects of methanol cyclohexane and methylene chloride extracts of Bidens pilosa on various gastric ulcer models in rats. J. ethnopharmacol. 73: 415-421.
  13. Yamamoto, K., Kakegawa, H., Matsumoto, H., Sudo, T. and Satoh, T. (1992). Gastric cytoprotective antiulcerogenicactions of hydroxychalcones in rats. Planta Medica.  58: 389-393,

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