Journal of Biomedical Sciences

Keywords

Cissampelos owariensis; Anti-ulcer effects; Wistar rats

Introduction

Medicinal plants refer to plants that have parts such as seeds, leaves, barks, roots, stem, fruits or the whole plant with constituent phytochemicals that can be applied for therapeutic purposes in order to ameliorate pains and cure diseases. These plants represent important components of natural plant biodiversity especially in many African countries where they constitute vital source of health care for many individuals due to the relative accessibility, affordability, efficacy and tolerability of medicinal plant products [1-3]. One of such medicinal plants is Cissampelos owariensis P. Beauvais ex DC. (also called lungwort) which belongs to the Menispermaceae family that comprises of about 70 genera and 450 species. C. owariensis is a twiner plant found in tropical regions especially in the wild of some sub-Saharan African countries [4]. Different parts of the plant (especially leaf and root) are used by traditional medical practitioners for various therapeutic applications. Extracts derived from C. owariensis have been applied in the treatment of metrorrhagia, wounds, snake bites, circulatory and reproductive diseases, amnesia and psychosis [5,6] prevention of miscarriage and treatment of sterility [7-9] and treatment of various gastrointestinal conditions such as dysentery, diarrhoea, enteritis, colic and intestinal worms [10,11]. They also exhibited diverse biological activities such as insecticidal activity, antimicrobial and antiviral activity, antibacterial and antifungal activity [12,13]. The previous study had reported potent anti-oxidant activity of methanol extract of C. owariensis which was especially linked to the flavonoid component of its phytochemicals [14]. These phytochemical flavonoids are plant-derived phenols that exhibit free radical scavenging, anti-allergic and antiinflammatory activity and help to prevent diseases including gastric ulcers [15-17]. However, there remains a dearth of documented pharmacological studies on various therapeutic uses of C. owariensis. Hence, the need for this present study in which, the methanolic leaf extracts of C. owariensis was investigated to assess its anti-ulcerogenic effects on gross and histomorphology of gastric tissues of experimental animals following exposure to the erosive effect of acidic gastric secretions.

Methods

Plant material

The gross appearance of the internal aspect of gastric tissues of experimental animals (Figure 1) showed normal gastric mucosa in the normal control group A, varying degrees of mucosal surface protection in treated groups B-D and prominent mucosal surface erosion in test control group E after exposure to the acidic gastric secretions during the pyloric-ligation method.

Figure 1: A-E: Macroscopic appearances of the internal aspect of gastric tissues of experimental animals. Group A animals represented normal control animals, group B, C and D animals were given 100 mg/kg, 300 mg/kg and 500 mg/kg methanolic extracts of C. owariensis respectively and group E animals represented test control animals. F: Ulcer index of gastric mucosa of experimental animals in groups A-E (*+p<0.05 was considered significant compared to Groups A and E respectively).

Ulcer index of the gastric mucosa of experimental animals

The ulcer index of gastric mucosa showed slightly significant increase in treated groups B-D due to the gastroprotective activity of the plant extracts against the erosive effects of gastric acid exposure. However, a spike in ulcer index was observed in test control group E due to exposure to acidic gastric secretions without prior treatment with the plant extracts.

Microscopic results

This histological examination of the gastric tissues of experimental animals (Figure 2) showed normal histological architecture of the gastric mucosa of treated animals in normal control group A, moderate mucosal surface erosion in treated groups B and C, mild mucosal surface erosion in treated group D and intense mucosal surface erosion in test control group E following exposure to acidic gastric secretions during pyloricligation method.

Figure 2: Histological appearances of the gastric tissue of experimental animals (groups A E) (H and E X100). Group A animals represented normal control animals, group B, C and D animals were given 100 mg/kg, 300 mg/kg and 500 mg/kg methanolic extracts of C. owariensis respectively and group E animals represented test control animals. Arrows indicated mucosal surface erosion.

Discussion

The gastric mucosa is constantly vulnerable due to exposure to different substances which may alter the structural integrity of the mucosa causing injury and ulceration especially when gastric mucosal defensive factors are over-whelmed. These defensive factors (such as mucin, bicarbonate, nitric oxide, prostaglandins, and others) help to mitigate against erosive effect of offensive factors (such as gastric acid, pepsin, stress, Helicobacter pylori, and others) thereby preventing mucosal injury and ulcerations [21,22]. Hence, potent anti-ulcerogenic or gastroprotective agents or drugs function by counteracting aggressive factors or stimulating the protective factors [23]. In this study, the pre-treatment of methanolic extracts of C. owariensis conferred on the gastric mucosa of experiment animals certain degrees of protection against the erosive effect of acidic gastric secretion exposure during the pyloricligation method. According to the result of the macroscopic and microscopic examinations of gastric mucosa of experimental animals (Figure 1), the treated groups B-D compared relatively with the mucosal morphology of the normal control group A. The treated groups B-D also showed very insignificant mucosal surface erosion when compared to the intensely eroded mucosal surface of test control group E. The observed anti-ulcer effects of methanolic extracts of C. owariensis in this study may be linked to its constituent bioactive phytochemical compounds. Generally, the constituent phytochemical compounds especially its high-value, lowvolume secondary metabolites confer on medicinal plants and or preparations the medicinal properties applied in ameliorating pains and treatment of diseases, hence, called active principles or bioactive components [24-26]. Previous studies have posited that flavonoids derived from medicinal plants exhibit significant anti-oxidant effect and protect against toxic effects of reactive oxygen species (ROS) due to their hydroxyl groups [27,28]. These phytochemical flavonoids have been described to exhibit gastroprotective functions due to by their ability to promote gastric mucus synthesis (by mucous cells), reduce gastric acid secretion (by parietal cells) and down-regulate pepsinogen synthesis (by chief cells) [29-31]. From the result of this study, the gastric mucosa of experimental animals with prior exposure to methanolic leaf extracts of C. owariensis exhibited some degrees of gastric mucosal protection against erosive effects of offensive factors (acidic gastric secretions). This is more prominent in higher dosage level of extracts which invariably contain more flavonoids compounds. Hence, the gastroprotective activity of methanolic leaf extracts of C. owariensis, like other pharmacological activities of the plant extracts, can be described as a function of its constituent phytochemical compounds. Further studies may be necessary to describe the cellular and sub-cellular mechanisms of anti-ulcer effects of methanolic leaf extracts of C. owariensis.

Conclusion

This study affirmed the anti-ulcerogenic activity of methanolic leaf extracts of Cissampelos owariensis (P. Beauv.) and such activity can be associated with therapeutic properties of phytochemical constituents of the plant extract.

References

1. Craig GM, David JN (2001) Natural product drug discovery in the next millennium. Pharmaceut Biol 39: 8-17.
2. Okigbo RN, Eme UE, Ogbogu S (2008) Biodiversity and conservation of medicinal and aromatic plants in Africa. Biotechnol Mol Biol Rev 3: 127-134.
3. Adelanwa EB, Tijjani AA (2013) An ethno medical survey of the flora of Kumbotso local government area of Kano State. Nig J Pharmaceut Sci 12: 1-9.
4. Akande R, Okwute SK, Iliya I, Efiom OO (2013) Chemical constituents and anti-tuberculosis activity of the root extracts of Cissampelos owariensis (P. Beauv.) Menispermaceae. Afr J Pure App Chem 7: 21-30.
5. Adjanohoun EG, Lo CA, Keita A, Lebras M, Lejoly J, et al. (1989) Traditional medicine and pharmacopoeia database (Pharmel).
6. Schmelzer GH (2008) Plant resources of tropical Africa. Medicinal plants PROTA, Wageningen, Netherlands.
7. Abbiw DK (1990) Useful plants of Ghana. West African uses of wild and cultivated plants. Intermediate Technology Publications, London and Royal Botanic Gardens, Kew.
8. Adjanohoun E, Ahyi MRA, Ake AL, Elewude JA, Dramane K, et al. (1991) Traditional medicine and pharmacopoeia contribution to ethnobotanical floristic studies in western Nigeria. pub. Organization of African Unity, Scientific Technical and Research Commission Lagos, Nigeria.
9. Neuwinger HD (2000) African traditional medicine: A dictionary of plant use and applications. Medpharm Scientific Publishers, Stuttgart.
10. Ekeanyanwu RC, Udeme AA, Onuigbo AO, Etienajirhevwe OF (2012) Anti-diabetic effect of ethanol leaf extract of Cissampelos owariensis (lungwort) on alloxan induced diabetic rats. Afr J Biotechnol 11: 6758-6762.
11. Erhirhie OE, Moke EG, Chinwuba P (2015) Cissampelos owariensis: Experimental review. Phar Innov J 3: 75-77.
12. Niber BT, Helenus J, Varis AL (1992) Toxicity of plant extract to three storage beetles (coleopteran). J Appl Entomol 113: 202-208.
13. Efiom OO, Okwute SK, Okogun JI, Orishadipe AT (2009) Sesquiterpenes from Cissampelos owariensis (P. BEAUV) root with antimicrobial and antiviral activity. J Chem Soc Nigeria 34: 11-16.
14. Olajide O, Orishadipe A, Fatokun O, Akande T, IIiya I (2013) The chemical composition of essential oil from the root of Cissampelos owariensis (P. Beauv) and free radical scavenging activities of its extracts. Afr J Pur Appl Chem 7: 225-230.
15. Polterait O (1997) Antioxidants and free radical scavengers of natural origin. Curr Org Chem 1: 415-440.
16. Aruma OI (1998) Free radicals, oxidative stress and antioxidants in human health and disease. J Am Oil Chem Soc 75: 199-212.
17. Ayoola GA, Coker HAB, Adesegun SA, Adepoju BAA, Obaweya K, et al. (2008) Phytochemical Screening and Anti-oxidant Activities of some selected Medicinal Plants Used for Malaria Therapy in South-Western Nigeria. Trop J Pharm Res 7: 1019-1024.
18. Shay JP, Komorov SA, Fels SS, Meranze D, Grunstein M, et al. (1945) A simple method for the uniform production of gastric ulceration in the rat. Gastroenterol 5: 43-61.
19. Ajeigbe KO, Olaleye SB, Oladejo EO, Olayanju AO (2011) Effect of folic acid supplementation on oxidative gastric mucosa damage and acid secretory response in the rat. Indian J Pharmacol 43: 578-581.
20. Sheehan D, Hrapchak B (1980) Theory and practice of histotechnology. 2nd ed Ohio USA Battelle Press, Columbus, pp: 153-166.
21. Ajeigbe KO, Onifade AA, Omotoso DR, Enitan SS, Olaleye SB (2014) Anti-ulcerogenic activity of Aspilia Africana leaf extract: Roles of gastric acid, oxidative stress and neutrophil infiltration. Afr J Biomed Res 17: 193-201.
22. Mary SJ, Merina AJ (2015) Gastroprotective Effect of Guttarda speciosa against Ethanol Induced Gastric Ulcer in Rats. Med Aromatic Plants 5: 224.
23. Adewoye EO, Salami AT (2013) Anti-ulcerogenic mechanism of magnesium in indomethacin induced gastric ulcer in rats. Nig J Physiol Sci 28: 193-199.
24. Cowman MM (1999) Plant products as antimicrobial agents. Clin Microbiol Rev 12: 561-582.
25. Duraipandiyan V, Ayyanar M, Ignacimuthu S (2006) Antimicrobial activity of some ethnomedicinal plants used by Paliyar tribe from Tamil Nadu, India. BMC Complem Alt Med 6: 35-41.
26. Banso A, Adeyemo SO (2007) Phytochemical and antimicrobial evaluation of ethanolic extract of Dra-caena manni Bark. Nig J Biotechnol 18: 27-32.
27. Vaya JS, Mahmood S, Goldblum A, Aviram M, Volkova N, et al. (2003) Inhibition of LDL oxidation by flavaonoids in relation of their structure and calculated enthalpy. Phytochem 62:  89-99.
28. Kris EPM, Hecker KD, Bonanome A, Coval SM, Binkoski AE, et al. (2002) Bioactive compounds in foods: their role in the prevention of cardiovascular disease and cancer. Am J Med 113: 71-88.
29. Lewis DA, Hanson PJ (1991) Anti-ulcer drugs of plant origin. In: Ellis GP West GB (EDS), Progress medicinal chemistry. Elsevier Sci Publishers 28: 2001-2031.
30. Reyes M, Martin C, Alarcon LC, Trujillo J, Toro MV, et al. (1996) Antiulcerogenicity of the flavonoids fraction from Erica and evalensis Cabezudo-Rivera. J Natural Sci 51: 563-569.
31. Borrelli F, Izzo AA (2000) The plant kingdom as source of anti-ulcer remedies. Phytother Res 14: 581-591.