Volume 9, number 1
 Views: (Visited 401 times, 1 visits today)    PDF Downloads: 1011

Dheeba B, Vaishnavi E, Sampathkumar P, Kannan M. Hepatoprotective and Curative Effect of Eclipta prostrata on CCl4 Induced Hepatotoxicity in Albino Rats. Biosci Biotech Res Asia 2012;9(1)
Manuscript received on : 12 December 2011
Manuscript accepted on : 23 January 2012
Published online on:  --
How to Cite    |   Publication History    |   PlumX Article Matrix

Hepatoprotective and Curative Effect of Eclipta prostrata on CCl4 Induced Hepatotoxicity in Albino Rats

B. Dheeba1, E. Vaishnavi1, P. Sampathkumar1 and M. Kannan2

1Department of Biosciences, SRC, SASTRA University, Kumbakonam - 626 001, India.

2Department of Microbiology, V.H.N.S.N. College, Virudhunagar - 626 001, India .

Corresponding Author E-mail:deepabaskaran76@gmail.com

ABSTRACT: The combined antioxidant and hepatoprotective effect of Eclipta prostrata was evaluated against carbon tetra chloride (CCl4) induced hepatic damage in wistar albino rats. Ethanolic extract from the Eclipta prostrata at a dose level of 200mg/kg of body weight was administered orally daily once for 15 days. The substantially elevated serum marker enzymes such as Aspartate transaminase (AST), Alanine transaminase (ALT), Alkaline phosphatase (ALP), Acid phosphatase (ACP) and the antioxidant enzymes such as glutathione peroxidase, superoxide dismutase and catalase were found due to CCl4 treatment. The levels of above mentioned enzymes were brought to near normalcy after administration of plant extract. The biochemical parameters like total protein, total bilirubin were also restored towards normal levels. In addition Eclipta prostrata significantly decrease the liver weight of CCl4 intoxicated rats. Silymarin at a dose level of 25mg/kg was used as a standard reference drug for comparison.. The results of this study strongly indicate that Eclipta prostrata is having a potent hepatoprotective action against CCl4 induced hepatic damage in rats.

KEYWORDS: Hepatoprotective; Marker Enzymes; Eclipta prostrata; Carbon Tetra Chloride

Download this article as: 
Copy the following to cite this article:

Dheeba B, Vaishnavi E, Sampathkumar P, Kannan M. Hepatoprotective and Curative Effect of Eclipta prostrata on CCl4 Induced Hepatotoxicity in Albino Rats. Biosci Biotech Res Asia 2012;9(1)

Copy the following to cite this URL:

Dheeba B, Vaishnavi E, Sampathkumar P, Kannan M. Hepatoprotective and Curative Effect of Eclipta prostrata on CCl4 Induced Hepatotoxicity in Albino Rats. Biosci Biotech Res Asia 2012;9(1). Available from: https://www.biotech-asia.org/?p=9648

Introduction

Liver, is a vital organ, it has a wide range of functions, such as detoxification, protein synthesis, and production of biochemicals necessary for digestion1. Hepatic damage is associated with some metabolic function2. Liver disease is still a worldwide health problem3 Treatment option may vary depending on the causes of liver disease unfortunately, conventional or synthetic drugs used in the treatment of liver diseases, and sometimes can have serious side effect4. In modern medicine there are number of medicinal preparations in Ayurveda recommended for the treatment of liver disorder5. In view of severe undesirable side effects of synthetic agents, there is growing focus to follow systemic research methodology and to evaluate scientific basis for the traditional herbal medicines that are claimed to possess hepatoprotective activity. A single drug cannot be effective for all types of severe liver diseases6. Therefore an effective formulation has to be developed using medicinal plants, with proper pharmacological experiments and clinical trials.

The ethanolic extract of Eclipta prostrata was subjected to various assays in order to evaluate their hepatoprotective effect against CCl4 toxicity in albino rats. This plant have traditional claim against liver disorders and all of them are scientifically evaluated for their potency individually7. The plant E.prostrata is available for the treatment of various liver disorders8. The Preliminary phytochemical analysis of the Eclipta prostrata reveals that the presence of flavonods, alkaloids, tannins,phenols, steroids, terpenoids, carbohydrate,  protein and aminoacids.9, 10  The activity of the E.prostrata against CCl4 toxicity was compared with a well-known antihepatotoxic  agent  silymarin.11,12 So the present study the antihepatotoxic property of Eclipta prostrate was tested against CCl4 treated animal model by measuring the substantially elevated serum marker enzymes such as Aspartate transaminase (AST), Alanine transaminase (ALT), Alkaline phosphatase (ALP), Acid phosphatase (ACP) and the antioxidant enzymes such as glutathione peroxidase, superoxide dismutase and catalase were examined.

Materials and Methods

The plant materials were collected from commercial medicinal shop at kumbakonam. The plant was identified and authenticated taxonomically by Dr. S. Kalavathy, Associate Professor, Department of Botany, Bishop Heber College, Trichy. The leaves of E.prostrata (1kg) were shade dried and pulverized to a coarse powder.

Extraction

Equal quantities of the powder was passed through 40-mesh sieve and exhaustively extracted with 95% (v/v) ethanol in Soxhlet apparatus at 60οC. The extract was evaporated under pressure until all the solvent had been removed and further removal of the water was carried out by   freeze drying. The extract was stored in refrigerator; weighed amount was used for present investigation.

Phytochemical Analysis

Phytochemical analysis were carried out qualitatively and quantitatively to identify the presence and quantify various secondary metabolites such as flavonoids, alkaloids, saponins and tannins by HPLC.

 Experimental animals

Male albino Wistar rats weighing 200–230 g were used in all experiments. Animals were maintained on 12 h light/dark cycle at approximately 27°C. The animals were fed on a commercial pelleted rat chow (Hindustan Lever Ltd, Mumbai) and water ad libitum. Experiment was performed according to ethical guidelines for the investigation of experimental pain in conscious animals. The animals were sheltered for one week and prior to the experiment they were acclimatized to laboratory temperature, acute toxicity study was carried out as per “up and down” or “stair case” method13.

Experimental design

Hepatic injury was induced in rats by intraperitoneal administration of a single dose of 1 ml/kg CCl4 along with olive oil in the ratio of 1:1 (v/v). Sylimarin, a known hepatoprotective agent was used as reference drug. Animals were grouped as follows

Group I  – Control group, treated with saline (2.0 ml daily) for 15 days.

Group II – Treated with saline (2.0 ml daily) for 15 days followed by CCl4 (1ml/Kg) on day 15.

Group III – Treated with ethanolic extract of Eclipta prostrate (200mg/kg) daily for 15 days followed by CCl4 on day 15.

Group IV – Treated with sylimarin (25mg/kg) daily for 15 days followed by CCl4 on day 15.

On the 15th day the animals were sacrificed and various biochemical parameters were analyzed.At the end of the treatment, blood samples of all animals were collected in sterile centrifuge tubes and allowed to clot. Serum was separated and used for the assay.

Biochemical and statistical analysis

The serum bilirubin14 ,protein15, superoxide Dismutase16,17, catalase18 , Glutathione peroxidase19, ALT 20, AST 20, ACP 2 and ALP22  were estimated. All the enzymatic and biochemical assays were taken at particular nm using Shimadzu spectrophotometer. Values reported as Mean ± Standard Deviation. The statistical analysis was carried out using analysis of variance (ANOVA) followed by student T test, P values >0.001 were considered as significant.

Results and Discussion

In the present study ethanolic extract of Eclipta prostrata were evaluated for hepatoprotective activity using CCl4 in rat model. Necrosis or membrane damage releases the AST, ALT into circulation, hence it can be measured in the serum. High levels of AST indicates liver damage, such as that caused by viral hepatitis as well as cardiac infarction and muscle injury, AST catalyses the conversion of alanine to pyruvate and glutamate and is released in a similar manner. Phytochemical analysis results showed qualitatively and quantitatively identified the presence of various secondary metabolites such as flavonoids, alkaloids, saponins and tannins were studied (Table 1). Therefore ALT is more specific to the liver, and is thus a better parameter for detecting liver injury. Elevated levels of serum enzymes are indicative of cellular leakage and loss of functional integrity of cell membrane in liver 23. Serum ALP, ACP, bilirubin and total protein levels on other hand are related to the function of hepatic cell. Increase in serum level of ALP is due to increased synthesis, in presence of increasing biliary pressure24.

Administration of CCl4 caused a significant elevation of enzyme levels such as AST, ALT, ALP, ACP, total bilirubin and decrease in total protein when compared to control (Table 2). There was a significant restoration of these enzyme levels on administration of the plant extract and also by silymarin at a dose of   25mg/kg. The reversal of increased serum enzymes in CCl4 induced liver damage by the extract may be due to the prevention of the leakage of intracellular enzymes by its membrane stabilizing activity 25. Effective control of ALP, ACP, total bilirubin and total protein levels points towards an early improvement in the secretary mechanism   of the hepatic cells. The efficacy of any hepatoprotective drug is dependent on its capacity of either reducing the harmful effect or restoring the normal hepatic physiology that has been distributed by a hepatotoxin. Both silymarin and the plant extract decreased CCl4 induced elevated enzyme levels in tested groups, indicating the protection of structural integrity of hepatocytic cell membrane or regeneration of damaged liver cells26.

Decrease in enzyme activity of SOD is a sensitive index in hepatocellular damage and is the most sensitive enzymatic index in liver injury27. SOD has been reported as one of the most important enzymes in the antioxidant defense system. It scavenges the superoxide anion to form hydrogen peroxide and thus diminishing the toxic effect caused by this radical. In Eclipta prostrata causes a significant increase in hepatic SOD activity and thus reduces reactive free radical induced oxidative damage to liver. CAT is widely distributed in all animal tissues, red cells and liver. CAT decomposes hydrogen peroxide and protects the tissues from highly reactive hydroxyl radicals 28. Therefore reduction in the activity of CAT may result in a number of deleterious effects due to the assimilation of superoxide radical and hydrogen peroxide (Table 3). Glutathione is one of the most abundant tripeptide, non-enzymatic biological antioxidant present in the liver. It removes free radical species such as hydrogen peroxide, superoxide radical and maintains membrane protein thiol. Also it is substrate for glutathione peroxidase29. Decreased level of GSH is associated with an enhanced lipid peroxidation in CCL4 treated rats. Administration of Eclipta prostrata significantly increased the level of GPX. Preliminary phytochemical studies reveal the presence of flavonoids and phenols in extract posses various activities such as hepatoprotective activity30, antioxidant activity, antidiabetic activity, antifungal and antibacterial activity30.31.

In conclusion the E.prostrata ethanolic extract afforded protection from CCl4 induced liver damage the protections against liver damage by the plant were found comparable to silymarin 32,33. Possible mechanism that may be responsible for the protection of CCl4 induced liver damage by E.prostrata may be it could act as a free radical scavenger intercepting those radicals involved in CCl4 metabolism by microsomal enzymes. By trapping oxygen related free radicals the extract could hinder their interaction with polyunsaturated fatty acids and would abolish the enhancement of lipid peroxidative processes34, 35, 36. It is well documented that flavonoids and glycosides are strong antioxidants37, 38. Antioxidant principles from herbal resources are multifaceted in their effect and provided enormous scope in correcting the imbalance through regular intake of a proper diet. Hence we conclude the administration of E.prostrata is a promising hepatoprotective agent and this hepatoprotective activity of the plant may be due to its antioxidant chemicals present in it.

Table 1: Quantitative analysis of secondary metabolites of the Eclipta prostrata using HPLC.

S.NO SECONDARY METABOLITS AMOUT mg/kg
1. Total Alkaloids 0.55
2. Total Flavonoids 1.97
3. Tannin 0.06
4. Lignin 0.08
5. Phenol 0.11
6. Sterol 0.06
7. Saponin 0.15
8. Quinones 0.06
9. Coumarins 0.04
10. Terpenoids 0.03
11. Vitamins 98

Table 2: The effect of ethanolic extract of Eclipta prostrata on biochemical parameters and marker enzymes of liver.

Parameter  Group1 Group2 Group3 Group4

 

Total protein

(mg/dl)

 7.31±0.06 5.4± 0.003* 6.8±0.22** 7.1±0.13*
AST

(IU/L)

 119.7±1.3 383.7±1.82* 289.2±1.20** 245.4±2.3**
ALT

(IU/L)

 37.39±3.2 133.9±1.94* 85.1±1.55** 79.8±4.7**
ACP

(IU/L)

 15.07±0.81 87.3±7.9* 35.7±1.44** 33.6±2.4**
ALP

(IU/L)

 110.9±0.031 339±0.77* 216.0±0.12** 175.7±0.9**
Total Bilirubin

(mg/dl)

 0.43±0.04 1.6±0.77* 0.63±0.06** 0.57±0.01**
SOD (units/mg ptn)  77.03±3.91 45.87±0.50* 81.07±0.77** 88.34±2.54**
CAT

(nmoles of H2 O2  utilised /mt/mg ptn)

293.73±13.05 147.73±5.78* 283.2±11.92*** 268.27±6.465**
Glutathione peroxidase

( nmoles of GSH/ mt/ mg ptn)

 0.993±0.07 0.61±0.02* 0.9±0.06** 0.95±0.03***

Values are mean ±SD. Stastistical significant test for comparison was done by ANOVA, followed by T test (n=6)  *p< 0.05 vs control, **p< 0.01 vs control. ***p< 0.001 vs control

Table 3: Antioxidant activity of ethanolic extract of Eclipta prostrata using Hydrogen peroxide assay and phospho molybdate method.                 

   S.No.

Concentration

(mg/ml)

      % of Inhibition
H2O2 Phospho molybdate
1. 50 0.4991 0.5432
2. 100 0.6089 0.5925
3. 150 0.7513 0.6639
4. 200 0.7954 0.8010

References

  1. Pierce, A & Luper, S. A Review of plants used in the treatment of liver disease, Alternative  medicine Review, 3 : 410-421, 1977.
  2. Wolf pl .Biochemical diagnosis of liver disease, Ind. J. Clin. Biochem. 14:59-64, 1999
  3. Samudram,p Rajeshwari Hari, Vasuki,R, Geetha, A & Sathiya moorthi, P. Hepatoprotective activity of Bi- herbal ethanolic extract on CCL4 induced hepatic demage in rats, African Journal of Biochemistry Research 2(2) :061-065, 2008.
  4. Guntupalli M Chandana v, Palpu Pushpangadan, & Annie Shiwaikar I. Hepatoprotective effects of rubiadin, a major constituents of Rubia cordifolia Linn, J.Ethnopharmacol, 103: 484-490, 2006.
  5. Sattyavathi, G.V., Gupta, A.K and Tandon, A. Medicinal plants of India, ICMR, New delhi, 2 : 574-578 ,1997. 
  6. Shahani S. Evaluation of hepatoprotective efficacy of APCL-A polyherbal formulation in vivo in rats, Ind  Drugs. 36:628, 1999.
  7. Kulshrestha V.K, Srivastava R.K, Rastogi S .K, Kohli RP. Analysis of central stimulatory activity of Piper longum, J. Res. Indian. Med. 6:17-18, 1971.
  8. Wagner H, Geyer B, Kiso Y, Rao GS. Coumestants as main active principle of the liver drug Eclipta alba and Wedelia Calendulaceae plant, Medica. 5:370-373. 1986.
  9. Sing B, Saxena A.K, Chandan B.K, Agarwal SG, Bhatia M.S, Anand K.K. Hepatoprotective effect of ethanolic extract of Eclipta alba on Experimental liver damage in rats and mice, Phy. The. Res:7:154-158, (1993).
  10. Christina A.J.M, Saraswathy G.R, Heison Robert S.J, Kothai R,Chidambaranathan N.            Inhibition of CCL4 induced liver fibrosis by Piper Longum Linn, Phytomed. 13: 196-198, (2006).
  11. Recknagel R.O, Glende E.A Jr, Dolak JA, Walker RL. Mechnaisms of carbon tetrachloride toxicity, Pharmacol Ther 43: 139-54, 1989.
  12. Johnson E, & Krocning C. Mechanism of early CCl4 toxicity in cultured rat hepatocytes, Pharmacol Toxicol, 83: 231-239, 1998.
  13. Ghosh M.N. Fundamentals of Experimental Pharmacology, Scientific Book Agency, Calcutta pp.156-157.
  14. 14)Gupta, M., Mazumder, U.K., Thamil Selvan, V., Manikandan, L., Senthil kumar, G.P., Suresh, K. and Kakotti, B.K. Iranian J. Pharmacol. Thera., 6: 5-9 2007.
  15. Lowry,O.H., Rosebrough,N.J., Farr,A.L. andRandall, R.J, J. Biol.Chem., 193: 265-275 1951.
  16. Sun Y, Oberley L.W, & Li Y. A simple method for clinical assay of superoxide dismutase. Clin. Chem 34: 479-500, 1998.
  17. Kakkar P, Das B, & Viswanathan P.N. A modified spectrophometric assay of SOD. Indian J. Biochem. Biophy. 21: 130-132, 1984.
  18. Beers R.F, & Sizer I.W. A spectrophotometric method for measuring the breakdown of hydrogen peroxide by catalase, J. Biol. Chem, 195 : 133-141. 1952.
  19. Paglia D, & Valentine W.N. Studies on the quantitative and aualitative characterization of Erythrocyte glutathione peroxide, The J. Lab Clin. Med, 70 : 158-163. 1967.
  20. Reitman, S. and Frankel,A.S.:Am. J. Clin. Path., 28:53-56, 1957.
  21. Walker K, & Schutt C. Acid Phosphatase, In : Bergmeyer, H.U (ed). Methods of Enzymatic Analysis, Academic Press : New York, NY : 856-860, 1974.
  22. Tiez, N.W.:Clin.Chem., 29: 751-761 1983.
  23. Drotman R & Lawhan G. Serum enzymes are indications of chemical induced liver damage,Drug Chem Toxicol, 1 : 163-171, 1978.
  24. Muriel P & Garcipiana T. Silymarin protects against paracetamol-induced lipid peroxidation and liver demage, J Appl Toxicol, 12 : 439-442,1992.
  25. Rajkapoor B, Venugopal Y, Anbu J, Harikrishnan N, Gobinath M and  Ravichandran V. Protective effect of  Phyllanthus Polyphyllu,  J.Pharm. Science 21, 1:57-62, 2008.
  26. Thabrew M and Joice P.  A comparative study of the efficacy of pavetta indica and Osbeckia Octanda in the treatment of liver dysfunction, Planta Med, 53: 239-241. 1987.
  27. Curtis JJ & Mortiz. Serum enzymes derived from liver cell fraction and response to carbon tetrachloride intoxication in rats,  Gastroenterol, 62:84-92, 1972.
  28. Chance B & Greenstein DS. The mechanism of catalase actions-steady state analysis, Arch Biochem Biophys, 37: 301- 339, 1992.
  29. Prakash J Gupta SK & Singh N. Chemopreventive activity of Withania somnifera in experimentally induced fibro sarcoma tumors in Swiss albino rats, Phytother Res, 15: 200-204, 2001.
  30. Seevola D, Baebacini GM & Bona S. Flavanoids and hepatic cyclic monophosphates in liver injury, Boll. Ins Steroter Milan, 63 : 777-782, 1984.
  31. Wegner T & Fintelmann V. Flavonoids and bioactivity, Wein Med, Wochem Sihr, 149 : 241-247, 1999.
  32. Upadhyay R.K, Pandey M.B, Jha R.N, & Pandey V.B. Eclalbatin triterpine saponinis from Eclipta alba, J. Asian nat Prod Res. 3: 213-217, 2001.
  33. Natarajan, Kavithalakshmi, Madhusudhanan, Narasimhan, Radha Shanmugasundaram K, Shanmugasundram ERB. Antioxidant activity of a salt- spice-herbal mixture against free radical induction, J. Ethnopharmacol. 105: 76-83, 2006.
  34. Dheeba, B., Sampathkumar, P., Sathiya Priya R. R. and Kannan, M., Phytochemical studies and evaluation of antioxidant potential of various extracts of Aegle marmelos bark.  Pharmacologyonline 3: 831-839, 2010.
  35. Rajashree C.R, Rajmohan T & Augusti K.T. Antiperoxidative effect of garlic in alcohol fed rats. Indian J. Exp. Biol, 36 : 60-64, 1998.
  36. Upadhyay R.K, Pandey M.B, Jha R.N, & Pandey V.B, Eclalbatin triterpine saponinis from Eclipta alba, J. Asian nat Prod Res. 3: 213-217, 2001.
  37. Marikani Kannan and Ranjit Singh, A.J.A., An Immuno-Pharmacological Investigation of Indian Medicinal Plant Nyctanthes arbor-tristis Linn, World Applied Science Journal,   Vol 11- 5., 2010.
  38. Natarajan, Kavithalakshmi, Madhusudhanan, Narasimhan, Radha Shanmugasundaram K, Shanmugasundram ERB, Antioxidant activity of a salt- spice-herbal mixture against free radical induction, J. Ethnopharmacol. 105: 76-83, 2006.
  39. Parthasarathy R, Nivethetha M, Brindha P. 2007. Hepatoprotective activity of Caesalpinia bonducella seeds onparacetamol induced hepatotoxicity in male albino rats. Indian Drugs 44(5):401-404.
(Visited 401 times, 1 visits today)

Creative Commons License
This work is licensed under a Creative Commons Attribution 4.0 International License.