Hypoglycemic Effect of Calotropis gigantea Linn. Leaves and Flowers in Streptozotocin-Induced Diabetic Rats  
   Nanu R Rathod,1 Havagiray R Chitme,2 Raghuveer Irchhaiya,3 Ramesh Chandra4   
 
 
  DOI 10.5001/omj.2011.26  
 
 
 
From the 1Department of Pharmacology, H. S. K. College of Pharmacy, Bagalkot, Karnataka, India; 2Oman Medical College, Baushar Campus Azaiba, Muscat, Sultanate of Oman; 3Institute of Pharmacy, Bundelkhand University, Jhansi, India; 4Ambedkar Centre for Biomedical Research, Delhi University New Delhi, India.

Received: 03 Dec 2010
Accepted: 11 Feb 2011

Address correspondence and reprints request to: Dr. Havagiray R Chitme, Oman Medical College, Baushar Campus, Azaiba, Muscat, Sultanate of Oman.
E-mail: hrchitme@rediffmail.com
 
 
 
 

How to cite this article

Rathod NR, Chitme HR, Irchhaiya R, Chandra R. Hypoglycemic Effect of Calotropis gigantea Linn. Leaves and Flowers in Streptozotocin-Induced Diabetic Rats. Oman Med J 2011 March; 26(2):104-108.

How to cite this URL

Rathod NR, Chitme HR, Irchhaiya R, Chandra R. Hypoglycemic Effect of Calotropis gigantea Linn. Leaves and Flowers in Streptozotocin-Induced Diabetic Rats. Oman Med J 2011 March; 26(2):104-108. Available from http://www.omjournal.org/fultext_PDF.aspx?DetailsID=80&type=fultext 

 
 
 
 

Abstract

Objectives: To evaluate the hypoglycemic and anti-diabetic activity of chloroform extract of Calotropis gigantea leaves and flowers in normal rats and streptozotocin induced diabetes.

Methods: The hypoglycemic activity in normal rats was carried out by treatment using chloroform extract of Calotropis gigantea leaf and flower 10, 20 and 50 mg/kg, orally. The oral glucose tolerance test was carried out by administering glucose (2 g/kg, p.o), to non-diabetic rats treated with leaf and flowers extracts at oral doses 10, 20 and 50 mg/kg, p.o and glibenclamide 10 mg/kg. The serum glucose was then measured at 0, 1.5, 3 and 5 hr after administration of extracts/drug. Streptozotocin-induced diabetic rats were administered the same doses of leaf and flower extracts, and standard drugs glibenclamide was given to the normal rats or 0.5 ml of 5% Tween-80, for 27 days. The blood sample from all groups collected by retro-orbital puncture on 7, 14, 21 and 27th days after administration of the extracts/drug and used for the estimation of serum glucose levels using the glucose kit.

Results: The Calotropis gigantea leaves and flowers extracts were effective in lowering serum glucose levels in normal rats. Improvement in oral glucose tolerance was also registered by treatment with Calotropis gigantean. The administration of leaf and flower extracts to streptozotocin-induced diabetic rats showed a significant reduction in serum glucose levels.

Conclusion: It is concluded that chloroform extracts of Calotropis gigantea leaves and flowers have significant anti-diabetic activity.

Introduction

Diabetes   is  the  world’s  largest  endocrine  disease with deranged carbohydrate, fats and protein metabolism. As part of the pathogenesis of type 2 diabetes; skeletal muscle, liver, glucose and adipose tissue become resistant to the hormonal effect  of insulin, which in turn lead to decreased insulin-mediated glucose disposal, hepatic glucose overproduction and a marked increase in lipolysis.1 There are an estimated 143 million people in the world with diabetes mellitus and this number will probably double by the year 2030.2   Due to the enormous costs of modern treatment for diabetes in developing countries, the use of medicinal plants and their preparation has flourished as an alternative for the control and prevention of the disease.3

Currently, there are several drugs available for treatment of diabetes mellitus but most of them are synthetic drugs and this makes the anti-diabetic treatment costly. In view of reducing the cost of treatment for diabetes mellitus, there is considerable research for herbal production as anti-diabetics and around 12000 plants have been reported to possess anti-diabetic property.4 Swarnabhasma; an Ayurvedic  preparation containing Calotropis  gigantea  R. Br (C. gigantea) and flowers  were extensively  used  by Ayurvedic physicians for treatment of disorders such  as diabetes mellitus, bronchial asthma, rheumatoid arthritis, and nervous disorders.5,6 Chloroform extract of C. gigantea leaves and flowers prevent insulin induced resistance in high fructose diet.7 Another member of this genus, Calotropis procera has also been reported to possess anti- diabetic activity.8  C. gigantea has been reported to contain proteases, 3'-methylbutanoates of amyrin,9 flavonol glycosides,10 calotropins,11 Stigmasterol and sitosterols,12 cardenolides,13 and pregnanone.14

Its   roots  have   been  used  in  leprosy, eczema,  syphilis, elephantiasis, ulceration, anti-diarrhoeal, and cough in the Indian system  of  traditional  medicine.15 Antipyretic  and   analgesic activities,11,16 of the alcohol extract of peeled roots of C. gigantea were also recently reported in mice models.17,18 The  milky juice of C. gigantea  has been reported to be a violent  purgative and gastrointestinal irritant and as being used for inducing abortion.19 The crude latex extract is reported to exhibit strong proteolytic activity, being able to hydrolyse casein, human fibrinogen and crude fibrin clot in a dose dependent manner.20  It has also been reported for Antiamoebic,21  wound healing,22  hepatoprotective,23    and anti- oxidant,24  properties.

Recently, many natural products containing glycosides, flavonoids and steroids are being reported to possess anti-diabetic and hypoglycaemic effects due to their anti-inflammatory and anti- oxidant properties.25-28 Previous studies carried out on C. gigantea have  indicated the presence of proteases, glycosides, flavonoids and phenolic compounds and were proven to be responsible for antioxidant and anti-inflammatory properties.9-14,17 

Based on  these findings,  we hypothesized that  this  plant preparation  may  also  exhibit  hypoglycemic and  anti-diabetic properties. Therefore, the present study was designed with an objective to evaluate possible anti-diabetic activity of C. gigantea using chloroform extract of leaves and flowers in diabetic rats and also to determine improvement in glucose tolerance by using oral glucose tolerance test (OGTT).

Methods

C. gigantea  leaves  and flowers  were collected in the region of Bagalkot-Karnataka India, during September - October 2005. The plant was authenticated at the Dept. of Botany, Basaveswara Science College, Bagalkot-Karnataka India. A voucher specimen (BSC/ BOT/04/09) was deposited in the same Institute. 

The plant material was shade-dried and uniformly powdered by passing through the sieve #44 and then subjected to hot continuous extraction with petroleum ether (40-60°C) to defat the preparation, followed by chloroform, ethyl acetate and methanol extraction for a 24 hr cycle. The crude extract solution was concentrated  by using rotary flash evaporator to produce a semisolid mass, and dried in lyophilizer (Mini Lyotrap, Serial No. J8199/5, LET Scientific LTD, UK). 

The Streptozotocin was purchased from Sigma Chemical Co St Louis, USA. Petroleum ether (40-60°C) chloroform, ethyl acetate, and methanol AR grade were purchased from Nice Pvt Ltd, India. 

The extracts were then formulated as suspension in distilled water using 5% Tween-80 as suspending agent.29  When different extracts were tested for hypoglycemic activity on normal rats, the chloroform extract was the only effective  one and was  the one selected for further treatment. The dose ranges were selected based on previous studies.17 Henceforth, CECGL and CECGF refers to chloroform extracts of C. gigantea leaves and flowers respectively. 

Wistar  albino rats (150-200 g) of either sex were used in this study, after one week period of acclimatization to laboratory conditions. The animals were housed under standard environmental condition of temperature (21 ± 2°C), humidity (51 ± 10%) and 12 hr light-dark cycles with standard pellet diet (Amrut Lab) and water ad libitum. Animals were divided into various groups, each group consisted of three male and three female rats. All the experiments were carried out as per the guidelines  of Institutional Animals Ethics Committee (RGE No.821/A/CPCSEA)  of College after approval (HSK/IAEC.Clear/2004-2005) dated 27/12/04.

Anti-diabetic activity  of  chloroform extract of  leaves  and flower was evaluated using STZ- induced diabetic rats. The STZ was dissolved in citrate buffer (pH 4.5) and was administered by intraperitoneal route at 55 mg/kg for each rat and their serum glucose levels were estimated after 72 hr. The rats’ serum glucose levels which were over and above 300 mg/dl were considered to be diabetic resembling chronic diabetic condition and hence they were selected and divided into eight groups of six rats each.1 

To determine the hypoglycemic activity in normal rats, the rats were kept on fasting for 18 hrs and were divided into seven groups of six rats each. 

Group 1: served as the controls, 0.5 ml of 5% Tween-80 in distilled water orally. Tween-80 was used as a suspending agent to suspend the      extract for oral administration. 

Group 2: CECGL extract 10 mg/kg, p.o

Group 3: CECGL extract 20 mg/kg, p.o

Group 4: CECGL extract 50 mg/kg, p.o

Group 5: CECGF extract 10 mg/kg, p.o

Group 6: CECGF extract 20 mg/kg, p.o

Group 7: CECGF extract 50 mg/kg, p.o

The blood samples from all groups were drawn by retro-orbital plexus from each rat, under anesthesia at 0, 1.5, 3 and 5 hrs after CECGL and CECGF extract administration. The serum glucose levels were estimated from all blood samples using a glucose kit.1

For the oral glucose tolerance test, the rats were kept on fasting for 18 hrs and then divided into eight groups of six rats each:

Group 1: served as the control, 0.5 ml of 5% Tween-80 in distilled water, p.o

Group 2: glibenclamide 10 mg/kg, p.o

Group 3: CECGL extract 10 mg/kg, p.o

Group 4: CECGL extract 20 mg/kg, p.o

Group 5: CECGL extract 50 mg/kg, p.o

Group 6: CECGF extract 10 mg/kg, p.o Group 7: CECGF extract 20 mg/kg, p.o

Group 8: CECGF extract 50 mg/kg, p.o

The rats of all groups were loaded with glucose (2 g/kg) 30 minutes after administration of extracts/ drugs. Blood samples were withdrawn from each rat at 0, 0.5, 1.5, and 3 hrs after CECGL and CECGF extract administration and the serum glucose levels were then estimated from all blood samples using a glucose kit 30, 31 

To determine the anti-diabetic activity, the rats were grouped as follows: 

Group 1: served as the controls, 0.5 ml of 5% Tween-80 in distilled water, p.o

Group 2: glibenclamide 10 mg/kg, p.o

Group 3: CECGL extract 10 mg/kg, p.o

Group 4: CECGL extract 20 mg/kg, p.o

Group 5: CECGL extract 50 mg/kg, p.o

Group 6: CECGF extract 10 mg/kg, p.o

Group 7: CECGF extract 20 mg/kg, p.o

Group 8: CECGF extract 50 mg/kg, p.o

The blood samples from all groups were drawn on the 7, 14, 21, and 27th days after administration of CECGL and CECGF extracts and were used for estimation of serum glucose levels using a glucose kit.30,31 All data collected from the experiment  were expressed as the mean ± standard error (SEM) and analyzed by student t test  by using Graphpad prism  4.02-version software (USA).30, 31

Results

The hypoglycemic effect of CECGL and CECGF extracts oral dose 10, 20 and 50 mg/kg were found to be effective in lowering serum glucose levels in normal rats.

The  CECGF  at  50  mg/kg  exhibited significant  (p<0.01) hypoglycemic  effects compared to leaves  at 3 hrs intervals. The serum glucose levels were proportionately reduced with increase in dose of CECGL and CECGF. It is evident from the results that the CECGF exhibited better hypoglycemic  effects  compared to CEGGL. (Table 1)

For the OGTT, CECGL and CECGF extracts, an oral dose of 50 mg/kg was found to be effective in lowering serum glucose levels. There was a significant (p<0.01) reduction in serum glucose levels at time intervals of 0.5-1.5 hr. (Table 2)

Table 1: Hypoglycemic effect of chloroform extracts of Calotropis gigantea leaf and flower in normal rats.


Treatments  
Mean blood serum glucose ± SEM (mg/dl) at the intervals 
 0 h 1.5 h   3 h 5 h
Controla 91.0 ± 3.0  89.2 ± 4.9 101.2 ± 4.5  101.8 ± 6.2
CECGLb 10 mg/kg 85.2 ± 5.9              69.8 ± 5.9*  66.8 ± 6.4* 70.6 ± 4.0*
CECGL b20 mg/kg  82.8 ± 3.9              69.9 ± 6.9*  63.1 ± 4.9*  63.9 ± 4.4*
CECGLb 50 mg/kg 83.1 ± 4.2            56.0 ± 5.4*  51.4 ± 4.3** 57.5 ± 3.9*
CECGFc 10 mg/kg 82.3 ± 5.3            57.1 ± 5.0** 53.8 ± 4.1* 70.6 ± 1.6*
CECGFc 20 mg/kg 78.9 ± 4.5             64.9 ± 4.9* 53.7 ± 3.4**  61.3 ± 2.3*
CECGFc 50 mg/kg 73.4 ± 7.5             48.8 ± 3.2* 39.9 ± 2.2** 8.2 ± 2.0*

a(0.5 ml of 5% Tween 80) CECGLb: (Chloroform extract of Calotropis gigantea leaves); CECGFc: (Chloroform extract of Calotropis gigantea flowers). Values are expressed in terms of the standard error of the mean (SEM) n=6 in each group *p <0.05, **p <0.01. When student t test (paired) compared 0 hr with the interval of 1.5, 3 and 5 hr.

Table 2: Effect of chloroform extracts of Calotropis gigantea leaf and flower on glucose tolerance in normal rats .


Treatments  
Mean blood serum glucose ± SEM (mg/dl) at the intervals 
 0 h 0.5 h   1.5 3 h
Control (glucose 2 g/kg) 78.2 ± 3.4        
153.7 ± 4.6
 144.1 ± 3.9
122.7 ± 3.1
Glibena 10 mg/kg + glucose 2 g/kg 75.4 ± 2.1
116.9 ± 5.3***
94.56 ± 3.1***
78.7 ± 4.0***
CECGLb 10 mg/kg + glucose 2 g/kg 86.5 ± 6.1
132.6 ± 3.2**
126.0 ± 3.5**
111.2 ± 3.8*
CECGLb 20 mg/kg + glucose 2 g/kg 82.9 ± 3.3 127.1 ± 5.7**
117.4 ± 4.7**
95.2 ± 5.2**
CECGLb 50 mg/kg + glucose 2 g/kg 80.0 ± 3.9    
125.9 ± 5.4** 
116.4 ± 7.1**
96.5 ± 5.3**
CCECGFc 10 mg/kg + glucose 2 g/kg 83.6 ± 4.5          
132.4 ± 2.5**
126.7 ± 2.2**
107.0 ± 5.5*
CECGFc 20 mg/kg + glucose 2 g/kg 76.9 ± 5.3       
131.3 ± 2.7** 
124.8 ± 2.2** 
109.1 ± 3.8*
CECGFc 50 mg/kg + glucose 2 g/kg 77.2 ± 4.6 129.7 ± 2.7** 122.0 ± 1.9*** 107.5 ± 3.4**

aGlibenclamide; CECGLb: (Chloroform extract of Calotropis gigantea leaves); CECGFc: (Chloroform extract of Calotropis gigantea flowers). Values are expressed  in terms of the standard error of the mean (SEM) n=6 in each group *p <0.05,  **p <0.01  ***p <0.001, when student t test (Unpaired)  compared to control.

The anti-diabetic effect of CECGL and CECGF extracts for 27 days of treatment were found to be effective even at an oral dose of 10 mg/kg (p<0.001) in lowering serum glucose levels in STZ-induced diabetic rats. However, the reduction in serum glucose levels was better on the 21st and 27th  days of treatment. The results further revealed that the maximum serum glucose suppression occurred on the 27th  day after CECGL and CECGF extracts treatment, when compared to the control. Glibenclamide at 10 mg/kg caused a significant (p<0.001) reduction in serum glucose on all days. (Table 3)

Table 3: Effect of chloroform extracts of Calotropis gigantea leaf and flower in STZ-induced diabetic rats.


Treatments  
Mean blood serum glucose ± SEM (mg/dl) in days 
7 14 21 27
Control  346.8 ± 12.6     
351.5 ± 11.9
346.1 ± 11.2
352.0 ± 9.0
Glibenb 10 mg/kg  210.6 ± 8.3***
176.0 ± 9.4***
192.4 ± 5.7***
160.0 ± 8.6***
CECGLb 10 mg/kg  262.3 ± 13.3*** 268.9 ± 18.1**  
271.8 ± 14.1**
275.3 ± 12.8***
CECGLb 20 mg/kg  239.6 ± 22.6**   263.0 ± 8.3*** 
264.8 ± 6.5***
266.5 ± 7.4***
CECGLb 50 mg/kg  264.3 ± 13.5**  269.8 ± 14.5** 
262.2 ± 13.1***
249.1 ± 18.2***
CCECGFc 10 mg/kg 239.4 ± 24.3** 244.3 ± 24.5**
274.8 ± 8.0*** 
270.7 ± 12.3***
CECGFc 20 mg/kg  267.5 ± 12.7** 271.0 ± 12.3***
268.1 ± 8.0***
270.6 ± 8.2***
CECGFc 50 mg/kg  287.1 ± 7.7**
261.3 ± 15.2*** 
271.9 ± 9.6*** 
266.5 ± 12.0***

aSTZ  (55 mg/kg + 0.5ml of 5% Tween 80); bGlibenclamide CECGLb: (Chloroform extract of Calotropis gigantea leaves); CECGFc: (Chloroform extract of Calotropis gigantea flowers).  Values are expressed  in terms of the standard error of the mean (SEM) n=6 in each group *p <0.05,  **p <0.01 ***p <0.001,  when student t test (Unpaired)  compared to control.

Discussion

In order to establish a scientific basis for the utilization CECGL and CECGF extracts in the treatment of diabetes, it was decided to evaluate the hypoglycemic effect, the OGTT in normal and STZ- induced diabetic rats. Earlier reports reveal  that  STZ-induced diabetic animals may exhibit most of the diabetic complications mediated  through   oxidative   stress.32 Glibenclamide is   often used as an insulin stimulant in many studies, and also used as a standard anti-diabetic drug in STZ-induced moderate diabetes to compare the anti-diabetic properties of a variety of hypoglycemic compounds.32,33 The findings of our study show that CECGL and CECGF have potent anti-diabetic activity in rats. The preliminary qualitative  chemical tests  of  CECGL  and  CECGF  confirmed the presence of glycosides, alkaloids,  flavonoids  and tannins by methods,34 supporting the earlier studies on C. gigantea.10,29 The glycosides may be responsible for observed pharmacological activity.33

Overall, the results show that the CECGL and CECGF possess marked hypoglycemic activity that resulted in improvement of oral glucose tolerance and lowering of the serum glucose levels in STZ- induced diabetic rats. The obtained results provide support for the use of the plant in traditional medicine. On the basis of the above evidence, it may be possible that the presence of flavonol glycosides may be responsible for the observed anti-diabetic activity.10,28

Conclusion

As far as the mechanism of action is concerned, we may speculate that the anti-diabetic activity of the extract may increase the glucose uptake,33 or may be partly mediated through suppression of the gluconeogenic  enzymes, glucose-6-phosphatase.35 However,  the precise mechanism(s) and site(s) of activity and active constituent(s) of chloroform extracts of C. gigantea leaves and flowers in addition to their toxicological effects have to be determined before concrete recommendation for drug development can be made.

Acknowledgements

The authors declare that they have no conflict of interest to disclose. This research was carried out as a part of doctoral studies by Mr. Nanu Rathod and has received no specific grant from any funding agency in the public, commercial or not-for-profit sectors. The authors would like to thank the Principal at the HSK  College of Pharmacy, Bagalkot-Karnataka, India Dr. I. S. Muchandi, for providing  all necessary facilities in successfully completing  this study.

 
 
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