Background
Diabetes mellitus is a metabolic disorder characterized by loss of glucose homeostasis occurring due to defects in insulin secretion or insulin action resulting from impaired metabolism of glucose, lipids and other energy yielding fuels such as lipids and proteins [
1]. It is a major endocrine disorder affecting nearly 10 % population all over the world [
2]. Globally diabetes has shadowed the spread of modern lifestyle and it can be linked to an increase in overweight and sedentary population [
3]. Despite the great strides that have been made in the understanding and management of diabetes, the disease and its related complications are increasing at an alarming rate [
4].
Patients with diabetes have dyslipidemia and an increased risk of stroke, coronary heart disease, myocardial infarction and peripheral vascular disease [
5]. Hyperglycemia, the primary clinical manifestations of diabetes is thought to contribute to diabetic complications by altering vascular cellular metabolism, vascular matrix molecules and circulating lipoproteins [
6]. There are also multiple abnormalities of lipoprotein metabolism in very low density lipoprotein (VLDL), low density lipoprotein (LDL) and high density lipoprotein (HDL) in diabetes. It is now well established that hyperlipidemia represents a major risk factor for the premature development of atherosclerosis and its cardiovascular complications [
7]. The American Heart Association (AHA) has identified the primary risk factor associated with progression of atherosclerotic lesions as elevated levels of total cholesterol (TC) and triglycerides (TG) in serum [
8]. So, diabetes is a multifactorial diseases leading to several complications require a multiple therapeutic approach. Many investigations suggested that the medicinal plants and dietary supplements improves diabetic conditions by lowering lipid and glucose levels and are useful in the management of diabetic complications especially its associated cardiovascular risks [
9].
The most commercially available antidiabetic agents are expensive and possess undesirable side effects such as potential for induction of hypoglycemia, weight gain, gastrointestinal disturbances and liver toxicity [
10]. In recent years, complementary medicines are gaining popularity worldwide because of their natural origin and less side effects. Over the years, various medicinal plants have been reported to be effective in the management of diabetes mellitus [
11]. The hypoglycemic and hypolipidemic effects of some medicinal plants have been evaluated and confirmed in human [
12] and animal models [
13,
14] and however, many remained to be scientifically established.
Grewia asiatica L. (Tiliaceae) is an exotic bush plant, known for its edible ripe fruit which are consumed fresh [
15]. The plant is native to the Indian subcontinent and now widely cultivated on a commercial scale in India, Bangladesh, Pakistan, Philippines and other tropical countries [
16]. Traditionally, the plant
G. asiatica widely used for its antidiabetic, antioxidant, antipyretic, analgesic, antibacterial properties [
17]. The plant reported to contain glycoside, flavonoids, vitamins A and C, minerals and dietary fiber [
18‐
21]. Earlier studies have shown the free radical scavenging activity and radioprotective efficacy of
G. asiatica fruit extract in brain [
22], liver and blood [
23].
G. asiatica leaves has been shown to possess hypoglycemic activity in diabetic rats [
24]. Parveen et. al investigated the comparative anti-hyperglycemic effects of crude ethanolic extracts of the fruit, stem bark and leaves of
G. asiatica and their fractions in alloxan-induced hyperglycemic rabbits after acute treatment [
25]. So, we have evaluated the antidiabetic, hypolipidemic and antioxidant effects of ethanol extract of stem bark from
G. asiatica (GAE) in alloxan induced diabetic rats after 15 days of oral administration.
Methods
Drug and chemicals
The standard drug, Metformin HCl was the generous gift sample obtained from Square Pharmaceuticals Ltd., Pabna, Bangladesh. Alloxan monohydrate was purchased from Sigma-Aldrich Co. Germany. All other chemical and solvent used were of analytical grade.
Plant material
The fresh stem barks of the plant G. asiatica were collected from botanical garden of Rajshahi University, Rajshahi, during the month of June-July in 2011. The authenticity of the plant was confirmed and a voucher specimen collection # 29, dated 06/30/2011 was kept in the Herbarium, Department of Botany, University of Rajshahi, Bangladesh.
The collected stem barks were washed, chopped into small pieces and sun dried for several days. The dried stem bark grinded to coarse powder after drying in an oven at below 50 °C. The powdered plant materials were soaked with 3 L of rectified spirit (96 % ethanol) for 7–10 days with occasional shaking and stirring. The extracts thus obtained were successively filtered through cotton and filter paper (Whatman Filter Paper No. 1). The filtrate was defatted with petroleum ether for several times. The defatted liquor was concentrated using a rotary evaporator at 40–45 °C under reduced pressure and finally, the extract kept into a desiccator to obtain a solid mass (yield 30.0 g; 3.0 %).
Phytochemical screening tests
Detection of phytoconstituents has been performed by the standard methods [
26,
27].
Animals
Nine-weeks-old Norwegian Long Evans rats (150–180 g) purchased from ICDDRB, Dhaka, Bangladesh were housed in cages in an air controlled room under light and dark cycle conditions. Rats were allowed to access standard rodent chow and water ad libitum. Throughout the study the animals were cared in accordance with the guidelines of our institution. The experimental protocol was approved by Institutional Animal, Medical Ethics, Biosafety and Biosecurity Committee (IAMEBBC) at the Institute of Biological Sciences, University of Rajshahi, Bangladesh.
Acute toxicity study
The acute oral toxicity study was carried out according to OECD guidelines. After administration of a fixed dose of 2000 mg/kg of extract, animals were individually observed for any change in autonomic or behavioral response for first 2 h, periodically during first 24 h and daily thereafter, for a total of 14 days [
28].
Induction of experimental diabetes
After fasting 16 h, diabetes was induced into rats by a single intra-peritoneal (i.p.) injection of alloxan monohydrade (110 mg/kg body weight) following base-line glucose estimations. After 96 h blood glucose levels were measured by glucometer using blood sample obtained from tail-vein of rat. Rats with blood sugar level higher than 11.5 mmol/L were considered for the treatment protocol [
29].
Experimental protocol
Twenty diabetic rats were divided into four groups and each group comprised of five animals. The standard drugs and/or extracts were suspended in vehicle (0.5 % methyl cellulose, MC) and administered orally in rats by gastric tube for 15 days. Age-matched healthy rats were used as normal control.
1.
Normal Control (Group NC, 0.5 % MC, n = 5)
2.
Diabetic Control (Group DC, 0.5 % MC, n = 5)
3.
Diabetic + Standard Drug (Group DS, Metformin, 150 mg/kg, n = 5)
4.
Diabetic + Extract (Group GAE200, 200 mg/kg, n = 5)
5.
Diabetic + Extract (Group GAE400, 400 mg/kg, n = 5)
Oral glucose tolerance test (OGTT)
Blood glucose level of rats were measured after fasting over-night. After 1 h of feeding of extracts and/drugs rats received glucose solutions (2 g/kg). Blood samples from each rat were withdrawn from the tail-vein at 0 min, before and after 30, 60 and 120 min of glucose loading. Plasma glucose levels were estimated using glucose oxidase-peroxidase method [
30].
Time course of changes in blood glucose levels
The blood glucose levels of rats were measured on day 0, before initiation and on 5, 10 and 15 days during the course of treatment. Blood samples were drawn from the tail-vein of rats and blood glucose levels were measured [
30].
Measurements of body weights and organ weights
The body weights of rats were measured before the initiation and after 15 days of oral treatment. At the end of experiment, the rats were anesthetized, chest opened, blood samples were withdrawn directly from aorta and poured into blood collecting tube. The blood samples were centrifuged at 4000 rpm for 10 min and the plasma samples thus, obtained were freeze up at −40 °C until further use. Heart, liver and pancreases were removed and cleaned of the surrounding tissues. The organ weights were measured immediately and the organ weight to body weight ratios were calculated. Samples of pancreas were stored in 10 % formalin for histopathological examination.
Analysis of lipid profile
Plasma triglycerides (TG), total cholesterol (TC) and high density lipoprotein (HDL) concentrations were analyzed by spectrophotometer (Shimadzu 1200, Japan) using commercial kits (Human, Germany). The low density lipoprotein (LDL) and very low density lipoprotein (LDL) levels were determined by the formula, VLDL=TG/5, LDL=TC-(HDL+VLDL) [
31]. The ratios of LDL to HDL cholesterol were calculated.
Estimation of liver glycogen, SGOT and CK-MB levels
Estimation of CK-MB was done by immuno-inhibition method as described by the manufacturer protocol [
32]. The liver enzyme, serum glutamate oxaloacetate transaminase (SGOT) was determined using commercial kits (Human, Germany) [
33,
34]. The liver glycogen content was determined according to the method described by Tarnoky K. et al., [
35]. Briefly, it utilizes the o-toluidine-glucose coupling reaction for the estimation of glycogen after extraction with trichloroacetic acid (TCA) followed by precipitation with alcohol and hydrolysis.
Histopathological study
The histopathological studies of liver and pancreas were carried out at the Department of Pathology, Rajshahi Medical College, Rajshahi, Bangladesh. Briefly, for light microscopy liver and pancreas were fixed in PBS containing 10 % formalin. The tissues were washed in running tap water, dehydrated in the descending grades of isopropanol and finally cleared in xylene. The tissues were then embedded in molten paraffin wax. After embedding in paraffin, several transverse sections (5 μm) were cut from the mid organ level and stained with hematoxylin-eosin stain. The specimens were observed under light microscope at the 400-fold magnification.
In vitro antioxidant activity of GAE extract by DPPH free radical scavenging assay
The antioxidant property was assessed by DPPH (2, 2-diphenyl-1-picrylhydrazyl) radical scavenging method [
36]. The hydrogen donating or radical scavenging ability of the extract was measured using a stable radical DPPH. 2.8 ml of DPPH solution (45 μg/ml) were rapidly added in 200 μl of methanol solution of plant extracts at different concentrations in test tubes. The solutions were mixed well and then kept in dark for 30 min at room temperature. The absorbance was measured at 517 nm in spectrophotometer against methanol solution used as a blank. Ascorbic acid was used as standard and trolox in the same concentrations was used as the positive control corresponding to 100 % radical scavenging activity. All measurements were done in triplicate.
The percentage (%) of scavenging of the DPPH free radical was measured by using the following equation:
$$ \left\{\left({\mathrm{A}}_0-{\mathrm{A}}_1\right)/{\mathrm{A}}_0\right\}\times 100 $$
Where, A0 = absorbance of the control
A1 = absorbance of the extract/standard
Then, the percentage (%) of inhibition was plotted against log concentration and IC50 was calculated from the graph.
Determination of total phenolic content in GAE
Total phenol content in extract was determined by Folin-Ciocalteu reagent [
37]. Briefly, the extract (200 μg/ml) was mixed with 400 μl of the Folin-Ciocalteu reagent and 1.5 ml of 20 % sodium carbonate. The mixture was shaken thoroughly and made up to 10 ml with distilled water and after 2 h absorbance of the mixture was measured at 765 nm. The total phenol content in GAE extract was determined from standard curve of gallic acid and was expressed as mg of gallic acid equivalent per gm of dried plant extract.
Determination of total flavonoid content in GAE
The total flavonoid content was determined using a method previously described by Kumaran K [
38]. In brief, 1 ml of plant extract in ethanol (200 μg/ml) was mixed with 1 ml aluminium trichloride in ethanol (20 mg/ml), a drop of acetic acid was added and then diluted with ethanol up to 25 ml. After 45 mins absorbance was measured at 415 nm against blank. The total flavonoid content in GAE extract was determined from the standard quercetin curve and was expressed as mg of quercetin equivalent per gm of dried plant extract.
Statistical analysis
Data were expressed as means ± standard error of means (SEM). Statistical comparison was performed by one-way (ANOVA) followed by Dunnett’s Multiple Comparison Test. The values were considered as statistically significant when p <0.05. Statistical calculations and the graph were prepared using GraphPad Prism Software version 5.0 (GraphPad Software, San Diego, CA, USA).
Discussion
Diabetes is multifactorial disease that has a significant adverse impact on health and mortality particularly from cardiovascular diseases. Now, a day, herbal drugs are gaining popularity in the treatment of diabetes and its related complications. The present study was designed to assess the hypoglycemic, hypolipidemic and antioxidant activities of ethanolic extract
of G. asiatica stem barks in alloxan-induced diabetic rats for 15 days. Alloxan is a hydrophilic and chemically unstable pyrimidine derivative which can generate free radicals that are toxic to pancreatic β-cells causing rapid release of insulin initially and then sharp decline due to excess liberation of stored insulin and in this study, the diabetogenic effect of alloxan was in accord with previous studies [
39]. Beside insulin, the most widely used hypoglycemic agents are sulfonylureas and biguanides. However, we choose metformin- a biguanides as a standard drug which inhibit gluconeogenesis in the liver, increases affinity to insulin receptors and thus, improve insulin resistance [
40].
The present study indicated that 15 days of oral administration of GAE improved survival rate and significant reduction in blood glucose, lipids, SGOT, CKMB levels and restored liver glycogen in diabetic rats. After 15 days diabetic rats showed a significant improvement in glucose tolerance and the effects of GAE on blood sugar levels and biochemical alterations were dose-dependent. Remarkably, the rats treated with GAE showed mild to moderate improvement in cellular architecture as observed by the restoration of normal cellular population size of islets.
We demonstrated that GAE at the doses of 200 and 400 mg/kg reduced elevated blood sugar level in alloxan-induced diabetic rats. Our results were in accordance with outcomes of Parveen et al. showed antihyperglycemic activity of different parts of
G. asiatica in alloxan-induced rabbits [
25]. A number of medicinal plants have been reported to have an antihyperglycemic activity and a stimulatory effect on insulin release [
41,
42]. The significant decrease in the fasting blood glucose levels by GAE in alloxan diabetic rats may be due to the stimulation of the residual pancreatic mechanism and probably by increasing peripheral utilization of glucose or glycogen synthesis in liver and decreased gluconeogenesis [
43].
Induction of diabetes with alloxan is associated with characteristic loss of body and organ weight, which is due to increase muscle wasting [
44] and loss of tissue proteins [
45]. Diabetic rats treated with GAE showed an increase in body weight and organ weight which may be due to protective effect of GAE on tissue structural constituents [
46].
Hyperglycemia is accompanied with the increase in TC, TG, LDL and decrease in HDL which is attributable to excess mobilization of fat from the adipose due to under peripheral utilization of glucose [
47]. The data revealed that TC, TG, LDL, VLDL levels were significantly decreased and HDL level increased in diabetic rats treated with GAE. The Group GAE400 exhibited greater improvement in lipid profile among the treatment groups. Oral administration of GAE might have improved utilization of glucose and suppression of lipid mobilizations responsible for the regression of diabetic state. Further, the effects may be due to the low activity of cholesterol biosynthesis enzymes and/or low level of lipolysis which is under the control of insulin [
48]. It is evident that triglycerides are independent risks factors of coronary heart diseases [
49] and most of the lipid lowering drug does not decrease TG levels. However, GAE lowered TG levels significantly and this effect might be due to an increase in endothelium bound lipoprotein lipase which regulates the disposal of lipids fuels in the body [
50].
The SGOT and CK-MB are sensitive markers of organ damage [
51]. The levels of SGOT and CK-MB were abnormally increased alloxan induced diabetic rats. The increase in SGOT levels might be due to hepatotoxicity and however, the cause of high levels CK-MB remained to be explained. Oral ingestion of GAE significantly reduced SGOT and CK-MB levels among the treatment groups suggestive of improvement in liver function and morphology in diabetic rats (Table
5). In our study, induction of diabetes with alloxan was associated with a marked reduction in liver glycogen stores which could be attributed to a decrease in the availability of the active form of enzyme glycogen synthetase probably because of low level of insulin [
52]. Oral administration of GAE restored the liver glycogen content possibly due to an increase level of insulin, which was evident by the preservation of pancreatic morphology and regeneration of β-cells (Fig.
3d and
e).
Vinca rosea extracts and (−)-Epicatechin have been shown to induce β-cell regeneration in alloxan-induced diabetic rats [
53,
54]. In our studies, the damaged pancreatic β-cells were observed in diabetic rats (Fig.
3b). However, oral ingestion of GAE restored normal population size of islets by the regeneration of β-cells (Fig.
3d and e). The antioxidant activity of the plant extract might play a significant role in the early recovery of damaged pancreas in diabetic rats which in turn may be due to the presence of flavonoid and phenolic compounds in
G. asiatica stem bark.
Conclusion
We concluded that ethanol extract of G. asiatica stem barks has antidiabetic and lipid lowering efficacy in alloxan-induced diabetic rats. The plant extract exerts its beneficial effects by the reduction of blood sugar levels, lipid profiles, SGOT and restoration of liver glycogen and antioxidant potentials. GAE treated pancreas showed maintenance of normal architecture of pancreatic β-cells as evidenced in histological findings. Thus, the antihyperglycemic effects of GAE can be partially explained by their ability to restore the functions of pancreatic tissues. However, further histopathological and biochemical studies are needed to elucidate the exact mechanism of action of G. asiatica in diabetic rats.
Acknowledgements
The authors would like to express thanks, to Department of Pharmacy, University of Rajshahi Bangladesh for providing laboratory facilities; Dean, Faculty of Science, University of Rajshahi for research grants and International Centre for Diarrhoeal Disease Research, Bangladesh (ICDDRB) for supplying rats for the research purpose.