J Islamabad Med Dental Coll 2019 34 Open Access Comparison of Caralluma tuberculata with Metformin for Anti- Diabetic Activity: An Animal Study Muhammad Saleh Faisal 1, Waqar Hayat 2, Asad Inayat 3, Muhammad Sohaib 4, Waheed Iqbal 5 1 Assistant Professor, Department of Pharmacology - Khyber Medical College, Peshawar 2 Trainee Medical Officer, Department of Medicine - Khyber Teaching Hospital, Peshawar 3 Trainee Medical Officer, Department of Medicine - Khyber Teaching Hospital, Peshawar 4 Research Assistant, Khyber Medical University, Peshawar 5 Chemist, Department of Pharmacology, Khyber Medical College, Peshawar A B S T R A C T Background: Caralluma tuberculata, is a wild herb, which grows in the hills of Balochistan and has been known to have medicinal and nutritional properties since antiquity. This experimental research was designed to study the hypoglycemic properties of Caralluma tuberculata and to compare them with Metformin. Material and Methods: This was a laboratory-based animal experimental study. It was conducted in the Pharmacology laboratory of Khyber Medical University, Peshawar from February 2016 to August 2016. Two types of extracts of Caralluma tuberculata [crude extract and carbon tetrachloride (CCl4) extract] were prepared and administered to normal and alloxan treated diabetic rabbits. To study anti-diabetic activity, eighty-four rabbits were divided into two main groups. Group I (Normal/Non-Diabetic Rabbits; n= 21) and Group II (Diabetic/Alloxanized Rabbits; n=63). Each group was further divided into sub-groups (7 rabbits in each). Effect of Caralluma tuberculata, Metformin and 2% gum tragacanth on blood glucose levels were checked at 0, 2, 4, 6, 8, 12 and 24 hours of drug administration. The extracts were given in capsule form and in cooking oil. Data analysis was done using SPSS version 16. For calculation and comparison of the hypoglycemic effects at various doses and different time intervals, analysis of variance (ANOVA) and Tukey’s post hoc test were applied. Results: The crude extract, 200mg/kg body weight of Caralluma tuberculata showed significant decrease (p<0.001) in mean blood glucose levels from 2-hour till12 hours. Whereas, highly significant reduction of blood glucose was seen from 2 hours after treatment till 24 hours, when carbon tetrachloride (CCl4) fraction of Caralluma (100mg/kg body weight) in capsule form was administered. Metformin 500mg/kg body weight was given to compare its effects with plant crude extract and it was found that metformin appeared to be less effective in comparison with Caralluma tuberculata. Conclusion: Caralluma tuberculata lowered the blood glucose level and turned out to be more significant in developing hypoglycemia when taken with cooking oil. More work is essential to provide stronger evidence for the use of this natural agent in the management of Diabetes Mellites. Key words: Anti-diabetic, Caralluma tuberculata, Hypoglycaemic Authors’ Contribution: 1,2 Conception, synthesis, planning of research and manuscript writing 3-5 Interpretation, discussion, Data analysis, Active participation in data collection. Correspondence: Waheed Iqbal Email: waheediqbal22@gmail.com Article info: Received: July 22, 2018 Accepted: November 10, 2018 Cite this article: Faisal MS, Hayat W, Inayat A, Sohaib M, Iqbal W. Comparison of Caralluma Tuberculata with Metformin for anti-diabetic activity: An animal study. J Islamabad Med Dental Coll.2019; 8(1):34-39 Funding Source: Nil Conflict of Interest: Nil I n t r o d u c t i o n Diabetes mellitus is one of the most common metabolic disorders which occur either due to insufficient insulin release (Type 1 diabetes) or tissue resistance to insulin (Type 2 diabetes). There were around 382 million diabetic patients in the year 2013, and it is estimated that this figure is going to flare up to 592 million by 2035. Most of O R I G I N A L A R T I C L E J Islamabad Med Dental Coll 2019 35 the diabetic patients reside in lower to middle developed countries.1 Prevalence of diabetes in rural areas of Pakistan constitutes 7% and 2.5% for men and women respectively, while in urban areas this figure is about 6% for men and 3% for women. According to another study, the glucose intolerance in urban areas is 14.2% for women and 6.3% for men versus 10.9% for women and 6.9% for men in rural areas.2 There are many plants which have been reported due to their traditional use as anti-diabetic agents, like momordica charantia, citrullus colocynthis, allium sativum, opuntia, aloe and artemisia.3,4 In many Indian traditional approaches like Ayurveda, about 800 different medicinal plants have been identified to have hypoglycemic activity, but very few of them got scientific scrutiny.5 Valuable information is available about phytochemical components responsible for hypoglycemic effect. The isolation of glycans from plant families such as, granmineae, ranunculaceae and extraction of glycosides from scrophulariaceae, rhamnaceae, caesalpiniaceae and papaveraceae are good examples of this. Moreover, some triterpenes from ranunculaceae, saponins of malvaceae and alkaloids of apocyanaceae have been reported for their hypoglycemic effect.6,7 However, the search for newer plants with anti-diabetic activity is still in progress. Caralluma tuberculata, which belongs to family Asclepiadaceae is a wild herb, grows in most of the hilly areas of Balochistan and is used as a vegetable since centuries. Caralluma species have been used by humans as tonic, carminative, anti-helminthic and anti-tumor agent.8 Caralluma is reported to be effective in rheumatism and also known to have hypotensive effect.9,10 The phytochemical constituents include volatile alkaloids, cardiac glycosides, flavonoids, saponins, sterols and tannins.11 Adnanet al reported that Caralluma when hydrolyzed under mild conditions gives cymarose, sarmentose, oleandrose or digitoxose as sugar component while work of Bashir et al identified its various nutritional aspects and composition.12, 13 This study was an attempt first to evaluate the hypoglycemic activity of crude and carbon tetrachloride (CCl4) extracts of Caralluma tuberculata and then to compare this hypoglycemic activity with metformin. M a t e r i a l a n d M e t h o d s This experimental study was carried out at the Department of Pharmacology, Khyber Medical University, Peshawar from February 2016 to August 2016. Institutional approval was obtained and all the ethical issues pertaining to animal pain and distress, feeding, caging etc. were addressed according to standard protocols for animal studies. Healthy male rabbits weighing 1 kg to 1.5 kg of Oryctologus cunniculus species were selected and kept in animal house for one week under strict observation where they were fed upon clean water and fresh fodder. To induce diabetes in normal rabbits, Alloxan monohydrate was injected in a dose of 150 mg/kg body weight using tuberculin syringe. A week later, blood levels of glucose were determined by glucose oxidase method and only those rabbits were included in the study whose blood glucose level was in the range 300-500mg/100ml.14,15 To study anti-diabetic activity, eighty-four rabbits were divided into two main groups. Group I (Normal/Non-Diabetic Rabbits; n= 21) and Group II (Diabetic/Alloxanized Rabbits; n=63). Each group was further divided into sub-groups (7 rabbits in each, as the minimum number in each group is 6 in already established protocols).15 Group 1 (n=21) was further subdivided into following 3 subgroups: Subgroup A1: Treated with crude extract of Caralluma tuberculata 200 mg/kg body weight. Subgroup B1: Treated with Metformin 500 mg/kg body weight. Subgroup C1: Serving as control receiving 20 ml 2% gum tragacanth solution. Group II (n=63) was further divided into following 9 sub- groups: Subgroup A2: Treated with crude extract of Caralluma tuberculata 200 mg/kg body weight (capsule form). Subgroup B2: Treated with Metformin 500 mg/kg body weight. Subgroup C2: Serving as control receiving 20 ml 2% gum tragacanth solution. Subgroup A3: Treated with CCl4 of Caralluma tuberculata 100 mg/kg body weight (capsule form). Subgroup B3: Treated with Metformin 500 mg/kg body weight. J Islamabad Med Dental Coll 2019 36 Subgroup C3: Serving as control receiving 20 ml 2% gum tragacanth solution. Subgroup A4: Treated with CCl4 of Caralluma tuberculata 100 mg/kg body weight (in cooking oil). Subgroup B4: Treated with Metformin 500 mg/kg body weight. Subgroup C4: Serving as control receiving 20 ml soy bean cooking oil. The aerial part of the plant was washed and air dried. The dried material was grinded, passed through a mesh and put in distilled water at room temperature for several days, followed by squeezing in a muslin cloth. This procedure was repeated thrice, which as a result produced green syrupy residue. Fractionation of crude extract of Caralluma tuberculata was carried out by suspending the crude extract in water, partitioned with carbon tetrachloride (CCl4) by vigorous shaking in a separating funnel. The CCl4 layer was separated and evaporated under reduced pressure in rotary evaporator. The resultant residue was then treated with methanol. The methanol soluble fraction was separated from the insoluble (water soluble) material and evaporated in rotary evaporator. Effect of Caralluma tuberculata, Metformin and 2% gum tragacanth on blood glucose levels were checked at 0, 2, 4, 6, 8, 12 and 24 hours of drug administration. Data analysis was done using SPSS version 16 and expressed as Mean ± SD. For calculation and comparison of the hypoglycemic effects at various doses & different time intervals, analysis of variance (ANOVA) and Tukey’s post hoc test were applied. R e s u l t s In non-diabetic group, treatment with crude extract of Caralluma produced significant reduction in mean blood glucose levels at 2 hours (p<0.001), 4 hours (p<0.001) 8 hours (p<0.001) and 12 hours, but gradual increase in blood glucose levels was seen at 24 hours as compared to that at 12 hours interval (p<0.001). However, with metformin, the blood glucose levels decreased after 2 and 4-hours interval but they started increasing from 8 to 24 hours interval after treatment. This increase was significantly high as compared to that at 12 hours interval (p<0.01). Oral administration of 20 ml 2% gum tragacanth suspension did not produce any appreciable decrease in blood glucose level (Table I). When capsule form of Caralluma crude extract was given, significant reduction in blood glucose levels were observed at 2, 4, 8, 12- and 24-hours interval (p<0.001) as compared to that at zero hour (p>0.1) (Table II). Compared to 2 hours interval, there was no significant decrease in blood glucose levels at 4 hours interval (p=0.2) and 8 hours interval (p=0.2). There was significant decrease in blood glucose levels at 12 hours interval compared to that at 8 hours interval (p<0.05) and highly significant increase at 24 hours interval compared to that at 12 hours interval (p<0.001). Table I: Blood glucose levels after oral administration of crude extract of Caralluma tuberculata, Metformin and 2% Gum tragacanth in non-diabetic rabbits (n=21) Time interval Crude extract 200mg/kg body weight 500 mg/kg body weight 20 ml (Hours) Caralluma tuberculate A1; (n=07) Metformin B1; (n=07) 2% Gum tragacanth C1; (n=07) Blood glucose (mg/dl) mean±SD Blood glucose (mg/dl) mean±SD Blood glucose (mg/dl) mean±SD 0 104.33  1.33 92.16±0.83 94.17±0.60 2 79.67 ± 2.96 82.00±0.96 94.00±0.58 4 73.17 ± 2.64 72.50±1.31 94.33±0.81 8 80.33 ± 2.23 79.66±1.76 93.50±0.67 12 72.50 ± 0.88 87.16±0.75 91.67±0.50 24 99.50 ± 1.61 92.00±0.57 92.50±1.05 Table II: Blood glucose levels after oral administration of crude extract of Caralluma tuberculata (capsule form), Metformin and 2% Gum tragacanth in diabetic rabbits (n=21) Time interval Crude extract 200mg/kg body weight (Capsule form) 500 mg/kg body weight 20 ml (Hours) Caralluma tuberculate A2;(n=07) Metformin B2;(n=07) 2% Gum tragacanth C2;(n=07) Blood glucose (mg/dl) mean±SD Blood glucose (mg/dl) mean±SD Blood glucose (mg/dl) mean±SD 0 318.16 ± 2.05 335.16 ± 3.04 309.00 ± 1.62 2 268.00 ± 2.61 318.50 ± 2.96 309.66 ± 1.78 4 263.00 ± 1.24 306.50 ± 1.65 309.00 ± 0.89 8 269.33 ± 1.97 322.66 ± 3.08 309.16 ± 3.25 12 260.33 ± 1.50 327.00 ± 2.50 312.00 ± 2.85 24 287.83 ± 3.52 340.80 ± 3.63 310.33 ± 2.50 J Islamabad Med Dental Coll 2019 37 In comparison with metformin, capsule form of Caralluma crude extract showed significantly low mean blood glucose levels at 2 hours interval (p<0.001), 4 hours interval (p<0.001), 8 hours interval (p<0.001), 12 hours interval (p<0.001) and 24 hours interval (p<0.001). Oral administration of 2% gum tragacanth did not produce any appreciable decrease in blood glucose levels. After oral administration of CCl4 fraction of Caralluma in capsule, blood glucose levels dropped markedly at 2 hours interval as compared to zero hour (p<0.001). But increase in mean blood glucose levels was observed at 8, 12 and 24 hours. In comparison with metformin and 2% gum tragacanth, CCl4 fraction of Caralluma significantly lowered the blood glucose levels at 2 hours interval (p<0.001); 4 hours interval (p<0.001); 8 hours intervals (p<0.001); 12 hours intervals (p<0.001) and 24 hours intervals (p<0.001) (Table III). Table IV shows that CCl4 fraction of Caralluma in soy bean cooking oil caused significant reduction in blood glucose levels at 2, 4, 8, 12- and 24-hours intervals (p<0.001). There was significant difference in blood glucose levels in all groups at 4 hours interval compared to that at 2 hours interval (p<0.05). No significant increase in comparison at 4 hours vs. 8 hours (p=0.2); 8 hours vs 12 hours (p=0.2) and 12 hours vs 24 hours (p=0.2) was observed in groups A4, B4 and C4. After treatment with 20 ml cooking oil, no appreciable difference in mean blood glucose levels was observed. This experiment was maintained as control against treatment groups. Table III: Blood glucose levels after oral administration of CCl4 fractions of Caralluma tuberculata (capsule form), Metformin and 2% Gum tragacanth in diabetic rabbits (n=21) Time interval CCl4 fraction 100mg/kg body weight (capsule form) 500 mg/kg body weight 20 ml (Hours) Caralluma tuberculate A3; (n=07) Metformin B3; (n=07) 2% Gum tragacanth C3; (n=07) Blood glucose (mg/dl) mean±SD Blood glucose (mg/dl) mean±SD Blood glucose (mg/dl) mean±SD 0 309.50±1.38 335.16±3.04 309.00±1.62 2 194.16±2.49 318.50±2.96 309.66±1.78 4 184.16±3.73 306.50±1.65 309.00±0.89 8 207.67±3.68 322.66±3.08 309.16 ± 3.25 12 206.67±2.59 327.00±2.50 312.00 ± 2.85 24 257.33±3.66 340.80±3.63 310.33 ± 2.50 Table IV: Blood Glucose levels after oral administration of CCl4 fractions of Caralluma tuberculata (in cooking oil), Metformin and 20ml Soybean cooking oil as control in diabetic rabbits (n=21) Time interval CCl4 fraction 100mg/kg body weight (In cooking oil) 500 mg/kg body weight 20 ml (Hours) Caralluma tuberculate A4; (n=07) Metformin B4; (n=07) Soy Bean cooking oil C4; (n=07) Blood glucose (mg/dl) mean±SD Blood glucose (mg/dl) mean±SD Blood glucose (mg/dl) mean±SD 0 287.55±1.96 335.16±3.04 301.00±2.08 2 142.33±1.74 318.50±2.96 301.00±2.35 4 151.33±2.26 306.50±1.65 302.66±3.48 8 153.16±3.13 322.66±3.08 301.16±1.58 12 158.00±2.80 327.00±2.50 303.16±2.24 24 164.66±3.23 340.80±3.63 303.16±2.24 It is worth mentioning here that from data given in Table III and IV, it is also observed that Caralluma tuberculata reduced blood glucose levels more efficiently when administered in cooking oil than in capsule form i.e. at 2, 4, 8, 12- and 24-hours interval (p<0.001). D i s c u s s i o n In the present study, experimentation was done on different forms of Caralluma tuberculata i.e. crude extract and carbon tetrachloride fractions (CCl4) in both capsule and in cooking oil to find out the form in which it is more effective as hypoglycaemic agent. When crude extract of Carallumain in a dose of 200mg/kg body weight was administered in capsule form to diabetic rabbits, it caused highly significant reduction in blood glucose level after 2 hours of treatment, which continued up to 12 hours. Whereas, when carbon tetrachloride (CCl4) fraction of Caralluma (100mg/kg body weight) in capsule form was administered, highly significant reduction in blood glucose level was seen from 2 hours after treatment till 24 hours. Carbon tetrachloride (CCl4) fraction of Caralluma (100mg/kg body weight) in cooking oil was also administered to diabetic rabbits. Beside significant reduction (p<0.001) in blood glucose levels, it was found that Caralluma tuberculata administered in cooking oil reduced blood glucose levels more than that administered in capsule form. J Islamabad Med Dental Coll 2019 38 Unlike other studies, we used carbon tetrachloride fraction in capsule and cooking oil forms to compare their efficacy. The reported information regarding effects of medicinal plants in developing hypoglycaemia was observed at maximum 6 hours after administration of dose. In our study, strategy was adopted to evaluate effect after two hours of administration of dose and again after 4, 8, 12 and 24 hours. It was aimed to see how long the dose effect of Caralluma sustains on blood glucose level. As far as the underlying mechanism for hypoglycaemia is concerned, it is deduced from various studies that this plant might contain multiple hypoglycaemic constituents, causing the release of insulin by stimulating beta cells and hence resulting in significant drop in blood glucose levels. Moreover, they may also have insulin like orally active substance, as Momordica charantia vegetable. 16 In addition, drugs such as biguanides are known to produce hypoglycaemia by decreasing gluconeogenesis and promoting glycolysis.17 Biguanides prevent hypoglycaemia in normal individuals by balancing the increased peripheral glucose utilization and additional glucose output of hepatocytes. So, it is suggested that Caralluma may contain specific constituents, which cause hypoglycaemia either by increasing the insulin secretion or mimicking insulin action.18 Different substances, like anterior and posterior pituitary hormones, prostaglandins, corticosteroids etc and plants like Trigonella foenum produces hypoglycaemia by different means and mechanisms.19 Therefore, establishment of detailed phytochemical and pharmacological profile of this plant is necessary to identify the exact underlying mechanism of hypoglycaemia. C o n c l u s i o n Caralluma tuberculata lowered the blood glucose levels in mammalian model of rabbits and turned out to be more effective when taken with cooking oil. However, the efficacy of herbal medications needs to be further evaluated by well designed, controlled clinical studies. R e c o m m e n d a t i o n s 1. 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