Research Article

In Effect of Poorna Chandrodayam Chendooram (metallic drug) on liver function, kidney function and lipid profile parameters of rats

Muthukumaran. P*, Pattabiraman. K, and Hazeena Begum

Published 12/11/2016 .
Email: kumaran.bio14@gmail.com

In Effect of Poorna Chandrodayam Chendooram   (metallic drug) on liver function, kidney function and lipid profile parameters of rats

 

Muthukumaran. P*, Pattabiraman. K, and Hazeena Begum

Department of Siddha Medicine, Faculty of Science, Tamil University, Vaakaiyur, Thanjavur - 613 010, Tamilnadu, India.

*Author to whom correspondence should be addressed/E-Mail: kumaran.bio14@gmail.com

Received: Oct 2016 / Accepted:  Oct2016/ Published: Dec 2016

ABSTRACT: Poorna chandrodayam chendooram (PCM), a Siddha preparation which is used for its effect on liver function, kidney function and lipid profile after administrations into the biological system. The experimental animal model was of Male rats. Triglycerides (TG) Total cholesterol (TC), and low density lipoprotein (LDL) were decreased in experimental groups whereas high density lipoprotein (HDL) were slightly increased in male rats. The total protein and albumin content of plasma were increased very high significantly. In case of bilirubin, the decrease was negligible for rats. The serum glutamic pyruvic transaminase (sGPT), serum glutamic oxaloacetic transaminase (sGOT) and alkaline phosphatase (ALP) content in the plasma were decreased very high significantly in the experimental groups. Creatinine, and urea were decreased in male where only change of uric acid level was significant increased.

Keywords: PCM, TG, TC, LDL, HDL, SGPT, SGPT and ALP

INTRODUCTION

Indian alchemy is one of the disciplines in which Parpam, Chendooram and Chunnam were first described as intriguing formulations of metals and minerals such as gold, silver, copper, iron, zinc, mercury, and so forth, apparently associated with organic macromolecules derived from the herbal juices by alchemic processes making these biologically assimilable. (Savrikar 2004). Minerals are combined with herbs that assist the assimilation and delivery of the ingredients to the human body (Suoboda 1998).These herbo mineral medicine are prepared by repeated incineration of metals or their salts (preferably oxides) with medicinal herbs or their extracts so as to eliminate their harmful effects and are taken along with honey, milk, butter, or ghee (a preparation from milk) (Patel., 1986). Most of the medicines are mixture of compounds and because of its synergistic action; toxicity is being diminished, thereby increasing bioavailability through the cells of the body. Treating the minerals with herbal juices may lead to reduction in particulate size even up to nano levels (less than 100 nm) enable increased potency.

Poorna chandrodayam chendooram is a well-known, mercurial preparation with gold and sulphur (Thiagarajan., 1992) widely used for many ailments like tuberculosis, jaundice, fever, rat bite, cancerous ulcer, sprue and male sterility. (Muthaliar, 1987) Hibiscus and Aloe juice is added for titration. (Mahdihassan 1985) These drugs are mostly a mixture of compounds and because of its synergistic action and purification process (Austin, 2002) toxicity is being diminished. (Hardy et al.,   1995), thereby increasing bioavailability through the cells of our body. (Sudha et al.,   2009) These drugs are known to be effective even in low concentration. (Kumar et al.,   2006)  The phytochemical studies of this drug Poorna chandrodayam chendooram has shown to contain flavonoids, phenols, and Vitamin C (Muthukumaran and Hazeena Begum., 2014), but a clear picture of its toxicokinetics is still obscure. The present study was aimed at evaluating the Liver, kidney and Lipid profile of Normal and PCC treated in experimental animal model.

 

MATERIALS AND METHODS

SELECTION OF ANIMAL

Healthy and pure strain Male Wistar rats, Rattus norvegicus, ranging from the body weight of 120-150 g were procured from the Venkateshwara Enterprises, Bangalore and maintained in the Central Animal House, Department of Siddha Medicine, Tamil University, and Thanjavur. Experimental protocol was approved by the Institutional Animal Ethics Committee (IAEC) of Tamil University, Thanjavur. The animals were maintained on standard diet (Kamadhenu Agencies, Bangalore) and water was given ad libitum.

 

DRUG PREPARATION

The (Poorna Chandrodayam Chendooram drug obtained from the SKM Siddha and Ayurvedic Medicine’s India Private Limited, Saminathapuram, mudakurichi, Erode- 638104. Tamilnadu, India. The drug (Poorna Chandrodayam Chendooram) is not soluble in water therefore a suspension of gum acacia is made for oral administration. The 10 gm. of gum acacia dissolved in 100 ml of distilled water by gradual trituration in a mortar. Then well prepared solution was taken and added Poorna chandrodayam chendooram at the dose of 3 mg/ml/100 gm.

 

EXPERIMENTAL DESIGN

After acclimatization, the rats were divided into 2 groups, each having 8 rats.

Group I: Untreated control were received water only.

Group II: Young rats were treated with Poorna chandrodaya chendooram4 (3.0 mg / kg body wt. calculated from human dose) with honey for 7 weeks (orally administered).

 

BLOOD SAMPLES COLLECTION AND PREPARATION OF PLASMA

Blood samples were collected from post vena cava and transferred into heparinised tubes immediately. Blood was then centrifuged at 4,000 g for 10 min using bench top centrifuge to remove red blood cells and recover plasma. Plasma samples were separated and were collected using dry Pasteur pipette and stored in the refrigerator for analyses. All analyses were completed within 24 h of sample collection.

 

 DETERMINATION OF BIOCHEMICAL PARAMETERS

To assess the state of the liver and kidney, biochemical studies involved analysis of parameters such as total protein, serum albumin, blood urea nitrogen (BUN), bilirubin, creatinine, and liver enzymes such as aspartate aminotransferase (AST), alanine aminotransferase (ALT) and alkaline phosphatase (ALP). For lipid profile study, trirglycerides (TG), total cholesterol (TC) and high density lipoprotein (HDL) were determined but low density lipoprotein (LDL) and very low density lipoprotein (VLDL) were calculated.

Biuret method (Plummer, 1971) was followed to determine the Total protein and serum Albumin concentration was determined by using the method of Doumas et al (1971). TG, TC and HDL concentration were evaluated according to Friedewald’s formula (Friedewald et al.,   1972) Serum bilirubin was determined according to the method of Evelyn and Malloy (1938). The procedure of Tietz et al (1994) was used to determine serum creatinine concentration while the serum urea concentration was determined by the method of Kaplan (1965), King and King (1954) method was employed to determine serum glutamic pyruvic transaminase (SGPT), serum glutamic oxaloacetic transaminase (SGOT) and alkaline phosphatase (ALP). The absorbance of all the tests were determined using spectrophotometer (UV-Visible Spectrophotometer Model No. UV-1601 PC.).

 

RESULT AND DISCUSSION

LIVER FUNCTION

Proteins are important organic substances required by an organism in the tissue building, the cellular organelles repair and also cellular metabolism (Yeragi et al.,   2000). Albumin constitutes a major antioxidant defense against oxidizing agents (Halliwell et al 1998). Bilirubin estimation is reliably sensitive in the diagnosis of hepatic disease (Harper., 1991), because bilirubin is a by-product of the breakdown of hemoglobin. The determination of the pathophysiological enzymes like SGOT and SGPT is a common mean of detecting the liver status. Alterations in SGOT and SGPT values are reported in hepatic disease or damage. SGOT, SGPT and bilirubin are the bio-markers for liver functions (Martin et al.,   1981; Ronald and koretz, 1992; Mazumder, 1999). Alkaline phosphatase is a membrane bound enzyme and its inactivation leads to membrane damage of hepatic cells (Flora et al.,   1994). Increased Alkaline phosphatase is responsible for intra-and extra-hepatic disease.

Table. 4. presents the effect of PCC on serum, serum protein, albumin bilirubin, SGPT, SGOT and ALP in control and experimental group of rats.  It shows the slightly increased level of serum total protein, albumin, and level of serum PCC treated rats. The increase level was 35.24% for total protein, 17% for albumin and 48 % for bilirubin.  But, the SGPT,SGOT and ALP levels were decreased .The decrease level was 25 % for SGPT,24 % for SGOT and 32% for ALP  in serum PCC treated rats when compared to normal rats

These proteins are important liver function marker. According to Naganna (1989), increase in bilirubin is indicating the abnormal liver function which may be the results of higher synthetic function of the liver. Statistically no important data of bilirubin, another liver function indicator. This is indicating the normal liver function which is contradictory with the total protein and albumin observation. SGPT, SGOT and ALP content in the plasma, of rats were decreased very high significantly. Alkaline phosphatase is the marker enzyme for plasma and endoplasmic reticulum (Wright and Plummer, 1974; Shahjahan et al.,   2004) and its decrease indicates the improved synthetic activity of liver, from the toxicological report of the serum parameters proved the safety of the drug. The toxicity of gold, mercury and sulphur was completely removed and the potency of the metals was only enhanced during the preparation on the drug. The detoxifying property is also attributed by the Alovevera brobadensis and Hibiscus extracts added during the preparation of the drug,

KIDNEY FUNCTION

Kidneys are the chief organs for the excretion of wastes. Besides their excretory function, kidney function in a significant manner in the maintenance of internal environment of the body. The damaged kidneys cause an elevated Urea because the kidneys are less able to clear urea from the blood stream. Urea measures the amount of urea nitrogen, a waste product of protein metabolism in the blood.  It is also useful to detect the function of kidney tissue. Urea is typically measured to assess kidney function (Mitchell et al.,   1972). Creatinine is also used to measure the filtration rate of the kidney. It is the indicators for the function of kidney (Gyton, 1991). Uric acid is a major contributor to total radical trapping capacity (TRAP) (Kharb and   Singh 2004)

Table 2.  represents the effect of PCM on kidney Creatinine, Urea and Uric acid levels in control and Drug treated rats. Creatinine and Urea levels were significantly decreased PCC treatment the decrease levels were 21% for creatinine and 27% for urea   when compared to control rats. But the Uric acid levels was significantly increased 12% in PCM treatment.

Creatinine and urea content, major kidney function parameter, in the male plasma was decreased significantly but the content of uric acid were slightly changed in significant manner. This reduced creatinine and urea level might have results from the decreased synthesis or increased functional capacity of tubular excretion (Mitchell et al.,   1972; Zilva et al.,   1991)

There are significant changes in serum urea, creatinine and uric acid .Yet these values were proving the safety of the drug. There is an increase in uric acid levels which aids to the safety of the drug. Renal function test credits the safety of the drug. PCC did not accumulate in renal tissues which could be evidently seen by the urea creatinine and uric acid in serum.

 

LIPID PROFILE

Atherogenicity with subsequent cardiovascular manifestations is one of the major causes of death and morbidity in the world (Raju and Binda, 2005). The important lipids whose elevations are implicated in these disease conditions are cholesterol and triacylglycerols. Lipids are transported as lipid-protein complexes called lipoprotiens, which are classified based on their density and charges. The High-density Lipoprotein cholesterol (HDL) transports lipids out of blood cells to the liver, while the Low Density Lipoproteins cholesterol (LDL) mobilizes lipids against the cells and blood vessels. Triacylglycerols have been found to be elevated along with total cholesterol elevation. Therefore, elevated low-density cholesterol, triacylglycerols and total cholesterol with reduced HDL will enhance the development of atherosclerosis and related cerebrovascular disorders (Nwanjo, 2004).  Figure.1. represents the level of lipid profile in PCM treated rats & Normal control rats. The value of TG, TC and LDL were significantly decreased. The decrease levels were 32.23 % for Triglycerides, 27.58 % for Cholesterol and 19.29 % for Low density lipoprotein in PCC treatment than normal control.  But the HDL level was significantly increased. The increase level was 44 % in PCM treatment than normal control rat’s serum.

The plants constituents (Lee et al.,   2000) reduced TG level and it could be suggested that PCM increased lipase activity which hydrolyzed TG. Among the lipids, increased blood level of TC and LDL as well as lowered level of HDL has been identified as contributors in the development of hyperlipidemia (Ross, 1999) which is the consequences of, in majority of the cases, diabetes mellitus (Pushparaj et al., 2000; Pepato et al.,   2003; Sharma et al.,   1983). The elevation of lipid components is a risk factor for coronary heart disease (Mironova et al., 2000). PCM may act as inhibitor for enzyme such as hydroxyl-methyl-glutaryl-CoA reductase, which is the key enzyme in de novo cholesterol biosynthesis as has been suggested for some plants earlier (Gebhardt and Beck, 1996; Eidi et al., 2006). This reduction could be beneficial in improving lipid metabolism and complications in diabetes (Cho et al., 2002) Abnormalities in serum lipids are associated with diabetes (Virella-Lopes and Virella, 2003; NCEP, 2002).

 

Table 1: Effect of oral administration of PCM (3 mg/ kg body weight) on various parameters of liver Functions of rats’ plasma

 

Parameters

Control

PCM Treated

Total protein

7.27±0.45

8.25±0.56**

Albumin

4.25±0.39

5.29±0.45**

Bilirubin

0.13 ± 0.01

0.02 ±0.01***

SGPT

60.27 ± 0.13

55.54 ± 0.12***

SGOT

101.73 ± 0.31

93.75 ± 0.24***

ALP

43.56 ± 0.11

40.12 ± 0.08***

In the tables the statistical data are shown as: * = p<0.05 = Significant, ** = p<0.01 = High Significant, *** = p<0.001 = Very High Significant

Table 2: Effect of administration of Poorna chandrodayam chendooram (3mg/ kg body weight) on various parameters of kidney functions of rats’ plasma

 

Parameters

Control

 

Creatinine

0.95±0.12

0.75 ± 0.02*

Urea

65.86 ± 1.04

47.35 ± 0.20*

Uric acid

2.58 ± 0.06

2.90 ± 0.08*

Values are expressed as mean ±S.D. for six rats. Camparisons were made between group I with II      P<0.05 = Significant

 

 

CONCLUSION

Interestingly, it is seen that PCC has steady decreased levels of urea, creatinine, SGOT, SGPT, ALP levels which reveal that fact that this drug may also be useful treatment of hepatic disorders and renal diseases. The myth that heavy metal cause toxicity is broken out in this study when the drug is properly prepared and given safe dosage during the duration of treatment. It is confirmed that Metal base drug PCC is a safe and effective drug .It is evident that the trial drug eliminate the toxic substances from the body and enhances the longevity of life.

 

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How to cite this article
Muthukumaran, P., Pattabiraman, K., & Hazeena, B. (2016). Effect of Poorna Chandrodayam Chendooram (metallic drug) on liver function, kidney
function and lipid profile parameters of rats. International Journal of Agricultural and Life Sciences, 2(4), 67-72. doi: 10.22573/spg.ijals.016.s12200068.
 

CONFLICTS OF INTEREST

“The authors declare no conflict of interest”.

                 

© 2016 by the authors; licensee SKY FOX Publishing Group, Tamilnadu, India. This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution license (http://creativecommons.org/licenses/by/3.0/).