Methods: Thirty-six Sprague-Dawley rats, weighing between 220 and 280 g, were included in this study and were randomly assigned to three groups with 12 rats in each group. While rats in the control group (Group 1) were fed standard rat chow diet, those in group 2 (High cholesterol diet group) and group 3 (100 mg/kg/day diosmin-hesperidin group) were fed high-cholesterol diet for three months. After the study period, the levels of total cholesterol, low-density lipoprotein (LDL) cholesterol, highdensity lipoprotein (HDL) cholesterol and triglycerides were measured in serum. Malondialdehyde (MDA), glutathione peroxidase (GPX), superoxide dismutase (SOD) and catalase levels were measured in serum and heart tissue samples.
Results: The levels of total cholesterol, LDL-cholesterol and triglyceride were not significantly different between the groups. High-density lipoprotein cholesterol level was found to be significantly higher in group 3 than that in groups 1 and 2. Malondialdehyde levels were not significantly different between the groups. Glutathione peroxidase and SOD levels were found to be significantly higher in group 3 than those in groups 1 and 2. There were no significant differences between the groups with respect to catalase levels. Intracardiac measurements of MDA, GPX, SOD and catalase were not found significantly different between the groups.
Conclusion: Diosmin-hesperidin administration to high-cholesterol diet-fed rats significantly increased HDL-cholesterol levels but did not significantly affect other lipid parameters. Positive changes occurred in oxidative-antioxidative balance and administration of diosmin-hesperidin significantly increased the levels of GPX and SOD.
Flavonoids are a group of natural compounds found in plants commonly consumed by human beings. These phenolic compounds, especially found in fruits and vegetables, have many biological and pharmacological activities like enzyme inhibition, free radical scavenging, anti-inflammatory and anti-estrogenic activity and tumor promotion inhibition.[1-6] It has been reported in epidemiological studies that longterm dietary intake of flavonoids reduce the incidence of coronary heart disease and mortality due to this disease.[7-9] Some biological activities of flavonoids, like anti-thrombotic, anti-inflammatory, anti-oxidative and vasorelaxant effects may contribute to the prevention of coronary heart disease.[2] Furthermore, flavonoids are known to have a high content of vitamins and minerals. In spite of this, many investigators have related their cardioprotective effects mainly to their antioxidative and vasodilatator properties.[3,10-12] On the other hand, it has been suggested that flavonoids have an antiatherosclerotic activity through the inhibition of distinct stages in the pathogenesis of atheromatous plaque formation.[3]
Purified micronized flavonoid fraction contains 90% diosmin and 10% hesperidin. It is a potent venotropic drug that has been used in the treatment of chronic venous diseases for a long time. It increases venous tone, improves lymph drainage, reduces mast cells, suppresses leukocyte activation, inhibits prostaglandin secretion, reduces inflammatory response, inhibits free oxygen radical synthesis and acts as a scavenger of these free radicals; so it improves capillary permeability and capillary resistance which are increased by free oxygen radicals.[13,14] Furthermore, it has been noted in various experimental studies that this potent agent prevents distant organ injury in ischemia reperfusion condition, reduces oxidative damage due to hyperglycemia and inhibits intraperitoneal adhesion formation.[14,15]
In this study, we aimed to investigate the effects of diosmin-hesperidin combination treatment on the lipid profile and oxidative-antioxidative system in rats fed high cholesterol diet for three months.
At the end of the experimental period, the animals were anesthetized with ketamine (10 mg/kg) and xylazine (3 mg/kg). Blood samples were taken from the heart for the determination of plasma lipid profiles and oxidative status. Blood samples were centrifuged at 4000 rpm for 10 minutes. In addition, the hearts were removed and rinsed with physiological saline for the determination of oxidative status. All samples were stored at –70 ºC until the day of analysis.
Table 1: Normal and high-cholesterol diet composition
Determination of plasma lipids
Plasma cholesterol levels were determined using a
commercial kit (Dade Behring Co., Germany). Total
cholesterol, high-density lipoprotein (HDL) cholesterol
and triglyceride tests were measured using a Behring
RXL autoanalyser (Dade Behring Co., Germany). Very-low-density lipoprotein (VLDL) was calculated
using the ratio of triglyceride/5 and low-density lipoprotein
(LDL) cholesterol was calculated with Friedewald
formula. All parameters were calculated according to
their standard curves.
Determination of oxidative status in plasma
Malondialdehyde assay: M alondialdehyde l evels w ere
measured by a spectrophotometer. The reaction mixture
contained 0.1 ml sample, 0.2 ml of 8.1% sodium dodecyl
sulfate, 1.5 ml of 20% acetic acid, and 1.5 ml of 0.8%
aqueous solution of thiobarbituric acid. The pH of the
mixture was adjusted to 3.5 and the volume was finally
made up to 4.0 ml with distilled water, and 5.0 ml of the
mixture of n-butanol and pyridine (15:1, v/v) was added.
The mixture was shaken vigorously. After centrifugation
at 4000 rpm for 10 minutes, the absorbance of the
organic layer was measured at 532 nm wavelength.
Glutathione peroxidase assay: Blood samples were diluted to 1/20 with distilled water. Ten milliliter diluted blood samples were taken and added to reaction mixture (100 ml tris- EDTA, 20 ml glutathione, 100 ml glutathione reductase, 100 ml NADPH and 660 ml distilled water). Samples were incubated at 37 °C in water bath for 10 minutes. Then 10 ml t-buthyl-hydroperoxide was added, and the measure was performed in the spectrophotometer at 340 nm wavelengths.
Superoxide dismutase activity assay: Superoxide dismutase was determined as described by Fridovich[16] This method employs xanthine and xanthine oxidase to generate superoxide radicals, which react with 2-(4-iodophenyl)-3-(4-nitro phenol-s-phenyl tetrazolium chloride) to form a red formazan dye. Superoxide dismutase is measured at 505 nm via spectrophotometric by the degree of inhibition of this reaction. Assay medium contains 0.01 molar phosphate buffer and CAPS [3-(cyclohexylamino)-1-propanesulfonic acid] buffer. Xanthine 0,05 mm, 0.025 mm INT [2-(4-iodophenyl)- 3-(4-nitrophenol)-5-phenyltetrazolium cloride] and xanthine oxidase (80 U/L) were used as substrates. All samples were calculated according to a standard curve and SOD activity was expressed as U/mg creatinine.
Catalase activity assay: Catalase activities were determined by measuring the decrease in hydrogen peroxide concentration at 230 nm. Assay medium consisted of 1M Tris-HCl; 5 mm Na2EDTA buffer solution (pH 8.0), 1M phosphate buffer solution (pH 7.0), and 10 mm H2O2. Catalase activity was expressed as U/mg creatinine.
Determination of oxidative status in heart tissue
Tissue samples were homogenized with 10 volumes of
ice-cold 0.25 M sucrose and centrifuged at 14,000 g to measure the levels of MDA, activities of SOD, GPX and
catalase.
Glutathione peroxidase activity in tissue homogenate supernatants was measured according to the Beutler method.[17] The method was based on an nicotinamide adenine dinucleotide phosphate-oxidase (NADPH)- coupled reaction, whereby oxidized glutathione (GSSG) produced by GSH-Px (GPX) and hydroxyperoxide were reduced by exogenous glutathione reductase and NADPH. Enzyme activity was measured at 340 nm and expressed in units, each representing the oxidation of 1 μmol NADPH per minute per ml supernatant.
Malondialdehyde method was based on measurement of the absorbance of thiobarbituric acid-MDA modified according to Ohkawa et al.[18] In our modification, the reaction mixture was heated at 95 °C for 60 min instead of 45 min.
Superoxide dismutase activity was determined as described by Fridovich[16] employing xanthine and xanthine oxidase to generate superoxide radicals, which react with 2-(4-iodophenyl)-3-(4-nitrophenol-S-phenyltetrazolium chloride) to form a red formazan dye. Superoxide dismutase activity is then measured by the degree of inhibition of this reaction. Protein was measured according to Lowry et al.[19] The catalase activity was spectrophotometrically measured by the disappearance of H2O2 at 230 nm. Results were expressed in nanomoles per milligram protein (nmol/mg protein).
Statistical analysis
All data presented as mean ± standard error of the mean
(SEM). Statistical comparisons between groups were
performed using analysis of variance (ANOVA) on the
log-transformed data with differences between groups
assessed with Tukey significant difference test. Statistical
significance was considered as a p value of <0.05.
Levels of total cholesterol, LDL cholesterol and triglycerides were found to be higher in group 2 than in group 1. These levels were also found to be higher in group 3 than in group 1, but lower than in group 2. However there was no statistically significant difference between the groups. High-density lipoprotein cholesterol levels were found to be lower in group 2 than group 1. However, there was no statistically significant difference between groups 1 and 2. In group 3, HDL cholesterol levels were found to be higher than groups 1 and 2. Although the difference regarding HDL cholesterol levels between group 3 and group 1 was not statistically significant (p>0.05), the difference between groups 3 and 2 was statistically significant (p<0.05). The results are shown in table 2.
Malondialdehyde levels (showing oxidative damage) were higher in groups 2 and 3 than in group 1 but the difference was not statistically significant. Although there was no significant difference between groups 1 and 2 with respect to GPX and SOD levels (showing antioxidative status), these levels were found to be significantly higher in group 3 than in groups 1 and 2 (p<0.05). There was no significant difference between the groups regarding catalase levels. The results are shown in table 3.
Table 3: Malondialdehyde, glutathione peroxidase, superoxide dismutase and catalase levels in plasma
The results of intracardiac measurements showed that MDA, GPX, SOD and catalase levels were not significantly different between the groups. The results are shown in table 4.
To test this proposition, we investigated the effect of diosmin-hesperidin (a flavonoid used in the treatment of chronic venous diseases) combination treatment on both serum lipid levels and oxidative-antioxidative system in high cholesterol diet-fed rats. Although the results were not statistically significant, serum levels of total cholesterol, LDL cholesterol and triglycerides were found to be higher in high cholesterol diet-fed rats than those in normal diet-fed rats. The resistance of rats to atherosclerosis may explain this insignificant change in the lipid profile even in the presence of high cholesterol diet. In most experimental studies, bile acids were added to diet in an attempt to elevate the lipid levels. Bile acids would increase the absorption of cholesterol from the intestines. Since we did not aim to render the intestine to absorb large amounts of cholesterol in a short period, bile acids were not added to the diet. Instead, we preferred to constitute a condition where the intestine absorbed the cholesterol in a slow manner. It is noteworthy to say that bile acids could affect the oxidative stress parameters, which could confound the interpretation of our results.
By treating high cholesterol diet-fed rats with diosmin- hesperidin combination, the levels of total cholesterol, LDL cholesterol and triglyceride decreased in an insignificant manner, but interestingly, the levels of HDL cholesterol increased significantly. The increase in HDL cholesterol levels after diosmin-hesperidin combination treatment may be explained by the increase in the levels of human serum paroxonase 1 (PON1). Paroxonase 1 enzyme, which protects HDL cholesterol against oxidation, is inactivated under oxidative stress. If oxidative stress is inhibited, PON1 levels may increase and this may protect HDL cholesterol against oxidation. Aviram[22] has reported that PON1 levels increased in rats fed with red wine flavonoids. Paroxonase 1 also reduces the oxidation of LDL cholesterol by hydrolyzing lipid peroxides.[5,22] Similar with this study, other experimental and clinical studies have reported that HDL cholesterol levels were increased by the increased intake of flavonoids.[8,20]
The key event in atherosclerosis is the oxidative modification of LDL cholesterol. Oxidized LDL is more atherogenic than native LDL.[5,21] Oxidative and modified LDL is a potent ligand for the receptors on macrophages and thus it causes the formation of foam cells derived from macrophages.[3-6,21] Antioxidative compounds provide resistance to this process and reduce atherogenicity by the inhibition of lipoprotein oxidation.
It is clear that oxidized LDL has a significant role in the initial endothelial damage that leads to atherogenesis. Because endothelial dysfunction is important in the pathogenesis of cardiovascular diseases and it is an early precursor of atherosclerosis,[12] protection of endothelial function is an important defense mechanism against atherosclerosis. For this reason, improvement in endothelial function may reduce the risk of atherosclerotic events. It has been suggested that antioxidants may inhibit arterial disease development by preserving endothelial function.[23] Being exposed to increased levels of reactive oxygen metabolites compromises hemostatic balance and this results in endothelial dysfunction.[24] Machha and Mustafa[12] have reported that aortas of hypertensive rats treated with flavonoids showed more relaxation in response to acetylcholine, flavonoids caused a decrease in blood pressure and these investigators have reported that the chronic treatment of hypertensive animals with flavonoids preserved vascular endothelial function.
In the present study, the serum levels of GPX and SOD significantly increased by the addition of diosminhesperidin combination to the diet, indicating that this drug has antioxidative properties. Many authors support this opinion. Previous studies have shown that flavonoids having antioxidative properties inhibit lipid peroxidation on vascular endothelial cell membranes by reducing the oxidative stress on macrophages and the effects of free radicals on the lipid layer.[3-6,21] It has been shown in various studies that dietary intake of flavonoids may reverse endothelial dysfunction and has high antioxidative effects.[3-5,8,12,21] In addition, various experimental studies showed a micronised purified flavonoid fraction, diosmin-hesperidin combination, also reduces oxidative stress.[15,20,24]
We found a slight increase in the serum MDA levels (showing oxidative stress) in response to a high cholesterol diet given to rats and a minimal decrease due to the addition of diosmin-hesperidin to the high cholesterol diet. But these increases or decreases were found to be statistically insignificant. Serum levels of GPX, SOD and catalase (showing antioxidative defence system) were not found to be different as compared with high cholesterol diet-fed rats and normal diet-fed rats. But serum levels of GPX and SOD significantly increased by adding diosmin-hesperidin combination to the diet. This may be related to the antioxidative effect of diosmin- hesperidin combination. Finding no difference between groups in respect of MDA levels may be attributed to the stress that may have been occurred during orogastric gavage.
Sato et al.[25] reported that although cholesterol levels did not significantly change, a vascular dysfunction occurred and aorta relaxation was impaired in high fatfed rats. They stated that this effect may be improved with the use of antioxidants and high fat diet may impair endothelial functions despite normal cholesterol levels. The results of our study were concordant with this; because we did not find significant important changes in LDL cholesterol levels. However, the antioxidant levels were increased by diosmin-hesperidin treatment and this probably preserved endothelial functions in early period by inhibiting LDL cholesterol oxidation.
We are strongly of the opinion that determining no difference between the three groups in intracardiac measurements may be related to the relatively short time period (i.e., three months) in performing our study which possibly was insufficient for the formation of a change in the heart. Furthermore, the very small values of intracardiac parameters measured may prevent making a reliable judgment.
As a conclusion, treating the high cholesterol-fed rats with diosmin-hesperidin combination may reduce the development of atherosclerosis by increasing HDL cholesterol levels and antioxidative defenses despite the lack of significant differences in serum lipid levels. However, our results should be supported by further clinical studies.
Declaration of conflicting interests
The authors declared no conflicts of interest with respect
to the authorship and/or publication of this article.
Funding
The authors received no financial support for the
research and/or authorship of this article.
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