This study examined the possible hepatoprotective effect of aminoguanidine in comparison with silymarin and investigated the possible beneficial effects of the combination of aminoguanidine and silymarin on CCL4-induced liver fibrosis. Male Wister albino rats were randomly divided into five groups (10 rats/group). Group I included control rats injected only with liquid paraffin and saline; group II represents CCL4 control (injected with CCL4 3 times a week for 6 weeks in a dose of 25μl/100gm.b.w i.p, diluted 1:6 with liquid paraffin); group III treated with aminoguanidine (100 mg/kg); group IV was given silymarin (100 mg/kg); group V was given aminoguanidine (100 mg/kg) and silymarin (100 mg/kg). Fibrosis was depicted histologically and biochemically.
CCL4 increased serum liver enzymes (ALT, AST, and ALP), lactate dehydrogenase (LDH), level of nitric oxide (NO), tumor necrosis factor alpha (TNFα) and liver malondialdehyde content (MDA), collagen fiber percent and decreased liver reduced glutathione (GSH) content as endogenous antioxidant. Histopathological changes induced by CCL4 include regenerative nodules, deteriorated parenchyma; the lobules were infiltrated with fat and structurally altered. Aminoguanidine, silymarin and their combination reduced these changes and attenuated the pathological effects of CCL4 induced liver injury. The combination of both drugs was better than each drug alone. It is concluded that aminoguanidine has protective effect against CCL4 induced hepatoxicity via its iNOS inhibition and antioxidant effects. In addition, the combination of AG with silymarin has more potent hepatoprotective effect than each drug alone.
Hepatic fibrosis is a common pathological process resulted from various chronic hepatic injuries, which is characterized by an increase of extracelluar matrix (ECM) deposition in the Disse’s space and the imbalance between synthesis and degradation of ECM.1 The primary cause of liver fibrosis includes viral hepatitis, alcohol consumption, autoimmune disorders, drug-induced, helminthic infection, iron or copper overload and biliary obstruction.2
Nitric oxide (NO) is an important mediator of hepatotoxicity.3,4 It is derived from two sources in liver. Hepatocytes and Kupffer cells contain inducible NO synthase (iNOS), the activity of which is markedly increased in inflammation. Endothelial cells contain constitutive NO synthase (eNOS). Nitric oxide is known to react with superoxide radical, forming peroxynitrite, an even more potent oxidizng agent.5 Peroxynitrite can react directly with sulfhydryl residues in the cell membranes leading to lipid peroxidation as well as with DNA resulting in cytotoxicity.6,7 The enzyme iNOS is expressed during the development of cirrhosis. Therefore, the prevention of iNOS expression may have an important role in both cirrhosis and endotoxaemia.8
Aminoguanidine (AG) is a selective iNOS inhibitor, 9-11 although the mechanism underlying this is unclear. Previous studies showed that AG protection could be through decreasing the metabolic activation of CC14 by directly inhibiting P4502E1, the isoenzyme most effective in the activation of CC14.12
Silymarin is the most known hepatoprotective drug used as a reference standard also exhibited significant protective effect against CCL4 induced liver damage.13-17
Present study aimed to examine firstly the possible hepatoprotective effect of aminoguanidine in comparison with Silymarin. Secondly study the possible beneficial effects of the combination of aminoguanidine with silymarin on hepatic fibrosis induced experimentally by CCL4 injection in rats.
Material and MethodsExperimental animalsAdult male albino rats (220-250 g) were supplied by Egyptian Organization for Biological Products and Vaccine (Helwan, Egypt). Rats were housed in stainless steel cages at constant temperature of 25 ± 2 °C, relative humidity of approximately 50%, illumination (12 h light/dark) and had free access to standard pellet chow and water ad Libitum. All experiments were carried out in accordance with protocols approved by the local experimental ethics committee.
Experimental designOne week after acclimatization, rats were randomly divided into five groups (10 rats/each). Group I includes control rats injected only with liquid paraffin and saline; group II injected with CCL4 3 times a week for 6 weeks in a dose of 25 μL/100 gm.b.w i.p, diluted 1:6 with paraffin oil to induce fibrosis; group III was given aminoguanidine (100 mg/kg); group IV was given silymarin (100 mg/kg); group V was given aminoguanidine and silymarin in the same previously mentioned doses. Groups (III, IV and V) received single oral daily dose of drugs for 2 weeks followed by concurrent adminstration of CCL4 for 6 weeks. At the end of the experiment, all animals from each group were anaesthetized with urethane (1.3 g/kg) and blood samples were collected from retrorbital sinus,18,19 subjected to serum separation and divided into aliquots. Fresh sera were tested for liver enzymes and other aliquots were stored at -20 °C for later biochemical analysis. Rats were then killed by decapitation; Livers were perfused with phosphate buffer solution (PBS) [PH = 7.4] containing 0.16 mg/mL heparin. Then livers were isolated and dissected into 3 parts. The first part was cut into longitudinal sections 2-4mm, in thickness and kept in 10% formalin in saline for histopathological examination. The second part was immersed immediately in liquid nitrogen and kept at -80°C for determination of glutathione and malondialdehyde contents. The third part was fixed in glutarlaldhyde for electron microscopical examination.
Biochemical analysis- •
Liver function tests. Serum ALT and AST activities were determined by a colorimetric method according to Reitman and Frankel.20 Serum alkaline phosphatase activity was determined by enzymatic colorimetric method according to Young, et al.21
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Liver GSH and membrane oxidation. The reduced form of glutathione was determined in the liver homogenate by colorimetric method according to Beutler, et al.22 Malondialdhyde (MDA) content as indicator of lipid peroxidation was determined in the liver homogenate, by a colorimetric method according to Satoh, et al.23
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Liver cell death. Serum lactate dehydrogenase activity as indicator of cell death was determined using a kinetic method according to Vassault, et al.24
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TNF-α measurement. Serum TNF-α was determined using an enzyme-linked immunosorbent assay according to.25
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Collagen content. Quantitive determination of collagen fibers in liver was performed according to the method of Crookham and Dapson.26
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NO level: Serum nitric oxide levels were measured by a colorimetric method as descibed by Montgomery and Dymock.27
For light microscopic investigations, specimens from liver were fixed in 10% phosphate buffer formalin, dehydrated in alcohols and embedded in paraffin. Five micron tissue sections were stained with hematoxylin and eosin stain (H&E) for general histopathological examination. Another part of liver was fixed in glutarlaldhyde and processed for electron microscopical examination.
Statistical analysisResults were expressed as mean ± SE. Statistical evaluation was done using one-way analysis of variance (ANOVA), and Tukey’s multiple comparison test using SPSS software version 12, SPSS Science, Chicago, Illinois, USA. Values of p < 0.05 were considered significant.
ResultsNumber of deaths of animalsWe started the study with 18 rat/CCL4 group and 10 rats/normal control, other groups treated with drugs was 15 rats /each group. In CCL4 group, 8 rats died. In the treatment groups 2 rats died and the extreme values are omitted giving 10 rats used for statistical analysis.
Liver function and cell deathTable 1 shows that CCl4 significantly increased serum activities of ALT, AST, ALP and LDH as compared to control (p < 0. 05).
Effects of CCL4 injection on serum activity of AST, ALT, ALP, LDH, levels of NO & TNFα and hepatic MDA, GSH and collagen fiber % in normal rats.
| Parameter | Control | CCI4 |
|---|---|---|
| ALT(U/L) | 23.9 ± 0.26 | 80.76* ± 2.56 |
| AST(U/L) | 30.29 ± 0.8 | 170.24* ± 5.18 |
| ALP (U/L) | 25.57 ± 0.96 | 172.98* ± 8.6 |
| LDH (U/L) | 103.98 ± 8.76 | 250.41* ± 11.32 |
| NO (μmol/L) | 19.26 ± 1.02 | 70.5* ± 4.06 |
| Collagen fiber (%) | 79.75 ± 3.9 | 700.99* ± 44.64 |
| TNFα (pg/mL) | 28.51 ± 1.51 | 187.8* ± 3.93 |
| Liver MDA (nmol/g.tisssue) | 17.25 ± 0.86 | 60*.55 ± 2.46 |
| Liver GSH (nmol/g.tisssue) | 75.72 ± 2.88 | 21.6* ± 1.35 |
Results are expressed as mean ± SD and (*) significant difference compared to control group at p < 0.05. n = 10.
Aminoguanidine and silymarin each alone caused significant (p < 0.05) decrease in the elevated activities of ALT, AST, ALP and LDH when compared to CCl4-treated rats. Their combination also showed significant (p < 0.05) decreases in the serum activities of ALT, AST, ALP and LDH when compared to CCl4-treated group (Table 2).
Effects of Aminoguanidine, Silymarin and their combination on serum activity of AST, ALT, ALP, LDH, levels of NO & TNFα and hepatic MDA, GSH and collagen fiber % in CCL4 treated rats.
| Parameter | CCl4 | CCl4+ AG | CCl4+ Silymarin | CCl4+AG+Silymarin |
|---|---|---|---|---|
| ALT(U/L) | 80.76 ±2.56 | 43.92# ± 0.92 | 46.04#± 0.83 | 44.75#± 1.87 |
| AST(U/L) | 170.24 ±5.18 | 104.32# ± 5.38 | 94.28#± 2.67 | 113.35a# ± 4.93 |
| ALP (U/L) | 172.98 ±8.6 | 76.97# ± 4.61 | 85.58#± 7.1 | 117.29ab#± 4.82 |
| LDH (U/L) | 250.41 ±11.32 | 137.76# ± 8.91 | 150.55# ± 10.72 | 205.18ab#± 9.27 |
| NO (μmol/L) | 70.5 ±4.06 | 46.87# ± 2.23 | 53.18# ± 2.83 | 31.5ab#± 0.51 |
| Collagen fiber (%) | 700.99 ±44.64 | 486.05# ± 15.8 | 596.62#± 57.2 | 289.42ab#± 16.43 |
| TNFα (pg/ml) | 187.8 ± 3.93 | 117# ± 3.83 | 106.02# ± 6.03 | 69.23ab#± 6.46 |
| Liver MDA (nmol/g.tisssue) | 60.55 ±2.46 | 34.34# ± 1.58 | 27.25b#± 1.48 | 24.77b#± 1.02 |
| Liver GSH (nmol/g.tisssue) | 21.6 ±1.35 | 37.58# ± 2.34 | 37.08#± 3.04 | 42.96#± 2.62 |
Results are expressed as mean ± SD (#) significant difference compared to CCL4 treated group and (a, b) significant difference from Silymarin and Aminoguanidine respectively at p < 0.05. n = 10.
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Oxidative stress markers:Table 1 also shows that CCL4 caused almost (71.47%, p < 0.05) depletion of liver GSH content as compared to control rats. While GSH content was significantly increased in silymarin pretreated rats (p < 0.05), AG (p < 0.05) and combination group was more potent than each drug alone (p < 0.05).Liver MDA content was increased significantly in CCL4 treated rats (p < 0.05) compared to control. Reduction of MDA content in liver was observed in silymarin pretreated rats (p < 0.05), AG (p < 0.05) and the combination (p < 0.05) compraed to CCL4 treated group (Table 2).
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Serum nitric oxide: CCL4 increased NO production (p < 0.05) compared to control group. Both silymarin, AG and their combination inhibited CCL4-induced NO production (Table 1 and Table 2).
The inhibitory effect of silymarin (p<0.05) was less than that of AG (p < 0.05). While, the combination of both drugs (p < 0.05) was more potent than each drug alone.
Serum TNFαCCL4 caused a significant increase in serum TNFα (p < 0.05) compared to control group (Table 1). This increase was inhibited by prophylactic administration of silymarin (p < 0.05), AG (p < 0.05) and their combination (p < 0.05) which was more potent than each drug alone (Table 2).
Liver collagen fiber percentLiver collagen fiber content was increased significantly in CCL4 treated rats (p < 0.05) compared to control rats (Table 1). Pretreatment of CCL4 treated rats with AG or silymarin caused a significant reduction of collagen fiber % (p < 0.05). The administration of AG together with silymarin resulted in greater decrease in collagen fiber % (p < 0.05) compared to silymarin alone (Table 2).
Liver histopathological examinationLiver sections from the control group rats showed normal hepatocytes, sinusoids and no fibrosis. While liver sections from CCL4 injected rats showed hepatocellular necrosis, massive fatty and inflammatory cellular infilteration in between degenerated hepatocytes.
Examination of hepatocytes of CCL4 injected rats under electron microscope showed dark heterochromatic nuclei; cytoplasm contained fragmented rER, dispersed glycogen granules and many electron lucent areas of the cytoplasm. Blood sinusoids were congested and filled with RBCs (Figures 1A, 2A, 1B and 2B).
Aminoguanidine treated rats revealed marked reduction in the hepatic lesions. Most of the hepatocytes were more or less similar to those of control group except mild dilatation of the sinusoids and few hepatocytes were vacuolated at the periphery of the lobules (Figure 1C and Figure 2C).
Haematoxylin and eosin stained sections from: (A) normal rat liver showing normal hepatocytes with euchromatic nuclei (N), their cytoplasm contain numerous mitochondria(m), many rough endoplasmic reticulium (rER) and numerous glycogen granules; (B) rat liver treated with CCl4 showing liver lobule with hepatocellular necrosis and massive fatty infilteration (f). Inflammatory cellular infilteration (arrow) is also seen inbetween degenerated hepatocytes; (C) rat livertreated with CCl4 and aminoguanidie showing liver lobule formed of central vein (v) and surrounded with normal liver cells cords (arrow). Each liver cell contains pale central rounded nuclei and acidophilic cytoplasm (arrow head); (D) rat liver treated with CCl4 and silymarin showing liver lobule formed of dilated congested central vein (v) surrounded by normal hepatic cells at the center. Some hepatic cells with vacuolated cytoplasm (arrow) and pyknotic nuclei (arrow head) were observed at the periphery of the lobule. Some blood sinusoids (BS) were dilated; (E) rat liver treated with CCl4 aminoguanidine and silymarin showing normal liver cell cords (arrow head). They contain central rounded nuclei.
Electron microscopic examination of sections from: (A) normal rat liver showing normal hepatic lobule formed of central vein (v) and liver cells cords around it (arrow); (B) rat liver treated with CCl4 showing hepatocytes with heterochromatic nuclei (N). Their cytoplasms contain few electron dense mitochondria, fragmented rER, dispersed glycogen granules and electron lucent areas of the cytoplasm (arrow). Notice that the blood sinusoid (BS) is congested and filled with RBCS; (C) rat liver treated with CCl4 and aminoguanidie showing normal hepatocytes formed of euchromatic nuclei (N), their cytoplasm contain numerous mitochondria (m), well developed cisternne of rER and some electron lucent areas of cytoplasm (arrow). Also, blood sinusoids are dilated and congested (BS); (D) rat liver treated with CCl4 and silymarin showing hepatocytes with euchromatic nuclei (N), their cytoplasm contain some electron dense mitochondria (m), few cisternae of rER and many electron lucent areas (arrow) of the cytoplasm. Also, blood sinusoids (BS) are congested and dilated; (E) rat liver treated with CCl4, aminoguanidine and silymarin showing normal hepatocytes with euchromatic nuclei (N), their cytoplasm contain numerous mitochondria (m), many cisternne of rER. Also, blood sinusoids (BS) are dilated and congested.
Silymarin treated rats showed liver lobule formed of congested central vein surrounded by normal hepatic cells at the center and some hepatic cells with vacculated cytoplasm at the periphery of the lobule. Hepatocytes had euchromatic nuclei, their cytoplasm contain some mitochondria, few cisternne of rER and electron lucent areas of cytoplasm (Figure 1D and Figure 2D).
Silymarin and AG combination treated rats showed most of liver cells preserved normal structure. However, some liver cells appear vacuolated. Normal hepatocytes with euchromatic nuclei, their cytoplasm contain numerous mitochondria, many cisternne of rER and few cisternne of sER were shown (Figure 1E and Figure 2E).
DiscussionFibrosis is both a sign of liver damage and a potential contributor to liver failure via progressive cirrhosis of the liver.28
In this study, CCL4 caused a significant elevation of serum AST, ALT, ALP and LDH activities. The altered activities of these enzymes in CCL4 treated rats corresponded to the extensive liver damage. The increased activities of ALT, LDH and AST may be attributed to the damaged structural integrity of the liver, because these are cytoplasmic in location and are released into circulation after cellular damage.32 This damage was further confirmed by light microscopical examination which showed enlargement of the liver, hepatocellular necrosis and massive fatty infilteration. In addition, the electron microscopic examination showed that hepatocytes with dark heterochromatic (inactive) nuclei; their cytoplasm showed fragmention of rER, dispersed glycogen granules and appearance of many electron lucent areas of the cytoplasm. These alterations may be due to toxic influence of CCL4 metabolites which injured multiple protein systems including those present in rER and mitochondria. Moreover, reactive oxygen species caused oxidation of cellular proteins and extensive mitochondrial DNA damage thus impaired mitochondrial synthesis by the liver cells.33 Blood sinusoids were congested and filled with RBCs.The observed electron-lucent areas of the cytoplasm may be lipid droplets.
Previous studies demonstrated visible accumulation of lipid and increased percentage of sER which were accompanied by elevated serum ALT and glutathione peroxidase. Glutathione peroxidase is responsible for reduction of lipid hydroperoxides to their corresponding alcohols and to reduce hydrogen peroxide to water in the cells.34-36
Hepatotoxicity of CCL4 is thought to involve two phases.37 In the first phase, CCL4 is metabolized by cytochrome P450 in hepatocytes, giving rise to highly reactive trichloromethyl radicals in the endoplasmic reticulium of kupffer cells and hepatocytes. This radical forms trichloromethyl peroxyl radical in the presence of oxygen. These free radicals are unstable and immediately react with the membrane components initiating a chain reaction that leads to lipid peroxidation (LPO).32
Results of the current study demonstrated that in CCL4 treated rats there was a significant elevation in MDA content of the liver tissue. This enhanced lipid peroxidation leads to tissue damage and failure of antioxidant defense mechanisms.38 A significant reduction in liver GSH in CCL4 treated rats was also observed in the present study. It may be due to enhanced substrate utilization by glutathione peroxidase, as there is a direct correlation between GSH depletion and enhanced lipid peroxidation.39
The second phase of CCL4 hepatotoxicity involved the inflammatory responses which play an important role. Some hepatic cells including Kupffer cells, hepatic stellate cells (HSCs) and sinusoidal endothelial cells are activated to secrete cytokines which mediate liver fibrogenesis.40
Tumor-necrosis factor TNF-α and interleukin (IL)-6 are considered the major hepatotoxicity mediators in liver injury.41 When an inflammatory reaction occurs, TNF-α is expressed by both infiltrating inflammatory cells such as macrophages in blood and hepatocytes in case of liver injury.
The present study showed that serum TNF-α level in CCL4 treated rats was significantly elevated. TNF-α caused overproduction of nitric oxide in liver.42 Nitric oxide is known to react with superoxide radical, forming peroxynitrite, an even more potent oxidizing agent.5 Peroxynitrite can react directly with sulfahydryl residues in cell membrane as well as with DNA leading to lipid peroxidation and cytotoxicity.6,7
This study illustrated that there is an elevation in serum nitric oxide level in CCL4 treated rats. This may be due to depletion of glutathione that may weaken cellular antioxidant defense to such a point that NO produced by iNOS may cause tissue injury.43
The present study demonstrated that there is a significant increase in collagen fiber percent of liver tissue after IP injection of CCL4. It has been shown that hepatic fibrosis largely resulted from the disorder in the homeostasis of synthesis, deposition, degeneration and absorption of collagens. In hepatic fibrosis, myofibroblasts characteristically assume the ability to remodel extracellular matrix (ECM) via their production of ECM proteins in liver.44 In liver cirrhosis, the proliferation of myofibroblasts is associated with inappropriate remodeling of ECM that generates scar tissue which leads to structural and functional disorders in normal tissue.45
Results of the current study demonstrated that aminoguanidine; a nucleophilic hydrazine compound structurally similar to L-arginine and acts as specific iNOS inhibitor10 caused a significant reduction in liver enzymes and LDH activities in CCL4 treated rats. Moreover, histopathological examination revealed marked reduction in the hepatic lesions.
This study demonstrated that aminoguanidine caused a significant reduction in serum NO level. It was found that plasma concentration of nitrates/nitrites, measured as an index of NO production, were significantly increased in the Fibrotic animals in the basal period and decreased with AG to normal control levels. INOS enzyme is expressed in hepatocytes and inflammatory cells during the development of cirrhosis. Therefore, inhibition of iNOS expression may have an important role in both cirrhosis and endotoxaemia.8
In the present study, there was a significant reduction in liver MDA content and a significant elevbation in liver GSH content in rats pretreated with aminoguanidine. This suggested an alternative mechanism of AG protection via decreasing the metabolic activation of CC14 by direct inhibition of P4502E1, the isoenzyme most effective in the activation of CC14.12 Thus decreasing the free radicals release that causes lipid peroxidation.46
It should also be noted that aminoguanidine not only act as inhibitor of nitric oxide synthase but also a peroxynitrite scavenger.47 These observations also indicate that the protective effect of AG against the enzyme leakage seems to be through the liver cell membrane permeability restoration and is independent of any effects on liver GSH contents.48
Results of the present study demonstrated that silymarin caused a significant reduction in AST, ALT, ALP and LDH activities in CCL4 treated rats.
In addition, histopathological examination of the liver of CCL4 treated rats pretreated with sily- marin showed an improvement in hepatic cell ultrastructure.
The cytoprotective effects of silymarin are mainly attributable to its antioxidant and free radical scavenging properties. Silymarin can enter inside the nucleus and act on RNA polymerase enzymes resulting in increased ribosomal formation. This in turn hastens protein and DNA synthesis.49,50 This action has important therapeutic implications in the repair of damaged hepatocytes and restoration of normal functions of liver. Silymarin can also interact directly with cell membrane components to prevent any abnormalities in the content of lipid fraction responsible for maintaining normal fluidity.51
The present study showed that silymarin caused a significant decrease in liver MDA content and a significant increase in liver GSH content in Fibrotic rats. This may be attributed to direct free radical scavenging properties of silymarin.
Furthermore, silymarin caused a significant reduction in serum nitrite level in Fibrotic rats. It was found that silymarin inhibited the production of O2-and NO in a dose-dependent manner.52
This study demonstrated that silymarin caused a significant reduction in serum TNFα level. This anti-inflammatory effect of silymarin on hepatic tissue is based on multiple activities including mast cell stabilization, inhibition of neutrophil migration, inhibition of kupffer cell activation and inhibition of the production of leukotrienes, cytokines and prostaglandin.53,54 In addittion, it inhibits hepatic stellate cell proliferation and transformation.55
In the present study, there was a significant decrease in the content of collagen fibers only by 15% in liver tissue of Fibrotic rats treated with silymarin. This protection can be attributed to antioxidant and membrane-stabilizing actions.52
The results obtained in the present investigation demonstrated for the first time to our knowledge that silymarin and AG combination caused a significant reduction in collagen fiber content in liver by 58% in Fibrotic rats, these reduction is better than the administration of each drug alone. As this combination may suppress the activation of HSCS due to the potent antifibrotic effect of both AG and silymarin when used together.
This is may be mediated by the reduction of liver MDA content, serum nitric oxide level and the increase in GSH content which were also better than silymarin alone. The antioxidant effects of both drugs can inhibit HSC activation, protect hepatocytes from undergoing apoptosis and attenuate liver fibrosis.56
In addition, the combination caused a significant reduction in serum TNFα level, which is better than each drug alone. As both AG and silymarin has anti-inflammatory properties that potentiate the effect of each other.
In the present investigation, silymarin and AG combination caused a significant reduction in serum AST and LDH activities, which were lesser than each drug alone. Moreover, the combination of the two drugs produced a significant reduction in serum ALT activity, which is similar to the effect of silymarin. These biochemical findings are confirmed by histopathological examination.
In summary, the current data showed that aminoguanidine has protective effect against CCL4 induced hepatoxicity via its iNOS inhibition and antioxidant effect. In addition, the combination of AG with silymarin has more potent hepatoprotective effect than each drug alone suggesting beneficial effect against liver fibrosis.
