Abstract
Taking statins can cause increase in the level of aspartate and alanine aminotransferase. The aim of this study was to assess the usefulness of melatonin in counteracting the adverse hepatic events from statins. Methods. The research program included 60 patients (aged 47–65 years, 41 women and 19 men) with hyperlipidemia taking atorvastatin or rosuvastatin at a dose of 20–40 mg daily. The patients were randomly allocated in two groups. Group I () was recommended to take the same statin at a standardized daily dose of 20 mg together with melatonin at a dose of mg. Group II () patients took statin with placebo at the same dose and time of the day. Follow-up laboratory tests (AST, ALT, GGT, and ALP) were evaluated after 2, 4, and 6 months of treatment. Results. In Group I the levels of all enzymes decreased after 6 months, particularly AST, U/L versus U/L (); ALT, U/L versus U/L (); and GGT, U/L versus 59,6 U/L (). Conclusion. Melatonin exerts a hepatoprotective effect in patients taking statins.
1. Introduction
Statins are widely used in the treatment and prevention of lipid metabolism disorders [1, 2]. They are generally well tolerated but not devoid of side effects [3, 4]. These include, among others, muscular symptoms, arthritis, headaches, and gynecomastia. Myositis and rhabdomyolysis associated with increased activity of creatinine kinase and serum creatinine levels are rare but serious adverse events of statin therapy [5, 6]. The risk of these complications is increased in elderly patients with chronic diseases and in alcohol abusers [7].
Furthermore, statins cause hepatotoxic effect which is observed in several percent of treated patients, usually in the first weeks of the therapy [8–10]. Most frequently it is manifested by asymptomatic increase in the level of aspartate and alanine aminotransferase [11]. This is usually a temporary increase, but in some patients the level of these enzymes exceeds 3 times the normal limit, which is a matter of concern [12, 13]. In such cases, patients expect the decision to discontinue the treatment or to administer hepatoprotective drugs [14]. Acetylcholine, silibinin, phospholipids, and other drugs used for this purpose are not always effective. Therefore, there is still search for alternative drugs for the protection of liver.
In our study melatonin was used for this purpose because previous experimental studies had demonstrated that it protected liver against harmful effects of many toxic agents [15–18] as well as the consequences of ischemia-reperfusion model [19–21].
The liver is an organ in which intensive metabolic and detoxification processes take place. In their course large amounts of reactive oxygen species are generated and they exert a toxic effect on hepatocytes. A complex antioxidant system, in which metabolized there melatonin (pineal and from other sources) is an important part, prevents that [22, 23].
The main melatonin metabolic pathway in the liver is through hydroxylation pathway at the C-6 position by 6-hydroxylase and P450 cytochromes (CYP1A1, CYP1A2, CYP2P19, and CYP1B1 isozymes) [24–26]. The 6-hydroxymelatonin, formed in this process, is conjugated with sulphate and glucuronide to 6-hydroxymelatonin sulphate or glucuronide. In this process melatonin and its metabolites exert high antioxidant activity.
An alternative metabolic pathway includes melatonin oxidation to N-acetyl-formyl-5-methoxykynuramine (AFMK) and N-acetyl-5-methoxykynuramine (AMK). The kynurenine pathway of melatonin metabolism leads to formation of a series of free radical scavengers [27, 28].
Furthermore, melatonin decreases the production of proinflammatory cytokines [29, 30] and inhibits hepatic fibrogenesis [31–34]. Owing to its multidirectional action in liver, apoptosis and necrosis decrease, the integrity is protected, and regeneration is improved [35–38].
The aim of this study was to assess the usefulness of melatonin in counteracting the adverse hepatic events from statins.
2. Material and Methods
2.1. Patients and Data Collection
The research program included 60 subjects, aged 47–68 years, 41 women and 19 men. All women were postpostmenopausal. Recruitment and diagnostic tests were conducted in the Department of Gastroenterology, Medical University of Lodz, and Outpatient Consulting Clinic “Gastro” in Lodz.
The research study was performed in the years 2012–2016.
Inclusion criteria are as follows:(i)Hyperlipidemia treated with statins for minimum of 6 months(ii)At least 2-fold increase in the level of aspartate and alanine aminotransferase found in two consecutive tests(iii)The persistence of increased aminotransferase levels despite the reduction in the statin doseAt the time of the inclusion of patients in the study, 38 subjects were taking atorvastatin (20 mg) and 26 rosuvastatin at the dose of 40 mg (3 patients), 20 mg (19 patients), and 15 mg (4 patients).
Exclusion criteria are as follows:(i)History of viral hepatitis(ii)Cholelithiasis(iii)Body mass index (BMI) > 30 kg/m2(iv)Alcohol abuse(v)Familial hypercholesterolemia(vi)Established hypertension(vii)Thyroid diseases(viii)Other organic, metabolic, or mental diseases(ix)Hormone replacement therapy(x)Taking other medications, especially analgesics and psychotropic drugs
2.2. Laboratory Tests
The following biochemical parameters using standard automated technique were assessed: blood cells count and levels of bilirubin, aspartate (AST) and alanine (ALT) aminotransferase, gamma-glutamyltransferase (GGT), alkaline phosphatase (ALP), total and LDL and HDL cholesterol, triglycerides, glucose, amylase, lipase, urea, creatinine, acute phase protein, thyroid stimulating hormone (TSH), and follicle-stimulating hormone (FSH) in serum.
2.3. Therapeutic Procedures
After inclusion into the study, all patients were recommended the same balanced diet with limited animal fats and simple carbohydrates of caloric content of 1600 kcal. At the same time, they were recommended to continue the treatment with the same statin at a daily dose of 20 mg.
The patients were randomly allocated into two groups. Group I () was recommended to take statin together with melatonin (LEK-AM, Poland) at a dose of 2 × 5 mg, at 7:00 a.m. and 9:00 p.m. In Group II () patients took statin with placebo (LEK-AM, Poland) at the same dose and time of the day.
Follow-up laboratory tests (AST, ALT, GGT, ALP, cholesterol, and triglycerides) were evaluated after 2, 4, and 6 months of treatment.
2.4. Ethical Procedures
A written consent was obtained from the patients and the Bioethics Committee of the Medical University in Lodz approved the study protocol (RNN/45/12/KB).
Tests were conducted in accordance with the Declaration of Helsinki and with the principles of Good Clinical Practice.
2.5. Statistical Analysis
All parameters were checked for normality using the Shapiro-Wilk test. Wilcoxon’s rank sum test was used for the comparison of basal treatment differences between each liver enzyme level. Comparison of parameters in four time series was calculated using ANOVA Friedman test. Mann–Whitney test was used for nonparametric data to perform the comparison between groups. Calculations were made using Statistical 9.1 Microsoft Co. software, and statistical significance was established at .
3. Results
In Group I the initial level of aspartate aminotransferase was 97.2 ± 19.1 U/L. After introduction of melatonin to the treatment this level decreased after 2 months to 77.5 ± 10.9 U/L () and it remained at a similar level after 4 months 66.2 ± 10.3 U/L () and after 6 months 52.8 ± 13.3 U/L ().
In Group II treated with statin and placebo, the AST level in the same time intervals was, respectively, 95.7 ± 16.3 U/L, 85.8 ± 14.5 U/L, 84.8 ± 12.5 U/L, and 87.5 ± 13.7 U/L; the differences were not statistically significant (Figure 1).
Alanine aminotransferase level was in Group I in the same time intervals, respectively, 87.4 ± 15.6 U/L, 65.2 ± 13.9 U/L (), 55.2 ± 11.1 U/L (), and 49.8 ± 14.5 U/L ().
However, in Group II, ALT level did not change significantly during the treatment and it was, respectively, 87.5 ± 15.7 U/L, 80.9 ± 11.3 U/L, 80.5 ± 13.2 U/L, and 84.2 ± 14.6 U/L (Figure 2).
The level of gamma-glutamyltransferase was in group receiving melatonin, respectively, 84.1 ± 14.8 U/L, 71.5 ± 14.3 U/L (), 62.8 ± 11.3 U/L (), and 59.6 ± 8.3 U/L (). In Group II, these values were, respectively, 75.9 ± 11.3 U/L, 72.9 ± 9.7 U/L, 69.9 ± 7.9 U/L, and 70.9 ± 9.2 U/L; the differences were statistically insignificant (Figure 3).
The level of alkaline phosphatase varied in both groups from 58.0 to 142.6 U/L and only in two patients in Group I and two in Group II patients it exceeded the upper limit of normal range of 120 U/L. These values returned to normal after 2 and 4 months of treatment only in Group I (Figure 4).
After 6 months the decrease of all enzyme levels was significantly higher in Group I compared to Group II (Figure 5).
After 6 months normal AST values were observed in 8 (25,0%), ALT in 9 (28,1%), and GGT in 11 (34,3%) on Group I patients.
In Group II, after 6 months, normal results were found only in 1 patient (3,7%), whereas in 6 of them AST and ALT level increased by the average of 11,3%.
In Group I, the level of total cholesterol decreased after 6 months from 254.2 ± 20.2 mg/dL to 212.6 ± 19.6 mg/dL and in Group II from 245.6 ± 16.4 mg/dL to 226.3 ± 20.7 mg/dL; differences between the groups were statistically significant ().
Triglyceride level decreased in Group I from 212,4 ± 20,3 mg/dL to 183,0 ± 14,6 mg/dL and in Group II from 193.6 ± 20,1 mg/dL to 171,4 ± 15,4 mg/dL; the differences between the groups were insignificant ().
All drugs were well tolerated. Patients did not complain of any ailments that could result from side effects before treatment or during its continuation. The exception was 6 patients from Group I, who in the first two weeks of taking melatonin felt mild fatigue in the morning hours.
4. Discussion
The task of the liver is to transform the lipophilic drugs into hydrophilic compounds, which are excreted in the bile or urine. To this purpose, the drugs undergo oxidation processes by cytochrome P450 isozymes and by conjugation mainly with sulfuric and glucuronic acid or with glutathione. In the oxidation reaction, together with chemically stable metabolites, there may appear reactive metabolites which damage hepatocytes by two main mechanisms.
The first mechanism is immune idiosyncrasy, a reaction involving a metabolite and the enzyme responsible for its formation, usually with an appropriate cytochrome P450. Such a protein complex becomes a new antigen which is transported to the hepatocyte surface. There, cellular and humoral immune response is induced, directed against antigen-presenting cells, which is manifested within a few weeks [39–41].
In the second mechanism, which is a reaction of metabolic hypersensitivity (metabolic idiosyncrasy) immune processes are not present. In this mechanism latency period is usually longer and it may be even several months [42, 43].
The direct drug-induced injury by molecular mechanisms is the opposite of idiosyncrasy. High concentration of a drug or its metabolite leads to the inactivation of many important cytoplasmic or mitochondrial proteins. Drugs can also disturb the processes of mitochondrial fatty acid oxidation or inhibit the activity of the respiratory chain. This results in metabolic changes such as hypertriglyceridemia, decrease in ATP production, and increased production of oxygen free radicals [44–46].
The mechanism of statin-related hepatotoxicity is not clear. It is suggested that statins cause damage to mitochondrial membranes which leads to the leakage of aminotransferases [47, 48]. Statin lipophilicity may play an important role. Statins of low lipophilicity (fluvastatin, rosuvastatin, and atorvastatin) more frequently cause the increase in aminotransferase levels compared to statins of higher lipophilicity (levostatin, simvastatin) [49, 50].
Statins even at low doses may lead to hepatocellular damage; however, this happens more often at high dose [51, 52]. An optimal dose of melatonin, which should be administered in different stages of diseases is a debatable issue. Harpsøe et al. [53] reviewed 392 literature records and found out that the applied melatonin doses ranged from 0.3 mg to 100 mg/daily. In order to control the sleep the most frequently recommended dose was 1–3 mg per night [54, 55]. The dose of 3 and 5 mg was used in the treatment of alimentary tract functional and inflammatory disorders [56–60] and in the treatment of headaches only 10 mg proved to be effective [61].
In the case of patients with nonalcoholic steatohepatitis (NASH), Gonciarz et al. [62, 63] administered melatonin at a dose of 2 × 5 mg for 3 months. The follow-up after 4, 8, and 12 weeks showed the decrease in the level of liver enzymes (AST < ALT and GGT) and this continued for further 12 weeks. Cichoz-Lach et al. [64], also in patients with NASH, used melatonin (2 × 5 mg) for 4 weeks and they also found the decreased level of liver enzymes and triglycerides and proinflammatory cytokines. Cardineli and Hadeland [65] suggested a melatonin dose of 50–100 mg/daily for the regulation of inflammatory and metabolic disorders. Such high single doses of melatonin were given to patients before liver transplantation and its good tolerability and a positive impact on the postoperative condition were demonstrated and it was expressed, among others, by faster drop in AST and ALT compared to placebo [66, 67].
Good tolerability and safety of melatonin result from its pharmacokinetic properties. Andersen et al. [68] administered intravenously 10 or 100 mg of melatonin to 12 healthy volunteers, obtaining its maximum serum concentrations of 185,637 and 1,770,500 pg/mL at T1/2, 43.3 and 46.2 minutes, with the absence of any side effects. The same researchers [69] administered orally 10 mg of melatonin to the volunteers and found its maximum serum concentration of 3550 pg/mL at T1/2, 53.7 min. Similar results of the studies on melatonin pharmacokinetics were obtained by other researchers who used the oral dose of 0.4 mg and 4 mg in older adults [70] and 80 mg in young male volunteers [71]. Thus, a single administration of melatonin raises its level for only a few hours. This justifies the administration of melatonin in divided doses in order to take full advantage of its hepatoprotective effect, particularly in metabolic disorders. Metabolic syndrome belongs to such conditions, since the results of experimental [72–74] and clinical studies [75–80] confirm the beneficial effect of melatonin.
Our results confirm significant hepatoprotective effect of melatonin in patients treated with statins. Medications regulating lipid metabolism are taken chronically and therefore hepatoprotective factors should be used on long-term basis and should be free of side effects; melatonin satisfies such conditions.
5. Conclusion
The conclusions from the obtained results support the opinion of many researchers that melatonin can be administered to protect against side effects of other drugs.
Conflicts of Interest
The authors declare that they have no conflicts of interest.
Acknowledgments
This work was supported by the grant from the Polish Ministry of Science and Higher Education no. NN 402 54 37/40.