The liver is a vital organ of the human body that is responsible for numerous fundamental and important roles, including digestive and excretory functions, in addition to nutrient storage and metabolic functions, synthesis of new molecules, and purification of toxic chemicals [1]. Recently, liver injuries induced by various factors, such as chemical pollutants, drugs, and alcohol, have been studied widely. Liver steatosis, fatty liver, hepatitis, fibrosis, cirrhosis and hepatocellular carcinoma are the most prevalent liver diseases, and have also been investigated extensively. The therapy choices for these injuries and diseases are very few. Therefore, it is imperative to seek an effective and safe treatment for liver injuries and diseases.

Melatonin (N-acetyl-5-methoxytryptamine) is mainly synthesized from the amino acid tryptophan by the pineal gland in mammals and humans [2,3]. Firstly, tryptophan is hydroxylated by tryptophan-5-hydroxylase to form 5-hydroxytryptophan. Then, it is decarboxylated to 5-hydroxytryptamine (serotonin) by l-aromatic amino acid decarboxylase. After serotonin acetylation, N-acetylserotonin is produced. At last, N-acetylserotonin is converted to N-acetyl-5-methoxytryptamine (melatonin) in the pineal gland [4]. Except for endogenous melatonin, exogenous melatonin can be consumed from a daily diet. There are lots of melatonin-rich foods, such as sour cherries, walnuts, and orange juice [5]. Melatonin could regulate the circadian rhythm, and alleviate insomnia and jet lag [5,6]. In addition, melatonin showed a variety of regulatory effects on sexual behavior, immune function, energy metabolism, the cardiovascular system, the reproductive system, and the neuropsychiatric system [4,7]. Melatonin also exhibited anticancer and anti-osteoarthritic activities. Moreover, melatonin showed strong antioxidant activity and possessed protective properties against oxidative stress [8,9]. Melatonin is the focus of many research areas due to its ability to scavenge free oxygen radicals and thereby protect cells and tissues from radical damage [10]. Recently, studies have focused on the roles of melatonin in oxidative stress, lipid metabolism, and its potential therapeutic action. There are numerous studies exhibiting the beneficial abilities of melatonin on liver injuries and diseases. This review summarizes the effects of melatonin on liver injuries induced by various factors and liver diseases, including liver steatosis, non-alcohol fatty liver, hepatitis, liver fibrosis, liver cirrhosis, and hepatocarcinoma, focusing on the mechanisms of action, such as antioxidant, anti-inflammation, anticancer, antiproliferation, and pro-apoptosis.

Liver steatosis is present in over two-thirds of the obese population. Hepatic steatosis could provoke insulin resistance and dysfunction of glucose and lipid metabolism [7]. Once steatosis has developed, the liver is “sensitized” to various inflammatory stimuli, which can precipitate nonalcoholic steatohepatitis [113]. However, there is a lack of effective treatment for hepatic steatosis. Recently, the role of melatonin in hepatic steatosis and its potential therapeutic effects have been identified.

A high-fat diet could induce oxidative stress with extensive liver steatosis in rats [7]. In rats fed a high-fat diet, mean liver weights (p < 0.001) and weight ratios of liver to body were reduced after melatonin treatment. Moreover, melatonin treatment significantly decreased hepatic steatosis. However, there was no evidence showing that melatonin reversed established steatosis [7]. Additionally, it has been demonstrated that melatonin has protective effects on hepatic steatosis induced by some other factors. Prenatal glucocorticoid overexposure could result in steatosis. In a prenatal glucocorticoid group, liver steatosis and apoptosis increased and the expression of leptin decreased. In addition, caspase 3, TNF-α, proteins expression, TUNEL stains, liver histone deacetylase, DNA methyltransferase activity, and DNA methylation were all increased in the prenatal glucocorticoid group. However, melatonin reversed these phenomena mentioned above and decreased liver steatosis [114]. In addition, estrogen deficiency and endoplasmic reticulum (ER) stress could also induce hepatic steatosis. In ovariectomized (OVX) rats, lipid accumulation and cellular oxidative stress were prevented by exogenous melatonin treatment in the liver. Melatonin alleviated steatosis and cellular oxidative stress in the livers of OVX rats [115]. Moreover, microRNAs (miRNAs) are pivotal regulators of gene regulation and their dysfunctions are common features in various metabolic diseases. Among miRNAs, miR-23a could regulate ER stress. Melatonin treatment rescued expression of miR-23a stimulated with tunicamycin, thus decreasing ER stress in primary hepatocytes and ameliorating ER stress-induced hepatic steatosis and inflammation [116].

Non-alcoholic fatty liver disease (NAFLD) may develop to end-stage liver diseases, which range from simple steatosis to steatohepatitis, advanced fibrosis, and cirrhosis. The main pathophysiological mechanisms of NAFLD are oxidative stress and lipid peroxidation [117]. Currently, there are no specific treatments against NAFLD [118]. NAFLD patients are characterized by hepatic steatosis, which several studies have demonstrated that melatonin attenuated [114,117]. Moreover, the effects of melatonin on NAFLD have been identified.

Some studies showed that melatonin protected against fatty liver mainly through preventing oxidative stress. Oxidative stress and extensive liver steatosis were observed in NAFLD rats, induced by a high-fat diet. Melatonin (2.5, 5, 10 mg/kg BW) improved SOD and GSH-Px activities, and a 10 mg/kg BW dose of melatonin decreased the MDA level in fatty liver. Additionally, melatonin (5 or 10 mg/kg BW) decreased hepatic steatosis and inflammation by lowering serum ALT, AST, liver total cholesterol, and TG in the fatty liver [117]. Another study determined the antioxidant activity of melatonin on hepatic oxidative stress in NAFLD female rats caused by ethionine. TG, MDA, and conjugate dienes (DC) were lower (p < 0.001), while GSH-Px activity was higher (p < 0.05) after treatment with melatonin. It could be concluded that hepatic oxidative stress in NAFLD female mice was reduced by melatonin [119]. In addition, melatonin reduced fatty liver by decreasing the level of pro-inflammatory cytokines and improving some parameters of fat metabolism in patients with NAFLD [120].

Diabetes mellitus patients were very likely to also have chronic liver disease. Moreover, chronic liver disease might be a leading cause of death in patients with diabetes mellitus. It was found that a majority of liver injuries induced by diabetes mellitus were associated with NAFLD [121]. Therefore, the protective effects of melatonin on diabetes mellitus-induced liver injury are also discussed in this section. Melatonin has been found to act as an anti-diabetic agent in animal models [122]. Melatonin improved glucose intolerance and insulin resistance in high fat diet-induced diabetic mice [123]. Moreover, melatonin was demonstrated to possess beneficial effects on liver injury induced by diabetes. The mechanism of protection might be associated with elevation in the antioxidant status of cells and mitochondrial physiology [124].

Diabetic rats were observed with markedly higher blood glucose levels than the rats of the control. Mean body weights of diabetic rats were meaningfully lower than those of the control. In histological investigations, hydropic and nuclear changes were observed in hepatocytes in the diabetic rats, and cellular glycogen depletion, congestion, sinusoidal dilatation, inflammation, and fibrosis were found in diabetic rats. In addition, both glycogen granules in the hepatocyte cytoplasm and mast cell granules were decreased in the diabetic rats [125,126]. Melatonin had a positive effect on these parameters. It was demonstrated that melatonin restored the morphological and histopathological changes of the liver induced by diabetes [127]. Additionally, MDA, protein carbonyl (PCO) and 8-hydroxy-2-deoxyguanosine (8-OHdG) levels in the plasma and the liver homogenates were considerably decreased due to melatonin administration. Total thiol (T-SH) and GSH levels in liver were meaningfully increased in diabetic rats following melatonin treatment [128,129,130].

Mitochondrial dysfunction and an overproduction in mitochondrial ROS during diabetes caused pathological consequences of hyperglycemia [124]. Moreover, the impairment of mitochondrial respiratory activity plays a key role in liver injury during diabetes [131]. The effects of melatonin on this particular functional impairment in rats’ liver mitochondria have been identified. In diabetic rats, the oxygen consumption rate V₃ and the acceptor control ratio were reversed to those of non-diabetic rats by melatonin. In addition, the suppressed activity of CAT in the cytoplasm of liver cells was restored, and mitochondrial GST inhibition was prevented by melatonin [124]. Thus, melatonin might regulate mitochondrial function under diabetes.

Hepatitis is a critical clinical issue. The pathogenesis of hepatitis is various, including viruses, drugs, alcohol, toxins, and so on. Developing an effective therapeutic agent for hepatitis is urgent. There is evidence showing that melatonin possesses beneficial effects on hepatitis.

In several experimental models, some drugs, such as acetaminophen, amoxicillin-clavulanic acid, albendazole, and labetalol, could induce toxic hepatitis [132,133,134,135]. Some food supplements might also induce toxic hepatitis [136]. Interestingly, in intact animals, GSH concentration and activities of GSH-Px, GSSG-R, NADP-isocitrate dehydrogenase, and glucose-6-phosphate dehydrogenase increased after the administration of melatonin. However, in animals with toxic hepatitis, GSH concentration and these enzyme activities decreased after melatonin treatment, which was probably associated with an inhibition of free radical oxidation [137].

The effects of melatonin on fulminant hepatitis induced by rabbit hemorrhagic disease virus (RHDV) have been identified in rabbits. RHDV infection triggered an inflammatory response; meanwhile, toll-like receptor 4, high-mobility group box (HMGB)1, IL-1β, IL-6, TNF-α, and C-reactive protein expression were increased, while decay accelerating factor (DAF/CD55) expression decreased. Melatonin meaningfully restored those changes. Melatonin also lowered matrix metalloproteinase-9 expression. Moreover, RHDV infection inhibited the hepatic regenerative/proliferative response and decreased the expression of hepatocyte growth factor (HGF), epidermal growth factor, platelet-derived growth factor (PDGF)-B, vascular endothelial growth factor, and their receptors, which were inhibited by melatonin treatment. Additionally, melatonin reduced phosphorylated Janus kinase expression and enhanced extracellular mitogen-activated protein kinase (ERK) and signal transducer and activator of transcription (STAT) 3 expression. It has been shown that melatonin had an anti-inflammation effect and stimulated regenerative mechanisms in rabbits infected by RHDV [138]. Concomitantly, hepatocyte apoptosis was crucial in the progress of fulminant hepatitis infected by RHDV. Melatonin reduced apoptotic liver damage by attenuating ER stress via modulation of unfolded protein response signaling [139].

NAFLD might progress into nonalcoholic steatohepatitis, and the major process is oxidative stress with excessive production of ROS and inflammatory cytokine generation [140]. Patients with histological evidence (liver biopsy) of nonalcoholic steatohepatitis and no history of alcohol abuse were included to determine the effects of melatonin on nonalcoholic steatohepatitis. After three months’ treatment with melatonin, enzymes in the plasma and liver of the patients significantly improved without any side effects [140,141].

Liver fibrosis is a wound-healing process of the liver in response to repeated and chronic liver injuries to hepatocytes or cholangiocytes. Based on the pathogenesis of liver fibrosis, therapeutic approaches to liver fibrosis could target each step of the process, including hepatocyte apoptosis, cholangiocyte proliferation, inflammation, and activation of myofibroblasts to deposit extracellular matrix [142]. Several studies have suggested that melatonin might be developed into a promising treatment for liver fibrosis. In addition, some studies demonstrated that melatonin attenuated liver fibrosis via limiting the expression of profibrogenic genes [143], directly suppressing hepatic stellate cells activation [144], and so on.

Hepatic fibrosis was commonly caused by CCl₄ in experiments. In a study, it was demonstrated that melatonin attenuated CCl₄-induced liver fibrosis through preventing necroptosis-associated inflammatory signaling. Melatonin reduced hepatic hydroxyproline content, hepatocellular damage, and transforming growth factor β1 and α-smooth muscle actin expression [145,146]. Moreover, melatonin significantly attenuated RIP1 expression, RIP1 and RIP3 necrosome complex formation, and mixed lineage kinase domain-like protein level in the liver [145]. Concomitantly, the expression of NFκB in the liver was inhibited, and the production of pro-inflammatory cytokines including TNF-α and IL-1β from Kupffer cells was decreased in fibrotic rats [147]. In another study, melatonin protected against liver fibrosis via inhibiting mitochondrial dysfunction, upregulating mitophagy, and mitochondrial biogenesis. Meanwhile, melatonin attenuated hallmarks of mitochondrial dysfunction, including mitochondrial swelling and glutamate dehydrogenase release [148]. In addition, pathologic evidence showed that melatonin prevented fibrosis (p < 0.05) caused by CCl₄. AST, ALT, laminin, and hyaluronic acid levels in serum and hydroxyproline content in the liver were markedly lowered in the melatonin treatment group. Moreover, treatment with melatonin greatly decreased the MDA level and improved GSH-Px activity in the liver [149]. Additionally, a combination of melatonin and human dental pulp stem cells transplantation (hDPSCs) were better at suppressing liver fibrosis and restoring ALT, AST, and ammonia levels in the group of CCl₄-injured mice than treatment with melatonin or hDPSCs alone [150].

Liver fibrosis could also be induced by bile-duct ligation, thioacetamide, and dimethylnitrosamine. Melatonin suppressed hepatic fibrotic changes (p < 0.001), lowered collagen, MDA, luminal, and lucigenin levels, and increased GSH levels in fibrotic liver caused by bile-duct ligation [151]. AST, ALT, and alkaline phosphatase (AP) had lower activity in fibrotic rats receiving thioacetamide followed by melatonin than rats receiving thioacetamide only. Moreover, melatonin lowered the levels of proinflammatory cytokines and oxidized glutathione, and increased the GSH level in the fibrotic liver. Additionally, an increase in the activity of paraoxonase 1 (PON-1) toward phenyl acetate and paraoxon was observed in the liver and serum after melatonin treatment [152]. In fibrotic rats induced by dimethylnitrosamine, fibrotic changes were suppressed by melatonin. Hydroxyproline and MDA levels were reduced, and GSH and SOD levels were elevated by melatonin treatment. Interestingly, there were no meaningful alterations in biochemical parameters when treated with melatonin only [153].

Liver cirrhosis is a critical stage of chronic liver diseases that can lead to liver failure, portal hypertension, and hepatocarcinoma [154]. In patients with liver cirrhosis, disturbances in serotonin and melatonin homeostasis were observed [155]. Moreover, primary biliary cirrhosis might be a pineal deficiency disease [156]. Thus, melatonin secreted by the pineal gland might exhibit protection on liver cirrhosis.

Constant oxidative stress could cause cell damage and fibrogenesis under liver cirrhosis [154]. Melatonin, as a powerful antioxidant, has been demonstrated to be beneficial in cases of liver cirrhosis. In thioacetamide-induced liver cirrhosis, oxidative stress with extensive tissue damage and increased α-smooth muscle actin expression were observed. Melatonin treatment showed protective effects on the oxidative stress-related changes, which suggested that melatonin prevented tissue damage and fibrosis in liver cirrhosis caused by thioacetamide [154]. In another study, secondary biliary cirrhosis was induced by bile duct ligation, and melatonin (20 mg/kg BW) was treated intraperitoneally for two weeks, starting 15 days after an operation. The data indicated that melatonin was useful for different tasks, including re-establishing normal liver enzyme concentration, decreasing the hepatosomatic and splenosomatic indices, restoring lipoperoxidation and the antioxidant enzyme level, and decreasing fibrosis and inflammation, thus weakening liver tissue injury in secondary biliary cirrhosis rats [157]. Concomitantly, melatonin concentration was meaningfully increased in the plasma by the oral administration of melatonin (10 mg), both under fasting and postprandial conditions, particularly in liver cirrhosis patients [158]. Herein, melatonin might be developed into a therapeutic agent for liver cirrhosis.

Cancer is a major public health problem and one of the leading causes of death [159,160]. Hepatocellular carcinoma (HCC), the main type of liver cancer (70%–80%), is one of the most common cancers and its incidence is growing worldwide [161,162]. In addition, HCC is one of the most lethal human cancers because of its high incidence and metastatic potential and the low efficacy of conventional therapies [163]. Surgery, radiotherapy, and chemotherapy are the major treatment modalities, but could induce certain side effects [164]. Epidemiological studies have suggested that antioxidant supplements might reduce the risk of cancer recurrence and cancer-related mortality [165]. Melatonin, a powerful antioxidant, showed protective effects on hepatocarcinoma. Its oncostatic effects on hepatocarcinoma were mainly due to its antioxidant, antiproliferative, and pro-apoptotic abilities.

Melatonin is an effective natural antioxidant that acts through different mechanisms to weaken the impairments of ROS [166]. In H4IIE hepatoma cells, the effect of melatonin on the hydrogen peroxide (H₂O₂)-induced activation of the mitogen-activated protein kinase (MAPK) and mTOR signaling pathways was identified. H₂O₂-induced activation of the extracellular signal-regulated protein kinases (ERK)1/2 and p38 MAPK, and some of their downstream targets, were strongly weakened by melatonin. H₂O₂-induced phosphorylation of Akt and the Akt substrate mTOR, a downstream target of mTOR action, and eIF4E-binding protein 1 (4E-BP1) were also weakened by melatonin. Upregulation of ERK1/2, p38, and Akt signaling by H₂O₂ were all accompanied by activation of Ras. Thus, melatonin acted to inhibit many of the H₂O₂-induced changes in the MAPK and mTOR signaling pathways, mainly via preventing Ras [166]. In addition, supplementation with isoquercitrin or melatonin reduced the oxidative stress-mediated hepatocellular tumor-promoting effect of oxfendazole. The number of glutathione S-transferase placental form (GST-P)-positive foci promoted by oxfendazole was prevented by the combined antioxidant isoquercitrin or melatonin treatment, and the area of GST-P-positive foci was suppressed by melatonin treatment. The mRNA expression of cytochrome P₄₅₀, family 2, subfamily b, polypeptide 2 (Cyp2b2), and malic enzyme 1 were decreased in the isoquercitrin and melatonin treatment groups, and mRNA expression levels of Cyp1a1 and aldo-keto reductase family 7, member A3 were also decreased in the melatonin treatment group. Furthermore, the production of NADPH-dependent ROS was inhibited in vitro due to isoquercitrin or melatonin treatment. Co-administration of isoquercitrin or melatonin suppressed the hepatocellular tumor-promoting activity of oxfendazole in rats by decreasing ROS production and activating Cyps [167]. In addition, it has been demonstrated that melatonin had effects on circadian rhythms of LPO and antioxidants in N-nitrosodiethylamine (NDEA)-induced hepatocarcinogenesis. Alteration of circadian systems could cause cancer and affect its development; meanwhile, circadian rhythms were markedly altered in tumors and tumor-bearing hosts [168]. Circadian rhythm characteristics, such as acrophase, amplitude, and mesor of thiobarbituric acid reactive substances (TBARS), SOD, CAT, GSH-Px, and reduced glutathione were significantly changed in NDEA-treated rats [3]. The amplitude and mesor values of these antioxidant indices were significantly increased and the mesor values of TBARS were decreased after melatonin administration. Melatonin also reversed further delays in acrophase in NDEA-induced rats [169,170].

The proliferation of a variety of cancer cell lines was suppressed by melatonin, but only a few studies have focused on this ability of melatonin in hepatocarcinoma [171]. In a study, the effects of melatonin on the mouse hepatoma cell line HEPA 1–6, co-incubated with ethanol, and tamoxifen, respectively, were investigated. The antiproliferative activity of melatonin was exhibited from 640 μM to 3 mM dose-dependently, which was meaningfully higher (p < 0.01) than that with the solvent (ethanol) alone. The mechanism of antiproliferative effect of melatonin might be the prolonged activation of MAPK, which was activated by phosphorylation 15 min after induction with melatonin [172]. In HepG2 human HCC cells, melatonin possessed a dose- and time-dependent antiproliferative effect after its administration for two, four, or six days at 1000 or 2500 μM. The cell cycle altered with a rise in the number of cells in G₂/M phase at both 1000 and 2500 μM melatonin concentrations, and S phase cell percentage had a significant increase at 2500 μM. Moreover, protein expression of MT₁, MT₃, and retinoic acid-related orphan receptor-α increased after melatonin treatment [161]. Additionally, the receptor antagonist luzindole was used to assess the melatonin effects on cell viability and proliferarion in HepG2 human HCC cells. A significant reduction in cell viability was observed after melatonin treatment (1000 and 2500 μM), and a meaningful decrease in cAMP level was detected at a dose of 2500 μM melatonin treatment, which was partly blocked by luzindole. Phosphorylated p38, ERK, and JNK expression was increased by both melatonin concentrations. ERK activation was completely abolished and cytosolic quinone reductase type-2 mRNA level was markedly improved in luzindole-treated cells. The data showed that the effects of melatonin on cell viability and proliferation in HepG2 human HCC cells were partly regulated via the MT1 membrane receptor, which also seemed to be associated with the melatonin modulation of cAMP and ERK activation [171]. Interestingly, the exposure to weak, extremely low frequency magnetic fields could also affect cancer progression. However, the cytoproliferative and dedifferentiating effects exerted by magnetic fields were prevented after 10 nM melatonin treatment in HepG2 cells [173].

Apoptosis resistance in HCC is an important factor in hepatocarcinogenesis and tumor progression, and causes resistance to conventional treatments [174]. Therefore, pro-apoptotic ability might be a key factor in treating HCC. Melatonin has shown its pro-apoptotic effect in many studies. Inhibitor of apoptosis proteins (IAPs) have exhibited an ability to resist apoptosis. Four members of IAPs (cIAP-1, cIAP-2, survivin, and XIAP) were overexpressed in human HCC tissue. Melatonin overcame apoptosis resistance by inhibiting survivin and XIAP via the COX-2/PI3K/Akt pathway in HCC cells. Inhibition of the growth of HepG2 and SMMC-7721 cells and promotion on apoptosis, accompanied by the downregulation of survivin and XIAP were found after melatonin treatment. Moreover, cIAP-1, survivin and XIAP, were related to the co-expression of COX-2 in human HCC specimens, and melatonin also decreased COX-2 expression and prevented Akt activation in HepG2 and SMMC-7721 cells [174]. In HepG2 HCC cells, melatonin treatment induced apoptosis with improved caspase-3 activity and poly (ADP-ribose) polymerase proteolysis. The pro-apoptotic effects of melatonin were associated with cytosolic cytochrome c release, upregulation of Bax, and induction of caspase-9 activity [175]. In another study, melatonin (10⁻⁸–10⁻⁵ M) showed a dose-dependent antiproliferative effect but no cytotoxic effect on hepatoma cell lines HepG2 and Bel-7402. Moreover, when combined with doxorubicin, melatonin meaningfully increased the effects of cell growth inhibition and cell apoptosis. The mechanism of cooperative apoptosis induction might be related to reduced Bcl-2 expression and improved Bax and caspase3 expression [176]. Previous studies have shown that melatonin elevated the effects of some chemotherapeutic drugs in HCC [177]. A study identified the roles of melatonin in ER stress-induced resistance to chemotherapeutic agents in HCC. Pre-treatment with tunicamycin (an ER stress inducer) significantly reduced the apoptosis rate produced by doxorubicin, while co-pretreatment with tunicamycin and melatonin drastically elevated the apoptosis caused by doxorubicin in HepG2 and SMMC-7721 cells. Additionally, phosphorylated Akt expression was decreased due to melatonin. Moreover, the C/EBP-homologous protein level was increased and survivin level was decreased by melatonin [177].

Except for the abovementioned effects, melatonin has other abilities that have been widely studied, such as autophagy, anti-invasion, antimetastasis, and anti-angiogenesis. In hepatoma H22 tumor-bearing mice, it was discovered that melatonin triggered an autophagic process by increasing Beclin 1 expression and inducing a conversion of microtubule-associated protein 1 light chain 3(LC3)-I to LC3-II, the protein related to the autophagosome membrane. Moreover, the phosphorylation of mTOR and Akt was inhibited by melatonin [178]. In addition, the autophagy induced by melatonin might be a potential strategy to potentiate melatonin’s apoptotic effects [179]. Extracellular matrix degradation by matrix metalloproteinases (MMPs) is related to cancer cell invasion, and it has been suggested that the inhibition of MMPs by synthetic and natural inhibitors might be of great importance in HCC therapies [180]. Melatonin exhibited anti-invasive and antimetastatic effects through preventing MMP-9 activity in various tumor types. More specifically, melatonin regulated the motility and invasiveness of HepG2 cells in vitro via a molecular mechanism that involved TIMP-1 upregulation and attenuation of MMP-9 expression and activity via NFκB signaling pathway inhibition [180]. In addition, melatonin showed anti-angiogenic features in the HCC cell lines. Angiogenic (CCL2, CXCL6, IL-8) and angiostatic (CXCL10) chemokine gene expression in two HCC cell lines was influenced by melatonin. Upregulation of CCL2, IL-8, and CXCL10 genes in the HCC24/KMUH cell line, but downregulation of CCL2, CXCL6, and IL-8 genes in the HCC38/KMUH cell line, and upregulation of CXCL10 gene in both cell lines, were found after melatonin treatment at pharmacologic concentrations (1 and 100 μM) [181]. Furthermore, melatonin exhibited an anti-angiogenic activity in HepG2 cells through affecting the transcriptional activation of vascular endothelial growth factor, via hypoxia inducible factor 1 α (Hif1α) and STAT3 [182].

The protective effects of melatonin on several liver injuries and diseases are summarized in Figure 2. Some possible mechanisms for melatonin improving liver injuries and diseases are given in Figure 3.

This review provides a detailed and updated description of the protective effects of melatonin against various factor-induced liver injuries and diseases. Melatonin has shown protective effects in liver injuries induced by chemical pollutants, drugs, and alcohol, as well as liver diseases including hepatic steatosis, fatty liver, hepatitis, fibrosis, cirrhosis, and hepatocarcinoma. Melatonin could alleviate liver injuries and diseases by preventing oxidative damage, improving mitochondrial physiology, inhibiting liver neutrophil infiltration, necrosis, and apoptosis, reducing the severity of morphological alterations, and suppressing liver fibrosis. However, related studies of melatonin applied to clinical treatment for liver injuries and diseases are limited. In the future, more clinical trials should be conducted to assess the effects of melatonin in this field. Furthermore, the mechanisms of action should be studied further.