Liver fibrogenesis is initiated by HSC activation, which is the primary effector cell orchestrating the deposition of ECM in the liver structure (Fig. 1). HSCs are located in the perisinusoidal space between the sinusoids and hepatocytes, known as the space of Disse [2]. HSCs activate the immune response through the secretion of cytokines and chemokines and through interactions with immune cells [3]. Activation of HSCs can be provoked by a range of chronic liver inflammatory factors, reactive oxygen species (ROS), and cytokines. Activated HSCs are transformed into myofibroblasts, which have profibrogenic properties; they secrete transforming growth factor β (TGF-β), α-smooth muscle actin, and type I collagen [4].

Immune interactions play an important role in driving fibrogenesis, as persistent inflammation usually precedes fibrosis.

The ECM is a very important component of the liver structure and undergoes highly dynamic changes during synthesis and degradation. Life-threatening pathological conditions arise when ECM remodeling becomes excessive or uncontrolled. HSCs, neutrophils, and macrophages are involved in hepatic ECM degradation. Matrix metalloproteinases (MMPs) are the main enzymes responsible for ECM degradation and TIMPs have the ability to inhibit MMPs [55]. Thus, regulation of the MMP-TIMP balance is critical for efficient ECM remodeling. Activated HSCs not only synthesize and secrete ECM proteins such as type I and type III collagen but also produce MMP1 and MMP13 [56]. Moreover, activated HSCs up-regulate the expression and synthesis of TIMP1 and TIMP2 [57]. TIMP1 not only prevents the degradation of the rapidly increasing ECM by blocking MMPs but also inhibits apoptosis of activated HSCs [58]. The net result is the deposition of mature collagen fibers within the space of Disse, resulting in scarring.

The induction and subsequent spontaneous resolution of fibrosis has been observed in several animal models, and constitute data that are invaluable in determining the underlying biological mechanisms of fibrosis [57,59]. In the face of ECM degradation, fibrotic ECM continues to accumulate in chronic liver injury because of inhibition of MMP activity by myofibroblast-derived TIMP-1 [60]. Several studies investigating the resolution of liver fibrosis in rats showed that levels of TIMP-1 decreased after the cessation of injury [57,61]. As the level of TIMP-1 decreased, hepatic collagenase activity increased and ECM degradation occurred. Subsequent mechanistic studies that altered TIMP to balance MMP levels in situ have confirmed the powerful influence of this ratio on the development and resolution of fibrosis in the liver [62]. In terms of restoration of macrophages, macrophages have also been shown to be pivotal in the resolution of fibrosis, which emphasizes their role as regulators of effective wound healing and organ homeostasis [37]. Located in fibrotic tissue of the liver, macrophages are ideally placed to mediate ECM degradation and are a rich source of fibrolytic MMPs, including MMP12/13 [63,64]. Macrophages also express TNF-related apoptosis-inducing ligand that promotes myofibroblast apoptosis. Furthermore, phagocytosis of apoptotic cells by macrophages induces MMP expression and augments ECM degradation in rodent models of resolving hepatocellular fibrosis [65]. Stabilization of DCs has also been investigated in the context of the resolution of liver fibrosis using Cd11c-diphtheria toxin receptor (DTR) transgenic mice to deplete hepatic DCs during the recovery phase, following CCl₄-mediated injury, as well as the use of adoptive transfer protocols. DCs were shown to mediate ECM degradation, probably through enhanced MMP9 expression [66].

Activation of HSCs in response to chronic liver injury is a key step in the pathogenesis of liver fibrosis. Recently, clinical and experimental studies have demonstrated that fibrosis resolution may occur upon eradication of the liver insult [67]. Experimental models of fibrosis recovery have consistently reported that elimination of activated HSCs by apoptosis or inactivation of fibrolytic pathways led to the regression of fibrosis. This suggests that clearance of activated HSCs is a fundamental step in the onset of fibrosis regression [68]. Myofibroblasts produce fibrous scars in hepatic fibrosis. In the CCl₄ model of liver fibrosis, quiescent HSCs are activated and transformed into myofibroblasts. When the underlying etiological agent is removed, clinical and experimental fibrosis undergo a remarkable regression, with complete disappearance of these myofibroblasts. However, it was shown that a subset of the myofibroblasts escaped apoptosis during regression of liver fibrosis, down-regulated fibrogenic genes, and acquired a phenotype similar to, but distinct from, quiescent HSCs; they were able to more rapidly reactivate into myofibroblasts in response to fibrogenic stimuli and strongly contribute to liver fibrosis. Inactivation of HSCs was associated with up-regulation of antiapoptotic genes, such as Hspa1a/b, which participate in the survival of HSCs in culture and in vivo [69].

In brief, liver fibrosis usually has potential for regression. Early liver fibrosis, which lacks ECM crosslinking and marked angiogenesis, can even reverse into almost normal architecture if the underlying cause is successfully treated [70]. This is considered the best form of antifibrotic therapy and facilitates the subsequent endogenous regulation of wound healing (Fig. 1).

Chronic hepatitis B (CHB) is a significant worldwide problem as CHB patients develop cirrhosis and hepatocellular carcinoma. Standard treatments include pegylated IFN-α and nucleos(t)ide analogues [91]. Several studies have demonstrated that hepatitis B virus (HBV) DNA suppression is associated with biochemical and histological responses. There is currently evidence that these surrogate markers correlate with improved long-term clinical outcome [92]. IFN has been used in the treatment of CHB since the 1980s. Peginterferon therapy has been shown to reduce fibrosis progression in hepatitis B envelop antigen (HBeAg)-positive patients, with a greater response seen in those who sustain HBeAg seroconversion, as well as in HBeAg negative patients with a sustained virologic/biochemical response [72,93]. In one experimental study, IFN-α therapy exhibited antifibrotic activity by inhibiting the production of TGF-β, reducing HSC activation, and stimulating HSC apoptosis in vitro [94]. Another study observed the antifibrotic effect that IFN-γ exerted in liver cells through STAT-1 phosphorylation and impaired TGF-β signaling [95]. Long-term therapy with nucleoside analogues has also been shown to improve liver fibrosis and disease progression. In a 3-year study of lamivudine for hepatitis B treatment, follow-up liver biopsies indicated reversal of cirrhosis in eight of 11 patients (73%) [73]. Entecavir, which is a more potent inhibitor of viral replication in CHB, improves liver fibrosis. In a recent study, 96% of patients had histological improvement after long-term treatment with entecavir. Ten of the 57 patients had advanced fibrosis or cirrhosis (Ishak score 4 to 6) at baseline. All 10 patients achieved at least a 1-point reduction in the Ishak fibrosis score after long-term entecavir therapy [74]. In a more recent 5-year study with tenofovir treatment for chronic HBV infection that included patients with liver cirrhosis at the start of the study, 74% demonstrated extensive histological improvement, such that they were no longer considered to be cirrhotic [75].

Recently, instead of liver biopsy, transient elastography (TE) has been applied for the clinical assessment of liver fibrosis [96,97]. A large prospective cohort study of 426 individuals reported a significant decline in TE values in CHB patients after 3 years of antiviral treatment. However, the significant reduction in TE values at follow-up, compared to those at baseline, was limited in patients who had initially elevated alanine transaminase (ALT) levels [96]. To exclude the confounding effect of high ALT, another study investigated changes in TE values during antiviral treatment in 41 patients with CHB exhibiting low ALT levels (≤ 2 × the upper limit of normal). After 1 to 2 years of antiviral treatment, TE values significantly decreased compared with baseline, whereas ALT levels remained unchanged [97]. Non-invasive serum fibrosis markers were also utilized for the assessment of changes in liver fibrosis. It was reported that fibrosis based on the four factors (FIB-4) and the aspartate aminotransferase-to-platelet ratio index (APRI) were significantly improved in 370 HBV-associated cirrhosis patients who received 2 years of entecavir therapy [98]. These results suggest that potential fibrosis regression could be possible with long-term antiviral treatment and that clinical monitoring using non-invasive methods is useful [99].

Patients with compensated cirrhosis and chronic hepatitis C (CHC) benefit from IFN-based antiviral treatment. Viral eradication can be achieved in up to 40% of patients with genotype 1, and in 70% of patients with genotypes 2 or 3, reducing the risk of developing cirrhosis, hepatic decompensation, and hepatocellular carcinoma [100]. In a 5-year follow-up study of CHC patients with stage 2 or greater fibrosis at baseline, 82% of patients who had achieved sustained virologic response (SVR) after IFN treatment had decreased fibrosis scores. Another study demonstrated a reduction in clinical events after SVR [76,101]. In addition to IFN, excellent efficacy has been reported with several new directly acting antiviral agents (DAA) for HCV. Although little data were reported on follow-up liver biopsy, a recent report showed the possibility of reversal of liver fibrosis and cirrhosis by indirect measurement. TE values as well as FIB-4 and APRI scores were evaluated prior to therapy and within 18 months after DAA therapy; patients who had achieved SVR after DAA therapy showed significant regression of TE values and improvement of FIB-4 and APRI scores [102]. Liver fibrosis and cirrhosis are expected to improve in these patients with resolution of HCV infection.

Clinical evidence for regression of fibrosis in alcoholic liver disease is limited. Results from randomized controlled trials (RCTs) assessing the effects of pharmacological agents on alcoholic fibrosis and cirrhosis have been disappointing. A Cochrane Intervention Review assessing the effect of colchicine for alcoholic and non-alcoholic liver fibrosis and cirrhosis from 15 RCTs reported the absence of statistically significant improvements in any significant clinical outcome, including liver histology [103]. However, there is a slight effect of abstinence of alcohol on clinical outcome. In one study, 100 patients with alcoholic cirrhosis were followed for 7 years after their baseline histological assessment. Abstinence at 1 month post-biopsy was associated with a significant improvement in long-term survival. This article demonstrated that there were benefits of abstinence after longer follow-up, with statistically significant differences in 5-year survival rates between those who abstained and persistent alcoholic drinkers (75% and 50%, respectively; p < 0.002) [77].

There are currently no approved treatments for non-alcoholic fatty liver disease (NAFLD) and therapies are based on targeting risk factors. Although there have been several studies defining the benefits of various pharmacological agents for NAFLD, these studies have been limited by small study populations and short-term follow-up periods [104]. Weight reduction through lifestyle modification is the first treatment strategy in NAFLD patients. Weight reduction is often associated with beneficial effects on multiple components of metabolic syndrome. Histological improvements have also been observed, particularly with respect to steatosis, but evidence of fibrosis regression is controversial. A RCT assessing the effect of weight reduction through lifestyle modification in 31 NASH patients over a 48-week period demonstrated significant improvements in the NASH histological activity score following an average weight loss of 9.3%, but failed to show a significant change in fibrosis [105].

Supplementation with the natural form of vitamin E (800 IU/day) has beneficial effects in patients with NASH, but benefits of pioglitazone are less clear according to the latest findings from the Pioglitazone vs. Vitamin E vs. Placebo for the Treatment of Nondiabetic Patients with Nonalcoholic Steatohepatitis (PIVENS) trial. In this study, 247 adults with biopsy-confirmed NASH without diabetes mellitus were randomly assigned to one of the three following treatment groups: (1) 30 mg per day of pioglitazone in addition to placebo; (2) 800 IU of vitamin E per day in addition to placebo; and (3) two placebo tablets daily. The primary outcome was a composite of improvement in hepatocellular ballooning, no worsening of fibrosis, and improved activity scores for NASH. Twice as many patients treated with vitamin E achieved the primary outcome compared to those who received placebo (43% vs. 19%). Although more patients in the pioglitazone group than the placebo group fulfilled the primary outcome (34% vs. 19%), the difference was not statistically significant [78].

A recent placebo-controlled randomized trial demonstrated that obeticholic acid, a synthetic farnesoid X receptor agonist, was effective in patients with NASH. Patients were treated for 72 weeks and the primary end-point was improvement in histology, as measured by a two-point reduction in a composite activity histological score without worsening of fibrosis. The therapeutic phase of the trial was stopped early partly because a preplanned interim analysis revealed that more patients on obeticholic acid (45%, 50 of 110) than on placebo (21%, 23 of 109) reached the primary endpoint (relative risk, 1.9; 95% confidence interval, 1.3 to 2.8). Thirty-six of 102 obeticholic acid-treated patients (35%) demonstrated fibrosis regression by one stage or more compared to 19 of 98 placebo-treated patients (19%). Although the study was stopped after the interim analysis, the main result of this study demonstrates a clear improvement in all histological features of NASH, including steatosis, inflammation, and liver-cell injury, together with a reduction in aminotransferases, biochemical markers of hepatic damage [106].

Approximately 40% of patients with autoimmune hepatitis develop cirrhosis under current therapies. Although the course is variable depending on the period of observation, the annual occurrence of cirrhosis is estimated at 3% per year [107,108]. Several studies have not only demonstrated the antifibrotic effects of immunosuppressive therapy in autoimmune hepatitis but have also strengthened the association between the indices of hepatic inflammation and the progression of liver fibrosis [79,80]. Fibrosis scores using the Ishak system improved in 46 of 87 treated patients (53%) with autoimmune hepatitis during 63 months, and the histological activity index decreased concurrently [79]. They suggested that improvement of hepatic fibrosis is possible in the majority of treated patients with autoimmune hepatitis and that failure to suppress liver inflammation worsens fibrosis [109].

The only clinically approved medical treatment for primary biliary cirrhosis (PBC) is ursodeoxycholic acid (UDCA) [110,111]. However, there are controversies regarding the interpretation of current evidence. In several studies with crossover from placebo or no UDCA treatment, the crossover patients’ conditions deteriorated despite using UDCA [112]. A Cochrane Review evaluating 16 RCTs using UDCA versus placebo revealed that almost half of these trials had a high risk of bias and concluded that UDCA did not significantly improve liver histology and had no demonstrable effect on improving mortality [113]. Nevertheless, UDCA may have benefits in early stage and asymptomatic PBC. In the asymptomatic PBC cohort described by Prince et al. [114], 45% of the patients taking UDCA did not develop liver-related symptoms during a median follow-up of 7.4 years.

The role of immunosuppressive agents in PBC remains controversial. A few studies evaluating methotrexate have presented conflicting results and some studies suggest that methotrexate may worsen mortality [115].

Obeticholic acid, a derivative of chenodeoxycholic acid, has, unlike UDCA, strong activating effects on the nuclear receptor farnesoid X receptor in phase II results [116]. In a recent clinical trial with obeticholic acid as therapy for PBC, favorable effects were also observed in PBC patients with an inadequate response to UDCA [117]. Alkaline phosphatase, γ glutamyl transpeptidase, and alanine aminotransferase levels were significantly improved in patients receiving obeticholic acid compared with those in the placebo group. In this study, the treatment period was only 3 months and liver biopsies were not obtained to identify histologic changes. Subjects were allowed to participate in an open-label extension trial, which demonstrated sustained decreases in liver enzyme levels over 12 months [117]. Future trials to determine the beneficial effects of obeticholic acid on hepatic fibrosis in patients with primary cirrhosis are warranted.

Few studies have identified a regression of fibrosis and reversal of cirrhosis using liver biopsy following phlebotomy in patients with hereditary hemochromatosis [118]. The most recent study addressing reversibility of liver fibrosis or cirrhosis assessed histological outcome following venesection in 36 cases of C282Y homozygotes with documented F3 or F4 fibrosis on index biopsy. The 36 patients were enrolled from C282Y homozygotes with either severe fibrosis or cirrhosis (F3 or F4 fibrosis, staged according to the METAVIR grading system). When defining regression of fibrosis as a decrease of at least 2 METAVIR units, fibrosis regressed in nine of 13 patients (69%) with stage F3 and in eight of 23 patients (35%) with stage F4 fibrosis [119].