Molecular Mechanisms Of Liver Fibrosis Research Articles

Natural Products in Liver Fibrosis Management: A Five-year Review.

Liver fibrosis, characterized by the overproduction of extracellular matrix proteins within liver tissue, poses a rising global health concern. However, no approved antifibrotic drugs are currently available, highlighting the critical need for understanding the molecular mechanisms of liver fibrosis. This knowledge could not only aid in developing therapies but also enable early intervention, enhance disease prediction, and improve our understanding of the interaction between various underlying conditions and the liver. Notably, natural products used in traditional medicine systems worldwide and demonstrating diverse biochemical and pharmacological activities are increasingly recognized for their potential in treating liver fibrosis. This review aims to comprehensively understand liver fibrosis, emphasizing the molecular mechanisms and advancements in exploring natural products' antifibrotic potential over the past five years. It also acknowledges the challenges in their development and seeks to underscore their potency in enhancing patient prognosis and reducing the global burden of liver disease.

Relationships between Cxcl12, Tweak, Notch1, and Yap mRNA Expression Levels in Molecular Mechanisms of Liver Fibrogenesis

Current data on the molecular mechanisms of liver fibrosis and cirrhosis fail to fully explain all stages of their development. Interactions between individual genes and signaling pathways are known to play an important role in their functions. However, data on their relationships are insufficient and often contradictory. For the first time, mRNA expression of Notch1, Notch2, Yap1, Tweak (Tnfsf12), Fn14 (Tnfrsf12a), Ang, Vegfa, Cxcl12 (Sdf), Nos2, and Mmp-9 was studied in detail at several stages of thioacetamide-induced liver fibrosis in Wistar rats. A factor analysis isolated three factors, which combined highly correlated target genes. The first factor included four genes: Cxcl12 (r = 0.829, p < 0.05), Tweak (r = 0.841, p < 0.05), Notch1 (r = 0.848, p < 0.05), and Yap1 (r = 0.921, p < 0.05). The second factor described the correlation between Mmp-9 (r = 0.791, p < 0.05) and Notch2 (r = 0.836, p < 0.05). The third factor included Ang (r = 0.748, p < 0.05) and Vegfa (r = 0.679, p < 0.05). The Nos2 and Fn14 genes were not included in any of the factors. The gene grouping by mRNA expression levels made it possible to assume a pathogenetic relationship between their products in the development of fibrotic changes due to liver toxicity.

Neutrophil extracellular traps promote MASH fibrosis by metabolic reprogramming of HSC.

Metabolic dysfunction-associated steatohepatitis (MASH) fibrosis is a reversible stage of liver disease accompanied by inflammatory cell infiltration. Neutrophils extrude a meshwork of chromatin fibers to establish neutrophil extracellular traps (NETs), which play important roles in inflammatory response regulation. Our previous work demonstrated that NETs promote HCC in MASH. However, it is still unknown if NETs play a role in the molecular mechanisms of liver fibrosis. Following 12 weeks of Western diet/carbon tetrachloride, MASH fibrosis was identified in C57BL/6 mice with increased NET formation. However, NET depletion using DNase I treatment or mice knocked out for peptidyl arginine deaminase type IV significantly attenuated the development of MASH fibrosis. NETs were demonstrated to induce HSCs activation, proliferation, and migration through augmented mitochondrial and aerobic glycolysis to provide additional bioenergetic and biosynthetic supplies. Metabolomic analysis revealed markedly an altered metabolic profile upon NET stimulation of HSCs that were dependent on arachidonic acid metabolism. Mechanistically, NET stimulation of toll-like receptor 3 induced cyclooxygenase-2 activation and prostaglandin E2 production with subsequent HSC activation and liver fibrosis. Inhibiting cyclooxygenase-2 with celecoxib reduced fibrosis in our MASH model. Our findings implicate NETs playing a critical role in the development of MASH hepatic fibrosis by inducing metabolic reprogramming of HSCs through the toll-like receptor 3/cyclooxygenase-2/cyclooxygenase-2 pathway. Therefore, NET inhibition may represent an attractive treatment target for MASH liver fibrosis.

Endothelial anthrax toxin receptor 2 plays a protective role in liver fibrosis.

Hepatocellular carcinoma is one of the leading cancers worldwide and is a potential consequence of fibrosis. Therefore, the identification of key cellular and molecular mechanisms involved in liver fibrosis is an important goal for the development of new strategies to control liver-related diseases. Here, single-cell RNA sequencing data (GSE136103 and GES181483) of clinical liver non-parenchymal cells were analyzed to identify cellular and molecular mechanisms of liver fibrosis. The proportion of endothelial subpopulations in cirrhotic livers was significantly higher than that in healthy livers. Gene ontology and gene set enrichment analysis of differentially expressed genes in the endothelial subgroups revealed that extracellular matrix (ECM)-related pathways were significantly enriched. Since anthrax toxin receptor 2 (ANTXR2) interacts with the ECM, the expression of ANTXR2 in the liver endothelium was analyzed. ANTXR2 expression in the liver endothelium of wild-type (WT) mice significantly decreased after a 4-time sequential injection of carbon tetrachloride (CCl4) to induce liver fibrosis. Next, conditional knockout mice selectively lacking Antxr2 in endothelial cells were generated. After endothelial-specific Antxr2 knockout mice were subjected to the CCl4 model, the degree of liver fibrosis in the knockout group was significantly more severe than that in the control group. In addition, ANTXR2 in human umbilical vein endothelial cells promoted matrix metalloproteinase 2 (MMP2) activation to degrade the ECM in vitro. Finally, endothelial-specific overexpression of Antxr2 alleviated the development of liver fibrosis following adeno-associated virus treatment. Collectively, these results suggested that endothelial ANTXR2 plays a protective role in liver fibrosis. This function of ANTXR2 may be achieved by promoting MMP2 activation to degrade the ECM.

Cellular and Molecular Mechanisms of Liver Fibrosis in Patients with NAFLD.

The expression of immune- and cancer-related genes was measured in liver biopsies from 107 NAFLD patients. The strongest difference in overall gene expression was between liver fibrosis stages F3 and F4, with 162 cirrhosis-associated genes identified. Strong correlations with fibrosis progression from F1 to F4 were observed for 91 genes, including CCL21, CCL2, CXCL6, and CCL19. In addition, the expression of 21 genes was associated with fast progression to F3/F4 in an independent group of eight NAFLD patients. These included the four chemokines, SPP1, HAMP, CXCL2, and IL-8. A six-gene signature including SOX9, THY-1, and CD3D had the highest performance detecting the progressors among F1/F2 NAFLD patients. We also characterized immune cell changes using multiplex immunofluorescence platforms. Fibrotic areas were strongly enriched in CD3+ T cells compared to CD68+ macrophages. While the number of CD68+ macrophages increased with fibrosis severity, the increase in CD3+ T-cell density was more substantial and progressive from F1 to F4. The strongest correlation with fibrosis progression was observed for CD3+CD45R0+ memory T cells, while the most significant increase in density between F1/F2 and F3/F4 was for CD3+CD45RO+FOXP3+CD8- and CD3+CD45RO-FOXP3+CD8- regulatory T cells. A specific increase in the density of CD68+CD11b+ Kupffer cells with liver fibrosis progression was also observed.

The Molecular Mechanisms of Liver Fibrosis and Its Potential Therapy in Application.

Liver fibrosis results from repeated and persistent liver damage. It can start with hepatocyte injury and advance to inflammation, which recruits and activates additional liver immune cells, leading to the activation of the hepatic stellate cells (HSCs). It is the primary source of myofibroblasts (MFs), which result in collagen synthesis and extracellular matrix protein accumulation. Although there is no FDA and EMA-approved anti-fibrotic drug, antiviral therapy has made remarkable progress in preventing or even reversing the progression of liver fibrosis, but such a strategy remains elusive for patients with viral, alcoholic or nonalcoholic steatosis, genetic or autoimmune liver disease. Due to the complexity of the etiology, combination treatments affecting two or more targets are likely to be required. Here, we review the pathogenic mechanisms of liver fibrosis and signaling pathways involved, as well as various molecular targets for liver fibrosis treatment. The development of efficient drug delivery systems that target different cells in liver fibrosis therapy is also summarized. We highlight promising anti-fibrotic events in clinical trial and preclinical testing, which include small molecules and natural compounds. Last, we discuss the challenges and opportunities in developing anti-fibrotic therapies.

Anti-fibrotic Therapy for Chronic Liver Diseases Review

Liver fibrosis reflects tissue scarring in the liver because of the accumulation of over the top extracellular matrix in light of constantly persistent liver injury. Hepatocyte cell death can trigger capillarization of liver sinusoidal endothelial cells, stimulation of immune cells including macrophages and Kupffer cells, and initiation of hepatic stellate cells (HSCs), bringing about progression of liver fibrosis. Liver cirrhosis is the terminal condition of liver fibrosis and is related with serious complications, like liver failure, portal hypertension, and liver malignant growth. In any case, compelling treatment for cirrhosis has not yet been set up, and liver transplantation is the main revolutionary treatment for severe cases. Studies examining HSC activation and guideline of collagen creation in the liver have made leap forwards in ongoing many years that have advanced the information with respect to liver fibrosis pathophysiology. In this review, we sum up molecular mechanisms of liver fibrosis and discuss the improvement of novel anti- fibrotic treatments.

Anti-fibrotic treatments for chronic liver diseases: The present and the future.

Liver fibrosis reflects tissue scarring in the liver due to the accumulation of excessive extracellular matrix in response to chronically persistent liver injury. Hepatocyte cell death can trigger capillarization of liver sinusoidal endothelial cells, stimulation of immune cells including macrophages and Kupffer cells, and activation of hepatic stellate cells (HSCs), resulting in progression of liver fibrosis. Liver cirrhosis is the terminal state of liver fibrosis and is associated with severe complications, such as liver failure, portal hypertension, and liver cancer. Nevertheless, effective therapy for cirrhosis has not yet been established, and liver transplantation is the only radical treatment for severe cases. Studies investigating HSC activation and regulation of collagen production in the liver have made breakthroughs in recent decades that have advanced the knowledge regarding liver fibrosis pathophysiology. In this review, we summarize molecular mechanisms of liver fibrosis and discuss the development of novel anti-fibrotic therapies.

Ubiquitin-Like Post-Translational Modifications (Ubl-PTMs): Small Peptides with Huge Impact in Liver Fibrosis

Liver fibrosis is characterized by the excessive deposition of extracellular matrix proteins including collagen that occurs in most types of chronic liver disease. Even though our knowledge of the cellular and molecular mechanisms of liver fibrosis has deeply improved in the last years, therapeutic approaches for liver fibrosis remain limited. Profiling and characterization of the post-translational modifications (PTMs) of proteins, and more specifically NEDDylation and SUMOylation ubiquitin-like (Ubls) modifications, can provide a better understanding of the liver fibrosis pathology as well as novel and more effective therapeutic approaches. On this basis, in the last years, several studies have described how changes in the intermediates of the Ubl cascades are altered during liver fibrosis and how specific targeting of particular enzymes mediating these ubiquitin-like modifications can improve liver fibrosis, mainly in in vitro models of hepatic stellate cells, the main fibrogenic cell type, and in pre-clinical mouse models of liver fibrosis. The development of novel inhibitors of the Ubl modifications as well as novel strategies to assess the modified proteome can provide new insights into the overall role of Ubl modifications in liver fibrosis.

Focal Adhesion Kinase Regulates Hepatic Stellate Cell Activation and Liver Fibrosis

Understanding the underlying molecular mechanisms of liver fibrosis is important to develop effective therapy. Herein, we show that focal-adhesion-kinse (FAK) plays a key role in promoting hepatic stellate cells (HSCs) activation in vitro and liver fibrosis progression in vivo. FAK activation is associated with increased expression of α-smooth muscle actin (α-SMA) and collagen in fibrotic live tissues. Transforming growth factor beta-1 (TGF-β1) induces FAK activation in a time and dose dependent manner. FAK activation precedes the α-SMA expression in HSCs. Inhibition of FAK activation blocks the α-SMA and collagen expression, and inhibits the formation of stress fibers in TGF-β1 treated HSCs. Furthermore, inhibition of FAK activation significantly reduces HSC migration and small GTPase activation, and induces apoptotic signaling in TGF-β1 treated HSCs. Importantly, FAK inhibitor attenuates liver fibrosis in vivo and significantly reduces collagen and α-SMA expression in an animal model of liver fibrosis. These data demonstrate that FAK plays an essential role in HSC activation and liver fibrosis progression, and FAK signaling pathway could be a potential target for liver fibrosis.

Optimized Mouse Models for Liver Fibrosis.

Fibrosis is the excessive accumulation of extracellular matrix components due to chronic injury, with collagens as predominant structural components. Liver fibrosis can progress to cirrhosis, which is characterized by a severe distortion of the delicate hepatic vascular architecture, the shunting of the blood supply away from hepatocytes and the resultant functional liver failure. Cirrhosis is associated with a highly increased morbidity and mortality and represents the major hard endpoint in clinical studies of chronic liver diseases. Moreover, cirrhosis is a strong cofactor of primary liver cancer. In vivo models are indispensable tools to study the cellular and molecular mechanisms of liver fibrosis and to develop specific antifibrotic therapies towards clinical translation. Here, we provide a detailed description of select optimized mouse models of liver fibrosis and state-of-the-art fibrosis readouts.

Liver fibrosis and hepatic stellate cells: Etiology, pathological hallmarks and therapeutic targets.

Liver fibrosis is a reversible wound-healing process aimed at maintaining organ integrity, and presents as the critical pre-stage of liver cirrhosis, which will eventually progress to hepatocellular carcinoma in the absence of liver transplantation. Fibrosis generally results from chronic hepatic injury caused by various factors, mainly viral infection, schistosomiasis, and alcoholism; however, the exact pathological mechanisms are still unknown. Although numerous drugs have been shown to have antifibrotic activity in vitro and in animal models, none of these drugs have been shown to be efficacious in the clinic. Importantly, hepatic stellate cells (HSCs) play a key role in the initiation, progression, and regression of liver fibrosis by secreting fibrogenic factors that encourage portal fibrocytes, fibroblasts, and bone marrow-derived myofibroblasts to produce collagen and thereby propagate fibrosis. These cells are subject to intricate cross-talk with adjacent cells, resulting in scarring and subsequent liver damage. Thus, an understanding of the molecular mechanisms of liver fibrosis and their relationships with HSCs is essential for the discovery of new therapeutic targets. This comprehensive review outlines the role of HSCs in liver fibrosis and details novel strategies to suppress HSC activity, thereby providing new insights into potential treatments for liver fibrosis.

Recent advancement of molecular mechanisms of liver fibrosis.

Liver fibrosis occurs in response to any etiology of chronic liver injury including hepatitis B and C, alcohol consumption, fatty liver disease, cholestasis, and autoimmune hepatitis. Hepatic stellate cells (HSCs) are the primary source of activated myofibroblasts that produce extracellular matrix (ECM) in the liver. Various inflammatory and fibrogenic pathways contribute to the activation of HSCs. Recent studies also discovered that liver fibrosis is reversible and activated HSCs can revert to quiescent HSCs when causative agents are removed. Although the basic research for liver fibrosis has progressed remarkably, sensitive and specific biomarkers as non-invasive diagnostic tools, and effective anti-fibrotic agents have not been developed yet. This review highlights the recent advances in cellular and molecular mechanisms of liver fibrosis, especially focusing on origin of myofibroblasts, inflammatory signaling, autophagy, cellular senescence, HSC inactivation, angiogenesis, and reversibility of liver fibrosis.

Abstract 5349: The role of growth hormone receptor in liver fibrosis and cancer

Abstract Liver fibrosis is defined as the pathological excessive deposition of extracellular matrix proteins which contributes to a disruption of normal liver architecture. Fibrosis can progress to cirrhosis, which can eventually result in hepatocellular carcinoma. Over the past decades our understanding of the cellular and molecular mechanisms of liver fibrosis has advanced greatly. Activated hepatic stellate cells, myofibroblasts of bone marrow origin and portal fibroblasts have all been identified as major contributors to fibrosis. Recently, growth hormone resistance and low serum levels of IGF-1 have also been associated with liver cirrhosis in humans, indicating a role for growth hormone receptor, which itself controls various cellular functions including the transcription of IGF-1 through Stat 5 signaling. Furthermore, supplementation of recombinant IGF-1 in cirrhotic animal models was shown to reduce disease severity. In order to elucidate whether the GHR plays an active role in the establishment of fibrotic liver diseases or rather represents a major consequence of this illness, we crossed mice lacking the Ghr/bp gene (Ghr -/-) with Mdr2 knockout mice (Mdr2-/-), a mouse model of inflammatory cholestasis and liver fibrosis. Our results show that Ghr-/-;Mdr2-/- mice display deregulated bile acid homeostasis and increased serum markers associated with inflammation and fibrosis. Bile duct proliferation and extensive collagen deposition were also observed in Ghr-/-;Mdr2-/- relative to Mdr2-/- mice. Additionally, compared to control mice a pronounced down regulation of the hepato-protective genes Hnf6, Egfr and Igf-1 was seen in Ghr-/-;Mdr2-/- animals, which also displayed significantly increased apoptosis. Moreover, single knockout mice (Ghr-/-) developed bile infacts when fed with 1% cholic acid compared to their wildtype littermates, indicating that loss of GHR renders hepatocytes more susceptible to toxic bile acid accumulation. Surprisingly and despite their severe fibrotic phenotype Ghr -/-; Mdr2 -/- mice showed a significant decrease in tumor incidence compared to Mdr2 -/- mice, indicating that loss of GHR signaling may slow the progression from fibrosis/cirrhosis to cancer in the liver. Our findings suggest that loss of GHR signaling results in increased liver injury in the Mdr2 -/- mouse model of inflammatory cholestasis and liver fibrosis, signifying the possible therapeutic value of this pathway in the development of liver fibrosis treatments. Citation Format: Patricia Stiedl, Leander Blaas, Viktoria Stanek, Jasmin Svinka, Robert Mc Mahon, Gernot Zollner, Thierry Claudel, Mathias Mueller, Wolfgang Mikulits, Harald Esterbauer, Robert Eferl, Johannes Haybaeck, Michael Trauner, Emilio Casanova. The role of growth hormone receptor in liver fibrosis and cancer. [abstract]. In: Proceedings of the 105th Annual Meeting of the American Association for Cancer Research; 2014 Apr 5-9; San Diego, CA. Philadelphia (PA): AACR; Cancer Res 2014;74(19 Suppl):Abstract nr 5349. doi:10.1158/1538-7445.AM2014-5349

Molecular mechanisms of liver fibrosis in HIV/HCV coinfection.

Chronic hepatitis C virus (HCV) infection is an important cause of morbidity and mortality in people coinfected with human immunodeficiency virus (HIV). Several studies have shown that HIV infection promotes accelerated HCV hepatic fibrosis progression, even with HIV replication under full antiretroviral control. The pathogenesis of accelerated hepatic fibrosis among HIV/HCV coinfected individuals is complex and multifactorial. The most relevant mechanisms involved include direct viral effects, immune/cytokine dysregulation, altered levels of matrix metalloproteinases and fibrosis biomarkers, increased oxidative stress and hepatocyte apoptosis, HIV-associated gut depletion of CD4 cells, and microbial translocation. In addition, metabolic alterations, heavy alcohol use, as well drug use, may have a potential role in liver disease progression. Understanding the pathophysiology and regulation of liver fibrosis in HIV/HCV co-infection may lead to the development of therapeutic strategies for the management of all patients with ongoing liver disease. In this review, we therefore discuss the evidence and potential molecular mechanisms involved in the accelerated liver fibrosis seen in patients coinfected with HIV and HCV.

Recent advances in our understanding of the molecular mechanisms of liver fibrosis

近30年来,肝纤维化的研究一直是肝病领域内的重点课题.目前已经明确:肝纤维化是细胞外基质(extracellular matrix,ECM)合成与降解失衡的动态过程;肝纤维化及早期肝硬化是可逆转的[1];纤维化ECM是由肌成纤维细胞(myofibroblast,MFB)产生的,MFB主要来源于活化的肝星状细胞(hepatic stellate cells,HSC)和汇管区成纤维细胞,少数来源于骨髓基质的纤维细胞,以及由肝细胞和肝内胆管上皮细胞经历上皮-间质细胞转化(epithelial-to-mesenchymal transition,EMT)而来[2-3];MFB及其产物是抗肝纤维化治疗的主要靶点.基于目前对肝纤维化细胞分子机制的认识,在实验性抗纤维化方面取得了一定成果. 关键词：肝硬化;细胞;分子

Testing Beneficial Therapy in Human Cirrhosis Using Animal Models of Cirrhosis

The study by Minuk and colleagues entitled “Daily Ciprofloxacin Treatment for Patients with Advanced Liver Disease Awaiting Liver Transplantation Reduces Hospitalizations” [1] tested the hypothesis that patients on the liver transplant list may benefit from antibiotics as a method of enhancing hepatic regeneration and improving liver function. The authors had previously shown in a rat model of acute and subacute liver failure that antibiotics improved survival [2, 3] and that antibiotics appeared to also improve survival in a model of chronic liver injury [4]. This benefit correlated in these animal models with improvement in markers of hepatic regeneration. In the current study, the authors asked whether the same benefit might be found in cirrhotic patients on the liver transplant waiting list. This single-site, prospective, randomized, double-blind study measured routine markers of hepatic function (albumin, bilirubin, and international normalized ratio for prothrombin time [INR]), markers of hepatic inflammation (aspartate aminotransferase [AST] and alanine aminotransferase [ALT]), and clinical outcomes (hospitalizations, hepatic encephalopathy, etc.) after 1 or 3 months of treatment with placebo or ciprofloxacin 250–500 mg twice daily. Results showed no systematic benefit at 1 or 3 months in markers of hepatic function or inflammation, and a significant improvement in albumin at 1 month was not confirmed at 3 months. However, it should be noted that more precise measurements of hepatic function [5, 6] or markers of regeneration might have shown subclinical benefits that would have been encouraging for further studies. Potential benefits in hospitalizations and clinical outcomes were also assessed. There were fewer hospitalizations for hepatic encephalopathy among subjects receiving ciprofloxacin, but little benefit for other clinical outcomes. As the authors note, antibiotics are helpful in treating encephalopathy and in prophylaxis against spontaneous bacterial peritonitis [7–10]. The effect of antibiotics on improvement in survival among variceal bleeders has been profound [11]. Thus, the reduction in hospitalizations among patients receiving antibiotics in this study is not surprising, and hepatic regeneration is not required to explain this improvement. Thus, the benefits of antibiotics in animal models of acute and chronic liver injury were not confirmed in this clinical trial among patients with advanced cirrhosis on the liver transplant waiting list. Animal models have been very useful in the evaluation of the pathophysiology of portal hypertension, ascites and hepatic fibrosis [12–17]. Why was so little benefit observed when antibiotics were used in humans with cirrhosis as compared with animal models? The answer partially lies in the difference between changes in pathophysiology in animal models of acute liver injury and humans with cirrhosis, who have dense hepatic fibrosis that develops over long periods of time and resolves slowly when the insult is stopped [18, 19]. By contrast, animal models of cirrhosis generally require continued liver injury to produce cirrhosis, and fibrosis resolves rapidly if the insult is stopped [12–17]. Furthermore, there is often a complex interaction of factors contributing to hepatic injury that includes bacterial products such as endotoxin from the gut that may be less important in man [12–14]. Antibiotics markedly decrease injury in most animal models [12–14]. Therefore, study of the pathophysiology of liver injury and complications of liver disease in animal models has been very valuable, but the regression of liver fibrosis differs between humans and animals. Thus, findings in animal models must be confirmed in clinical settings, and we applaud the authors for testing their hypothesis in humans [1]. Unfortunately, this study shows that antibiotics do not enhance hepatic regeneration or improve clinical outcomes by means of regeneration in patients on the liver transplant list. According to several recent studies, there is no experimental model that completely reproduces human liver fibrosis [12–14]. Since there are contraindications to serial liver biopsies in humans with liver disease, studies of genetic and molecular aspects of liver injury and fibrosis should continue. An initial approach should involve exploration of the molecular mechanisms of liver fibrosis in different diseases [20]. This might elucidate areas of potential efficacy of ciprofloxacin and other fluoroquinolones. Ultimately, all benefits in animals must be confirmed by clinical trials in man.

Therapeutical targets for revert liver fibrosis

Liver fibrosis is the common response to chronic liver injury, ultimately leading to cirrhosis and its complications: portal hypertension, liver failure, hepatic encephalopathy, and hepatocellular carcinoma and others. Efficient and well-tolerated antifibrotic drugs are still lacking, and current treatment of hepatic fibrosis is limited to withdrawal of the noxious agent. Efforts over the past decade have mainly focused on fibrogenic cells generating the scarring response, although promising data on inhibition of parenchymal injury or reduction of liver inflammation have also been obtained. A large number of approaches have been validated in culture studies and in animal models, and several clinical trials are underway or anticipated for a growing number of molecules. This review highlight recent advances in the molecular mechanisms of liver fibrosis and discusses mechanistically based strategies that have recently emerged.

Blancos terapéuticos potenciales para revertir la cirrosis hepática

Liver fibrosis is the common response to chronic liver injury, ultimately leading to cirrhosis and its complications: portal hypertension, liver failure, hepatic encephalopathy, and hepatocellular carcinoma and others. Efficient and well-tolerated antifibrotic drugs are still lacking, and current treatment of hepatic fibrosis is limited to withdrawal of the noxious agent. Efforts over the past decade have mainly focused on fibrogenic cells generating the scarring response, although promising data on inhibition of parenchymal injury or reduction of liver inflammation have also been obtained. A large number of approaches have been validated in culture studies and in animal models, and several clinical trials are underway or anticipated for a growing number of molecules. This review highlight recent advances in the molecular mechanisms of liver fibrosis and discusses mechanistically based strategies that have recently emerged.

Hepatic fibrosis: molecular mechanisms and drug targets.

Liver fibrosis is the common response to chronic liver injury, ultimately leading to cirrhosis and its complications, portal hypertension, liver failure, and hepatocellular carcinoma. Efficient and well-tolerated antifibrotic drugs are currently lacking, and current treatment of hepatic fibrosis is limited to withdrawal of the noxious agent. Efforts over the past decade have mainly focused on fibrogenic cells generating the scarring response, although promising data on inhibition of parenchymal injury and/or reduction of liver inflammation have also been obtained. A large number of approaches have been validated in culture studies and in animal models, and several clinical trials are underway or anticipated for a growing number of molecules. This review highlights recent advances in the molecular mechanisms of liver fibrosis and discusses mechanistically based strategies that have recently emerged.