Effect of ribavirin on the frequency of RNase L cleavage sites within the hepatitis C viral genome

Summary. The mechanisms of synergy in antiviral activity of interferon‐α and ribavirin in treating chronic hepatitis C virus (HCV) infection are still unknown. Interferon‐α indirectly induces cleavage of viral RNA by RNase L at UU/UA dinucleotides. There is evidence that HCV genomes with a higher number of UU/UA dinucleotides are more sensitive to interferon‐α. As a guanosine analogue, ribavirin exerts a mutagenic effect promoting G‐to‐A and C‐to‐U transitions. This study investigates whether ribavirin‐induced mutagenesis causes a higher frequency of UU/UA dinucleotides in the viral progeny sequences. Increased mutational frequencies in favour of G‐to‐A and C‐to‐U transitions during ribavirin treatment was reported by Hofmann et al. (Gastroenterology 2007;132:921–930). Overall, 937 nucleotide sequences from that publication were reanalysed for RNase L cleavage sites. These included HCV NS3 quasispecies from three patients with ribavirin monotherapy and NS5B quasispecies from patients who received ribavirin alone (n = 7) or in combination with interferon‐α (n = 7) at baseline and during treatment; NS5B quasispecies from a subgenomic HCV replicon system after 24, 48 and 72 h of cultivation with or without ribavirin or with levovirin. For NS3 quasispecies during ribavirin monotherapy and NS5B quasispecies from patients who received ribavirin alone or in combination with interferon‐α, analysis of RNase L cleavage sites did not reveal changes during treatment or differences between treatment regimes. Similarly, RNaseL cleavage sites from NS5B quasispecies of the HCV replicon did not differ significantly between time points or treatments. In conclusion, Ribavirin‐induced mutagenesis did not increase RNase L cleavage sites (UU/UA dinucleotides) within the HCV NS3 or NS5B encoding regions.     

Evolution of hepatitis C virus genome in chronically infected patients receiving ribavirin monotherapy

Recent results of clinical trials suggest that combination of interferon and ribavirin exhibits an enhanced antiviral effect in the treatment of chronic hepatitis C. To investigate the effect of ribavirin on hepatitis C virus (HCV) infection, we analysed the evolution of the genetic heterogeneity of HCV in relation to the anti-HCV humoral response in patients treated by ribavirin alone. The study population included 35 patients with liver biopsy proven chronic hepatitis C infected with HCV genotype 1. Among them, 26 were treated with ribavirin for at least 12 months and nine untreated patients served as a control group. Serum samples were analysed before and at 6 and 12 months of therapy. Three regions of the HCV genome, i.e. HVR1, a domain of NS5A including part of the interferon sensitivity determining region (ISDR), and a segment of NS5B, were amplified by RT-PCR using specific primers. The PCR products were then studied using single-strand conformation polymorphism (SSCP) analysis followed by either direct sequencing, or cloning and sequencing. In parallel, the humoral anti-E1 response was studied using an ELISA (Innotest HCV E1Ab, Innogenetics). The results of HCV genome analysis showed no significant effect on the amino acid sequence evolution of the HVR1, NS5A and NS5B regions of HCV. Analysis of a phylogenetic tree from the major quasispecies variants showed the absence of correlation with ribavirin response, and the absence of selection of viral strains during ribavirin treatment. A trend towards a decrease in the anti-E1 Ab response was also observed. Altogether these results suggest that ribavirin may not exhibit a direct antiviral effect, but may trigger a favourable response to interferon by modulating the immune response against HCV.     

Chronic hepatitis C

The goal of antiviral therapy for patients with chronic hepatitis C virus (HCV) infection is to attain a sustained virologic response (SVR), which is defined as undetectable serum HCV-RNA levels at 6 months after the cessation of treatment. Major improvements in antiviral therapy for chronic hepatitis C have occurred in the past decade. The addition of ribavirin to interferon-alfa therapy and the introduction of pegylated interferon (PEG-IFN) have substantially improved SVR rates in patients with chronic hepatitis C. The optimization of HCV therapy with PEG-IFN and ribavirin continues to evolve. Studies are ongoing that use viral kinetics to tailor therapy to an individual's antiviral response and determine the ideal length of treatment to maximize the chance of SVR. Improved SVR can be achieved with new specific inhibitors that target the HCV NS3/4A protease and the NS5B polymerase. Several long-term follow-up studies have shown that SVR, when achieved, is associated with a very low risk of virologic relapse. Furthermore, antiviral therapy can reduce the morbidity and mortality rates associated with chronic hepatitis C by reducing fibrosis progression, the incidence of cirrhosis, and hepatocellular carcinoma.     

New treatments for chronic hepatitis C: An overview for paediatricians

Pegylated interferon(IFN)α-2a or 2b in combination with ribavirin for children aged 3 years and older is the standard treatment for paediatric chronic hepatitis C.This treatment regimen was developed firstly in adults.In recent years,a number of direct-acting antiviral agents(DAAs)are under development for treatment of chronic hepatitis C virus(HCV)infection.These agents block viral replication inhibiting directly one of the several steps of HCV lifecycle.DAAs are classified into several categories based on their molecular target:HCV NS3/4A protease inhibitors,HCV NS5B polymerase inhibitors and HCV NS5A inhibitors.Other promising compounds are cyclophilin A inhibitors,mi-RNA122and IFN-λ.Several new drugs associations will be developed in the near future starting from the actual standard of care.IFN-based and IFN-free regimens are being studied in adults.In this constantly evolving scenario new drug regimens targeted and suitable for children would be possible in the next future.Especially for children,it is crucial to identify the right combination of drugs with the highest potency,barrier toresistance and the best safety profile.     

Association between HCV amino acid substitutions and outcome of peginterferon and ribavirin combination therapy in HCV genotype 1b and high viral load

Background and Aim: We prospectively compared the sensitivity to interferon (IFN) and the efficacy of antiviral combination therapy with peginterferon (PEG‐IFN) and ribavirin for chronic hepatitis C virus (HCV) genotype 1b infection according to the amino acid sequences of the HCV core, E1, and NS5A regions reported to be associated with the outcome of antiviral therapy. Methods: A total of 107 patients with HCV genotype 1b were investigated. All patients received combination therapy with PEG‐IFN alpha‐2b and ribavirin. Amino acids 70 and 91 (core), 139 (E1), and 2209–2248 (NS5A) of HCV were analyzed by direct nucleotide sequencing. Results: The reduction in HCV RNA concentration at 24 h after a single administration of conventional IFN‐alpha and after the start of combination therapy was significantly less marked, and rates of complete early virologic response, end‐of‐treatment response, and sustained virologic response (SVR) were significantly lower (all P < 0.0001) in patients with glutamine at amino acid 70 (n = 29) than in those with arginine at that position (n = 70). We found no differences associated with the other amino acid positions. Amino acid 70 was an independent factor for the responses to the therapy in multivariate analysis. Conclusion: The identity of amino acid 70 of the HCV core region affected the sensitivity to IFN; patients with glutamine at amino acid 70 of HCV showed resistance to IFN. Consequently, it strongly affected the outcome of combination therapy with PEG‐IFN and ribavirin in Japanese patients with HCV genotype 1b.     

Interferon and ribavirin therapy does not select for resistance mutations in hepatitis C virus polymerase

Summary.  Ribavirin has a minor and transient effect on hepatitis C virus (HCV) replication and has been suggested to select a novel mutation, F415Y, in the RNA-dependent RNA polymerase of subtype 1a viruses. Twenty-nine patients with chronic hepatitis C (subtyped by INNO LiPA as 1a, 17; 1b, 11; 1a/1b, 1) who were nonresponders to interferon-based therapies were identified retrospectively and screened at Baseline, week 24 of treatment, and 24 weeks post-treatment. Selection of resistance mutations, including at amino acid position 415 of the polymerase, was investigated. Using clonal sequencing and pyrosequencing of the NS5B gene, we screened for the F415Y resistance mutation among patients who received combination therapy with ribavirin and interferon α. Of the 15 subtype 1a patients treated with interferon plus ribavirin, only one had the F415Y change at week 24, and an F/Y mixture was still present 24 weeks after therapy. Four additional patients in this group had the F415Y change 24 weeks post-therapy. The NS5B genes were sequenced in order to identify amino acid changes associated with ribavirin therapy, but no evidence was found that ribavirin selects for particular amino acids in the RNA-dependent RNA polymerase. Ribavirin, a weak inhibitor of HCV replication, does not select for resistance mutations in the sequence of the HCV RNA polymerase.     

The Future of HCV Therapy: NS4B as an Antiviral Target

Chronic hepatitis C virus (HCV) infection is a major worldwide cause of liver disease, including cirrhosis and hepatocellular carcinoma. It is estimated that more than 170 million individuals are infected with HCV, with three to four million new cases each year. The current standard of care, combination treatment with interferon and ribavirin, eradicates the virus in only about 50% of chronically infected patients. Notably, neither of these drugs directly target HCV. Many new antiviral therapies that specifically target hepatitis C (e.g. NS3 protease or NS5B polymerase inhibitors) are therefore in development, with a significant number having advanced into clinical trials. The nonstructural 4B (NS4B) protein, is among the least characterized of the HCV structural and nonstructural proteins and has been subjected to few pharmacological studies. NS4B is an integral membrane protein with at least four predicted transmembrane (TM) domains. A variety of functions have been postulated for NS4B, such as the ability to induce the membranous web replication platform, RNA binding and NTPase activity. This review summarizes potential targets within the nonstructural protein NS4B, with a focus on novel classes of NS4B inhibitors.     

IL‐28B (IFN‐λ3) and IFN‐α synergistically inhibit HCV replication

Genetic variation in the IL‐28B (interleukin‐28B; interferon lambda 3) region has been associated with sustained virological response (SVR) rates in patients with chronic hepatitis C treated with peginterferon‐α and ribavirin. However, the mechanisms by which polymorphisms in the IL‐28B gene region affect host antiviral responses are not well understood. Using the HCV 1b and 2a replicon system, we compared the effects of IFN‐λs and IFN‐α on HCV RNA replication. The anti‐HCV effect of IFN‐λ3 and IFN‐α in combination was also assessed. Changes in gene expression induced by IFN‐λ3 and IFN‐α were compared using cDNA microarray analysis. IFN‐λs at concentrations of 1 ng/mL or more exhibited concentration‐ and time‐dependent HCV inhibition. In combination, IFN‐λ3 and IFN‐α had a synergistic anti‐HCV effect; however , no synergistic enhancement was observed for interferon‐stimulated response element (ISRE) activity or upregulation of interferon ‐ stimulated genes (ISGs). With respect to the time course of ISG upregulation, the peak of IFN‐λ3‐induced gene expression occurred later and lasted longer than that induced by IFN‐α. In addition, although the genes upregulated by IFN‐α and IFN‐λ3 were similar to microarray analysis, interferon‐stimulated gene expression appeared early and was prolonged by combined administration of these two IFNs. In conclusion, IFN‐α and IFN‐λ3 in combination showed synergistic anti‐HCV activity in vitro. Differences in time‐dependent upregulation of these genes might contribute to the synergistic antiviral activity.     

Mutagenic effect of ribavirin on hepatitis C nonstructural 5B quasispecies in vitro and during antiviral therapy

BACKGROUND AND AIMS: Addition of ribavirin to interferon alfa treatment has substantially increased sustained virologic response rates in patients with chronic hepatitis C (CHC). Ribavirin acts as an RNA virus mutagen in vitro, thereby leading to error catastrophe. However, data in CHC are controversial. METHODS: The nonstructural (NS) 5B quasi-species heterogeneity was analyzed in Huh7 cells harboring a subgenomic hepatitis C virus (HCV) replicon system treated with ribavirin or levovirin. Accordingly, NS5B quasi-species were studied in 14 patients with CHC who received ribavirin alone or combined with pegylated interferon alfa both at baseline and during the first weeks of therapy. Analysis of NS3 quasi-species served as control. RESULTS: Cultivation of HCV replicon cells with ribavirin led to higher NS5B mutational frequencies compared with levovirin-treated or untreated cells (P < .05). Patients receiving ribavirin monotherapy showed higher overall mutational frequencies within NS3 and NS5B during therapy as compared with baseline (P < .01). Proportions of ribavirin-specific G-to-A and C-to-T transitions increased (P < .01). Paired analysis confirmed significant mean increases of mutational frequencies of approximately 5%. Ribavirin serum concentrations were positively correlated with mutational frequency changes (P < .05). In patients receiving combination therapy, a decrease of NS5B mutational frequencies ( approximately 10%) and lower proportions of G-to-A and T-to-C mutations (P < .01) were detectable. CONCLUSIONS: Ribavirin, but not its L-enantiomer levovirin, is a mutagen in HCV replicon cells. In patients with CHC, ribavirin monotherapy exhibits a moderate mutagenic effect early during therapy that is not detectable in combination with pegylated interferon alfa.     

Treatment of chronic hepatitis C: Anticipated impact of resistance in patients treated with protease inhibitors

A main target of specifically targeted antiviral therapy for hepatitis C (STAT-C) is the NS3-protease, which has key functions in the hepatitis C virus (HCV) replication cycle. HCV/NS3-protease inhibitors have shown high antiviral activity in vitro and in patients with chronic hepatitis C. Protease-resistant HCV variants occurred rapidly in patients receiving protease-inhibitor monotherapy. The development of resistance can be best explained by selection of preexisting resistant variants, which grow out under selective pressure. Numerous mutations associated with resistance were identified. Clinical trials showed that protease-resistant strains are sensitive to interferon and that a triple combination of protease inhibitors, peginterferon, and ribavirin may improve the sustained virologic response rate compared with standard peginterferon/ribavirin combination therapy. Overall, it can be anticipated that successful treatment with protease inhibitors will require either combination therapy with peginterferon/ribavirin or a combination of STAT-C compounds with distinct modes of action and resistance patterns.     

Mutations in the NS5A and E2‐PePHD regions of hepatitis C virus genotype 1b and response to combination therapy of interferon plus ribavirin

Background/aims: Combination therapy with interferon (IFN) and ribavirin is the current standard treatment for chronic hepatitis C, but the efficacy is still not satisfactory, especially for genotype 1b. NS5A and E2 proteins of hepatitis C virus (HCV) may repress the IFN‐induced RNA‐dependent protein kinase (PKR), and thus have the potential to influence the response of HCV to IFN therapy; however, this issue remains controversial. Methods: Nucleotide sequences of the PKR‐eIF2α phosphorylation homology domain (E2‐PePHD) and PKR‐binding domain (NS5A‐PKR bd) of the HCV genome were analyzed by amplification and direct sequencing in 30 HCV genotype 1b patients who had been treated with IFN and ribavirin. Results: Nine (30%) patients achieved a sustained virological response (SVR) to combination therapy. Pretreatment variables and amino acid substitutions were compared between responders and non‐responders. The responders were younger than non‐responders (37.2±10.4 vs. 45.4±9.5 years, P=0.017), whereas no significant statistical differences were found in the number of amino acid substitutions in NS5A and E2‐PePHD regions between the two groups. Conclusions: Genetic heterogeneity in NS5A and E2‐PePHD regions of the HCV genome may not serve as a predictor for treatment outcome with combination therapy in Taiwanese patients with chronic HCV genotype 1b infection.     

In vivo interferon system assessed by 2′‐5′ oligoadenylate synthetase activity in chronic hepatitis C virus patients treated with pegylated interferon and ribavirin

Aim: 2′,5′ oligoadenylate synthetase (2‐5AS), an enzyme induced by interferon, is an accurate indicator of the antiviral effect of interferon. We measured it during pegylated interferon based therapies in patients with chronic hepatitis C virus (HCV) in order to determine the dynamics of antiviral status in vivo and the relationship between the response to exogenous interferon and the outcome of therapy. Methods: A total of 160 patients with chronic HCV were treated with pegylated interferon alfa 2a or 2b or non‐pegylated interferon, with or without ribavirin. Serum 2‐5AS activity was measured by radioimmunoassay assay kits every 2 weeks. Results: In 60 patients treated with pegylated interferon alfa 2a or 2b, 2‐5AS levels increased to 7–40 times (average 235 pmol/dL) above the pretreatment levels (30 pmol/dL), which were significantly higher than the levels during non‐pegylated interferon therapy. Ribavirin did not enhance 2‐5AS levels. 2‐5AS levels between sustained virological response (SVR) and non‐SVR, including null responders to pegylated interferon plus ribavirin therapy were not significantly different. Conclusion: 2‐5AS levels were significantly higher in patients treated with pegylated interferon than in those treated with non‐pegylated interferon, suggesting that pegylated interferon is more potent at inducing interferon response genes resulting in an improved antiviral effect. Ribavirin did not appear to be related to interferon response gene induction.     

What Are the Promising New Therapies in the Field of Chronic Hepatitis C After the First-Generation Direct-Acting Antivirals?

A number of promising new hepatitis C virus (HCV) antiviral regimens have emerged during the last few years, with a trend toward increased efficacy, safety, and tolerability, when compared with currently available therapies. The focus of recent HCV antiviral drug development has been on inhibition of HCV replication, largely by targeting specific components of the HCV replication complex itself. A significant effort has been put into generating drugs that inhibit the NS5B polymerase. A number of such drugs have been developed, and NS5B polymerase inhibitors can be divided into nucleoside polymerase inhibitors and nonnucleoside polymerase inhibitors, with each group carrying specific pharmacologic and clinical characteristics. Additional research has explored the efficacy of drugs that inhibit the HCV replication complex via other mechanisms. Second-generation NS3-4A protease inhibitors have been developed, which have generally improved on the efficacy of the currently available FDA-approved first-generation agents. NS5A inhibitors have also been studied. These medications impede HCV replication and viral particle assembly and enhance host immune activation via novel mechanisms. Alternatively, medications that target a host protein, cyclophillin B, are under evaluation. These medications block HCV replication via modification of the effects of NS5B and via other poorly understood mechanisms. Detailed below are the most important HCV antiviral agents under development, many of which show promise for use within the next few years.     

Hepatitis C: viral and host factors associated with non‐response to pegylated interferon plus ribavirin

Treatment for chronic hepatitis C virus (HCV) infection has evolved considerably in the last years. The standard of care (SOC) for HCV infection consists in the combination of pegylated interferon (PEG‐IFN) plus ribavirin. However, it only induces a sustained virological response (SVR) in half of genotype 1‐infected patients. Several viral and host factors have been associated with non‐response: steatosis, obesity, insulin resistance, age, male sex, ethnicity and genotypes. Many studies have demonstrated that in non‐responders, some interferon‐stimulated genes were upregulated before treatment. Those findings associated to clinical, biochemical and histological data may help detect responders before starting any treatment. This is a very important issue because the standard treatment is physically and economically demanding. The future of HCV treatment would probably consist in the addition of specifically targeted antiviral therapy for HCV such as protease and/or polymerase inhibitors to the SOC. In genotype 1 patients, very promising results have been reported when the protease inhibitor telaprevir or boceprevir is added to the SOC. It increases the SVR rates from approximately 50% (PEG‐IFN plus ribavirin) to 70% (for patients treated with a combination of PEG‐IFN plus ribavirin plus telaprevir). Different elements are associated with non‐response: (i) viral factors, (ii) host factors and (iii) molecular mechanisms induced by HCV proteins to inhibit the IFN signalling pathway. The goal of this review is to present the mechanisms of non‐response, to overcome it and to identify factors that can help to predict the response to anti‐HCV therapy.     

Prevalence and clinical significance of GB virus type C/hepatitis G virus coinfection in patients with chronic hepatitis C undergoing antiviral therapy

Summary. Coinfection with GBV‐C/HGV in patients with chronic hepatitis C (CHC) may influence clinical course and response rates of antiviral therapy. Aim of the study was to investigate the prevalence of GBV‐C/HGV/HCV coinfection and its influence on outcome of interferon/ribavirin combination therapy. Three hundred and four patients with CHC [m/f = 211/93, age: 42 (18–65)] were investigated. HGV RNA detection was performed by polymerase chain reaction prior to and 6 months after the end of antiviral therapy. HGV/HCV coinfection could be identified in 37/304 (12.2%) patients with intravenous drug abuse as the most common source of infection (N = 21, (56.8%)). The predominant HCV genotype in coinfected individuals was HCV‐3a (HCV‐3a: 51.4%, HCV‐1: 37.8%, HCV‐4: 10.8%). HGV coinfection was more prevalent in patients infected with HCV‐3 compared to HCV‐1 or HCV‐4 [19/45 (42.2%) vs 14/185 (7.6%) vs 4/52 (7.7%), P < 0.01]. Patients with HGV/HCV coinfection were younger [35 (18–56) vs 43 (19–65), years; P < 0.01], and advanced fibrosis (F3‐F4) was less frequent (22.2%vs 42.9%, P < 0.05). A sustained virological response was achieved more frequently in HGV/HCV coinfected patients [26/37 (70.3%)] than in monoinfected patients [120/267 (44.9%), P < 0.01]. HGV RNA was undetectable in 65.7% of the coinfected patients at the end of follow‐up. Intravenous drug abuse seems to be a major risk factor for HGV coinfection in patients with chronic hepatitis C. Coinfection with HGV does not worsen the clinical course of chronic hepatitis C or diminish response of HCV to antiviral therapy. Interferon/ribavirin combination therapy also clears HGV infection in a high proportion of cases.     

Effect of mutation in the hepatitis C virus nonstructural 5B region on HCV replication

Background We have reported that the presence of a mutation at the hepatitis C virus (HCV) nonstructural protein 5B (NS5B), defined as a change in amino acids at sites specific for a different reported genotype, was related to complete response (CR) to interferon (IFN) therapy in patients with chronic hepatitis C (CHC) with genotype 1b. The present study assessed the impact of the NS5B mutation on the replication of HCV in these patients.Methods Genotype-specific mutations of HCV NS5B were determined by direct sequencing. We measured HCV-RNA titers in serum by real-time detected polymerase chain reaction (PCR), and serum HCV core protein levels (as a marker of HCV-RNA replication) were measured using an enzyme immunoassay in patients with CHC genotype 1b. RNA-dependent RNA polymerase (RdRp) activity was measured by Behrens method in liver cirrhosis patients infected with HCV (n = 13) and in those infected with hepatitis B virus (HBV; n = 2).Results The titers of HCV-RNA (n = 44) and the levels of HCV core protein (n = 41) were significantly lower in patients with the HCV genotype 1b mutant compared with wild-type HCV (P < 0.05). RdRp activity in liver tissue did not show any correlation with the HCV NS5B mutation.Conclusions HCV NS5B genotype-specific mutations in HCV genotype 1b may influence HCV replication.     

Long term histological improvement and clearance of intrahepatic hepatitis C virus RNA following sustained response to interferon-ribavirin combination therapy in liver transplanted patients with hepatitis C virus recurrence

BACKGROUND AND AIMS: A proportion of liver transplanted patients with recurrent chronic hepatitis have a sustained virological response to combination therapy with interferon plus ribavirin. However, the long term benefit of antiviral therapy with regard to hepatitis C virus (HCV) RNA clearance remains unknown in patients with HCV recurrence. This study examined the long term biochemical, virological, and histological outcome in transplanted patients with recurrent chronic hepatitis who had a sustained virological response to antiviral therapy. PATIENTS AND METHODS: Fifty four patients with recurrent hepatitis C were treated with antiviral therapy involving induction by combination therapy (interferon (IFN) plus ribavirin) for six months and maintenance ribavirin therapy for 12 months. Fourteen patients who had recurrent chronic hepatitis and sustained virological response to antiviral therapy were followed for three years after the end of antiviral therapy. Serum alanine aminotransferases were assessed every three months during the observation period. Serum hepatitis C RNA detected by polymerase chain reaction was evaluated every six months during follow up, and protocol biopsy procedures were performed routinely every year. Semiquantitative histopathological assessment of allograft hepatitis was performed using the Knodell score and HCV was also detected by polymerase chain reaction on frozen graft tissue samples. RESULTS: At the end of antiviral therapy, the sustained response rate was 26%. A complete response (normal serum alanine aminotransferase level and undetectable serum HCV RNA) was achieved in 13/14 (93%) patients three years after the end of treatment. A comparison of liver histology findings before and after a mean of three years after antiviral therapy showed a clear improvement in 12/14 (86%) patients. In 5/14 (36%) patients, the last biopsy showed normal or near normal histological findings. After three years of follow up, the total Knodell score was 3.2 (range 1-8) versus 8.3 (range 5-12) before treatment (p=0.001). Graft HCV RNA was detectable before treatment in all 14 patients and was undetectable at the end of follow up in 13/14 (93%) patients tested. CONCLUSION: In patients with biochemical and virological responses induced by ribavirin and interferon, a complete response was sustained in 93% for at least three years after cessation of therapy. This long term response was associated with absence of detectable intrahepatic hepatitis C RNA and marked histological improvement.     

Integrity of the NS5A (amino acid 2209 to 2248) region in hepatitis C virus 1b patients non‐responsive to interferon therapy

Abstract: Background/Aims: In hepatitis C virus‐1b, it has been suggested that an amino acid stretch (aa 2209–2248) of the carboxy terminal half of the non‐structural 5A (NS5A) region participates in the response to interferon treatment. We tested the hypothesis that absence of mutations in the NS5A (aa 2209–2248) sequence is required for interferon resistance. We also investigated the importance of different HCV‐1b isolates in interferon response in France. Methods: We determined the NS5A sequences of 70 patients with chronic hepatitis C before IFN therapy and then compared them with HCV‐J prototype sequence. The isolates were determined by NS5B sequencing, the “gold standard” method for genotyping and subtyping. Pre‐therapeutic viral load was also measured. Results: No sustained virological response was observed in the patients without amino acid substitutions in the NS5A (aa 2209–2248) sequence, and in the patients with HCV‐J isolates. Viral load was significantly higher in the patients with no amino acid substitutions in the NS5A (aa 2209–2248) sequence. Conclusions: In HCV‐1b infected patients, an HCV‐J strain with no amino acid substitution in the NS5A (aa 2209–2248) region indicates a poor prognosis for response to IFN therapy. The low interferon response rate in HCV‐1b infection in Europe is probably not due to a difference between isolates.     

Dual daclatasvir and sofosbuvir for treatment of genotype 3 chronic hepatitis C virus infection

Chronic hepatitis C virus (HCV) infection is one of the most common etiologies of liver-related mortality throughout the world. Traditionally, therapy has been focused on pegylated interferon in combination with ribavirin, with clinical trials demonstrating that HCV genotype 1 had the lowest response rate (40–50%), while genotype 3 had an intermediate response rate (60–70%). Recently, significant advances have been made with all-oral direct-acting antiviral (DAA) therapy, which have significantly improved cure rates for HCV genotype 1. Accordingly, HCV genotype 3 is now potentially the most difficult to treat. One of the most potent DAA medications is sofosbuvir, a pan-genotypic nucleotide analogue that inhibits the NS5B polymerase of HCV. Daclatasvir, a pan-genotypic inhibitor of the HCV NS5A replication complex, was recently approved in the United States for treatment of HCV genotype 3 in conjunction with sofosbuvir. This combination may provide a powerful tool in the treatment of HCV genotype 3.     

A phase 3b study of sofosbuvir plus ribavirin in treatment‐naive and treatment‐experienced Korean patients chronically infected with genotype 2 hepatitis C virus

In Korea, patients with chronic hepatitis C virus (HCV) infection are typically treated with pegylated interferon‐alpha plus ribavirin, but interferons are contraindicated in many patients and are often poorly tolerated, particularly by the elderly and those with advanced liver disease. No interferon‐free treatment regimens are approved in Korea. Sofosbuvir is an oral nucleotide analog inhibitor of the HCV nonstructural 5B RNA polymerase. It is approved in the USA, European Union and Japan for treating a number of HCV genotypes, including genotype 2. Genotype 2 has a seroprevalence of 38–46% in Korea. This single‐arm, phase 3b study (NCT02021643) examined the efficacy and safety of sofosbuvir plus ribavirin (12‐week duration) in chronic genotype 2 HCV‐infected treatment‐naive and treatment‐experienced Korean patients with and without cirrhosis. The proportion of patients with sustained virologic response 12 weeks after treatment discontinuation (SVR12) was 97% (125/129), with 96% (101/105) of treatment‐naive and 100% (24/24) of treatment‐experienced patients achieving SVR12. Two patients experienced virologic failure (n = 1, on‐treatment failure; n = 1, relapse). No patient discontinued study treatment due to an adverse event (AE). The most common treatment‐emergent AEs were headache (18%, 23/129) and pruritus (15%, 19/129). Few patients had grade 3 AEs (5%, 6/129) or grade 3 laboratory abnormalities (12%, 15/129). No grade 4 AE was reported. These data suggest that 12 weeks of treatment with the all‐oral, interferon‐free regimen of sofosbuvir plus ribavirin is effective and well tolerated in Korean patients with chronic genotype 2 HCV infection.