New therapeutic strategies in HCV: polymerase inhibitors

Review Article

New therapeutic strategies in HCV: polymerase inhibitors

 

Ludmila Gerber, Tania M. Welzel, Stefan Zeuzem^*

 

Article first published online: 3 JAN 2013

 

 

 

DOI: 10.1111/liv.12068

© 2012 John Wiley & Sons A/S

Issue

Liver International

 

Special Issue: Proceedings of the 6th Paris Hepatitis Conference, International Conference on the Management of Patients with Viral Hepatitis

 

Volume 33, Issue Supplements 1, pages 85–92, February 2013

 

Additional Information

 

How to Cite

Gerber, L., Welzel, T. M. and Zeuzem, S. (2013), New therapeutic strategies in HCV: polymerase inhibitors. Liver International, 33: 85–92. doi: 10.1111/liv.12068

Author Information

1. Klinikum der J.W. Goethe Universität, Frankfurt am Main, Germany
2.  Correspondence Stefan Zeuzem, MD, Professor of Medicine, Chief \x96 Department of Medicine I, J.W. Goethe University Hospital, Theodor-Stern-Kai 7, 60590 Frankfurt, Germany
   Tel: +49 (0)69 6301 6899 or 4544
   Fax: +49 (0)69 6301 6448

antiviral therapy;
hepatitis C;
non-nucleoside polymerase inhibitors;
nucleoside polymerase inhibitors

Abstract

The characterization of the viral life cycle facilitated the development of directly acting antiviral drugs. Among those, several inhibitors of the viral RNA-dependent RNA polymerase have proven effectiveness in clinical trials. The characteristics of different nucleos(t)ide and non-nucleoside polymerase inhibitors, as well as their clinical applications and combinations with other classes of directly acting antiviral drugs are reviewed herein.

 

Abbreviations
DAA directly acting antiviral

eRVR extended rapid virological response

HCV hepatitis C virus

HCC hepatocellular carcinoma

PEG-IFN pegylated interferon

PI protease inhibitors

RVR rapid viral response

RBV ribavirin

SOC standard of care

SVR sustained virological response

 

According to the World Health Organization (WHO), about 3% of the world's population has been infected with the hepatitis C virus (HCV). Of those, approximately 170 million are chronic HCV carriers at risk of developing cirrhosis and hepatocellular carcinoma (HCC) contributing to a large percentage of liver transplantations in Europe and the United States [1].

 

For almost a decade, the combination of pegylated interferon (PEG-IFN) and ribavirin (RBV) has been the standard of care (SOC) producing sustained virological response (SVR) rates of ~50% in treatment-naive patients infected with HCV genotype 1 and 70–90% in patients infected with HCV genotypes 2 and 3 [2]. Recently, this therapeutic backbone has been supplemented by the addition of first- generation protease inhibitors (Telaprevir, Boceprevir) directly targeting the viral NS3/4A protease. This ‘triple therapy’ improved SVR rates to 70–80% in treatment-naive patients infected with HCV genotype 1 [3, 4].

 

The development of directly acting antiviral (DAA) HCV therapeutics was facilitated by the adaptation of HCV to a cell culture system allowing the description of the HCV lifecycle and identification of potential novel drug targets. In addition to protease inhibitors (PI), these targets include inhibitors of the non-structural NS5A enzyme, a protein possibly involved in HCV replication, and nucleoside/nucleotide analogue and non-nucleoside inhibitors of the HCV RNA-dependent RNA polymerase (RdRp/NS5B) [5-7].

 

The following sections provide an overview of novel therapeutic strategies involving nucleoside/nucleotide analogue and non-nucleoside inhibitors of the HCV RNA-dependent RNA polymerase (RdRp/NS5B).

 

Function and biological role of the Hepatitis C Virus (HCV) polymerase inhibitor

A highly structured association of RNA and viral proteins, of cellular proteins and cofactors, and of rearranged intracellular lipid membranes derived from the endoplasmic reticulum are essential for replication of the viral RNA genome [8]. The key enzyme in this process is NS5B, a RNA-dependent RNA polymerase, catalysing the synthesis of a complementary negative-strand RNA by using the positive-strand RNA genome as a template. Numerous RNA strands of positive polarity are produced by NS5B activity from this negative-strand RNA and serve as templates for further replication and polyprotein translation [9].
 

Schematically, the NS5B protein has the shape of a right hand with an active site located within the palm domain and encircled of a thumb and a finger domain (Fig. 1). The thumb domains act as regulator of nucleic acid binding and the catalytic efficiency of the enzyme's active site, while the palm domains coordinate the function of the active site and carry out the nucleotidyl transfer reaction [10].
 

Figure 1. NS5B polymerase structure and molecular target sites. Ribbon model of the NS5B polymerase from PDB structure 2IJN. Palm, thumb and fingers are coloured in red, green and blue respectively, with finger loops coloured in yellow. Active site with bound inhibitor (blue space-filling model) and non-nucleoside inhibitor (NNI) sites 1–4 are indicated.

Figure 1. NS5B polymerase structure and molecular target sites. Ribbon model of the NS5B polymerase from PDB structure 2IJN. Palm, thumb and fingers are coloured in red, green and blue respectively, with finger loops coloured in yellow. Active site with bound inhibitor (blue space-filling model) and non-nucleoside inhibitor (NNI) sites 1–4 are indicated.

Two classes of NS5B inhibitors have been developed: nucleoside/nucleotide and non-nucleoside polymerase inhibitors.

Nucleoside/nucleotide analogue polymerase inhibitors

Nucleoside/nucleotide analogues act as natural polymerase substrates leading to termination of RNA chain elongation by inhibition of the active site of the HCV RdRp.

Mostly synthetic prodrugs of nucleotides are administered to facilitate resorption, and additional steps of intracellular phosphorylation are required to gain full functional activity as a nucleosid triphosphate.
 

Because of high conservation of the active site of the HCV RdRp across all HCV genotypes, these drugs have pan-genotype equivalent antiviral activity in vitro. In vivo data have not yet been completed. In vitro, nucleosidic inhibitors display a low ‘genetic barrier to resistance’ as drug resistance can be observed with single amino acid substitutions. However, because of the poor fitness of resistant variants in the presence of nucleosidic inhibitors, these agents are considered to have a high overall ‘barrier’ to resistance.

Non-nucleoside polymerase inhibitors

Non-nucleoside inhibitors bind outside the active site and target allosteric sites on the surface of the enzyme, downregulating the RdRp activity through induction of conformational changes (Fig.1).

Non-nucleoside inhibitors are so far specific for HCV genotype 1. The efficacy against genotype 1 subtypes, however, may differ. The barrier to resistance of non-nucleoside inhibitors is considered to be low.
 

Four groups of non-nucleoside inhibitors have entered clinical development
(summarized in Table 1).

Table 1. Polymerase inhibitors in clinical development

				Efficiency / log decline (log10 IU/ml)
	Generic name	Phase of development		Monotherapy	Combination	Comment
Nucleosidic inhibitors
NM-283 (Idenix)	Valopicitabin	Phase I	discontinued	0.87 (15 d)	3.90-4.56 (IFN)	Gastrointestinal side effects
R-1626 (Roche)		Phase II	discontinued	2.6-3.7 (14 d)	5.2 (IFN/R)	Neutropenia, lymphopenia, neurotoxicity
INX-189/BMS-986094 (Inhibitex/BMS)		Phase III	discontinued	0.6-4.25 (7 d)	0.75-3.79 (R/7 d)	Liver and severe cardiac & renal toxicity
PSI-938/GS-938 (Pharmasset/Gilead)		Phase III	discontinued	4.8-5.8 (14 d)		Hepatotoxicity
Alios-2200 (Alios)		Phase I	ongoing	4.54 (7 d)	n.a.
Alios-2158 (Alios)		Phase I	ongoing	n.a.	n.a.
R-7128/RG-7128 (Roche)	Mericitabine	Phase II	ongoing	2.7 (14 d)	5.00
PSI-7977/GS-7977 (Pharmasset/Gilead)	Sofosbuvir	Phase III	ongoing	4.7 (7 d)	6.4 (IFN/R)
Non-nucleosidic inhibitors
Thumb I inhibitors
BILB-1941 (Boehringer Ingelheim)		Phase I	discontinued	> 1 (5 d)	/	gastro-intestinal side effects
MK-3281 (Merk)		Phase I	discontinued	3.75 (7 d)	/	gastro-intestinal side effects
BI-207127 (Boehringer Ingelheim)		Phase II	ongoing	0.6-3.1 (5 d)	5.6 (IFN/R)
Thumb II inhibitors
VX-759 (Vertex)		Phase I	discontinued	2.5 (10 d)	3.7 (VX222)	low anti-viral efficacy
VX-916 (Vertex)		Phase I	discontinued	1.5 (3 d)	/	low anti-viral efficacy
GS-9669 (Gilead)		Phase I	ongoing	3.5 (3 d)	/
PF-00868554 (Pfizer)	Filibuvir	Phase II	ongoing	0.68-2.13 (8 d)	3.44-4.43 (IFN/R)
VX-222 (Vertex)		Phase II	ongoing	3.1-3.4 (3 d)	ongoing
Palm I inhibitors
ABT-333 (Abbott)		Phase I	ongoing	0.7-1.5 (2 d)	3.5-4.0 (IFN/R)
ABT-072 (Abbott)		Phase I	ongoing	1.19-2-3 (2 d)	(ABT-450/-333)
ANA-598 (Roche)	Setrobuvir	Phase II	ongoing	2.4-2.9 (3 d)	outstanding
Palm II inhibitors
HCV-796 (ViroPharma/Wyeth)	Nesbuvir	Phase I	discontinued	1.4 (14 d)	/	hepatotoxicity
IDX-375 (Idenix)		Phase I	discontinued	0.5-1.1 (1 d)	/	hepatotoxicity
GS-9190 (Gilead)	Tegobuvir	Phase II	ongoing	1.4-1.7 (8 d)	5.7 (9256/IFN/RBV)

Thumb I inhibitors (benzimidazole site): MK-3281 (Merck, Rahway, New Jersey, USA), B ILB1941 and BI 207127 (Boehringer-Ingelheim, Ingelheim am Rhein, Germany) are thumb I site inhibitors. Pre-existing NS5B substitutions known to reduce sensitivity were identified e.g. for BILB1941 at positions V494I/A, I424V and P496A [11].
 

Thumb II inhibitors (thiophene site): filibuvir (PF-00868554/Pfizer, New York, USA), VX-759, VX-916 and VX-222 (Vertex, Cambridge, Massachusetts, USA) bind to the thumb II site. Variants at position M423 known to confer resistance to filibuvir from in vitro studies were also selected in most patients in vivo. For VCH-759 as well as VCH-916, viral breakthroughs with selection of resistant variants conferring high (M423T/V/I) and medium (L419V/M, I482L/V/T, V494A/I) levels of resistance were described [11].
 

Palm I inhibitors (benzothiadiazine site): ABT-333, ABT-072 (both Abbott, Abbott Park, Illinois, USA) and Setrobuvir (ANA598; Anadys/Roche, Basel, Switzerland) are inhibitors of the palm I site. Several variants (M414T, G554D, D559G) were described from in vitro replicon studies to confer resistance to ANA598. Mutations associated with resistance in patients treated with ABT-333 were observed at positions C316Y and Y448C [11].
 

Palm II inhibitors (benzofuran site): nesbuvir (HCV-796/ViroPharma/Wyeth, Exton, Pennsylvania, USA) and IDX-375 (Idenix, Cambridge, Massachusetts, USA) act at the palm II site. The C316Y mutation in NS5B is associated with resistance to HCV-796 in vitro and in vivo [11].

Polymerase inhibitors in clinical trials

Nucleoside and non-nucleoside inhibitors have been investigated in combination with PEG-IFN and RBV and in PEG-IFN-free therapeutic regimens.

Nucleos(t)ide inhibitors

Several drugs in clinical development were discontinued because of clinically significant side effects including valopicitabine (NM-283), R-1626, PSI-938 and BMS-986094 (formerly known as INX-189) (Table 1).
 

Promising clinical data have been presented for the following HCV nucleos(t)ide analogues that have entered phase 2/3 clinical testing: mericitabine (RG-7128; prodrug of the pyrimidine (cytosine) nucleoside analogue PSI-6130) and sofosbuvir (PSI-7977/GS-7977; chirally pure isomer form of PSI-7851; prodrug of the nucleotide pyrimidine (uridine) analogue GS-7411). Early results were recently reported for ALS-2200, a novel nucleotide pyrimidine analogue polymerase inhibitor with a median reduction in HCV-RNA of 4.54 log₁₀ after 7 days of dosing [12].

Nucleos(t)ide inhibitors in clinical trials with interferon

Mericitabine (RG 7128)

The PROPEL study investigated safety, tolerability and efficacy of 8 and 12 weeks of mericitabine (1000 mg BID) in combination with PEG-IFN/RBV in 408 treatment-naive patients with chronic HCV genotype 1 or 4 infection. The rapid viral response (RVR) rates were up to 62% in the treatment arms with mericitabine compared with 18% in the control arm with PEG-IFN/RBV alone. SVR rates, however, did not differ between patients receiving mericitabine in combination with PEG-IFN/RBV and patients who received placebo plus PEG-IFN/RBV for 48 weeks. In the response-guided arms, fewer patients achieved SVR (33–49%) because of high virological relapse rates [13].
 

The JUMP-C trial (phase 2) investigated the safety and efficacy of 24 weeks of response-guided therapy with mericitabine (1000 mg BID), PEG-IFN/RBV in 168 treatment-naive patients with HCV genotype 1 or 4 infection. Patients were randomized (1:1) to response-guided therapy with mericitabine plus PEG-IFN and RBV for 24 or 48 weeks or to placebo, PEG-IFN/RBV for 48 weeks. In the mericitabine treatment arm, therapy was stopped at week 24 in patients with an extended rapid virological response [eRVR], defined as undetectable HCV RNA (<15 IU/ml) from week 4 to 22. Patients without eRVR received PEG-IFN/RBV for another 24 weeks. Overall SVR rates were higher in patients treated with mericitabine plus PEG-IFN/RBV than in patients treated with PEG-IFN/RBV alone (58% vs. 36%). Among 49 patients (60%) who achieved an eRVR with mericitabine plus PEG-IFN/RBV and discontinued therapy at week 24, the SVR rate was 78%. Combination therapy with mericitabine was safe, well-tolerated, demonstrated a high resistance barrier and a low potential for pharmacokinetic drug–drug interactions [14].
 

The MATTERHORN study, another phase 2 trial, is an ongoing study evaluating the efficacy and safety of various combinations of mericitabine and ritonavir-boosted danoprevir and PEG-IFN/RBV in patients with HCV genotype 1 infection.
 

The ongoing phase 2 DYNAMO I and II studies investigate quadruple therapy with mericitabine in combination with the protease inhibitors boceprevir or telaprevir and PEG-IFN/RBV in HCV genotype 1 non-responders to PEG-IFN/RBV.

Sofosbuvir (GS-7977, formerly PSI-7977)

The combination of sofosbuvir (400 mg QD), PEG-IFN and RBV was assessed for 12 weeks in 25 treatment-naive patients infected with HCV genotypes 2/3 in an open-label, uncontrolled pilot study (PROTON). Of the patients, who completed therapy (n = 24), 100% achieved an SVR. Based on these favourable results, the PROTON study was expanded to treatment-naive patients infected with HCV genotype 1. Patients were randomized 2:2:1 to different dose groups of sofosbuvir (200 or 400 mg QD) for 12 weeks plus PEG-IFN/RBV for 24 weeks. Patients without RVR were continued on PEG-IFN/RBV through week 48. Reported SVR rates were 88, 91% and <50% for sofosbuvir 200, 400 mg and the control group respectively [15, 16].
 

The ELECTRON study investigated sofosbuvir (400 mg QD) and RBV for 12 weeks in combination with 0, 4, 8 or 12 weeks PEG-IFN. All patients (n = 10 per group) achieved an SVR after 12 weeks of therapy [17].
 

The ATOMIC study, a Phase 2 randomized open-label trial investigated sofosbuvir in combination with PEG-IFN/RBV in 316 non-cirrhotic HCV genotype 1, 4 and 6 patients. Patients infected with HCV genotype 1 were randomized to 12 or 24 weeks sofosbuvir, PEG-IFN/RBV, or 12 weeks of the triple combination followed by re-randomization (1:1) to receive additional 12 weeks of either sofosbuvir alone or sofosbuvir plus RBV. Also, 16 patients infected with HCV genotypes 4 and 6 were randomized to the 24-week regimen of sofosbuvir plus PEG-IFN/RBV. Results of an interim analysis showed SVR rates of 90% in patients who received 12 weeks of the triple combination [18].

The phase III trial NEUTRINO, a single-arm study, evaluating a 12-week course of sofosbuvir plus PEG-IFN/RBV in 300 patients infected with HCV genotypes 1, 4, 5 and 6 is currently ongoing.

Nucleos(t)ide inhibitors in clinical trials without interferon

Nucleos(t)ide analogues were also investigated in combination with RBV, NS3/4A protease inhibitors, NS5A inhibitors and/or other nucleotide inhibitors in IFN-free treatment regimens.

Mericitabine (RG 7128)

The INFORM-1 study provided first proof of principle that suppression of HCV RNA with an interferon-free combination of mericitabine and danoprevir (NS3/4 protease inhibitor) is effective. Different doses of mericitabine in combination with danoprevir were administered for 14 days to patients infected with HCV genotype 1. At the highest combination doses tested (1000 mg mericitabine and 900 mg danoprevir BID), the median change in HCV RNA concentration from baseline to day 14 was −5.1 log(10) IU/ml in treatment-naive patients and −4.9 log(10) IU/ml in previous null-responders to PEG-IFN/RBV therapy[19].
 

INFORM-SVR, a phase 2b trial, subsequently investigated a 12 or 24 week interferon-free regimen of ritonavir-boosted danoprevir (DNV/r, 100/100 mg), and mericitabine (1000 mg BID) with or without RBV in treatment-naive HCV genotype 1 infected patients. Patients with undetectable HCV RNA at week 2 and week 10 were re-randomized at week 12 to stop therapy or to continue until week 24. Rapid viral response was similar and comparable in both arms (91 and 93% respectively). Owing to high relapse rates, however, the 12-week treatment arm was prematurely stopped. Furthermore, patients randomized to the RBV-free group were offered to continue on PEG-IFN/RBV therapy because of insufficient SVR rates. The data show SVR in 71% of HCV genotype 1b patients, but only in 26% of the genotype 1a-infected patients who received 24 weeks of DNV/r, mericitabine and RBV treatment. Higher SVR rates were reported among patients who were rapid virological responders. Among patients with undetected HCV-RNA at week 2, 80% with genotype 1b and 31% with genotype 1a achieved SVR. IL28B genotype appeared to have less impact on SVR rates.

Breakthrough rates were higher among patients not receiving RBV and showed in all patients, the selection of danoprevir-resistant variants, while only one patient showed the NS5B S282T polymerase mutation associated with resistance to mericitabine. Neutropenia or treatment emergent liver toxicity was not observed [20].
 

The currently ongoing phase II study ANNAPURNA evaluates the safety, tolerability, and efficacy of combination treatment with mericitabine (1000 mg BID), ritonavir-boosted danoprevir (DNV/r 100/100 mg), setrobuvir (ANA-598) and RBV administered for 12–14 or 24–26 weeks to treatment-naive patients or for 24–26 weeks to non-responders to PEG-IFN/RBV therapy with chronic hepatitis C genotype 1 infection.

Sofosbuvir (GS-7977/PSI-7977)

In the ELECTRON trial, the interferon-free combination of sofosbuvir and RBV achieved 100% SVR rates in treatment-naive patients infected with HCV genotype 2/3. In subsequent cohorts, patients with HCV genotype 1 infection and prior non-response to PEG-IFN/RBV received sofosbuvir and RBV for 12 weeks, but showed high relapse rates after the end of 12 weeks of treatment (89%). Reported SVR4 rates in treatment-naive patients infected with genotype 1 or treatment-experienced patients infected with genotype 2/3 receiving sofosbuvir and RBV for 12 weeks were 88 and 80% respectively [17].
 

The QUANTUM study, a phase 2b study, was planned as the first interferon-free, pan-genotypic, all-nucleotide study, combining a pyrimidine and a purine analogue, sofosbuvir and PSI-938 with or without RBV for 12 weeks. However, PSI-938 had to be discontinued because of liver toxicity. An SVR rate of 59% was reported for 17 HCV genotype 1 patients [21].
 

Three ongoing US studies for patients with HCV genotype 2/3 infection are FISSION, POSITRON, and FUSION. FISSION will compare 12 weeks of treatment with sofosbuvir and RBV to 24 weeks of PEG-IFN/RBV therapy. POSITRON evaluates the same combination for 12 weeks in interferon ineligible or intolerant patients. FUSION will examine treatment-experienced patients exploring 12 or 16 weeks of treatment with sofosbuvir and RBV.
 

Furthermore, a phase 3 study (VALENCE) was recently started to investigate the combination of sofosbuvir and RBV for 12 weeks in treatment-naive and treatment-experienced patients with HCV genotype 2 and 3 infection also in Europe.
 

Different oral combinations of sofosbuvir (400 mg QD) plus daclatasvir (BMS-790052, 60 mg QD) with/without RBV were tested in an open-label Phase 2a pharmaceutical cross-collaboration in treatment-naive non-cirrhotic HCV genotype 1-, 2- and 3-infected patients. SVR rates were 88, 100, and 79% respectively [22]. Furthermore, a combination study of simeprevir (TMC435) plus sofosbuvir is ongoing and a phase III study, investigating the combination of sofosbuvir and GS-5885 (NS5A inhibitor), is currently in preparation.

Non-nucleoside inhibitors

Several non-nucleoside inhibitors were discontinued from clinical development for different reasons. BILB1941 and MK-3281 were discontinued because of gastrointestinal side events [23-25], VX-759 and VX-916 showed only low-to-medium antiviral activity [26, 27], nesbuvir (HCV-796) and IDX-375 showed elevation of liver enzymes [27].
 

Currently, BI 207127, VX-222, ABT-072, ABT-333, setrobuvir (ANA-598), filibuvir and tegobuvir (GS-9190) are still investigated in clinical trials.

Non-nucleoside inhibitors in clinical trials with interferon

BI 207127

The SOUND C1 trial evaluated the combination of the non-nucleoside polymerase inhibitor BI 207127 with the protease inhibitor BI 201335 and RBV for 4 weeks followed by BI 201335 and PEG-IFN/RBV in treatment-naive patients with HCV genotype 1 infection. The RVR rates ranged from 73% (genotype 1a) to 100% (genotype 1b). An SVR rate of 94% was achieved in the group receiving a higher dose of BI 207127 (600 mg; TID) [28].

VX-222

The Phase 2 ZENITH study was designed to evaluate the antiviral activity of the protease inhibitor telaprevir and two dose levels of VX-222 administered with or without PEG-IFN/RBV for 12 or 24 weeks in treatment-naive patients with genotype 1 infection. This quad regimen led to SVR rates of 82–93% [29].

Setrobuvir (ANA-598)

Setrobuvir was studied at different doses in combination with PEG-IFN and RBV in treatment-naive and treatment-experienced patients with HCV genotype 1. Both doses of setrobuvir demonstrated a favourable safety and tolerability profile through 12 weeks. SVR was achieved in 8 of 11 patients (73%) who received 24 weeks of treatment [30].

Tegobuvir (GS-9190)

The antiviral activity of tegobuvir and the NS3/4A protease inhibitor GS-9256 alone or in combination with RBV or PEG-IFN/RBV in treatment-naive patients with HCV genotype 1 was assessed in a phase II trial. Patients were randomized to 28 days of tegobuvir/GS-9256, tegobuvir/GS-9256/RBV or tegobuvir/GS-9256/Peg-IFN/RBV, followed by PEG-IFN/RBV for further 44 weeks. Rapid viral response was observed in 100% (14 of 14) of patients receiving tegobuvir/GS-9256/PEG-IFN/RBV [31]. Response-guided quadruple therapy with tegobuvir and GS-9256 plus PEG-IFN/RBV based on a virological response at week 2 enabled to shorten antiviral therapy to 16 weeks and yielded an SVR rate of 95% [32].
 

Because of pancytopenia in quadruple therapy combinations including tegobuvir, the polymerase inhibitors GS-9256 or GS-9451, Peg-IFN and RBV, dosing of tegobuvir was discontinued [33].

Non-nucleoside inhibitors in clinical trials without interferon

BI 207127

SOUND-C2 (n = 362), an open-label, randomized, phase IIb trial investigated safety and efficacy of the combination faldaprevir (BI 201335; protease inhibitor), BI 207127 with or without RBV for 16, 28, 40 weeks in genotype 1-infected treatment-naive patients, including 10% of patients with compensated cirrhosis. Patients were randomized to one of five treatment arms: (A) 120mg QD BI 201335 (1335_QD) plus 600mg TID BI 207127 (7127_TID) and RBV for 16 weeks, (B) 28 weeks, or (C) 40 weeks; (D) 1335_QD plus 600mg BID BI 207127 (7127_BID) and RBV for 28 weeks; (E) 1335 plus 7127_TID (no RBV) for 28 weeks. Randomization to Arm E was stopped prematurely according to FDA feedback on study design prior to data analysis. The RBV-sparing arm showed substantial but lower response rates than other arms of the trial.
 

This combination therapy achieved a SVR rate of 60% in treatment-naive patients with genotype 1 after 16 weeks of treatment, confirming the potent antiviral activity of this treatment regimen. In patients with liver cirrhosis, an SVR rate of 60% in HCV genotype 1a and up to 83% in HCV genotype 1b-infected patients was reported. The BID (for BI 207127) regimen demonstrated the most favourable safety and tolerability profile with a low rate of adverse event-related study discontinuations. Post-hoc subanalyses by IL28B genotype showed clinically important differences in SVR rates: HCV 1a (IL28B: non-CC) 32% vs. HCV 1a (IL28B: CC) 75% and HCV 1b (IL28B: CC and non-CC) 82–84% [34].

ABT-072 and ABT-333

In the PILOT trial, 11 treatment-naive, non-cirrhotic HCV genotype 1 infected patients expressing the IL28B CC genotype were treated with ABT-450/r (150/100 mg QD), ABT-072 (400 mg QD) and RBV for 12 weeks. The SVR rate was 91%.
 

Another study (Co-Pilot) investigated ABT-450/r in combination with ABT-333 and RBV in 33 treatment-naive HCV genotype-1 infected patients and 17 non-responders to previous PEG-IFN/RBV therapy. Therapy-naive patients were treated with two different doses of ABT-450/r (250/100 mg and 150/100 mg, Arm 1 and 2 respectively) while prior non-responders received open-label ABT-450/r (150/100 mg, Arm 3). ABT-333 was administered in a fixed dose of 400 mg QD across groups. SVR rates in treatment-naïve patients were independent of ABT-450/r dose and IL28B genotype (95 and 93% for arm 1 and 2 respectively. In previous non-responders (Arm 3), the SVR rate was 47% [35].

VX-222

The phase 2 ZENITH study was designed to evaluate the antiviral activity of the protease inhibitor telaprevir and VX-222 in a dual regimen, in addition with RBV as triple or with PEG-IFN/RBV as quadruple combination therapy in treatment-naive patients with genotype 1 infection. A proportion of 38% of patients receiving 100 mg VX-222 plus telaprevir and 50% of patients receiving 400 mg VX-222 plus telaprevir were able to undergo only 12 weeks of therapy because of RVR (undetectable HCV-RNA at week 2 and 8) and achieved SVR rates of 83 and 90% respectively [29].

Tegobuvir (GS-9190)

Another interferon-free study, investigating the combination of tegobuvir, GS-5885 (NS5A inhibitor), GS-9451 (NS3/4A protease inhibitor) and RBV for 12 and 24 weeks in treatment-naive and experienced HCV genotype 1 patients demonstrated SVR rates up to 89% in patients treated for 12 weeks and up to 100% in patients treated for 24 weeks. Viral breakthrough occurred only in GT1a-infected patients [36].

Conclusion

The optimal treatment regimens for patients with chronic hepatitis C must still be defined. In many trials, nucleos(t)ide and non-nucleoside polymerase inhibitors are key components. The high resistance barrier of the nucleoside analogue inhibitors provides a potential backbone in various interferon-free treatment combinations. The non-nucleoside inhibitors have complementary resistance profiles to protease inhibitors and NS5A inhibitors and are also positioned to become relevant components in combination trials. In the near future, polymerase inhibitors as key components could be clinically available if ongoing clinical trials continue to show promising results on efficacy, safety and tolerability.

Acknowledgements

We thank Dr C. Welsch for providing Figure 1.

Disclosure

Financial disclosures: Stefan Zeuzem – Consultancies for Abbott, Achillion, AstraZeneca, BMS, Boehringer-Ingelheim, Gilead, Idenix, Janssen, Merck, Novartis, Presidio, Roche, Santaris, Vertex. Tania M. Welzel – Consultancies for Novartis. Ludmila Gerber has no disclosure.

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  de Bruijne J, de Rooij JV, van Vliet A, et al. Phase I study in healthy volunteers and patients with IDX-375, a novel non-nucleoside HCV polymerase inhibitor. Hepatology 2010; 52(Suppl): 1219A.
• 13
  Jensen DM, Wedemeyer H, Herring RW, et al. High rates of early viral response, promising safety profile and lack resistance-related breakthrough in HCV GT1/4 patients treated with RG7128 plus pegIFN alfa-2a (40KD)/RBV: planned week 12 interim analysis from the PROPEL study. Hepatology 2010; 52(Suppl): 360–1A.
• 14
  Pockros P, Jensen D, Tsai N, et al. SVR-12 among G1/4treatment-naïve patients receiving mericitabine in combination with peg-IFNa-2A7RBV: interim analysis from the JUMP-C study. J Hepatol 2012; 56(Suppl): 477–8.
• 15
  Lawitz E, et al. PSI-7977 PROTON AND ELECTRON: 100% concordance of SVR4 with in HCV GT1, GT2, & GT3. J Hepatol 2012; 56(Suppl): S4.
• 16
  Lalezari J, Lawitz E, Rodriguez-Torres M, et al. Once daily PSI-7977 plus peginterferon/ribavirin in a Phase 2b trial: rapid virologic suppression in treatment-naive patients with HCV genotype 2/3. J Hepatol 2011; 54(Suppl): S28.
• 17
  Gane EJ, et al. Once daily GS-7977 plus ribavirin in HCV genotypes 1-3: the ELECTRON. Hepatology 2012; 56(Suppl): 306–7A.
• 18
  Hassanein T, Lawitz E, et al. Once daily sofosbuvir (GS-7977) plus PEG/RBV: high early response rates are maintained during post-treatment follow-up in treatment-naïve patients with HCV genotype 1, 4, and 6 infection in the ATOMIC study. Hepatology 2012; 56(Suppl): 307A.
• 19
  Gane EJ, Roberts SK, Stedman CA, et al. Oral combination therapy with a nucleoside polymerase inhibitor (RG7128) and danoprevir for chronic hepatitis C genotype 1 infection (INFORM-1): a randomised, double-blind, placebo-controlled, dose-escalation trial. Lancet 2010; 376: 1467–75.
• 20
  Gane EJ. Interferon-free treatment with a combination of mericitabine and danoprevir/r with or without ribavirin in treatment naive HCV genotype 1 infected patients. J Hepatol 2012; 56(Suppl): 555–6.
• 21
  Gilead Announces Early Sustained Virologic Response Rates for GS-7977 Plus Ribavirin in Genotype 1 Treatment-Naive Hepatitis C Patients: Available at http://investors.gilead.com/phoenix.zhtml?c&#x00A0;=&#x00A0;69964&p=irol-newsArticle&ID=1684792&highlight. Accessed: October 2012.
• 22
  Sulkowski M, et al. Potent viral suppression with all-oral combination of daclatasvir (NS5A inhibitor) and GS-7977 (NS5B inhibitor), +/-ribavirin, in treatment-naive patients with chronic HCV GT1, 2, or 3. J Hepatol 2012; 56(Suppl): 560.
• 23
  Erhardt A, Deterding K, Benhamou Y, et al. Safety, pharmacokinetics and antiviral effect of BILB 1941, a novel hepatitis C virus RNA polymerase inhibitor, after 5 days oral treatment. Antivir Ther 2009; 14: 23–32.
• 24
  Larrey D, Benhamou Y, Lohse AW, et al. Safety, pharmacokinetic and antiviral effect of BI207127, a novel HCV RNA polymerase inhibitor, after 5 days oral treatment in patients with chronic hepatitis C. J Hepatol 2009; 50(Suppl): S383–4.
• 25
  Brainard DM, Anderson MS, Petry A, et al. Safety and antiviral activity of NS5B polymerase inhibitor MK-3281, in treatment-naive genotype 1a, 1b and 3 HCV-infected patients. Hepatology 2009; 50(Suppl): 1026-7A.
• 26
  Cooper C, Lawitz EJ, Ghali P, et al. Evaluation of VCH-759 monotherapy in hepatitis C infection. J Hepatol 2009; 51: 39–46.
• 27
  Lawitz E, Cooper C, Rodriguez-Torres M, et al. Safety, tolerability and antiviral activity of VCH-916, a novel non-nucleoside HCV polymerase inhibitor in patients with chronic HCV genotype 1 infection. J Hepatol 2009; 50(Suppl): S37.
• 28
  Zeuzem S, Asselah T, Angus PW, et al. High SVR following IFN-free treatment of chronic HCV GT1 infection for 4 weeks with HCV protease inhibitor BI 201335, polymerase inhibitor BI 207127 and ribavirin, followed by BI 201335 and PegIFN/ribavirin – the SOUND-C1 study. Hepatology 2011; 54(Suppl): 486-7A.
• 29
  Nelson DR, Gane EJ, Jacobson IM, et al. VX-222/telaprevir in combination with peginterferon-alfa-2a and ribavirin in treatment-naive genotype 1 HCV patients treated for 12 weeks: ZENITH study, SVR12 interim analysis. Hepatology 2011; 54: 1435A.
• 30
  Lawitz E, Rodriguez-Torres M, DeMicco M, et al. Antiviral activity of ANA598, a potent non-nucleoside polymerase inhibitor, in chronic hepatitis C patients. J Hepatol 2009; 50(Suppl): S384.
• 31
  Zeuzem S, Buggisch P, Agarwal K, et al. The protease inhibitor, GS-9256, and non-nucleoside polymerase inhibitor tegobuvir alone, with ribavirin, or pegylated interferon plus ribavirin in hepatitis C. Hepatology 2012; 55: 749–58.
• 32
  Nelson DR, Lawitz E, Bain V, et al. High SVR12 with 16 weeks of tegobuvir and GS-9256 with peginterferon-alfa 2a and ribavirin in treatment-naive genotype 1 HCV patients. J Hepatol 2012; 56(Suppl): S6–7.
• 33
  Vertex Announces Positive Results from Viral Kinetic Study of the Nucleotide Analogue ALS-2200 in People with Hepatitis C: Available at http://investors.vrtx.com/releasedetail.cfm?releaseid=696581. Accessed: October 2012.
• 34
  Zeuzem S, Soriano V, Asselah T, et al. Virologic response to an interferon-free regimen of BI 201335 and BI 207127, with and without ribavirin, in treatment-naive patients with chronic genotype-1 HCV infection: week 12 interim results of the SOUND-C2 study. Hepatology 2011; 54(Suppl): 1436A.
• 35
  Poordad F et al., A 12-week interferon-free regimen of ABT-450/r + ABT-333 + ribavirin achieved SVR12 in more than 90% of treatment-naïve HCV genotype-1-infected subjects and 47% of previous non-responders. J Hepatol 2012; 56(Suppl): S549–50.
• 36
  Sulkowski M, Rodriguez-Torres M, Lawitz E, et al. Complete SVR4 rates in treatment-naïve HCV genotype 1a and 1b patients who achieved vRVR with an interferon-free all-oral regimen. Hepatology 2012; 56(Suppl): 298A.

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Vertex Announces Presentation of New Data from Hepatitis C Development Program at AASLD Annual Meeting

October 1, 2012

Vertex Announces Presentation of New Data from Hepatitis C Development Program at AASLD Annual Meeting

CAMBRIDGE, Mass.--(BUSINESS WIRE)-- Vertex Pharmaceuticals Incorporated (Nasdaq: VRTX) today announced that 11 abstracts from its hepatitis C research and development program will be presented at The Liver Meeting®, the 63rd Annual Meeting of the American Association for the Study of Liver Diseases (AASLD) in Boston, November 9 to 13, 2012. Presentations will include data on INCIVEK® (telaprevir) tablets, Vertex's approved medicine for the treatment of genotype 1 chronic hepatitis C, and two of the company's hepatitis C treatments in development: VX-222, a non-nucleoside polymerase inhibitor, and ALS-2200 (VX-135), a uridine nucleotide analogue pro-drug.

These accepted abstracts are now available on the AASLD website at: https://www.aasld.org/lm2012.

ALS-2200 (VX-135) Presentations

1. "ALS-2200, a Novel Once-Daily Nucleotide HCV Polymerase Inhibitor, Demonstrates Potent Antiviral Activity over 7 Days in Treatment-Naïve Genotype 1 (GT1) Patients." November 11, 2012, 5:00 p.m. EST. Oral Presentation #86

2. "Preclinical Characterization of ALS-2200, a Potent Nucleotide Polymerase Inhibitor for the Treatment of Chronic Hepatitis C." November 13, 2012, 8:00 a.m. - 12:00 p.m. EST. Poster Presentation #1882

3. "Analysis of ALS-2200, a Novel Potent Nucleotide Analog, Combination Drug Interactions in the Hepatitis C Virus (HCV) Subgenomic Replicon System." November 13, 2012, 8:00 a.m. - 12:00 p.m. EST. Poster Presentation #1887

INCIVEK (telaprevir) Presentations

1. "Telaprevir in Combination with Peginterferon Alfa-2a/Ribavirin in HCV/HIV Co-infected Patients: SVR24 Final Study Results." November 11, 2012, 4:15 p.m. EST. Oral Presentation #54

2. "Evaluation of Liver and Plasma HCV RNA Kinetics and Telaprevir Levels in Genotype 1 HCV Patients Treated with Telaprevir using Serial Fine Needle Aspirates." November 13, 2012, 9:00 a.m. EST. Oral Presentation #215

3. "The Safety of Telaprevir in the Absence of Interferon and/or Ribavirin: Analysis of On-Treatment Data from the ZENITH Trial." November 11, 2012, 8:00 a.m. - 5:30 p.m. EST. Poster Presentation #786

4. "Factors Predictive of Anemia Development in Treatment-Experienced Patients Receiving Telaprevir (TVR) Plus Peginterferon/Ribavirin (PR) in the REALIZE Trial." November 11, 2012, 8:00 a.m. - 5:30 p.m. EST. Poster Presentation #771

5. "Rate of Disappearance of Telaprevir Resistant Variants Using Clonal and Population Sequence Data from Phase 3 Studies." November 11, 2012, 8:00 a.m. - 5:30 p.m. EST. Poster Presentation #756

6. "Deep Sequencing of the HCV NS3/4A Region Confirms Low Prevalence of the Telaprevir-Resistant Variants Both at Baseline and End of Study." November 11, 2012, 8:00 a.m. - 5:30 p.m. EST. Poster Presentation #1091

VX-222 Presentations

1. "VX-222, Telaprevir and Ribavirin in Treatment-Naïve Patients with Genotype 1 Chronic Hepatitis C: Results of the ZENITH Study Interferon-Free Regimen." November 13, 2012, 11:15 a.m. EST. Oral Presentation #231

2. "Effect of Hepatic Impairment on the Pharmacokinetics of VX-222: Results From a Multicenter Phase 1 Study." November 13, 2012, 8:00 a.m.- 12:00 p.m. EST. Poster Presentation #1880

About ALS-2200 (VX-135) and VX-222

ALS-2200 (VX-135) is a uridine nucleotide analogue pro-drug that appears to have a high barrier to drug resistance based on in vitro studies. It is designed to inhibit the replication of the hepatitis C virus by acting on the NS5B polymerase. In vitro studies of the compound showed antiviral activity across all genotypes, or forms, of the hepatitis C virus, including genotypes more prevalent outside of the United States.

Vertex gained worldwide rights to ALS-2200 through an exclusive worldwide licensing agreement signed with Alios BioPharma, Inc. in June 2011. The agreement also includes a research program that will focus on the discovery of additional nucleotide analogues that act on hepatitis C polymerase. Vertex has the option to select additional compounds for development emerging from the research program.

VX-222 is an oral medicine in development that is a non-nucleoside inhibitor of the HCV NS5B polymerase. Vertex has worldwide commercial rights for VX-222.

About INCIVEK

INCIVEK® (telaprevir) tablets is an oral medicine that acts directly on the hepatitis C virus protease, an enzyme essential for viral replication.

INCIVEK was approved by the U.S. Food and Drug Administration (FDA) in May 2011 and by Health Canada in August 2011 for use in combination with pegylated-interferon and ribavirin for adults with genotype 1 chronic hepatitis C with compensated liver disease (some level of damage to the liver but the liver still functions), including cirrhosis (scarring of the liver). INCIVEK is approved for people who are new to treatment, and for people who were treated previously with interferon-based treatment but who did not achieve a sustained viral response, or viral cure (relapsers, partial responders and null responders).

Vertex developed telaprevir in collaboration with Janssen and Mitsubishi Tanabe Pharma. Vertex has rights to commercialize telaprevir in North America where it is being marketed under the brand name INCIVEK (in-SEE-veck). Janssen has rights to commercialize telaprevir in Europe, South America, Australia, the Middle East and certain other countries. In September 2011, telaprevir was approved in the European Union and Switzerland. Telaprevir is known as INCIVO® in Europe. Mitsubishi Tanabe Pharma has rights to commercialize telaprevir in Japan and certain Far East countries. In September 2011, telaprevir was approved in Japan and is known as Telavic®.

IMPORTANT SAFETY INFORMATION

Indication

INCIVEK® (telaprevir) is a prescription medicine used with the medicines peginterferon alfa and ribavirin to treat chronic (lasting a long time) hepatitis C genotype 1 infection in adults with stable liver problems, who have not been treated before or who have failed previous treatment. It is not known if INCIVEK is safe and effective in children under 18 years of age.

Important Safety Information

INCIVEK should always be taken in combination with peginterferon alfa and ribavirin. Ribavirin may cause birth defects or death of an unborn baby. Therefore, a patient should not take INCIVEK combination treatment if she is pregnant or may become pregnant, or if he is a man with a sexual partner who is pregnant. Patients must use two forms of effective birth control during treatment and for the 6 months after treatment with these medicines. Hormonal forms of birth control, including birth control pills, vaginal rings, implants or injections, may not work during treatment with INCIVEK.

INCIVEK and other medicines can affect each other and can also cause side effects that can be serious or life threatening. There are certain medicines patients cannot take with INCIVEK combination treatment. Patients should tell their healthcare providers about all the medicines they take, including prescription and non-prescription medicines, vitamins and herbal supplements.

INCIVEK can cause serious side effects including skin reactions, rash and anemia that can be severe. The most common side effects of INCIVEK include itching, nausea, diarrhea, vomiting, anal or rectal problems, taste changes and tiredness. There are other possible side effects of INCIVEK, and side effects associated with peginterferon alfa and ribavirin also apply to INCIVEK combination treatment. Patients should tell their healthcare providers about any side effect that bothers them or doesn't go away.

Please see full Prescribing Information for INCIVEK including the Medication Guide, available at www.INCIVEK.com.

About Hepatitis C

Hepatitis C is a serious liver disease caused by the hepatitis C virus, which is spread through direct contact with the blood of infected people and ultimately affects the liver.1 Chronic hepatitis C can lead to serious and life-threatening liver problems, including liver damage, cirrhosis, liver failure or liver cancer.1 Though many people with hepatitis C may not experience symptoms, others may have symptoms such as fatigue, fever, jaundice and abdominal pain.1

Unlike HIV and hepatitis B virus, chronic hepatitis C can be cured.2 However, approximately 60 percent of people do not achieve SVR,3,4,5 or viral cure,6 after treatment with 48 weeks of pegylated-interferon and ribavirin alone. If treatment is not successful and a person does not achieve a viral cure, they remain at an increased risk for progressive liver disease.7,8

More than 170 million people worldwide are chronically infected with hepatitis C.6 In the United States, up to 5 million people have chronic hepatitis C and 75 percent of them are unaware of their infection.9,10 Hepatitis C is four times more prevalent in the United States compared to HIV.10 The majority of people with hepatitis C in the United States were born between 1945 and 1965, accounting 82 percent of people with the disease.11 Hepatitis C is the leading cause of liver transplantations in the United States and is reported to contribute to 15,000 deaths annually.12,13 By 2029, total annual medical costs in the United States for people with hepatitis C are expected to more than double, from $30 billion in 2009 to approximately $85 billion.10

About Vertex

Vertex creates new possibilities in medicine. Our team discovers, develops and commercializes innovative therapies so people with serious diseases can lead better lives.

Vertex scientists and our collaborators are working on new medicines to cure or significantly advance the treatment of hepatitis C, cystic fibrosis, rheumatoid arthritis and other life-threatening diseases.

Founded more than 20 years ago in Cambridge, Mass., we now have ongoing worldwide research programs and sites in the U.S., U.K. and Canada. Today, Vertex has more than 2,000 employees around the world, and for three years in a row, Science magazine has named Vertex one of its Top Employers in the life sciences

Vertex's press releases are available at www.vrtx.com.

(VRTX-GEN)

References:

1 Centers for Disease Control and Prevention. Hepatitis C Fact Sheet: CDC Viral Hepatitis. Available at: http://www.cdc.gov/hepatitis/HCV/PDFs/HepCGeneralFactSheet.pdf Updated June 2010. Accessed September 21, 2012.

2 Pearlman BL and Traub N. Sustained Virologic Response to Antiviral Therapy for Chronic Hepatitis C Virus Infection: A Cure and So Much More. Clin Infect Dis. 2011 Apr;52(7):889-900.

3 Manns MP, McHutchison JG, Gordon SC, et al. Peginterferon alfa-2b plus ribavirin compared with interferon alfa-2b plus ribavirin for initial treatment of chronic hepatitis C: a randomised trial. Lancet. 2001;358:958-965.

4 Fried MW, Shiffman ML, Reddy KR, et al. Peginterferon alfa-2a plus ribavirin for chronic hepatitis C virus infection. N Engl J Med. 2002;347:975-982.

5 McHutchison JG, Lawitz EJ, Shiffman ML, et al; IDEAL Study Team. Peginterferon alfa-2b or alfa-2a with ribavirin for treatment of hepatitis C infection. N Engl J Med. 2009;361:580-593.

6 Ghany MG, Strader DB, Thomas DL, Seeff, LB. Diagnosis, management and treatment of hepatitis C; An update. Hepatology. 2009;49 (4):1-40.

7 Morgan TR, Ghany MG, Kim HY, Snow KK, Lindsay K, Lok AS. Outcome of sustained virological responders and non-responders in the Hepatitis C Antiviral Long-Term Treatment Against Cirrhosis (HALT-C) trial. Hepatology. 2008;50(Suppl 4):357A (Abstract 115).

8 Veldt BJ, Heathcote J, Wedmeyer H. Sustained virologic response and clinical outcomes in patients with chronic hepatitis C and advanced fibrosis. Annals of Internal Medicine. 2007; 147: 677-684.

9 Chak, E, et. al. Hepatitis C Virus Infection In USA: An Estimate of True Prevalence. Liver Intl. 2011;1096 -1098.

10 Institute of Medicine of the National Academies. Hepatitis and liver cancer: a national strategy for prevention and control of hepatitis B and C. Colvin HM and Mitchell AE, ed. Available at: http://www.iom.edu/Reports/2010/Hepatitis-and-Liver-Cancer-A-National-Strategy-for-Prevention-and-Control-of-Hepatitis-B-and-C.aspx Updated January 11, 2010. Accessed September 21, 2012.

11 Smith, BD, et al. Hepatitis C Virus Antibody Prevalence, Correlates and Predictors among Persons Born from 1945 through 1965, United States, 1999-2008. AASLD 2011 Annual Meeting.

12 Volk MI, Tocco R, Saini S, Lok, ASF. Public health impact of antiviral therapy for hepatitis C in the United States. Hepatology. 2009;50(6):1750-1755.

13 S.D. Holmberg, K.N. Ly., et.al. The Growing Burden of Mortality Associated with Viral Hepatitis in the United States, 1999-2007. AASLD 2011 Annual Meeting.


Vertex Pharmaceuticals Incorporated
Media:
Erin Emlock or Zach Barber, 617-444-6992
mediainfo@vrtx.com
or
Investors:
Kelly Lewis, 617-444-7530
or
Michael Partridge, 617-444-6108

Source: Vertex Pharmaceuticals Incorporated


News Provided by Acquire Media

May 26 Weekend Reading-Relevant Hepatitis C Research and News

Girl Reading  by Pablo Picasso

Greetings,

Most weekends this blog offers up a few substantial links to relevant HCV information, click here for previous "Weekend Reading" articles. Hepatitis C New Drug Research And Liver Health has an article database which includes full-text and abstracts on hepatitis C.  View the RSS feed for this weekend of updates.

Meeting Coverage In The News

EASL 2012

EASL: Telaprevir 100% Effective for IL28B CC, Adding VX-222 Overcomes Unfavorable Genes

23 May 2012

Written by Liz Highleyman

Adding telaprevir (Incivek) to pegylated interferon and ribavirin cured all hepatitis C patients with the favorable IL28B gene pattern, researchers reported at the 47th International Liver Congress (EASL 2012) last month in Barcelona. Another study found that adding the experimental HCV protease inhibitor VX-222 raised cure rates even for those with unfavorable IL28B patterns.

Continue Reading.... 

DDW -HCV

DDW, the annual meeting of the American Gastroenterological Association (AGA) Institute, is jointly sponsored by the American Association for the Study of Liver Diseases, the AGA, the American Society for Gastrointestinal Endoscopy and the Society for Surgery of the Alimentary Tract.

Increased mortality observed in patients with HCV and diabetes

May 23, 2012

Those with both hepatitis C and diabetes had a higher mortality rate when compared with those who had either condition alone, according to research presented during Digestive Disease Week 2012.

When we observed the rates for patients who had both hepatitis C and diabetes, we saw that the mortality rate was significantly increased — at least three times the amount of patients died in the group with both hepatitis C and diabetes compared with patients who had neither condition,”

Meira Abramowitz, MD, of the division of internal medicine at SUNY Downstate Medical Center in Brooklyn, N.Y., told Infectious Disease News.

Abramowitz and colleagues conducted a retrospective chart review of patients treated at the VA New York Harbor Healthcare System from 2002 to 2003. Mortality data were collected from 2011.

Patients with HCV were identified from a registry of more than 6,000 patients with HCV. These patients were age-matched with other patients without HCV from the VA system, some of whom had diabetes.

The final cohort included 1,846 patients, of whom 18.8% had neither HCV nor diabetes and 12.8% had both. Of the 579 patients with diabetes, 31.3% died vs. 20.6% of the 1,213 patients without diabetes. Of the 1,141 patients with HCV, 24.5% died vs. 24.1% of the 692 patients without HCV.

Of the 237 patients with both HCV and diabetes, 36.3% died vs. 20.8% of the 867 patients with HCV alone, 27.8% of the 342 patients with diabetes alone and 20.2% of the 346 patients with neither disease. The OR for mortality in patients with diabetes vs. patients without diabetes was 1.7 (95% CI, 1.3-2.24). This increased to 1.89 when the researchers compared patients with both HCV and diabetes to patients with neither disease (95% CI, 1.45-2.46).

“We are not entirely sure why this mortality increase took place because both of these conditions have their own individual complications,” Abramowitz said. “Hepatitis C can develop into hepatocellular carcinoma and hepatic encephalopathy, while diabetes can progress into diabetic nephropathy and diabetic neuropathy with accompanying cardiovascular complications.”

References:

• Abramowitz M. #MO1905. Presented at: Digestive Disease Week 2012 Annual Meeting; May 19-22; San Diego.

Disclosures:

• Dr. Abramowitz reports no relevant financial disclosures.

Source

DDW

DDW-Hepatitis C Patients May Be Able to Delay Therapy
Improved treatment coming for HIV/ HCV co-infection

DDW-New research examines impact of liver disease

DDW-Statins Shown to Be Safe in Patients With Cirrhosis

DDW: Body-Building Supplements Top List of Hepatotoxic Agents

DDW- Georgetown doctors test milk thistle to counter amanitin toxins in the liver

View Additional DDW articles..............

Research

Clinical Reviews

Gastroenterology & Endoscopy News 

ISSUE: MAY 2012 | VOLUME: 63:5

Update on the Diagnosis and Treatment of Hepatitis C

by Arun B. Jesudian, MD and Ira M. Jacobson, MD

Hepatitis C virus (HCV) infection is a national and global public health concern, affecting up to 4 million individuals in the United States and 200 million individuals worldwide. Despite a declining incidence of new HCV infections in the United States, the prevalence of advanced liver disease secondary to chronic HCV infection, including cirrhosis and hepatocellular carcinoma, is expected to rise in the coming years.

Download to read this article in PDF document:

Update on the Diagnosis and Treatment of Hepatitis C

This article is in PDF format and it requires Abobe Reader. If you do not have Adobe Reader installed on your computer then please download and install from the link below.

Download Adobe Reader

Newsletters/Bulletins

NICE Bites is a monthly bulletin which summarises key prescribing points from NICE guidance. This edition includes two topics; Anaphylaxis and Hepatis C – technology appraisals.

NICEBitesMay2012AnaphylaxisHepC.pdf

Healthy You

Oregon State University

Like curry? New biological role identified for compound used in ancient medicine

CORVALLIS, Ore. – Scientists have just identified a new reason why some curry dishes, made with spices humans have used for thousands of years, might be good for you.

New research at Oregon State University has discovered that curcumin, a compound found in the cooking spice turmeric, can cause a modest but measurable increase in levels of a protein that's known to be important in the "innate" immune system, helping to prevent infection in humans and other animals.

This cathelicidin antimicrobial peptide, or CAMP, is part of what helps our immune system fight off various bacteria, viruses or fungi even though they hadn't been encountered before.

Prior to this, it was known that CAMP levels were increased by vitamin D. Discovery of an alternative mechanism to influence or raise CAMP levels is of scientific interest and could open new research avenues in nutrition and pharmacology, scientists said.

Turmeric is a flavorful, orange-yellow spice and an important ingredient in many curries, commonly found in Indian, South Asian and Middle Eastern cuisine. It has also been used for 2,500 years as a medicinal compound in the Ayurvedic system of medicine in India – not to mention being part of some religious and wedding ceremonies. In India, turmeric is treated with reverence.

The newest findings were made by researchers in the Linus Pauling Institute at OSU and published today in the Journal of Nutritional Biochemistry, in collaboration with scientists from the University of Copenhagen in Denmark. The work was supported by the National Institutes of Health.

"This research points to a new avenue for regulating CAMP gene expression," said Adrian Gombart, an associate professor of biochemistry and biophysics in the Linus Pauling Institute. "It's interesting and somewhat surprising that curcumin can do that, and could provide another tool to develop medical therapies."

The impact of curcumin in this role is not nearly as potent as that of vitamin D, Gombart said, but could nonetheless have physiologic value. Curcumin has also been studied for its anti-inflammatory and antioxidant properties.

"Curcumin, as part of turmeric, is generally consumed in the diet at fairly low levels," Gombart said. "However, it's possible that sustained consumption over time may be healthy and help protect against infection, especially in the stomach and intestinal tract."

In this study, Chunxiao Guo, a graduate student, and Gombart looked at the potential of both curcumin and omega-3 fatty acids to increase expression of the CAMP gene. They found no particular value with the omega-3 fatty acids for this purpose, but curcumin did have a clear effect. It caused levels of CAMP to almost triple.

There has been intense scientific interest in the vitamin D receptor in recent years because of potential therapeutic benefits in treating infection, cancer, psoriasis and other diseases, the researchers noted in their report. An alternative way to elicit a related biological response could be significant and merits additional research, they said.

The CAMP peptide is the only known antimicrobial peptide of its type in humans, researchers said. It appears to have the ability to kill a broad range of bacteria, including those that cause tuberculosis and protect against the development of sepsis.

Is coffee good for the liver?
ISIC the Institute for Scientific Information on Coffee©
14th May 2012

Questions patients ask

Q: Is coffee good for the liver?
A: Research suggests that regular, moderate coffee consumption can lower people’s risk of developing a range of liver diseases – including cancer, fibrosis (scar tissue that builds up within the liver) and cirrhosis (the result of a long-term build up of scar tissue within the liver).

Q: How many cups of coffee do I need to drink to see a benefit?
A: It is too early to make specific recommendations concerning the levels of coffee intake that may be beneficial for liver function. Research suggests that regular, moderate coffee consumption may be beneficial

1,2. However certain patients with specific conditions may need to limit their caffeine consumption. For example, pregnant women are advised to limit their caffeine intake to 200-300mg per day – the equivalent amount found in 2-3 regular cups of coffee.

Q: Are the benefits of coffee down to caffeine?
A: While research has suggested that caffeine may slow down the progression of liver fibrosis, alcoholic cirrhosis and liver cancer

3,4,5, the extent to which caffeine is implicated in the reduced risk of developing these diseases remains unclear. Research also suggests that other coffee constituents, including cafestol and kahweol6 (naturally occurring compounds found in the oily part of coffee), and antioxidants may have a beneficial effect on liver function.

Q: Is decaffeinated coffee as good as regular coffee?
A: Research suggests that caffeine might play a role in the relationship between coffee drinking and lower risk of liver disease; however, currently there are no published studies specifically investigating the effects of decaffeinated coffee on liver function.

Q: If I’m a coffee drinker, can I drink more alcohol without increasing my risk of liver disease?
A: No. All medical advice makes clear that excessive alcohol consumption is detrimental to health. Adults, who choose to consume alcohol, should be aware of the recommended advice for safe consumption. While scientific research suggests that coffee drinking may have a beneficial effect on liver function, the risks associated with excessive alcohol consumption are not counter balanced by coffee consumption.

Q: I’ve heard that the effects of alcohol on the liver can be different for women than for men. Is the same true for coffee?
A: Generally, the effect of coffee drinking does not differ between the sexes; however, some groups, such as pregnant women, smokers, or women taking hormone replacement therapy do metabolise caffeine at a different rate to those in the general population. Pregnant women are advised to limit their caffeine intake to 200-300mg per day – the equivalent amount found in 2-3 regular cups of coffee.

Q: Do all types of coffee have the same effect?
A: Studies investigating the relationship between coffee and liver function have demonstrated beneficial effects in various types of coffee preparation, including filtered, instant and espresso coffee.

Q: Is it safe for individuals with liver disease to drink coffee?
A: Yes, there is no evidence to suggest that moderate coffee drinking poses any dangers for individuals with liver disease. In fact, some studies suggest coffee may slow down the progression of liver disease in some patients.

Q: Does coffee have any benefits for individuals with liver disease?
A: Research has shown that individuals with liver disease who regularly drink moderate amounts of coffee tend to display a milder progression of the disease7,8.
 Source and References

Stanford internist discusses how diet affects health

May 24

Think you eat a nutritious diet but still find yourself battling sugar cravings, feeling fatigued and struggling to lose weight? Then carve out time today to watch this talk by Stanford internist Nicole Peoples, DO. In this video lecture, she explains what happens once food enters your system, how your body responds to it and why the food choices you’re making could be contributing to these and other symptoms.

http://scopeblog.stanford.edu/2012/05/stanford-internist-discusses-how-diet-affects-health/