Telaprevir and Peginterferon with or without Ribavirin for Chronic HCV Infection

New England Journal of Medicine

Volume 360:1839-1850 April 30, 2009 Number 18

Telaprevir and Peginterferon with or without Ribavirin for Chronic HCV Infection

Christophe Hézode, M.D., Nicole Forestier, M.D., Geoffrey Dusheiko, M.D., Peter Ferenci, M.D., Stanislas Pol, M.D., Tobias Goeser, M.D., Jean-Pierre Bronowicki, M.D., Marc Bourlière, M.D., Shahin Gharakhanian, M.D., Leif Bengtsson, B.S.C., Lindsay McNair, M.D., M.P.H., Shelley George, M.D., Tara Kieffer, Ph.D., Ann Kwong, Ph.D., Robert S. Kauffman, M.D., Ph.D., John Alam, M.D., Jean-Michel Pawlotsky, M.D., Ph.D., Stefan Zeuzem, M.D., for the PROVE2 Study Team

Abstract

Editorial
by Hoofnagle, J. H.

ABSTRACT

Background In patients with chronic infection with hepatitis C virus (HCV) genotype 1, treatment with peginterferon alfa and ribavirin for 48 weeks results in rates of sustained virologic response of 40 to 50%. Telaprevir is a specific inhibitor of the HCV serine protease and could be of value in HCV treatment.

Methods

A total of 334 patients who had chronic infection with HCV genotype 1 and had not been treated previously were randomly assigned to receive one of four treatments involving various combinations of telaprevir (1250 mg on day 1, then 750 mg every 8 hours), peginterferon alfa-2a (180 µg weekly), and ribavirin(dose according to body weight). The T12PR24 group (81 patients) received telaprevir, peginterferon alfa-2a, and ribavirin for 12 weeks, followed by peginterferon alfa-2a and ribavirin for 12 more weeks. The T12PR12 group (82 patients) received telaprevir, peginterferon alfa-2a, and ribavirin for 12 weeks. The T12P12 group (78 patients) received telaprevir and peginterferon alfa-2awithout ribavirin for 12 weeks. The PR48 (control) group (82 patients) received peginterferon alfa-2a and ribavirin for 48 weeks. The primary end point, a sustained virologic response (an undetectable HCV RNA level 24 weeks after the end of therapy), was compared between the control group and the combined T12P12 and T12PR12 groups. Results The rate of sustained virologic response for the T12PR12 and T12P12 groups combined was 48% (77 of 160 patients), as compared with 46% (38 of 82) in the PR48 (control) group (P=0.89). The rate was 60% (49 of 82 patients) in the T12PR12 group (P=0.12 for the comparison with the PR48 group), as compared with 36% (28 of 78 patients) in the T12P12 group (P=0.003; P=0.20 for the comparison with the PR48 group). The rate was significantly higher in the T12PR24 group (69% [56 of 81 patients]) than in the PR48 group (P=0.004). The adverse events with increased frequency in the telaprevir-based groups were pruritus, rash, and anemia.

Conclusions

In this phase 2 study of patients infected with HCV genotype 1 who had not been treated previously, one of the three telaprevir groups had a significantly higher rate of sustained virologic response than that with standard therapy. Response rates were lowest with the regimen that did not include ribavirin.(ClinicalTrials.gov number, NCT00372385 [ClinicalTrials.gov]

Hepatitis C virus (HCV) is the most common infectious cause of chronic liver disease in Europe and the United States. Chronic hepatitis C may result in life-threatening complications, including cirrhosis and hepatocellular carcinoma. Antiviral therapy may result in a sustained virologic response, characterized by an undetectable HCV RNA level 24 weeks after the end of therapy, which correlates with a long-term clinical benefit. In patients infected with HCV genotype 1, the most common genotype worldwide, the standard combination of peginterferon alfa and ribavirin for 48 weeks results in rates of sustained virologic response of only 40 to 50%.1,2,3A number of new therapeutic approaches are being assessed.4 The nonstructural 3/4A (NS3/4A) serine protease processes the HCV polyprotein to generate mature viral proteins. Direct protease inhibition emerged as a promising target for therapy when a reduction in viral replication of several log10 units was shown after 2 days of administration of an NS3/4A protease inhibitor.5 Telaprevir is a reversible, selective, orally bioavailable inhibitor of the HCV NS3/4A serine protease.6 Telaprevir monotherapy for 14 days induced a median decline of more than 4.4 log10 units in the plasma HCV RNA level in patients with chronic HCV genotype 1 infection.7 In an early study, all 12 patients with HCV genotype 1 who were receiving telaprevir with peginterferon and ribavirin for 28 days had undetectable HCV RNA levels at the end of the therapy with these three study drugs.8 The Protease Inhibition for Viral Evaluation 2 (PROVE2) trial was a multicenter, randomized, partially double-blind, placebo-controlled phase 2b trial conducted in Europe to assess the efficacy and adverse event profile of various regimens combining telaprevir with peginterferon alfa-2a, with or without ribavirin, as compared with peginterferon alfa-2a and ribavirin alone, in patients infected with HCV genotype 1 who had not been treated previously.

Methods

Patients

Patients were enrolled at 28 centers in France, Germany, the United Kingdom, and Austria between August 2, 2006, and January 17, 2007. Eligibility criteria included no previous treatment for HCV infection, an age of 18 to 65 years, chronic HCV genotype 1 infection with detectable plasma HCV RNA levels, and no histologic evidence of cirrhosis within 2 years before study day 1. The protocol and informed-consent form were approved by appropriate ethics committees at all study centers, in accordance with national procedures. All patients provided written informed consent before participating in the study. The study was conducted in accordance with the Declaration of Helsinki, Good Clinical Practice guidelines, and local laws and regulations.

Study Design

This was a phase 2b, randomized, partially double-blind, placebo-controlled trial. Eligible patients were stratified on the basis of self-reported race or ethnic group (black or other) and baseline weight (>75 kg vs. 75 kg). Patients were randomly assigned to one of four treatment groups: the T12PR24 group, which received telaprevir (VX-950, Vertex Pharmaceuticals), peginterferon alfa-2a (Pegasys, Roche), and ribavirin (Copegus, Roche) for 12 weeks, followed by peginterferon alfa-2a and ribavirin for 12 more weeks; the T12PR12 group, which received telaprevir, peginterferon alfa-2a, and ribavirin for 12 weeks; the T12P12 group, which received telaprevir and peginterferon alfa-2a, without ribavirin, for 12 weeks; and the PR48 (control) group, which received placebo, peginterferon alfa-2a, and ribavirin for 12 weeks, followed by peginterferon alfa-2a and ribavirin for 36 more weeks. Randomization was performed through a central telephone-based system, in a 1:1:1:1 ratio (with randomization blocks of 4). In the PR48 group, as in clinical practice,9 if there was a decline of 2 log10 units in the plasma HCV RNA level at week 12 and the HCV RNA level was undetectable at week 24, treatment was continued; if not, treatment was stopped, since the chance of clearing the infection was extremely low.10,11. Telaprevir was given as a single dose of 1250 mg on study day 1, followed by a dose of 750 mg every 8 hours; peginterferon alfa-2a was given subcutaneously at a dose of 180 µg per week; ribavirin was given orally at a dose of 1000 mg per day (for body weight <75 kg) or 1200 mg per day (for body weight 75 kg). Treatment of the PR48, T12PR12, and T12PR24 groups was double-blinded through week 10. Treatment of the T12P12 group was not blinded, because the absence of ribavirin would result in discernable hematologic effects. Patients in the T12PR24, T12PR12, and T12P12 groups were required to have undetectable HCV RNA levels at the last study visit before the planned end of treatment (i.e., at week 10 for the T12PR12 and T12P12 groups and at week 20 for the T12PR24 group). If patients had detectableHCV RNA levels at this visit, they were to continue to receive peginterferon alfa-2a and ribavirin through treatment week 48. Since the intention was to assess the efficacy of shorter treatment durations, these patients were considered to have treatment failure in the analysis of a sustained virologic response. The study sponsor and the academic principal investigators were responsible for study design and protocol development. The manuscript was drafted by the principal academic authors with input from the publication committee (consisting of four academic authors). All authors had access to the data and assume responsibility for the accuracy and completeness of the data reported.

Efficacy Assessments

Plasma HCV RNA levels were measured with the use of the COBAS TaqMan HCV assay, version 1.0 (Roche Molecular Systems), with a lower limit of quantification of 30 IU per milliliter and a lower limit of detection of 10 IU per milliliter. HCV RNA assessments were performed at the screening visit, at days 1, 4, and 8, and at weeks 2, 3, 4, 6, 8, 10, and 12; additional assessments occurred at weeks 16, 20, and 24 in the T12PR24 and PR48 groups and at weeks 28, 36, and 48 in the PR48 group. All patients had a follow-up visit 2 weeks after completion of the study treatment. In patients in the three telaprevir-based groups who had completed all treatment (ending at week 12 or week 24), HCV RNA levels were also measured 1, 2, 4, 8, 12, 24, 36, and 48 weeks after completion of the study treatment. Viral breakthrough during therapy was defined as an increase of more than 1 log10 IU per milliliter from the lowest HCV RNA level or as an HCV RNA level above 100 IU per milliliter in patients with previously undetectable HCV RNA. Relapse was defined as a detectable HCV RNA level during the 24-week post-treatment period in patients who had undetectable HCV RNA at the end of treatment.

Safety Assessments

Safety assessments included physical examinations, recording of adverse events, and serum chemical and hematologic evaluations at all study visits, and electrocardiography at the start and end of the treatment period. The original protocol was amended in January 2007 to add specific evaluations for grade 3 or 4 rashes, including pharmacokinetic analysis and HLA typing of blood samples.
Stepwise temporary reductions or short interruptions of ribavirin or peginterferon alfa-2a therapy were permitted, to manage adverse events or laboratory abnormalities. Dose reduction or interruption of telaprevir was not allowed. The use of granulocyte colony-stimulating factor and erythropoietin was not allowed during the initial 12 weeks of study treatment.

Statistical Analysis

The main efficacy measure was the proportion of patients who had a sustained virologic response: an HCV RNA level that was undetectable (<10 IU per milliliter) 24 weeks after the completion of study treatment. The analysis included all patients who had undergone randomization and had received at least one dose of any study drug. The planned primary analysis was the comparison of the PR48 group with the T12PR12 group and the T12P12 group (which did not receive ribavirin) combined, and the planned secondary analysis was a comparison of each of the three telaprevir-based groups with the PR48 group. Assuming rates of sustained virologic response of 50% in the PR48 group and 70% in the combined T12PR12 and T12P12 groups, we calculated that with 80 patients who could be evaluated in the PR48 group and 160 who could be evaluated in the combined groups, the study would have a statistical power of at least 80% to show a significant difference. Five planned interim analyses were conducted by the sponsor, Vertex Pharmaceuticals, to monitor safety and assess antiviral efficacy during the treatment period. Each interim analysis included descriptive analyses of safety data (adverse events and laboratory data) and HCV RNA results. There were no stopping rules or a priori plans for changes to the study conduct on the basis of interim analyses. After the third interim analysis, it became apparent that the T12P12 group did not have a response during the treatment period that was similar to the response of the T12PR12 group, and the statistical-analysis plan was revised by the sponsor to remove the originally planned primary analysis. The original secondary analysis, a comparison of the sustained virologic response in each of the three telaprevir-based groups with the response in the PR48 group, became the primary analysis. Results of the fourth interim analysis (performed after all patients had reached the end of the treatment period and data on sustained virologic response were available for the T12PR24 group) and fifth interim analysis (conducted when the PR48 group was still undergoing follow-up but data on the post-treatment responses for the three telaprevir groups were available) were made available to the investigators and presented at scientific meetings. Because it is not clear how to adjust the interpretation of the analyses for these unplanned changes and multiple examinations of the data, the results are reported as originally planned. Treatment assignments were unblinded at week 10 for all patients; therefore, there was no data and safety monitoring board. Safety of the patients was monitored by investigators and three study medical monitors, who reviewed all safety events, and by means of a review of adverse-event data during the interim analyses. The comparisons between groups were performed with the use of Fisher's exact test. All reported P values are two-sided and have not been adjusted for multiple testing. A prespecified multivariate analysis to evaluate the possible relationshipbetween a sustained virologic response and baseline variables (age, weight and body-mass index, and baseline HCV RNA level) was performed by means of a logistic-regression model with a sustained virologic response as the dependent variable. The following factors were added post hoc and were also explored in the model: sex, HCV genotype 1 subtype (1a vs. 1b), and alanine aminotransferase and fasting glucose levels at baseline. Variables that had a weak association (P>0.20) with a sustained virologic response in the initial logistic-regression model were excluded from the final model.

Results

Characteristics of the Patients

Of 388 patients screened, 334 were randomly assigned to a treatment group and 323 received study medication (Figure 1). The characteristics of the treatment groups were similar at baseline

Figure 1. Enrollment and Follow-up among the Study Patients.
The reasons for the exclusion of the 54 patients were as follows: 29 did not meet the eligibility criteria (2 were not between 18 and 65 years of age, 2 had concurrent medical conditions, 6 had cirrhosis or another hepatic finding on biopsy, 8 had an HCV genotype other than 1, and 11 did not meet other criteria), 10 patients withdrew consent after starting the screening process, and 15 were excluded or the screening failed because of unknown reasons. Two patients underwent randomization twice (and were thus assigned two randomization numbers) in error. Of the 334 patients (332, in actuality) who underwent randomization, 11 (9, in actuality) did not receive any study drug: 5 patients withdrew consent between the time of randomization (5 to 7 days before the start of dosing) and day 1, 2 were withdrawn by the investigators (1 at the discretion of the investigator and 1 for noncompliance with study requirements), 1 was lost to follow-up, and 1 had cirrhosis but was randomized and then withdrawn. The protocol-defined stopping rule (stating that patients must have had a drop of 2 log10 units in the HCV RNA level, as compared with the baseline level, at week 12 of treatment and an undetectable HCV RNA level at week 24 of treatment to continue to receive the study drugs) was applicable only to the PR48 group.

Table 1. Baseline Characteristics of the Study Patients, According to Treatment Group.

Virologic Responses during the Treatment Period

Table 2 shows the proportion of patients with undetectable HCV RNA (<10 IU per milliliter) at weeks 4, 12, and 24 during the treatment period as well as 24 weeks after completion of planned treatment (the time of assessment for a sustained virologic response) in the four groups. The median time to an undetectable HCV RNA level was 113 days (range, 15 to 337) in the PR48 group, 28 days (range, 8 to 172) in the T12PR24 group, 22 days (range, 4 to 85) in the T12PR12 group, and 29 days (range, 4 to 86) in the T12P12 group. Figure 2 shows the mean change in HCV RNAlevels during the first 12 weeks of treatment.

Table 2. Undetectable HCV RNA Levels during and after Treatment, According to Treatment Group.

Figure 2. Mean Log10 HCV RNA Levels during the First 12 Weeks of Treatment, According to Treatment Group.
If HCV RNA values were detectable but not quantifiable (<30 IU per milliliter), for purposes of calculation, the value was considered as 20 IU per milliliter; if the value was undetectable (<10 IU per milliliter), the value was considered as 5 IU per milliliter. Data are shown for 81 patients in the T12PR24 group, 82 in the T12PR12 group, 78 in the T12P12 group, and 82 in the PR48 (control) group. The proportions of patients who had undetectable HCV RNA levels at weeks 4 and 12 were significantly higher in all telaprevir-based groups than in the PR48 group. At week 4, levels were undetectable in 69% of patients in the T12PR24 group, 80% in the T12PR12 group, and 50% in the T12P12 group (vs. 13% in the PR48 group, P<0.001 for each comparison). At week 12, levels were undetectable in 73% of patients in the T12PR24 group (vs. 43% in the PR48 group, P<0.001), 80% in the T12PR12 group (P<0.001), and 62% in the T12P12 group (P=0.02). At the end of treatment — i.e., at week 24 in the T12PR24 group, week 12 in the T12PR12 and T12P12 groups, and week 48 in the PR48 group — theproportions of patients with undetectable HCV RNA levels were higher in both groups receiving all three study drugs (70% in the T12PR24 group and 80% in the T12PR12 group) and in the T12P12 group (62%) than in the PR48 group (55%).

Sustained Virologic Response

A sustained virologic response, defined as an undetectable HCV RNA 24 weeks after completion of therapy, was the primary end point. In the three telaprevir-based groups, 19 patients (14 in the T12P12 group) had detectable HCV RNA at the last study visit before the planned end of treatment and were therefore assigned to complete a total of 48 weeks of peginterferon alfa-2a and ribavirin, according to the protocol. Seven patients (all in the T12P12 group) completed this treatment; three of the seven had a sustained virologic response but were counted as having treatment failure in the analysis of the rate of sustained virologic response.
The rate of sustained virologic response for the PR48 group was 46% (38 of 82 patients). According to the originally planned primary analysis, the rate of sustained virologic response for the combined T12P12 and T12PR12 groups was 48% (77 of 160, P=0.89 for the comparison with the PR48 group). In the T12PR24 group, a sustained virologic response was achieved in 47 of the 61 patients who completed the assigned treatment and in 9 of the 20 patients who discontinued the study treatment before week 24, for an overall rate of 69% (56 of 81 patients), which was significantly higher than that in the PR48 group (P=0.004). The rate of sustained virologic response was not significantly higher in the T12PR12 group or the T12P12 group than in the PR48 group. In the T12PR12 group, there was a sustained virologic response in 46 of the 72 patients who completed treatment and in 3 of the 10 who discontinued treatment, for an overall rate of 60% (49 of 82 patients, P=0.12 for the comparison with the PR48 group). In the group not receiving ribavirin (the T12P12 group), a sustained virologic response was achieved in 24 of the 70 patients who completed treatment and in 4 of the 8 who discontinued treatment, for an overall rate of 36% (28 of 78patients, P=0.20 for the comparison with the PR48 group). The difference between the rates in the T12PR12 group and the T12P12 group was significant (P=0.003).

Viral Breakthrough and Relapse

By week 12, a viral breakthrough had been observed in 1 of 82 patients (1%) in the PR48 group, 19 of 78 (24%) in the T12P12 group, 1 of 82 (1%) in the T12PR12 group, and 4 of 81 (5%) in the T12PR24 group. Additional viral breakthroughs occurred in 1 of the 81 patients in the T12PR24 group, after the completion of telaprevir, and in 3 of the 82 patients in the PR48 group between weeks 12 and 48. Relapse (defined as a detectable HCV RNA level during the 24-week post-treatment period in patients who had undetectable HCV RNA at the end of the treatment period) occurred in 8 of 57 patients (14%) in the T12PR24 group, 19 of 63 (30%) in the T12PR12 group, 22 of 46 (48%) in the T12P12 group, and 10 of 45 (22%) in the PR48 group. In the T12PR24 group, the relapse rate among those who had undetectable HCV RNA at weeks 4 and 12 was 7% (3 of 45 patients). In the T12PR24, T12PR12, and T12P12 groups, of the 133 patients with a sustained virologic response, 118 returned for follow-up visits through 48 weeks after the completion of treatment. Two of the 133 patients had a late relapse: 1 in the T12PR24 group had discontinued treatment on day 65 and had an HCV RNA level that became detectable 48 weeks after the end of treatment; the other, in the T12P12 group, had discontinued treatment on day 60 and had a detectable HCV RNA level 36 weeks after the end of treatment. In both patients, viral sequence analysis confirmed the recurrence of the original infection. Analysis of the full-length NS3 protease sequence was carried out in patients with a breakthrough and in those who had a relapse after completion of telaprevir therapy. HCV virus that had low-level resistance to telaprevir was found at baseline in 1% of patients. Among the 22 patients who had a viral breakthrough during the 12 weeks of telaprevir administration and had a viral RNA level above the limit of detection of the sequencing assay, wild-type virus was found in 1 (5%), variants with low-level resistance in 9 (41%), and variants with high-level resistance in 12 (55%) (Table 3). Among the 42 patients who had a relapse after completion of treatment with telaprevir and had a viral RNA level above the limit of detection of the sequencing assay, wild-type virus was found in 2 (5%), low-level resistant variants in 33 (79%) and high-level resistant variants in 7 (17%). In some patients who did not receive ribavirin, complex changes in sequence were seen during the study.

Table 3. Incidence of Amino Acid Substitutions in Patients Who Had Viral Breakthrough or Relapse.

Independent Predictors of Sustained Virologic Response

The association between a sustained virologic response and independent variables was explored with the use of a logistic-regression model. Treatment group and baseline HCV RNA level were the only two variables significantly associated with a sustained virologic response (P<0.001) (Table 1 in the Supplementary Appendix, available with the full text of this article at NEJM.org).

Safety

Table 4 lists the principal adverse events reported in each group. Pruritus and rash were more frequent in the telaprevirgroups than in the control group. Pruritus occurred in 51% of patients (41 of 81) in the T12PR24 group, 63% (52 of 82) inthe T12PR12 group, and 59% (46 of 78) in the T12P12 group, as compared with 35% (29 of 82) in the PR48 group. The incidence of rash was 49% (40 of 81 patients) in the T12PR24 group, 44% (36 of 82) in the T12PR12 group, and 47% (37 of 78) in the T12P12 group, as compared with 35% (29 of 82) in the PR48 group. The rashes in patients in the telaprevir-based groups were generally maculopapular and were clinically similar to those observed in drug reactions. The median time to the appearance of a rash of any severity in the telaprevir-based groups was 9 to 12 days. Severe (grade 3) rash was found in 7% of patients (6 of 81) in the T12PR24 group, 6% (5 of 82) in the T12PR12 group, and 3% (2 of 78) in the T12P12 group, but was not seen in the PR48 group (Table 4). There were no grade 4 rashes reported. Twelve of the 163 patients (7%) in the combined T12PR24 and T12PR12 groups discontinued treatment because of rash.

Table 4. Incidence of Adverse Events and Severe (Grade 3) Adverse Events between Baseline and Week 48, According to Treatment Group.

Telaprevir administration also affected hemoglobin levels during the treatment period. During the first 12 weeks of treatment, the median decrease in the baseline hemoglobin level was 3.0 g per deciliter in the PR48 group, 3.1 g per deciliter in the T12P12 group, and 3.6 and 3.9 g per deciliter in the T12PR24 and T12PR12 groups, respectively. Other adverse events were similar in type and frequency in the telaprevir-based groups and the control group. Twenty-eight of the 241 patients (12%) in the telaprevir-based groups discontinued the study treatment because of adverse events, including 18 patients who did so before week 12 (i.e., during the period of telaprevir administration), as compared with 6 of 82 patients (7%) in the control group.

Discussion

In this phase 2 study of patients infected with HCV genotype 1 who had not been treated previously, one of the three telaprevir-containing regimens tested — treatment with telaprevir for 12 weeks and peginterferon alfa-2a and ribavirin for 24 weeks (T12PR24) — resulted in a significantly higher rate, by approximately 20 percentage points, of sustained virologic response than was found with the standard therapy of 48 weeks of peginterferon alfa-2a and ribavirin (PR48). These data, together with those from a similar phase 2 study performed in the United States (PROVE1, described elsewhere in this issue of the Journal),12 support the performance of a larger, phase 3 trial of telaprevir in combination with peginterferon alfa-2a and ribavirin. However, several questions remain unanswered. Patients with cirrhosis were not evaluated. Durations of triple-combination therapies with peginterferon alfa, ribavirin, and telaprevir that differ from the durations tested in PROVE2 will require further investigation, as will the criteria for extension of peginterferon alfa and ribavirin therapy. Further investigation will shed light on the usefulness of tailoring therapy on the basis of the kinetics of the early viral response. Our results show the necessity of administering ribavirin in combination with peginterferon alfa and telaprevir. Ribavirinwill most likely be required in combination with the use of other specific HCV inhibitors and peginterferon alfa to achievethe high rates of sustained virologic response seen in our study. Among patients receiving telaprevir-based regimens, the addition of ribavirin increased the sustained virologic response rates by preventing relapse and the emergence of both low-level and high-level telaprevir resistance. In spite of its moderate, transient antiviral effect on HCV replication when administered as monotherapy,13 ribavirin has been shown to prevent viral breakthrough during, and relapse after, the treatment period by significantly accelerating the second slope of viral-RNA decrease in patients who have a response to the antiviral effect of peginterferon alfa.14 The modes of action of ribavirin remain under debate.15,16,17,18,19 Our study results are consistent with the notion that ribavirin does not act by directly inhibiting HCV replication, since it cannot be replaced by a potent HCV inhibitor in combination with peginterferon alfa-2a. Both rash and pruritus were frequently reported in this study, but they did not always occur in combination. Severe rash occurred in approximately 5% of patients treated with telaprevir. Both rash and pruritus regressed after withdrawal of telaprevir and administration of appropriate therapy, including topical treatments for symptoms and corticosteroids (in some cases, systemic corticosteroids). Patients receiving telaprevir should be clinically monitored for dermatologic reactions and treated appropriately. The optimal management of rash and its effect on treatment adherence and efficacy requires further investigation. Decreased hemoglobin levels were also more frequent among the patients receivingtelaprevir than among those in the control group, though the condition was not often a cause of treatment discontinuation.
In conclusion, although a significant improvement in sustained virologic response was not shown in association with two of the telaprevir regimens tested, 12 weeks of telaprevir combined with 24 weeks of peginterferon alfa-2a and ribavirin resulted in significantly higher rates of sustained virologic response than 48 weeks of peginterferon and ribavirin alone. This study therefore suggests that the use of telaprevir may improve the rate of sustained virologic response in patients with a chronic HCV genotype 1 infection. A drug-induced rash necessitated that telaprevir be discontinued in some patients. Larger and longer studies are required to assess the efficacy and safety of telaprevir for HCV infection.

Supported by Vertex Pharmaceuticals.
Dr. Hézode reports receiving consulting fees from Roche and Novartis and lecture fees from Gilead Sciences, Roche and Schering-Plough; Dr. Forestier, consulting fees from Tibotec Pharmaceuticals and lecture fees from Roche; Dr. Dusheiko, consulting fees from Hoffmann–La Roche, Schering-Plough, Tibotec Pharmaceuticals, and Vertex Pharmaceuticals; Dr. Ferenci, consulting fees from Novartis, Roche, Salix Pharmaceuticals, and Vertex Pharmaceuticals, lecture fees from Merz Pharmaceuticals, Roche, and Salix Pharmaceuticals, grant support from Roche, and investigator fees from Human Genome Sciences, Roche, Tibotec Pharmaceuticals, and Vertex Pharmaceuticals; Dr. Pol, consulting fees from Bristol-Myers Squibb, Boehringer-Ingelheim, Gilead Sciences, Idenix, Novartis, Roche, Schering-Plough, Tibotec Pharmaceuticals and Wyeth, lecture fees from Bristol-Myers Squibb, Boehringer-Ingelheim, Gilead Sciences, Roche, Schering-Plough, Tibotec, and Wyeth, and grant support from Roche; Dr. Goeser, grant support from Roche; Dr. Bronowicki, consulting and lecture fees from Roche and Schering-Plough; and Dr. Bourlière, consulting fees from Gilead Sciences, Roche, and Schering-Plough and lecture fees from Roche and Schering-Plough. Dr. Gharakhanian, Mr. Bengtsson, and Drs. McNair, George, Kieffer, Kwong, Kauffman, and Alam report being current or former employees of Vertex Pharmaceuticals and holding stock options in this entity. Dr. Pawlotsky reports receiving consulting fees from Abbott, AstraZeneca, Bristol-Myers Squibb, Gilead Sciences, GlaxoSmithKline, Merck, Roche, Schering-Plough, Tibotec Pharmaceuticals, Valeant Pharmaceuticals, and Vertex Pharmaceuticals and grant support from Gilead Sciences; and Dr. Zeuzem, consulting fees from Vertex and Roche and lecture fees from Roche. No other potential conflict of interest relevant to this article was reported. We thank the study coordinators, nurses, and staff at investigative sites and, especially, all patients involved in the PROVE2 study; Desiree Devonish, M.P.H., for clinical project management and Katia Alves, M.D., M.P.H, Claude Fiset, Lily Lee, Ph.D., Kevin Stephenson, M.S., and all members of the PROVE2 Clinical Working Groups (all at Vertex Pharmaceuticals); and ICON Clinical Research Teams in the European Union for study monitoring and management.

* Members of the Protease Inhibition for Viral Evaluation 2 (PROVE2) study team are listed in the Appendix.

Source Information

From Assistance Publique–Hôpitaux de Paris, Henri Mondor Hospital, University of Paris 12 and INSERM Unité 955, Créteil (C.H., J.-M.P.); Université Paris Descartes, INSERM Unité 567, and Assistance Publique–Hôpitaux de Paris, Cochin Hospital Paris, Paris (S.P.); INSERM Unité 724, University Hospital of Nancy, Vandoeuvre-les-Nancy (J.-P.B.); and St. Joseph Hospital, Marseille (M.B.) — all in France; J.W. Goethe University Hospital, Frankfurt (N.F., S.Z.); and University Hospital of Cologne, Cologne (T.G.) — both in Germany; Royal Free Hospital, London (G.D.); Medical University of Vienna, Vienna (P.F.); and Vertex Pharmaceuticals, Cambridge, MA (S. Gharakhanian, L.B., L.M., S. George, T.K., A.K., R.S.K., J.A.).

Drs. Hézode and Forestier contributed equally to this article.

Address reprint requests to Dr. Pawlotsky at the Department of Virology, Hôpital Henri Mondor, 51 Ave. du Maréchal de Lattre de Tassigny, 94010 Créteil, France, or at jean-michel.pawlotsky@hmn.aphp.fr.

References

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Appendix

The members of the PROVE2 study group were as follows: France — Y. Benhamou, Groupe Hospitalier Pitié–Salpêtrière, Paris; M. Bourlière, Hôpital Saint-Joseph, Marseille; J.-P. Bronowicki, Hôpital de Brabois, Nancy; P. Couzigou, Hôpital du Haut-Lévêque, Bordeaux; J.-D. Grangé, Hôpital Tenon, Paris; P. Marcellin, Hôpital Beaujon, Clichy; P. Mathurin, Hôpital Claude Hurriez, Lille; J.-M. Pawlotsky, Hôpital Henri Mondor, Université Paris 12, Créteil; S. Pol, Hôpital Cochin, Paris; L. Serfaty, Hôpital Saint Antoine, Paris; A. Tran, Hôpital de L'Archet 2, Nice; C. Trépo, Hôtel-Dieu, Lyon; J.-P. Zarski, Hôpital de la Tronche, Grenoble. Germany — T. Berg, Universitätsklinikum Charité, Berlin; P. Buggisch, Universitätsklinikum Hamburg-Eppendorf, Hamburg; H. Diepolder, Klinikum Grosshadern, Munich; A. Erhardt, Universitätsklinikum Düsseldorf, Düsseldorf; G. Gerken, Universitätsklinikum Essen, Essen; T. Goeser, Universitätsklinikum Köln, Cologne; R. Günther, Universitätsklinikum Kiel, Kiel; J. Rasenack, Universitätsklinikum Freiburg, Freiburg; W. Schmidt, Ruhr-Universität Bochum, Bochum; U. Spengler,Universitätsklinikum Bonn, Bonn; H. Wedemeyer, Medizinische Hochschule Hannover, Hannover; S. Zeuzem, Universitätsklinikum des Saarlandes, Hamburg. United Kingdom — G. Dusheiko, Royal Free Hospital & University College London Institute of Hepatology, London; D. Mutimer, Queen Elizabeth Hospital, Birmingham. Austria — P. Ferenci, Medizinische Universität Wien, Vienna.