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Pharmacokinetic characteristics of telaprevir in healthy Korean male subjects and comparisons with Japanese

Authors Choi Y, Yoon S , Matsumoto K, Ohta Y, Lee S , Yu KS , Jang IJ 

Received 2 August 2017

Accepted for publication 6 November 2017

Published 30 April 2018 Volume 2018:12 Pages 1045—1051

DOI https://doi.org/10.2147/DDDT.S148117

Checked for plagiarism Yes

Review by Single anonymous peer review

Peer reviewer comments 2

Editor who approved publication: Professor Anastasios Lymperopoulos



Yewon Choi,1 Seonghae Yoon,1 Kyoko Matsumoto,2 Yoshiyasu Ohta,3 SeungHwan Lee,1 Kyung-Sang Yu,1 In-Jin Jang1

1Department of Clinical Pharmacology and Therapeutics, Seoul National University College of Medicine and Hospital, Seoul, Republic of Korea; 2Ikuyaku Integrated Value Development Division, Mitsubishi Tanabe Pharma Corporation, Osaka, Japan; 3Sohyaku Innovative Research Division, Mitsubishi Tanabe Pharma Corporation, Tokyo, Japan

Introduction: Telaprevir, a reversible selective inhibitor of viral protease and a potential blocker of viral replication, is indicated for the treatment of hepatitis C virus genotype 1 infection. In this study, the pharmacokinetic profile, safety, and tolerability of telaprevir and the effect of food on telaprevir exposure were evaluated in healthy Korean subjects, and compared with data from a previous study in Japanese male subjects.
Methods: The single ascending dose study was conducted in 3 dose-based groups (500, 750, and 1,250 mg, six subjects each) in a fasted state. In the multiple dose study, eight subjects in the fed state received 750 mg of telaprevir once on Day 1 and every 8 hours from Day 2 until the morning of Day 6. Serial blood samples for pharmacokinetic analysis were collected for up to 24 hours in the single ascending dose study and for 6 days in the multiple dose study. Individual pharmacokinetic parameters were calculated using a non-compartmental analysis method. Safety and tolerability profiles were evaluated throughout the study.
Results: Following multiple administrations of telaprevir, maximum plasma concentrations (Cmax), area under the concentration–time curve (AUC0–8), and Ctrough (concentration at 8 h after drug administration) increased by ~2.41-fold. Compared to fasted state values, mean Cmax and AUC0–24 increased by 4.92- and 4.81-fold, respectively, after food intake. The Cmax and AUCinf of Korean subjects were 26%–34% higher than those of Japanese subjects; however, these differences were not clinically significant. All observed adverse events were mild and there was no discontinuation due to AEs.
Conclusion: In conclusion, the telaprevir’s pharmacokinetic characteristics were similar in Korean and Japanese subjects. Telaprevir was well tolerated in a single dose of up to 1,250 mg and in multiple doses of 750 mg.

Keywords: antiviral agents, hepatitis C virus, NS3/4A protease, ethnicity, pharmacokinetic profile

Introduction

Hepatitis C virus (HCV) is one of the major causes of liver disease and may lead to liver cirrhosis, hepatocellular cancer, liver failure, and even death.1 While HCV is prevalent worldwide, the most affected regions are North Africa, Central Asia, and East Asia.2 Among the seven recognized genotypes (1–7) of HCV strains, HCV genotype 1 is considered responsible for the majority of HCV cases in East Asia.

Although a large proportion of the HCV infection cases in Korea are caused by HCV genotype 1, only a few treatment options are currently available. Telaprevir is a reversible, selective inhibitor of the HCV NS3/4A protease, which results in inhibition of viral replication.3 Orally administered telaprevir is absorbed in the small intestine, metabolized extensively in the liver, and eliminated in the feces.4,5 Approved in 2011 in the USA and Japan, telaprevir is indicated, in combination with peg-interferon alpha and ribavirin, for the treatment of HCV genotype 1 infection.6 The Korean Ministry of Food and Drug Safety requires supporting data regarding telaprevir pharmacokinetics (PK), pharmacodynamics, safety, and dosing regimens in order to extrapolate foreign clinical data to the Korean population. The Ministry of Food and Drug Safety also accepts a PK study if a drug is less likely to be sensitive to ethnic factors.7 According to previous studies, telaprevir has a flat effect–concentration curve for efficacy and safety and a wide therapeutic dose range, undergoes metabolism via cytochrome P450 (CYP)3A4 and other multiple pathways including non-CYP-mediated metabolism,5 and has little potential for inappropriate use.8,9 As the phenotype distribution of CYP3A4 is similar in Korean and Japanese populations, telaprevir is expected to be less sensitive to ethnic factors between the two ethnicities and to manifest few interethnic differences between Korean and Japanese subjects. Therefore, this study was conducted to 1) investigate the safety, tolerability, and PK characteristics of telaprevir after single and multiple administration in healthy Korean male volunteers in both a fasted and a fed state, and 2) compare these PK characteristics with those of Japanese subjects from a previous study.

Subjects and methods

Study population

Healthy Korean male subjects aged 20–55 years with a body mass index of 18.5–25.0 kg/m2 were eligible for this study. Study protocols (ClinicalTrials.gov: NCT01766167) and informed consent forms were reviewed and approved by the Institutional Review Board of Seoul National University Hospital. Written informed consent was obtained from all subjects after providing an adequate explanation of the study. Subjects were evaluated on the basis of medical history, physical examination, vital signs, 12-lead electrocardiography, and clinical laboratory tests. Subjects were excluded if they had any evidence of a current or previous history of cardiac disease or positive results on tests for hepatitis B viral antigen or HCV antibody at the time of examination.

Study design

This was an open-label, uncontrolled study of telaprevir. The telaprevir used in the study was supplied by Mitsubishi Tanabe Pharma Corporation (Tokyo, Japan) as a 250 mg tablet formulation. In the single ascending dose (SAD) study, 18 participants were assigned to three dose groups (500, 750, and 1,250 mg) and received a single oral dose of telaprevir in the fasted state on Day 1. In the multiple dose study, eight healthy volunteers received 750 mg of telaprevir once in the morning of Day 1, 3 times a day (every 8 h) from Day 2 to 5, and once in the morning on Day 6 in the fed state after taking standard breakfast. For the fed state experiments, subjects maintained a fasted state until breakfast before dosing. Otherwise, subjects received regular meals at scheduled times at the study site.

Sample collection and bioanalytical methods

In the SAD study, 3 mL blood samples were obtained at 0 (pre-dose), 0.25, 0.5, 0.75, 1, 1.5, 2, 2.5, 3, 4, 5, 6, 8, 10, 12, 16, and 24 h after drug administration. For the multiple dose study, blood samples were obtained at 0 (pre-dose), 0.25, 0.5, 0.75, 1, 1.5, 2, 2.5, 3, 4, 5, 6, 8, 10, 12, and 16 h after drug administration on Days 1 and 6; at 0 (pre-dose), 8, and 16 h after drug administration on Days 2 and 5; and at 0 (pre-dose) h on Days 3 and 4.

Blood samples were collected in vacuum tubes with EDTA-3K, mixed with inversion 8–10 times, and then cooled on ice immediately. The samples were centrifuged at 1,500× g for 10 min at 4°C within 30 min from the sampling point, and 0.05 mL of 10% formic acid was added to 1 mL of the separated plasma to prevent epimerization of telaprevir.

Plasma concentrations of telaprevir were determined using validated liquid chromatography–mass spectrometry with tandem mass spectrometric detection. The linear range for quantitation of telaprevir in plasma was 2–500 ng/mL, and the lower limit of quantitation was 2.000 ng/mL. Precision and accuracy were evaluated by monitoring quality control samples and standard samples for the calibration curve in the same batch of analytical samples. The telaprevir assays were performed at the Analytical Research Center, Shimura Laboratory, Mitsubishi Chemical Medicine Corporation, Japan.

Safety assessment

Adverse events (AEs) were identified throughout the study by asking open questions. The following characteristics of all AEs were assessed by the investigator: intensity, time course, outcome, seriousness, and relationship to telaprevir. Vital signs, clinical laboratory tests, physical examinations, and clinical evaluations were conducted to evaluate the safety and tolerability of telaprevir.

PK and statistical analysis

Individual PK parameters were evaluated using a non-compartmental analysis (NCA) method with WinNonlin® (Version 6.4; Certara, Princeton, NJ, USA). The following parameters were calculated or determined: area under the curve (AUC), maximum plasma concentration (Cmax), concentration at 8 h after drug administration (Ctrough), time to reach maximum plasma concentration (tmax), apparent clearance (CL/F), terminal half-life (t1/2), and apparent volume of distribution (Vd/F). The accumulation ratio of multiple administrations was calculated as the ratio of Cmax, AUC0–8, and Ctrough values on Day 6 to the values on Day 1 in a fed state.

All statistical analyses were performed using SAS 9.2® (SAS Institute Inc., Cary, NC, USA). Demographic characteristics and PK parameters were analyzed using descriptive statistics, including mean and percent coefficient of variation (CV%). Log-transformed Cmax, AUC0–24, and AUCinf were analyzed for statistical analysis. Dose proportionality for Cmax and AUCinf was examined using power models in the SAD study, and the effect of food on the Cmax, AUC0–24, and AUCinf of 750 mg single-dose telaprevir was assessed using an analysis of variance model with a fixed effect for fed or fasted treatment.

Comparison of PK

In Japan, a randomized, open-label, SAD study of telaprevir was conducted several years earlier (Mitsubishi Tanabe Pharma Corporation, unpublished data, 2013). A single 500, 750, or 1,250 mg dose of telaprevir was administered to healthy Japanese male subjects in the fasted state (n=6 in each dose group), and the subjects in the 750 mg group were administered the same dose again in a fed state. PK samplings were conducted up to 24 h after the dose was administered. The results of the Japanese PK study were used to compare telaprevir PK characteristics between Korean and Japanese subjects. Log-transformed PK parameters (Cmax and AUCinf) of both ethnicities were analyzed using an analysis of variance model with fixed effects for ethnicity, dose, and dose by ethnicity.

Results

Subject characteristics

Demographic characteristics of the 26 subjects enrolled in this study were similar across dose groups, including single- dose and multiple-dose studies. Overall, the mean age and body weight (±SD) were 27.2±3.4 years and 67.4±7.2 kg, respectively. In the multiple-dose study, two subjects withdrew consent after receiving telaprevir. One subject was withdrawn after the morning dose on Day 4, and the other subject was withdrawn after the first dose on Day 1. These subjects were included in the safety and tolerability analysis, but excluded from the PK analysis. The demographic characteristics were not significantly different between Korean and Japanese subjects.

Pharmacokinetics

After oral administration of a single dose of telaprevir in the fasted state, the plasma telaprevir concentration slowly reached Cmax at 3.75–5.00 h and then declined monoexponentially with a half-life (t1/2) of 5.37–9.32 h (Table 1; Figure 1). In the fasted state, the Cmax, AUC0–24, and AUCinf of telaprevir tended to increase with increasing dose. When log-transformed Cmax, AUC0–24, and AUCinf were assessed with the power model, dose proportionality was observed with a wide CI range.

Table 1 Pharmacokinetic parameters of telaprevir in fasted and fed states after administration of single and multiple doses of telaprevir in healthy Korean subjects
Notes: All values are presented as mean (CV%). aGeometric means of pharmacokinetic parameters of fasted and fed states are compared after a single dose of 750 mg of telaprevir. btmax is presented as the median (minimum, maximum).
Abbreviations: AUC0–t, area under the concentration–time curve until time point of t; AUCinf, area under the concentration–time curve to infinity; CL/F, apparent clearance; Cmax, peak plasma concentration; Ctrough, minimum plasma concentration; CV%, percent coefficient of variation; t1/2, terminal elimination half-life; tmax, time to peak plasma concentration; Vd/F, apparent volume of distribution.

Figure 1 Mean plasma concentration–time plot after a single oral dose of telaprevir 500, 750, or 1,250 mg in fasted and fed states (left, linear scale; right, semi-logarithmic scale).

Repeated telaprevir administration every 8 h for 6 days under the fed condition resulted in a cumulative increase in plasma telaprevir concentration (Table 1; Figure 2). The accumulation ratios of Cmax, AUC0–8, and Ctrough were 1.461, 2.413, and 1.540, respectively, after 6-day multiple administrations.

Figure 2 Mean plasma concentration–time plot after a single dose (1 day) and at steady state after multiple doses (6 days) of telaprevir 750 mg in a fed state.

Following the administration of 750 mg telaprevir with food, the Cmax, AUC0–24, and AUCinf of telaprevir increased by ~4.73-fold compared to values in the fasted condition (Table 1). These results suggest a significant effect of food on telaprevir exposure. Food did not affect the t1/2 in the 750 mg dose group, but the tmax was delayed to 6 h after drug administration compared to 5 h in the fasted group.

When the PK profiles of telaprevir in Korean subjects were compared with those in Japanese subjects (Table 2), the extent of telaprevir exposure was 20%–30% higher in the Korean subjects. However, 90% CIs of geometric mean ratios of Cmax and AUCinf in Korean versus Japanese subjects included the value of unity (1.260 [0.925, 1.717] and 1.337 [0.973, 1.838] as point estimate [90% CI], respectively) and high variability (CV% of 46.4% and 49.9%, respectively). Distributions of dose-normalized Cmax and AUCinf were also similar between Korean and Japanese subjects (Figure 3). Thus, the difference in PK profiles between the two ethnicities was not clinically significant.

Table 2 Pharmacokinetic parameters of telaprevir in fasted and fed states after administration of single dose of telaprevir in healthy Japanese subjects
Notes: All values are presented as mean (CV%). atmax is presented as the median (minimum, maximum).
Abbreviations: AUC0–t, area under the concentration–time curve until time point of t; AUCinf, area under the concentration–time curve to infinity; CL/F, apparent clearance; Cmax, peak plasma concentration; CV%, percent coefficient of variation; t1/2, terminal elimination half-life; tmax, time to peak plasma concentration; Vd/F, apparent volume of distribution.

Figure 3 Box plots of dose-normalized Cmax (left) and AUCinf (right) after a single oral dose of 500, 750, or 1,250 mg of telaprevir in Korean and Japanese subjects.

Safety and tolerability

A single telaprevir dose of up to 1,250 mg and multiple doses of 750 mg for 6 days were generally safe and well tolerated in healthy subjects. A total of nine AEs occurred, and they were considered to be related to telaprevir in 7 out of 18 Korean subjects in the SAD study. Asthenia (two cases) and diarrhea (two cases) were the most frequently reported AEs. In the multiple-dose study, 12 AEs were reported in five out of eight subjects, and abdominal distension was the most common AE. All these AEs were considered mild, and subjects recovered without sequelae. There were no clinically important changes relative to the baseline laboratory test values or vital signs, or electrocardiography and physical examination findings.

Discussion

The objective of this study was to investigate the PK and safety profile of telaprevir, including the effect of food on telaprevir exposure and the extent of accumulation after multiple doses of telaprevir in healthy subjects. NCA revealed a CV% of exposure that ranged from 35% to 63% in both the fasted and fed states, implying that telaprevir PK varies widely between subjects. This variability was consistent with the results of previous studies where AUC0–8, Cmax, and Cmin ranged from 19% to 48%.8 PK analysis revealed that the dose proportionality of telaprevir was unclear after SADs from 500 to 1,250 mg, likely because of the large PK variability.

The CL/F at the steady state after multiple doses was comparable to that of the first dose, whereas the half-life and Vd/F were more than doubled. Considering that telaprevir is extensively metabolized by the hepatic CYP3A enzyme and transported by the P-glycoprotein (P-gp) transporter, time-dependent inhibition of hepatic CYP3A4 might have caused the increased half-life and decreased drug elimination after multiple administrations.911 However, little change of CL/F and increased Vd/F were not consistent with a previous report, where clearance was reduced at steady state.15 Change of F after multiple administrations has not been investigated in the former studies, but if any, it might be increased because of time-dependent inhibition and saturation of intestinal CYP3A4 and P-gp transporter. Change of F might have affected CL/F and Vd/F, but increased Vd/F could not be explained with these factors or other findings of this study.

In this study, highly variable PK characteristics were observed when CV% values were calculated. We also observed delayed telaprevir absorption after oral administration in the fasted state, with a median tmax of 3.75–5.00 h. In a previous study, telaprevir absorption was characterized by an initial slow phase followed by a second rapid phase, with an average lag time of 0.21 h.12 These features seem to be partly due to the lipophilicity of telaprevir, which results in a long intestinal transit time and high variability in the absorption process, thereby affecting Cmax and tmax.4

Assessment of the effect of food on telaprevir exposure after administration of the 750 mg dose revealed that food intake significantly increased telaprevir exposure by a maximum of 5.73-fold, and the median value of tmax increased up to 6 h compared to exposure under the fasted condition. This result is consistent with the findings of another study where food intake enhanced telaprevir exposure by 3- to 4-fold.5 The bioavailability of telaprevir during the absorption and metabolism phases is determined by several factors, including the aforementioned transporters and metabolic enzymes, and dissolution, ionization, and gastric emptying time. It can be suggested that intake of standard meal increases the solubility of telaprevir which is lipid soluble, and food intake increases the transit time and duration of absorption of telaprevir in the small intestine, thereby resulting in increased Tmax and total intestinal absorption of telaprevir. Food intake mainly delayed and prolonged absorption phase of telaprevir, but did not significantly affect elimination of telaprevir, considering that t1/2 of telaprevir after single dose was similar in the fasted group and the fed group. Meanwhile, it is less likely that absorption of telaprevir was affected by pH change after food intake, because dissolution of telaprevir is independent of pH. The variability of bioavailability is also affected by several factors, and the types of food or total food intake itself may influence the bioavailability of telaprevir, although the absolute bioavailability of telaprevir has not been determined in humans.8,13

The lipophilic characteristics of telaprevir may influence the distribution phase by allowing it to penetrate tissues beyond the systemic circulation, resulting in a large apparent volume of distribution (Vd/F) with high intraindividual variability.5 In Korean subjects, CV% of Vd/F was 78.7%, which was consistent with the results of a pooled population PK analysis conducted in previous Phase 2 and 3 studies where intersubject variability was estimated as 72.2%.8 The expression of the P-gp transporter and the CYP3A4 are also potential sources of high variability of telaprevir absorption and metabolism.10,14 When telaprevir was administered under fed conditions in this study, interindividual variabilities of Cmax, AUC0–8, and AUC0–24 were smaller than those under fasted conditions. The high variability of PK parameters under fasted conditions may be partly due to the highly variable bioavailability of telaprevir. In addition, the variability of PK parameters might decrease after food intake because of increased bioavailability and decreased variability due to diet.

Clinically, telaprevir is prescribed with other drugs such as antiviral agents to avoid drug resistance and enhance viral eradication or immunosuppressants in posttransplantation treatment. Thus, drug interaction should be assessed before prescription and monitored during the treatment period. Regarding peg-interferon and ribavirin which are used in combination with telaprevir, the AUC and Cmax of telaprevir were increased by about 30%–40% after coadministration with peg-interferon, while ribavirin did not affect telaprevir exposure and telaprevir did not change the exposure of either peg-interferon or ribavirin in a previous study.5 For other drugs, a significant increase of AUC and Cmax (more than 5-fold) of tacrolimus, midazolam, or atorvastatin was observed after coadministration with telaprevir in other studies. Some drug interactions with telaprevir can be explained by telaprevir’s inhibitory effect on CYP3A4 metabolic pathway (eg, tacrolimus, midazolam, and so on) or on organic anion-transporting polypeptide transporter (eg, atorvastatin); however, the mechanisms of most interactions still remain to be studied.5,9,15,16

When the PK exposure parameters (Cmax, AUC0–24, and AUCinf) calculated using NCA were compared between Korean and Japanese subjects, we found small differences in both fasting and fed states. However, these differences were considered clinically insignificant. Because of the wide therapeutic range and large individual variability of PK–pharmacodynamic characteristics of telaprevir, the difference in exposures between Korean and Japanese subjects is trivial from a clinical perspective.17 When the individual dose-normalized Cmax and AUCinf were plotted, their distributions were similar between Korean and Japanese subjects (Figure 3). Moreover, the 90% CI of the geometric mean ratio of each exposure parameter included the value of unity, suggesting that the difference between the two ethnic groups was statistically insignificant. Additionally, while telaprevir is mainly metabolized by hepatic CYP3A4, ethnic-based genetic differences in the effect of CYP3A4 on the PK of telaprevir may be minimal because allele frequencies of CYP3A4 are similar between the Korean and Japanese populations.6

This study has some limitations. Although subject demographic characteristics were homogeneous and well distributed throughout the dose groups, the sample size, with only six subjects in each fasted group and eight subjects in the fed group, was small for investigating the PK parameters in the presence of large variability. Also, sex differences in PK characteristics could not be analyzed because only male subjects were included in this study. Considering the characteristics of absorption, distribution, and metabolism of telaprevir, a study with a larger sample size is warranted for the evaluation of dose proportionality and ethnic differences.

In conclusion, when single doses of telaprevir ranging from 500 to 1,250 mg were administered to healthy Korean subjects, dose proportionality was unclear because of large variability and telaprevir exposure was increased after food intake. Telaprevir was well tolerated up to 1,250 mg as a single dose in the fasting state and as 750 mg multiple doses in the fed state. Moreover, the PK characteristics were similar in healthy Korean and Japanese male subjects.

Acknowledgments

We would like to appreciate all the support of the staff at the Clinical Trial Center, Seoul National University Hospital during the conduct of this study. This work was supported by Mitsubishi Tanabe Pharma Corporation, Tokyo, Japan, who sponsored the study.

Disclosure

KM and YO are employees of Mitsubishi Tanabe Pharma Corporation, Tokyo, Japan. The authors report no other conflicts of interest in this work.


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