Assessment of the effects of renal impairment and smoking on the pharmacokinetics of a single oral dose of the soluble guanylate cyclase stimulator riociguat (BAY 63-2521).

Renal impairment is a common comborbidity in patients with pulmonary hypertension. The breakdown of riociguat, an oral soluble guanylate cyclase stimulator used to treat pulmonary hypertension, may be affected by smoking because polycyclic aromatic hydrocarbons in tobacco smoke induce expression of one of the metabolizing enzymes, CYP1A1. Two nonrandomized, nonblinded studies were therefore performed to investigate the pharmacokinetics and safety of a single oral dose of riociguat 1.0 mg in individuals with mild, moderate, or severe renal impairment compared with age-, weight-, and sex-matched healthy controls, including either smokers and nonsmokers (study I) or nonsmokers alone (study II). Pharmacokinetic analyses focused on the integrated per-protocol data set of both studies (N = 63). In patients with renal impairment, the renal clearance of riociguat was reduced and its terminal half-life prolonged compared with those in healthy controls. There was a monotonic relationship between creatinine clearance on treatment day and riociguat renal clearance (R (2) = 0.62). However, increased riociguat exposure with decreasing renal function was not strictly proportional. Riociguat exposure appeared to be greater in nonsmokers than in the combined population of smokers and nonsmokers, irrespective of renal function. Adverse events were mild to moderate and in line with the mode of action of riociguat. No serious adverse events occurred. In conclusion, renal impairment was associated with reduced riociguat clearance compared with that in controls; however, riociguat exposure in patients with renal impairment was highly variable, and ranges overlapped with those observed in healthy controls.

Effects of omeprazole and aluminum hydroxide/magnesium hydroxide on riociguat absorption.

Riociguat, a soluble guanylate cyclase stimulator, is a novel therapy for the treatment of pulmonary hypertension. Riociguat bioavailability is reduced in neutral versus acidic conditions and therefore may be affected by concomitant use of medications that increase gastric pH. The effect of coadministration of the proton pump inhibitor omeprazole or the antacid AlOH/MgOH on the pharmacokinetics, safety, and tolerability of riociguat 2.5 mg was characterized in two open-label, randomized, crossover studies in healthy males. In study 1, subjects pretreated for 4 days with omeprazole 40 mg received cotreatment with omeprazole plus riociguat or riociguat alone (no pretreatment) on day 5 (n = 12). In study 2, subjects received cotreatment with 10 mL AlOH/MgOH plus riociguat or riociguat alone (n = 12). Pre- and cotreatment with omeprazole decreased riociguat bioavailability (mean decreases in area under the plasma concentration-time curve [AUC] and maximum concentration in plasma [C max] were 26% and 35%, respectively). Cotreatment with AlOH/MgOH resulted in greater decreases in riociguat bioavailability (mean decreases in AUC and C max were 34% and 56%, respectively). In both studies, most adverse events (AEs) were of mild intensity, and no serious AEs were reported. No additional safety signals were identified. Treatment with riociguat, with or without omeprazole or AlOH/MgOH, was well tolerated, with a good safety profile. Owing to the resulting increase of gastric pH, riociguat bioavailability is reduced by coadministration with AlOH/MgOH and, to a lesser extent, by coadministration with omeprazole. Thus, antacids should not be administered within an hour of receiving riociguat, but no dose adjustment is required for coadministration of proton pump inhibitors.

Pharmacokinetic interaction of riociguat with ketoconazole, clarithromycin, and midazolam.

Riociguat is a soluble guanylate cyclase stimulator for the treatment of pulmonary hypertension that is principally metabolized via the cytochrome P450 (CYP) pathway. Three studies in healthy males investigated potential pharmacokinetic interactions between riociguat and CYP inhibitors (ketoconazole, clarithromycin, and midazolam). In two studies, subjects were pretreated with either once-daily ketoconazole 400 mg or twice-daily clarithromycin 500 mg for 4 days before cotreatment with either riociguat 0.5 mg ± ketoconazole 400 mg or riociguat 1.0 mg ± clarithromycin 500 mg. In the third study, subjects received riociguat 2.5 mg 3 times daily (tid) for 3 days, followed by cotreatment with riociguat 2.5 mg tid ± midazolam 7.5 mg. Pharmacokinetic parameters, the effect of smoking on riociguat pharmacokinetics, safety, and tolerability were assessed. Pre- and cotreatment with ketoconazole and clarithromycin led to increased riociguat exposure. Pre- and cotreatment with riociguat had no significant effect on midazolam plasma concentrations. In all studies, the bioavailability of riociguat was reduced in smokers because its clearance to the metabolite M1 increased. Riociguat ± ketoconazole, clarithromycin, or midazolam was generally well tolerated. The most common treatment-emergent adverse events (TEAEs) across all studies were headache and dyspepsia. One serious TEAE was reported in the midazolam study. Owing to the potential for hypotension, concomitant use of riociguat with multipathway inhibitors, such as ketoconazole, should be approached with caution. Coadministration of riociguat with strong CYP3A4 inhibitors, for example, clarithromycin, does not require additional dose adjustment. No significant drug-drug interaction was revealed between riociguat and midazolam.

Assessment of the effects of hepatic impairment and smoking on the pharmacokinetics of a single oral dose of the soluble guanylate cyclase stimulator riociguat (BAY 63-2521).

Riociguat, a soluble guanylate cyclase stimulator developed for the treatment of pulmonary hypertension, is metabolized in part by the liver. Expression of one of the metabolizing enzymes, CYP1A1, is induced by aromatic hydrocarbons in tobacco smoke. Two nonrandomized, nonblinded studies were conducted to investigate the pharmacokinetics of riociguat in individuals with mild (Child-Pugh A) or moderate (Child-Pugh B) hepatic impairment associated with liver cirrhosis compared with that in age-, weight-, and sex-matched healthy controls: study 1 included smokers and nonsmokers, and study 2 included nonsmokers only. Data from these studies were integrated for analysis. All participants (N = 64) received a single oral dose of riociguat 1.0 mg. Riociguat exposure was significantly higher in individuals with Child-Pugh B hepatic impairment than in healthy controls (ratio: 153% [90% confidence interval: 103%-228%]) but was similar in those with Child-Pugh A hepatic impairment and controls. The half-life of the riociguat metabolite M1 was prolonged in patients with Child-Pugh B or A hepatic impairment compared with that in controls by approximately 43% and 24%, respectively. Impaired hepatic function was associated with higher riociguat exposure in nonsmokers compared with the population of smokers and nonsmokers combined. Riociguat's safety profile was similar in individuals with impaired or normal liver function. In conclusion, moderate hepatic impairment was associated with increased riociguat exposure compared with that in controls, probably as a result of reduced clearance of the metabolite M1. This suggests that dose titration of riociguat should be administered with particular care in patients with moderate hepatic impairment.

Population pharmacokinetics of single-dose riociguat in patients with renal or hepatic impairment.

This population pharmacokinetics (PK) analysis characterized the PK of the oral soluble guanylate cyclase stimulator riociguat in patients with renal or hepatic impairment and determined whether smoking affects riociguat dosing. Two phase 1 studies were performed in patients with renal impairment (n = 72, of whom 11 were smokers), and two were performed in those with hepatic impairment (n = 64, of whom 12 were smokers). Plasma and urine samples were collected after a single oral dose of riociguat 1.0 or 0.5 mg. Nonlinear mixed-effects modeling was used to develop a combined, two-compartment population PK model for riociguat and its main metabolite, M1. Riociguat and M1 clearance was split into renal and nonrenal parts; the nonrenal part for riociguat was divided into metabolism to M1 and a metabolic (nonrenal) part. Total clearance of riociguat was 1.912 L/h. The main route of riociguat clearance is metabolism to M1 (1.2 L/h). In this model, hepatic function biomarkers or Child-Pugh classification had no significant effect on riociguat or M1 clearance. Nonrenal (nonmetabolism) riociguat clearance was similar in all groups. Renal clearance (0.242 L/h) contributed less to riociguat total clearance, mainly determined by glomerular filtration (0.174 L/h). Renal impairment reduced riociguat and M1 clearance. Hepatic or renal impairment had limited effects on total exposure to riociguat. However, individual dose adjustment of riociguat should be administered with particular care in patients with moderate hepatic or renal impairment. Riociguat is not recommended in severe hepatic or renal impairment. Smoking reduced riociguat exposure by significantly increasing metabolism to M1.

Population pharmacokinetics and the pharmacokinetic/pharmacodynamic relationship of riociguat in patients with pulmonary arterial hypertension or chronic thromboembolic pulmonary hypertension.

This analysis aimed to characterize the pharmacokinetics (PK) and PK/pharmacodynamic (PK/PD) relationship of riociguat and its metabolite M1 in patients with chronic thromboembolic pulmonary hypertension (CTEPH) or pulmonary arterial hypertension (PAH). Blood samples were collected in two phase 3 studies-PATENT-1 (Pulmonary Arterial Hypertension Soluble Guanylate Cyclase-Stimulator Trial 1; 12 weeks; PAH) and CHEST-1 (Chronic Thromboembolic Pulmonary Hypertension Soluble Guanylate Cyclase-Stimulator Trial 1; 16 weeks; CTEPH)-and long-term extensions. Patients were initially randomized to receive placebo or riociguat, and they received riociguat in the extensions. Nonlinear mixed-effects modeling was used to develop a population PK model describing riociguat PK. PK/PD relationships were investigated by comparing derived PK parameters with changes in PD parameters. Covariate analyses included smoking status, bosentan comedication, bilirubin levels, and baseline creatinine clearance. The PK of riociguat/M1 was described by a one-compartment model. Mean population estimates for riociguat absorption rate constant, clearance, and volume of distribution were 2.17/h, 1.81 L/h, and 32.3 L, respectively; for M1 they were 0.258/h, 3.16 L/h, and 124 L. Interindividual variability was moderate for riociguat and moderate to high for M1. There was no evidence of time- or dose-dependent changes in riociguat/M1 PK. Riociguat clearance was higher in smokers (120% increase) and bosentan-treated patients (36% increase) than in nonsmokers and those not receiving bosentan. There was an inverse correlation between bilirubin and riociguat clearance. In PK/PD analyses, 6-minute walk distance was related to hemodynamic parameters, particularly pulmonary vascular resistance. Riociguat PK were described by a one-compartment model. Effects of covariates on riociguat and M1 PK were established, and a PK/PD relationship was demonstrated. (ClinicalTrials.gov identifiers: PATENT-1, NCT00810693; PATENT-2, NCT00863681; CHEST-1, NCT00855465; CHEST-2, NCT00910429.).

Pharmacokinetics of the soluble guanylate cyclase activator cinaciguat in individuals with hepatic impairment.

Cinaciguat is intended for use in patients with acute decompensated heart failure. The drug is eliminated predominantly via the liver and, therefore, the potential impact of hepatic impairment on cinaciguat pharmacokinetics needs to be determined. This nonrandomized, open-label, observational study investigated the pharmacokinetics of cinaciguat in individuals with mild (Child-Pugh A; n = 8) or moderate (Child-Pugh B; n = 8) hepatic impairment and matched healthy volunteers (n = 16). An exploratory analysis of pharmacodynamic parameters was also conducted. Individuals with mild hepatic impairment and their controls received a single (4-hour) intravenous infusion of 100 µg/h cinaciguat, whereas individuals with moderate hepatic impairment and their controls received 50 µg/h. Cinaciguat was well tolerated and had a favorable safety profile. The most frequent treatment-emergent adverse events were headache (4 participants) and spontaneous penile erection (2 participants). In individuals with mild hepatic impairment, only minor increases in plasma cinaciguat concentrations and no significant differences in pharmacodynamic parameters were observed, compared with controls. Individuals with moderate hepatic impairment had a substantially higher cinaciguat exposure than controls. This higher exposure was associated with more pronounced vasodilatation. This study demonstrates that in individuals with mild hepatic impairment, individual dose adaptation may not be required.