Clinical Pharmacokinetics and Pharmacodynamics of the Endothelin Receptor Antagonist Macitentan

Pulmonary arterial hypertension (PAH) is a chronic disease characterized by an increase in pulmonary vascular resistance, which leads to right ventricular failure and ultimately death if not treated [1, 2]. PAH is a rare condition affecting 15–50 people per million population. Discussion of the classification, diagnosis, and assessment of PAH at consensus meetings has resulted in recommendations that were incorporated into international guidelines and were recently updated during the 5th World Symposium on Pulmonary Hypertension in 2013 in Nice, France [3, 4]. In short, PAH is the first of five general categories of pulmonary hypertension. It can be idiopathic or heritable, but can also be the result of drug or toxin use or associated with other diseases such as mixed connective tissue disease, HIV infection, portal hypertension, congenital heart disease, schistosomiasis, and chronic hemolytic anemia [3‐9].

The basis of the increase in pulmonary vascular resistance resides in a combination of factors such as endothelial dysfunction, increased contractility of small pulmonary arteries, proliferation and remodeling of endothelial and smooth muscle cells, and in situ thrombosis [10‐12].

The three identified mechanisms that are mainly involved in regulation of the pulmonary vascular pressure are the prostacyclin, nitric oxide (NO), and endothelin (ET) pathways. Both the prostacyclin and the NO pathway act directly on the vascular bed [11, 13].

ET-1, part of a family of closely related 21-amino-acid polypeptides, works through a different mechanism promoting endothelial dysfunction and vascular remodeling [11]. ET-1 achieves its effects by activation of specific G-protein-coupled cell surface receptors. Two subtypes of ET-1 have been identified, termed ET_A and ET_B receptors. ET_A receptors are predominantly located in vascular smooth muscle cells and cardiomyocytes and mediate contraction. ET_B receptors are also present in smooth muscle cells in which they have a similar function as ET_A, but are mainly located in vascular endothelial cells where they mediate vascular dilatation through NO release and regulate ET-1 uptake and production [14‐21]. Under normal conditions, ET-1 production and clearance of ET-1 from the vascular bed is balanced, but in diseases such as PAH, the balance is disrupted and leads to an increase in circulating levels of ET-1 and detrimental effects [22‐24]. It has been observed that in chronic pathological situations, ET_B receptors are down-regulated on endothelial cells and up-regulated on smooth muscle cells and fibroblasts [25‐28]. While it could be hypothesized that the beneficial effects of ET_B on the endothelial cells could be reduced by blockade of ET_B, selective ET_A blockade would leave the ET_B receptors that are up-regulated on smooth muscle cells functional. Specific blockade of ET_A has been shown to activate the renin–angiotensin system, potentially resulting in edema [29, 30]. Therefore, sustained blockade of both ET receptors may be a better strategy to obtain optimal efficacy and safety [26, 28, 31‐33].

ET receptor antagonists (ERAs) have been proven to be effective in the treatment of PAH [34‐38]. Treatment with approved ERAs has been shown to confer improvements in a number of important clinical endpoints, including exercise capacity, modified New York Heart Association (NYHA) functional class, and pulmonary hemodynamics [34‐38]. Both ET_A/ET_B receptor antagonists and selective ET_A receptor antagonists are currently licensed for the treatment of PAH [39, 40]. Traditionally, approval was granted based on short-term studies (12–16 weeks) with low patient numbers, in which an improvement in exercise capacity was shown, based on the distance walked in 6 min [41, 42]. However, current guidelines for clinical research on PAH encourage the conduct of long-term outcome studies with morbidity/mortality endpoints [43‐45]. Besides ERAs, other specific pharmacotherapies such as treatment with prostanoids, phosphodiesterase type-5 (PDE-5) inhibitors, or a stimulator of soluble guanylate cyclase are used. Guidelines have recently been revised to reflect current strategies with regard to targeted and combination therapy [1, 36].

Macitentan (Fig. 1), N-[5-(4-Bromophenyl)-6-[2-[(5-bromo-2-pyrimidinyl)oxy]ethoxy]-4-pyrimidinyl]-N′-propylsulfamide, is an oral, once-daily, potent dual ET_A/ET_B receptor antagonist.

Macitentan is metabolized to a major and pharmacologically active metabolite, ACT-132577. In functional assays, both macitentan and ACT-132577 behave as dual receptor antagonists. ACT-132577 is approximately fivefold less potent than macitentan on ET_A receptors and presents an ET_A/ET_B inhibitory potency ratio of 16, versus 50 for its parent compound [46]. Free median 50 % inhibition concentration (IC₅₀) values for ET_A and ET_B were within the range of free concentrations observed in humans treated with macitentan at the therapeutic dose of 10 mg, suggesting that ET_B blockade is achieved. In vivo, ET-1 plasma concentrations were increased, which is typical of treatment with a dual ERA and not a selective ERA [46].

This sulfamide was the result of a targeted medicinal chemistry program to identify a novel, potent ERA with high oral efficacy [47]. In preclinical models of hypertension and PAH, macitentan showed a dose-dependent decrease in mean arterial blood pressure without affecting the heart rate [46, 47]. This decrease was even observed when macitentan was given on top of the ERA bosentan, whereas this decrease was not observed when bosentan was given on top of macitentan [48]. Tissue targeting was achieved through an increase in acid dissociation constant (pKa) and log D values resulting in a higher affinity of macitentan for lipophilic structures [46]. In vitro, macitentan displayed insurmountable antagonism to ET receptors, due to its slower apparent receptor association rate when compared with other ERAs [49]. Therefore, macitentan could lead to a more effective blockage blockade of ET-1 than other ERAs [49].

Macitentan was granted approval for the treatment of PAH in several countries including the USA, Canada, Europe, and Switzerland and marketed as Opsumit^® at a dosing regimen of 10 mg once daily [50‐52] following the results of SERAPHIN (Study with an Endothelin Receptor Antagonist in Pulmonary Arterial Hypertension to Improve Clinical Outcome), a landmark phase III study. SERAPHIN was a long-term, randomized, placebo-controlled study in PAH patients. The primary endpoint used was a clearly defined morbidity/mortality endpoint allowing evaluation of the efficacy and safety of macitentan [53, 54]. Two dose levels (3 and 10 mg) were studied; macitentan reduced the risk of a morbidity/mortality event vs. placebo (10 mg dose, risk reduction 45 %, p < 0.001; 3 mg dose, risk reduction 30 %, p = 0.01) and was well-tolerated at both dose levels [53]. The number of adverse events (AEs) reported and of patients discontinuing treatment due to AEs was similar across all treatment groups and the incidence of macitentan-induced liver injury was comparable to that induced by placebo [53]. A thorough discussion of the study and its limitations is provided by Pulido et al. [53] as well as Dingemanse et al. [54].

In early clinical phase I and II studies, macitentan was administered in hard gelatin capsules [55]. A film-coated tablet of macitentan 10 mg, which is easier to ingest than the capsule, was developed for later phase I and III studies and subsequently marketed as Opsumit^®. The in vitro dissolution rate of a macitentan 10 mg capsule was slightly higher than that of the tablet formulation, while dissolution characteristics of an uncoated tablet formulation did not differ from the coated formulation [55]. In healthy male subjects, the extent of absorption of macitentan given as a tablet was slightly lower than the capsule formulation, leading to the lower of the 90 % confidence limits of the geometric mean ratio for maximum plasma concentration (C _max) to fall outside the commonly referenced range of bioequivalence of 0.80–1.25. Geometric mean ratios and 90 % confidence intervals (CIs) of total exposure expressed as area under the plasma concentration–time curve (AUC) from time zero to infinity (AUC_∞) and AUC from time zero to last timepoint t of the measurable plasma concentrations (AUC_t) were completely within the referenced bioequivalence range [55]. As the change in C _max observed in the tablet formulation was minor and total exposure, which is a more relevant measure for drugs that are used long-term, was not different from that of the capsule formulation, the observation was considered to be not clinically relevant. Therefore, no dose adjustment was needed for the tablet formulation.

In the course of its clinical development, in a dedicated study investigating the absorption, distribution, metabolism, and elimination (ADME) of macitentan, a pharmacologically inactive metabolite, ACT-373898, was discovered [56]. As the inactive metabolite had been characterized adequately in animals (see Sect. 4.3) and did not appear in high enough concentrations to raise concern in human studies [56], ACT-373898 was not routinely measured in healthy subjects and only assessed in subjects with hepatic and renal impairment.

Macitentan, its active metabolite ACT-132577, and its pharmacologically inactive metabolite ACT-373898 (Fig. 1) were determined in human plasma using a validated liquid chromatography–tandem mass spectrometry (LC-MS/MS) method. After thawing, human plasma samples were vortexed and centrifuged, and a mixture of acetonitrile/ethanol was added followed by addition of the deuterated standard. After protein precipitation, plasma samples were filtrated through a protein precipitation plate and the filtrate was injected onto the high-performance liquid chromatography (HPLC) column. The analysis of macitentan and ACT-132577 was performed by separation with reverse-phase chromatography followed by detection with triple-stage quadrupole tandem mass spectrometry (MS/MS) in positive ion mode. The assay was linear in the concentration range 1–2000 ng/mL for both analytes. The performance of the method was monitored using quality control samples at concentrations of 3, 100, and 1500 ng/mL [55, 57]. In the study with renally impaired subjects, ACT-373898 was measured separately and was detected using triple-state quadrupole MS/MS in negative ion mode [57].

Macitentan was approved at a dose of 10 mg after having undergone one of the largest phase III studies conducted in PAH and used a composite morbidity/mortality primary endpoint, consisting of clinically highly relevant components. The pharmacokinetics of macitentan can be characterized by slow absorption of macitentan and slow formation of ACT-132577 with t _½ values of 16 and 48 h, respectively, therefore justifying a once-daily dosing regimen. Formation of ACT-132577 was mainly catalyzed by CYP3A4 with minor contributions of CYP2C8, CYP2C9, and CYP2C19. Over the dose range tested in multiple-dose regimens the pharmacokinetics of macitentan and ACT-132577 were dose proportional and not influenced by meals, sex, age, or ethnicity. Due to elimination both by liver and kidney, no dose adjustment based on pharmacokinetics appeared necessary in patients with hepatic or renal impairment. It is remarkable that the pharmacokinetics of macitentan were not influenced by hepatic impairment, given the observation that macitentan is extensively metabolized before being excreted and that unchanged macitentan was not detected in urine. A possible explanation could be that the major metabolites identified in urine and feces are hydrolysis products and, therefore, only in part dependent on metabolism in the liver. Further, it is known that in hepatically impaired patients hepatic levels of CYP enzymes are diminished but this does not result in a decrease of CYP activity [95]. In fact, many patients with chronic liver disease (without cirrhosis) can metabolize drugs at a normal rate [95‐98]. A third hypothesis could be that urine and/or feces samples were not sufficiently stabilized to prevent hydrolysis of macitentan and ACT-132577, therefore underestimating the amount of unchanged macitentan and ACT-132577 excreted.

It must be noted that no clinical data of PAH patients with severe or moderate hepatic impairment are available. As the class of ERAs is associated with hepatotoxicity, macitentan should not be used in patients with severe hepatic impairment.

The pharmacokinetic characteristics of macitentan and ACT-132577 were consistent in healthy subjects and patients with essential hypertension or PAH. This allows utilization of population pharmacokinetic and pharmacokinetic/pharmacodynamic analysis methods to predict concentrations in other patient populations, in particular children, for whom no data exist at this time. Also, the observed data can be useful for assessing the potential for other drug–drug interactions. At the approved clinical dose of macitentan of 10 mg, its drug–drug interaction potential is considered low. Macitentan pharmacokinetics were not affected by commonly co-prescribed medications in PAH patients such as warfarin and sildenafil. Unlike other ERAs such a bosentan, macitentan and ACT-132577 are not substrates of OATP and can be administered concomitantly with cyclosporine without need for dose adjustment. The results of the study with cyclosporine, which inhibits other drug transporters besides OATP, indicate that the pharmacokinetics of macitentan would not be affected by inhibitors of OATP, P-gp or BCRP. Concomitant treatment with a strong inhibitor or inducer of CYP3A4 affected the pharmacokinetics markedly. Therefore, this combination should be avoided. Using the clinical data of the study with sildenafil, a sensitive substrate of CYP3A4, it is unlikely that macitentan would affect other CYP3A4 substrates including new oral anticoagulants (e.g., rivoraxaban) or hormonal contraceptives. These drugs are frequently used by PAH patients and, therefore, an absence of such an interaction would provide benefit to the patient. The use of modeling could support the absence of drug–drug interactions.

The potential of macitentan to have an improved liver safety profile is supported by a lack of effect on concentrations of bile salts and demonstrated in the pharmacokinetic/pharmacodynamic analysis of the SERAPHIN study in which no correlations between macitentan concentrations and increases in ALT, AST, and γ-glutamyl transferase were detected. ET-1 data in healthy subjects and patients with essential hypertension supported a dose of 10 mg as being efficacious, which was confirmed by the SERAPHIN results. Results of the TQT study indicated that macitentan, both at the therapeutic dose of 10 mg and at a supratherapeutic dose of 30 mg, does not have a pro-arrhythmic potential. The safety of macitentan has been reviewed and reported in several other publications [53, 54, 75]. In clinical studies, macitentan had a good safety and tolerability profile. As with other ERAs, macitentan carries a black box warning because of risk of embryo-fetal toxicity and a decrease in hemoglobin. Also, due to an assumed pharmacologic class effect, macitentan could have an adverse effect on spermatogenesis.

Data from the long-term phase III SERAPHIN study indicate a favorable profile with respect to liver enzyme elevations and edema/fluid retention.

In conclusion, the studies discussed in this review support the use of macitentan as an efficacious and well-tolerated treatment for patients with PAH with possible benefits compared with treatment with other registered ERAs.