Effect of the endothelin-receptor antagonist bosentan on the pharmacokinetics and pharmacodynamics of warfarin

Bosentan therapy for pulmonary arterial hypertension

Pulmonary arterial hypertension (PAH) is characterized by the progressive increase in pulmonary vascular resistance potentially leading to right heart failure and death. Since endothelins may play a pathogenic role in the development of the disease, endothelin receptor antagonists have been proposed for the treatment of this condition. Bosentan (Tracleer®), an oral nonselective ETA/ETB endothelin receptor antagonist, has been shown to improve exercise capacity, quality of life and hemodynamics of patients with PAH in short-term trials. These improvements were sustained and a long-term observational study on idiopathic PAH patients suggested a favorable effect on survival in this subset. The present report summarizes the pharmacology, clinical efficacy and safety profile of bosentan with an overview of the current therapies available for the treatment of PAH.

Clinical pharmacology of bosentan, a dual endothelin receptor antagonist

Bosentan, a dual endothelin receptor antagonist, is indicated for the treatment of patients with pulmonary arterial hypertension (PAH). Following oral administration, bosentan attains peak plasma concentrations after approximately 3 hours. The absolute bioavailability is about 50%. Food does not exert a clinically relevant effect on absorption at the recommended dose of 125 mg. Bosentan is approximately 98% bound to albumin and, during multiple-dose administration, has a volume of distribution of 30 L and a clearance of 17 L/h. The terminal half-life after oral administration is 5.4 hours and is unchanged at steady state. Steady-state concentrations are achieved within 3-5 days after multiple-dose administration, when plasma concentrations are decreased by about 50% because of a 2-fold increase in clearance, probably due to induction of metabolising enzymes. Bosentan is mainly eliminated from the body by hepatic metabolism and subsequent biliary excretion of the metabolites. Three metabolites have been identified, formed by cytochrome P450 (CYP) 2C9 and 3A4. The metabolite Ro 48-5033 may contribute 20% to the total response following administration of bosentan. The pharmacokinetics of bosentan are dose-proportional up to 600 mg (single dose) and 500 mg/day (multiple doses). The pharmacokinetics of bosentan in paediatric PAH patients are comparable to those in healthy subjects, whereas adult PAH patients show a 2-fold increased exposure. Severe renal impairment (creatinine clearance 15-30 mL/min) and mild hepatic impairment (Child-Pugh class A) do not have a clinically relevant influence on the pharmacokinetics of bosentan. No dosage adjustment in adults is required based on sex, age, ethnic origin and bodyweight. Bosentan should generally be avoided in patients with moderate or severe hepatic impairment and/or elevated liver aminotransferases. Ketoconazole approximately doubles the exposure to bosentan because of inhibition of CYP3A4. Bosentan decreases exposure to ciclosporin, glibenclamide, simvastatin (and beta-hydroxyacid simvastatin) and (R)- and (S)-warfarin by up to 50% because of induction of CYP3A4 and/or CYP2C9. Coadministration of ciclosporin and bosentan markedly increases initial bosentan trough concentrations. Concomitant treatment with glibenclamide and bosentan leads to an increase in the incidence of aminotransferase elevations. Therefore, combined use with ciclosporin and glibenclamide is contraindicated and not recommended, respectively. The possibility of reduced efficacy of CYP2C9 and 3A4 substrates should be considered when coadministered with bosentan. No clinically relevant interaction was detected with the P-glycoprotein substrate digoxin. In healthy subjects, bosentan doses >300 mg increase plasma levels of endothelin-1. The drug moderately reduces blood pressure, and its main adverse effects are headache, flushing, increased liver aminotransferases, leg oedema and anaemia. In a pharmacokinetic-pharmacodynamic study in PAH patients, the haemodynamic effects lagged the plasma concentrations of bosentan.

Endothelin receptor antagonists in pulmonary arterial hypertension

Endothelin receptor antagonism has emerged as an important therapeutic strategy in pulmonary arterial hypertension (PAH). Laboratory and clinical investigations have clearly shown that endothelin (ET)-1 is overexpressed in several forms of pulmonary vascular disease and likely plays a significant pathogenetic role in the development and progression of pulmonary vasculopathy. Oral endothelin receptor antagonists (ERAs) have been shown to improve pulmonary hemodynamics, exercise capacity, functional status, and clinical outcome in several randomized placebo-controlled trials. Bosentan, a dual-receptor antagonist, is approved by the U.S. Food and Drug Administration for class III and IV patients with PAH, based on two phase III trials. In addition to its efficacy as sole therapy, bosentan may have a role as part of a combination of drugs such as a prostanoid or sildenafil. The selective endothelin receptor-A antagonists sitaxsentan and ambrisentan are currently undergoing investigation.

Bosentan and warfarin interaction

OBJECTIVE

To report a case of decreased international normalized ratio (INR) in a patient receiving warfarin and bosentan.

CASE SUMMARY

A 35-year-old African American woman with a history of primary pulmonary hypertension managed with warfarin, diltiazem, and hydrochlorothiazide was initiated on bosentan therapy. The patient's INR had been stable and within therapeutic range (goal 2.0-3.0) for the previous 3 months with warfarin 27.5 mg/wk, but became subtherapeutic after 10 days of bosentan therapy. Addition of over-the-counter medications, herbal products, vitamins, or dietary changes was denied. The INR remained subtherapeutic for 5 weeks despite weekly warfarin dose increases. After these 5 weeks of dosage increases, the INR became supratherapeutic for 3 weeks, resulting in a subsequent dosage decrease. The resultant warfarin dose required to maintain a therapeutic INR was 45 mg/wk, a 63.6% dosage increase after the initiation of bosentan.

DISCUSSION

This case shows that a clinically significant interaction between bosentan and warfarin may exist. An objective causality assessment revealed that the interaction was probable. Although the possibility of this interaction has been noted, no previously documented occurrence of this interaction has been identified.

CONCLUSIONS

Bosentan may significantly decrease the anticoagulant properties of warfarin. The INR should be monitored more frequently when bosentan is initiated, adjusted, or discontinued in patients taking warfarin.

Bosentan for the treatment of pulmonary arterial hypertension

OBJECTIVE

To describe the pharmacology, pharmacokinetics, efficacy, and safety of bosentan in the treatment of pulmonary arterial hypertension (PAH).

DATA SOURCES

A MEDLINE and Current Contents search (1966-June 2002) of the English-language literature was conducted to identify published dose-ranging, pharmacokinetic, pivotal efficacy trials and review articles of bosentan and endothelin antagonists. Additional references were identified from the bibliographies of the retrieved articles.

DATA SYNTHESIS

Bosentan is the first orally active, nonpeptide endothelin receptor antagonist approved by the Food and Drug Administration for use in patients with World Health Organization (WHO) functional class III and IV PAH. Titrated to a dose of 125 mg twice daily, bosentan produces pulmonary vasodilation, improving cardiopulmonary hemodynamics leading to better outcomes for patients. It is metabolized primarily by the hepatic system via the cytochrome P450 enzyme pathway and eliminated by biliary excretion. Bosentan is an inducer of the isoenzymes CYP3A4 and 2C9. It possesses a unique pharmacokinetic profile with a terminal elimination half-life of approximately 5 hours, yet steady-state plasma concentrations are not achieved for 3-5 days as a result of enhanced drug clearance and autoinduction following multiple daily dosing. The major adverse effects of bosentan are the potential for birth defects and hepatotoxicity.

CONCLUSIONS

The use of bosentan in patients with WHO functional class III and IV PAH is associated with improved exercise tolerance, cardiopulmonary hemodynamics, and increased time to clinical worsening when compared with placebo. It offers significant advantage in ease of administration and quality of life compared with epoprostenol therapy, with similar efficacy.

Investigation of the mutual pharmacokinetic interactions between bosentan, a dual endothelin receptor antagonist, and simvastatin

BACKGROUND

In vitro, bosentan has been shown to be a mild inducer of cytochrome P450 (CYP) 2C9 and 3A4.

PURPOSE

To investigate in vivo the mutual pharmacokinetic interactions between bosentan and simvastatin, a CYP3A4 substrate.

METHODS

Nine healthy male subjects were treated in a three-period randomised crossover study with: (A) bosentan 125 mg twice daily for 5.5 days; (B) simvastatin 40 mg once daily for 6 days; and (C) bosentan 125 mg twice daily and simvastatin 40 mg once daily for 5.5 and 6 days, respectively. Plasma concentration-time profiles of bosentan and its metabolites (treatments A and C) and simvastatin and beta-hydroxyacid simvastatin (treatments B and C) were determined on day 6.

RESULTS

Steady-state conditions for bosentan and its metabolites were attained on day 4 of treatment. The pharmacokinetic parameters of bosentan and its metabolites were not influenced by concomitant treatment with simvastatin: areas under the plasma concentration-time curve over one administration interval of 12 hours (AUC(tau)) [geometric mean and 95% CI] were 4586 (3719-5656) and 4928 (3945-6156) micro g * h/L. In contrast, bosentan significantly reduced exposure to simvastatin and beta-hydroxyacid simvastatin by 34 and 46%, respectively. AUC(tau) values for simvastatin were 30.5 (23.1-40.2) and 20.0 (15.9-25.1) micro g * h/L and for beta-hydroxyacid simvastatin 43.0 (32.1-57.8) and 23.4 (16.7-32.6) micro g * h/L in treatments B and C, respectively.

CONCLUSIONS

Concomitant treatment with bosentan reduces the exposure to simvastatin and beta-hydroxyacid simvastatin by approximately 40%, indicating that in vivo bosentan is also a mild inducer of CYP3A4.

Bosentan

Bosentan is the first endothelin (ET) receptor antagonist approved by the Food and Drug Administration for the management of pulmonary arterial hypertension (PAH). In patients with World Health Organization Class III and IV PAH, bosentan has demonstrated improvement in dyspnea and exercise tolerance. ET also plays an important role in the pathophysiology of different vascular diseases. Therefore, bosentan also may have the potential to alter the outcome of many other diseases, such as heart failure, hypertension, ischemic heart disease, and renal disease, as well as cerebrovascular disorders. Because of the rarity and the poor prognosis of patients with PAH, as well as the requirement of close monitoring of bosentan (due to its potential of causing liver dysfunction and its teratogenic effects), bosentan is currently available only through a special access program and is distributed by certain selected pharmacies. Patients who are receiving bosentan should be taught to recognize early signs and symptoms of liver dysfunction and possible pregnancy. In addition, bosentan is not only a substrate but also an inducer of CYP3A4 and CYP2C9. Therefore, it is anticipated that numerous drug interactions may occur. Patients should be advised to consult their physicians or pharmacists should they need to consume other prescription or nonprescription medications.

No effect of the novel antidiabetic agent nateglinide on the pharmacokinetics and anticoagulant properties of warfarin in healthy volunteers

The novel hypoglycemic agent nateglinide is pharmacologically distinct from oral hypoglycemic agents such as sulfonylureas and repaglinide. The present study investigated the effects in healthy volunteers of multiple doses of nateglinide on the pharmacokinetics and pharmacodynamics of warfarin. The study comprised a randomized two-group, two-way crossover, open-label design in 12 healthy male subjects. One group of 6 subjects initially received a single oral dose of warfarin 30 mg and then, after a 7- to 14-day washout, received both warfarin and nateglinide (120 mgnateglinide, 10 min before meals for 4 days and a single dose of 30 mg warfarin on the second day). The alternate group of 6 subjects received treatments in the opposite order. Pharmacokinetic profiles were derived from plasma warfarin and nateglinide concentrations. Prothrombin measurements were evaluated in both periods as a measure of warfarin activity. When administered alone or in combination, there were no statistically significant differences in mean warfarin (R- and S-enantiomers) or nateglinide pharmacokinetic parameters. The concurrent administration of nateglinide and warfarin did not affect the maximal change in prothrombin time that follows warfarin administration. In this study, there was no evidence of an effect of coadministration of nateglinide on the pharmacodynamic action of warfarin or any pharmacokinetic interaction between warfarin and nateglinide.

Bosentan, a dual endothelin receptor antagonist, activates the pregnane X nuclear receptor

Recent clinical studies have shown that bosentan, a dual endothelin receptor antagonist, decreases the exposure to various substrates of cytochrome P450 (CYP) isoenzymes 2C9 and 3A4. The aim of the study was to investigate the effect of bosentan, its metabolites and glibenclamide on the activity of the pregnane X receptor, a nuclear receptor that regulates the transcription of CYP3A4. CV-1 monkey kidney cells were transiently transfected with a luciferase reporter plasmid containing three copies of the ER6 response element of CYP3A4 and the human or mouse pregnane X receptor. Subsequently, the cells were incubated with the test compounds and the activity of luciferase determined. Bosentan activated the human pregnane X receptor with an EC(50) of 19.9 microM, whereas rifampicin had an EC(50) value of 1.9 microM. Ro 47-8634 (4-tert-butyl-N-[6-(2-hydroxy-ethoxy)-5-(2-hydroxy-phenoxy)-2,2'-bipyrimidin-4-yl]-benzenesulfonamide), a metabolite of bosentan, and glibenclamide also activated the pregnane X receptor. The findings provide a molecular mechanism for the interactions observed between bosentan and several drugs.

Bosentan: a dual endothelin receptor antagonist

The peptide endothelin plays a significant role in a wide array of pathological conditions, including primary pulmonary hypertension and pulmonary arterial hypertension associated with collagen vascular disease. These are life-threatening conditions that can severely compromise the function of the lungs and heart. Inhibiting the actions of endothelin by blockade of its receptors provides a new and effective approach to therapy for patients with these conditions. Bosentan (Tracleer ) is the first orally-active dual endothelin receptor antagonist and has recently been approved in the US, Canada, Switzerland and the EU for the treatment of pulmonary arterial hypertension. Bosentan significantly improves exercise capacity, symptoms and functional status in patients with this disease and also slows clinical deterioration, which may be indicative of a delay of disease progression. Results from large-scale studies of bosentan in patients with pulmonary arterial hypertension and chronic heart failure have established its long-term safety and tolerability profiles. The introduction of the dual endothelin receptor antagonist bosentan has provided an essential treatment for pulmonary arterial hypertension and ongoing trials are evaluating its potential role in the management of other endothelin-mediated disease states.

Single- and multiple-dose pharmacokinetics of bosentan and its interaction with ketoconazole

AIMS

The present study was conducted to characterize the single- and multiple-dose pharmacokinetics of bosentan, a dual endothelin receptor antagonist, and to investigate a possible pharmacokinetic interaction with ketoconazole.

METHODS

In a randomized, two-way crossover study, 10 healthy male subjects received treatments A and B. Treatment A consisted of a single dose of 62.5 mg bosentan on day 1 followed by 62.5 mg twice daily for 5.5 days. Treatment B consisted of bosentan (62.5 mg twice daily) for 5.5 days plus concomitant ketoconazole (200 mg once daily) for 6 days. Plasma concentrations of bosentan and its three metabolites were measured on days 1 and 7 of treatment A and on day 6 of treatment B.

RESULTS

Bosentan was absorbed and eliminated with a tmax of 4.5 h (range 3.5-6.0 h) and a t(1/2) of 5.4 h (95% CI; 4.5, 6.6). Upon multiple dosing, the exposure to bosentan was reduced by 33% without change in tmax and t(1/2). Concomitant administration of ketoconazole increased the Cmax and AUC of bosentan 2.1- (95% CI; 1.5, 2.7) and 2.3-fold (95% CI; 1.8, 2.9), respectively. Exposure to the metabolites was low and represented less than 25% of that to bosentan both after single and multiple doses. In the presence of ketoconazole, formation of the metabolites was inhibited.

DISCUSSION

The multiple-dose pharmacokinetics of bosentan are consistent with the phenomenon of auto-induction. In the presence of CYP3A4 inhibitors, bosentan concentrations may be increased 2-fold.

Effect of modafinil at steady state on the single-dose pharmacokinetic profile of warfarin in healthy volunteers

Modafinil has been reported to produce a concentration-related suppression of CYP2C9 activity in vitro in primary cultures of human hepatocytes. To determine whether this effect occurs in vivo, the pharmacokinetics of (S)-warfarin was investigated after single oral doses of racemic warfarin (5 mg; COUMADIN) in a placebo-controlled, single-blind, single-period study in 28 volunteers. Subjects received an oral dose of warfarin prior to administration of modafinil (200 mg for 7 days, followed by 400 mg for 21 days) or placebo and they received another after 4 weeks of treatment. Treatment with modafinil did not significantly alter the pharmacokinetics of (S)- or (R)-warfarin relative to placebo. Since (S)-warfarin is predominantly metabolized via CYP2C9, the results indicate that the marked suppression of CYP2C9 activity in vitro does not translate into a similar effect clinically. However, limitations arising from investigation of single doses of warfarin preclude global conclusions about the potential for more subtle interactions after chronic warfarin administration.

The therapeutic potential of endothelin receptor antagonists in cardiovascular disease

Endothelin (ET)-1, a 21-amino acid peptide, is the predominant isoform of the endothelin peptide family. ET-1 is ubiquitously expressed and stimulates vasoconstriction and cell proliferation. Enzymes such as endothelin converting enzymes (ECE), chymases, and non-ECE metalloproteinases contribute to the synthesis of ET-1, which is regulated in an autocrine fashion in vascular and nonvascular cells. Endothelin ET(A) receptors mediate vasoconstriction and cell proliferation, whereas ET(B) receptors are involved in the clearance of ET-1, inhibition of endothelial apoptosis, release of nitric oxide and prostacyclin, and inhibition of ECE-1 expression. Most cardiovascular diseases, such as arterial hypertension, atherosclerosis, restenosis, heart failure, idiopathic cardiomyopathy, pulmonary hypertension, and renal failure are associated with local activation of the endothelin system. Experimental studies and first clinical trials suggest that ET-1 is importantly involved in the functional and structural changes in the cardiovascular system, and that many of the actions of ET-1 are mediated through pressure-independent mechanisms. Endothelin antagonists promise to be successful as a new class of drugs for the treatment of cardiovascular diseases.

Endothelins and endothelin receptor antagonists: therapeutic considerations for a novel class of cardiovascular drugs

The 21-amino acid peptide endothelin-1 (ET-1) is the predominant isoform of the endothelin peptide family, which includes ET-2, ET-3, and ET-4. It exerts various biological effects, including vasoconstriction and the stimulation of cell proliferation in tissues both within and outside of the cardiovascular system. ET-1 is synthesized by endothelin-converting enzymes (ECE), chymases, and non-ECE metalloproteases; it is regulated in an autocrine fashion in vascular and nonvascular cells. ET-1 acts through the activation of G(i)-protein-coupled receptors. ET(A) receptors mediate vasoconstriction and cell proliferation, whereas ET(B) receptors are important for the clearance of ET-1, endothelial cell survival, the release of nitric oxide and prostacyclin, and the inhibition of ECE-1. ET is activated in hypertension, atherosclerosis, restenosis, heart failure, idiopathic cardiomyopathy, and renal failure. Tissue concentrations more reliably reflect the activation of the ET system because increased vascular ET-1 levels occur in the absence of changes in plasma. Experimental studies using molecular and pharmacological inhibition of the ET system and the first clinical trials have demonstrated that ET-1 takes part in normal cardiovascular homeostasis. Thus, ET-1 plays a major role in the functional and structural changes observed in arterial and pulmonary hypertension, glomerulosclerosis, atherosclerosis, and heart failure, mainly through pressure-independent mechanisms. ET antagonists are promising new agents in the treatment of cardiovascular diseases.