Sildenafil in the treatment of pulmonary hypertension
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Sildenafil in the treatment of pulmonary hypertension
Correspondence: Roberto F Machado Vascular Medicine Branch, National Heart Lung and Blood Institute, National Institutes of Health, Clinical Center, Building 10- CRC, Room 5-5130, Bethesda, MD 20892-1454, USA Tel +1 301 594 3455 Fax +1 301 451 7091 Email vog.hin.iblhn@motrebor
Abstract
The therapy of pulmonary hypertension has evolved rapidly in the last 10 years from the use of non-selective vasodilators to drugs that specifically target pulmonary vasodilation, endothelial function, and vascular remodeling. Sildenafil is a phosphodiesterase type 5 inhibitor that has an expanding role in the treatment of pulmonary hypertension. Case series and small studies, as well as the first large randomized controlled trial, have demonstrated the safety and efficacy of sildenafil in improving mean pulmonary artery pressure, pulmonary vascular resistance, cardiac index, and exercise tolerance in pulmonary arterial hypertension. It may be useful in adults, children, and neonates after cardiac surgery, with left heart failure, in fibrotic pulmonary disease, high altitude exposure, and thromboembolic disease, and in combination with other therapies for pulmonary hypertension, such as inhaled iloprost. The oral formulation and favorable adverse effect profile make sildenafil an attractive alternative in the treatment of selected patients with pulmonary hypertension.
Introduction
The development of sildenafil began in 1986 when chemists at Pfizer searching for a compound to treat hypertension chose to target augmentation of the renal tubular activity of atrial natriuretic peptide through its second messenger cyclic guanosine monophosphate (cGMP) and the phosphodiesterase (PDE) family of enzymes ( Kling 1998 ). Test compounds were shown to antagonize the activity of PDE 5, resulting in vasodilation and platelet inhibition, turning their focus to treatment of angina. Trials in angina were disappointing but some patients reported the surprising and unexpected side-effect of penile erections ( Morales et al 1998 ), leading to its development as a treatment for erectile dysfunction. As understanding of the mechanism of sildenafil grew, a role in the treatment of pulmonary hypertension (PH) was postulated, eventually leading to the recent Super-1 trial and FDA approval for this indication. Sildenafil is administered orally, is well tolerated with few drug interactions, and does not require intensive monitoring, making it an attractive alternative to other drugs for the treatment of PH. In this article, we review the growing role of sildenafil in the treatment of PH.
PH pathogenesis and clinical course
Pulmonary hypertension is a general term for a disease process resulting in a progressive increase in the mean pulmonary artery pressure (mPAP) (mPAP ≥25 mmHg at rest or ≥30 mmHg with exercise) ( Barst et al 2004 ). According to the World Health Organization Revised Clinical Classification of Venice ( Simonneau et al 2004 ), pulmonary arterial hypertension (PAH) is a specific subtype of PH with a pulmonary capillary wedge pressure (PCWP) ≤15 mmHg and by pulmonary vascular resistance (PVR) >3 wood units. PAH can be idiopathic, familial, or secondary to a variety of conditions such as connective tissue disease, hemoglobinopathies, or HIV infection ( Table 1 ).
Table 1
Revised clinical classification of pulmonary hypertension
| 1. | Pulmonary arterial hypertension (PAH) | ||
| 1.1 | Idiopathic (IPAH) | ||
| 1.2 | Familial (FPAH) | ||
| 1.3 | Associated with (APAH): | ||
| 1.3.1 | Collagen vascular disease | ||
| 1.3.2 | Congenital systemic-to-pulmonary shunts | ||
| 1.3.3 | Portal hypertension | ||
| 1.3.4 | HIV infection | ||
| 1.3.5 | Drugs and toxins | ||
| 1.3.6 | Other (thyroid disorders, glycogen storage disease, Gaucher disease, hereditary hemorrhagic telangiectasia, hemoglobinopathies, myeloproliferative disorders, splenectomy) | ||
| 1.4 | Associated with significant venous or capillary involvement | ||
| 1.4.1 | Pulmonary veno-occlusive disease (PVOD) | ||
| 1.4.2 | Pulmonary capillary hemangiomatosis (PCH) | ||
| 1.5 | Persistent pulmonary hypertension of the newborn | ||
| 2. | Pulmonary hypertension (PH) with left heart disease | ||
| 2.1 | Left-sided atrial or ventricular heart disease | ||
| 2.2 | Left-sided valvular heart disease | ||
| 3. | PH associated with lung disease and/or hypoxemia | ||
| 3.1 | Chronic obstructive pulmonary disease | ||
| 3.2 | Intersitial lung disease | ||
| 3.3 | Sleep-disordered breathing | ||
| 3.4 | Alveolar hypoventilation disorders | ||
| 3.5 | Chronic exposure to high altitude | ||
| 3.6 | Development abnormalities | ||
| 4. | PH due to chronic thrombotic and/or embolic disease | ||
| 4.1 | Thromboembolic obstruction of proximal pulmonary arteries | ||
| 4.2 | Thromboembolic obstruction of distal pulmonary arteries | ||
| 4.3 | Non-thrombotic pulmonary embolism (tumor, parasites, foreign material) | ||
| 5. | Miscellaneous | ||
| Sarcoidosis, pulmonary Langerhans cell histiocytosis, lymphangiomatosis, compression of pulmonary vessels by adenopathy, tumor fibrosing mediastinitis, or other process | |||
Adapted with permission from Simonneau G, Galie N, Rubin LJ, et al. 2004 . Clinical classification of pulmonary hypertension. J Am Coll Cardiol, 43:5S–12S. © 2004 Elsevier.
Endothelial dysfunction resulting from an imbalance of endogenous vasoconstrictors (eg, endothelin-1) and vasodilators (eg, nitric oxide [NO], prostacyclin) is thought to lead to vascular constriction, in situ thrombosis, and progressive remodeling of the pulmonary arteries ( Pietra et al 1989 ; Rubin 1997 ). Vascular remodeling in PAH is characterized by distal pulmonary arterial smooth muscle cell hypertrophy and proliferation with subsequent luminal narrowing and development of plexiform lesions. Regardless of the etiology, the pathologic appearance is remarkably similar, suggesting an underlying, common disease pathway ( Galiè et al 1998 ).
Patients with PH often present with signs and symptoms of right heart failure. Diagnostic evaluation includes a search for any underlying diseases followed by right heart catheterization for the measurement of mPAP, PCWP, and PVR, and performance of vasodilator testing. The 6 minute walk test is performed at baseline and on follow up to track exercise capacity and assess disease severity ( Miyamoto et al 2000 ; McLaughlin et al 2002 ; Hoeper et al 2004 ).
Therapies for PH
Prior to the advent of vasodilator therapy, progressive right-sided heart failure frequently lead to death within 2–3 years ( D’Alonzo et al 1991 ). Calcium channel blockers were the first drugs shown to benefit patients with idiopathic PAH ( Rich et al 1992 ) and remain first-line therapy in the few patients who respond during vasodilator testing ( Sitbon et al 2005 ). Based on autopsy findings of frequent undetected pulmonary thrombi ( Fuster et al 1984 ) and a small retrospective series showing increased transplant-free survival in anticoagulated patients, treatment with warfarin has also become a part of standard therapy. The use of diuretics and digoxin can help relieve symptoms of right heart failure.
In 1996, intravenous epoprostenol was shown in a randomized controlled trial to improve exercise tolerance, hemodynamics, and survival in PAH ( Barst et al 1996 ). Prostacyclin and other prostanoids are administered by continuous intravenous or subcutaneous infusion, inhalation, or orally. Treatment may be complicated by systemic vasodilation resulting in hypotension, headache and jaw pain, or hypoxemia due to ventilation/perfusion (V/Q) mismatch, or right to left shunting ( Rubin 1997 ; Castro et al 1998 ). Other potential adverse effects include infections, thrombosis, and malfunction of the delivery system resulting in pulmonary hypertensive crisis ( Barst et al 1996 ).
Two randomized trials have shown significant improvements in 6 minute walk distance, hemodynamics, and time to clinical worsening during treatment with the oral endothelin A/B receptor antagonist bosentan ( Channick et al 2001 ; Rubin et al 2002 ). The most common adverse effect is a dose-related elevation in liver enzymes that can occur in up to 11% of patients and necessitate cessation of therapy ( Lee and Channick 2005 ).
Pharmacology and acute effects of sildenafil in PH
Sildenafil is a selective and potent inhibitor of PDE type 5 which specifically degrades cyclic guanosine monophosphate and is found in high concentrations in pulmonary arteries and the corpora cavernosum ( Rabe et al 1994 ; Ahn et al 1991 ; Boolell et al 1996 ; Pauvert et al 2002 ; Pauvert et al 2003 ). Normally, endothelium-derived NO stimulates intracellular soluble guanylate cyclase resulting in increased levels of cGMP, which then acts to mediate smooth muscle relaxation ( Figure 1 ). Sildenafil inhibits the degradation of cGMP by PDE 5 and prolongs the actions of cGMP.
Mechanism of vasodilatory and antiproliferative effects of sildenafil. NO from vascular endothelial cells stimulates the activity of sGC which produces cGMP from GTP. Sildenafil inhibits the breakdown of cGMP to GMP by PDE 5, increasing cellular concentrations of cGMP which increases the formation of PKG. Competitive inhibition of PDE inhibits breakdown of cAMP which stimulates increased production of PKA. Vasodilation results primarily from modulation of ion channel activity by cGMP with a lesser contribution from increased levels of cAMP. Inhibition of smooth muscle cell proliferation occurs via increased levels of PKA and PKG.
Abbreviations: AMP, adenosine monophosphate; cAMP, cyclic adenosine monophosphate; cGMP, cyclic guanosine monophosphate; GMP, guanosine monophosphate; GTP, guanosine triphosphate; NO, nitric oxide; PDE 5, phosphodiesterase type 5, PKA, cAMP dependent protein kinase; PKG, cGMP dependent protein kinase; sGC, soluble guanylate cyclase.
Metabolism of sildenafil occurs primarily by hepatic cytochrome P450 enzymes yielding one active metabolite with a potency of approximately 50% of the parent drug. Patients with age greater than 65, with creatinine clearance less than 30, and with hepatic cirrhosis have reduced clearance of sildenafil.
During trials for erectile dysfunction, sildenafil was administered to more than 3700 patients worldwide with over 550 patients treated for more than one year. Adverse events included headache 16%, flushing 10%, dyspepsia 7%, and nasal congestion 4% and were similar to those reported in the largest trial of sildenafil in PAH ( Galiè et al 2005 ). Sildenafil leads to a small, usually clinically insignificant drop in blood pressure ( Kloner 2004 ). Cases of vision loss due to non-arteritic anterior ischemic optic neuropathy (NAION) have been reported ( McGwin et al 2006 ), but have not occurred during studies of pulmonary hypertension ( Galiè et al 2005 ; Machado et al 2005 ). Inhibition of the hepatic P450 enzyme system can potentiate adverse effects of sildenafil by accelerating or decreasing its metabolism and clearance.
Trials of sildenafil to date have exploited its ability to cause rapid and potent vasodilatation resulting in improved hemodynamics. Acute administration of a single oral dose of sildenafil causes a significant decrease in mPAP and PVR with minimal or no affect on mean arterial pressure (MAP) and improvement, or a trend towards improvement, in cardiac output. The effect peaks at 60 minutes and lasts as long as 4 hours ( Hoeper et al 2000 ; Ghofrani et al 2002a , 2002b ; Lepore et al 2002 ; Michelakis et al 2002 ). Two studies found a dose-dependent relationship for changes in cardiac index (CI), pulmonary arterial pressure, and pulmonary vascular resistance index (PVRI) ( Ghofrani et al 2002a , 2002b ). One report describes a decrease in the ratio of PVR to systemic vascular resistance (SVR) at lower doses, suggesting selectivity for the pulmonary vasculature ( Ghofrani et al 2002a ). The magnitude of the effect in the pulmonary circulation is comparable to that of inhaled NO, iloprost, and prostacyclin ( Hoeper et al 2000 ; Lepore et al 2002 ).
Vasodilators may improve hemodynamics, but treatments that inhibit or reverse vascular remodeling to slow inevitable disease progression are being sought. Sildenafil may prevent or reverse remodeling through NO and cGMP modulation of smooth muscle proliferation and apoptosis ( Figure 1 ) ( Garg and Hassid 1990 ; Lee et al 1996 ; Pollman et al 1996 ; Chiche et al 1998 ; Osinski et al 2001 ). Clinical data with adequate follow-up time in patients treated with sildenafil are so far inadequate to address this possibility, but limited data from early studies suggest that it is plausible and mechanistically sound.
In one report, sildenafil inhibited platelet derived growth factor (PDGF)-induced DNA synthesis and cell proliferation, and inhibited hypoxia-induced cell proliferation. Increased levels of cGMP indirectly lead to increased levels of cAMP which may suppress transcription of DNA, activate anti-proliferative protein kinases, and inhibit PDGF activity ( Tantini et al 2005 ). In vivo, sildenafil has been shown to prevent and reverse remodeling in monocrotaline-, hypoxia-, and overcirculation-induced animal models of PAH ( Sebkhi et al 2003 ; Itoh et al 2004 ; Rondelet et al 2004 ; Schermuly et al 2004 ). In humans, PDE 5 expression was increased in remodeled pulmonary arteries from patients with idiopathic PAH and familial PAH. Stimulation of the cGMP pathway inhibited DNA synthesis and cell proliferation and promoted apoptosis in isolated pulmonary artery smooth muscle cells, an effect potentiated by sildenafil ( Wharton et al 2005 ).
Clinical applications
The use of sildenafil to treat PH from a variety of causes has increased dramatically although, for many applications, only case reports or small series offer evidence of safety and efficacy. Future large, well designed trials are critical to direct physicians in the treatment of unstudied populations who might benefit from sildenafil.
Three randomized controlled trials have been performed to evaluate the use of sildenafil in patients with PAH ( Table 2 ). Ten patients with New York Heart Association (NYHA) classification >2, pulmonary artery systolic pressure (PASP) ≥35 mmHg, normal left ventricular function, and no reversible cause of PAH were included in a prospective randomized, placebo-controlled cross over study to evaluate the effects of short-term sildenafil treatment. PAH was idiopathic (3), or related to interstitial lung disease (2), chronic thromboembolic disease (1), or chronic left to right shunt (3). Patients in the sildenafil group had an improvement in the primary endpoint of 6 minute walk distance from 163.9 to 266.7 m (p<0.005) compared with no change with placebo. Changes in secondary endpoints with sildenafil treatment included a decrease in the Borg dyspnea index and PASP from 5.2 to 3.6 (p<0.01) and 80.8 to 55.3 mmHg (p<0.05) respectively ( Bharani et al 2003 ).
Table 2
Summary of randomized controlled trials of sildenafil in the treatment of PAH ( Bharani et al 2003 ; Sastry et al 2004 ; Galiè et al 2005 )
| Baharani 2003 | Sastry 2004 | Galiè 2005 | |
|---|---|---|---|
| Trial design | Randomized, placebo controlled, double blind, crossover | Randomized, placebo controlled, double blind, crossover | Randomized double blind, placebo controlled |
| No (male) | 9 (4) | 22 (10) | 277 (68) |
| Etiology (number) | Idiopathic PAH (3) | Idiopathic PAH (22) | Idiopathic PAH (175) |
| Left to right shunt (3) | CTD (84) | ||
| Thromboembolism (1) ILD (2) | Left to right shunt (18) | ||
| Duration | 2 weeks | 6 weeks | 12 weeks |
| Primary outcome | 6 min walk 170 m at end of placebo phase vs 266 m at end of sildenafil phase, p | Exercise treadmill time 475±168 s at end of placebo phase vs 686±224 s at end of sildenafil phase, p | Placebo corrected increase in mean 6 min walk distance 20, 40, and 80 mg; 45, 46, and 50 m (p<0.001) |
| Secondary outcomes | Significant improvement in Borg dyspnea score and PASP | Significant improvement in cardiac index and QOL, no change in PASP | Significant improvement in mPAP, CI (40 and 80 mg dose), PVR,WHO functional class, no change in time to worsening or Borg dyspnea scale |
| Adverse effects | None reported | Similar to placebo | Increased rate of headache and epistaxis in sildenafil group |
Abbreviations: CTD, connective tissue disease; ILD, interstitial lung disease; mPAP, mean pulmonary artery pressure; PAH, pulmonary arterial hypertension; PASP, pulmonary artery systolic pressure; PVR, pulmonary vascular resistance; QOL, quality of life.
In another trial, 22 patients with NYHA class II-III and PASP >70 mmHg by echocardiography were randomized to 6 weeks of sildenafil or placebo with subsequent crossover. The primary endpoint of exercise time decreased non-significantly compared with baseline in the placebo first group, but increased from 451 to 698 seconds during sildenafil (p<0.001) then decreased to 527 seconds during placebo (p<0.001 compared with baseline) in the sildenafil first group. When the groups were combined, exercise time increased from 475 seconds after placebo to 686 seconds after 6 weeks of sildenafil (p<0.0001). Cardiac index (2.8–2.45 L⋅min −1 ⋅m −2 , p<0.0001) and quality of life measures for dyspnea and fatigue improved although there was no significant difference in PASP ( Sastry et al 2004 ).
The Super-1 trial was an international multicenter, randomized, blinded, controlled study involving 278 patients with symptomatic PAH that was idiopathic, associated with connective tissue disease, or repaired congenital systemic to pulmonary shunts. Patients were stratified according to baseline walk distance and etiology of PAH and randomized to placebo or sildenafil at a dose of 20, 40, or 80 mg 3 times daily for 12 weeks followed by a long-term extension study of sildenafil 80 mg. For the primary outcome of exercise capacity, there was a significant improvement in 6 minute walk distance in all patients taking sildenafil ( Table 3 ). There was no significant difference in time to clinical worsening, but fewer patients taking sildenafil were hospitalized for worsening PAH. One patient developed left ventricular dysfunction and one patient had postural hypotension thought to be related to sildenafil ( Galiè et al 2005 ). There was a non-significant trend towards improved hemodynamics with higher doses and the extension study showed favorable results of long-term treatment with 80 mg.
Table 3
Results of the Super-1 trial showing improvements in hemodynamics and 6 minute walk test with use of sildenafil
| Effect at 8 weeks | Placebo (95% confidence interval) | 20 mg (95% confidence interval) | 40 mg (95% confidence interval) | 80 mg (95% confidence interval) |
|---|---|---|---|---|
| 6 minute walk distance (placebo corrected, in meters) | 45 (21, 70) | 46 (20, 72) | 50 (23, 77) | |
| Mean pulmonary artery pressure (mmHG) | 0.6 (−0.8, 2.0) | −2.1 (−4.3, 0.0) | −2.6 (−4.4, −0.9) | −4.7 (−6.7, −2.8) |
| Cardiac index (L·min −1 ·m −2 ) | −0.02 (−0.17, 0.13) | 0.21 (0.04, 0.8) | 0.24 (0.05, 0.42) | 0.37 (0.20, 0.55) |
| PVR (dynes·s −1 ·cm −5 ) | 49 (−54, 153) | −22 (−217, −27) | −143 (−218, −69) | −261 (−365, −157) |
Abbreviations: PVR, pulmonary vascular resistance.
The only comparative treatment trial studied patients with idiopathic or collagen vascular disease associated PAH who were symptomatic despite maximal conventional therapy. For the primary outcome of right ventricular mass, there was a significant improvement in baseline versus sildenafil but no difference between baseline and bosentan or between sildenafil and bosentan. There were differences between treatment groups (sildenafil superior) only in 6 minute walk distance and quality of life score ( Wilkins et al 2005 ).
The Super-1 trial is the only high quality, randomized, blinded controlled study that has shown a benefit of treatment with sildenafil. The study population was made up largely of individuals with idiopathic PAH, and subgroup analysis of patients with other diagnoses failed to show a statistically significant improvement in 6 minute walk distance at a dose of 20 mg 3 times daily. Some experts have expressed concern that FDA approval of only the 20-mg dose could result in some patients being harmed by undertreatment ( Hoeper et al 2006 ). For now, data are adequate to support treatment of PAH with sildenafil. Although accumulating evidence is encouraging and reported toxicities are limited, sildenafil treatment for PH other than PAH should be considered experimental.
HIV-associated PAH
HIV-associated PAH is estimated to occur in 0.5% of infected patients with a mortality approaching 50% at 36 months ( Speich et al 1991 ; Pellicelli et al 2001 ). Pathologic examination shows plexiform lesions and the disease is thought to be mediated by endothelial dysfunction secondary to the host immune response or HIV therapy. Calcium channel blocker therapy is not successful and patients are particularly susceptible to adverse effects of prostacyclin infusion and to bosentan associated hepatic toxicity. Treatment of HIV-associated PAH with sildenafil has been limited due to interactions between sildenafil and protease inhibitors and recreational use of street drugs such as amyl nitrate. Successful treatment with sildenafil has been reported in 3 adult patients with HIV-associated PAH ( Schumacher et al 2001 ; Carlsen et al 2002 ; Alp et al 2003 ). All three patients showed improvements in hemodynamics, functional class, and symptoms. Treatment of one 18-month-old patient with supra systemic pulmonary artery pressures and right heart dysfunction has also been reported. Twelve months of sildenafil resulted in near resolution of right heart abnormalities by echocardiography ( Wong et al 2006 ).
Hemolysis associated PAH
PAH affects approximately 30% of patients with sickle cell anemia ( Sutton et al 1994 ; Castro 1996 ; Castro et al 2003 ; Castro and Gladwin 2005 ) and has been identified as a major independent predictor of death ( Gladwin et al 2004 ). A hemolysis-mediated decrease in NO bioavailability ( Reiter et al 2002 ) increased production of endothelin-1 and free radicals, platelet activation, and endothelial dysfunction along with chronic hypoxia, and a prothrombotic state occurs in hemolytic disorders resulting in PAH ( Machado and Gladwin 2005 ). Because of the abnormally high rate of NO destruction central to the pathophysiology of these disorders, sildenafil may be a uniquely well suited treatment choice.
One small study evaluated the efficacy and safety of sildenafil in 7 patients with thalassemia intermedia, thalassemia major, and sickle cell thalassemia with advanced disease despite maximal conventional therapy. All patients experience progressive hemodynamic and symptomatic improvement. No patients reported adverse effects and no patients stopped the drug due to adverse effects ( Derchi et al 2005 ).
In another small, uncontrolled, open label trial we evaluated the effects of sildenafil on hemodynamics and functional status in patients with mild to moderate PAH and impaired exercise capacity associated with sickle cell disease. Acute administration of sildenafil during right heart catheterization resulted in a statistically significant change of mPAP of −26%, PVR of −57%, CI of 45%, and PVR to SVR ratio of −38%, suggesting preferential pulmonary vasodilation. Among 12 patients treated chronically, pulmonary artery systolic pressure (PASP) measured by echocardiogram and 6 minute walk improved significantly from 50 to 41 mmHg and 384 to 462 m respectively. One patient had to stop treatment due to headaches ( Machado et al 2005 ). Based on these results, a large National Heart Lung and Blood Institute sponsored randomized trial of sildenafil in sickle cell anemia-associated PAH will be launched in the next 12 months.
Portopulmonary hypertension
Pulmonary hypertension with a mPAP of 40–45 mmHg prior to liver transplantation is associated with a mortality of 70%–80% ( Makisalo et al 2004 ) and successful treatment of PH is required prior to listing for transplant. End stage liver disease precludes the use of bosentan and prostacyclin use is especially challenging in this population. However, concerns have been raised about the interaction of the potential antiplatelet effect of sildenafil and bleeding diathesis that results from liver disease.
The literature contains reports of 2 patients with primary billiary cirrhosis hepatitis C complicated by portopulmonary hypertension who were treated with sildenafil. Both patients responded well allowing liver transplantation to proceed. One patient developed a hematoma post-operatively that may have been secondary to the antiplatelet effects of sildenafil ( Makisalo et al 2004 ; Chua et al 2005 ). Another small trial studied 14 patients with portopulmonary hypertension treated with sildenafil or inhaled iloprost plus sildenafil. Patients had a statistically significant improvement in PVR and 6 minute walk distance at 3 and 12 months follow up. Two patients died as a result of their underlying disease but there were no adverse bleeding events related to sildenafil ( Reichenberger et al 2006 ).
Persistent PH of the newborn
Persistent PH of the newborn (PPHN) occurs when PVR remains elevated after birth resulting in right to left shunting and hypoxemia. The incidence is 0.43–6.8/1000 live births and it has a mortality rate of 10%–20% ( Travadi and Patole 2003 ). Management is supportive and inhaled NO and extra corporeal membrane oxygenation (ECMO) are indicated if they are available ( Schreiber et al 2003 ). Sildenafil could provide a feasible and cost-effective alternative to inhaled NO and ECMO ( Kumar 2002 ). Three cases of children between 7 days and 5 months of age with bronchopulmonary dysplasia, an intracardiac shunt, and acute respiratory failure treated with sildenafil have been published. All patients were critically ill, requiring maximal available hemodynamic and respiratory support. After beginning sildenafil, all patients had rapid improvement ( Chaudhari et al 2005 ; Hon et al 2005 ; Juliana and Abbad 2005 ).
Pediatric patients with PAH
One open label single drug trial evaluated the effects of 12 months of sildenafil-treatment pediatric patients with idiopathic PAH, post op congenital heart defect repair, and Eisenmenger syndrome. Right heart catheterization in 9 showed a significant reduction in mPAP from 60 to 50 mmHg and a decrease in pulmonary vascular resistance index from 15 to 12 wood units/m 2 without a change in systemic hemodynamics. Six minute walk distance increased from a mean of 278 m to 432 m. There were no deaths during the 12-month study period compared with 37% survival in historical controls ( Humpl et al 2005 ).
Combination therapy in PAH
Data on combination therapy in PH is limited, but it has already become common practice among some physicians ( Hoeper and Dinh-Xuan 2004 ). Similar to therapy of congestive heart failure, patients may benefit from synergistic effects of drugs with disparate mechanisms of action. Numerous small trials have begun exploring the utility of this approach.
In one study, exercise treadmill time, dyspnea fatigue score, and WHO functional class improved in 8 patients on chronic, subcutaneous treprostenol treated with oral sildenafil ( Gomberg-Maitland et al 2005 ). Another study examined 30 patients with idiopathic PAH, CREST, congenital vascular defect, or chronic thromboembolic disease treated with inhaled NO followed by inhaled iloprost then by sildenafil alone or inhaled iloprost plus sildenafil. With combined iloprost and sildenafil therapy, the effect on mPAP, PVR, and CI was more pronounced and longer lasting, and the vasodilatory response was greater than for the sum of the individual therapies, suggesting treatment synergy ( Ghofrani et al 2002 ). Ghofrani and colleagues also studied 14 patients deteriorating on inhaled iloprost and found that the addition of sildenafil resulted in an increased 6 minute walk distance, decreased mPAP, decreased PVR, and improved functional class ( Ghofrani et al 2003 ). Lastly, a study of beraprost and sildenafil resulted in a more potent lowering of the mPAP and a longer treatment effect than beraprost alone ( Ikeda et al 2005 ).
A study of goal-based therapy versus historical controls treated with inhaled or i.v. prostaglandins involved treatment with bosentan followed by the addition of sildenafil, inhaled iloprost, or change to intravenous iloprost, to achieve a 6 minute walk distance >380 m, a peak oxygen uptake >10.4 mL⋅min −1 ⋅kg −1 , and a peak SBP during exercise of >120 mmHg. Among 123 patients enrolled, 43.2% met treatment goals on 2 drugs, 16.1% on 3, and 4.2% required intravenous iloprost. Mortality (23.8% vs 13.8%) and transplantation-free survival were better in the goal based treatment group ( Hoeper et al 2005 ).
Heart failure, cardiac surgery, and cardiac transplant
Pulmonary hypertension is a complication of heart failure from left ventricular dysfunction associated with increased mortality and is a contraindication to heart transplant ( Erickson et al 1990 ; Costard-Jackle and Fowler 1992 ; Delgado et al 2001 ). Sildenafil has been used in the pre-operative period in 2 studies to test vasoreacticity ( Alaeddini et al 2004 ) and to successfully treat established PH that would have otherwise been a contraindication to heart transplant ( Gómez-Moreno et al 2005 ).
PH can also complicate cardiac and peripheral vascular surgery and is thought to be due to pulmonary endothelial dysfunction related to cardiopulmonary bypass and other factors ( Hayward et al 1999 ; Fung et al 2005 ). Standard therapies include beta agonists, PDE III inhibitors, and intravenous or inhaled nitrovasodilators ( Trachte et al 2005 ). Treatment with sildenafil, however, is growing more common even in the absence trial data to support its use ( Madden and Crerar-Gilbert 2005 ).
Three reports describe the use of sildenafil for worsening PH in post-operative patients requiring multiple pressors and inotropic support. In one, sildenafil decreased the mPAP from 58 to 29 mmHg and the PCWP from 32 to 18 mmHg after coronary bypass and mitral annuloplasty, improving systemic blood pressure. In the second, sildenafil was given intra-operatively during an aortic valve replacement for a mPAP of 90 mmHg accompanied by systemic hypotension despite epinephrine, milrinone resulting in a decrease in mPAP to 50 mmHg ( Madden and Crerar-Gilbert 2005 ). In a third, patients’ status post mitral valve surgery or left ventricular assist device (LVAD) placement who received sildenafil for elevated PAP had significant improvement in MAP, mPAP, and PVRI. SVRI decreased, but the PVR/SVR ratio decreased consistent with a preferential pulmonary vasodilation ( Trachte et al 2005 ).
PH is common in the peri-operative period in pediatric cardiac surgery and may respond to treatment with sildenafil. In 12 children with an increased PVRI after cardiac surgery, sildenafil resulted in a significant decrease in PVRI that was greater than that achieved with NO alone, and PVRI/SVRI ratio was consistent with pulmonary selectivity. The addition of NO to sildenafil did not result in a greater benefit. A significant increase in shunt fraction from 16.5% to 25.5% occurred after treatment with sildenafil; however, no patients experienced hypoxia and dead space ventilation remained unchanged. The authors concluded that treatment with inhaled NO and sildenafil were equivalent ( Schulze-Neick et al 2003 ).
A prospective study randomized 15 ventilated infants after ventricular or atrial septal defect closure to receive NO followed by sildenafil or the same therapies in the reverse order. Although sildenafil treatment decreased mPAP and PVRI, the study was stopped early due to worsening oxygenation and systemic hypotension associated with sildenafil ( Stocker et al 2003 ).
Pulmonary thromboembolic disease
Sildenafil has been used in a case of acute pulmonary embolism and right heart failure in the setting of chronic PAH from right to left shunt. A 58-year-old woman hospitalized with a massive tri-lobe pulmonary embolism was found to have a PASP of 100 mmHg accompanied by severe refractory hypoxemia. Sildenafil was started and after 2 hours, PVRI had decreased from 700 to 425 dynes·s −1 ·cm −5 ·m −2 and CI had increased from 2.1 to 3.2 L·min −1 ·m −2 with no change in mPAP ( Ganiere et al 2006 ).
The effects of sildenafil were studied in 12 patients with severe chronic thromboembolic PH (CTEPH) who were not candidates for thrombectomy. Average baseline mPAP, PVRI, and CI were 52.6 mmHg, 1935 dynes·s −1 ·cm −5 ·m −2 and 2.01 min −1 ·m −2 . After approximately 6.5 months of sildenafil treatment, a statistically significant improvement had occurred in all parameters with a mPAP, PVRI, and CI of 44.9 mmHg, 1361 dynes·s −1 ·cm −5 ·m −2 and 2.4 min −1 ·m −2 , respectively, and no adverse events ( Ghofrani et al 2003b ).
Pulmonary fibrosis associated PH
Fibrotic lung disease is frequently associated with PH and can be a source of significant morbidity and mortality ( King et al 2001 ). In patients with interstitial lung disease, systemic administration of vasodilators can increase blood flow to poorly ventilated areas overriding physiologic hypoxic vasoconstriction, leading to worsening V/Q mismatch and shunting with a resultant decrease in arterial oxygenation. Nebulized or inhaled therapies avoid this problem by distributing preferentially to well ventilated alveoli, but delivery systems can be costly and cumbersome to use.
A randomized, open label trial examined the effects of acute administration of oral sildenafil on V/Q matching in interstitial lung disease. Sixteen patients with fibrotic lung disease (idiopathic pulmonary fibrosis, CREST, systemic sclerosis, silicosis, and extrinsic allergic alveolitis) and an mPAP greater than 35 mmHg underwent vasodilator testing with inhaled NO and were randomized to receive intravenous epoprostenol or oral sildenafil. Inhaled NO, epoprostenol, and sildenafil all resulted in a significant decrease in mPAP and PVRI. Cardiac output remained nearly constant in the NO group, while it increased in the sildenafil group and increased to a greater extent in the epoprostenol group. Inhaled NO caused a non-significant decrease in pulmonary shunt flow and a moderate increase in the partial pressure of oxygen. Epoprostenol resulted in a large, significant 16.8% increase in shunt flow, a decrease in the PaO2, increased perfusion to low V/Q areas, and an increase in mean ventilation. Oral sildenafil resulted in a non-significant decrease in shunt flow and a rise in the partial pressure of oxygen. The authors concluded that sildenafil induces vasodilation selectively in well ventilated lung units by acting through intrinsic vasodilator/vasoconstrictor pathways ( Ghofrani et al 2002c ). There are, however, no data evaluating the chronic effects of sildenafil on PH related to alveolar hypoxemia.
Altitude-associated PH
High altitude pulmonary edema (HAPE) is a syndrome that occurs shortly after ascent due to a deranged response to hypoxia and hypobaria in susceptible individuals and accounts for the majority of deaths related to high altitude ( Schäfer and Bauersachs 2002 ). The mechanism is unclear but may be related to an abnormally pronounced degree of pulmonary vasoconstriction secondary to abnormalities in vasodilators and vasoconstrictors (such as NO and endothelin-1), pulmonary capillary tears and leaks, exaggerated sympathetic tone, and induction and release of inflammatory cytokines ( Basnyat and Murdoch 2003 ). Treatment with portable hyperbaric chambers, supplemental oxygen, and nifedipine have been studied in small trials, but their utility is limited by availability and adverse effects. Several trials have examined the role of sildenafil in attenuating the effects of alveolar hypoxia on pulmonary artery pressures and in improving exercise tolerance.
Ghofrani et al examined the response of exercise pulmonary hemodynamics to sildenafil during hypoxic conditions at sea level and at the Mount Everest base camp. When compared with baseline, all participants had a significant pulmonary hypertensive response to hypoxic conditions at sea level and at Everest base camp. The effect was augmented by exercise but significantly blunted by treatment with a one time dose of 50mg of sildenafil (increase in mPAP: placebo group sea level hypoxia rest +75%, exercise +145%; Everest rest +57%, exercise +92%; sildenafil sea level hypoxia rest +26%, exercise +108%; Everest rest +26%, exercise +57%). Sildenafil treatment also resulted in a statistically significant improvement in exercise tolerance under hypoxic or high altitude conditions (hypoxic exercise +20%, Everest exercise +11%) without affecting systemic blood pressure, heart rate, or oxygen saturation ( Ghofrani et al 2004 ).
Another trial examined the effects of sildenafil on hemodynamics in 12 healthy men at sea level, and at 4350m before and after treatment with sildenafil. The sildenafil group had a significantly lower heart rate, higher oxygen saturation, and lower PASP compared with the placebo group. During exercise testing, peak oxygen consumption was higher in the sildenafil group than the placebo group ( Richalet et al 2005 ).
Chronic mountain sickness is a syndrome occurring with long-term exposure to altitude that can result in PH and right heart failure( Ge and Helun 2001 ). A randomized, controlled study evaluated the use of sildenafil to treat PH in residents of the Naryn region of Krygystan, 2500–4000 m a.s.l. Twenty-two patients with PH were randomized to treatment with a single dose and then chronic administration of placebo versus 25 or 100 mg of sildenafil every 8 hours. Compared with placebo, there was a significant decrease in mPAP of 6.7 and 11.6 mmHg after the first dose of sildenafil and at 12 weeks, respectively. Six minute walk and physical symptoms score improved significantly by 43.5 m and 10.4 points at 12 weeks compared with placebo. There was a trend towards a decrease in PVR in the treatment groups ( Aldashev et al 2005 ).
Conclusion
Over the last two decades, enormous progress has been made in the treatment of patients with PH resulting in significant improvement in morbidity and mortality. One example of such advances was the advent of oral therapies for PAH. In this context, sildenafil has emerged as an effective first-line oral therapeutic agent for patients with symptomatic PAH who do not have indications for treatment with intravenous prostacyclin. Salutary effects that may play an important role in the clinical efficacy of sildenafil, but require further study include selective pulmonary vasodilation and antiremodeling properties. Sildenafil shows promise as a useful therapy in numerous case reports of PH from a variety of causes. With the exception of post-operative pediatric cardiac surgery patients, sildenafil has not been associated with significant adverse effects in any of the subtypes of PH for which it has been studied. Clarification of the role of sildenafil in forms of PH other than idiopathic PAH will require future well designed trials.
Drug Interactions With Phosphodiesterase-5 Inhibitors Used for the Treatment of Erectile Dysfunction or Pulmonary Hypertension
From the Heart Institute, Good Samaritan Hospital (B.G.S., R.A.K.), and Department of Internal Medicine, Division of Cardiovascular Medicine, Keck School of Medicine at the University of Southern California (R.A.K.), Los Angeles.
From the Heart Institute, Good Samaritan Hospital (B.G.S., R.A.K.), and Department of Internal Medicine, Division of Cardiovascular Medicine, Keck School of Medicine at the University of Southern California (R.A.K.), Los Angeles.
Originally published 6 Jul 2010 https://doi.org/10.1161/CIRCULATIONAHA.110.944603 Circulation. 2010;122:88–95
Sildenafil and tadalafil were the 32nd and 74th, respectively, most popular prescription drugs dispensed in the United States in 2006. Erectile dysfunction (ED) currently affects >30 million men in the United States and >150 million men worldwide and will become more prevalent as the population ages. 1 Phosphodiesterase-5 (PDE5) inhibitors (PDE5Is) (sildenafil [Viagra], 2 vardenafil [Levitra], 3 and tadalafil [Cialis] 4 ) are first-line therapy for ED. Use of PDE5Is will increase because sildenafil (Revatio) 5 and tadalafil (Adcirca) 6 are now prescribed as first-line therapy for many patients with pulmonary hypertension (PHT). 5–8
Several pooled analyses comprising dozens of trials and thousands of patients, including patients with coronary artery disease and on antihypertensive medications, reported that PDE5Is did not significantly affect the incidence of adverse cardiovascular events. 9–12 However, PDE5 is distributed in many tissues, including platelets, veins, and arterial smooth muscle (pulmonary, coronary, and systemic arteries). 13 Thus, PDE5Is affect the cardiovascular system, mostly via vasodilation, and often cause small decreases in blood pressure (BP). When PDE5Is are coadministered with nitrates or α-blockers, pronounced systemic vasodilation and severe hypotension are possible. Many patients with ED are elderly and have the same risk factors as patients with coronary artery disease, so these drug combinations are commonly considered or encountered in clinical practice. 1 This article covers the important PDE5I drug interactions, including antihypertensive agents, nitrates, α-blockers, PHT agents, cytochrome P450 inhibitors, and other miscellaneous drugs.
Metabolic Clearance
Sildenafil is metabolized mainly by the cytochrome P450 3A4 pathway (79%) and to a lesser extent by 2C9 (20%). 14,15 Vardenafil is metabolized in a similar manner, mainly by 3A4 with a smaller contribution by 2C9. 15 Tadalafil is metabolized almost solely by 3A4. 15 Therefore, drugs that inhibit the 3A4 pathway decrease the metabolism and increase the plasma concentrations of PDE5Is (Table 1). Area under the concentration-time curve (exposure) values for sildenafil ranged from 0.8- to 2.6-fold (mean, 1.2-fold increase) when coadministered with 250 mL grapefruit juice (a 3A4 inhibitor), and results would vary even more in an uncontrolled setting (Table 1). 20 Data on changes in half-life and elimination time are less frequently reported, but 3A4 inhibitors reportedly have small effects or no effect on the half-lives of PDE5Is. 15 An exception is ritonavir, a potent inhibitor of several P450 cytochromes, including 3A4 and 2C9. By simultaneously blocking both pathways, ritonavir prevents a compensatory shift to the 2C9 pathway. Ritonavir increases exposure to sildenafil by 11-fold and increases the half-life of vardenafil from 4 to 26 hours. 3,18 Ritonavir initially inhibits 3A4 but later induces 3A4 after ≈1 week of steady-state levels. 6 The timing of observation likely accounts for the large difference in effects reported with ritonavir coadministration (Table 1). Cimetidine, a less potent, nonspecific cytochrome P450 inhibitor, increases exposure to sildenafil by 1.6-fold. 21 Ketoconazole inhibits sildenafil metabolism to a degree similar to ritonavir. 14 Although each drug combination has not been studied, the following 3A4 inhibitors would likely increase exposure to each of the PDE5Is: erythromycin, ketoconazole, itraconazole, clarithromycin, HIV protease inhibitors, and grapefruit juice. 2–4 The 2C9 inhibitors do not significantly affect the metabolism of PDE5Is. 15 It is unlikely and there is no evidence to date that other drugs metabolized by the 3A4 pathway competitively inhibit PDE5I metabolism because the 3A4 system has a high capacity. 2–4,15,23
Table 1. PDE5I Drug Interactions Involving Cytochrome P450 Isoenzyme CYP3A4
High doses of sildenafil (up to 800 mg) increased the incidence rates and severities of adverse events, although the types of adverse events were similar to those observed with lower doses, including visual disturbances, hypotension, syncope, and prolonged erection. 2 It is likely that higher plasma concentrations resulting from coadministration of 3A4 inhibitors would similarly influence the side-effect profile. For instance, the combination of itraconazole and tadalafil caused priapism in a healthy 56-year-old man. 24 In addition, higher PDE5I plasma concentrations resulting from 3A4 inhibitors can influence the severity and timing of other PDE5I drug interactions, including with nitrates and α-blockers. PDE5I dose adjustments are usually indicated when coadministered with 3A4 inhibitors (Table 2).
Table 2. Dosing of PDE5Is
Conversely, inducers of P450 3A4 increase the clearance and decrease the plasma concentrations of PDE5Is. 2,4 Rifampin reduced exposure to tadalafil by 88%. 4 Although each interaction has not been studied, other 3A4 inducers, including carbamazepine, phenytoin, and phenobarbital, would likely decrease PDE5I plasma levels. 2,4 No initial PDE5I dose adjustment is indicated when coadministered with 3A4 inducers; however, efficacy may be reduced in some patients requiring an increased dose. Adcirca is not recommended for patients taking long-term rifampin. 6
Notably, the metabolism of sildenafil was not affected by warfarin, azithromycin, 16 selective serotonin reuptake inhibitors, thiazides, angiotensin-converting enzyme inhibitors, calcium channel blockers, or antacid. 21 Vardenafil was not affected by warfarin, glyburide, digoxin, or ranitidine. Tadalafil was not affected by warfarin, midazolam, lovastatin, or theophylline. 2–4
Sildenafil and vardenafil weakly inhibit several cytochrome P450 pathways at doses much higher than recommended doses (ie, plasma concentrations 20 times higher than achieved with vardenafil 80 mg). 3,15 There is no evidence to date that sildenafil or vardenafil affects the clearance of other commonly used drugs, including warfarin, digoxin, atorvastatin, ritonavir, amlodipine, 25 and slow-release nifedipine. 2,3 Tadalafil does not inhibit or induce cytochrome P450 pathways and had no significant effect on the pharmacokinetics of digoxin, theophylline, warfarin, midazolam, or lovastatin. 4,15
Pharmacodynamics and Dosing
Sildenafil and vardenafil each have a half-life of 3 to 4 hours, lead to peak plasma levels ≈60 minutes after ingestion, and exhibit reduced absorption with a high-fat meal. 15 The half-life of sildenafil increases as the dose increases (25 mg, 2.6 hours; 100 mg, 3.7 hours). 26 Tadalafil has a half-life of 17.5 hours, which peaks at 2 hours, and its absorption is not influenced by food. 15 Tadalafil can be prescribed for ED as on-demand or once-daily dosing or as once daily for PHT. A dosing guide is provided in Table 2. Refer to the Physicians’ Desk Reference and its updates or product prescribing information for specific dose adjustments. 2–6 Higher plasma concentrations are desirable for the treatment of PHT compared with ED. Of note, some physicians prescribe higher doses of sildenafil (up to 80 mg 3 TID) for PHT than recommended (20 mg TID) on the basis of the doses used in a few clinical trials of PHT. 27,28 Although comparisons were made only with placebo, sildenafil 80 mg TID appeared to improve World Health Organization functional class more than 20 mg TID (placebo-corrected proportion of patients with improvement of at least 1 functional class with sildenafil 80 mg TID, 42%; with 20 mg TID, 28%). 28
Antihypertensives and PDE5Is
PDE5Is can be coadministered with most antihypertensive medications without inducing clinically significant reductions in BP. 29–31 Caution must be used with α-blockers. In general, the BP reductions caused by PDE5Is are small whether they are taken alone or in conjunction with other antihypertensive medications, including β-blockers, diuretics, calcium channel blockers, angiotensin-converting enzyme inhibitors, and angiotensin receptor blockers (Table 3). In most healthy subjects, BP returned to baseline values within 6 hours of sildenafil administration. 34 After tadalafil administration, diastolic BP decreased slightly and remained low for 12 hours, whereas systolic BP (SBP) did not change. 33 Coadministration of sildenafil with antihypertensive medications was evaluated in a posthoc subanalysis of 18 trials including 3975 men, 1094 of whom were also taking at least 1 antihypertensive medication. 30 The incidence of adverse events and adverse events potentially related to BP was similar between men with and those without antihypertensive medications (34% versus 38%) and was also similar in men with multiple antihypertensive medications and between each individual medication. Even coadministration of multiple antihypertensive medications with the relatively longer-acting tadalafil did not increase the occurrence of potentially clinically significant decreases in BP. 29 PDE5Is precipitate little or no change in heart rate. 12,25,33,34,36 Although PDE5Is are generally safe with most vasodilating medications, the exceptions are nitrates and α-blockers, described next.
Table 3. Interactions Between PDE5Is and Various Antihypertensive Medications
Nitrates and PDE5Is
Penile erections and endothelium-mediated vasodilation are mediated through cGMP, which promotes trabecular and vascular smooth muscle relaxation. PDE5Is prevent the breakdown of cGMP. Nitric oxide donors (ie, nitrates) increase the production of cGMP. Because both PDE5Is and nitrates increase cGMP, coadministration can generate excess accumulation of cGMP and can trigger marked vasodilation and severe hypotension. For instance, when Emmick and colleagues 37 analyzed nitroglycerin 0.4 mg in combination with sildenafil 50 mg, tadalafil 10 mg, and placebo, a potentially clinically significant change in BP was observed more frequently with each PDE5I than with placebo (standing SBP
Duration of Contraindication
If a patient has taken a PDE5I and then develops stable angina, unstable angina, or a myocardial infarction, when can nitrates be administered safely? The American College of Cardiology and American Heart Association suggest nitrates can be administered 24 hours (6 half-lives) after sildenafil intake to allow full clearance of the drug. 23 The study by Emmick and colleagues 37 evaluated nitroglycerin administration 1 day after sildenafil, tadalafil, or placebo. The incidence of a significant decrease in BP was similar between sildenafil and placebo but inconclusive for tadalafil (standing SBP 30 mm Hg: placebo, 12%; sildenafil, 4%; tadalafil, 20%). Sildenafil no longer showed evidence of an interaction with nitroglycerin 24 hours after sildenafil administration. 37 The interaction with nitrates may be gone as early as 4 hours after sildenafil intake. When nitroglycerin was administered 4 hours after sildenafil or placebo, there was no significant difference in mean maximal change from baseline BP; however, this abstract did not report the incidence of potentially clinically significant decreases in BP. 38 Likewise, vardenafil is suggested to lack an interaction with nitrates at 24 hours after intake (6 half-lives). 3 Conversely, tadalafil does interact with sublingual nitroglycerin to increase the risk of hypotension at 24 hours but not at 48 hours after tadalafil intake. 39 After receiving tadalafil 20 mg or placebo for 7 consecutive days, 150 men were given repeated doses of nitroglycerin 0.4 mg. At 4, 8, and 24 hours after the last tadalafil intake, nitroglycerin caused more subjects in the tadalafil group than in the placebo group to experience a potentially clinically significant decrease in BP, including a standing SBP
Treatment of PDE5I-Nitrate–Induced Hypotension
What if a patient has taken a PDE5I, receives a nitrate, and becomes hypotensive from pronounced vasodilation? The American College of Cardiology and AHA suggest placing the patient in the Trendelenburg position, aggressive fluid resuscitation, and if necessary an α-agonist (phenylephrine), a β-agonist (norepinephrine), and intraaortic balloon counterpulsation. 23 There is no antidote to PDE5Is.
α-Blockers and PDE5Is
“Uroselective” α-blockers (tamsulosin, alfuzosin) preferentially inhibit α1A and α1D receptors found primarily in the prostate and benefit patients with benign prostatic hypertrophy. Other α-blockers (terazosin) are less selective, and some (doxazosin) are used as third-line agents for hypertension because of their higher affinity for α1B receptors, which are abundant in the peripheral vasculature. 40–42 All α-blockers can cause vasodilation and orthostatic hypotension, and coadministration with PDE5Is increases the risk of a clinically significant decrease in BP. Various combinations of PDE5Is and α-blockers interact to different degrees, as shown in Table 4. The degree of PDE5I–α-blocker interaction depends on which drugs are coadministered, the dose of α-blocker, the timing of administration, and the duration or stability of the α-blocker therapy (Table 4). 42 Tadalafil has fewer effects on the cardiovascular system than the other PDE5Is, as exemplified by its minimal effects on BP in healthy control subjects (Table 3). 33
Table 4. Interactions Between PDE5Is and α-Blockers
Timing of Administration
Vardenafil was studied with terazosin and (in a separate study) tamsulosin, both simultaneously and separated by 6 hours (Table 4). 3 A standing SBP 30-mm Hg decrease in standing SBP occurred in 9 of 24 men receiving tamsulosin and in 19 of 29 men receiving terazosin and led to the early termination of the simultaneous administration of terazosin arm. Compared with administration 6 hours apart, simultaneous administration of vardenafil and terazosin more frequently resulted in a standing SBP 30-mm Hg decrease in standing SBP.
Uroselective α-Blockers
Coadministration of tadalafil with doxazosin and with tamsulosin was evaluated (Table 4). 43 Tamsulosin with tadalafil decreased SBP only minimally and did not increase the risk of a potentially clinically significant decrease in BP relative to placebo. Compared with doxazosin and placebo, doxazosin and tadalafil significantly reduced standing SBP (−9.8 mm Hg) and increased the incidence of a standing SBP
When sildenafil 100 mg alone was compared with sildenafil 100 mg and tamsulosin 0.4 mg coadministration, BP was not statistically different between groups in supine patients or after tilt testing. 45
When coadministration of tadalafil and alfuzosin (uroselective) was evaluated, the change in standing SBP was not statistically significant from tadalafil and placebo (Table 4). 41 Although 1 asymptomatic man had a standing SBP of 83 mm Hg, no man had a supine SBP 30-mm Hg decrease in SBP, or a diastolic BP
Stability of α-Blocker Therapy
Twenty-two men with benign prostatic hypertrophy on stable tamsulosin therapy for >4 weeks were given vardenafil or placebo (Table 4). 44 Small decreases in BP were observed, and the number of potentially clinically significant decreases in SBP was similar between vardenafil and placebo (1 versus 0). Of note, the study described in Timing of Administration did not specify the duration of tamsulosin therapy before vardenafil coadministration.
Dose of α-Blocker
Forty-five men were given tadalafil (5 mg) or placebo for 28 days, and beginning on day 8, increasing doses of doxazosin (1, 2, and 4 mg/d) were administered. 40 The total number of subjects experiencing a potentially clinically significant decrease in SBP or diastolic BP increased on the first day that doxazosin 4 mg was administered (9 of 39 with tadalafil and 7 of 40 with placebo) but decreased by the seventh day of doxazosin 4 mg coadministration (1 of 39 with tadalafil and 2 of 40 with placebo). Therefore, coadministration of doxazosin with long-term tadalafil appeared to have similar effects on BP as placebo; increasing the dose of doxazosin increased the incidence of potentially clinically significant decreases in BP on the first day of the 4 mg dose.
Collectively, these studies indicate that combining PDE5Is with α-blockers increases the risk of a clinically significant decrease in BP. This risk is reduced with tadalafil, with uroselective α-blockers, when low doses of α-blockers are used, when dosing is separated by several hours (instead of simultaneously), and when patients are on stable therapy with 1 agent before the other drug class is administered. 42 Consequently, for patients prescribed α-blockers, current Food and Drug Administration labeling states that PDE5Is are recommended only once α-blocker therapy has become stable. Once stability is achieved with an α-blocker, a PDE5I can be initiated at a low dose (Table 2). When starting α-blocker therapy for patients already optimized on a PDE5I, physicians should begin with the lowest α-blocker dose. Thereafter, increasing the dose of either the α-blocker or PDE5I may further lower BP.
Drugs for PHT and PDE5Is
Because sildenafil and tadalafil have been approved for PHT therapy and their use in combination therapy has been endorsed for certain World Health Organization class IV patients, 7 coadministration with other PHT agents warrants investigation. Administering sildenafil to patients with PHT already taking epoprostenol, 27 iloprost, 46,47 nitric oxide, 48,49 or bosentan 50,51 further improves an array of hemodynamic, clinical status, and exercise capacity parameters with little or no effect on systemic BP and without increasing adverse events or hypotension. Moreover, sildenafil prolonged the effect of inhaled nitric oxide on pulmonary vasodilatation and prevented rebound pulmonary vasoconstriction after inhaled nitric oxide. 49 Coadministration of epoprostenol reduced plasma concentrations of sildenafil by ≈25%, but this interaction was not considered clinically relevant. 5
Bosentan, a P450 3A4 inducer, reduced tadalafil exposure by 42%, whereas bosentan levels were unchanged. 6 Coadministration of bosentan and sildenafil reduced sildenafil exposure by 63% and increased bosentan exposure by 1.5-fold. 22 Coadministration with sildenafil does not increase the risk of liver aminotransferase elevation associated with bosentan. 52 A study of 405 patients with PHT (53% also receiving background bosentan therapy) showed that tadalafil improved 6-minute walk distance, time to clinical worsening, and the incidence of clinical worsening. 53 Interestingly, the increase in 6-minute walk distance was significant in bosentan-naïve patients (44 m; P<0.01) but not for patients on background bosentan (23 m; P=0.09). 53 The greater improvement for bosentan-naïve patients may support the ceiling phenomenon hypothesis that limits additional improvements in patients on background PHT therapy or may reflect the decrease in plasma concentration of PDE5I observed with bosentan coadministration. 53 Additional studies are underway to guide combination therapy.
In subjects given very high doses (sildenafil 800 mg), the types of adverse events were the same, but the incidences and severities of adverse events were increased. 2 Moreover, compared with the doses used for ED, 2,4 the higher doses used for PHT increased the incidences of adverse events. 5,6 For example, the incidence of headache with PHT doses (sildenafil, 46% 5 ; tadalafil, 42% 6 ) was higher compared with ED doses (sildenafil, 16% 2 ; tadalafil, 11% 4 ). Coadministration with 3A4 inhibitors would likely further increase the incidences of adverse events.
There is little direct evidence on the drug interactions of nitrates and α-blockers with the higher PHT doses of PDE5Is. The higher doses increase the plasma concentrations and prolong the elimination time of sildenafil. 4,26 Consequently, the contraindication with nitrates may extend beyond the previously discussed time frames derived from studies using ED doses. Conversely, combination therapy with PDE5Is and systemic nitrates could be therapeutic if the synergistic effect on cGMP and vasodilation remains relatively selective for the pulmonary vasculature as observed with PDE5Is alone. 54
The α-blocker data are inconclusive. In studies using different ED doses of PDE5Is with α-blockers, greater reductions in mean BP parameters and more frequent, potentially clinically significant decreases in BP were observed with higher doses, 4 but many reports were inconclusive, 2,3,43,44 and greater effects were reported with lower doses in some studies. 42
PDE5Is and Risk of Bleeding
The use of PDE5Is has not been evaluated in patients with bleeding disorders, with active peptic ulceration, or on multiple blood-thinning and antiplatelet agents. 2–4 PDE5Is may affect bleeding by a direct action on platelets, which contain PDE5. 55 The product inserts report that PDE5Is, alone or with aspirin, did not affect bleeding time. 2–4,6 Berkels and colleagues 55 reported that sildenafil 100 mg transiently prolonged bleeding time 1 hour after administration and that sildenafil 50 mg did not alter bleeding time. Compared with placebo, sildenafil increased the incidence of epistaxis in patients on concomitant vitamin K antagonists (9% versus 2%) and in patients with PHT secondary to connective tissue disease (13% versus 2%) but not in patients with primary PHT (3% versus 2%). 5 The incidence of epistaxis in PHT clinical trials was higher with sildenafil 27,28 than with placebo and minimally higher with tadalafil 53 compared with placebo. Epistaxis has been associated with on-demand use of sildenafil 56,57 and tadalafil 56,57 for enhanced sexual activity. Sildenafil inhibits ADP-dependent platelet aggregation in vitro, with an additive effect when combined with nitrates. 5,55 Sildenafil combined with heparin had an additive effect on bleeding time in rabbits but has not been studied in humans. 2 Theoretically, dipyridamole, ticlopidine, and clopidogrel may interact with PDE5Is, although no studies have been conducted to evaluate a potential interaction. In conclusion, PDE5Is appear to minimally increase the risk of minor bleeding especially when combined with vitamin K antagonists or nitrates.
Miscellaneous
Unlike other β-blockers, rather than impair sexual activity, nebivolol improves erectile function. 58,59 Nebivolol decreases plasma sildenafil concentration by ≈20%. 60 Coadministration with sildenafil does not potentiate the vasodilatory effect of nebivolol, 61 and the product insert for nebivolol indicates that the effect of the drug combination on pulse and BP is additive. 60
The tadalafil label cautions against ≥5 U alcohol (1 U is ≈1 oz of 80-proof liquor). 4,6 Orthostatic hypotension was observed in patients given tadalafil and 6 U alcohol but not with 4 U. 4 Sildenafil and vardenafil do not carry this warning.
Patient Education
Because of the potential for life-threatening hypotension, patients should be counseled appropriately on the drug interactions of PDE5Is. Patients should be warned to avoid all nitrates, including recreationally inhaled poppers and nitroglycerin from friends or family. Patients should be cautioned appropriately on α-blockers, cimetidine (which can be obtained over the counter), and grapefruit juice. If patients develop chest pain while on PDE5Is, it is crucial for them to divulge the use of PDE5Is to their healthcare providers. Patients should be instructed to contact emergency services if they experience severe dizziness, headache, or syncope that may be related to PDE5Is, and they should inform healthcare workers of their most recent PDE5I intake so that appropriate care can be given. Patients should not share PDE5Is with friends, family, or the “black market.”
Conclusions
PDE5Is are commonly prescribed and have benefited millions of men with ED and increasing numbers of patients with PHT. Although PDE5Is are safe with most antihypertensive agents, coadministration with nitrates or α-blockers poses a risk of severe hypotension. Nitrates are contraindicated within 24 hours of sildenafil and vardenafil and within 48 hours of tadalafil. Only after patients are on stable α-blocker therapy should PDE5Is be initiated, starting with a low dose. Metabolic interactions with bosentan may call for dose adjustments when combination therapy is used. Potent cytochrome P450 3A4 inhibitors, including erythromycin, clarithromycin, ketoconazole, itraconazole, and HIV protease inhibitors, increase PDE5I plasma concentrations. PDE5I drug interactions have the potential to cause life-threatening hypotension in patients with coexisting cardiac disease requiring nitrates or α blockers. Knowledge of these potential drug interactions is needed to avoid severe side effects.
Dr Kloner has served as a speaker and consultant to Pfizer and Lilly. Dr Schwartz reports no conflicts.
Footnotes
Reprint requests to Robert A. Kloner, MD, PhD, Heart Institute, Good Samaritan Hospital, 1225 Wilshire Blvd, Los Angeles, CA 90017-2395. E-mail [email protected]
Cialis originale
Il farmaco Cialis originale distribuito dalla Lilly serve per combattere la disfunzione erettile, ma oggi viene assunto anche da tantissimi uomini che hanno un’attività sessuale del tutto normale. Il Con il principio attivo Tadalafil, una dose di questo potente farmaco regala infatti, un’erezione durevole. Il Cialis nella sua versione originale fa dunque in modo che i problemi generati dalla patologia di cui si è affetti rimangano soltanto un lontano ricordo. Inoltre è importante sottolineare che non bisogna nemmeno preoccuparsi di mangiare del cibo prima di assumerlo e nemmeno di bere bevande alcoliche, anche se questi ultimi è sempre meglio evitarli.
| Pacco | Per Pillola | Prezzo | Risparmio | Bonus | |
|---|---|---|---|---|---|
| 5mg x 4 pillole | € 6.25 | € 25.00 | Compra | ||
| 5mg x 12 pillole | € 4.12 | € 49.39 | € 25.61 | 2 pillole | Compra |
| 5mg x 24 pillole | € 3.26 | € 78.15 | € 71.85 | 3 pillole | Compra |
| 5mg x 48 pillole | € 3.00 | € 143.88 | € 156.12 | 5 pillole | Compra |
| 5mg x 96 pillole | € 2.33 | € 223.57 | € 376.43 | 5 pillole | Compra |
| 5mg x 120 pillole | € 2.13 | € 255.96 | € 494.04 | 5 pillole | Compra |
| Pacco | Per Pillola | Prezzo | Risparmio | Bonus | |
|---|---|---|---|---|---|
| 10mg x 4 pillole | € 6.59 | € 26.34 | Compra | ||
| 10mg x 12 pillole | € 4.89 | € 58.73 | € 20.29 | 2 pillole | Compra |
| 10mg x 24 pillole | € 3.72 | € 89.17 | € 68.87 | 3 pillole | Compra |
| 10mg x 48 pillole | € 3.32 | € 159.24 | € 156.84 | 5 pillole | Compra |
| 10mg x 96 pillole | € 3.12 | € 299.91 | € 332.25 | 5 pillole | Compra |
| 10mg x 120 pillole | € 2.97 | € 356.60 | € 433.60 | 5 pillole | Compra |
| Pacco | Per Pillola | Prezzo | Risparmio | Bonus | |
|---|---|---|---|---|---|
| 20mg x 4 pillole | € 7.09 | € 28.36 | Compra | ||
| 20mg x 12 pillole | € 5.49 | € 65.89 | € 19.19 | 2 pillole | Compra |
| 20mg x 24 pillole | € 4.86 | € 116.58 | € 53.58 | 3 pillole | Compra |
| 20mg x 48 pillole | € 4.29 | € 205.74 | € 134.58 | 5 pillole | Compra |
| 20mg x 96 pillole | € 3.41 | € 326.92 | € 353.72 | 5 pillole | Compra |
| 20mg x 120 pillole | € 3.21 | € 385.03 | € 465.77 | 5 pillole | Compra |
| Pacco | Per Pillola | Prezzo | Risparmio | Bonus | |
|---|---|---|---|---|---|
| 40mg x 4 pillole | € 8.35 | € 33.41 | Compra | ||
| 40mg x 12 pillole | € 6.04 | € 72.43 | € 27.80 | 2 pillole | Compra |
| 40mg x 24 pillole | € 5.33 | € 127.81 | € 72.65 | 3 pillole | Compra |
| 40mg x 48 pillole | € 4.58 | € 219.85 | € 181.07 | 4 pillole | Compra |
| 40mg x 96 pillole | € 3.72 | € 357.41 | € 444.43 | 5 pillole | Compra |
| 40mg x 120 pillole | € 3.46 | € 415.21 | € 587.09 | 5 pillole | Compra |
Le compresse del farmaco Cialis original oggi è possibile tra l’altro comprarle online anche in Italia e senza ricetta in quanto è un prodotto che è stato approvato dal Ministero della Salute ed è ufficialmente riconosciuto come potenziatore sessuale in grado tra l’altro di curare svariate malattie veneree croniche o contratte a seguito di rapporti sessuali non sufficientemente protetti.
Dove e come acquistare il Cialis online
Quello che contraddistingue il Cialis originale da altri farmaci in vendita e dal tipo generico venduto in una farmacia tradizionale consiste nel fatto che sia se viene assunto nella dose da 2,5 mg che in quella da 10 mg al giorno, è l’unico che riesce a durare molto a lungo ovvero per circa 36 ore ed anche oltre. Il prezzo in farmacia del Cialis originale inoltre è anche vantaggioso ed inferiore ad altri di note case farmaceutiche. Per comprare online il Cialis originale ci si può rivolgere anche ad una farmacia online di fiducia che dall’alto della sua provata esperienza di vendita sul web e soprattutto per la serietà da sempre dimostrata, può garantire un acquisto online sicuro in tutti i sensi, ovvero sia dal punto di vista della qualità del farmaco che come a certezza di ottenere il prodotto in tempi piuttosto brevi e senza nessuna sgradita sorpresa. Il Cialis originale e lo stesso dicasi per gli altri della gama come il Cialis Professional o il Cialis super Active è dunque possibile ottenerli non solo al banco di una comune farmacia terrestre, ma anche in una farmacia che opera online e soprattutto senza necessariamente presentare alcuna ricetta medica.
Come agisce il Cialis sull’apparato sessuale?
Il Cialis originale tra i suoi eccipienti base vanta il principio attivo tadalafil. Questo componente serve ad inibire il guanosina monofosfato ciclico, che durante l’eccitazione sessuale libera l’ossido nitrico, con un conseguente aumento del fosfodiesterasi di tipo 5. Sotto l’effetto del tadalafil si ottiene invece una significativa riduzione della suddetta guanosina con un conseguente maggior afflusso di sangue nei genitali che consentono a loro volta al pene di ritrovarsi al massima dell’erezione.
Il corretto dosaggio giornaliero del Cialis
La dose raccomandata di Cialis originale è di una compressa da 10 mg o da 20 mg, prese prima di iniziare l’attività sessuale. Gli uomini con disturbi del fegato o del rene non devono però mai assumere più di 10 mg al giorno del prodotto. Il farmaco può richiedere fino a 16 minuti per migliorare la funzionalità erettile, e i suoi effetti possono durare fino a 36 ore dopo la somministrazione. La somministrazione di Cialis ogni giorno può essere appropriata per gli uomini che prevedono di cimentarsi in rapporti sessuali più di due volte a settimana e la dose consigliata al’inizio è di 5 mg .
Con quali farmaci il Cialis non può interagire?
Il Cialis originale è noto anche per la possibilità di interagire con molti altri medicinali, cosi come alcuni vanno assolutamente evitati in concomitanza con l’assunzione del farmaco per la disfunzione erettile. Ciò significa che il medico può regolarne la dose in base ad un elenco ben preciso che il paziente sottopone alla sua visione, specie se l’assunzione del farmaco Cialis avviene senza informarlo e approfittando del fatto che si può comprare online senza ricetta. Tali farmaci ovviamente non possono interagire nemmeno con gli altri prodotti della gamma Lilly quindi con il Cialis Professional, il Cialis Super Active e il Cialis Soft Tabs.
Chi deve evitare categoricamente il Cialis originale?
Il Cialis originale non va assunto da donne o uomini che abbiano un’età inferiore ai 18 anni. Inoltre l’uso è vietato in altre condizioni di salute come ad esempio in presenza di allergie a tutti gli ingredienti in esso contenuti, nel caso ci siano delle terapie in corso con altri farmaci contenenti nitrati oppure nitriti, sali di isosorbide e nitrato di amilico, sia regolarmente che occasionalmente. Inoltre, del farmaco Cialis, è importante sapere che ci deve essere un periodo di almeno 48 ore (oppure di 4-5 giorni per gli anziani) a partire dall’ultima dose di somministrazione prima di usare di nuovo farmaci contenenti i suddetti nitrati o nitriti.
Le controindicazioni del Cialis originale
Tra le controindicazioni presenti nel Cialis vale la pena sottolineare che quelle che maggiormente sono rilevanti interessano i soggetti affetti da patologie di carattere cardiovascolare come ad esempio angina instabile e grave insufficienza cardiaca. Lo stesso discorso vale per chi ha dei problemi di fegato e renali, mentre recenti studi hanno dimostrato che sono trascurabili dei sintomi comuni come la congestione nasale, il mal di testa oppure l’offuscamento della vista. Tuttavia nel caso questi sintomi dovessero apparire e risultare persistenti è sempre opportuno consultare un medico.
