Heart Septal Defects, Atrial Clinical Trial
Official title:
BOsentan for Mild Pulmonary Vascular Disease in Asd Patients (the BOMPA Trial): a Double-blind, Randomized Controlled, Pilot Trial
Volume overload due to left-to-right shunting in patients with atrial septal defect type
secundum causes pulmonary vascular disease over a long period of time. Pulmonary vascular
resistance can be assessed non-invasively using bicycle stress echocardiography. By
measuring cardiac output and pulmonary artery pressures at different stages of exercise, a
pressure-output plot can be obtained. The slope of the pressure-output plot reflects
pulmonary vascular resistance. In patients undergoing ASD repair after the age of 40 years,
pulmonary vascular resistance was higher when compared to age-matched controls, indicating
the presence of mild pulmonary vascular disease. Bosentan has been shown to decrease
pulmonary vascular resistance.
The investigators hypothesize that in patients with an ASD type secundum, who underwent ASD
repair after the age of 40 years, administration of bosentan decreases pulmonary vascular
resistance as assessed by bicycle stress echocardiography.
1. INTRODUCTION AND RATIONALE
1.1 MEDICAL BACKGROUND
Atrial septal defect (ASD) represents approximately 10% of all congenital heart
diseases and is the third most common form of congenital heart defect. The incidence of
congenital heart disease in Belgium is 1%, with ASD accounting for 25% of the cases
(Data from the database of congenital heart diseases UZ Leuven.) Characterized by a
free communication between the left and the right atrium, it may take the form of an
ostium secundum defect (in the region of the fossa ovalis); an ostium primum defect (in
the lower part of the atrial septum and associated with mitral regurgitation) or a
sinus venosus defect (in the upper atrial septum and associated with anomalous drainage
of one or more pulmonary veins)
Patients with atrial septal defect (ASD) initially present with a left-to-right shunt,
which may cause elevated pulmonary artery pressures at rest and/or during exercise.
However, this persistently elevated pulmonary blood-flow also causes progressive
lesions of the pulmonary vasculature, as first described by Heath and Edwards. The
earlier stages present with medial hypertrophy and/or intimal proliferation and are
largely reversible after closure of the defect. Later stages, however, are
irriversible: the origin of pulmonary arterial hypertension (PAH). Eventually, this
volume and pressure overload of the right heart may lead to heart failure and/or
arrhythmias. As PVR exceeds systemic resistance, the shunt is reversed (right-to-left
shunt) leading to systemic arterial desaturation (and the related consequences:
polyglobulia, hyperuricemia, decreased renal function and abnormal coagulation): the
Eisenmenger syndrome (ES). When occlusive fibrotic lesions have developed later in
life, closure of the ASD, although still feasible, may not result in complete
normalization of pulmonary artery pressures. Moreover, it has been shown that closure
after the age of 40 years is associated with worse outcome. It has been suggested that
an abnormal increase in pulmonary artery pressures during exercise reflects mild
pulmonary vascular disease. However, pulmonary artery pressures are defined by both
cardiac output and pulmonary vascular resistance. During exercise, the relationship
between pulmonary artery pressures and cardiac output is slightly curvilinear because
of a natural distensibility of the pulmonary arterioles. Using bicycle stress
echocardiography, pulmonary vascular resistance can be estimated either as a ratio of
pulmonary artery pressure and cardiac output at each stage (total PVR) or by using
linear regression analysis of the pressure-flow plots (dynamic PVR).
Prognosis of patients with unrepaired ASDs is thought to be shortened and repair can
avoid right ventricular (RV) failure, pulmonary hypertension, thrombo-embolic events
and atrial dysrrhythmias. So, when the defect is discovered early, an ASD is usually
closed in childhood, unless the defect is considered not to be clinical significant.
Sometimes, as most patients with an isolated ASD are asymptomatic during childhood, an
ASD comes to medical attention at an older age.
Patients with a corrected ASD have a poorer prognosis than patients in a control group,
especially in the presence of PAH, which confers an eightfold increased probability of
functional limitations. In the Euroheart survey PAH was present in 12% of patients with
a closed ASD. As PAH is a progressive disease, early diagnosis and treatment may
improve outcome in these patients.
A first analysis of data obtained from the registry of ASD showed that in the
transcatheter closed ASD patients, mPAP was the only independent predictor of atrial
arrhythmia after ASD repair. Moreover, our first prospective study showed that it is
possible to identify patients with mild pulmonary vascular disease using stress
echocardiography and that patients with an ASD closed at later age were unable to
decrease pulmonary vascular resistance during exercise, resulting in a higher pulmonary
vascular resistance at peak exercise when compared to a control group. This was
reflected in a steeper pressure-flow plot when compared to healthy controls. Endothelin
has shown to influence vasomotor tone, especially during exercise. Moreover, Faoro et
al showed that bosentan decreased pulmonary vascular resistance as assessed with
pressure-flow plots during hypoxia. Therefore, this study was designed to evaluate the
effect of an dual endothelin receptor antagonist on total pulmonary vascular resistance
during exercise in an older ASD patient population.
1.2 DRUG PROFILE
Mechanism of action
Bosentan is a dual endothelin receptor antagonist (ERA) with affinity for both
endothelin A and B (ET-A and ET-B) receptors. Bosentan decreases both pulmonary and
systemic vascular resistance resulting in increased cardiac output without increasing
heart rate.
The neurohormone endothelin-1 (ET-1) is one of the most potent vasoconstrictors known
and can also promote fibrosis, cell proliferation, cardiac hypertrophy, and remodeling
and is pro-inflammatory. These effects are mediated by endothelin binding to ET-A and
ET-B receptors located in the endothelium and vascular smooth muscle cells. ET-1
concentrations in tissues and plasma are increased in several cardiovascular disorders
and connective tissue diseases, including pulmonary arterial hypertension, scleroderma,
acute and chronic heart failure, myocardial ischaemia, systemic hypertension and
atherosclerosis, suggesting a pathogenic role of ET-1 in these diseases. In pulmonary
arterial hypertension and heart failure, in the absence of endothelin receptor
antagonism, elevated ET-1 concentrations are strongly correlated with the severity and
prognosis of these diseases.
Bosentan competes with the binding of ET-1 and other ET peptides to both ET-A and ET-B
receptors, with a slightly higher affinity for ET-A receptors (Ki = 4.1-43 nM) than for
ET-B receptors (Ki = 38-730 nM). Bosentan specifically antagonises ET receptors and
does not bind to other receptors.
1.3 RATIONALE FOR PERFORMING THE STUDY
Although an ASD seems an easily correctable defect, patients with a repaired ASD have a
poorer prognosis than patients in a control group, especially in the presence of PAH,
which confers an eightfold increased probability of functional limitations. In the
Euroheart survey PAH was present in 12% of patients with a closed ASD. Whether it is
useful to treat mild to moderate pulmonary vascular disease after repair of an ASD with
specific PAH treatment in order to have a positive effect on exercise capacity and even
outcome outcome still needs to be evaluated.
As outlined in section 1.1, the investigators were able to identify patients with mild
pulmonary vascular disease using bicycle exercise echocardiography. Patients with an
ASD repaired after the age of 40 years appeared to have higher PVR when compared to
healthy controls. Moreover, in older patients a higher mPAP at diagnosis was an
independent predictor for the occurrence of late atrial arrhythmias.
Therefore, the present study will investigate whether bosentan has a beneficial effect
on PVR as measured with bicycle stress echocardiography in patients with repaired ASD
and WHO FC II mild pulmonary vascular disease using dynamic PVR as a surrogate
endpoint.
1.3.1 DOSE AND POSOLOGY
Treatment will be initiated at a dose of 62.5 mg twice daily for 4 weeks and then
increased to the maintenance dose of 125 mg twice daily for 12 weeks.
Dosage in elderly patients: No dosage adjustment in required in patients over the age
of 65 years.
2. STUDY OBJECTIVES
The primary efficacy objective is to assess the efficacy of the dual active endothelin
receptor antagonist bosentan in patients with WHO functional class II mild to moderate
PAH after surgical or interventional closure of an ASD .
3. STUDY DESIGN
This is a prospective, monocentric, randomised, double-blind, placebo-controlled, pilot
study to evaluate the efficacy of dual active endothelin receptor antagonist bosentan in
patients with WHO FC II, mild pulmonary vascular disease after ASD repair.
4 STATISTICAL METHODS AND DETERMINATION OF SAMPLE SIZE
The null hypothesis of the study is that in patients receiving specific PAH treatment no
change in PVR is observed. This trial aims to demonstrate to efficacy of bosentan to lower
PVR as assessed by bicycle exercise echocardiography in patients with surgically or
transcatheter closed ASD.
5 RANDOMISATION
Patients will be randomly assigned to treatment groups with equal probability of assignment
to each treatment arm (allocation ratio 1:1). The randomisation schedule will be generated
using validated software. The investigators will remain blinded to the randomisation
schedule until after the final database is locked. The randomisation schedule will be
examined only if required by an emergency. Any such break should be documented clearly.
6 SAMPLE SIZE CALCULATION
As the study design is considered as a pilot trial, it primarily aims at defining means and
standard deviations in both treatment arms in order to allow for future sample size
calculations.
;
Allocation: Randomized, Endpoint Classification: Efficacy Study, Intervention Model: Parallel Assignment, Masking: Double Blind (Subject, Caregiver, Investigator, Outcomes Assessor), Primary Purpose: Treatment
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