Congenital Heart Disease Clinical Trial
Official title:
Influence of Genetic Polymorphisms on Ventricular Structure and Function in Patients With Single Ventricle Anatomy
There are many kids born with congenital heart disease. Some of these defects may lead to the formation of a single ventricle (the heart having only one pumping chamber). These children normally undergo a series of corrective surgeries to help overcome the problems of having just one ventricle. However there are some differences in how well the patients respond to the surgeries. In the adult population, studies have shown that there may be a genetic link that may be responsible for the differences in how patients respond. The investigators would like to study the pediatric population by looking for certain genetic markers in the patients' blood. They will also collect basic health information on each patient.
In the United States, approximately 30,000 children are born with congenital heart disease
every year. Between 1000 and 2000 of these children have some form of functional single
ventricle anatomy, with variants of hypoplastic left heart syndrome (HLHS) comprising about
half. Patients with functional single ventricle anatomy are born with a malformation that
renders one of their ventricles unusable and surgically unrecoverable. In HLHS, for example,
either the mitral or aortic valve can be absent or significantly stenotic, which is
generally associated with marked hypoplasia of the left ventricle and the ascending aorta.
Other common variants of single ventricle anatomy are tricuspid or pulmonary atresia, often
associated with some degree of right ventricular hypoplasia, unbalanced atrioventricular
defects, in which either ventricle can be unusable due to malposition of the
interventricular septum, and the heterotaxy syndromes. All of these congenital cardiac
anomalies, as well as several other less common variants, can be treated with a multi-stage
surgical palliation that usually requires three surgical procedures during the first three
years of life. At the completion of this series of palliative procedures the children are
left with their single functional ventricle driving blood flow to the systemic circulation
while their pulmonary circulation is derived from passive drainage of the systemic venous
return into and through the pulmonary vasculature. This arrangement, the so-called "Fontan
physiology", can provide an excellent quality of life as these children grow and enter young
adulthood; however, it is by no means a normal hemodynamic arrangement and a significant
percentage of children with single ventricle anatomy will fail either during the early
palliative steps or at some point after they achieve final Fontan palliation.
Failure of single ventricle patients to progress through the multi-stage palliation or late
failure of patients after the Fontan procedure can result from a myriad of causes. While
ventricular dysfunction is a common finding in failing single ventricle patients, an
anatomic reason for their clinical failure, such as myocardial ischemia or ventricular
outflow obstruction, often cannot be identified. Many of these patients subsequently die or
require cardiac transplantation when their single ventricle fails. Because patient outcomes
are highly variable despite similar anatomy and hemodynamics, it has been suggested that
genetic variability may play a role in the ability of patients to tolerate long-term single
ventricle palliation.
The interaction between genetic variability and outcomes has been well documented for adult
patients with cardiovascular disease. Genetic polymorphisms in the renin-angiotensin system
(RAS) in particular have been well studied. The active final product of the RAS is
angiotensin-II, which is produced by the sequential cleavage of angiotensinogen (AGT) by
renin and angiotensin-converting enzyme (ACE). Several steps in this series of enzymatic
reactions have been evaluated as candidate genes of influence for cardiovascular disorders.
Polymorphisms in the AGT gene have been associated with essential hypertension, however, a
subsequent study failed to demonstrate any influence of these polymorphisms on outcome in
patients with idiopathic dilated cardiomyopathy. A polymorphism in the ACE gene involving a
287-base pair insertion (I) or deletion (D) has been evaluated in several studies. The DD
genotype is associated with higher serum levels of ACE and angiotensin II, increased
incidence of sudden death in patients with hypertrophic cardiomyopathy, increased mortality
in patients with idiopathic heart failure, and decreased exercise tolerance in patients with
congestive heart failure. Meanwhile, a genetic variant in the Angiotensin II type 2-receptor
(AT2-R) has been shown to influence left ventricular structure and function in young men
with hypertension.
Another potentially important contributor to ventricular function that has been studied with
regard to genetic polymorphism related variability is the Beta1-adrenergic receptor
(Beta1-AR). The Beta1-AR is the primary myocardial receptor for the catecholamines
epinephrine and norepinephrine, which increase myocardial contractility and blood pressure.
Several polymorphisms in the Beta1-AR gene have been associated with an increased risk for
congestive heart failure and with exercise capacity in patients with ischemic or idiopathic
cardiomyopathy.
A final area of interest is the opposing system of vasodilators and vasoconstrictors that
control systemic vascular tone. Two major contributors to vasomotor tone in humans are the
endothelium derived vasodilator nitric oxide (NO) and the powerful vasoconstrictor
endothelin-1. Endothelial NO is produced by the enzyme endothelial nitric oxide synthase
(eNOS). A single base-pair polymorphism (G894T) is associated with an increased risk of
vasospastic angina pectoris and with increased vascular responsiveness to phenylephrine in
patients on cardiopulmonary bypass. Meanwhile, a single base-pair polymorphism in the
preproendothelin-1 (pp-ET1) gene (G5665T) has been shown to increase vasomotor reactivity in
human mammary arteries. This polymorphism is also associated with hypertension in overweight
patients with the T allele.
While there is very little data available regarding the causes of failure in children with
single ventricle anatomy, it is clear that genetic factors which influence ventricular
function and the development of heart failure in adults with two ventricles could play a
role in the failure of patients with one ventricle. We propose a combined retrospective and
prospective evaluation of each of the candidate gene polymorphisms discussed above for
potential linkage to poor outcome in children with single ventricle anatomy. Poor outcome
for these children would be defined as a multi-endpoint variable including death, evaluation
for heart transplantation, or the development of severe single ventricle dysfunction by
echocardiographic or cardiac catheterization criteria. Identification of high-risk
combinations of genetic alleles could guide therapy for patients with poor predicted
outcome, possibly steering such patients towards early transplantation rather than attempted
staged palliation.
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Observational Model: Cohort, Time Perspective: Prospective
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