Pulmonary Arterial Hypertension Clinical Trial
Official title:
4DFlow Magnetic Resonance Imaging in Patients With Pulmonary Hypertension Associated With Congenital Heart Disease
Congenital heart disease is the most common congenital anomaly. The life expectancy of
children with congenital heart disease has increased considerably in recent years.
Nevertheless, the evolution of these patients is marked by an increased risk of
complications. Arrhythmias, heart failure, pulmonary arterial hypertension (PAH) and
endocarditis may be promoted by the absence or delay of management in childhood, by residual
lesions or post-operative cardiac scars and by the presence of prosthetic materials.
PAH is a common complication of congenital heart disease, especially in non-operated shunts.
PAH corresponds to an increase in pulmonary vascular resistance and mean pulmonary arterial
pressure that becomes greater than 25mmHg at rest, leading to right ventricular failure and
ultimately to the patient's death.
Eisenmenger's syndrome corresponds to a non-reversible pulmonary arterial hypertension with a
left-right shunt initially left open, then right-left secondary to the increase in pulmonary
vascular resistance, leading to cyanosis, polycythemia and multivisceral involvement. It is
the most advanced form of PAH with congenital heart disease.
PAH will be suspected during echocardiographic follow-up of any patient with congenital heart
disease, on the analysis of the velocity of tricuspid and/or pulmonary regurgitation flow.
Echocardiography allows the monitoring of the VD (right ventricle) function, which is the
major prognostic element in PAH. Cardiac catheterization is systematically recommended and
remains the gold standard to confirm the diagnosis of PAH, establish its pathophysiology and
prognosis but also for the follow-up under medical treatment of these patients in tertiary
centres every 6 months. Although this tool is the gold standard, rigorously performed, it
remains an invasive examination often poorly experienced by patients.
4D Flow MRI is a promising imaging that allows the acquisition of anatomical, volume, right
ventricular remodeling and intracardiac flow information in a single step with 2D (only 8
minutes extra), in free breathing and totally autonomous mode. Thus, at the same time as the
realization of a 2D MRI, essential for the diagnosis and follow-up of PAH, with an additional
8 minutes for 4D flow, the investigators could have additional fundamental information on
pulmonary cardiac output but also prognostic markers of right ventricular dysfunction turning
dramatic in pulmonary vascular disease.
Cardiac catheterization is systematically recommended and remains the gold standard to
confirm the diagnosis of PAH, establish its pathophysiology and prognosis but also for the
follow-up under medical treatment of these patients in tertiary centres every 6 months. Some
centres repeat invasive hemodynamic assessment in the event of clinical aggravation before
considering a change in drug management or overall management. This is the reference
examination for the calculation of PVRs, an extremely rigorous methodology is required in
patients with intracardiac shunt: the Fick principle must then be applied to calculate Qp.
Usually, it is calculated by thermodilution but is no longer applicable in the case of
intracardiac shunt, as is significant valvulopathy or massive tricuspid leakage. Qp is equal
to the oxygen consumption (MVO2) divided by the difference in oxygen content (CaO2) between
the pulmonary artery and the pulmonary veins (VP). Qp= MVO2/ (CaO2VP- CaO2 AP). They must be
carried out with a rigorous methodology adapted on a case-by-case basis according to the
anatomy and hemodynamics of the heart disease and a precise knowledge of the limits of the
technique, in expert centres in PAH and congenital heart disease and must not be seen as
without consequences for the patient . Although this tool is the gold standard, rigorously
carried out in our reference centre, with rare accidents or potential risks, it remains an
invasive examination often poorly experienced by patients .
Magnetic resonance imaging (MRI) has emerged in recent years as the reference technique for
non-invasive morphological and functional evaluation of the right ventricle. It also seems
relevant for the study of pulmonary arterial hemodynamics while providing prognostic values
for PAH. Its regular implementation is indicated in the 2015 ESC guidelines for the diagnosis
and follow-up of patients, with more particularly an injection of gadolinium for the search
for myocardial fibrosis, a marker of right ventricular remodelling. Also considered are:
decrease in right ventricular ejection fraction, paradoxical septal kinetics, decrease in
left ventricular dimensions, compliance of the pulmonary artery (mL/mmHg) and mean flow
velocity (cm/s). Carrying out this examination using conventional techniques (2D MRI) has
some limitations. Extrinsic, linked to operators and observers. The quality of the
examinations here depends on the quality of the acquisitions made by the radiology
manipulators (sequences / section plans) as well as an adapted analysis of these
cardiopathies. All of this involves a high degree of technical expertise on the part of
paramedical staff, as well as expertise in congenital heart disease and cardiac imaging for
medical staff. Finally, this examination has intrinsic limitations, since it does not allow
the characteristics of intracardiac or vascular flows (turbulence, direction, vortex) to be
explored. All this implies an examination time of about 30 minutes 4D Flow MRI is a promising
imaging that allows the acquisition of anatomical, volume, right ventricular remodeling and
intracardiac flow information in a single step with 2D (only 8 minutes extra), in free
breathing and totally autonomous mode. It is a sequence allowing a quasi-isotopic,
retrospective analysis, providing information on blood flow in the 3 planes of the space,
during the cardiac cycle. It is not influenced by the quality of the medical teams and, above
all, it allows an unlimited post-processing capacity. This innovative imaging method is
therefore particularly suitable for the study of cardiac output such as Qp. The right
ventricular volume is difficult to analyze due to the complexity of its geometry, automatic
segmentation is still under development, this element seems to be a promising hemodynamic
parameter since it is quantitatively calculated and seems to be correlated with the systolic
function of the left ventricle and inaccessible to conventional techniques due to the
particular geometry of the right ventricle. Previous studies have demonstrated the
possibility of qualitative analysis of intraventricular blood flows by studying retrograde
flows, vortices and their kinetic energy, which are involved in diastolic dysfunction of the
right ventricle .Studies have shown that these structures can be altered in PAH dog models
but also in repaired Fallot tetralogy series and Fontan type circulations .
Thus, at the same time as the realization of a 2D MRI, essential for the diagnosis and
follow-up of PAH, with an additional 8 minutes for 4D flow, the investigators could have
additional fundamental information on pulmonary cardiac output but also prognostic markers of
right ventricular dysfunction turning dramatic in pulmonary vascular disease.
Our objective is to evaluate the contribution of 4D MRI flow imaging to the measurement of
pulmonary cardiac output compared to the gold standard which is cardiac catheterization using
the Fick method. But also, to compare 2D and 4D MRI flow for the evaluation of volumes,
function and right ventricular remodeling, as well as the quantification of pulmonary,
tricuspid and systemic flows.
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