Objective
Valve in valve (ViV) procedures using transcatheter aortic valves
(TAV) are increasingly performed to treat degenerated bioprosthetic surgical
aortic valves (SAV) due to being less invasive than redo aortic valve
replacement. The objective of this study is to quantify the changes in
aortic sinus blood flow dynamics before and after ViV to gain insight into
mechanisms for clinical and sub-clinical thrombosis of leaflets.
Methods
A detailed description of the sinus hemodynamics for ViV implantation
was performed in-vitro. A Medtronic Hancock II porcine bioprosthesis was
modeled as SAV and a Medtronic CoreValve and Edwards Sapien were used as the
TAVs. High-resolution particle image velocimetry (PIV) was employed to
compare the flow patterns from these two valves within both the left
coronary and non-coronary sinuses in vitro.
Results
Velocity and vorticity within the surgical valve sinuses reached peak
values of 0.7 m/s and 1000 s−1, with a 70%
decrease in peak fluid shear stress near the aortic side of the leaflet in
the non-coronary sinus. With the introduction of TAV, peak velocity and
vorticity were reduced to around 0.4 m/s and 550 s−1 and
0.58 m/s and 653 s−1 without coronary flow and 0.60 m/s
and 631 s−1 and 0.81 m/s and 669 s−1
with coronary flow for CoreValve and Sapien ViV respectively. Also, peak
shear stress was around 38% higher along the aortic side of the
coronary vs non-coronary TAV leaflet.
Conclusions
Decreased flow and shear stress in ViV indicates higher risk of
leaflet thrombosis secondary to flow stasis in the non-coronary sinus.
(1) Comparable PGs were found among the TAVs in different models; (2) pinwheeling indices were found to be different between both TAVs; (3) turbulence patterns among both TAVs translated according to RSS were different. Rigid aortic models yield more conservative estimates of turbulence; (4) both TAVs exhibit peak maximal RSS that exceeds platelet activation 100 Pa threshold limit.
Transcatheter aortic valves (TAVs) represent the latest advances in prosthetic heart valve technology. TAVs are truly transformational as they bring the benefit of heart valve replacement to patients that would otherwise not be operated on. Nevertheless, like any new device technology, the high expectations are dampened with growing concerns arising from frequent complications that develop in patients, indicating that the technology is far from being mature. Some of the most common complications that plague current TAV devices include malpositioning, crimp-induced leaflet damage, paravalvular leak, thrombosis, conduction abnormalities and prosthesis-patient mismatch. In this article, we provide an in-depth review of the current state-of-the-art pertaining the mechanics of TAVs while highlighting various studies guiding clinicians, regulatory agencies, and next-generation device designers.
First, supraannular axial deployment is associated with lower PGs irrespective of commissural alignment. Second, subannular deployment is associated with more favorable sinus hemodynamics and less LF. Further in vivo studies are needed to substantiate these observations and facilitate optimal prosthesis positioning during ViV procedures.
Sinus flow dynamics are highly sensitive to aortic root characteristics and transcatheter aortic valve aortic root interaction. Differences in sinus-flow washout and stasis regions between representative patient models may be reflected in different risks of leaflet thrombosis or valve degeneration.
Leaflet thrombosis is a complication associated with transcatheter aortic valve (TAV) replacement (TAVR) correlated with sinus flow stasis. Sinus hemodynamics are important because they dictate shear stress and washout necessary to avoid stasis on TAV leaflets. Sinus flow is controlled by TAV axial deployment position but little is known regarding TAV axis misalignment effect. This study aims to elucidate TAV angular misalignment with respect to aortic root axis effect on sinus flow stasis potentially leading to leaflet thrombosis. Sinus hemodynamics were assessed in vitro using particle-image velocimetry in three different angular misalignments with respect to aorta axis: untilted, tilted away from the sinus and tilted towards sinus. A 26 mm Edwards SAPIEN3 was implanted in a 3D printed model of an anatomically realistic aortic root. TAV hemodynamics, sinus vortex tracking, leaflet shear stress probability density functions, and sinus blood time to washout were calculated. While pressure gradients differed insignificantly, blood velocity and vorticity decreased significantly in both tilted cases sinuses. Shear stress probability near the leaflet decreases with tilt indicating stasis. TAV tilted away from the sinus is the most unfavorable scenario with poor washout. TAV axial misalignment adds to factors list that could influence leaflet thrombosis risk through modifying sinus hemodynamics and washout.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.