Optimizing pulmonary valved conduit leaflet geometry by reducing leaflet height decreased peak velocity by 3.79%, maximum equivalent strain by 45.18%, and coaptation area by 66.57% at 3.5 L/min.
Optimizing leaflet morphology by reducing leaflet height and scaling down free edge length improves the hemodynamic performance and reduces strain in pulmonary valved conduits in vitro.
ABSTRACT This study investigated the influence of leaflet geometry on the hemodynamic performance of pulmonary valved conduits and optimized leaflet trimming parameters using a design of experiments (DOE) approach combined with in vitro hydrodynamic testing. In vitro hydrodynamic experiments were performed to validate the feasibility of the valved conduit. A computational model was then established based on the experimental setup. DOE was applied to systematically assess and optimize leaflet tailoring parameters. Fluid–structure interaction simulations showed that leaflet tailoring significantly affects hemodynamic outcomes. Reducing leaflet height improved conduit performance. At a cardiac output of 3.5 L/min, the optimized valve exhibited a 3.79% decrease in peak velocity, a 45.18% reduction in maximum equivalent strain, and a 66.57% decrease in coaptation area. These findings suggest that scaling down the free edge length relative to graft diameter and moderately reducing leaflet height may help reduce diastolic regurgitation caused by redundant leaflet overlap while lowering leaflet strain, thereby enhancing valve durability.
Zheng et al. (Sun,) ने Pulmonary valved conduit डिज़ाइन में एक और अध्ययन किया। Hemodynamic प्रदर्शन (peak velocity, maximum equivalent strain, coaptation area) पर Optimized leaflet trimming parameters बनाम Unoptimized valve का मूल्यांकन किया गया। leaflet ऊंचाई को कम करके pulmonary valved conduit leaflet geometry का अनुकूलन करने से peak velocity 3.79% कम हो गया, maximum equivalent strain 45.18% कम हो गया, और coaptation area 66.57% कम हो गया 3.5 L/min पर।