电气导管
心脏瓣膜
球囊扩张
阀体孔板
气球
医学
外科
生物医学工程
生物相容性材料
解剖
机械工程
工程类
作者
Richard L. Li,Mingze Sun,Jonathan B. Russ,Pierre‐Louis Pousse,Alexander P. Kossar,Isabel Gibson,Costas Paschalides,Abigail R. Herschman,Maryam H. Abyaneh,Giovanni Ferrari,Emile Bacha,Haim Waisman,Vijay Vedula,Jeffrey W. Kysar,David Kalfa
标识
DOI:10.1002/mabi.202300011
摘要
Abstract Currently available heart valve prostheses have no growth potential, requiring children with heart valve diseases to endure multiple valve replacement surgeries with compounding risks. This study demonstrates the in vitro proof of concept of a biostable polymeric trileaflet valved conduit designed for surgical implantation and subsequent expansion via transcatheter balloon dilation to accommodate the growth of pediatric patients and delay or avoid repeated open‐heart surgeries. The valved conduit is formed via dip molding using a polydimethylsiloxane‐based polyurethane, a biocompatible material shown here to be capable of permanent stretching under mechanical loading. The valve leaflets are designed with an increased coaptation area to preserve valve competence at expanded diameters. Four 22 mm diameter valved conduits are tested in vitro for hydrodynamics, balloon dilated to new permanent diameters of 23.26 ± 0.38 mm, and then tested again. Upon further dilation, two valved conduits sustain leaflet tears, while the two surviving devices reach final diameters of 24.38 ± 0.19 mm. After each successful dilation, the valved conduits show increased effective orifice areas and decreased transvalvular pressure differentials while maintaining low regurgitation. These results demonstrate concept feasibility and motivate further development of a polymeric balloon‐expandable device to replace valves in children and avoid reoperations.
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