Transcatheter management of pure native aortic valve regurgitation in patients with left ventricular assist device.

OBJECTIVES: Aortic valve regurgitation (AR) frequently complicates the clinical course after left ventricular assist device (LVAD) implantation. Transcatheter aortic valve implantation (TAVI) has emerged as an alternative to surgical aortic valve replacement (SAVR) in this cohort with a mostly high surgical risk profile. The unique challenges in LVAD patients, such as presence of non-calcified aortic valves and annular dilatation, raise concerns about device migration and paravalvular leakage (PVL) leading to missing device success. This study evaluates procedural outcomes and survival rates in LVAD patients who underwent TAVI, emphasizing strategies to enhance device success. METHODS: Between January 2017 and April 2023, 27 LVAD patients with clinically significant AR underwent elective or urgent TAVI at our centre. Primary end-points were procedural success rates, without the need for a second transcatheter heart valve (THV) and postprocedural AR/PVL. Secondary outcomes included survival rates and adverse events. RESULTS: Among the cohort, 14.8% received AR-dedicated TAVI devices, with none requiring a second THV. There was no intraprocedural AR, and 1 patient (25%) had AR > 'trace' at discharge. Additionally, 25.9% underwent device landing zone (DLZ) pre-stenting with a standard TAVI device, all without needing a second THV. There was no intraprocedural AR, and none to trace AR at discharge. Among the 59.3% receiving standard TAVI devices, 37.5% required a second THV. In this subgroup, intraprocedural AR > 'trace' occurred in 12.5%, decreasing to 6.25% at discharge. In-hospital mortality was 3.7%, and median follow-up survival was 388 days (interquartile range 208-1167 days). CONCLUSIONS: TAVI yields promising procedural outcomes and early survival rates in LVAD patients with AR. Tailored TAVI devices and pre-stenting techniques enhance procedural success. Continued research into these strategies is essential to optimize outcomes in this complex patient cohort.

Anisotropic topographies restore endothelial monolayer integrity and promote the proliferation of senescent endothelial cells.

Thrombogenicity remains a major issue in cardiovascular implants (CVIs). Complete surficial coverage of CVIs by a monolayer of endothelial cells (ECs) prior to implantation represents a promising strategy but is hampered by the overall logistical complexity and the high number of cells required. Consequently, extensive cell expansion is necessary, which may eventually lead to replicative senescence. Considering that micro-structured surfaces with anisotropic topography may promote endothelialization, we investigated the impact of gratings on the biomechanical properties and the replicative capacity of senescent ECs. After cultivation on gridded surfaces, the cells showed significant improvements in terms of adherens junction integrity, cell elongation, and orientation of the actin filaments, as well as enhanced yes-associated protein nuclear translocation and cell proliferation. Our data therefore suggest that micro-structured surfaces with anisotropic topographies may improve long-term endothelialization of CVIs.

The path to a hemocompatible cardiovascular implant: Advances and challenges of current endothelialization strategies.

Cardiovascular (CV) implants are still associated with thrombogenicity due to insufficient hemocompatibility. Endothelialization of their luminal surface is a promising strategy to increase their hemocompatibility. In this review, we provide a collection of research studies and review articles aiming to summarize the recent efforts on surface modifications of CV implants, including stents, grafts, valves, and ventricular assist devises. We focus in particular on the implementation of micrometer or nanoscale surface modifications, physical characteristics of known biomaterials (such as wetness and stiffness), and surface morphological features (such as gratings, fibers, pores, and pits). We also review how biomechanical signals originating from the endothelial cell for surface interaction can be directed by topography engineering approaches toward the survival of the endothelium and its long-term adaptation. Finally, we summarize the regulatory and economic challenges that may prevent clinical implementation of endothelialized CV implants.