Transcatheter mitral valve in ring, hazards of long anterior mitral leaflet and 3-dimensional rings.

OBJECTIVES: The purpose of this study was to define anterior mitral leaflet (AML) length and mitral ring characteristics associated with LVOT obstruction and PVL following MViR. BACKGROUND: Transcatheter Mitral Valve in Ring (MViR) procedural complications including parvalvular leak (PVL) and left ventricular outflow tract (LVOT) obstruction are frequent. METHODS: Clinical records, computer tomographic scans (CTs) and echocardiograms of consecutive MViR patients were retrospectively reviewed for anterior mitral leaflet length, CT-simulated neoLVOT, and aortomitral angle among patients with and without MViR-induced LVOT obstruction. Acute and 1-year outcomes are described. RESULTS: Twenty-two patients underwent MViR. Technical success was achieved in 13/22 (57.1%) patients, limited by paravalvular regurgitation requiring second transcatheter heart valves (THVs) in seven patients. Second valves were needed in 6/11 (54.5%) patients with 3-dimensional rings but 1/11 (9.1%, p = .06) of patients with planar rings. Procedure success at 30 days was achieved in 20/22 (90.9%) patients. There were no procedural, in-hospital, or 30-day deaths. Two patients developed significant LVOT obstruction, one managed with urgent surgery and one with elective alcohol septal ablation. Anterior mitral leaflets were longer among the two patients with LVOT obstruction than the 20 patients who did not develop LVOT obstruction when measured by TEE (30 mm vs. 21 mm, p = .009) or by CT (29 mm vs. 22 mm, p = .026). CONCLUSIONS: AML >25 mm increases the risk of MViR induced LVOT obstruction. PVL is common, particularly in 3-dimensional rings which can be managed with a second THV.

Transcatheter Aortic Valve-in-Valve Replacement for Degenerated Stentless Bioprosthetic Aortic Valves: Results of a Multicenter Retrospective Analysis.

OBJECTIVES: The purpose of this study was to evaluate the safety and efficacy of valve-in-valve (ViV) transcatheter aortic valve replacement (TAVR) for stentless bioprosthetic aortic valves (SBAVs) and to identify predictors of adverse events. BACKGROUND: ViV TAVR in SBAVs is associated with unique technical challenges and risks. METHODS: Clinical records and computer tomographic scans were retrospectively reviewed for procedural complications, predictors of coronary obstruction, mortality, and echocardiographic results. RESULTS: Among 66 SBAV patients undergoing ViV TAVR, mortality was 2 of 66 patients (3.0%) at 30 days and 5 of 52 patients (9.6%) at 1 year. At 1 year, left ventricular end-systolic dimension was decreased versus baseline (median [interquartile range (IQR)]: 3.0 [2.6 to 3.6] cm vs. 3.7 [3.2 to 4.4] cm; p < 0.001). Coronary occlusion in 6 of 66 procedures (9.1%) resulted in myocardial infarction in 2 of 66 procedures (3.0%). Predictors of coronary occlusion included subcoronary implant technique compared with full root replacement (6 of 31, 19.4% vs. 0 of 28, 0%; p = 0.01), short simulated radial valve-to-coronary distance (median [IQR]: 3.4 [0.0 to 4.6] mm vs. 4.6 [3.2 to 6.2] mm; p = 0.016), and low coronary height (7.8 [5.8 to 10.0] mm vs. 11.6 [8.7 to 13.9] mm; p = 0.003). Coronary arteries originated <10 mm above the valve leaflets in 34 of 97 unobstructed coronary arteries (35.1%). CONCLUSIONS: TAVR in SBAVs is frequently associated with high-risk coronary anatomy but can be performed with a low risk of death and myocardial infarction, resulting in favorable ventricular remodeling. A subcoronary surgical approach is associated with an increased risk of coronary obstruction.

A look between the cardiomyocytes: the extracellular matrix in heart failure.

The extracellular matrix (ECM) of the heart dynamically interacts with various cellular components of the myocardium, including the myocytes and connective tissue cells. With the development and progression of heart failure, left ventricular (LV) myocardial remodeling occurs. The progression of LV remodeling is accompanied by alterations in the structure and function of the ECM that occur after injury resulting from neurohormonal activation, changes in LV loading conditions, and alterations in myocardial perfusion and metabolism and is secondary to a host of nonmyocyte signaling pathways that affect repair and remodeling of the myocardium as a whole. This article attempts to review some of these processes and their interactions and to provide a focus to the often overlooked contribution of the ECM to the development and progression of heart failure and thereby its potential role as a target for therapy for heart failure.