Outcomes of Redo Transcatheter Aortic Valve Replacement According to the Initial and Subsequent Valve Type.

BACKGROUND: As transcatheter aortic valve (TAV) replacement is increasingly used in patients with longer life expectancy, a sizable proportion will require redo TAV replacement (TAVR). The unique configuration of balloon-expandable TAV (bTAV) vs a self-expanding TAV (sTAV) potentially affects TAV-in-TAV outcome. OBJECTIVES: The purpose of this study was to better inform prosthesis selection, TAV-in-TAV outcomes were assessed according to the type of initial and subsequent TAV. METHODS: Patients from the Redo-TAVR registry were analyzed using propensity weighting according to their initial valve type (bTAV [n = 115] vs sTAV [n = 106]) and subsequent valve type (bTAV [n = 130] vs sTAV [n = 91]). RESULTS: Patients with failed bTAVs presented later (vs sTAV) (4.9 ± 2.1 years vs 3.7 ± 2.3 years; P < 0.001), with smaller effective orifice area (1.0 ± 0.7 cm2 vs 1.3 ± 0.8 cm2; P = 0.018) and less frequent dominant regurgitation (16.2% vs 47.3%; P < 0.001). Mortality at 30 days was 2.3% (TAV-in-bTAV) vs 0% (TAV-in-sTAV) (P = 0.499) and 1.7% (bTAV-in-TAV) vs 1.0% (sTAV-in-TAV) (P = 0.612); procedural safety was 72.6% (TAV-in-bTAV) vs 71.2% (TAV-in-sTAV) (P = 0.817) and 73.2% (bTAV-in-TAV) vs 76.5% (sTAV-in-TAV) (P = 0.590). Device success was similar according to initial valve type but higher with subsequent sTAV vs bTAV (77.2% vs 64.3%; P = 0.045), primarily because of lower residual gradients (10.3 mm Hg [8.9-11.7 mm Hg] vs 15.2 mm Hg [13.2-17.1 mm Hg]; P < 0.001). Residual regurgitation (moderate or greater) was similar after bTAV-in-TAV and sTAV-in-TAV (5.7%) and nominally higher after TAV-in-bTAV (9.1%) vs TAV-in-sTAV (4.4%) (P = 0.176). CONCLUSIONS: In selected patients, no association was observed between TAV type and redo TAVR safety or mortality, yet subsequent sTAV was associated with higher device success because of lower redo gradients. These findings are preliminary, and more data are needed to guide valve choice for redo TAVR.

Leaflet Thickening and Motion After Transcatheter Aortic Valve Replacement: Design and Rationale of the Rotterdam Edoxaban Trial.

BACKGROUND: Multislice computed tomography (MSCT) may reveal hypo-attenuated leaflet thickening (HALT) and/or reduced leaflet motion (RELM) in approximately 15 % of patients after transcatheter aortic valve replacement (TAVR). These supposedly thrombogenic phenomena may be associated with neurological events and increased transprosthetic gradients. It is unclear whether oral anticoagulant therapy -specifically a factor Xa inhibitor- could affect the incidence of HALT/RELM. STUDY DESIGN: The Rotterdam EDOXaban (REDOX) trial is an investigator-initiated, single-center, prospective registry in which 100 patients with no formal indication for oral anticoagulant drugs or dual antiplatelet therapy, will receive a 3-month treatment with edoxaban, followed by a MSCT to detect HALT/RELM. The primary endpoint is the incidence of HALT at 3-months follow-up. Secondary endpoints include the incidence of RELM at 3 months; change in transprosthetic gradients at 1 year and the clinical composite endpoint of all-cause death, myocardial infarction (MI), ischemic stroke, systemic thromboembolism, valve thrombosis and major bleeding (International Society on Thrombosis and Hemostasis [ISTH] definition) at 1 year follow up. The study is powered to demonstrate with 90 % statistical power and a 0.025 alpha a 4 % incidence of HALT with edoxaban as compared to the expected 15 % rate with an antiplatelet regimen and will enroll 100 patients to account for loss of follow-up or CT-drop out. CONCLUSION: The REDOX trial will investigate the short-term effect of an Xa-inhibitor on the incidence of HALT after TAVR. (ClinicalTrials.gov Identifier: NCT04171726).

Left atrial appendage thrombus and cerebrovascular events post-transcatheter aortic valve implantation.

AIMS: To elucidate the frequency and clinical impact of left atrial appendage thrombus (LAAT) in patients set for transcatheter aortic valve implantation (TAVI). METHODS AND RESULTS: All patients undergoing TAVI between January 2014 and June 2020 with analysable multislice computed tomography (MSCT) for LAAT were included. Baseline and procedural characteristics were collected, pre-procedural MSCT's were retrospectively analysed for LAAT presence. The primary endpoint was defined as the cumulative incidence of any cerebrovascular event (stroke or transient ischaemic attack) within the first year after TAVI. A Cox proportional hazards model was used to identify predictors.A total of 1050 cases had analysable MSCT. Median age was 80 [interquartile range (IQR) 74-84], median Society of Thoracic Surgeons' Predicted Risk Of Mortality (STS-PROM) was 3.4% (IQR 2.3-5.5). Thirty-six percent were on oral anticoagulant therapy for atrial fibrillation (AF). LAAT was present in 48 (4.6%) of cases. Patients with LAAT were at higher operative risk [STS-PROM: 4.9% (2.9-7.1) vs. 3.4% (2.3-5.5), P = 0.01], had worse systolic left ventricular function [EF 52% (35-60) vs. 55% (45-65), P = 0.01] and more permanent pacemakers at baseline (35% vs. 10%, P < 0.01). All patients with LAAT had a history of AF and patients with LAAT were more often on vitamin K antagonist-treatment than patients without LAAT [43/47 (91%) vs. 232/329 (71%), P < 0.01]. LAAT [hazard ratio (HR) 2.94 (1.39-6.22), P < 0.01] and the implantation of more than one valve [HR 4.52 (1.79-11.25), P < 0.01] were independent predictors for cerebrovascular events. CONCLUSION: Patients with MSCT-identified LAAT were at higher risk for cerebrovascular events during the first year after TAVI.

Insights in a restricted temporary pacemaker strategy in a lean transcatheter aortic valve implantation program.

OBJECTIVES: To study the safety and feasibility of a restrictive temporary-RV-pacemaker use and to evaluate the need for temporary pacemaker insertion for failed left ventricular (LV) pacing ability (no ventricular capture) or occurrence of high-degree AV-blocks mandating continuous pacing. BACKGROUND: Ventricular pacing remains an essential part of contemporary transcatheter aortic valve implantation (TAVI). A temporary-right-ventricle (RV)-pacemaker lead is the standard approach for transient pacing during TAVI but requires central venous access. METHODS: An observational registry including 672 patients who underwent TAVI between June 2018 and December 2020. Patients received pacing on the wire when necessary, unless there was a high-anticipated risk for conduction disturbances post-TAVI, based on the baseline-ECG. The follow-up period was 30 days. RESULTS: A temporary-RV-pacemaker lead (RVP-cohort) was inserted in 45 patients, pacing on the wire (LVP-cohort) in 488 patients, and no pacing (NoP-cohort) in 139 patients. A bailout temporary pacemaker was implanted in 14 patients (10.1%) in the NoP-cohort and in 24 patients (4.9%) in the LVP-cohort. One patient in the LVP-cohort needed an RV-pacemaker for incomplete ventricular capture. Procedure time was significantly longer in the RVP-cohort (68 min [IQR 52-88.] vs. 55 min [IQR 44-72] in NoP-cohort and 55 min [IQR 43-71] in the LVP-cohort [p < 0.005]). Procedural high-degree AV-block occurred most often in the RVP-cohort (45% vs. 14% in the LVP and 16% in the NoP-cohort [p ≤ 0.001]). Need for new PPI occurred in 47% in the RVP-cohort, versus 20% in the NoP-cohort and 11% in the LVP-cohort (p ≤ 0.001). CONCLUSION: A restricted RV-pacemaker strategy is safe and shortens procedure time. The majority of TAVI-procedures do not require a temporary-RV-pacemaker.

Multidimensional Prognostic Index and Outcomes in Older Patients Undergoing Transcatheter Aortic Valve Implantation: Survival of the Fittest.

Selecting patients with a high chance of endured benefit from transcatheter aortic valve implantation (TAVI) is becoming relevant with changing indications and increasing number of TAVI being performed. The aim of our study was to investigate the association of the multidimensional prognostic index (MPI) based on a comprehensive geriatric assessment (CGA) on survival. The TAVI Care & Cure program is a prospective, observational registry of patients referred for TAVI at the Erasmus MC University Medical Center. Consecutive patients who underwent a complete CGA and TAVI were included. CGA components were used to calculate the MPI score. The impact of the MPI score on survival was evaluated using Cox regression. Furthermore, 376 patients were included, 143 (38.0%) patients belonged to the MPI-1 group and 233 (61.9%) patients to the MPI-2-3 group. After 3 years, 14.9% of the patients in the MPI-1 group and 30.5% of the patients in the MPI-2-3 group died (p = 0.001). Patients in MPI-1 had increased chances of overall survival in comparison with patients in MPI group 2-3 Hazard Ratio (HR) 0.57, (95% Confidence Interval (CI) 0.33-0.98)). In this study we found that the MPI tool could be useful to assess frailty and to predict which patient will have a higher chance of enduring benefit from a TAVI procedure.

Incidence, Causes, and Outcomes Associated With Urgent Implantation of a Supplementary Valve During Transcatheter Aortic Valve Replacement.

Importance: Transcatheter aortic valve replacement (TAVR) failure is often managed by an urgent implantation of a supplementary valve during the procedure (2-valve TAVR [2V-TAVR]). Little is known about the factors associated with or sequelae of 2V-TAVR. Objective: To examine the incidence, causes, and outcomes of 2V-TAVR. Design, Setting, and Participants: A retrospective cohort study was performed using data from an international registry of 21 298 TAVR procedures performed from January 1, 2014, through February 28, 2019. Among the 21 298 patients undergoing TAVR, 223 patients (1.0%) undergoing 2V-TAVR were identified. Patient-level data were available for all the patients undergoing 2V-TAVR and for 12 052 patients (56.6%) undergoing 1V-TAVR. After excluding patients with missing 30-day follow-up or data inconsistencies, 213 2V-TAVR and 10 010 1V-TAVR patients were studied. The 2V-TAVR patients were compared against control TAVR patients undergoing a 1-valve TAVR (1V-TAVR) using 1:4 17 propensity score matching. Final analysis included 1065 (213:852) patients. Exposures: Urgent implantation of a supplementary valve during TAVR. Main Outcomes and Measures: Mortality at 30 days and 1 year. Results: The 213 patients undergoing 2V-TAVR had similar age (mean [SD], 81.3 [0.5] years) and sex (110 [51.6%] female) as the 10 010 patients undergoing 1V-TAVR (mean [SD] age, 81.2 [0.5] years; 110 [51.6%] female). The 2V-TAVR incidence decreased from 2.9% in 2014 to 1.0% in 2018 and was similar between repositionable and nonrepositionable valves. Bicuspid aortic valve (odds ratio [OR], 2.20; 95% CI, 1.17-4.15; P = .02), aortic regurgitation of moderate or greater severity (OR, 2.02; 95% CI, 1.49-2.73; P < .001), atrial fibrillation (OR, 1.43; 95% CI, 1.07-1.93; P = .02), alternative access (OR, 2.59; 95% CI, 1.72-3.89; P < .001), early-generation valve (OR, 2.32; 95% CI, 1.69-3.19; P < .001), and self-expandable valve (OR, 1.69; 95% CI, 1.17-2.43; P = .004) were associated with higher 2V-TAVR risk. In 165 patients (80%), the supplementary valve was implanted because of residual aortic regurgitation after primary valve malposition (94 [46.4%] too high and 71 [34.2%] too low). In the matched 2V-TAVR vs 1V-TAVR cohorts, the rate of device success was 147 (70.4%) vs 783 (92.2%) (P < .001), the rate of coronary obstruction was 5 (2.3%) vs 3 (0.4%) (P = .10), stroke rate was 9 (4.6%) vs 13 (1.6%) (P = .09), major bleeding rates were 25 (11.8%) vs 46 (5.5%) (P = .03) and annular rupture rate was 7 (3.3%) vs 3 (0.4%) (P = .03). The hazard ratios for mortality were 2.58 (95% CI, 1.04-6.45; P = .04) at 30 days, 1.45 (95% CI, 0.84-2.51; P = .18) at 1 year, and 1.20 (95% CI, 0.77-1.88; P = .42) at 2 years. Nontransfemoral access and certain periprocedural complications were independently associated with higher risk of death 1 year after 2V-TAVR. Conclusions and Relevance: In this cohort study, valve malposition was the most common indication for 2V-TAVR. Incidence decreased over time and was low overall, although patients with a bicuspid or regurgitant aortic valve, nontransfemoral access, and early-generation or self-expandable valve were at higher risk. These findings suggest that compared with 1V-TAVR, 2V-TAVR is associated with high burden of complications and mortality at 30 days but not at 1 year.

Impact of Interventricular membranous septum length on pacemaker need with different Transcatheter aortic valve implantation systems.

Background The need for new permanent pacemaker implantation (PPI) after Transcatheter Aortic Valve Implantation (TAVI) remains a critical issue. Membranous Septum (MS) length is associated with PPI after TAVI. The aim of this study was to identify different MS thresholds for the contemporary THV-platforms. Methods This retrospective, case-control study enrolled all patients who underwent a successful TAVI procedure with contemporary THV-platforms in the Erasmus University Medical Center between January 2016 and March 2020. The follow-up period for new PPI was 30 days. MS-length was determined by Computed Tomography. Results The study consisted 653 TAVI patients with median age 80.6 years (IQR 74.7-84.8). New PPI occurred in 120 patients (18.4%). Patients with new PPI had a shorter MS-length (2.9 mm (IQR 2.3-4.3) vs. 4.2 mm (IQR 2.9-5.7), p < 0.001). MS-length < 3 mm identified a high-risk phenotype with 30.3% PPI-rate (OR 6.5 [95%CI 2.9-14.9]), MS-length 3-6 mm an intermediate-risk phenotype with 15.4% PPI-rate (OR 2.7 [95%CI 1.2-6.2]) and MS > 6 mm a low-risk phenotype with a 6.3% PPI-rate (reference). For the Lotus valve, there was no significant difference in PPI-rates between the high-risk (45.8%, OR 3.5 [95%CI 0.8-15.1]) and low-risk group (20%). By multivariate analysis MS-length, Agatston-score, use of Lotus valve, and ECG with first-degree AV block, RBBB or bifascular block were independent predictors for new PPI. Conclusion MS-length was an independent predictor for new PPI post-TAVI. Three phenotypes were found based on MS-length. MS < 3 mm was universally associated with a high risk for new PPI (>30%). MS > 6 mm represented a low-risk phenotype with PPI-rate < 10%. PPI-rate varied per THV type in the intermediate phenotype. PPI-rate with Lotus was high regardless of MS-length.

Vascular complications with a plug-based vascular closure device after transcatheter aortic valve replacement: Predictors and bail-outs.

BACKGROUND: The MANTA vascular closure device (VCD) is dedicated to large bore access closure and associated with favorable results in selected study populations. Anatomical predictors for access site complications are lacking. AIM: To evaluate MANTA in a real-world population and identify predictors for vascular complications. METHODS: All patients undergoing transfemoral transcatheter aortic valve replacement (TAVR) between January 2016 and May 2020 with MANTA closure were included. Baseline characteristics were collected, pre-procedural computed tomography and post-deployment femoral angiograms were analyzed for anatomical differences. The primary endpoint was a composite of access site related major and minor vascular complications at 30 days follow-up according to the VARC-2 definitions. Secondary endpoints included bleeding, time to hemostasis, procedural length and incomplete arteriotomy closure or arterial occlusion by angiography. A Cox proportional hazards model was used to compare all-cause mortality for patients with and without an access site complication. RESULTS: The 512 patients underwent TAVR with MANTA access closure. Median age was 80 (IQR 75-85), 53% was male, median BMI was 26.4 kg/m2 (IQR 23.4-29.7). Access site related major- or minor vascular complication occurred in 20 (4%) and 23 (4%) of patients respectively. Median time to hemostasis was 42 s (IQR 28-98). Post deployment angiogram showed an occlusion in 24 patients (5%), incomplete closure in 60 patients (12%) or both in three patients (1%). Of these 87 patients, 36 (41%) had a vascular complication. Femoral artery diameter (OR 0.70 [0.53-0.93]), low- (OR 3.47 [1.21-10.00]) and high (OR 2.43 [1.16-5.10]) arteriotomies were independent predictors for vascular complications. CONCLUSION: In this contemporary TAVR population, access-site related complications occurred in 8% of patients and were mainly due to percutaneous closure device failure. Small artery diameter and off-target punctures were independent predictors.

Transcatheter Replacement of Transcatheter Versus Surgically Implanted Aortic Valve Bioprostheses.

BACKGROUND: Surgical aortic valve replacement and transcatheter aortic valve replacement (TAVR) are now both used to treat aortic stenosis in patients in whom life expectancy may exceed valve durability. The choice of initial bioprosthesis should therefore consider the relative safety and efficacy of potential subsequent interventions. OBJECTIVES: The aim of this study was to compare TAVR in failed transcatheter aortic valves (TAVs) versus surgical aortic valves (SAVs). METHODS: Data were collected on 434 TAV-in-TAV and 624 TAV-in-SAV consecutive procedures performed at centers participating in the Redo-TAVR international registry. Propensity score matching was applied, and 330 matched (165:165) patients were analyzed. Principal endpoints were procedural success, procedural safety, and mortality at 30 days and 1 year. RESULTS: For TAV-in-TAV versus TAV-in-SAV, procedural success was observed in 120 (72.7%) versus 103 (62.4%) patients (p = 0.045), driven by a numerically lower frequency of residual high valve gradient (p = 0.095), ectopic valve deployment (p = 0.081), coronary obstruction (p = 0.091), and conversion to open heart surgery (p = 0.082). Procedural safety was achieved in 116 (70.3%) versus 119 (72.1%) patients (p = 0.715). Mortality at 30 days was 5 (3%) after TAV-in-TAV and 7 (4.4%) after TAV-in-SAV (p = 0.570). At 1 year, mortality was 12 (11.9%) and 10 (10.2%), respectively (p = 0.633). Aortic valve area was larger (1.55 ± 0.5 cm2 vs. 1.37 ± 0.5 cm2; p = 0.040), and the mean residual gradient was lower (12.6 ± 5.2 mm Hg vs. 14.9 ± 5.2 mm Hg; p = 0.011) after TAV-in-TAV. The rate of moderate or greater residual aortic regurgitation was similar, but mild aortic regurgitation was more frequent after TAV-in-TAV (p = 0.003). CONCLUSIONS: In propensity score-matched cohorts of TAV-in-TAV versus TAV-in-SAV patients, TAV-in-TAV was associated with higher procedural success and similar procedural safety or mortality.

Suture- or Plug-Based Large-Bore Arteriotomy Closure: A Pilot Randomized Controlled Trial.

OBJECTIVES: This study sought to test the superiority in terms of efficacy and safety of a dedicated plug-based vascular closure device (VCD) during transcatheter aortic valve replacement (TAVR) over a suture-based VCD. BACKGROUND: Vascular complications after TAVR are relevant and often associated with VCD failure. METHODS: The MASH (MANTA vs. Suture-based vascular closure after transcatHeter aortic valve replacement) trial is an international, 2-center pilot randomized controlled trial comparing the MANTA VCD (Teleflex, Wayne, Pennsylvania) versus 2 ProGlides (Abbott Vascular, Abbott Park, Illinois). The primary composite endpoint consisted of access site-related major or minor vascular complications at 30-days' follow-up. Secondary endpoints included clinically relevant access site bleeding, time to hemostasis, and modified VCD failure (defined as failure to achieve hemostasis within 5 min or requiring additional endovascular maneuvers such as endovascular stenting, surgical techniques, or additional closure devices). Adverse events were adjudicated by an independent clinical events committee according to the VARC-2 definitions. RESULTS: A total of 210 TAVR patients were included between October 2018 and January 2020. Median age was 81 years, 54% were male, and the median STS score was 2.7%. There was no significant difference in the primary endpoint of access site-related vascular complications between MANTA and ProGlide (10% vs. 4%; p = 0.16). Clinically significant access site bleedings were similar with both closure techniques (9% vs. 6%; p = 0.57). Modified VCD failure occurred less frequently in MANTA versus ProGlide (20% vs. 40%; p < 0.01). Suture-based closure required more often additional closure devices, whereas MANTA numerically needed more covered stents and surgical bailouts. CONCLUSIONS: Plug-based large-bore arteriotomy closure was not superior to suture-based closure. Plug-based closure required fewer, but a different kind of bailout maneuvers.

Simplified Trans-Axillary Aortic Valve Replacement Under Local Anesthesia - A Single-Center Early Experience.

BACKGROUND: The axillary artery is an alternative route for patients with comorbidities and unfavorable femoral arteries who need transcatheter aortic valve replacement (TAVR). Simplified trans-axillary transcatheter aortic valve replacement (TAx-TAVR) implies a completely percutaneous approach under local anesthesia and arteriotomy closure with vascular closure techniques. Herein, we report on early experience with simplified TAx-TAVR under local anesthesia. METHODS: We enrolled all consecutive patients who underwent simplified TAx-TAVR in our center. Main study parameter was the incidence of axillary access related major vascular complications within 30 days. Secondary parameters included a composite early safety endpoint, axillary access-site related vascular/bleeding complications and short-term mortality. Post TAVR axillary stent patency was evaluated during follow-up by CT-analysis. RESULTS: Between July 2018 and April 2020, Tax-TAVR was attempted in 35 patients with a mean age of 79 years. Local anesthesia and conscious sedation were used in 91.4% (n = 32) and 8.6% (n = 3) respectively. A covered stent was needed for complete axillary hemostasis in 44.1% (n = 15). Device success was achieved in 91.2% (n = 31/34). The 30-day axillary artery major vascular and ≥major bleeding complication rates were 14% (n = 5) and 11% (n = 4). The early safety endpoint was reached in 22.9% (n = 8). Mortality rates at 30 days and six months were 2.9% and 11.6%. Computed tomography (CT) confirmed axillary stent patency during follow-up in 82% (n = 9/11). CONCLUSIONS: In patients with high/prohibitive surgical risk and unsuitable femoral access, simplified TAx-TAVR under local anesthesia offers a valuable alternative for transfemoral TAVR but requires advanced access site management techniques including covered stents. Our data suggest an unmet clinical need for dedicated TAx closure devices.

HAS-BLED score and actual bleeding in elderly patients undergoing transcatheter aortic valve implantation.

BACKGROUND: The optimal antithrombotic therapy after transcatheter aortic valve implantation (TAVI) is unsettled. Short and longer-term thromboembolic and bleeding risk post TAVI remain high. Non-vitamin K oral anticoagulant drugs (NOAC) may be attractive after TAVI but the implications of prolonged NOAC in this setting require further research. The aim of this study was to assess the HAS-BLED bleeding risk in a contemporary TAVI population and explore its correlation with the effective bleeding complications with or without (N)OAC. METHODS: This study included 986 consecutive successful TAVI patients from 2 tertiary care facilities. Statistical analysis consisted of Cox regression. Bleedings were classified according to VARC-2 criteria. RESULTS: Mean age was 80.5 years, mean STS was 4.7 and 54% were males. A total of 483 patients (49.2%) had AF and 42.1% were on (N)OAC. The median HAS-BLED score was 2, 42.6% had a HAS-BLED≥3. Overall 216 patients (21.9%) experienced at least 1 bleeding, 166 (16.9%) occurred early after TAVI. HAS-BLED≥3 was an independent predictor of overall and pre-discharge bleeding (respectively HR 1.347 CI 1.029-1.763, P=0.03: HR 1.403 CI 1.032-1.905, P=0.05). The incidence of bleeding was similar in patient on (N)OAC vs. patients not on (N)OAC, both in the low and high HAS-BLED cohorts (P=0.93, P=0.42 respectively). Cardiovascular mortality was significantly higher in the high HAS-BLED cohort (37.5% vs. 24%, P=0.04) and HAS-BLED≥3 was an independent predictor of late mortality (HR 1.452 CI 1.028-2.053, P=0.03). CONCLUSIONS: In our series, contemporary TAVI patients had an elevated HAS-BLED score. The HAS-BLED score correlated with early bleedings and mortality after TAVI. Use of (N)OAC was not associated with more bleedings after TAVI.

Impact of frailty on health-related quality of life 1 year after transcatheter aortic valve implantation.

BACKGROUND: Transcatheter aortic valve implantation (TAVI) brings symptom relief and improvement in health-related quality of life (HRQoL) in the majority of patients treated for symptomatic, severe aortic stenosis. However, there is a substantial group of patients that do not benefit from TAVI. The aim of this study is to investigate the impact of frailty on HRQoL 1 year after TAVI. METHODS: The TAVI Care & Cure Program is an ongoing, prospective, observational study including patients referred for TAVI to our institution. A comprehensive geriatric assessment was performed to evaluate existence of frailty using the Erasmus Frailty Score (EFS). HRQoL was assessed using the EQ-5D-5 L at baseline and 1 year after TAVI. RESULTS: 239 patients underwent TAVI and completed HRQoL assessment 1 year after TAVI. Seventy (29.3%) patients were classified as frail (EFS ≥ 3). In non-frail patients, the EQ-5D-5 L index did not change (0.71(± 0.22) to 0.68(± 0.33) points, P = 0.22); in frail patients, the EQ-5D-5 L index decreased from 0.55(±0.26) to 0.44 points (±0.33) (P = 0.022). Frailty was an independent predictor of deteriorated HRQoL 1 year after TAVI (OR 2.24, 95% CI 1.07-4.70, P = 0.003). In frail patients, the absence of peripheral artery disease (OR 0.17, 95% 0.05-0.50, P = 0.001) and renal dysfunction (OR 0.13, 95% CI 0.04-0.41, P = <0.001) at baseline was associated with improved HRQoL 1 year after TAVI. CONCLUSION: Frailty is associated with deterioration of HRQoL 1 year after TAVI. Notably, HRQoL did improve in frail patients with no peripheral arterial disease or renal impairment at baseline.

Repeat Transcatheter Aortic Valve Replacement for Transcatheter Prosthesis Dysfunction.

BACKGROUND: Transcatheter aortic valve replacement (TAVR) use is increasing in patients with longer life expectancy, yet robust data on the durability of transcatheter heart valves (THVs) are limited. Redo-TAVR may play a key strategy in treating patients in whom THVs fail. OBJECTIVES: The authors sought to examine outcomes following redo-TAVR. METHODS: The Redo-TAVR registry collected data on consecutive patients who underwent redo-TAVR at 37 centers. Patients were classified as probable TAVR failure or probable THV failure if they presented within or beyond 1 year of their index TAVR, respectively. RESULTS: Among 63,876 TAVR procedures, 212 consecutive redo-TAVR procedures were identified (0.33%): 74 within and 138 beyond 1 year of the initial procedure. For these 2 groups, TAVR-to-redo-TAVR time was 68 (38 to 154) days and 5 (3 to 6) years. The indication for redo-TAVR was THV stenosis in 12 (16.2%) and 51 (37.0%) (p = 0.002) and regurgitation or combined stenosis-regurgitation in 62 (83.8%) and 86 (62.3%) (p = 0.028), respectively. Device success using VARC-2 criteria was achieved in 180 patients (85.1%); most failures were attributable to high residual gradients (14.1%) or regurgitation (8.9%). At 30-day and 1-year follow-up, residual gradients were 12.6 ± 7.5 mm Hg and 12.9 ± 9.0 mm Hg; valve area 1.63 ± 0.61 cm2 and 1.51 ± 0.57 cm2; and regurgitation ≤mild in 91% and 91%, respectively. Peri-procedural complication rates were low (3 stroke [1.4%], 7 valve malposition [3.3%], 2 coronary obstruction [0.9%], 20 new permanent pacemaker [9.6%], no mortality), and symptomatic improvement was substantial. Survival at 30 days was 94.6% and 98.5% (p = 0.101) and 83.6% and 88.3% (p = 0.335) at 1 year for patients presenting with early and late valve dysfunction, respectively. CONCLUSIONS: Redo-TAVR is a relatively safe and effective option for selected patients with valve dysfunction after TAVR. These results are important for applicability of TAVR in patients with long life expectancy in whom THV durability may be a concern.

PulseCath iVAC2L: next-generation pulsatile mechanical circulatory support.

Contemporary state of the art percutaneous coronary intervention techniques offer treatment strategies and solutions to an increasing number of patients with heart failure and complex coronary artery disease. Percutaneous mechanical circulatory support is intended to alleviate the mechanical and energetic workload imposed to a failing ventricle by reducing left ventricle pressures and volumes and potentially also increasing coronary blood flow. The PulseCath iVAC2L is a transaortic left ventricular assist device that applies a pneumatic driving system to produce pulsatile forward flow. Herein, the essential aspects regarding iVAC2L are discussed with focus on its mechanisms of action and the available clinical experience.

Impact of Valvulo-Arterial Impedance on Long-Term Quality of Life and Exercise Performance After Transcatheter Aortic Valve Replacement.

BACKGROUND: In aortic stenosis, valvulo-arterial impedance (Zva) estimates the overall left ventricular afterload (valve and arterial component). We investigated the association of Zva (≥5 versus <5 mm Hg mL-1 m-2) on quality of life (QOL) and exercise performance (EP) ≥1 year after transcatheter aortic valve replacement (TAVR). METHODS: The study population consists of 250 TAVR patients in whom baseline Zva and follow-up QOL was prospectively assessed using EuroQOL-5-dimensions instruments; EP was assessed in 192 patients who survived ≥1 year after TAVR using questionnaires related to daily activities. In 124 patients, Zva at 1-year was also available and was used to study the change in Zva (baseline to 1 year) on QOL/EP. RESULTS: Elevated baseline Zva was present in 125 patients (50%). At a median of 28 (IQR, 17-40) months, patients with elevated baseline Zva were more limited in mobility (88% versus 71%; P=0.004), self-care (40% versus 25%; P=0.019), and independent daily activities (taking a shower: 53% versus 38%, P=0.030; walking 100 meter: 76% versus 54%, P=0.001; and walking stairs: 74% versus 54%, P=0.011). By multivariable analysis, elevated Zva predicted unfavorable QOL (lower EuroQOL-5-dimensions-Utility Index, odds ratio, 1.98; CI, 1.15-3.41) and unfavorable EP (any limitation in ≥3 daily activities, odds ratio, 2.55; CI, 1.41-4.62). After TAVR, the proportion of patients with elevated Zva fell from 50% to 21% and remained 21% at 1 year and was found to be associated with more limitations in mobility, self-care, and daily activities compared with patients with Zva <5 mm Hg mL-1 m-2. CONCLUSIONS: Elevated Zva was seen in half of patients and predicted unfavorable long-term QOL and EP. At 1 year after TAVR, the prevalence of elevated Zva was 21% but remained associated with poor QOL/EP.

Large-bore Vascular Closure: New Devices and Techniques.

Endovascular aneurysm repair, transcatheter aortic valve implantation and percutaneous mechanical circulatory support systems have become valuable alternatives to conventional surgery and even preferred strategies for a wide array of clinical entities. Their adoption in everyday practice is growing. These procedures require large-bore access into the femoral artery. Their use is thus associated with clinically significant vascular bleeding complications. Meticulous access site management is crucial for safe implementation of large-bore technologies and includes accurate puncture technique and reliable percutaneous closure devices. This article reviews different strategies for obtaining femoral access and contemporary percutaneous closure technologies.

Maturation from CoreValve® to Evolut Pro®: a clinical overview.

The only curative treatment of aortic stenosis is through surgical or transcatheter aortic valve replacement. Transcatheter aortic valve implantation has evolved from its first in human experience in 2002 and matured to the treatment of first choice of symptomatic severe aortic stenosis in elderly patients with an elevated operative risk. The self-expanding CoreValve® bioprosthesis has been on the forefront of this growing transcatheter aortic valve implantation experience. Over the last decade, various device iterations resulted in the current Evolut PRO® self-expanding valve platform with reduced profile, repositioning/retrievable features and porcine pericardial wrap. Herein we provide a critical appraisal of the consecutive device iterations and highlight the clinical foundation for the use of the self-expanding CoreValve® /Evolut platforms in current clinical practice.

Clinical symptoms of right ventricular failure in experimental chronic pressure load are associated with progressive diastolic dysfunction.

BACKGROUND: Right ventricular failure (RVF) due to pressure load is a major cause of death in congenital heart diseases and pulmonary hypertension. The mechanisms of RVF are unknown. We used an experimental approach based upon clinical signs of RVF to delineate functional and biological processes associated with RVF. METHODS AND RESULTS: Wistar rats were subjected to a pulmonary artery banding (PAB n=12) or sham surgery (CON, n=7). After 52±5days, 5/12 PAB rats developed clinical symptoms of RVF (inactivity, ruffled fur, dyspnea, ascites) necessitating termination (PAB+CF). We compared these to PAB rats with RVF without clinical symptoms (PAB-). PAB resulted in reduced cardiac output, RV stroke volume, TAPSE, and increased end diastolic pressure (all p<0.05 vs. CON) in all rats, but PAB+CF rats were significantly more affected than PAB-, despite similar pressure load (p=ns). Pressure-volume analysis showed enhanced contractility (end systolic elastance) in PAB- and PAB+CF, but diastolic function (end diastolic elastance, end diastolic pressure) deteriorated especially in PAB+CF. In PAB+CF capillary density was lower than in PAB-. Gene-array analysis revealed downregulation of both fatty acid oxidation and carbohydrate metabolism in PAB+CF. CONCLUSION: Chronic PAB led to different degrees of RVF, with half of the rats developing severe clinical symptoms of RVF, associated with progressive deterioration of diastolic function, hypoxia-prone myocardium, increased response to oxidative stress and suppressed myocardial metabolism. This model represents clinical RVF and allows for unraveling of mechanisms involved in the progression from RV adaptation to RV failure and the effect of intervention on these mechanisms.