CLINICAL RESEARCH

DOI: 10.4244/EIJ-D-17-00546

Matched comparison of next- and early-generation balloon-expandable transcatheter heart valve implantations in failed surgical aortic bioprostheses

Moritz Seiffert1, MD; Hendrik Treede2, MD; Joachim Schofer3, MD; Axel Linke4, MD; Jochen Wöhrle5, MD; Hardy Baumbach6, MD; Julinda Mehilli7, MD; Vinayak Bapat8, MD; Matheus Simonato9; Thomas Walther10, MD; Mathias Kullmer11, MD; Peter Boekstegers12, MD; Stephan Ensminger13, MD; Thomas Kurz14, MD; Helene Eltchaninoff15, MD; Ardawan Rastan16, MD; Nicolas Werner17, MD; Arend de Weger18, MD; Christian Frerker19, MD; Bernward Lauer

Abstract

Aims: Transcatheter valve-in-valve implantation (VinV) is established for the treatment of degenerated surgical bioprostheses in patients at high operative risk. Our aim was to report on the first large assessment of VinV with next-generation balloon-expandable transcatheter heart valves.

Methods and results: After SAPIEN XT or SAPIEN 3 VinV, 514 patients were analysed using an inverse probability of treatment weighting. Standardised clinical and haemodynamic outcomes were compared, and core laboratory evaluation of implantation depth was performed. Thirty-day all-cause mortality was 0.6% and 3.5% for SAPIEN 3 and SAPIEN XT (p=0.077). Residual transprosthetic gradient ≥20 mmHg was observed in 38.3% (SAPIEN 3) and 35.7% (SAPIEN XT) of patients (p=0.627) with increased rates in small bioprostheses (≤21 mm true ID). In SAPIEN 3 VinV, low implantation depth >20% THV stent frame length was associated with a higher rate of elevated transaortic gradients (p=0.048). Similarly, an implantation depth >5 mm was linked to more pacemaker implantations (p=0.01). Overall, a trend towards higher pacemaker implantation rates was observed after SAPIEN 3 VinV (6% vs. 2.5% in SAPIEN XT, p=0.071).

Conclusions: Transcatheter aortic VinV with the balloon-expandable SAPIEN XT or SAPIEN 3 was similarly safe and effective. However, residual stenosis remains a concern, particularly in smaller bioprostheses and with increasing implantation depth.

Abbreviations

CI: confidence interval

iEOA: indexed effective orifice area

IPT: inverse probability of treatment

ROC: receiver operating characteristic

STS-PROM: Society of Thoracic Surgeons predicted risk of mortality score

TAVI: transcatheter aortic valve implantation

THV: transcatheter heart valves

VARC-2: Valve Academic Research Consortium-2

VinV: valve-in-valve

VIVID: Valve-in-Valve International Data

Introduction

Valve-in-valve (VinV) implantation of transcatheter heart valves (THV) has become an established therapy for the treatment of degenerated surgical bioprostheses in patients at high operative risk. With the increasing selection of bioprostheses over mechanical valves in younger patients undergoing surgical valve replacement1, a large number of patients is expected to require redo valve procedures to treat structural valve degeneration within the next decade. Broad experience has been gained with the CoreValve® (Medtronic, Minneapolis, MN, USA) and SAPIEN XT (Edwards Lifesciences, Irvine, CA, USA) platforms in VinV procedures2. Limitations of the procedure include a need for precise positioning, the risk of coronary obstruction and – foremost – residual stenosis. Elevated post-procedural gradients and prosthesis-patient mismatch are commonly observed after VinV procedures, especially in procedures performed utilising balloon-expandable devices in small surgical bioprostheses2,3.

The next-generation balloon-expandable SAPIEN 3 THV (Edwards Lifesciences) has demonstrated promising clinical outcomes in native aortic valve stenosis and is currently the most widely used THV device in transcatheter aortic valve implantation (TAVI) procedures worldwide. Prominent new features of this device include an outer polyethylene terephthalate cuff at the inflow portion of the THV that minimises paravalvular leakage and a longer stent frame profile that shortens significantly during balloon inflation. However, paravalvular leakage is rarely a concern in VinV procedures in comparison to conventional TAVI procedures2, while the longer device frame may result in lower implantation with part of the THV stent extending into the left ventricular outflow tract, resulting in conduction defects4. At present, the feasibility of using SAPIEN 3 for VinV therapy is limited to case reports and small case series.

The objective of this study was to evaluate the safety and efficacy of the newest-generation balloon-expandable THV, the SAPIEN 3, for VinV treatment of degenerated aortic surgical bioprostheses in comparison to the earlier-generation SAPIEN XT.

Methods

REGISTRY DESIGN

The Valve-in-Valve International Data (VIVID) registry is an ongoing investigator-initiated global registry of VinV procedures including different THV devices and valve positions2. Contribution of anonymised patient data to the VIVID registry was performed according to local ethics committee requirements. Data inconsistencies were resolved with local investigators.

PATIENT SELECTION

Only cases performed in the aortic position and using the balloon-expandable SAPIEN 3 and SAPIEN XT devices are included. We estimate propensity score inverse probability of treatment (IPT) weights to adjust for baseline characteristics between SAPIEN 3 and SAPIEN XT patients (Supplementary Appendix for statistical analysis and inverse probability of treatment weighting process).

DEFINITIONS

Patients’ risk of operative mortality was calculated using the Society of Thoracic Surgeons predicted risk of mortality score (STS-PROM) (http://riskcalc.sts.org/stswebriskcalc/). The mechanism of prosthetic valve failure was evaluated according to echocardiographic guidelines and defined as regurgitation, stenosis or mixed5. Body surface area was calculated according to the Mosteller formula and included in the calculation of the indexed effective orifice area (iEOA). True internal diameter bioprostheses specifications were retrieved from the valve-in-valve application version 2.06. Standardised clinical and haemodynamic outcomes were defined according to the updated Valve Academic Research Consortium definitions (VARC-2)7 and compared between SAPIEN 3 and SAPIEN XT groups. Early post-implantation haemodynamic data were obtained from intraprocedural or early post-procedural echocardiograms.

IMPLANTATION DEPTH ANALYSIS

Implantation depth was assessed by an experienced operator blinded to clinical results in a central core laboratory (St. Paul’s Hospital, Vancouver, Canada), as previously described8. Briefly, fluoroscopic images were obtained from all centres. Images of 90 procedures (57.7% of SAPIEN 3 cases) with sufficient resolution, perpendicularity of THV and adequate radiopaque markers of the surgical prostheses were analysed. For each SAPIEN 3, one vertical line was traced on each side of the device. The values were added, and their average was considered the height of the device. Another line was traced at each side of the THV starting from the bottom of the surgical valve ring to the bottom of the THV. The values were added, and their average was considered the depth numeric value. The depth numeric value was divided by the height of the device frame, thus obtaining the relative depth. An absolute depth value was estimated by multiplying the relative depth value by the height of a nominally expanded SAPIEN 3 device (15.5 mm for the 20 mm THV, 18 mm for the 23 mm THV, 20 mm for the 26 mm THV, and 22.5 mm for the 29 mm THV).

Receiver operating characteristic (ROC) analysis was used to determine the appropriate depth of implantation cut-off for pacemaker risk and elevated mean gradient (≥30 mmHg). AUC values were 0.63 for optimal implant depth (standard error 0.086; 95% confidence interval [CI]: 0.465-0.801; p=0.22) and 0.77 for decreased pacemaker rate (standard error 0.103; 95% CI: 0.564-0.969; p=0.01) in SAPIEN 3 cases.

Results

PATIENT CHARACTERISTICS

From a total of 541 aortic VinV procedures with balloon-expandable devices in the VIVID registry, 514 cases (95.0%) (144 SAPIEN 3 and 370 SAPIEN XT) had complete baseline characteristics used to fit the propensity score model. Patient demographics (Table 1) had negligible to small differences between SAPIEN 3 and SAPIEN XT patients before and after IPT weighting. Propensity scores had sufficient common support not to exclude any observations, ranging from 0.18 to 0.81 for SAPIEN XT with a median of 0.23 and from 0.058 to 0.52 for SAPIEN 3 with a median of 0.26 (Supplementary Figure 1). After IPT weighting, patients presented at a mean age of 76.2±7.1 (SAPIEN 3) and 76.9±14.1 (SAPIEN XT) years and at a median of 10 (CI: 7-13) years after initial surgical aortic valve replacement for the treatment of bioprosthesis degeneration. Degeneration mode was equally distributed among predominant stenosis, regurgitation or a combination of both. Surgical prostheses were stented in the majority of cases (Supplementary Table 1 for list of degenerated bioprostheses). No significant differences were observed with regard to label size or true internal diameters between groups.

PERIPROCEDURAL PARAMETERS

After IPT weighting, VinV procedures were performed via transfemoral access in 88.2% (SAPIEN 3) and 58.5% (SAPIEN XT, p<0.001) of cases (Table 2). General anaesthesia was employed in 52.5% (SAPIEN 3) and 75.0% (SAPIEN XT, p<0.001). Transoesophageal echocardiographic guidance was performed in 53.5% (SAPIEN 3) and 74.7% (SAPIEN XT, p<0.001) of procedures. Predilation of the degenerated bioprostheses was performed in 27.0% (SAPIEN 3) and 29.3% (SAPIEN XT, p=0.618) of cases. The 23 mm THV was the most commonly selected size for VinV implantation in both groups, being chosen in 67.8% (SAPIEN 3) and 60.2% (SAPIEN XT, p=0.395). Post-dilation (4.7% and 1.2%, p=0.033) and implantation of a second valve due to displacement or suboptimal function (3.2% and 0.4%, p=0.052) were rare for both groups but more common for SAPIEN XT procedures. Coronary obstruction occurred in no patient during implantation of a SAPIEN 3 and in eight patients of the SAPIEN XT group (Freestyle™ [Medtronic], Toronto® [St. Jude Medical, St. Paul, MN, USA], PERIMOUNT [Edwards Lifesciences]).

HAEMODYNAMIC RESULTS

Aortic regurgitation (>mild) was reduced from 44.3% at baseline to 2.1% of patients after VinV (SAPIEN 3, p<0.001) and from 48.8% to 5.2% (SAPIEN XT, p<0.001) (Table 2). Effective orifice areas improved 0.330 cm2/m2 (SAPIEN 3) and 0.223 cm2/m2 (SAPIEN XT) (p=0.007). Mean transvalvular gradients decreased 14.7 mmHg (SAPIEN 3) and 18.1 mmHg (SAPIEN XT). A residual transprosthetic gradient ≥20 mmHg was observed in 38.3% (SAPIEN 3) and 35.7% (SAPIEN XT) of patients (p=0.627). An association of elevated residual gradients and small surgical bioprostheses was noted with both devices (Figure 1A-Figure 1C). For SAPIEN 3, low implantation (defined as >20% THV stent length) was additionally associated with elevated gradients (p=0.049) (Figure 2, Figure 3A). Elevated residual gradients ≥20 mmHg were also observed more frequently after VinV treatment of stenosed bioprostheses vs. regurgitation and mixed (42.6% vs. 33.9% overall, p=0.053) and stented vs. stentless valves (39.3% vs. 24.7%, p=0.013). Of note, a low implantation of the SAPIEN 3 was intended in two patients to alleviate parasurgical valve regurgitation and successfully carried out. One-year follow-up demonstrated a mean gradient of 18±9.1 mmHg for SAPIEN 3 patients, with an associated aortic valve area of 1.24±0.4 cm2. Out of 53 patients with available data, 52 had none or mild aortic regurgitation.

Figure 1. Post valve-in-valve mean gradient according to surgical valve internal diameter. A) & B) Post-procedural gradients according to the true inner diameter (ID) of degenerated surgical bioprostheses for the SAPIEN 3 and the SAPIEN XT transcatheter heart valves. Higher rates of elevated gradients were observed with both devices after implantation in small bioprostheses with ≤21 mm inner diameter (SAPIEN 3: p=0.02, SAPIEN XT: p=0.01). C) Subgroup analysis showing the significant association of mean gradients and true ID (p<0.01 in SAPIEN XT and SAPIEN 3).

Figure 2. SAPIEN 3 valve-in-valve implantation depth. VinV implantation of a 23 mm SAPIEN 3 THV into a 21 mm PERIMOUNT bioprosthesis at 36% and 15.5% depth, yielding a 35 and 18 mmHg mean transvalvular gradient, respectively.

CLINICAL OUTCOMES

A trend towards better clinical outcomes was observed in the SAPIEN 3 group. All-cause mortality at thirty days was 0.6% and 3.5% in SAPIEN 3 and SAPIEN XT patients, respectively (p=0.077) (Table 2). Acute kidney injury stages 2-3 became prevalent in 3.5% vs. 7.9% (p=0.093), while major/life-threatening bleeding occurred in 1.9% of SAPIEN 3 vs. 6.0% of SAPIEN XT cases (p=0.065). Outcomes were similar regarding rates of major stroke (0.5% vs. 2.0%, p=0.184) or major vascular/access-site complications (6.9% vs. 7.5%, p=0.805). The rate of permanent pacemaker implantations was higher in SAPIEN 3 than in SAPIEN XT patients (6.0% vs. 2.5% in patients without a permanent pacemaker prior to VinV, p=0.071). Indications for pacemaker implantation in SAPIEN 3 patients were an intermittent or persistent complete heart block in seven cases and a combined left bundle branch block and prolonged first-degree atrioventricular block in one patient. Of note, three of these patients displayed a pre-existing right bundle branch block at baseline. Six out of eight pacemaker implantations were performed in patients with a low implanted SAPIEN 3, and a cut-off of deeper implantation than 5 mm was identified as associated with increased risk (depth ≤5 mm 4% vs. depth >5 mm 22.2%; p=0.01) (Figure 3B). Out of 90 SAPIEN 3 patients with available one-year information, 16 had died (17.8%).

Figure 3. SAPIEN 3 valve-in-valve implantation depth and clinical outcomes. A) Post-procedural gradients after VinV with the SAPIEN 3 according to implantation depth as a function of % total SAPIEN 3 frame length. Implantation depth >20% was associated with a mean gradient ≥30 mmHg in 13.8% of patients compared to none after implantation depth ≤20% (p=0.049). B) Six out of eight pacemaker implantations were performed after low SAPIEN 3 implantation (>5 mm, p=0.01).

Discussion

The data represent the first large analysis of aortic VinV implantations with the latest-generation SAPIEN 3, comparing it to a similar cohort of SAPIEN XT VinV procedures. Baseline parameters and the IPT propensity score weighting suggest that the two cohorts are generally similar. Three major findings can be drawn from this analysis: (i) VinV implantation using the SAPIEN 3 was safe, (ii) elevated residual gradients remain a concern with both balloon-expandable THV (particularly in small surgical prostheses), and (iii) higher SAPIEN 3 implantation within degenerated bioprostheses may be beneficial.

Compared to the SAPIEN XT, VinV procedures using the SAPIEN 3 THV were both equally safe and effective for the treatment of degenerated aortic bioprostheses. With smaller delivery sheaths, procedures in the SAPIEN 3 group were more often performed via transfemoral access under local anaesthesia and without transoesophageal echocardiographic guidance.

Short-term clinical follow-up demonstrated low early mortality and low periprocedural complication rates in both groups, underlining the high safety profile of the procedure. A trend towards fewer events of bleeding, acute kidney injury and 30-day mortality in the SAPIEN 3 group may reflect the learning curve and substantial procedural and device-based refinements that have been achieved in the meantime. In addition, rates of post-dilation or the need for a second THV were low with both platforms and in favour of the SAPIEN 3. Predilation of the degenerated bioprostheses was reported in 29.3% of procedures. Due to the inherent risk of predilation-associated embolisation and the negligible number of cases with difficulties in crossing the prosthesis, this number appears unreasonably high. The detrimental effect of paravalvular regurgitation on long-term outcome has been investigated9. Rates of residual regurgitation were low with both devices; the additional sealing cuff of the SAPIEN 3 may have facilitated even lower rates in this group compared to the SAPIEN XT. In two cases, the SAPIEN 3 facilitated the treatment of paraprosthetic regurgitation in degenerated bioprostheses. Its design featuring an additional cuff at the inflow portion may allow sufficient sealing of paravalvular leaks if implanted low enough. The rate of pacemaker implantations after VinV was higher in the SAPIEN 3 group compared to SAPIEN XT patients. The longer device frame of the next-generation SAPIEN 3 THV may have contributed to this result as an association of implantation depth and pacemaker implantations was demonstrated. It should be noted that early SAPIEN 3 cases were included in this analysis. As such, results may also have been influenced by a learning curve regarding implantation depth and foreshortening of the SAPIEN 3 THV frame. In addition, a pre-existent right bundle branch block was evident in a relevant number of these patients, increasing the risk for conduction disturbances yielding permanent pacemaker implantations.

Residual aortic valve stenosis remains the Achilles’ heel of VinV implantation. Elevated gradients after VinV procedures were reported before and were inversely related to the internal diameter of the surgical bioprostheses2,3. This observation was substantiated by our analysis. The non-distensible valve prosthesis stents limit the THV expansion with residual higher gradients than after implantation in native aortic valves. We noted elevated gradients in approximately one third of patients after VinV with the SAPIEN 3, similar to the SAPIEN XT in this analysis. Prosthesis-patient mismatch and low rates of device success (VARC-defined) remain an issue in a significant number of patients, particularly in smaller bioprostheses with internal diameters of 21 mm or less. Previous analyses from the VIVID registry10 and in vitro experiments11 noted lower residual gradients for THV featuring a supra-annular design, particularly in small bioprostheses. In vitro studies demonstrated that high deployment of intra-annular THV may also reduce transvalvular gradients, at the risk, however, of valve embolisation12. Our data suggest that low implantation of the next-generation SAPIEN 3 (>20% THV stent frame length) may yield higher residual gradients, particularly in small prostheses. Hence, care should be taken to position the SAPIEN 3 precisely within the bioprosthesis’ ring. Similar observations were reported for the SAPIEN XT and Medtronic CoreValve8. Comprehensive knowledge of valve design and dimensions to achieve precise implantation of the THV into the surgical bioprostheses at the desired height remains essential to achieve favourable haemodynamic outcomes. Although the influence of elevated gradients on long-term clinical outcome and durability of the THV remains to be determined, data from surgical aortic valve replacement strongly suggest an adverse impact of prosthesis-patient mismatch on long-term survival13. As we are already observing an expansion of VinV treatment to intermediate-risk and younger patients, favourable haemodynamic results without any residual stenosis after VinV implantation are essential to achieve good long-term outcomes. Of note, prosthesis-patient mismatch due to surgical aortic valve replacement with undersized bioprostheses (in relation to the body surface area) should probably be treated rarely using VinV therapy, particularly with intra-annular THV.

Limitations

The current analysis provides the most comprehensive analysis of SAPIEN 3 THV for VinV treatment to date. Nevertheless, important limitations should be noted. This is a retrospective and observational analysis, including the early experience with the SAPIEN 3 for VinV treatment, and limited to acute data. Although the cohorts appeared similar before and after IPT weighting, small baseline covariate imbalances remained. In addition, propensity score weighting and matching procedures are unable to address unobserved confounding. A broad range of degenerated prostheses treated by VinV therapy impeded an exact match according to specific surgical prostheses. Clinical outcomes and echocardiographic measurements were site-reported. No information was available on whether balloon underfilling was performed on the cases included. Due to insufficient resolution, perpendicularity or the lack of radiopaque markers, depth analysis was not performed in all SAPIEN 3 cases. Subsequently, the ROC analysis of optimal implantation depth resulted in modest AUC values. Comparison of SAPIEN 3 with other THV devices was beyond the scope of the current analysis, and haemodynamic benefits of supra-annular over intra-annular THV devices have already been extensively described by other studies8,10.

Conclusions

In conclusion, transcatheter aortic VinV implantation was similarly safe and effective using the next-generation SAPIEN 3 and the predecessor SAPIEN XT. However, residual stenosis remains a concern with balloon-expandable VinV procedures, particularly when performed in smaller bioprostheses. Low implantation of the SAPIEN 3 was associated with elevated gradients and pacemaker implantations. Hence, careful patient selection and device positioning are crucial to achieve favourable results with these devices.

Impact on daily practice

Balloon-expandable VinV with both previous-generation and current-generation devices is safe, but still gives rise to considerable issues, such as residual stenosis and need for pacemaker implantation. The development of future-generation balloon-expandable devices should take into consideration the long-standing issues that have not been solved by current-generation devices, especially in the context of VinV.

Acknowledgements

We would like to thank Alex Woersching, PhD candidate at the University of Washington, for his assistance in revising the statistical methods of this paper.

Conflict of interest statement

S. Ensminger is a consultant for Edwards Lifesciences. V. Bapat is a consultant for Edwards Lifesciences, Boston Scientific, Medtronic and Sorin, and has received research grants from Boston Scientific. D. Dvir is a consultant to Edwards Lifesciences, Medtronic and St. Jude Medical. The other authors have no conflicts of interest to declare.

Supplementary data

Supplementary Appendix. Methods.

Supplementary Table 1. Type of degenerated bioprostheses treated by VinV procedures.

Supplementary Figure 1. Kernel density plot of propensity scores for SAPIEN 3 and SAPIEN XT patients.

To read the full content of this article, please download the PDF.


References

Volume 14 Number 4
Jul 20, 2018
Volume 14 Number 4
View full issue


Key metrics

On the same subject

Editorial

10.4244/EIJ-E-23-00009 Apr 24, 2023
SAPIEN 3 Ultra: better sealing, reduced paravalvular leak and a move in the right direction?
Reardon MJ and Goel SS
free

10.4244/EIJV15I14A219 Feb 20, 2020
Going ultra!
Lefèvre T
free

Clinical research

10.4244/EIJ-D-22-00164 Jan 23, 2023
ACURATE neo2 versus SAPIEN 3 Ultra for transcatheter aortic valve implantation
Pellegrini C et al
free

CLINICAL RESEARCH

10.4244/EIJV12I2A37 Jun 10, 2016
Thirty-day outcomes in patients at intermediate risk for surgery from the SAPIEN 3 European approval trial
Vahanian A et al
free
Trending articles
281.53

State-of-the-Art Review

10.4244/EIJ-D-21-00695 Nov 19, 2021
Transcatheter treatment for tricuspid valve disease
Praz F et al
free
243.2

State of the art

10.4244/EIJ-D-21-01117 Sep 20, 2022
Recanalisation of coronary chronic total occlusions
Di Mario C et al
free
208.35

State-of-the-Art Review

10.4244/EIJ-D-21-01034 Jun 3, 2022
Management of in-stent restenosis
Alfonso F et al
free
168.7

Translational research

10.4244/EIJ-D-21-00824 May 15, 2022
Bench test and in vivo evaluation of longitudinal stent deformation during proximal optimisation
Toth GG et al
free
167.05

Expert review

10.4244/EIJ-D-21-00690 May 15, 2022
Crush techniques for percutaneous coronary intervention of bifurcation lesions
Moroni F et al
free
151.03

State-of-the-Art

10.4244/EIJ-D-22-00776 Apr 3, 2023
Computed tomographic angiography in coronary artery disease
Serruys PW et al
free
118

Translational research

10.4244/EIJ-D-22-00718 Jun 5, 2023
Preclinical evaluation of the degradation kinetics of third-generation resorbable magnesium scaffolds
Seguchi M et al
110.35

Viewpoint

10.4244/EIJ-E-22-00007 May 15, 2022
TAVI at 20: how a crazy idea led to a clinical revolution
Eltchaninoff H et al
free
X

The Official Journal of EuroPCR and the European Association of Percutaneous Cardiovascular Interventions (EAPCI)

EuroPCR EAPCI
PCR ESC
Impact factor: 6.2
2022 Journal Citation Reports®
Science Edition (Clarivate Analytics, 2023)
Online ISSN 1969-6213 - Print ISSN 1774-024X
© 2005-2024 Europa Group - All rights reserved