Ted E Feldman1, Michael J Reardon2, Vivek Rajagopal3, Raj R Makkar4, Tanvir K Bajwa5, Neal S Kleiman6, Axel Linke7, Dean J Kereiakes8, Ron Waksman9, Vinod H Thourani9, Robert C Stoler10, Gregory J Mishkel11, David G Rizik12, Vijay S Iyer13, Thomas G Gleason14, Didier Tchétché15, Joshua D Rovin16, Maurice Buchbinder17, Ian T Meredith18, Matthias Götberg19, Henrik Bjursten20, Christopher Meduri3, Michael H Salinger1, Dominic J Allocco18, Keith D Dawkins18. 1. Evanston Hospital Cardiology Division, Northshore University Health System, Evanston, Illinois. 2. Department of Cardiovascular Surgery, Houston Methodist DeBakey Heart and Vascular Center, Houston, Texas. 3. Piedmont Heart Institute, Atlanta, Georgia. 4. Cedars-Sinai Heart Institute, Los Angeles, California. 5. Aurora St Luke's Medical Center, Milwaukee, Wisconsin. 6. Department of Cardiology, Houston Methodist DeBakey Heart and Vascular Center, Houston, Texas. 7. University of Leipzig, Heart Center and Leipzig Heart Institute, Leipzig, Germany. 8. Christ Hospital Heart and Vascular Center/Lindner Research Center, Cincinnati, Ohio. 9. Washington Hospital Center, Washington, DC. 10. Baylor Heart and Vascular Hospital, Dallas, Texas. 11. St John's Hospital, Springfield, Illinois. 12. HonorHealth and the Scottsdale-Lincoln Health Network, Scottsdale, Arizona. 13. University at Buffalo/Gates Vascular Institute, Buffalo, New York. 14. University of Pittsburgh Medical Center, Pittsburgh, Pennsylvania. 15. Clinique Pasteur, Toulouse, France. 16. Morton Plant Mease Healthcare System, Clearwater, Florida. 17. Foundation for Cardiovascular Medicine, Stanford University, Stanford, California. 18. Boston Scientific Corp, Marlborough, Massachusetts. 19. Department of Cardiology, Clinical Sciences, Lund University, Skåne University Hospital, Lund, Sweden. 20. Department of Cardiothoracic Surgery, Clinical Sciences, Lund University, Skåne University University Hospital, Lund, Sweden.
Abstract
Importance: Transcatheter aortic valve replacement (TAVR) is established for selected patients with severe aortic stenosis. However, limitations such as suboptimal deployment, conduction disturbances, and paravalvular leak occur. Objective: To evaluate if a mechanically expanded valve (MEV) is noninferior to an approved self-expanding valve (SEV) in high-risk patients with aortic stenosis undergoing TAVR. Design, Setting, and Participants: The REPRISE III trial was conducted in 912 patients with high or extreme risk and severe, symptomatic aortic stenosis at 55 centers in North America, Europe, and Australia between September 22, 2014, and December 24, 2015, with final follow-up on March 8, 2017. Interventions: Participants were randomized in a 2:1 ratio to receive either an MEV (n = 607) or an SEV (n = 305). Main Outcomes and Measures: The primary safety end point was the 30-day composite of all-cause mortality, stroke, life-threatening or major bleeding, stage 2/3 acute kidney injury, and major vascular complications tested for noninferiority (margin, 10.5%). The primary effectiveness end point was the 1-year composite of all-cause mortality, disabling stroke, and moderate or greater paravalvular leak tested for noninferiority (margin, 9.5%). If noninferiority criteria were met, the secondary end point of 1-year moderate or greater paravalvular leak was tested for superiority in the full analysis data set. Results: Among 912 randomized patients (mean age, 82.8 [SD, 7.3] years; 463 [51%] women; predicted risk of mortality, 6.8%), 874 (96%) were evaluable at 1 year. The primary safety composite end point at 30 days occurred in 20.3% of MEV patients and 17.2% of SEV patients (difference, 3.1%; Farrington-Manning 97.5% CI, -∞ to 8.3%; P = .003 for noninferiority). At 1 year, the primary effectiveness composite end point occurred in 15.4% with the MEV and 25.5% with the SEV (difference, -10.1%; Farrington-Manning 97.5% CI, -∞ to -4.4%; P<.001 for noninferiority). The 1-year rates of moderate or severe paravalvular leak were 0.9% for the MEV and 6.8% for the SEV (difference, -6.1%; 95% CI, -9.6% to -2.6%; P < .001). The superiority analysis for primary effectiveness was statistically significant (difference, -10.2%; 95% CI, -16.3% to -4.0%; P < .001). The MEV had higher rates of new pacemaker implants (35.5% vs 19.6%; P < .001) and valve thrombosis (1.5% vs 0%) but lower rates of repeat procedures (0.2% vs 2.0%), valve-in-valve deployments (0% vs 3.7%), and valve malpositioning (0% vs 2.7%). Conclusions and Relevance: Among high-risk patients with aortic stenosis, use of the MEV compared with the SEV did not result in inferior outcomes for the primary safety end point or the primary effectiveness end point. These findings suggest that the MEV may be a useful addition for TAVR in high-risk patients. Trial Registration: ClinicalTrials.gov Identifier: NCT02202434.
RCT Entities:
Importance: Transcatheter aortic valve replacement (TAVR) is established for selected patients with severe aortic stenosis. However, limitations such as suboptimal deployment, conduction disturbances, and paravalvular leak occur. Objective: To evaluate if a mechanically expanded valve (MEV) is noninferior to an approved self-expanding valve (SEV) in high-risk patients with aortic stenosis undergoing TAVR. Design, Setting, and Participants: The REPRISE III trial was conducted in 912 patients with high or extreme risk and severe, symptomatic aortic stenosis at 55 centers in North America, Europe, and Australia between September 22, 2014, and December 24, 2015, with final follow-up on March 8, 2017. Interventions: Participants were randomized in a 2:1 ratio to receive either an MEV (n = 607) or an SEV (n = 305). Main Outcomes and Measures: The primary safety end point was the 30-day composite of all-cause mortality, stroke, life-threatening or major bleeding, stage 2/3 acute kidney injury, and major vascular complications tested for noninferiority (margin, 10.5%). The primary effectiveness end point was the 1-year composite of all-cause mortality, disabling stroke, and moderate or greater paravalvular leak tested for noninferiority (margin, 9.5%). If noninferiority criteria were met, the secondary end point of 1-year moderate or greater paravalvular leak was tested for superiority in the full analysis data set. Results: Among 912 randomized patients (mean age, 82.8 [SD, 7.3] years; 463 [51%] women; predicted risk of mortality, 6.8%), 874 (96%) were evaluable at 1 year. The primary safety composite end point at 30 days occurred in 20.3% of MEV patients and 17.2% of SEV patients (difference, 3.1%; Farrington-Manning 97.5% CI, -∞ to 8.3%; P = .003 for noninferiority). At 1 year, the primary effectiveness composite end point occurred in 15.4% with the MEV and 25.5% with the SEV (difference, -10.1%; Farrington-Manning 97.5% CI, -∞ to -4.4%; P<.001 for noninferiority). The 1-year rates of moderate or severe paravalvular leak were 0.9% for the MEV and 6.8% for the SEV (difference, -6.1%; 95% CI, -9.6% to -2.6%; P < .001). The superiority analysis for primary effectiveness was statistically significant (difference, -10.2%; 95% CI, -16.3% to -4.0%; P < .001). The MEV had higher rates of new pacemaker implants (35.5% vs 19.6%; P < .001) and valve thrombosis (1.5% vs 0%) but lower rates of repeat procedures (0.2% vs 2.0%), valve-in-valve deployments (0% vs 3.7%), and valve malpositioning (0% vs 2.7%). Conclusions and Relevance: Among high-risk patients with aortic stenosis, use of the MEV compared with the SEV did not result in inferior outcomes for the primary safety end point or the primary effectiveness end point. These findings suggest that the MEV may be a useful addition for TAVR in high-risk patients. Trial Registration: ClinicalTrials.gov Identifier: NCT02202434.
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