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Transcatheter mitral valve replacement: A frontier in cardiac intervention
In the last 10 years, we have seen a revolution in transcatheter therapies for structural heart disease. The most widely embraced, transcatheter aortic valve replacement (TAVR) was originally intended for patients in whom surgery was considered impossible, but it has now been established as an excellent alternative to surgical aortic valve replacement in patients at high or intermediate risk.1–3 As TAVR has become established, with well-designed devices and acceptable safety and efficacy, it has inspired operators and inventors to push the envelope of innovation to transcatheter mitral valve replacement (TMVR).
This review summarizes the newest data available for the TMVR devices currently being tested in patients with native mitral regurgitation, bioprosthetic degeneration, and degenerative mitral stenosis.
THE MITRAL VALVE: THE NEW FRONTIER
Whereas the pathologic mechanisms of aortic stenosis generally all result in the same anatomic consequence (ie, calcification of the valve leaflets and commissures resulting in reduced mobility), mitral valve regurgitation is much more heterogeneous. Primary (degenerative) mitral regurgitation is caused by intrinsic valve pathology such as myxomatous degeneration, chordal detachment, fibroelastic deficiency, endocarditis, and other conditions that prevent the leaflets from coapting properly. In contrast, in secondary or functional mitral regurgitation, the leaflets are normal but do not coapt properly because of apical tethering to a dilated left ventricle, reduced closing forces with left ventricular dysfunction, or annular dilation as the result of either left ventricular or left atrial dilation.
Surgical mitral valve repair is safe and effective in patients with degenerative mitral regurgitation caused by leaflet prolapse and flail. However, some patients cannot undergo surgery because they have comorbid conditions that place them at extreme risk.4 For example, most patients with functional mitral regurgitation due to ischemic or dilated cardiomyopathy have significant surgical risk and multiple comorbidities, and in this group surgical repair has limited efficacy.5 A sizeable proportion of patients with mitral regurgitation may not be offered surgery because their risk is too high.6 Therefore, alternatives to the current surgical treatments have the potential to benefit a large number of patients.
Similarly, many patients with degenerative mitral stenosis caused by calcification of the mitral annulus also cannot undergo cardiac surgery because of prohibitively high risk. While rheumatic disease is the most common cause of mitral stenosis worldwide, degenerative mitral stenosis may be the cause in up to one-fourth of patients overall and up to 60% of patients older than 80 years.7 In the latter group, not only do old age and comorbidities such as diabetes mellitus and chronic kidney disease pose surgical risks, the technical challenge of surgically implanting a prosthetic mitral valve in the setting of a calcified annulus may be significant.8
The mitral valve is, therefore, the perfect new frontier for percutaneous valve replacement therapies, and TMVR is emerging as a potential option for patients with mitral regurgitation and degenerative mitral stenosis. The currently available percutaneous treatment options for mitral regurgitation include edge-to-edge leaflet repair, direct and indirect annuloplasty, spacers, and left ventricular remodeling devices (Table 1).9,10 As surgical mitral valve repair is strongly preferred over mitral valve replacement, the percutaneous procedures and the devices that are used are engineered to approximate the current standard surgical techniques. However, given the complex pathologies involved, surgical repair often requires the use of multiple repair techniques in the same patient. Therefore, percutaneous repair may also require more than one type of device in the same patient and may not be anatomically feasible in many patients. Replacing the entire valve may obviate some of these challenges.
Compared with the aortic valve, the mitral valve poses a greater challenge to percutaneous treatment due to its structure and dynamic relationship with the left ventricle. Some specific challenges facing the development of TMVR are that the mitral valve is large, it is difficult to access, it is asymmetrical, it lacks an anatomically well-defined annulus to which to anchor the replacement valve, its geometry changes throughout the cardiac cycle, and placing a replacement valve in it entails the risk of left ventricular outflow tract obstruction. Despite these challenges, a number of devices are undergoing preclinical testing, a few are in phase 1 clinical trials, and registries are being kept. Depending on the specific device, an antegrade transseptal approach to the mitral valve (via the femoral vein) or a retrograde transapical approach (via direct left ventricular access) may be used (Figure 1).
NATIVE MITRAL VALVE REGURGITATION
For degenerative mitral regurgitation, the standard of care is cardiac surgery at a hospital experienced with mitral valve repair, and with very low rates of mortality and morbidity. For patients in whom the surgical risk is prohibitive, percutaneous edge-to-edge leaflet repair using the MitraClip (Abbott Vascular, Minneapolis, MN) is the best option if the anatomy permits. If the mitral valve pathology is not amenable to MitraClip repair, the patient may be evaluated for TMVR under a clinical trial protocol.
For functional mitral regurgitation, the decisions are more complex. If the patient has chronic atrial fibrillation, electrical cardioversion and antiarrhythmic drug therapy may restore and maintain sinus rhythm, though if the left atrium is large, sinus rhythm may not be possible. If the patient has left ventricular dysfunction, guideline-directed medical therapy should be optimized; this reduces the risk of exacerbations, hospitalizations, and death and may also reduce the degree of regurgitation. If the patient has severe left ventricular dysfunction and a wide QRS duration, cardiac resynchronization therapy (biventricular pacing) may also be beneficial and reduce functional mitral regurgitation. If symptoms and severe functional mitral regurgitation persist despite these measures and the patient’s surgical risk is deemed to be extreme, options include MitraClip placement as part of the randomized Cardiovascular Outcomes Assessment of the MitraClip Percutaneous Therapy (COAPT) trial, which compares guideline-directed medical therapy with guideline-directed therapy plus MitraClip. Another option is enrollment in a clinical trial or registry of TMVR.
At this writing, six TMVR devices have been implanted in humans:
- Fortis (Edwards Lifesciences, Irvine, CA)
- Tendyne (Tendyne Holding Inc, Roseville, MN)
- NaviGate (NaviGate Cardiac Structures, Inc, Lake Forest, CA)
- Intrepid (Medtronic, Minneapolis, MN)
- CardiAQ (Edwards Lifesciences, Irvine, CA)
- Tiara (Neovasc Inc, Richmond, BC).
Most of the early experience with these valves has not yet been published, but some data have been presented at national and international meetings.
The Fortis valve
The Fortis valve consists of a self-expanding nitinol frame and leaflets made of bovine pericardium and is implanted via a transapical approach.
The device was successfully implanted in three patients in Quebec City, Canada, and at 6 months, all had improved significantly in functional class and none had needed to be hospitalized.11 Echocardiographic assessment demonstrated trace or less mitral regurgitation and a mean transvalvular gradient less than 4 mm Hg in all.
Bapat and colleagues12 attempted to implant the device in 13 patients in Europe and Canada. The average left ventricular ejection fraction was 34%, and 12 of 13 patients (92%) had functional mitral regurgitation. Procedural success was achieved in 10 patients, but five patients died within 30 days. While the deaths were due to nonvalvular issues (multiorgan failure, septic shock, intestinal ischemia after failed valve implantation and conversion to open surgery, malnutrition leading to respiratory failure, and valve thrombosis), the trial is currently on hold as more data are collected and reviewed. Among the eight patients who survived the first month, all were still alive at 6 months, and echocardiography demonstrated no or trivial mitral regurgitation in six patients (80%) and mild regurgitation in two patients (20%); the average mitral gradient was 4 mm Hg, and there was no change in mean left ventricular ejection fraction.
The Tendyne valve
The Tendyne valve is a self-expanding prosthesis with porcine pericardial leaflets. It is delivered transapically and is held in place by a tether from the valve to the left ventricular apex.
In the first 12 patients enrolled in an early feasibility trial,13 the average left ventricular ejection fraction was 40%, and 11 of the 12 patients had functional mitral regurgitation. The device was successfully implanted in 11 patients, while one patient developed left ventricular outflow tract obstruction and the device was uneventfully removed. All patients were still alive at 30 days, and the 11 patients who still had a prosthetic valve did not have any residual mitral regurgitation.
As of this writing, almost 80 patients have received the device, though the data have not yet been presented. Patients are being enrolled in phase 1 trials.
The NaviGate valve
The NaviGate valve consists of a trileaflet subassembly fabricated from bovine pericardium, mounted on a self-expanding nitinol stent, and is only implanted transatrially.
NaviGate valves were successfully implanted in two patients via a transatrial approach (Figure 2). Both patients had excellent valve performance without residual mitral regurgitation or left ventricular outflow tract obstruction. The first patient showed significant improvement in functional class and freedom from hospitalization at 6 months, but the second patient died within a week of the implant due to advanced heart failure.14 A US clinical trial is expected soon.
The Intrepid valve
The Intrepid valve consists of an outer stent to provide fixation to the annulus and an inner stent that houses a bovine pericardial valve. The device is a self-expanding system that is delivered transapically.
In a series of 15 patients, 11 had functional mitral regurgitation (with an average left ventricular ejection fraction of 35%) and four had degenerative mitral regurgitation (with an average left ventricular ejection fraction of 57%).15 The device was successfully implanted in 14 patients, after which the average mitral valve gradient was 4 mm Hg. All patients but one were left with no regurgitation (the other patient had 1+ regurgitation).
A trial is currently under way in Europe.
The CardiAQ valve
The CardiAQ is constructed of bovine pericardium and can be delivered by the transseptal or transapical route.
Of 12 patients treated under compassionate use,16 two-thirds (eight patients) had functional mitral regurgitation. Two patients died during the procedure, three died of noncardiac complications within 30 days, and one more died of sepsis shortly after 30 days. This early experience demonstrates the importance of careful patient selection and postprocedural management in the feasibility assessment of these new technologies.
Patients are being enrolled in phase 1 trials.
The Tiara valve
The Tiara valve, a self-expanding prosthesis with bovine pericardial leaflets, is delivered by the transapical route.
Eleven patients underwent Tiara implantation as part of either a Canadian special access registry or an international feasibility trial. Their average Society of Thoracic Surgeons score (ie, their calculated risk of major morbidity or operative mortality) was 15.6%, and their average left ventricular ejection fraction was 29%. Only two patients had degenerative mitral regurgitation. Nine patients had uneventful procedures and demonstrated no residual mitral regurgitation and no left ventricular outflow tract obstruction. The procedure was converted to open surgery in two patients owing to valve malpositioning, and both of them died within 30 days. One patient in whom the procedure was successful suffered erosion of the septum and died on day 4.17
Patients are being enrolled in phase 1 trials.
DEGENERATIVE MITRAL STENOSIS
In patients with degenerative mitral stenosis, extensive mitral annular calcification may provide an adequate “frame” to hold a transcatheter valve prosthesis (Figure 3). Exploiting this feature, numerous investigators have successfully deployed prosthetic valves designed for TAVR in the calcified mitral annulus via the retrograde transapical and antegrade transseptal routes.
Guerrero and colleagues presented results from the first global registry of TMVR in mitral annular calcification at the 2016 EuroPCR Congress.18 Of 104 patients analyzed, almost all received an Edwards’ Sapien balloon-expandable valve (first-generation, Sapien XT, or Sapien 3); the others received Boston Scientific’s Lotus or Direct Flow Medical (Direct Flow Medical, Santa Clara, CA) valves. With an average age of 73 years and a high prevalence of comorbidities such as diabetes, chronic obstructive pulmonary disease, atrial fibrillation, chronic kidney disease, and prior cardiac surgery, the group presented extreme surgical risk, with an average Society of Thoracic Surgeons risk score of 14.4%. Slightly more than 40% of the patients underwent transapical implantation, slightly less than 40% underwent transfemoral or transseptal implantation, and just under 20% had a direct atrial approach.
The implantation was technically successful in 78 of 104 patients (75%); 13 patients (12.5%) required a second mitral valve to be placed, 11 patients (10.5%) had left ventricular outflow tract obstruction, four patients (4%) had valve embolization, and two patients (2%) had left ventricular perforation. At 30 days, 11 of 104 patients (10.6%) had died of cardiac causes and 15 patients (14.4%) had died of noncardiac causes. When divided roughly into three equal groups by chronological order, the last third of patients, compared with the first third of patients, enjoyed greater technical success (80%, n = 32/40 vs 62.5%, n = 20/32), better 30-day survival (85%, n = 34/40 vs 62.5%, n = 20/32), and no conversion to open surgery (0 vs 12.5%, n = 4/32), likely demonstrating both improved patient selection and lessons learned from shared experience. At 1 year, almost 90% of patients had New York Heart Association class I or II symptoms. Prior to the procedure, 91.5% had New York Heart Association class III or IV symptoms.
At present, TMVR in mitral annular calcification is not approved in the United States or elsewhere. However, multiple registries are currently enrolling patients or are in formative stages to push the frontier of the currently available technologies until better, dedicated devices are available for this group of patients.
BIOPROSTHETIC VALVE OR VALVE RING FAILURE
Implantation of a TAVR prosthetic inside a degenerated bioprosthetic mitral valve (valve-in-valve) and mitral valve ring (valve-in-ring) is generally limited to case series with short-term results using the Edwards Sapien series, Boston Scientific Lotus, Medtronic Melody (Medtronic, Minneapolis, MN), and Direct Flow Medical valves (Figure 4).19–23
The largest collective experience was presented in the Valve-in-Valve International Data (VIVID) registry, which included 349 patients who had mitral valve-in-valve placement and 88 patients who had mitral valve-in-ring procedures. Their average age was 74 and the mean Society of Thoracic Surgeons score was 12.9% in both groups.24 Of the 437 patients, 345 patients (78.9%) underwent transapical implantation, and 391 patients (89.5%) received a Sapien XT or Sapien 3 valve. In the valve-in-valve group, 41% of the patients had regurgitation, 25% had stenosis, and 34% had both. In the valve-in-ring group, 60% of the patients had regurgitation, 17% had stenosis, and 23% had both.
Valve placement was successful in most patients. The rate of stroke was low (2.9% with valve-in-valve placement, 1.1% with valve-in-ring placement), though the rate of moderate or greater residual mitral regurgitation was significantly higher in patients undergoing valve-in-ring procedures (14.8% vs 2.6%, P < .001), as was the rate of left ventricular outflow tract obstruction (8% vs 2.6%, P = .03). There was also a trend toward worse 30-day mortality in the valve-in-ring group (11.4% vs 7.7%, P = .15). As with aortic valve-in-valve procedures, small surgical mitral valves (≤ 25 mm) were associated with higher postprocedural gradients.
Eleid and colleagues25 published their experience with antegrade transseptal TMVR in 48 patients with an average Society of Thoracic Surgeons score of 13.2%, 33 of whom underwent valve-in-valve procedures and nine of whom underwent valve-in-ring procedures. (The other six patients underwent mitral valve implantation for severe mitral annular calcification.) In the valve-in-valve group, 31 patients successfully underwent implant procedures, but two patients died during the procedure from left ventricular perforation. Of the nine valve-in-ring patients, two had acute embolization of the valve and were converted to open surgery. Among the seven patients in whom implantation was successful, two developed significant left ventricular outflow tract obstruction; one was treated with surgical resection of the anterior mitral valve leaflet and the other was medically managed.
CONCLUSION
Transcatheter mitral valve replacement in regurgitant mitral valves, failing mitral valve bioprosthetics and rings, and calcified mitral annuli has been effectively conducted in a number of patients who had no surgical options due to prohibitive surgical risk. International registries and our experience have demonstrated that the valve-in-valve procedure using a TAVR prosthesis carries the greatest likelihood of success, given the rigid frame of the surgical bioprosthetic that allows stable valve deployment. While approved in Europe for this indication, use of these devices for this application in the United States is considered “off label” and is performed only in clinically extenuating circumstances. Implantation of TAVR prosthetics in patients with prior mitral ring repair or for native mitral stenosis also has been performed successfully, although left ventricular outflow tract obstruction is a significant risk in this early experience.
Devices designed specifically for TMVR are in their clinical infancy and have been implanted successfully in only small numbers of patients, most of whom had functional mitral regurgitation. Despite reasonable technical success, most of these trials have been plagued by high mortality rates at 30 days in large part due to the extreme risk of the patients in whom these procedures have been conducted. At present, enrollment in TMVR trials for patients with degenerative or functional mitral regurgitation is limited to those without a surgical option and who conform to very specific anatomic criteria.
- Leon MB, Smith CR, Mack M, et al; PARTNER Trial Investigators. Transcatheter aortic-valve implantation for aortic stenosis in patients who cannot undergo surgery. N Engl J Med 2010; 363:1597–1607.
- Smith CR, Leon MB, Mack MJ, et al; PARTNER Trial Investigators. Transcatheter versus surgical aortic-valve replacement in high-risk patients. N Engl J Med 2011; 364:2187–2198.
- Thourani VH, Kodali S, Makkar RR, et al. Transcatheter aortic valve replacement versus surgical valve replacement in intermediate-risk patients: a propensity score analysis. Lancet 2016; 387:2218–2225.
- Goel SS, Bajaj N, Aggarwal B, et al. Prevalence and outcomes of unoperated patients with severe symptomatic mitral regurgitation and heart failure: comprehensive analysis to determine the potential role of MitraClip for this unmet need. J Am Coll Cardiol 2014; 63:185–186.
- DiBardino DJ, ElBardissi AW, McClure RS, Razo-Vasquez OA, Kelly NE, Cohn LH. Four decades of experience with mitral valve repair: analysis of differential indications, technical evolution, and long-term outcome. J Thorac Cardiovasc Surg 2010; 139:76–83; discussion 83–74.
- Mirabel M, Iung B, Baron G, et al. What are the characteristics of patients with severe, symptomatic, mitral regurgitation who are denied surgery? Eur Heart J 2007; 28:1358–1365.
- Iung B, Baron G, Butchart EG, et al. A prospective survey of patients with valvular heart disease in europe: the Euro Heart Survey on Valvular Heart Disease. Eur Heart J 2003; 24:1231–1243.
- Sud K, Agarwal S, Parashar A, et al. Degenerative mitral stenosis: unmet need for percutaneous interventions. Circulation 2016; 133:1594–1604.
- Svensson LG, Ye J, Piemonte TC, Kirker-Head C, Leon MB, Webb JG. Mitral valve regurgitation and left ventricular dysfunction treatment with an intravalvular spacer. J Card Surg 2015; 30:53–54.
- Raman J, Raghavan J, Chandrashekar P, Sugeng L. Can we repair the mitral valve from outside the heart? A novel extra-cardiac approach to functional mitral regurgitation. Heart Lung Circ 2011; 20:157–162.
- Abdul-Jawad Altisent O, Dumont E, Dagenais F, et al. Initial experience of transcatheter mitral valve replacement with a novel transcatheter mitral valve: procedural and 6-month follow-up results. J Am Coll Cardiol 2015; 66:1011–1019.
- Bapat V. FORTIS: design, clinical results, and next steps. Presented at CRT (Cardiovascular Research Technologies) 16; Feburary 20–23, 2016; Washington, DC.
- Sorajja P. Tendyne: technology and clinical results update. Presented at CRT (Cardiovascular Research Technologies) 16; February 20–23, 2016; Washington, DC.
- Navia J. Personal communication.
- Bapat V. Medtronic Intrepid transcatheter mitral valve replacement. Presented at EuroPCR 2015; May 19–22, 2015; Paris, France.
- Herrmann H. Cardiaq-Edwards TMVR. Presented at CRT (Cardiovascular Research Technologies) 16; February 20–23, 2016; Washington, DC.
- Dvir D. Tiara: design, clincal results, and next steps. Presented at CRT (Cardiovascular Research Technologies) 16; February 20–23, 2016; Washington, DC.
- Guerrero M, Dvir D, Himbert D, et al. Transcatheter mitral valve replacement in native mitra valve disease with severe mitral annular calcification: results from the first global registry. JACC Cardiovasc Interv 2016; 9:1361–1371.
- Seiffert M, Franzen O, Conradi L, et al. Series of transcatheter valve-in-valve implantations in high-risk patients with degenerated bioprostheses in aortic and mitral position. Catheter Cardiovasc Interv 2010; 76:608–615.
- Webb JG, Wood DA, Ye J, et al. Transcatheter valve-in-valve implantation for failed bioprosthetic heart valves. Circulation 2010; 121:1848–1857.
- Cerillo AG, Chiaramonti F, Murzi M, et al. Transcatheter valve in valve implantation for failed mitral and tricuspid bioprosthesis. Catheter Cardiovasc Interv 2011; 78:987–995.
- Seiffert M, Conradi L, Baldus S, et al. Transcatheter mitral valve-in-valve implantation in patients with degenerated bioprostheses. JACC Cardiovasc Interv 2012; 5:341–349.
- Wilbring M, Alexiou K, Tugtekin SM, et al. Pushing the limits—further evolutions of transcatheter valve procedures in the mitral position, including valve-in-valve, valve-in-ring, and valve-in-native-ring. J Thorac Cardiovasc Surg 2014; 147:210–219.
- Dvir D, on behalf of the VIVID Registry Investigators. Transcatheter mitral valve-in-valve and valve-in-ring implantations. Transcatheter Valve Therapies 2015.
- Eleid MF, Cabalka AK, Williams MR, et al. Percutaneous transvenous transseptal transcatheter valve implantation in failed bioprosthetic mitral valves, ring annuloplasty, and severe mitral annular calcification. JACC Cardiovasc Interv 2016; 9:1161–1174.
In the last 10 years, we have seen a revolution in transcatheter therapies for structural heart disease. The most widely embraced, transcatheter aortic valve replacement (TAVR) was originally intended for patients in whom surgery was considered impossible, but it has now been established as an excellent alternative to surgical aortic valve replacement in patients at high or intermediate risk.1–3 As TAVR has become established, with well-designed devices and acceptable safety and efficacy, it has inspired operators and inventors to push the envelope of innovation to transcatheter mitral valve replacement (TMVR).
This review summarizes the newest data available for the TMVR devices currently being tested in patients with native mitral regurgitation, bioprosthetic degeneration, and degenerative mitral stenosis.
THE MITRAL VALVE: THE NEW FRONTIER
Whereas the pathologic mechanisms of aortic stenosis generally all result in the same anatomic consequence (ie, calcification of the valve leaflets and commissures resulting in reduced mobility), mitral valve regurgitation is much more heterogeneous. Primary (degenerative) mitral regurgitation is caused by intrinsic valve pathology such as myxomatous degeneration, chordal detachment, fibroelastic deficiency, endocarditis, and other conditions that prevent the leaflets from coapting properly. In contrast, in secondary or functional mitral regurgitation, the leaflets are normal but do not coapt properly because of apical tethering to a dilated left ventricle, reduced closing forces with left ventricular dysfunction, or annular dilation as the result of either left ventricular or left atrial dilation.
Surgical mitral valve repair is safe and effective in patients with degenerative mitral regurgitation caused by leaflet prolapse and flail. However, some patients cannot undergo surgery because they have comorbid conditions that place them at extreme risk.4 For example, most patients with functional mitral regurgitation due to ischemic or dilated cardiomyopathy have significant surgical risk and multiple comorbidities, and in this group surgical repair has limited efficacy.5 A sizeable proportion of patients with mitral regurgitation may not be offered surgery because their risk is too high.6 Therefore, alternatives to the current surgical treatments have the potential to benefit a large number of patients.
Similarly, many patients with degenerative mitral stenosis caused by calcification of the mitral annulus also cannot undergo cardiac surgery because of prohibitively high risk. While rheumatic disease is the most common cause of mitral stenosis worldwide, degenerative mitral stenosis may be the cause in up to one-fourth of patients overall and up to 60% of patients older than 80 years.7 In the latter group, not only do old age and comorbidities such as diabetes mellitus and chronic kidney disease pose surgical risks, the technical challenge of surgically implanting a prosthetic mitral valve in the setting of a calcified annulus may be significant.8
The mitral valve is, therefore, the perfect new frontier for percutaneous valve replacement therapies, and TMVR is emerging as a potential option for patients with mitral regurgitation and degenerative mitral stenosis. The currently available percutaneous treatment options for mitral regurgitation include edge-to-edge leaflet repair, direct and indirect annuloplasty, spacers, and left ventricular remodeling devices (Table 1).9,10 As surgical mitral valve repair is strongly preferred over mitral valve replacement, the percutaneous procedures and the devices that are used are engineered to approximate the current standard surgical techniques. However, given the complex pathologies involved, surgical repair often requires the use of multiple repair techniques in the same patient. Therefore, percutaneous repair may also require more than one type of device in the same patient and may not be anatomically feasible in many patients. Replacing the entire valve may obviate some of these challenges.
Compared with the aortic valve, the mitral valve poses a greater challenge to percutaneous treatment due to its structure and dynamic relationship with the left ventricle. Some specific challenges facing the development of TMVR are that the mitral valve is large, it is difficult to access, it is asymmetrical, it lacks an anatomically well-defined annulus to which to anchor the replacement valve, its geometry changes throughout the cardiac cycle, and placing a replacement valve in it entails the risk of left ventricular outflow tract obstruction. Despite these challenges, a number of devices are undergoing preclinical testing, a few are in phase 1 clinical trials, and registries are being kept. Depending on the specific device, an antegrade transseptal approach to the mitral valve (via the femoral vein) or a retrograde transapical approach (via direct left ventricular access) may be used (Figure 1).
NATIVE MITRAL VALVE REGURGITATION
For degenerative mitral regurgitation, the standard of care is cardiac surgery at a hospital experienced with mitral valve repair, and with very low rates of mortality and morbidity. For patients in whom the surgical risk is prohibitive, percutaneous edge-to-edge leaflet repair using the MitraClip (Abbott Vascular, Minneapolis, MN) is the best option if the anatomy permits. If the mitral valve pathology is not amenable to MitraClip repair, the patient may be evaluated for TMVR under a clinical trial protocol.
For functional mitral regurgitation, the decisions are more complex. If the patient has chronic atrial fibrillation, electrical cardioversion and antiarrhythmic drug therapy may restore and maintain sinus rhythm, though if the left atrium is large, sinus rhythm may not be possible. If the patient has left ventricular dysfunction, guideline-directed medical therapy should be optimized; this reduces the risk of exacerbations, hospitalizations, and death and may also reduce the degree of regurgitation. If the patient has severe left ventricular dysfunction and a wide QRS duration, cardiac resynchronization therapy (biventricular pacing) may also be beneficial and reduce functional mitral regurgitation. If symptoms and severe functional mitral regurgitation persist despite these measures and the patient’s surgical risk is deemed to be extreme, options include MitraClip placement as part of the randomized Cardiovascular Outcomes Assessment of the MitraClip Percutaneous Therapy (COAPT) trial, which compares guideline-directed medical therapy with guideline-directed therapy plus MitraClip. Another option is enrollment in a clinical trial or registry of TMVR.
At this writing, six TMVR devices have been implanted in humans:
- Fortis (Edwards Lifesciences, Irvine, CA)
- Tendyne (Tendyne Holding Inc, Roseville, MN)
- NaviGate (NaviGate Cardiac Structures, Inc, Lake Forest, CA)
- Intrepid (Medtronic, Minneapolis, MN)
- CardiAQ (Edwards Lifesciences, Irvine, CA)
- Tiara (Neovasc Inc, Richmond, BC).
Most of the early experience with these valves has not yet been published, but some data have been presented at national and international meetings.
The Fortis valve
The Fortis valve consists of a self-expanding nitinol frame and leaflets made of bovine pericardium and is implanted via a transapical approach.
The device was successfully implanted in three patients in Quebec City, Canada, and at 6 months, all had improved significantly in functional class and none had needed to be hospitalized.11 Echocardiographic assessment demonstrated trace or less mitral regurgitation and a mean transvalvular gradient less than 4 mm Hg in all.
Bapat and colleagues12 attempted to implant the device in 13 patients in Europe and Canada. The average left ventricular ejection fraction was 34%, and 12 of 13 patients (92%) had functional mitral regurgitation. Procedural success was achieved in 10 patients, but five patients died within 30 days. While the deaths were due to nonvalvular issues (multiorgan failure, septic shock, intestinal ischemia after failed valve implantation and conversion to open surgery, malnutrition leading to respiratory failure, and valve thrombosis), the trial is currently on hold as more data are collected and reviewed. Among the eight patients who survived the first month, all were still alive at 6 months, and echocardiography demonstrated no or trivial mitral regurgitation in six patients (80%) and mild regurgitation in two patients (20%); the average mitral gradient was 4 mm Hg, and there was no change in mean left ventricular ejection fraction.
The Tendyne valve
The Tendyne valve is a self-expanding prosthesis with porcine pericardial leaflets. It is delivered transapically and is held in place by a tether from the valve to the left ventricular apex.
In the first 12 patients enrolled in an early feasibility trial,13 the average left ventricular ejection fraction was 40%, and 11 of the 12 patients had functional mitral regurgitation. The device was successfully implanted in 11 patients, while one patient developed left ventricular outflow tract obstruction and the device was uneventfully removed. All patients were still alive at 30 days, and the 11 patients who still had a prosthetic valve did not have any residual mitral regurgitation.
As of this writing, almost 80 patients have received the device, though the data have not yet been presented. Patients are being enrolled in phase 1 trials.
The NaviGate valve
The NaviGate valve consists of a trileaflet subassembly fabricated from bovine pericardium, mounted on a self-expanding nitinol stent, and is only implanted transatrially.
NaviGate valves were successfully implanted in two patients via a transatrial approach (Figure 2). Both patients had excellent valve performance without residual mitral regurgitation or left ventricular outflow tract obstruction. The first patient showed significant improvement in functional class and freedom from hospitalization at 6 months, but the second patient died within a week of the implant due to advanced heart failure.14 A US clinical trial is expected soon.
The Intrepid valve
The Intrepid valve consists of an outer stent to provide fixation to the annulus and an inner stent that houses a bovine pericardial valve. The device is a self-expanding system that is delivered transapically.
In a series of 15 patients, 11 had functional mitral regurgitation (with an average left ventricular ejection fraction of 35%) and four had degenerative mitral regurgitation (with an average left ventricular ejection fraction of 57%).15 The device was successfully implanted in 14 patients, after which the average mitral valve gradient was 4 mm Hg. All patients but one were left with no regurgitation (the other patient had 1+ regurgitation).
A trial is currently under way in Europe.
The CardiAQ valve
The CardiAQ is constructed of bovine pericardium and can be delivered by the transseptal or transapical route.
Of 12 patients treated under compassionate use,16 two-thirds (eight patients) had functional mitral regurgitation. Two patients died during the procedure, three died of noncardiac complications within 30 days, and one more died of sepsis shortly after 30 days. This early experience demonstrates the importance of careful patient selection and postprocedural management in the feasibility assessment of these new technologies.
Patients are being enrolled in phase 1 trials.
The Tiara valve
The Tiara valve, a self-expanding prosthesis with bovine pericardial leaflets, is delivered by the transapical route.
Eleven patients underwent Tiara implantation as part of either a Canadian special access registry or an international feasibility trial. Their average Society of Thoracic Surgeons score (ie, their calculated risk of major morbidity or operative mortality) was 15.6%, and their average left ventricular ejection fraction was 29%. Only two patients had degenerative mitral regurgitation. Nine patients had uneventful procedures and demonstrated no residual mitral regurgitation and no left ventricular outflow tract obstruction. The procedure was converted to open surgery in two patients owing to valve malpositioning, and both of them died within 30 days. One patient in whom the procedure was successful suffered erosion of the septum and died on day 4.17
Patients are being enrolled in phase 1 trials.
DEGENERATIVE MITRAL STENOSIS
In patients with degenerative mitral stenosis, extensive mitral annular calcification may provide an adequate “frame” to hold a transcatheter valve prosthesis (Figure 3). Exploiting this feature, numerous investigators have successfully deployed prosthetic valves designed for TAVR in the calcified mitral annulus via the retrograde transapical and antegrade transseptal routes.
Guerrero and colleagues presented results from the first global registry of TMVR in mitral annular calcification at the 2016 EuroPCR Congress.18 Of 104 patients analyzed, almost all received an Edwards’ Sapien balloon-expandable valve (first-generation, Sapien XT, or Sapien 3); the others received Boston Scientific’s Lotus or Direct Flow Medical (Direct Flow Medical, Santa Clara, CA) valves. With an average age of 73 years and a high prevalence of comorbidities such as diabetes, chronic obstructive pulmonary disease, atrial fibrillation, chronic kidney disease, and prior cardiac surgery, the group presented extreme surgical risk, with an average Society of Thoracic Surgeons risk score of 14.4%. Slightly more than 40% of the patients underwent transapical implantation, slightly less than 40% underwent transfemoral or transseptal implantation, and just under 20% had a direct atrial approach.
The implantation was technically successful in 78 of 104 patients (75%); 13 patients (12.5%) required a second mitral valve to be placed, 11 patients (10.5%) had left ventricular outflow tract obstruction, four patients (4%) had valve embolization, and two patients (2%) had left ventricular perforation. At 30 days, 11 of 104 patients (10.6%) had died of cardiac causes and 15 patients (14.4%) had died of noncardiac causes. When divided roughly into three equal groups by chronological order, the last third of patients, compared with the first third of patients, enjoyed greater technical success (80%, n = 32/40 vs 62.5%, n = 20/32), better 30-day survival (85%, n = 34/40 vs 62.5%, n = 20/32), and no conversion to open surgery (0 vs 12.5%, n = 4/32), likely demonstrating both improved patient selection and lessons learned from shared experience. At 1 year, almost 90% of patients had New York Heart Association class I or II symptoms. Prior to the procedure, 91.5% had New York Heart Association class III or IV symptoms.
At present, TMVR in mitral annular calcification is not approved in the United States or elsewhere. However, multiple registries are currently enrolling patients or are in formative stages to push the frontier of the currently available technologies until better, dedicated devices are available for this group of patients.
BIOPROSTHETIC VALVE OR VALVE RING FAILURE
Implantation of a TAVR prosthetic inside a degenerated bioprosthetic mitral valve (valve-in-valve) and mitral valve ring (valve-in-ring) is generally limited to case series with short-term results using the Edwards Sapien series, Boston Scientific Lotus, Medtronic Melody (Medtronic, Minneapolis, MN), and Direct Flow Medical valves (Figure 4).19–23
The largest collective experience was presented in the Valve-in-Valve International Data (VIVID) registry, which included 349 patients who had mitral valve-in-valve placement and 88 patients who had mitral valve-in-ring procedures. Their average age was 74 and the mean Society of Thoracic Surgeons score was 12.9% in both groups.24 Of the 437 patients, 345 patients (78.9%) underwent transapical implantation, and 391 patients (89.5%) received a Sapien XT or Sapien 3 valve. In the valve-in-valve group, 41% of the patients had regurgitation, 25% had stenosis, and 34% had both. In the valve-in-ring group, 60% of the patients had regurgitation, 17% had stenosis, and 23% had both.
Valve placement was successful in most patients. The rate of stroke was low (2.9% with valve-in-valve placement, 1.1% with valve-in-ring placement), though the rate of moderate or greater residual mitral regurgitation was significantly higher in patients undergoing valve-in-ring procedures (14.8% vs 2.6%, P < .001), as was the rate of left ventricular outflow tract obstruction (8% vs 2.6%, P = .03). There was also a trend toward worse 30-day mortality in the valve-in-ring group (11.4% vs 7.7%, P = .15). As with aortic valve-in-valve procedures, small surgical mitral valves (≤ 25 mm) were associated with higher postprocedural gradients.
Eleid and colleagues25 published their experience with antegrade transseptal TMVR in 48 patients with an average Society of Thoracic Surgeons score of 13.2%, 33 of whom underwent valve-in-valve procedures and nine of whom underwent valve-in-ring procedures. (The other six patients underwent mitral valve implantation for severe mitral annular calcification.) In the valve-in-valve group, 31 patients successfully underwent implant procedures, but two patients died during the procedure from left ventricular perforation. Of the nine valve-in-ring patients, two had acute embolization of the valve and were converted to open surgery. Among the seven patients in whom implantation was successful, two developed significant left ventricular outflow tract obstruction; one was treated with surgical resection of the anterior mitral valve leaflet and the other was medically managed.
CONCLUSION
Transcatheter mitral valve replacement in regurgitant mitral valves, failing mitral valve bioprosthetics and rings, and calcified mitral annuli has been effectively conducted in a number of patients who had no surgical options due to prohibitive surgical risk. International registries and our experience have demonstrated that the valve-in-valve procedure using a TAVR prosthesis carries the greatest likelihood of success, given the rigid frame of the surgical bioprosthetic that allows stable valve deployment. While approved in Europe for this indication, use of these devices for this application in the United States is considered “off label” and is performed only in clinically extenuating circumstances. Implantation of TAVR prosthetics in patients with prior mitral ring repair or for native mitral stenosis also has been performed successfully, although left ventricular outflow tract obstruction is a significant risk in this early experience.
Devices designed specifically for TMVR are in their clinical infancy and have been implanted successfully in only small numbers of patients, most of whom had functional mitral regurgitation. Despite reasonable technical success, most of these trials have been plagued by high mortality rates at 30 days in large part due to the extreme risk of the patients in whom these procedures have been conducted. At present, enrollment in TMVR trials for patients with degenerative or functional mitral regurgitation is limited to those without a surgical option and who conform to very specific anatomic criteria.
In the last 10 years, we have seen a revolution in transcatheter therapies for structural heart disease. The most widely embraced, transcatheter aortic valve replacement (TAVR) was originally intended for patients in whom surgery was considered impossible, but it has now been established as an excellent alternative to surgical aortic valve replacement in patients at high or intermediate risk.1–3 As TAVR has become established, with well-designed devices and acceptable safety and efficacy, it has inspired operators and inventors to push the envelope of innovation to transcatheter mitral valve replacement (TMVR).
This review summarizes the newest data available for the TMVR devices currently being tested in patients with native mitral regurgitation, bioprosthetic degeneration, and degenerative mitral stenosis.
THE MITRAL VALVE: THE NEW FRONTIER
Whereas the pathologic mechanisms of aortic stenosis generally all result in the same anatomic consequence (ie, calcification of the valve leaflets and commissures resulting in reduced mobility), mitral valve regurgitation is much more heterogeneous. Primary (degenerative) mitral regurgitation is caused by intrinsic valve pathology such as myxomatous degeneration, chordal detachment, fibroelastic deficiency, endocarditis, and other conditions that prevent the leaflets from coapting properly. In contrast, in secondary or functional mitral regurgitation, the leaflets are normal but do not coapt properly because of apical tethering to a dilated left ventricle, reduced closing forces with left ventricular dysfunction, or annular dilation as the result of either left ventricular or left atrial dilation.
Surgical mitral valve repair is safe and effective in patients with degenerative mitral regurgitation caused by leaflet prolapse and flail. However, some patients cannot undergo surgery because they have comorbid conditions that place them at extreme risk.4 For example, most patients with functional mitral regurgitation due to ischemic or dilated cardiomyopathy have significant surgical risk and multiple comorbidities, and in this group surgical repair has limited efficacy.5 A sizeable proportion of patients with mitral regurgitation may not be offered surgery because their risk is too high.6 Therefore, alternatives to the current surgical treatments have the potential to benefit a large number of patients.
Similarly, many patients with degenerative mitral stenosis caused by calcification of the mitral annulus also cannot undergo cardiac surgery because of prohibitively high risk. While rheumatic disease is the most common cause of mitral stenosis worldwide, degenerative mitral stenosis may be the cause in up to one-fourth of patients overall and up to 60% of patients older than 80 years.7 In the latter group, not only do old age and comorbidities such as diabetes mellitus and chronic kidney disease pose surgical risks, the technical challenge of surgically implanting a prosthetic mitral valve in the setting of a calcified annulus may be significant.8
The mitral valve is, therefore, the perfect new frontier for percutaneous valve replacement therapies, and TMVR is emerging as a potential option for patients with mitral regurgitation and degenerative mitral stenosis. The currently available percutaneous treatment options for mitral regurgitation include edge-to-edge leaflet repair, direct and indirect annuloplasty, spacers, and left ventricular remodeling devices (Table 1).9,10 As surgical mitral valve repair is strongly preferred over mitral valve replacement, the percutaneous procedures and the devices that are used are engineered to approximate the current standard surgical techniques. However, given the complex pathologies involved, surgical repair often requires the use of multiple repair techniques in the same patient. Therefore, percutaneous repair may also require more than one type of device in the same patient and may not be anatomically feasible in many patients. Replacing the entire valve may obviate some of these challenges.
Compared with the aortic valve, the mitral valve poses a greater challenge to percutaneous treatment due to its structure and dynamic relationship with the left ventricle. Some specific challenges facing the development of TMVR are that the mitral valve is large, it is difficult to access, it is asymmetrical, it lacks an anatomically well-defined annulus to which to anchor the replacement valve, its geometry changes throughout the cardiac cycle, and placing a replacement valve in it entails the risk of left ventricular outflow tract obstruction. Despite these challenges, a number of devices are undergoing preclinical testing, a few are in phase 1 clinical trials, and registries are being kept. Depending on the specific device, an antegrade transseptal approach to the mitral valve (via the femoral vein) or a retrograde transapical approach (via direct left ventricular access) may be used (Figure 1).
NATIVE MITRAL VALVE REGURGITATION
For degenerative mitral regurgitation, the standard of care is cardiac surgery at a hospital experienced with mitral valve repair, and with very low rates of mortality and morbidity. For patients in whom the surgical risk is prohibitive, percutaneous edge-to-edge leaflet repair using the MitraClip (Abbott Vascular, Minneapolis, MN) is the best option if the anatomy permits. If the mitral valve pathology is not amenable to MitraClip repair, the patient may be evaluated for TMVR under a clinical trial protocol.
For functional mitral regurgitation, the decisions are more complex. If the patient has chronic atrial fibrillation, electrical cardioversion and antiarrhythmic drug therapy may restore and maintain sinus rhythm, though if the left atrium is large, sinus rhythm may not be possible. If the patient has left ventricular dysfunction, guideline-directed medical therapy should be optimized; this reduces the risk of exacerbations, hospitalizations, and death and may also reduce the degree of regurgitation. If the patient has severe left ventricular dysfunction and a wide QRS duration, cardiac resynchronization therapy (biventricular pacing) may also be beneficial and reduce functional mitral regurgitation. If symptoms and severe functional mitral regurgitation persist despite these measures and the patient’s surgical risk is deemed to be extreme, options include MitraClip placement as part of the randomized Cardiovascular Outcomes Assessment of the MitraClip Percutaneous Therapy (COAPT) trial, which compares guideline-directed medical therapy with guideline-directed therapy plus MitraClip. Another option is enrollment in a clinical trial or registry of TMVR.
At this writing, six TMVR devices have been implanted in humans:
- Fortis (Edwards Lifesciences, Irvine, CA)
- Tendyne (Tendyne Holding Inc, Roseville, MN)
- NaviGate (NaviGate Cardiac Structures, Inc, Lake Forest, CA)
- Intrepid (Medtronic, Minneapolis, MN)
- CardiAQ (Edwards Lifesciences, Irvine, CA)
- Tiara (Neovasc Inc, Richmond, BC).
Most of the early experience with these valves has not yet been published, but some data have been presented at national and international meetings.
The Fortis valve
The Fortis valve consists of a self-expanding nitinol frame and leaflets made of bovine pericardium and is implanted via a transapical approach.
The device was successfully implanted in three patients in Quebec City, Canada, and at 6 months, all had improved significantly in functional class and none had needed to be hospitalized.11 Echocardiographic assessment demonstrated trace or less mitral regurgitation and a mean transvalvular gradient less than 4 mm Hg in all.
Bapat and colleagues12 attempted to implant the device in 13 patients in Europe and Canada. The average left ventricular ejection fraction was 34%, and 12 of 13 patients (92%) had functional mitral regurgitation. Procedural success was achieved in 10 patients, but five patients died within 30 days. While the deaths were due to nonvalvular issues (multiorgan failure, septic shock, intestinal ischemia after failed valve implantation and conversion to open surgery, malnutrition leading to respiratory failure, and valve thrombosis), the trial is currently on hold as more data are collected and reviewed. Among the eight patients who survived the first month, all were still alive at 6 months, and echocardiography demonstrated no or trivial mitral regurgitation in six patients (80%) and mild regurgitation in two patients (20%); the average mitral gradient was 4 mm Hg, and there was no change in mean left ventricular ejection fraction.
The Tendyne valve
The Tendyne valve is a self-expanding prosthesis with porcine pericardial leaflets. It is delivered transapically and is held in place by a tether from the valve to the left ventricular apex.
In the first 12 patients enrolled in an early feasibility trial,13 the average left ventricular ejection fraction was 40%, and 11 of the 12 patients had functional mitral regurgitation. The device was successfully implanted in 11 patients, while one patient developed left ventricular outflow tract obstruction and the device was uneventfully removed. All patients were still alive at 30 days, and the 11 patients who still had a prosthetic valve did not have any residual mitral regurgitation.
As of this writing, almost 80 patients have received the device, though the data have not yet been presented. Patients are being enrolled in phase 1 trials.
The NaviGate valve
The NaviGate valve consists of a trileaflet subassembly fabricated from bovine pericardium, mounted on a self-expanding nitinol stent, and is only implanted transatrially.
NaviGate valves were successfully implanted in two patients via a transatrial approach (Figure 2). Both patients had excellent valve performance without residual mitral regurgitation or left ventricular outflow tract obstruction. The first patient showed significant improvement in functional class and freedom from hospitalization at 6 months, but the second patient died within a week of the implant due to advanced heart failure.14 A US clinical trial is expected soon.
The Intrepid valve
The Intrepid valve consists of an outer stent to provide fixation to the annulus and an inner stent that houses a bovine pericardial valve. The device is a self-expanding system that is delivered transapically.
In a series of 15 patients, 11 had functional mitral regurgitation (with an average left ventricular ejection fraction of 35%) and four had degenerative mitral regurgitation (with an average left ventricular ejection fraction of 57%).15 The device was successfully implanted in 14 patients, after which the average mitral valve gradient was 4 mm Hg. All patients but one were left with no regurgitation (the other patient had 1+ regurgitation).
A trial is currently under way in Europe.
The CardiAQ valve
The CardiAQ is constructed of bovine pericardium and can be delivered by the transseptal or transapical route.
Of 12 patients treated under compassionate use,16 two-thirds (eight patients) had functional mitral regurgitation. Two patients died during the procedure, three died of noncardiac complications within 30 days, and one more died of sepsis shortly after 30 days. This early experience demonstrates the importance of careful patient selection and postprocedural management in the feasibility assessment of these new technologies.
Patients are being enrolled in phase 1 trials.
The Tiara valve
The Tiara valve, a self-expanding prosthesis with bovine pericardial leaflets, is delivered by the transapical route.
Eleven patients underwent Tiara implantation as part of either a Canadian special access registry or an international feasibility trial. Their average Society of Thoracic Surgeons score (ie, their calculated risk of major morbidity or operative mortality) was 15.6%, and their average left ventricular ejection fraction was 29%. Only two patients had degenerative mitral regurgitation. Nine patients had uneventful procedures and demonstrated no residual mitral regurgitation and no left ventricular outflow tract obstruction. The procedure was converted to open surgery in two patients owing to valve malpositioning, and both of them died within 30 days. One patient in whom the procedure was successful suffered erosion of the septum and died on day 4.17
Patients are being enrolled in phase 1 trials.
DEGENERATIVE MITRAL STENOSIS
In patients with degenerative mitral stenosis, extensive mitral annular calcification may provide an adequate “frame” to hold a transcatheter valve prosthesis (Figure 3). Exploiting this feature, numerous investigators have successfully deployed prosthetic valves designed for TAVR in the calcified mitral annulus via the retrograde transapical and antegrade transseptal routes.
Guerrero and colleagues presented results from the first global registry of TMVR in mitral annular calcification at the 2016 EuroPCR Congress.18 Of 104 patients analyzed, almost all received an Edwards’ Sapien balloon-expandable valve (first-generation, Sapien XT, or Sapien 3); the others received Boston Scientific’s Lotus or Direct Flow Medical (Direct Flow Medical, Santa Clara, CA) valves. With an average age of 73 years and a high prevalence of comorbidities such as diabetes, chronic obstructive pulmonary disease, atrial fibrillation, chronic kidney disease, and prior cardiac surgery, the group presented extreme surgical risk, with an average Society of Thoracic Surgeons risk score of 14.4%. Slightly more than 40% of the patients underwent transapical implantation, slightly less than 40% underwent transfemoral or transseptal implantation, and just under 20% had a direct atrial approach.
The implantation was technically successful in 78 of 104 patients (75%); 13 patients (12.5%) required a second mitral valve to be placed, 11 patients (10.5%) had left ventricular outflow tract obstruction, four patients (4%) had valve embolization, and two patients (2%) had left ventricular perforation. At 30 days, 11 of 104 patients (10.6%) had died of cardiac causes and 15 patients (14.4%) had died of noncardiac causes. When divided roughly into three equal groups by chronological order, the last third of patients, compared with the first third of patients, enjoyed greater technical success (80%, n = 32/40 vs 62.5%, n = 20/32), better 30-day survival (85%, n = 34/40 vs 62.5%, n = 20/32), and no conversion to open surgery (0 vs 12.5%, n = 4/32), likely demonstrating both improved patient selection and lessons learned from shared experience. At 1 year, almost 90% of patients had New York Heart Association class I or II symptoms. Prior to the procedure, 91.5% had New York Heart Association class III or IV symptoms.
At present, TMVR in mitral annular calcification is not approved in the United States or elsewhere. However, multiple registries are currently enrolling patients or are in formative stages to push the frontier of the currently available technologies until better, dedicated devices are available for this group of patients.
BIOPROSTHETIC VALVE OR VALVE RING FAILURE
Implantation of a TAVR prosthetic inside a degenerated bioprosthetic mitral valve (valve-in-valve) and mitral valve ring (valve-in-ring) is generally limited to case series with short-term results using the Edwards Sapien series, Boston Scientific Lotus, Medtronic Melody (Medtronic, Minneapolis, MN), and Direct Flow Medical valves (Figure 4).19–23
The largest collective experience was presented in the Valve-in-Valve International Data (VIVID) registry, which included 349 patients who had mitral valve-in-valve placement and 88 patients who had mitral valve-in-ring procedures. Their average age was 74 and the mean Society of Thoracic Surgeons score was 12.9% in both groups.24 Of the 437 patients, 345 patients (78.9%) underwent transapical implantation, and 391 patients (89.5%) received a Sapien XT or Sapien 3 valve. In the valve-in-valve group, 41% of the patients had regurgitation, 25% had stenosis, and 34% had both. In the valve-in-ring group, 60% of the patients had regurgitation, 17% had stenosis, and 23% had both.
Valve placement was successful in most patients. The rate of stroke was low (2.9% with valve-in-valve placement, 1.1% with valve-in-ring placement), though the rate of moderate or greater residual mitral regurgitation was significantly higher in patients undergoing valve-in-ring procedures (14.8% vs 2.6%, P < .001), as was the rate of left ventricular outflow tract obstruction (8% vs 2.6%, P = .03). There was also a trend toward worse 30-day mortality in the valve-in-ring group (11.4% vs 7.7%, P = .15). As with aortic valve-in-valve procedures, small surgical mitral valves (≤ 25 mm) were associated with higher postprocedural gradients.
Eleid and colleagues25 published their experience with antegrade transseptal TMVR in 48 patients with an average Society of Thoracic Surgeons score of 13.2%, 33 of whom underwent valve-in-valve procedures and nine of whom underwent valve-in-ring procedures. (The other six patients underwent mitral valve implantation for severe mitral annular calcification.) In the valve-in-valve group, 31 patients successfully underwent implant procedures, but two patients died during the procedure from left ventricular perforation. Of the nine valve-in-ring patients, two had acute embolization of the valve and were converted to open surgery. Among the seven patients in whom implantation was successful, two developed significant left ventricular outflow tract obstruction; one was treated with surgical resection of the anterior mitral valve leaflet and the other was medically managed.
CONCLUSION
Transcatheter mitral valve replacement in regurgitant mitral valves, failing mitral valve bioprosthetics and rings, and calcified mitral annuli has been effectively conducted in a number of patients who had no surgical options due to prohibitive surgical risk. International registries and our experience have demonstrated that the valve-in-valve procedure using a TAVR prosthesis carries the greatest likelihood of success, given the rigid frame of the surgical bioprosthetic that allows stable valve deployment. While approved in Europe for this indication, use of these devices for this application in the United States is considered “off label” and is performed only in clinically extenuating circumstances. Implantation of TAVR prosthetics in patients with prior mitral ring repair or for native mitral stenosis also has been performed successfully, although left ventricular outflow tract obstruction is a significant risk in this early experience.
Devices designed specifically for TMVR are in their clinical infancy and have been implanted successfully in only small numbers of patients, most of whom had functional mitral regurgitation. Despite reasonable technical success, most of these trials have been plagued by high mortality rates at 30 days in large part due to the extreme risk of the patients in whom these procedures have been conducted. At present, enrollment in TMVR trials for patients with degenerative or functional mitral regurgitation is limited to those without a surgical option and who conform to very specific anatomic criteria.
- Leon MB, Smith CR, Mack M, et al; PARTNER Trial Investigators. Transcatheter aortic-valve implantation for aortic stenosis in patients who cannot undergo surgery. N Engl J Med 2010; 363:1597–1607.
- Smith CR, Leon MB, Mack MJ, et al; PARTNER Trial Investigators. Transcatheter versus surgical aortic-valve replacement in high-risk patients. N Engl J Med 2011; 364:2187–2198.
- Thourani VH, Kodali S, Makkar RR, et al. Transcatheter aortic valve replacement versus surgical valve replacement in intermediate-risk patients: a propensity score analysis. Lancet 2016; 387:2218–2225.
- Goel SS, Bajaj N, Aggarwal B, et al. Prevalence and outcomes of unoperated patients with severe symptomatic mitral regurgitation and heart failure: comprehensive analysis to determine the potential role of MitraClip for this unmet need. J Am Coll Cardiol 2014; 63:185–186.
- DiBardino DJ, ElBardissi AW, McClure RS, Razo-Vasquez OA, Kelly NE, Cohn LH. Four decades of experience with mitral valve repair: analysis of differential indications, technical evolution, and long-term outcome. J Thorac Cardiovasc Surg 2010; 139:76–83; discussion 83–74.
- Mirabel M, Iung B, Baron G, et al. What are the characteristics of patients with severe, symptomatic, mitral regurgitation who are denied surgery? Eur Heart J 2007; 28:1358–1365.
- Iung B, Baron G, Butchart EG, et al. A prospective survey of patients with valvular heart disease in europe: the Euro Heart Survey on Valvular Heart Disease. Eur Heart J 2003; 24:1231–1243.
- Sud K, Agarwal S, Parashar A, et al. Degenerative mitral stenosis: unmet need for percutaneous interventions. Circulation 2016; 133:1594–1604.
- Svensson LG, Ye J, Piemonte TC, Kirker-Head C, Leon MB, Webb JG. Mitral valve regurgitation and left ventricular dysfunction treatment with an intravalvular spacer. J Card Surg 2015; 30:53–54.
- Raman J, Raghavan J, Chandrashekar P, Sugeng L. Can we repair the mitral valve from outside the heart? A novel extra-cardiac approach to functional mitral regurgitation. Heart Lung Circ 2011; 20:157–162.
- Abdul-Jawad Altisent O, Dumont E, Dagenais F, et al. Initial experience of transcatheter mitral valve replacement with a novel transcatheter mitral valve: procedural and 6-month follow-up results. J Am Coll Cardiol 2015; 66:1011–1019.
- Bapat V. FORTIS: design, clinical results, and next steps. Presented at CRT (Cardiovascular Research Technologies) 16; Feburary 20–23, 2016; Washington, DC.
- Sorajja P. Tendyne: technology and clinical results update. Presented at CRT (Cardiovascular Research Technologies) 16; February 20–23, 2016; Washington, DC.
- Navia J. Personal communication.
- Bapat V. Medtronic Intrepid transcatheter mitral valve replacement. Presented at EuroPCR 2015; May 19–22, 2015; Paris, France.
- Herrmann H. Cardiaq-Edwards TMVR. Presented at CRT (Cardiovascular Research Technologies) 16; February 20–23, 2016; Washington, DC.
- Dvir D. Tiara: design, clincal results, and next steps. Presented at CRT (Cardiovascular Research Technologies) 16; February 20–23, 2016; Washington, DC.
- Guerrero M, Dvir D, Himbert D, et al. Transcatheter mitral valve replacement in native mitra valve disease with severe mitral annular calcification: results from the first global registry. JACC Cardiovasc Interv 2016; 9:1361–1371.
- Seiffert M, Franzen O, Conradi L, et al. Series of transcatheter valve-in-valve implantations in high-risk patients with degenerated bioprostheses in aortic and mitral position. Catheter Cardiovasc Interv 2010; 76:608–615.
- Webb JG, Wood DA, Ye J, et al. Transcatheter valve-in-valve implantation for failed bioprosthetic heart valves. Circulation 2010; 121:1848–1857.
- Cerillo AG, Chiaramonti F, Murzi M, et al. Transcatheter valve in valve implantation for failed mitral and tricuspid bioprosthesis. Catheter Cardiovasc Interv 2011; 78:987–995.
- Seiffert M, Conradi L, Baldus S, et al. Transcatheter mitral valve-in-valve implantation in patients with degenerated bioprostheses. JACC Cardiovasc Interv 2012; 5:341–349.
- Wilbring M, Alexiou K, Tugtekin SM, et al. Pushing the limits—further evolutions of transcatheter valve procedures in the mitral position, including valve-in-valve, valve-in-ring, and valve-in-native-ring. J Thorac Cardiovasc Surg 2014; 147:210–219.
- Dvir D, on behalf of the VIVID Registry Investigators. Transcatheter mitral valve-in-valve and valve-in-ring implantations. Transcatheter Valve Therapies 2015.
- Eleid MF, Cabalka AK, Williams MR, et al. Percutaneous transvenous transseptal transcatheter valve implantation in failed bioprosthetic mitral valves, ring annuloplasty, and severe mitral annular calcification. JACC Cardiovasc Interv 2016; 9:1161–1174.
- Leon MB, Smith CR, Mack M, et al; PARTNER Trial Investigators. Transcatheter aortic-valve implantation for aortic stenosis in patients who cannot undergo surgery. N Engl J Med 2010; 363:1597–1607.
- Smith CR, Leon MB, Mack MJ, et al; PARTNER Trial Investigators. Transcatheter versus surgical aortic-valve replacement in high-risk patients. N Engl J Med 2011; 364:2187–2198.
- Thourani VH, Kodali S, Makkar RR, et al. Transcatheter aortic valve replacement versus surgical valve replacement in intermediate-risk patients: a propensity score analysis. Lancet 2016; 387:2218–2225.
- Goel SS, Bajaj N, Aggarwal B, et al. Prevalence and outcomes of unoperated patients with severe symptomatic mitral regurgitation and heart failure: comprehensive analysis to determine the potential role of MitraClip for this unmet need. J Am Coll Cardiol 2014; 63:185–186.
- DiBardino DJ, ElBardissi AW, McClure RS, Razo-Vasquez OA, Kelly NE, Cohn LH. Four decades of experience with mitral valve repair: analysis of differential indications, technical evolution, and long-term outcome. J Thorac Cardiovasc Surg 2010; 139:76–83; discussion 83–74.
- Mirabel M, Iung B, Baron G, et al. What are the characteristics of patients with severe, symptomatic, mitral regurgitation who are denied surgery? Eur Heart J 2007; 28:1358–1365.
- Iung B, Baron G, Butchart EG, et al. A prospective survey of patients with valvular heart disease in europe: the Euro Heart Survey on Valvular Heart Disease. Eur Heart J 2003; 24:1231–1243.
- Sud K, Agarwal S, Parashar A, et al. Degenerative mitral stenosis: unmet need for percutaneous interventions. Circulation 2016; 133:1594–1604.
- Svensson LG, Ye J, Piemonte TC, Kirker-Head C, Leon MB, Webb JG. Mitral valve regurgitation and left ventricular dysfunction treatment with an intravalvular spacer. J Card Surg 2015; 30:53–54.
- Raman J, Raghavan J, Chandrashekar P, Sugeng L. Can we repair the mitral valve from outside the heart? A novel extra-cardiac approach to functional mitral regurgitation. Heart Lung Circ 2011; 20:157–162.
- Abdul-Jawad Altisent O, Dumont E, Dagenais F, et al. Initial experience of transcatheter mitral valve replacement with a novel transcatheter mitral valve: procedural and 6-month follow-up results. J Am Coll Cardiol 2015; 66:1011–1019.
- Bapat V. FORTIS: design, clinical results, and next steps. Presented at CRT (Cardiovascular Research Technologies) 16; Feburary 20–23, 2016; Washington, DC.
- Sorajja P. Tendyne: technology and clinical results update. Presented at CRT (Cardiovascular Research Technologies) 16; February 20–23, 2016; Washington, DC.
- Navia J. Personal communication.
- Bapat V. Medtronic Intrepid transcatheter mitral valve replacement. Presented at EuroPCR 2015; May 19–22, 2015; Paris, France.
- Herrmann H. Cardiaq-Edwards TMVR. Presented at CRT (Cardiovascular Research Technologies) 16; February 20–23, 2016; Washington, DC.
- Dvir D. Tiara: design, clincal results, and next steps. Presented at CRT (Cardiovascular Research Technologies) 16; February 20–23, 2016; Washington, DC.
- Guerrero M, Dvir D, Himbert D, et al. Transcatheter mitral valve replacement in native mitra valve disease with severe mitral annular calcification: results from the first global registry. JACC Cardiovasc Interv 2016; 9:1361–1371.
- Seiffert M, Franzen O, Conradi L, et al. Series of transcatheter valve-in-valve implantations in high-risk patients with degenerated bioprostheses in aortic and mitral position. Catheter Cardiovasc Interv 2010; 76:608–615.
- Webb JG, Wood DA, Ye J, et al. Transcatheter valve-in-valve implantation for failed bioprosthetic heart valves. Circulation 2010; 121:1848–1857.
- Cerillo AG, Chiaramonti F, Murzi M, et al. Transcatheter valve in valve implantation for failed mitral and tricuspid bioprosthesis. Catheter Cardiovasc Interv 2011; 78:987–995.
- Seiffert M, Conradi L, Baldus S, et al. Transcatheter mitral valve-in-valve implantation in patients with degenerated bioprostheses. JACC Cardiovasc Interv 2012; 5:341–349.
- Wilbring M, Alexiou K, Tugtekin SM, et al. Pushing the limits—further evolutions of transcatheter valve procedures in the mitral position, including valve-in-valve, valve-in-ring, and valve-in-native-ring. J Thorac Cardiovasc Surg 2014; 147:210–219.
- Dvir D, on behalf of the VIVID Registry Investigators. Transcatheter mitral valve-in-valve and valve-in-ring implantations. Transcatheter Valve Therapies 2015.
- Eleid MF, Cabalka AK, Williams MR, et al. Percutaneous transvenous transseptal transcatheter valve implantation in failed bioprosthetic mitral valves, ring annuloplasty, and severe mitral annular calcification. JACC Cardiovasc Interv 2016; 9:1161–1174.
KEY POINTS
- Most TMVR procedures are performed by either a retrograde transapical approach or an antegrade transseptal approach.
- In the small number of patients who have undergone TMVR for native mitral valve regurgitation to date, mortality rates at 30 days have been high, reflecting the seriousness of illness in these patients.
- At present, none of the new devices for TMVR in patients with native mitral valve regurgitation are approved for general use, although some of them are being tested in phase 1 clinical trials that are enrolling patients.
- Valves made for TAVR have been used for TMVR in patients with degenerative mitral stenosis or failure of mitral bioprostheses; however, these are off-label uses of these devices.
Understanding the CREST results. Carotid stenting vs surgery: Parsing the risk of stroke and MI
For patients with carotid artery stenosis, percutaneous intervention with stenting is as good as surgery (carotid endarterectomy). This was the major finding of the recently completed Carotid Revascularization Endarterectomy Versus Stenting Trial (CREST)1—with some qualifications.
CREST is the latest in a series of clinical trials of treatment of carotid stenosis that have generated reams of numbers and much debate. The topic of surgery vs percutaneous intervention is a moving target, as techniques evolve and improve. We believe the CREST results are valuable and should help inform decisions about treatment in the “real world.”
In this article, we offer a critical review of CREST, with a careful evaluation of its methods, results, and conclusions.
AN EVOLVING FIELD
Despite improvements in diagnosis and management, stroke remains one of the leading causes of morbidity and death in the United States, with an annual incidence of 780,000 cases and 270,000 deaths.2,3
From 10% to 30% of ischemic strokes are due to emboli from the carotid arteries.4–6 Carotid endarterectomy is an established treatment in selected patients with symptomatic carotid stenosis of 50% or greater or asymptomatic stenosis of 60% or greater.7,8 However, percutaneous techniques such as carotid artery angioplasty with stenting have improved, making them a viable, less invasive option (Figure 1).
Randomized trials of stenting have had mixed results, leading the Centers for Medicare and Medicaid Services (CMS) to adopt strict reimbursement policies. Currently, CMS reimburses for stenting only in symptomatic cases with at least 50% carotid artery stenosis. It also reimburses for stenting in asymptomatic cases in patients at high risk with 80% or greater stenosis, but only if the patients are enrolled in ongoing clinical trials or registries.
CREST compared stenting with endarterectomy and provided important insights into each approach.1
BEFORE CREST
Endarterectomy is superior to medical therapy for symptomatic stenosis
First described in 1953, carotid endarterectomy became the most widely used invasive treatment for significant carotid stenosis.9 Several studies have described patient subsets that benefit from this procedure.
NASCET (the North American Symptomatic Carotid Endarterectomy Trial)10 assigned 2,226 patients with symptomatic stenosis (transient ischemic attack or stroke within the past 180 days) to medical management or endarterectomy.
Surgery was associated with a 65% lower rate of ipsilateral cerebral events in patients with 70% or greater stenosis.10 Surgery was also found to be superior in patients with moderate disease (50% to 69% stenosis), but the difference only approached statistical significance. In patients with stenosis of less than 50%, the outcomes were similar with endarterectomy and medical management.11
ECST (the European Carotid Surgery Trial)12 included a similar population of 3,024 patients. Those with high-grade disease (stenosis ≥ 80%) had significantly better outcomes with endarterectomy, but in those with stenosis less than 70%, surgery was no better than drug therapy.
Comment. NASCET and ECST taught us that endarterectomy is clearly superior to medical therapy in patients with severe symptomatic carotid disease. However, both trials excluded patients at high surgical risk, eg, those with severe coronary artery disease, kidney disease, or heart failure. Additionally, medical management was not aggressive by today’s standards in terms of control of blood pressure and hyperlipidemia, and this could have skewed the results in favor of carotid endarterectomy.
The case for carotid endarterectomy for asymptomatic stenosis
Endarterectomy has also been compared with drug therapy for asymp tomatic carotid artery stenosis in several trials.13–15
ACAS (the Asymptomatic Carotid Atherosclerosis Study)15 assigned 1,662 patients who had no symptoms and had at least 60% carotid artery stenosis to endarterectomy or to medical management, and found a relative risk reduction of 53% in favor of surgery.15
The Veterans Affairs Cooperative Study Group14 corroborated these results in 444 patients with asymptomatic stenosis of greater than 50%. Endarterectomy was associated with a 61% lower risk of transient ischemic attack, transient monocular blindness, or stroke compared with medical therapy. However, there was no statistically significant difference in rates of stroke or death at 30 days.14
ACST (the Asymptomatic Carotid Surgery Trial),13 the largest study to compare carotid endarterectomy with drug therapy for asymptomatic stenosis, randomized 3,120 patients to surgery or drug therapy. The net 5-year risk of stroke was 6.4% with endarterectomy vs 11.8% with drug therapy (P < .0001). The rate of fatal stroke was also lower with endarterectomy: 2.1% vs 4.2% (P = .006).13
Comment. The results of these and other studies of endarterectomy vs medical therapy may not be applicable to current practice, since medical therapy has evolved and the risks with current drug therapy are likely much lower than seen in these trials, some of which began 2 decades ago. Another problem with interpreting these trials is that they excluded surgically “high-risk” patients, which limits the generalizability of the findings to this particular patient population.
The American Heart Association and the American Stroke Association have, on the basis of these trials, recommended carotid endarterectomy in patients with7,8,16:
- Ipsilateral, symptomatic carotid artery stenosis of 70% to 99% (class I, level of evidence A)
- Symptomatic stenosis of 50% to 69%, depending on patient-specific factors such as age, sex, and comorbidities
- High-grade asymptomatic carotid stenosis, if the patients are carefully selected and the surgery is performed by surgeons with procedural morbidity and mortality rates of less than 3% (class I, level of evidence A).
The case for percutaneous intervention
While carotid endarterectomy is proven to be more efficacious than medical management in certain patient subsets, studies favoring surgery over medical therapy have been criticized because they excluded patients with significant comorbidities. In addition, surgery has been associated with significant cardiovascular events, wound complications, and cranial nerve damage, and it requires general anesthesia in most cases.12,17–19 These and other factors spurred the development of less invasive, percutaneous approaches for patients with substantial comorbidities.
So far, several trials have investigated carotid angioplasty with or without stents and with or without devices to capture distal emboli. This interest set the stage for CREST.20,21
Initial attempts at angioplasty without distal protection were not very successful. A meta-analysis of nonrandomized trials that included 714 patients from the initial 13 studies of angioplasty (with or without stenting) and 6,970 patients from 20 studies of carotid endarterectomy found angioplasty to be possibly associated with higher rates of stroke within 30 days of the procedure.20
With improvements in technology, routine use of embolic protection devices, more experience, and better selection of patients, the outcome of carotid stenting has improved. In fact, a meta-analysis comparing stenting without an embolic protection device (26 trials with 2,357 patients) vs stenting with an embolic protection device (11 trials with 839 patients) showed that embolic protection led to significantly better outcomes with fewer strokes—outcomes arguably similar to those of carotid endarterectomy.21
SAPPHIRE (the Stenting and Angioplasty With Protection in Patients at High Risk for Endarterectomy trial)22 was the only completed US trial until CREST that compared carotid artery stenting with distal protection against surgery. It included 334 high-risk patients with either symptomatic stenosis of 50% or greater or asymptomatic stenosis of 80% or greater.
The results suggested that the outcomes with stenting with embolic protection were in fact similar to those of endarterectomy, with possibly fewer complications.23 The benefit persisted up to 2 years.22
The US Food and Drug Administration (FDA), on the basis of these data, approved the use of stenting with distal protection for high-risk patients, and the CMS reimburses for symptomatic stenosis of 50% or greater and for asymptomatic stenosis of 80% or greater as long as the patient is enrolled in a registry.
SPACE (the Stent-Protected Angioplasty Versus Carotid Endarterectomy in Symptomatic Patients trial),24 conducted in Germany, included 1,214 patients with symptomatic stenosis of at least 50%. Results were similar in terms of the combined primary end point of stroke or death at 30 days. However, the results were not similar enough to prove that stenting is not inferior to surgery, according to preset study criteria.
EVA-3S (the Endarterectomy Versus Stenting in Patients With Symptomatic Severe Carotid Stenosis trial),25 in France, evaluated 527 patients with symptomatic carotid disease (stenosis ≥ 60%), but was terminated early due to significantly higher rates of death or stroke at 30 days in the stenting group.
Comment. SPACE and EVA-3S have been widely criticized for not mandating the use of an embolic protection device (used in 27% of cases in SPACE and in 91.9% of cases in EVA-3S). Questions were also raised about the experience level of the operators who performed the carotid stenting: up to 39% of the primary operators involved in stent placement were trainees.26 Also, myocardial infarction (MI), an important complication of carotid endarterectomy, was not included in the primary end point.
ICSS (the International Carotid Stenting Study)27 compared stenting with endarterectomy in 1,713 patients with symptomatic carotid stenosis of greater than 50%. The primary end point was the rate of fatal or disabling stroke at 3 years.
An interim safety analysis at 120 days of follow-up showed the primary end point had occurred in 4.0% of stenting cases vs 3.2% of endarterectomy cases, a difference that was not statistically significant (hazard ratio [HR] 1.28, 95% confidence interval [CI] 0.77–2.11). However, the risk of any stroke was higher with stenting, with a rate of 7.7% vs 4.1% in the surgical group—a statistically significant difference (HR 1.92, 95% CI 1.27–2.89).
In a substudy of ICSS,28 the investigators corroborated these findings, using magnetic resonance imaging to evaluate for new ischemic brain lesions periprocedurally. They found more new ischemic brain lesions in patients who underwent stenting than in patients who underwent surgery—a statistically significant finding.
Comment. ICSS had limitations: eg, it included only patients with symptoms, and the training for the stenting procedure was not standardized. Furthermore, the use of embolic protection devices was not mandated in stenting procedures.
Because of the controversial and incongruous findings of the above trials, there has been much anticipation for further large, appropriately conducted, randomized controlled trials such as CREST.
CREST STUDY DESIGN
CREST was a prospective, multicenter randomized controlled trial with blinded end point adjudication. Assignment to stenting or surgery occurred in a one-to-one fashion, and patients were stratified by medical center and symptomatic status.
Conducted at 108 sites in the United States and nine sites in Canada, CREST was supported by a grant from the National Institutes of Health and by the manufacturer of the catheter and stent delivery and embolic protection systems. The manufacturer’s representative held a nonvoting position on the executive committee and reviewed the manuscript of the results before submission.
CREST included patients with or without symptoms
CREST was initially designed to compare carotid artery stenting vs carotid endarterectomy in patients with symptoms, but enrollment was later extended to patients without symptoms.
Patients with symptoms were included if they had stenosis of at least 50% on angiography, at least 70% on ultrasonography, or at least 70% on computed tomographic angiography or magnetic resonance angiography if stenosis on ultrasonography was 50% to 69%. Carotid artery stenosis was considered symptomatic if the patient had a transient ischemic attack, amaurosis fugax, or minor disabling stroke in the hemisphere supplied by the target vessel within 180 days of randomization.
Patients without symptoms were eligible if they had at least 60% stenosis on angiography, at least 70% stenosis on ultrasonography, or at least 80% stenosis on computed tomographic angiography or magnetic resonance angiography if the stenosis was 50% to 69% on ultrasonography.
Other eligibility criteria included favorable anatomy and clinical stability for both stenting and surgical procedures.
Exclusion criteria were evolving stroke, history of major stroke, chronic or paroxysmal atrial fibrillation on anticoagulation therapy, MI within the previous 30 days, and unstable angina.
Patients received antiplatelet agents
Patients undergoing stenting received aspirin and clopidogrel (Plavix) before and up to 30 days after the procedure. Continuation of antiplatelet therapy was recommended beyond 1 month.
Patients undergoing endarterectomy received aspirin before surgery and continued to receive aspirin for at least 1 year.
Alternatives to aspirin in both groups were ticlopidine (Ticlid), clopidogrel, or aspirin with extended-release dipyridamole (Aggrenox).
End points: Stroke, MI, death
The primary end point was a composite of periprocedural clinical stroke (any type), MI, or death, and of ipsilateral stroke up to 4 years after the procedure. Secondary analyses were also planned for evaluation of treatment modification by age, symptom status, and sex.
Stroke was defined as any acute neurologic ischemic event lasting at least 24 hours with focal signs and symptoms.
Two separate definitions were applied to distinguish major stroke from nonmajor stroke. Major stroke was defined as a National Institutes of Health Stroke Scale (NIHSS) score greater than 9 or records suggesting that the event was a disabling stroke if admitted to another facility. Nonmajor stroke included an event that did not fit these criteria. The stroke review process was initiated with a significant neurologic event, a positive transient ischemia attack or stroke questionnaire, or a two-point or greater increase in the NIHSS score.
MI was defined as a combination of an elevation of cardiac enzymes to at least twice the laboratory upper limit of normal, as well as clinical signs suggesting MI or electrocardiographic evidence of ischemia.29
Stroke was adjudicated by two independent neurologists, and MI was adjudicated by two independent cardiologists blinded to treatment group assignment.
The Rankin scale, the transient ischemic attack and stroke questionnaire, and the Medical Outcomes Survey were also used to assess for disability and quality of life in long-term follow-up.
Intention-to-treat analysis
Intention-to-treat survival analysis was used along with time-to-event statistical modeling with adjustment for major baseline covariates. Differences in outcomes were assessed, and a noninferiority analysis was performed. Kaplan-Meier estimates were constructed of the proportion of patients remaining free of the composite end point at 30 days, 6 months, 1 year, and annually thereafter, and of the associated confidence intervals. The hazard ratios between groups were estimated after adjustment for important covariates.
Most patients enrolled were available for analysis
From December 2000 to July 2008, 2,522 patients were enrolled; 1,271 were assigned to stenting, and 1,251 were assigned to surgery. After randomization, 2.8% of the patients assigned to stenting withdrew consent, 5.7% underwent surgery, and 2.6% were lost to follow-up. Of those assigned to surgery, 5.1% withdrew consent, 1.0% underwent stenting, and 3.8% were lost to follow-up.
A ‘conventional-risk’ patient population
The trial sought to include a “conventional-risk” patient population to make the study more applicable to real-world practice. The mean age was 69 years in both groups. Of the 2,522 patients enrolled:
- 35% were women
- 47% had asymptomatic carotid disease
- 86% had carotid stenosis of 70% or greater
- 86% had hypertension
- 30% had diabetes mellitus
- 83% had hyperlipidemia
- 26% were current smokers
- 42% had a history of cardiovascular disease
- 21% had undergone coronary artery bypass grafting surgery.
The only statistically significant difference in measured baseline variables between the two treatment groups was a slightly higher rate of dyslipidemia in the group undergoing surgery.
The interventionalists and surgeons were highly experienced
Operators performing stenting underwent a lead-in phase of training, with close supervision and scrutiny before eligibility. Of patients undergoing stenting, 96.1% also received an embolic protection device. Antiplatelet therapy was continued in 99% of the patients.
The surgeons performing endarterectomy were experienced and had documented low complication rates. General anesthesia was used in 90% of surgical patients. Shunts were used during surgery in 57%, and patches were used in 62%. After endarterectomy, 91% of the patients received antiplatelet therapy.
CREST STUDY RESULTS: STENTING WAS AS GOOD AS SURGERY
Periprocedural outcomes
- Stroke, MI, or death: 5.2% with stenting vs 4.5% with surgery, HR 1.18, 95% CI 0.82–1.68, P = .38
- Stroke: 4.1% vs 2.3%, HR 1.79, 95% CI 1.14–2.82, P = .01
- MI: 1.1% vs 2.3%, HR 0.50, 95% CI 0.26–0.94, P = .03
- Cranial nerve palsy: 0.3% vs 4.8%, HR 0.07, 95% CI 0.02–0.18, P < .0001 (Table 2).
Outcomes at 4 years
- The primary end point (periprocedural stroke, MI, or death, or ipsilateral stroke within 4 years after the procedure): 7.2% with stenting vs 6.8% with surgery, HR 1.11, 95% CI 0.81–1.51, P = .51. A Kaplan-Meier analysis showed similar findings with statistically similar outcomes (Figure 2).
- Ipsilateral stroke: 2.0% vs 2.4%, HR 0.94, 95% CI 0.50–1.76, P = .85.
The primary outcome was analyzed for interactions of baseline variables, and no effect was detected for symptomatic status or sex. There was a suggestion of an interaction with age, with older patients (over age 70) benefiting more from endarterectomy.
Quality-of-life indices showed that both major and minor strokes were likely to produce long-term physical limitations, with minor stroke associated with worse mental and physical health at 1 year. The effect of periprocedural MI on long-term physical and mental health was less certain. The increased incidence of cranial nerve palsy noted with endarterectomy has been found before and has had no effect on quality of life.
WHAT DO THE CREST FINDINGS MEAN?
CREST is the largest trial to date to compare stenting and surgery. It is an important addition to the literature, not only because of its size, but also because it focused on a real-world patient population. For this reason, its results are more applicable to patients seen in primary care clinics, ie, with peripheral vascular disease, coronary artery disease, diabetes mellitus, hypertension, and smoking.
As noted, previous studies of endarterectomy had strict inclusion and exclusion criteria, which selected against patients at high surgical risk. Therefore, the CREST findings are of greater relevance when comparing stenting and endarterectomy.
Periprocedural and long-term neurologic outcomes
CREST showed similar findings for the composite end point of periprocedural stroke, death, or MI (ie, within 30 days of the procedure) and long-term stroke, establishing similar outcomes in patients undergoing stenting and surgery.
However, an analysis of the individual components of the composite end point showed significant differences between the two treatments. The risk of ipsilateral periprocedural stroke was higher with stenting; these events were defined as nonmajor by NIHSS criteria. The risk of contralateral stroke was similar and low with each treatment.
While the increased risk of periprocedural ipsilateral stroke was not synonymous with an increased risk of major stroke, post hoc analysis showed that any stroke was associated with decreased physical and mental health at 1 year. Therefore, patients who had even a minor stroke did worse from a physical and mental standpoint, a finding that argues for the superiority of surgery in selected patients at risk of periprocedural stroke.
If periprocedural stroke is excluded, the risk of long-term ipsilateral stroke was similar for each treatment, and extremely low (2% for stenting, 2.4% for surgery). Despite this, given the importance of periprocedural minor and major stroke, better predictive models are needed to identify patients at risk of procedural neurologic events. These prediction models will allow better patient selection.
The CREST data and medical therapy
The rates of stroke in this trial were similar to those observed with current medical treatment (approximately 1% per year), especially for patients with asymptomatic disease. Such findings introduce fresh controversy in the necessity of performing either procedure for this patient subset and may lead to further studies evaluating current medical therapy vs intervention.
Periprocedural myocardial infarction
Vascular surgery has long been associated with high cardiovascular risk, especially an increased risk of periprocedural MI.30 Findings from CREST provide further evidence of the risk of MI with endarterectomy in a real-world patient population. Given the evidence of a strong correlation between periprocedural cardiac enzyme elevations and adverse outcomes, the increased incidence of periprocedural MI is worrisome.31 As with risk assessment for periprocedural stroke, better predictive models are needed for patients at risk of cardiovascular events during endarterectomy.
Procedural complications
Carotid endarterectomy entails incisions in the neck with disruption of tissue planes, as opposed to catheter entry site wounds with stenting. The more invasive nature of endarterectomy thus carries a higher risk of wound complications. In fact, in the NASCET trial, the risk of wound complications was 9.3%.10,19 In CREST, surgery carried a higher risk of wound complications compared with stenting (42 vs 0 cases), although stenting involved more periprocedural transfusions, presumably due to retroperitoneal bleeding in four patients.
Use of general anesthesia is also associated with adverse outcomes.17,18 In CREST, 90% of endarterectomy procedures required general anesthesia, whereas none of the stenting procedures required this.
Cranial nerve palsy is an often overlooked but real complication after these procedures. Cranial nerve palsies can lead to vocal, swallowing, and sensory problems that can have a transient or permanent impact on quality of life. In CREST, as in EVA-3S, SAPPHIRE, and ICSS, this risk was substantially higher with surgery,23,25,27 although the long-term consequences of these palsies were not found to affect quality of life at 1 year of follow-up.
HOW CREST FINDINGS COMPARE WITH PREVIOUS STUDIES
Patients in CREST enjoyed overall better outcomes than in previous studies. In earlier trials of surgery vs medical therapy, the rates of adverse outcomes were higher than in CREST. In NASCET, the risk of ipsilateral stroke was 9% with surgery, with 2.5% being fatal or disabling strokes.10 In the ECST, rates of major stroke or death with endarterectomy were 7.0% within 30 days of surgery and 37.0% at a mean follow-up of 6.1 years.12
In earlier studies of surgery vs stenting, outcomes at 30 days were also substantially worse than those in CREST. In the EVA-3S trial, the 30-day incidence of stroke or death was 3.9% after surgery and 9.6% after stenting. These findings were similar at 6 months in EVA-3S, with a 6.1% rate of adverse events after surgery and 11.7% after stenting.25 In the SAPPHIRE trial, the cumulative incidence of stroke and death at 1 year was 21.4% for surgery and 13.6% for stenting.23
Overall, the CREST results show better outcomes than in previous trials. This may be due to improvements in technical aspects of the interventions and to more aggressive drug therapy. Also, because of the high number of patients enrolled in CREST, surgeons and interventionalists were required to meet eligibility criteria, which could have contributed to the improved outcomes.32
CREST was also unique in that stenting was done with an embolic protection device whenever possible, and this also likely had an impact on outcomes.
CREST vs ICSS
CREST and ICSS, published within a few months of each other, seem to have arrived at entirely different conclusions. As both studies are well-designed randomized controlled trials, these distinct results have yielded much controversy. However, closer scrutiny sheds light as to why the results may be different.
While ICSS focused only on patients with symptoms, CREST also included those without symptoms. The difference in patient populations is itself enough to account for the different outcomes.
Also, the interim analysis of ICSS was at 120 days, which makes periprocedural events a more dominant factor in outcomes, whereas these events likely do not last into the long term, as was the case in CREST. Analysis of the ICSS data at a later follow-up date may show results more similar to those of CREST.
The design of ICSS was also different than CREST. In ICSS, the use of an embolic protection device in stenting was not mandated, and the study lacked a lead-in phase of intensive training for those performing stenting. Furthermore, MI was adjudicated only when clinically recognized, which is different than the more rigorous method used in CREST.
Yet despite these differences, CREST and ICSS shed light on a controversial area of carotid stenosis management, and both studies boasted low rates of periprocedural complications. Clinicians should keep in mind the inclusion criteria and the technical specificities of these trials in order to explain to patients the risks and benefits of stenting and surgery, and to arrive at a decision together.
Limitations
The results of CREST should also be reviewed carefully due to a number of limitations. The study began in 2000 with symptomatic patients only, and began enrolling asymptomatic patients in 2005, so that the methodology of the study was changed midway. However, the investigators performed a subgroup analysis to distinguish between outcomes of the symptomatic and the asymptomatic groups and found no statistical interaction for the primary end point based on symptom status.
Despite careful patient selection, many of the predictors of adverse outcomes with stenting, such as lesion length, level of calcification, and lesion location, were not accounted for in the earlier days of enrollment. This may have had an impact on the incidence of stroke in patients enrolled in the early years of the trial. We await the analysis of predictors of perioperative stroke from CREST.
TAKE-HOME POINTS AND FUTURE DIRECTIONS
The CREST findings show that outcomes with stenting are similar to those with surgery in both the short term and the long term, and that the choice of management should be individualized. Each patient’s risk of MI and stroke should be considered based on a variety of factors, including the severity of coronary artery disease, the length of the carotid lesion, the level of calcification, the location of the lesion, and aortic atheroma. The treatment should be selected after also taking into account the patient’s preference and the available expertise, and only after a comprehensive discussion with the patient.
- Brott TG, Hobson RW, Howard G, et al; CREST Investigators. Stenting versus endarterectomy for treatment of carotid-artery stenosis. N Engl J Med 2010; 363:11–23.
- Thom T, Haase N, Rosamond W, et al; American Heart Association Statistics Committee and Stroke Statistics Subcommittee. Heart disease and stroke statistics—2006 update: a report from the American Heart Association Statistics Committee and Stroke Statistics Subcommittee. Circulation 2006; 113:e85–e151.
- Rosamond WD, Folsom AR, Chambless LE, et al. Stroke incidence and survival among middle-aged adults: 9-year follow-up of the Atherosclerosis Risk in Communities (ARIC) cohort. Stroke 1999; 30:736–743.
- Chaturvedi S, Bruno A, Feasby T, et al; Therapeutics and Technology Assessment Subcommittee of the American Academy of Neurology. Carotid endarterectomy—an evidence-based review: report of the Therapeutics and Technology Assessment Subcommittee of the American Academy of Neurology. Neurology 2005; 65:794–801.
- Howell GM, Makaroun MS, Chaer RA. Current management of extracranial carotid occlusive disease. J Am Coll Surg 2009; 208:442–453.
- Barnett HJ, Gunton RW, Eliasziw M, et al. Causes and severity of ischemic stroke in patients with internal carotid artery stenosis. JAMA 2000; 283:1429–1436.
- Biller J, Feinberg WM, Castaldo JE, et al. Guidelines for carotid endarterectomy: a statement for healthcare professionals from a Special Writing Group of the Stroke Council, American Heart Association. Circulation 1998; 97:501–509.
- Goldstein LB, Adams R, Alberts MJ, et al; American Heart Association; American Stroke Association Stroke Council. Primary prevention of ischemic stroke: a guideline from the American Heart Association/American Stroke Association Stroke Council: cosponsored by the Atherosclerotic Peripheral Vascular Disease Interdisciplinary Working Group; Cardiovascular Nursing Council; Clinical Cardiology Council; Nutrition, Physical Activity, and Metabolism Council; and the Quality of Care and Outcomes Research Interdisciplinary Working Group. Circulation 2006; 113:e873–e923.
- Strully KJ, Hurwitt ES, Blankenberg HW. Thrombo-endarterectomy for thrombosis of the internal carotid artery in the neck. J Neurosurg 1953; 10:474–482.
- Beneficial effect of carotid endarterectomy in symptomatic patients with high-grade carotid stenosis. North American Symptomatic Carotid Endarterectomy Trial Collaborators. N Engl J Med 1991; 325:445–453.
- Barnett HJ, Taylor DW, Eliasziw M, et al. Benefit of carotid endarterectomy in patients with symptomatic moderate or severe stenosis. North American Symptomatic Carotid Endarterectomy Trial Collaborators. N Engl J Med 1998; 339:1415–1425.
- Randomised trial of endarterectomy for recently symptomatic carotid stenosis: final results of the MRC European Carotid Surgery Trial (ECST). Lancet 1998; 351:1379–1387.
- Halliday A, Mansfield A, Marro J, et al; MRC Asymptomatic Carotid Surgery Trial (ACST) Collaborative Group. Prevention of disabling and fatal strokes by successful carotid endarterectomy in patients without recent neurological symptoms: randomised controlled trial. Lancet 2004; 363:1491–1502.
- Hobson RW, Weiss DG, Fields WS, et al. Efficacy of carotid endarterectomy for asymptomatic carotid stenosis. The Veterans Affairs Cooperative Study Group. N Engl J Med 1993; 328:221–227.
- Endarterectomy for asymptomatic carotid artery stenosis. Executive Committee for the Asymptomatic Carotid Atherosclerosis Study. JAMA 1995; 273:1421–1428.
- Sacco RL, Adams R, Albers G, et al; American Heart Association/American Stroke Association Council on Stroke; Council on Cardiovascular Radiology and Intervention; American Academy of Neurology. Guidelines for prevention of stroke in patients with ischemic stroke or transient ischemic attack: a statement for healthcare professionals from the American Heart Association/American Stroke Association Council on Stroke: co-sponsored by the Council on Cardiovascular Radiology and Intervention: the American Academy of Neurology affirms the value of this guideline. Circulation 2006; 113:e409–e449.
- Watts K, Lin PH, Bush RL, et al. The impact of anesthetic modality on the outcome of carotid endarterectomy. Am J Surg 2004; 188:741–747.
- Weber CF, Friedl H, Hueppe M, et al. Impact of general versus local anesthesia on early postoperative cognitive dysfunction following carotid endarterectomy: GALA Study Subgroup Analysis. World J Surg 2009; 33:1526–1532.
- Ferguson GG, Eliasziw M, Barr HW, et al. The North American Symptomatic Carotid Endarterectomy Trial: surgical results in 1415 patients. Stroke 1999; 30:1751–1758.
- Golledge J, Mitchell A, Greenhalgh RM, Davies AH. Systematic comparison of the early outcome of angioplasty and endarterectomy for symptomatic carotid artery disease. Stroke 2000; 31:1439–1443.
- Kastrup A, Gröschel K, Krapf H, Brehm BR, Dichgans J, Schulz JB. Early outcome of carotid angioplasty and stenting with and without cerebral protection devices: a systematic review of the literature. Stroke 2003; 34:813–819.
- Gurm HS, Yadav JS, Fayad P, et al; SAPPHIRE Investigators. Long-term results of carotid stenting versus endarterectomy in high-risk patients. N Engl J Med 2008; 358:1572–1579.
- Yadav JS, Wholey MH, Kuntz RE, et al; Stenting and Angioplasty with Protection in Patients at High Risk for Endarterectomy Investigators. Protected carotid-artery stenting versus endarterectomy in high-risk patients. N Engl J Med 2004; 351:1493–1501.
- Eckstein HH, Ringleb P, Allenberg JR, et al. Results of the Stent-Protected Angioplasty versus Carotid Endarterectomy (SPACE) study to treat symptomatic stenoses at 2 years: a multinational, prospective, randomised trial. Lancet Neurol 2008; 7:893–902.
- Mas JL, Chatellier G, Beyssen B, et al; EVA-3S Investigators. Endarterectomy versus stenting in patients with symptomatic severe carotid stenosis. N Engl J Med 2006; 355:1660–1771.
- Roffi M, Sievert H, Gray WA, et al. Carotid artery stenting versus surgery: adequate comparisons? Lancet Neurol 2010; 9:339–341.
- International Carotid Stenting Study Investigators; Ederle J, Dobson J, Featherstone RL, et al. Carotid artery stenting compared with endarterectomy in patients with symptomatic carotid stenosis (International Carotid Stenting Study): an interim analysis of a randomised controlled trial. Lancet 2010; 375:985–997.
- Bonati LH, Jongen LM, Haller S, et al; ICSS-MRI study group. New ischaemic brain lesions on MRI after stenting or endarterectomy for symptomatic carotid stenosis: a sub-study of the International Carotid Stenting Study (ICSS). Lancet Neurol 2010; 9:353–362.
- Sheffet AJ, Roubin G, Howard G, et al. Design of the Carotid Revascularization Endarterectomy vs. Stenting Trial (CREST). Int J Stroke 2010; 5:40–46.
- Fleisher LA, Beckman JA, Brown KA, et al. ACC/AHA 2007 guidelines on perioperative cardiovascular evaluation and care for noncardiac surgery: a report of the American College of Cardiology/American Heart Association Task Force on Practice Guidelines (Writing Committee to Revise the 2002 Guidelines on Perioperative Cardiovascular Evaluation for Noncardiac Surgery) developed in collaboration with the American Society of Echocardiography, American Society of Nuclear Cardiology, Heart Rhythm Society, Society of Cardiovascular Anesthesiologists, Society for Cardiovascular Angiography and Interventions, Society for Vascular Medicine and Biology, and Society for Vascular Surgery. J Am Coll Cardiol 2007; 50:e159–e241.
- Bhatt DL, Topol EJ. Does creatinine kinase-MB elevation after percutaneous coronary intervention predict outcomes in 2005? Periprocedural cardiac enzyme elevation predicts adverse outcomes. Circulation 2005; 112:906–915.
- Hobson RW, Howard VJ, Roubin GS, et al; CREST. Credentialing of surgeons as interventionalists for carotid artery stenting: experience from the lead-in phase of CREST. J Vasc Surg 2004; 40:952–957.
For patients with carotid artery stenosis, percutaneous intervention with stenting is as good as surgery (carotid endarterectomy). This was the major finding of the recently completed Carotid Revascularization Endarterectomy Versus Stenting Trial (CREST)1—with some qualifications.
CREST is the latest in a series of clinical trials of treatment of carotid stenosis that have generated reams of numbers and much debate. The topic of surgery vs percutaneous intervention is a moving target, as techniques evolve and improve. We believe the CREST results are valuable and should help inform decisions about treatment in the “real world.”
In this article, we offer a critical review of CREST, with a careful evaluation of its methods, results, and conclusions.
AN EVOLVING FIELD
Despite improvements in diagnosis and management, stroke remains one of the leading causes of morbidity and death in the United States, with an annual incidence of 780,000 cases and 270,000 deaths.2,3
From 10% to 30% of ischemic strokes are due to emboli from the carotid arteries.4–6 Carotid endarterectomy is an established treatment in selected patients with symptomatic carotid stenosis of 50% or greater or asymptomatic stenosis of 60% or greater.7,8 However, percutaneous techniques such as carotid artery angioplasty with stenting have improved, making them a viable, less invasive option (Figure 1).
Randomized trials of stenting have had mixed results, leading the Centers for Medicare and Medicaid Services (CMS) to adopt strict reimbursement policies. Currently, CMS reimburses for stenting only in symptomatic cases with at least 50% carotid artery stenosis. It also reimburses for stenting in asymptomatic cases in patients at high risk with 80% or greater stenosis, but only if the patients are enrolled in ongoing clinical trials or registries.
CREST compared stenting with endarterectomy and provided important insights into each approach.1
BEFORE CREST
Endarterectomy is superior to medical therapy for symptomatic stenosis
First described in 1953, carotid endarterectomy became the most widely used invasive treatment for significant carotid stenosis.9 Several studies have described patient subsets that benefit from this procedure.
NASCET (the North American Symptomatic Carotid Endarterectomy Trial)10 assigned 2,226 patients with symptomatic stenosis (transient ischemic attack or stroke within the past 180 days) to medical management or endarterectomy.
Surgery was associated with a 65% lower rate of ipsilateral cerebral events in patients with 70% or greater stenosis.10 Surgery was also found to be superior in patients with moderate disease (50% to 69% stenosis), but the difference only approached statistical significance. In patients with stenosis of less than 50%, the outcomes were similar with endarterectomy and medical management.11
ECST (the European Carotid Surgery Trial)12 included a similar population of 3,024 patients. Those with high-grade disease (stenosis ≥ 80%) had significantly better outcomes with endarterectomy, but in those with stenosis less than 70%, surgery was no better than drug therapy.
Comment. NASCET and ECST taught us that endarterectomy is clearly superior to medical therapy in patients with severe symptomatic carotid disease. However, both trials excluded patients at high surgical risk, eg, those with severe coronary artery disease, kidney disease, or heart failure. Additionally, medical management was not aggressive by today’s standards in terms of control of blood pressure and hyperlipidemia, and this could have skewed the results in favor of carotid endarterectomy.
The case for carotid endarterectomy for asymptomatic stenosis
Endarterectomy has also been compared with drug therapy for asymp tomatic carotid artery stenosis in several trials.13–15
ACAS (the Asymptomatic Carotid Atherosclerosis Study)15 assigned 1,662 patients who had no symptoms and had at least 60% carotid artery stenosis to endarterectomy or to medical management, and found a relative risk reduction of 53% in favor of surgery.15
The Veterans Affairs Cooperative Study Group14 corroborated these results in 444 patients with asymptomatic stenosis of greater than 50%. Endarterectomy was associated with a 61% lower risk of transient ischemic attack, transient monocular blindness, or stroke compared with medical therapy. However, there was no statistically significant difference in rates of stroke or death at 30 days.14
ACST (the Asymptomatic Carotid Surgery Trial),13 the largest study to compare carotid endarterectomy with drug therapy for asymptomatic stenosis, randomized 3,120 patients to surgery or drug therapy. The net 5-year risk of stroke was 6.4% with endarterectomy vs 11.8% with drug therapy (P < .0001). The rate of fatal stroke was also lower with endarterectomy: 2.1% vs 4.2% (P = .006).13
Comment. The results of these and other studies of endarterectomy vs medical therapy may not be applicable to current practice, since medical therapy has evolved and the risks with current drug therapy are likely much lower than seen in these trials, some of which began 2 decades ago. Another problem with interpreting these trials is that they excluded surgically “high-risk” patients, which limits the generalizability of the findings to this particular patient population.
The American Heart Association and the American Stroke Association have, on the basis of these trials, recommended carotid endarterectomy in patients with7,8,16:
- Ipsilateral, symptomatic carotid artery stenosis of 70% to 99% (class I, level of evidence A)
- Symptomatic stenosis of 50% to 69%, depending on patient-specific factors such as age, sex, and comorbidities
- High-grade asymptomatic carotid stenosis, if the patients are carefully selected and the surgery is performed by surgeons with procedural morbidity and mortality rates of less than 3% (class I, level of evidence A).
The case for percutaneous intervention
While carotid endarterectomy is proven to be more efficacious than medical management in certain patient subsets, studies favoring surgery over medical therapy have been criticized because they excluded patients with significant comorbidities. In addition, surgery has been associated with significant cardiovascular events, wound complications, and cranial nerve damage, and it requires general anesthesia in most cases.12,17–19 These and other factors spurred the development of less invasive, percutaneous approaches for patients with substantial comorbidities.
So far, several trials have investigated carotid angioplasty with or without stents and with or without devices to capture distal emboli. This interest set the stage for CREST.20,21
Initial attempts at angioplasty without distal protection were not very successful. A meta-analysis of nonrandomized trials that included 714 patients from the initial 13 studies of angioplasty (with or without stenting) and 6,970 patients from 20 studies of carotid endarterectomy found angioplasty to be possibly associated with higher rates of stroke within 30 days of the procedure.20
With improvements in technology, routine use of embolic protection devices, more experience, and better selection of patients, the outcome of carotid stenting has improved. In fact, a meta-analysis comparing stenting without an embolic protection device (26 trials with 2,357 patients) vs stenting with an embolic protection device (11 trials with 839 patients) showed that embolic protection led to significantly better outcomes with fewer strokes—outcomes arguably similar to those of carotid endarterectomy.21
SAPPHIRE (the Stenting and Angioplasty With Protection in Patients at High Risk for Endarterectomy trial)22 was the only completed US trial until CREST that compared carotid artery stenting with distal protection against surgery. It included 334 high-risk patients with either symptomatic stenosis of 50% or greater or asymptomatic stenosis of 80% or greater.
The results suggested that the outcomes with stenting with embolic protection were in fact similar to those of endarterectomy, with possibly fewer complications.23 The benefit persisted up to 2 years.22
The US Food and Drug Administration (FDA), on the basis of these data, approved the use of stenting with distal protection for high-risk patients, and the CMS reimburses for symptomatic stenosis of 50% or greater and for asymptomatic stenosis of 80% or greater as long as the patient is enrolled in a registry.
SPACE (the Stent-Protected Angioplasty Versus Carotid Endarterectomy in Symptomatic Patients trial),24 conducted in Germany, included 1,214 patients with symptomatic stenosis of at least 50%. Results were similar in terms of the combined primary end point of stroke or death at 30 days. However, the results were not similar enough to prove that stenting is not inferior to surgery, according to preset study criteria.
EVA-3S (the Endarterectomy Versus Stenting in Patients With Symptomatic Severe Carotid Stenosis trial),25 in France, evaluated 527 patients with symptomatic carotid disease (stenosis ≥ 60%), but was terminated early due to significantly higher rates of death or stroke at 30 days in the stenting group.
Comment. SPACE and EVA-3S have been widely criticized for not mandating the use of an embolic protection device (used in 27% of cases in SPACE and in 91.9% of cases in EVA-3S). Questions were also raised about the experience level of the operators who performed the carotid stenting: up to 39% of the primary operators involved in stent placement were trainees.26 Also, myocardial infarction (MI), an important complication of carotid endarterectomy, was not included in the primary end point.
ICSS (the International Carotid Stenting Study)27 compared stenting with endarterectomy in 1,713 patients with symptomatic carotid stenosis of greater than 50%. The primary end point was the rate of fatal or disabling stroke at 3 years.
An interim safety analysis at 120 days of follow-up showed the primary end point had occurred in 4.0% of stenting cases vs 3.2% of endarterectomy cases, a difference that was not statistically significant (hazard ratio [HR] 1.28, 95% confidence interval [CI] 0.77–2.11). However, the risk of any stroke was higher with stenting, with a rate of 7.7% vs 4.1% in the surgical group—a statistically significant difference (HR 1.92, 95% CI 1.27–2.89).
In a substudy of ICSS,28 the investigators corroborated these findings, using magnetic resonance imaging to evaluate for new ischemic brain lesions periprocedurally. They found more new ischemic brain lesions in patients who underwent stenting than in patients who underwent surgery—a statistically significant finding.
Comment. ICSS had limitations: eg, it included only patients with symptoms, and the training for the stenting procedure was not standardized. Furthermore, the use of embolic protection devices was not mandated in stenting procedures.
Because of the controversial and incongruous findings of the above trials, there has been much anticipation for further large, appropriately conducted, randomized controlled trials such as CREST.
CREST STUDY DESIGN
CREST was a prospective, multicenter randomized controlled trial with blinded end point adjudication. Assignment to stenting or surgery occurred in a one-to-one fashion, and patients were stratified by medical center and symptomatic status.
Conducted at 108 sites in the United States and nine sites in Canada, CREST was supported by a grant from the National Institutes of Health and by the manufacturer of the catheter and stent delivery and embolic protection systems. The manufacturer’s representative held a nonvoting position on the executive committee and reviewed the manuscript of the results before submission.
CREST included patients with or without symptoms
CREST was initially designed to compare carotid artery stenting vs carotid endarterectomy in patients with symptoms, but enrollment was later extended to patients without symptoms.
Patients with symptoms were included if they had stenosis of at least 50% on angiography, at least 70% on ultrasonography, or at least 70% on computed tomographic angiography or magnetic resonance angiography if stenosis on ultrasonography was 50% to 69%. Carotid artery stenosis was considered symptomatic if the patient had a transient ischemic attack, amaurosis fugax, or minor disabling stroke in the hemisphere supplied by the target vessel within 180 days of randomization.
Patients without symptoms were eligible if they had at least 60% stenosis on angiography, at least 70% stenosis on ultrasonography, or at least 80% stenosis on computed tomographic angiography or magnetic resonance angiography if the stenosis was 50% to 69% on ultrasonography.
Other eligibility criteria included favorable anatomy and clinical stability for both stenting and surgical procedures.
Exclusion criteria were evolving stroke, history of major stroke, chronic or paroxysmal atrial fibrillation on anticoagulation therapy, MI within the previous 30 days, and unstable angina.
Patients received antiplatelet agents
Patients undergoing stenting received aspirin and clopidogrel (Plavix) before and up to 30 days after the procedure. Continuation of antiplatelet therapy was recommended beyond 1 month.
Patients undergoing endarterectomy received aspirin before surgery and continued to receive aspirin for at least 1 year.
Alternatives to aspirin in both groups were ticlopidine (Ticlid), clopidogrel, or aspirin with extended-release dipyridamole (Aggrenox).
End points: Stroke, MI, death
The primary end point was a composite of periprocedural clinical stroke (any type), MI, or death, and of ipsilateral stroke up to 4 years after the procedure. Secondary analyses were also planned for evaluation of treatment modification by age, symptom status, and sex.
Stroke was defined as any acute neurologic ischemic event lasting at least 24 hours with focal signs and symptoms.
Two separate definitions were applied to distinguish major stroke from nonmajor stroke. Major stroke was defined as a National Institutes of Health Stroke Scale (NIHSS) score greater than 9 or records suggesting that the event was a disabling stroke if admitted to another facility. Nonmajor stroke included an event that did not fit these criteria. The stroke review process was initiated with a significant neurologic event, a positive transient ischemia attack or stroke questionnaire, or a two-point or greater increase in the NIHSS score.
MI was defined as a combination of an elevation of cardiac enzymes to at least twice the laboratory upper limit of normal, as well as clinical signs suggesting MI or electrocardiographic evidence of ischemia.29
Stroke was adjudicated by two independent neurologists, and MI was adjudicated by two independent cardiologists blinded to treatment group assignment.
The Rankin scale, the transient ischemic attack and stroke questionnaire, and the Medical Outcomes Survey were also used to assess for disability and quality of life in long-term follow-up.
Intention-to-treat analysis
Intention-to-treat survival analysis was used along with time-to-event statistical modeling with adjustment for major baseline covariates. Differences in outcomes were assessed, and a noninferiority analysis was performed. Kaplan-Meier estimates were constructed of the proportion of patients remaining free of the composite end point at 30 days, 6 months, 1 year, and annually thereafter, and of the associated confidence intervals. The hazard ratios between groups were estimated after adjustment for important covariates.
Most patients enrolled were available for analysis
From December 2000 to July 2008, 2,522 patients were enrolled; 1,271 were assigned to stenting, and 1,251 were assigned to surgery. After randomization, 2.8% of the patients assigned to stenting withdrew consent, 5.7% underwent surgery, and 2.6% were lost to follow-up. Of those assigned to surgery, 5.1% withdrew consent, 1.0% underwent stenting, and 3.8% were lost to follow-up.
A ‘conventional-risk’ patient population
The trial sought to include a “conventional-risk” patient population to make the study more applicable to real-world practice. The mean age was 69 years in both groups. Of the 2,522 patients enrolled:
- 35% were women
- 47% had asymptomatic carotid disease
- 86% had carotid stenosis of 70% or greater
- 86% had hypertension
- 30% had diabetes mellitus
- 83% had hyperlipidemia
- 26% were current smokers
- 42% had a history of cardiovascular disease
- 21% had undergone coronary artery bypass grafting surgery.
The only statistically significant difference in measured baseline variables between the two treatment groups was a slightly higher rate of dyslipidemia in the group undergoing surgery.
The interventionalists and surgeons were highly experienced
Operators performing stenting underwent a lead-in phase of training, with close supervision and scrutiny before eligibility. Of patients undergoing stenting, 96.1% also received an embolic protection device. Antiplatelet therapy was continued in 99% of the patients.
The surgeons performing endarterectomy were experienced and had documented low complication rates. General anesthesia was used in 90% of surgical patients. Shunts were used during surgery in 57%, and patches were used in 62%. After endarterectomy, 91% of the patients received antiplatelet therapy.
CREST STUDY RESULTS: STENTING WAS AS GOOD AS SURGERY
Periprocedural outcomes
- Stroke, MI, or death: 5.2% with stenting vs 4.5% with surgery, HR 1.18, 95% CI 0.82–1.68, P = .38
- Stroke: 4.1% vs 2.3%, HR 1.79, 95% CI 1.14–2.82, P = .01
- MI: 1.1% vs 2.3%, HR 0.50, 95% CI 0.26–0.94, P = .03
- Cranial nerve palsy: 0.3% vs 4.8%, HR 0.07, 95% CI 0.02–0.18, P < .0001 (Table 2).
Outcomes at 4 years
- The primary end point (periprocedural stroke, MI, or death, or ipsilateral stroke within 4 years after the procedure): 7.2% with stenting vs 6.8% with surgery, HR 1.11, 95% CI 0.81–1.51, P = .51. A Kaplan-Meier analysis showed similar findings with statistically similar outcomes (Figure 2).
- Ipsilateral stroke: 2.0% vs 2.4%, HR 0.94, 95% CI 0.50–1.76, P = .85.
The primary outcome was analyzed for interactions of baseline variables, and no effect was detected for symptomatic status or sex. There was a suggestion of an interaction with age, with older patients (over age 70) benefiting more from endarterectomy.
Quality-of-life indices showed that both major and minor strokes were likely to produce long-term physical limitations, with minor stroke associated with worse mental and physical health at 1 year. The effect of periprocedural MI on long-term physical and mental health was less certain. The increased incidence of cranial nerve palsy noted with endarterectomy has been found before and has had no effect on quality of life.
WHAT DO THE CREST FINDINGS MEAN?
CREST is the largest trial to date to compare stenting and surgery. It is an important addition to the literature, not only because of its size, but also because it focused on a real-world patient population. For this reason, its results are more applicable to patients seen in primary care clinics, ie, with peripheral vascular disease, coronary artery disease, diabetes mellitus, hypertension, and smoking.
As noted, previous studies of endarterectomy had strict inclusion and exclusion criteria, which selected against patients at high surgical risk. Therefore, the CREST findings are of greater relevance when comparing stenting and endarterectomy.
Periprocedural and long-term neurologic outcomes
CREST showed similar findings for the composite end point of periprocedural stroke, death, or MI (ie, within 30 days of the procedure) and long-term stroke, establishing similar outcomes in patients undergoing stenting and surgery.
However, an analysis of the individual components of the composite end point showed significant differences between the two treatments. The risk of ipsilateral periprocedural stroke was higher with stenting; these events were defined as nonmajor by NIHSS criteria. The risk of contralateral stroke was similar and low with each treatment.
While the increased risk of periprocedural ipsilateral stroke was not synonymous with an increased risk of major stroke, post hoc analysis showed that any stroke was associated with decreased physical and mental health at 1 year. Therefore, patients who had even a minor stroke did worse from a physical and mental standpoint, a finding that argues for the superiority of surgery in selected patients at risk of periprocedural stroke.
If periprocedural stroke is excluded, the risk of long-term ipsilateral stroke was similar for each treatment, and extremely low (2% for stenting, 2.4% for surgery). Despite this, given the importance of periprocedural minor and major stroke, better predictive models are needed to identify patients at risk of procedural neurologic events. These prediction models will allow better patient selection.
The CREST data and medical therapy
The rates of stroke in this trial were similar to those observed with current medical treatment (approximately 1% per year), especially for patients with asymptomatic disease. Such findings introduce fresh controversy in the necessity of performing either procedure for this patient subset and may lead to further studies evaluating current medical therapy vs intervention.
Periprocedural myocardial infarction
Vascular surgery has long been associated with high cardiovascular risk, especially an increased risk of periprocedural MI.30 Findings from CREST provide further evidence of the risk of MI with endarterectomy in a real-world patient population. Given the evidence of a strong correlation between periprocedural cardiac enzyme elevations and adverse outcomes, the increased incidence of periprocedural MI is worrisome.31 As with risk assessment for periprocedural stroke, better predictive models are needed for patients at risk of cardiovascular events during endarterectomy.
Procedural complications
Carotid endarterectomy entails incisions in the neck with disruption of tissue planes, as opposed to catheter entry site wounds with stenting. The more invasive nature of endarterectomy thus carries a higher risk of wound complications. In fact, in the NASCET trial, the risk of wound complications was 9.3%.10,19 In CREST, surgery carried a higher risk of wound complications compared with stenting (42 vs 0 cases), although stenting involved more periprocedural transfusions, presumably due to retroperitoneal bleeding in four patients.
Use of general anesthesia is also associated with adverse outcomes.17,18 In CREST, 90% of endarterectomy procedures required general anesthesia, whereas none of the stenting procedures required this.
Cranial nerve palsy is an often overlooked but real complication after these procedures. Cranial nerve palsies can lead to vocal, swallowing, and sensory problems that can have a transient or permanent impact on quality of life. In CREST, as in EVA-3S, SAPPHIRE, and ICSS, this risk was substantially higher with surgery,23,25,27 although the long-term consequences of these palsies were not found to affect quality of life at 1 year of follow-up.
HOW CREST FINDINGS COMPARE WITH PREVIOUS STUDIES
Patients in CREST enjoyed overall better outcomes than in previous studies. In earlier trials of surgery vs medical therapy, the rates of adverse outcomes were higher than in CREST. In NASCET, the risk of ipsilateral stroke was 9% with surgery, with 2.5% being fatal or disabling strokes.10 In the ECST, rates of major stroke or death with endarterectomy were 7.0% within 30 days of surgery and 37.0% at a mean follow-up of 6.1 years.12
In earlier studies of surgery vs stenting, outcomes at 30 days were also substantially worse than those in CREST. In the EVA-3S trial, the 30-day incidence of stroke or death was 3.9% after surgery and 9.6% after stenting. These findings were similar at 6 months in EVA-3S, with a 6.1% rate of adverse events after surgery and 11.7% after stenting.25 In the SAPPHIRE trial, the cumulative incidence of stroke and death at 1 year was 21.4% for surgery and 13.6% for stenting.23
Overall, the CREST results show better outcomes than in previous trials. This may be due to improvements in technical aspects of the interventions and to more aggressive drug therapy. Also, because of the high number of patients enrolled in CREST, surgeons and interventionalists were required to meet eligibility criteria, which could have contributed to the improved outcomes.32
CREST was also unique in that stenting was done with an embolic protection device whenever possible, and this also likely had an impact on outcomes.
CREST vs ICSS
CREST and ICSS, published within a few months of each other, seem to have arrived at entirely different conclusions. As both studies are well-designed randomized controlled trials, these distinct results have yielded much controversy. However, closer scrutiny sheds light as to why the results may be different.
While ICSS focused only on patients with symptoms, CREST also included those without symptoms. The difference in patient populations is itself enough to account for the different outcomes.
Also, the interim analysis of ICSS was at 120 days, which makes periprocedural events a more dominant factor in outcomes, whereas these events likely do not last into the long term, as was the case in CREST. Analysis of the ICSS data at a later follow-up date may show results more similar to those of CREST.
The design of ICSS was also different than CREST. In ICSS, the use of an embolic protection device in stenting was not mandated, and the study lacked a lead-in phase of intensive training for those performing stenting. Furthermore, MI was adjudicated only when clinically recognized, which is different than the more rigorous method used in CREST.
Yet despite these differences, CREST and ICSS shed light on a controversial area of carotid stenosis management, and both studies boasted low rates of periprocedural complications. Clinicians should keep in mind the inclusion criteria and the technical specificities of these trials in order to explain to patients the risks and benefits of stenting and surgery, and to arrive at a decision together.
Limitations
The results of CREST should also be reviewed carefully due to a number of limitations. The study began in 2000 with symptomatic patients only, and began enrolling asymptomatic patients in 2005, so that the methodology of the study was changed midway. However, the investigators performed a subgroup analysis to distinguish between outcomes of the symptomatic and the asymptomatic groups and found no statistical interaction for the primary end point based on symptom status.
Despite careful patient selection, many of the predictors of adverse outcomes with stenting, such as lesion length, level of calcification, and lesion location, were not accounted for in the earlier days of enrollment. This may have had an impact on the incidence of stroke in patients enrolled in the early years of the trial. We await the analysis of predictors of perioperative stroke from CREST.
TAKE-HOME POINTS AND FUTURE DIRECTIONS
The CREST findings show that outcomes with stenting are similar to those with surgery in both the short term and the long term, and that the choice of management should be individualized. Each patient’s risk of MI and stroke should be considered based on a variety of factors, including the severity of coronary artery disease, the length of the carotid lesion, the level of calcification, the location of the lesion, and aortic atheroma. The treatment should be selected after also taking into account the patient’s preference and the available expertise, and only after a comprehensive discussion with the patient.
For patients with carotid artery stenosis, percutaneous intervention with stenting is as good as surgery (carotid endarterectomy). This was the major finding of the recently completed Carotid Revascularization Endarterectomy Versus Stenting Trial (CREST)1—with some qualifications.
CREST is the latest in a series of clinical trials of treatment of carotid stenosis that have generated reams of numbers and much debate. The topic of surgery vs percutaneous intervention is a moving target, as techniques evolve and improve. We believe the CREST results are valuable and should help inform decisions about treatment in the “real world.”
In this article, we offer a critical review of CREST, with a careful evaluation of its methods, results, and conclusions.
AN EVOLVING FIELD
Despite improvements in diagnosis and management, stroke remains one of the leading causes of morbidity and death in the United States, with an annual incidence of 780,000 cases and 270,000 deaths.2,3
From 10% to 30% of ischemic strokes are due to emboli from the carotid arteries.4–6 Carotid endarterectomy is an established treatment in selected patients with symptomatic carotid stenosis of 50% or greater or asymptomatic stenosis of 60% or greater.7,8 However, percutaneous techniques such as carotid artery angioplasty with stenting have improved, making them a viable, less invasive option (Figure 1).
Randomized trials of stenting have had mixed results, leading the Centers for Medicare and Medicaid Services (CMS) to adopt strict reimbursement policies. Currently, CMS reimburses for stenting only in symptomatic cases with at least 50% carotid artery stenosis. It also reimburses for stenting in asymptomatic cases in patients at high risk with 80% or greater stenosis, but only if the patients are enrolled in ongoing clinical trials or registries.
CREST compared stenting with endarterectomy and provided important insights into each approach.1
BEFORE CREST
Endarterectomy is superior to medical therapy for symptomatic stenosis
First described in 1953, carotid endarterectomy became the most widely used invasive treatment for significant carotid stenosis.9 Several studies have described patient subsets that benefit from this procedure.
NASCET (the North American Symptomatic Carotid Endarterectomy Trial)10 assigned 2,226 patients with symptomatic stenosis (transient ischemic attack or stroke within the past 180 days) to medical management or endarterectomy.
Surgery was associated with a 65% lower rate of ipsilateral cerebral events in patients with 70% or greater stenosis.10 Surgery was also found to be superior in patients with moderate disease (50% to 69% stenosis), but the difference only approached statistical significance. In patients with stenosis of less than 50%, the outcomes were similar with endarterectomy and medical management.11
ECST (the European Carotid Surgery Trial)12 included a similar population of 3,024 patients. Those with high-grade disease (stenosis ≥ 80%) had significantly better outcomes with endarterectomy, but in those with stenosis less than 70%, surgery was no better than drug therapy.
Comment. NASCET and ECST taught us that endarterectomy is clearly superior to medical therapy in patients with severe symptomatic carotid disease. However, both trials excluded patients at high surgical risk, eg, those with severe coronary artery disease, kidney disease, or heart failure. Additionally, medical management was not aggressive by today’s standards in terms of control of blood pressure and hyperlipidemia, and this could have skewed the results in favor of carotid endarterectomy.
The case for carotid endarterectomy for asymptomatic stenosis
Endarterectomy has also been compared with drug therapy for asymp tomatic carotid artery stenosis in several trials.13–15
ACAS (the Asymptomatic Carotid Atherosclerosis Study)15 assigned 1,662 patients who had no symptoms and had at least 60% carotid artery stenosis to endarterectomy or to medical management, and found a relative risk reduction of 53% in favor of surgery.15
The Veterans Affairs Cooperative Study Group14 corroborated these results in 444 patients with asymptomatic stenosis of greater than 50%. Endarterectomy was associated with a 61% lower risk of transient ischemic attack, transient monocular blindness, or stroke compared with medical therapy. However, there was no statistically significant difference in rates of stroke or death at 30 days.14
ACST (the Asymptomatic Carotid Surgery Trial),13 the largest study to compare carotid endarterectomy with drug therapy for asymptomatic stenosis, randomized 3,120 patients to surgery or drug therapy. The net 5-year risk of stroke was 6.4% with endarterectomy vs 11.8% with drug therapy (P < .0001). The rate of fatal stroke was also lower with endarterectomy: 2.1% vs 4.2% (P = .006).13
Comment. The results of these and other studies of endarterectomy vs medical therapy may not be applicable to current practice, since medical therapy has evolved and the risks with current drug therapy are likely much lower than seen in these trials, some of which began 2 decades ago. Another problem with interpreting these trials is that they excluded surgically “high-risk” patients, which limits the generalizability of the findings to this particular patient population.
The American Heart Association and the American Stroke Association have, on the basis of these trials, recommended carotid endarterectomy in patients with7,8,16:
- Ipsilateral, symptomatic carotid artery stenosis of 70% to 99% (class I, level of evidence A)
- Symptomatic stenosis of 50% to 69%, depending on patient-specific factors such as age, sex, and comorbidities
- High-grade asymptomatic carotid stenosis, if the patients are carefully selected and the surgery is performed by surgeons with procedural morbidity and mortality rates of less than 3% (class I, level of evidence A).
The case for percutaneous intervention
While carotid endarterectomy is proven to be more efficacious than medical management in certain patient subsets, studies favoring surgery over medical therapy have been criticized because they excluded patients with significant comorbidities. In addition, surgery has been associated with significant cardiovascular events, wound complications, and cranial nerve damage, and it requires general anesthesia in most cases.12,17–19 These and other factors spurred the development of less invasive, percutaneous approaches for patients with substantial comorbidities.
So far, several trials have investigated carotid angioplasty with or without stents and with or without devices to capture distal emboli. This interest set the stage for CREST.20,21
Initial attempts at angioplasty without distal protection were not very successful. A meta-analysis of nonrandomized trials that included 714 patients from the initial 13 studies of angioplasty (with or without stenting) and 6,970 patients from 20 studies of carotid endarterectomy found angioplasty to be possibly associated with higher rates of stroke within 30 days of the procedure.20
With improvements in technology, routine use of embolic protection devices, more experience, and better selection of patients, the outcome of carotid stenting has improved. In fact, a meta-analysis comparing stenting without an embolic protection device (26 trials with 2,357 patients) vs stenting with an embolic protection device (11 trials with 839 patients) showed that embolic protection led to significantly better outcomes with fewer strokes—outcomes arguably similar to those of carotid endarterectomy.21
SAPPHIRE (the Stenting and Angioplasty With Protection in Patients at High Risk for Endarterectomy trial)22 was the only completed US trial until CREST that compared carotid artery stenting with distal protection against surgery. It included 334 high-risk patients with either symptomatic stenosis of 50% or greater or asymptomatic stenosis of 80% or greater.
The results suggested that the outcomes with stenting with embolic protection were in fact similar to those of endarterectomy, with possibly fewer complications.23 The benefit persisted up to 2 years.22
The US Food and Drug Administration (FDA), on the basis of these data, approved the use of stenting with distal protection for high-risk patients, and the CMS reimburses for symptomatic stenosis of 50% or greater and for asymptomatic stenosis of 80% or greater as long as the patient is enrolled in a registry.
SPACE (the Stent-Protected Angioplasty Versus Carotid Endarterectomy in Symptomatic Patients trial),24 conducted in Germany, included 1,214 patients with symptomatic stenosis of at least 50%. Results were similar in terms of the combined primary end point of stroke or death at 30 days. However, the results were not similar enough to prove that stenting is not inferior to surgery, according to preset study criteria.
EVA-3S (the Endarterectomy Versus Stenting in Patients With Symptomatic Severe Carotid Stenosis trial),25 in France, evaluated 527 patients with symptomatic carotid disease (stenosis ≥ 60%), but was terminated early due to significantly higher rates of death or stroke at 30 days in the stenting group.
Comment. SPACE and EVA-3S have been widely criticized for not mandating the use of an embolic protection device (used in 27% of cases in SPACE and in 91.9% of cases in EVA-3S). Questions were also raised about the experience level of the operators who performed the carotid stenting: up to 39% of the primary operators involved in stent placement were trainees.26 Also, myocardial infarction (MI), an important complication of carotid endarterectomy, was not included in the primary end point.
ICSS (the International Carotid Stenting Study)27 compared stenting with endarterectomy in 1,713 patients with symptomatic carotid stenosis of greater than 50%. The primary end point was the rate of fatal or disabling stroke at 3 years.
An interim safety analysis at 120 days of follow-up showed the primary end point had occurred in 4.0% of stenting cases vs 3.2% of endarterectomy cases, a difference that was not statistically significant (hazard ratio [HR] 1.28, 95% confidence interval [CI] 0.77–2.11). However, the risk of any stroke was higher with stenting, with a rate of 7.7% vs 4.1% in the surgical group—a statistically significant difference (HR 1.92, 95% CI 1.27–2.89).
In a substudy of ICSS,28 the investigators corroborated these findings, using magnetic resonance imaging to evaluate for new ischemic brain lesions periprocedurally. They found more new ischemic brain lesions in patients who underwent stenting than in patients who underwent surgery—a statistically significant finding.
Comment. ICSS had limitations: eg, it included only patients with symptoms, and the training for the stenting procedure was not standardized. Furthermore, the use of embolic protection devices was not mandated in stenting procedures.
Because of the controversial and incongruous findings of the above trials, there has been much anticipation for further large, appropriately conducted, randomized controlled trials such as CREST.
CREST STUDY DESIGN
CREST was a prospective, multicenter randomized controlled trial with blinded end point adjudication. Assignment to stenting or surgery occurred in a one-to-one fashion, and patients were stratified by medical center and symptomatic status.
Conducted at 108 sites in the United States and nine sites in Canada, CREST was supported by a grant from the National Institutes of Health and by the manufacturer of the catheter and stent delivery and embolic protection systems. The manufacturer’s representative held a nonvoting position on the executive committee and reviewed the manuscript of the results before submission.
CREST included patients with or without symptoms
CREST was initially designed to compare carotid artery stenting vs carotid endarterectomy in patients with symptoms, but enrollment was later extended to patients without symptoms.
Patients with symptoms were included if they had stenosis of at least 50% on angiography, at least 70% on ultrasonography, or at least 70% on computed tomographic angiography or magnetic resonance angiography if stenosis on ultrasonography was 50% to 69%. Carotid artery stenosis was considered symptomatic if the patient had a transient ischemic attack, amaurosis fugax, or minor disabling stroke in the hemisphere supplied by the target vessel within 180 days of randomization.
Patients without symptoms were eligible if they had at least 60% stenosis on angiography, at least 70% stenosis on ultrasonography, or at least 80% stenosis on computed tomographic angiography or magnetic resonance angiography if the stenosis was 50% to 69% on ultrasonography.
Other eligibility criteria included favorable anatomy and clinical stability for both stenting and surgical procedures.
Exclusion criteria were evolving stroke, history of major stroke, chronic or paroxysmal atrial fibrillation on anticoagulation therapy, MI within the previous 30 days, and unstable angina.
Patients received antiplatelet agents
Patients undergoing stenting received aspirin and clopidogrel (Plavix) before and up to 30 days after the procedure. Continuation of antiplatelet therapy was recommended beyond 1 month.
Patients undergoing endarterectomy received aspirin before surgery and continued to receive aspirin for at least 1 year.
Alternatives to aspirin in both groups were ticlopidine (Ticlid), clopidogrel, or aspirin with extended-release dipyridamole (Aggrenox).
End points: Stroke, MI, death
The primary end point was a composite of periprocedural clinical stroke (any type), MI, or death, and of ipsilateral stroke up to 4 years after the procedure. Secondary analyses were also planned for evaluation of treatment modification by age, symptom status, and sex.
Stroke was defined as any acute neurologic ischemic event lasting at least 24 hours with focal signs and symptoms.
Two separate definitions were applied to distinguish major stroke from nonmajor stroke. Major stroke was defined as a National Institutes of Health Stroke Scale (NIHSS) score greater than 9 or records suggesting that the event was a disabling stroke if admitted to another facility. Nonmajor stroke included an event that did not fit these criteria. The stroke review process was initiated with a significant neurologic event, a positive transient ischemia attack or stroke questionnaire, or a two-point or greater increase in the NIHSS score.
MI was defined as a combination of an elevation of cardiac enzymes to at least twice the laboratory upper limit of normal, as well as clinical signs suggesting MI or electrocardiographic evidence of ischemia.29
Stroke was adjudicated by two independent neurologists, and MI was adjudicated by two independent cardiologists blinded to treatment group assignment.
The Rankin scale, the transient ischemic attack and stroke questionnaire, and the Medical Outcomes Survey were also used to assess for disability and quality of life in long-term follow-up.
Intention-to-treat analysis
Intention-to-treat survival analysis was used along with time-to-event statistical modeling with adjustment for major baseline covariates. Differences in outcomes were assessed, and a noninferiority analysis was performed. Kaplan-Meier estimates were constructed of the proportion of patients remaining free of the composite end point at 30 days, 6 months, 1 year, and annually thereafter, and of the associated confidence intervals. The hazard ratios between groups were estimated after adjustment for important covariates.
Most patients enrolled were available for analysis
From December 2000 to July 2008, 2,522 patients were enrolled; 1,271 were assigned to stenting, and 1,251 were assigned to surgery. After randomization, 2.8% of the patients assigned to stenting withdrew consent, 5.7% underwent surgery, and 2.6% were lost to follow-up. Of those assigned to surgery, 5.1% withdrew consent, 1.0% underwent stenting, and 3.8% were lost to follow-up.
A ‘conventional-risk’ patient population
The trial sought to include a “conventional-risk” patient population to make the study more applicable to real-world practice. The mean age was 69 years in both groups. Of the 2,522 patients enrolled:
- 35% were women
- 47% had asymptomatic carotid disease
- 86% had carotid stenosis of 70% or greater
- 86% had hypertension
- 30% had diabetes mellitus
- 83% had hyperlipidemia
- 26% were current smokers
- 42% had a history of cardiovascular disease
- 21% had undergone coronary artery bypass grafting surgery.
The only statistically significant difference in measured baseline variables between the two treatment groups was a slightly higher rate of dyslipidemia in the group undergoing surgery.
The interventionalists and surgeons were highly experienced
Operators performing stenting underwent a lead-in phase of training, with close supervision and scrutiny before eligibility. Of patients undergoing stenting, 96.1% also received an embolic protection device. Antiplatelet therapy was continued in 99% of the patients.
The surgeons performing endarterectomy were experienced and had documented low complication rates. General anesthesia was used in 90% of surgical patients. Shunts were used during surgery in 57%, and patches were used in 62%. After endarterectomy, 91% of the patients received antiplatelet therapy.
CREST STUDY RESULTS: STENTING WAS AS GOOD AS SURGERY
Periprocedural outcomes
- Stroke, MI, or death: 5.2% with stenting vs 4.5% with surgery, HR 1.18, 95% CI 0.82–1.68, P = .38
- Stroke: 4.1% vs 2.3%, HR 1.79, 95% CI 1.14–2.82, P = .01
- MI: 1.1% vs 2.3%, HR 0.50, 95% CI 0.26–0.94, P = .03
- Cranial nerve palsy: 0.3% vs 4.8%, HR 0.07, 95% CI 0.02–0.18, P < .0001 (Table 2).
Outcomes at 4 years
- The primary end point (periprocedural stroke, MI, or death, or ipsilateral stroke within 4 years after the procedure): 7.2% with stenting vs 6.8% with surgery, HR 1.11, 95% CI 0.81–1.51, P = .51. A Kaplan-Meier analysis showed similar findings with statistically similar outcomes (Figure 2).
- Ipsilateral stroke: 2.0% vs 2.4%, HR 0.94, 95% CI 0.50–1.76, P = .85.
The primary outcome was analyzed for interactions of baseline variables, and no effect was detected for symptomatic status or sex. There was a suggestion of an interaction with age, with older patients (over age 70) benefiting more from endarterectomy.
Quality-of-life indices showed that both major and minor strokes were likely to produce long-term physical limitations, with minor stroke associated with worse mental and physical health at 1 year. The effect of periprocedural MI on long-term physical and mental health was less certain. The increased incidence of cranial nerve palsy noted with endarterectomy has been found before and has had no effect on quality of life.
WHAT DO THE CREST FINDINGS MEAN?
CREST is the largest trial to date to compare stenting and surgery. It is an important addition to the literature, not only because of its size, but also because it focused on a real-world patient population. For this reason, its results are more applicable to patients seen in primary care clinics, ie, with peripheral vascular disease, coronary artery disease, diabetes mellitus, hypertension, and smoking.
As noted, previous studies of endarterectomy had strict inclusion and exclusion criteria, which selected against patients at high surgical risk. Therefore, the CREST findings are of greater relevance when comparing stenting and endarterectomy.
Periprocedural and long-term neurologic outcomes
CREST showed similar findings for the composite end point of periprocedural stroke, death, or MI (ie, within 30 days of the procedure) and long-term stroke, establishing similar outcomes in patients undergoing stenting and surgery.
However, an analysis of the individual components of the composite end point showed significant differences between the two treatments. The risk of ipsilateral periprocedural stroke was higher with stenting; these events were defined as nonmajor by NIHSS criteria. The risk of contralateral stroke was similar and low with each treatment.
While the increased risk of periprocedural ipsilateral stroke was not synonymous with an increased risk of major stroke, post hoc analysis showed that any stroke was associated with decreased physical and mental health at 1 year. Therefore, patients who had even a minor stroke did worse from a physical and mental standpoint, a finding that argues for the superiority of surgery in selected patients at risk of periprocedural stroke.
If periprocedural stroke is excluded, the risk of long-term ipsilateral stroke was similar for each treatment, and extremely low (2% for stenting, 2.4% for surgery). Despite this, given the importance of periprocedural minor and major stroke, better predictive models are needed to identify patients at risk of procedural neurologic events. These prediction models will allow better patient selection.
The CREST data and medical therapy
The rates of stroke in this trial were similar to those observed with current medical treatment (approximately 1% per year), especially for patients with asymptomatic disease. Such findings introduce fresh controversy in the necessity of performing either procedure for this patient subset and may lead to further studies evaluating current medical therapy vs intervention.
Periprocedural myocardial infarction
Vascular surgery has long been associated with high cardiovascular risk, especially an increased risk of periprocedural MI.30 Findings from CREST provide further evidence of the risk of MI with endarterectomy in a real-world patient population. Given the evidence of a strong correlation between periprocedural cardiac enzyme elevations and adverse outcomes, the increased incidence of periprocedural MI is worrisome.31 As with risk assessment for periprocedural stroke, better predictive models are needed for patients at risk of cardiovascular events during endarterectomy.
Procedural complications
Carotid endarterectomy entails incisions in the neck with disruption of tissue planes, as opposed to catheter entry site wounds with stenting. The more invasive nature of endarterectomy thus carries a higher risk of wound complications. In fact, in the NASCET trial, the risk of wound complications was 9.3%.10,19 In CREST, surgery carried a higher risk of wound complications compared with stenting (42 vs 0 cases), although stenting involved more periprocedural transfusions, presumably due to retroperitoneal bleeding in four patients.
Use of general anesthesia is also associated with adverse outcomes.17,18 In CREST, 90% of endarterectomy procedures required general anesthesia, whereas none of the stenting procedures required this.
Cranial nerve palsy is an often overlooked but real complication after these procedures. Cranial nerve palsies can lead to vocal, swallowing, and sensory problems that can have a transient or permanent impact on quality of life. In CREST, as in EVA-3S, SAPPHIRE, and ICSS, this risk was substantially higher with surgery,23,25,27 although the long-term consequences of these palsies were not found to affect quality of life at 1 year of follow-up.
HOW CREST FINDINGS COMPARE WITH PREVIOUS STUDIES
Patients in CREST enjoyed overall better outcomes than in previous studies. In earlier trials of surgery vs medical therapy, the rates of adverse outcomes were higher than in CREST. In NASCET, the risk of ipsilateral stroke was 9% with surgery, with 2.5% being fatal or disabling strokes.10 In the ECST, rates of major stroke or death with endarterectomy were 7.0% within 30 days of surgery and 37.0% at a mean follow-up of 6.1 years.12
In earlier studies of surgery vs stenting, outcomes at 30 days were also substantially worse than those in CREST. In the EVA-3S trial, the 30-day incidence of stroke or death was 3.9% after surgery and 9.6% after stenting. These findings were similar at 6 months in EVA-3S, with a 6.1% rate of adverse events after surgery and 11.7% after stenting.25 In the SAPPHIRE trial, the cumulative incidence of stroke and death at 1 year was 21.4% for surgery and 13.6% for stenting.23
Overall, the CREST results show better outcomes than in previous trials. This may be due to improvements in technical aspects of the interventions and to more aggressive drug therapy. Also, because of the high number of patients enrolled in CREST, surgeons and interventionalists were required to meet eligibility criteria, which could have contributed to the improved outcomes.32
CREST was also unique in that stenting was done with an embolic protection device whenever possible, and this also likely had an impact on outcomes.
CREST vs ICSS
CREST and ICSS, published within a few months of each other, seem to have arrived at entirely different conclusions. As both studies are well-designed randomized controlled trials, these distinct results have yielded much controversy. However, closer scrutiny sheds light as to why the results may be different.
While ICSS focused only on patients with symptoms, CREST also included those without symptoms. The difference in patient populations is itself enough to account for the different outcomes.
Also, the interim analysis of ICSS was at 120 days, which makes periprocedural events a more dominant factor in outcomes, whereas these events likely do not last into the long term, as was the case in CREST. Analysis of the ICSS data at a later follow-up date may show results more similar to those of CREST.
The design of ICSS was also different than CREST. In ICSS, the use of an embolic protection device in stenting was not mandated, and the study lacked a lead-in phase of intensive training for those performing stenting. Furthermore, MI was adjudicated only when clinically recognized, which is different than the more rigorous method used in CREST.
Yet despite these differences, CREST and ICSS shed light on a controversial area of carotid stenosis management, and both studies boasted low rates of periprocedural complications. Clinicians should keep in mind the inclusion criteria and the technical specificities of these trials in order to explain to patients the risks and benefits of stenting and surgery, and to arrive at a decision together.
Limitations
The results of CREST should also be reviewed carefully due to a number of limitations. The study began in 2000 with symptomatic patients only, and began enrolling asymptomatic patients in 2005, so that the methodology of the study was changed midway. However, the investigators performed a subgroup analysis to distinguish between outcomes of the symptomatic and the asymptomatic groups and found no statistical interaction for the primary end point based on symptom status.
Despite careful patient selection, many of the predictors of adverse outcomes with stenting, such as lesion length, level of calcification, and lesion location, were not accounted for in the earlier days of enrollment. This may have had an impact on the incidence of stroke in patients enrolled in the early years of the trial. We await the analysis of predictors of perioperative stroke from CREST.
TAKE-HOME POINTS AND FUTURE DIRECTIONS
The CREST findings show that outcomes with stenting are similar to those with surgery in both the short term and the long term, and that the choice of management should be individualized. Each patient’s risk of MI and stroke should be considered based on a variety of factors, including the severity of coronary artery disease, the length of the carotid lesion, the level of calcification, the location of the lesion, and aortic atheroma. The treatment should be selected after also taking into account the patient’s preference and the available expertise, and only after a comprehensive discussion with the patient.
- Brott TG, Hobson RW, Howard G, et al; CREST Investigators. Stenting versus endarterectomy for treatment of carotid-artery stenosis. N Engl J Med 2010; 363:11–23.
- Thom T, Haase N, Rosamond W, et al; American Heart Association Statistics Committee and Stroke Statistics Subcommittee. Heart disease and stroke statistics—2006 update: a report from the American Heart Association Statistics Committee and Stroke Statistics Subcommittee. Circulation 2006; 113:e85–e151.
- Rosamond WD, Folsom AR, Chambless LE, et al. Stroke incidence and survival among middle-aged adults: 9-year follow-up of the Atherosclerosis Risk in Communities (ARIC) cohort. Stroke 1999; 30:736–743.
- Chaturvedi S, Bruno A, Feasby T, et al; Therapeutics and Technology Assessment Subcommittee of the American Academy of Neurology. Carotid endarterectomy—an evidence-based review: report of the Therapeutics and Technology Assessment Subcommittee of the American Academy of Neurology. Neurology 2005; 65:794–801.
- Howell GM, Makaroun MS, Chaer RA. Current management of extracranial carotid occlusive disease. J Am Coll Surg 2009; 208:442–453.
- Barnett HJ, Gunton RW, Eliasziw M, et al. Causes and severity of ischemic stroke in patients with internal carotid artery stenosis. JAMA 2000; 283:1429–1436.
- Biller J, Feinberg WM, Castaldo JE, et al. Guidelines for carotid endarterectomy: a statement for healthcare professionals from a Special Writing Group of the Stroke Council, American Heart Association. Circulation 1998; 97:501–509.
- Goldstein LB, Adams R, Alberts MJ, et al; American Heart Association; American Stroke Association Stroke Council. Primary prevention of ischemic stroke: a guideline from the American Heart Association/American Stroke Association Stroke Council: cosponsored by the Atherosclerotic Peripheral Vascular Disease Interdisciplinary Working Group; Cardiovascular Nursing Council; Clinical Cardiology Council; Nutrition, Physical Activity, and Metabolism Council; and the Quality of Care and Outcomes Research Interdisciplinary Working Group. Circulation 2006; 113:e873–e923.
- Strully KJ, Hurwitt ES, Blankenberg HW. Thrombo-endarterectomy for thrombosis of the internal carotid artery in the neck. J Neurosurg 1953; 10:474–482.
- Beneficial effect of carotid endarterectomy in symptomatic patients with high-grade carotid stenosis. North American Symptomatic Carotid Endarterectomy Trial Collaborators. N Engl J Med 1991; 325:445–453.
- Barnett HJ, Taylor DW, Eliasziw M, et al. Benefit of carotid endarterectomy in patients with symptomatic moderate or severe stenosis. North American Symptomatic Carotid Endarterectomy Trial Collaborators. N Engl J Med 1998; 339:1415–1425.
- Randomised trial of endarterectomy for recently symptomatic carotid stenosis: final results of the MRC European Carotid Surgery Trial (ECST). Lancet 1998; 351:1379–1387.
- Halliday A, Mansfield A, Marro J, et al; MRC Asymptomatic Carotid Surgery Trial (ACST) Collaborative Group. Prevention of disabling and fatal strokes by successful carotid endarterectomy in patients without recent neurological symptoms: randomised controlled trial. Lancet 2004; 363:1491–1502.
- Hobson RW, Weiss DG, Fields WS, et al. Efficacy of carotid endarterectomy for asymptomatic carotid stenosis. The Veterans Affairs Cooperative Study Group. N Engl J Med 1993; 328:221–227.
- Endarterectomy for asymptomatic carotid artery stenosis. Executive Committee for the Asymptomatic Carotid Atherosclerosis Study. JAMA 1995; 273:1421–1428.
- Sacco RL, Adams R, Albers G, et al; American Heart Association/American Stroke Association Council on Stroke; Council on Cardiovascular Radiology and Intervention; American Academy of Neurology. Guidelines for prevention of stroke in patients with ischemic stroke or transient ischemic attack: a statement for healthcare professionals from the American Heart Association/American Stroke Association Council on Stroke: co-sponsored by the Council on Cardiovascular Radiology and Intervention: the American Academy of Neurology affirms the value of this guideline. Circulation 2006; 113:e409–e449.
- Watts K, Lin PH, Bush RL, et al. The impact of anesthetic modality on the outcome of carotid endarterectomy. Am J Surg 2004; 188:741–747.
- Weber CF, Friedl H, Hueppe M, et al. Impact of general versus local anesthesia on early postoperative cognitive dysfunction following carotid endarterectomy: GALA Study Subgroup Analysis. World J Surg 2009; 33:1526–1532.
- Ferguson GG, Eliasziw M, Barr HW, et al. The North American Symptomatic Carotid Endarterectomy Trial: surgical results in 1415 patients. Stroke 1999; 30:1751–1758.
- Golledge J, Mitchell A, Greenhalgh RM, Davies AH. Systematic comparison of the early outcome of angioplasty and endarterectomy for symptomatic carotid artery disease. Stroke 2000; 31:1439–1443.
- Kastrup A, Gröschel K, Krapf H, Brehm BR, Dichgans J, Schulz JB. Early outcome of carotid angioplasty and stenting with and without cerebral protection devices: a systematic review of the literature. Stroke 2003; 34:813–819.
- Gurm HS, Yadav JS, Fayad P, et al; SAPPHIRE Investigators. Long-term results of carotid stenting versus endarterectomy in high-risk patients. N Engl J Med 2008; 358:1572–1579.
- Yadav JS, Wholey MH, Kuntz RE, et al; Stenting and Angioplasty with Protection in Patients at High Risk for Endarterectomy Investigators. Protected carotid-artery stenting versus endarterectomy in high-risk patients. N Engl J Med 2004; 351:1493–1501.
- Eckstein HH, Ringleb P, Allenberg JR, et al. Results of the Stent-Protected Angioplasty versus Carotid Endarterectomy (SPACE) study to treat symptomatic stenoses at 2 years: a multinational, prospective, randomised trial. Lancet Neurol 2008; 7:893–902.
- Mas JL, Chatellier G, Beyssen B, et al; EVA-3S Investigators. Endarterectomy versus stenting in patients with symptomatic severe carotid stenosis. N Engl J Med 2006; 355:1660–1771.
- Roffi M, Sievert H, Gray WA, et al. Carotid artery stenting versus surgery: adequate comparisons? Lancet Neurol 2010; 9:339–341.
- International Carotid Stenting Study Investigators; Ederle J, Dobson J, Featherstone RL, et al. Carotid artery stenting compared with endarterectomy in patients with symptomatic carotid stenosis (International Carotid Stenting Study): an interim analysis of a randomised controlled trial. Lancet 2010; 375:985–997.
- Bonati LH, Jongen LM, Haller S, et al; ICSS-MRI study group. New ischaemic brain lesions on MRI after stenting or endarterectomy for symptomatic carotid stenosis: a sub-study of the International Carotid Stenting Study (ICSS). Lancet Neurol 2010; 9:353–362.
- Sheffet AJ, Roubin G, Howard G, et al. Design of the Carotid Revascularization Endarterectomy vs. Stenting Trial (CREST). Int J Stroke 2010; 5:40–46.
- Fleisher LA, Beckman JA, Brown KA, et al. ACC/AHA 2007 guidelines on perioperative cardiovascular evaluation and care for noncardiac surgery: a report of the American College of Cardiology/American Heart Association Task Force on Practice Guidelines (Writing Committee to Revise the 2002 Guidelines on Perioperative Cardiovascular Evaluation for Noncardiac Surgery) developed in collaboration with the American Society of Echocardiography, American Society of Nuclear Cardiology, Heart Rhythm Society, Society of Cardiovascular Anesthesiologists, Society for Cardiovascular Angiography and Interventions, Society for Vascular Medicine and Biology, and Society for Vascular Surgery. J Am Coll Cardiol 2007; 50:e159–e241.
- Bhatt DL, Topol EJ. Does creatinine kinase-MB elevation after percutaneous coronary intervention predict outcomes in 2005? Periprocedural cardiac enzyme elevation predicts adverse outcomes. Circulation 2005; 112:906–915.
- Hobson RW, Howard VJ, Roubin GS, et al; CREST. Credentialing of surgeons as interventionalists for carotid artery stenting: experience from the lead-in phase of CREST. J Vasc Surg 2004; 40:952–957.
- Brott TG, Hobson RW, Howard G, et al; CREST Investigators. Stenting versus endarterectomy for treatment of carotid-artery stenosis. N Engl J Med 2010; 363:11–23.
- Thom T, Haase N, Rosamond W, et al; American Heart Association Statistics Committee and Stroke Statistics Subcommittee. Heart disease and stroke statistics—2006 update: a report from the American Heart Association Statistics Committee and Stroke Statistics Subcommittee. Circulation 2006; 113:e85–e151.
- Rosamond WD, Folsom AR, Chambless LE, et al. Stroke incidence and survival among middle-aged adults: 9-year follow-up of the Atherosclerosis Risk in Communities (ARIC) cohort. Stroke 1999; 30:736–743.
- Chaturvedi S, Bruno A, Feasby T, et al; Therapeutics and Technology Assessment Subcommittee of the American Academy of Neurology. Carotid endarterectomy—an evidence-based review: report of the Therapeutics and Technology Assessment Subcommittee of the American Academy of Neurology. Neurology 2005; 65:794–801.
- Howell GM, Makaroun MS, Chaer RA. Current management of extracranial carotid occlusive disease. J Am Coll Surg 2009; 208:442–453.
- Barnett HJ, Gunton RW, Eliasziw M, et al. Causes and severity of ischemic stroke in patients with internal carotid artery stenosis. JAMA 2000; 283:1429–1436.
- Biller J, Feinberg WM, Castaldo JE, et al. Guidelines for carotid endarterectomy: a statement for healthcare professionals from a Special Writing Group of the Stroke Council, American Heart Association. Circulation 1998; 97:501–509.
- Goldstein LB, Adams R, Alberts MJ, et al; American Heart Association; American Stroke Association Stroke Council. Primary prevention of ischemic stroke: a guideline from the American Heart Association/American Stroke Association Stroke Council: cosponsored by the Atherosclerotic Peripheral Vascular Disease Interdisciplinary Working Group; Cardiovascular Nursing Council; Clinical Cardiology Council; Nutrition, Physical Activity, and Metabolism Council; and the Quality of Care and Outcomes Research Interdisciplinary Working Group. Circulation 2006; 113:e873–e923.
- Strully KJ, Hurwitt ES, Blankenberg HW. Thrombo-endarterectomy for thrombosis of the internal carotid artery in the neck. J Neurosurg 1953; 10:474–482.
- Beneficial effect of carotid endarterectomy in symptomatic patients with high-grade carotid stenosis. North American Symptomatic Carotid Endarterectomy Trial Collaborators. N Engl J Med 1991; 325:445–453.
- Barnett HJ, Taylor DW, Eliasziw M, et al. Benefit of carotid endarterectomy in patients with symptomatic moderate or severe stenosis. North American Symptomatic Carotid Endarterectomy Trial Collaborators. N Engl J Med 1998; 339:1415–1425.
- Randomised trial of endarterectomy for recently symptomatic carotid stenosis: final results of the MRC European Carotid Surgery Trial (ECST). Lancet 1998; 351:1379–1387.
- Halliday A, Mansfield A, Marro J, et al; MRC Asymptomatic Carotid Surgery Trial (ACST) Collaborative Group. Prevention of disabling and fatal strokes by successful carotid endarterectomy in patients without recent neurological symptoms: randomised controlled trial. Lancet 2004; 363:1491–1502.
- Hobson RW, Weiss DG, Fields WS, et al. Efficacy of carotid endarterectomy for asymptomatic carotid stenosis. The Veterans Affairs Cooperative Study Group. N Engl J Med 1993; 328:221–227.
- Endarterectomy for asymptomatic carotid artery stenosis. Executive Committee for the Asymptomatic Carotid Atherosclerosis Study. JAMA 1995; 273:1421–1428.
- Sacco RL, Adams R, Albers G, et al; American Heart Association/American Stroke Association Council on Stroke; Council on Cardiovascular Radiology and Intervention; American Academy of Neurology. Guidelines for prevention of stroke in patients with ischemic stroke or transient ischemic attack: a statement for healthcare professionals from the American Heart Association/American Stroke Association Council on Stroke: co-sponsored by the Council on Cardiovascular Radiology and Intervention: the American Academy of Neurology affirms the value of this guideline. Circulation 2006; 113:e409–e449.
- Watts K, Lin PH, Bush RL, et al. The impact of anesthetic modality on the outcome of carotid endarterectomy. Am J Surg 2004; 188:741–747.
- Weber CF, Friedl H, Hueppe M, et al. Impact of general versus local anesthesia on early postoperative cognitive dysfunction following carotid endarterectomy: GALA Study Subgroup Analysis. World J Surg 2009; 33:1526–1532.
- Ferguson GG, Eliasziw M, Barr HW, et al. The North American Symptomatic Carotid Endarterectomy Trial: surgical results in 1415 patients. Stroke 1999; 30:1751–1758.
- Golledge J, Mitchell A, Greenhalgh RM, Davies AH. Systematic comparison of the early outcome of angioplasty and endarterectomy for symptomatic carotid artery disease. Stroke 2000; 31:1439–1443.
- Kastrup A, Gröschel K, Krapf H, Brehm BR, Dichgans J, Schulz JB. Early outcome of carotid angioplasty and stenting with and without cerebral protection devices: a systematic review of the literature. Stroke 2003; 34:813–819.
- Gurm HS, Yadav JS, Fayad P, et al; SAPPHIRE Investigators. Long-term results of carotid stenting versus endarterectomy in high-risk patients. N Engl J Med 2008; 358:1572–1579.
- Yadav JS, Wholey MH, Kuntz RE, et al; Stenting and Angioplasty with Protection in Patients at High Risk for Endarterectomy Investigators. Protected carotid-artery stenting versus endarterectomy in high-risk patients. N Engl J Med 2004; 351:1493–1501.
- Eckstein HH, Ringleb P, Allenberg JR, et al. Results of the Stent-Protected Angioplasty versus Carotid Endarterectomy (SPACE) study to treat symptomatic stenoses at 2 years: a multinational, prospective, randomised trial. Lancet Neurol 2008; 7:893–902.
- Mas JL, Chatellier G, Beyssen B, et al; EVA-3S Investigators. Endarterectomy versus stenting in patients with symptomatic severe carotid stenosis. N Engl J Med 2006; 355:1660–1771.
- Roffi M, Sievert H, Gray WA, et al. Carotid artery stenting versus surgery: adequate comparisons? Lancet Neurol 2010; 9:339–341.
- International Carotid Stenting Study Investigators; Ederle J, Dobson J, Featherstone RL, et al. Carotid artery stenting compared with endarterectomy in patients with symptomatic carotid stenosis (International Carotid Stenting Study): an interim analysis of a randomised controlled trial. Lancet 2010; 375:985–997.
- Bonati LH, Jongen LM, Haller S, et al; ICSS-MRI study group. New ischaemic brain lesions on MRI after stenting or endarterectomy for symptomatic carotid stenosis: a sub-study of the International Carotid Stenting Study (ICSS). Lancet Neurol 2010; 9:353–362.
- Sheffet AJ, Roubin G, Howard G, et al. Design of the Carotid Revascularization Endarterectomy vs. Stenting Trial (CREST). Int J Stroke 2010; 5:40–46.
- Fleisher LA, Beckman JA, Brown KA, et al. ACC/AHA 2007 guidelines on perioperative cardiovascular evaluation and care for noncardiac surgery: a report of the American College of Cardiology/American Heart Association Task Force on Practice Guidelines (Writing Committee to Revise the 2002 Guidelines on Perioperative Cardiovascular Evaluation for Noncardiac Surgery) developed in collaboration with the American Society of Echocardiography, American Society of Nuclear Cardiology, Heart Rhythm Society, Society of Cardiovascular Anesthesiologists, Society for Cardiovascular Angiography and Interventions, Society for Vascular Medicine and Biology, and Society for Vascular Surgery. J Am Coll Cardiol 2007; 50:e159–e241.
- Bhatt DL, Topol EJ. Does creatinine kinase-MB elevation after percutaneous coronary intervention predict outcomes in 2005? Periprocedural cardiac enzyme elevation predicts adverse outcomes. Circulation 2005; 112:906–915.
- Hobson RW, Howard VJ, Roubin GS, et al; CREST. Credentialing of surgeons as interventionalists for carotid artery stenting: experience from the lead-in phase of CREST. J Vasc Surg 2004; 40:952–957.
KEY POINTS
- In CREST, stenting and surgery had similar combined rates of stroke, MI, and death when performed by highly qualified interventionalists and surgeons in carefully selected patients.
- The risk of periprocedural stroke was higher with stenting; most of those strokes were nonmajor. Both major and nonmajor strokes were associated with decreased quality of life in long-term follow-up.
- Endarterectomy was associated with higher rates of periprocedural MI than stenting.
- Endarterectomy carried a significantly higher rate of cranial nerve damage than stenting.
Percutaneous treatment of aortic valve stenosis
Stenosis of the aortic valve has a long, latent, asymptomatic phase, but when symptoms finally occur, clinical deterioration can be rapid. For patients with severe stenosis, the standard treatment has long been replacement of the aortic valve via open heart surgery. But many patients with severe stenosis are considered too high-risk for this procedure.
Until about 5 years ago, these patients had no other option but medical therapy or percutaneous aortic balloon valvuloplasty as a palliative measure or as a bridge to open heart surgery. But 5 years of experience with percutaneous techniques to implant prosthetic aortic valves show that this less-invasive approach may become a viable option for patients with severe symptomatic aortic valve stenosis.
In this review, we discuss current prosthetic valves and percutaneous techniques and their relative advantages and limitations and the potential future role of this new treatment option.
THE NEED FOR A LESS-INVASIVE APPROACH
Calcific aortic stenosis is the most common valvular heart disease, affecting 2% to 4% of adults over age 65 in the United States alone.1,2 The aging of our population and the lack of drug therapies to prevent, halt, or effectively slow aortic valve stenosis are leading to a greater burden of this condition.1,3,4 Already in the United States more than 50,000 surgical aortic valve replacements are performed every year for severe aortic stenosis.1,2 The associated in-hospital death rate is 8.8% in patients over age 65 years, and as high as 13% in low-volume centers.1,5
The steady increase in the number of patients requiring aortic valve replacement, the high surgical risk in patients with multiple comorbidities, the reluctance of some patients to undergo the trauma and pain associated with open heart surgery via sternotomy, and the fact that percutaneous procedures are less traumatic and offer faster recovery and fewer hospital days—all these are forces that have been driving the development of percutaneous techniques for the treatment of aortic stenosis.6–11 In addition, a recent study12 showed that 33% of patients over age 75 were deemed too high-risk for open heart surgery and thus were left untreated.12
The evolution of percutaneous aortic valve replacement
The idea of percutaneous treatment of aortic stenosis was first put into clinical practice in 1985, when Cribier performed an aortic balloon valvuloplasty.6 This was followed in 200013 by the first successful implantation of a catheter-based stent valve in a human, and in 2002 by the first successful percutaneous aortic valve replacement in a human.13–15 In the following sections, we discuss the percutaneous approaches in current use for the treatment of degenerative aortic stenosis.
AORTIC BALLOON VALVULOPLASTY
Percutaneous aortic balloon valvuloplasty, partial dilation of the stenotic aortic valve with a balloon inserted via a catheter,1,16–19 improves symptoms but has failed to show a sustained benefit on rates of mortality or morbidity.1,16–18 The restenosis rate is high, and symptoms recur in most patients within months to a year.1,16–18 Procedural complication rates are about 10%, and complication rates at the catheter access site are even higher.1,16–18 The 30-day death rate in the National Heart, Lung, and Blood Institute’s Balloon Valvuloplasty Registry, which included more than 600 patients, was 14%.18 In a retrospective study of 212 patients who underwent single or repeat percutaneous aortic balloon valvuloplasty,20 the 1-year mortality rate was 36% for the entire cohort, with a median survival of 3 years. Patients who underwent a repeat procedure (33%) had 1-year mortality rate of 42%, compared with 16% in patients who did not undergo a repeat procedure.20
Percutaneous aortic balloon valvuloplasty serves best as palliative therapy in severely symptomatic patients, and as a bridge to surgery in hemodynamically unstable adult patients.21,22 Percutaneous aortic balloon valvuloplasty is not an option in patients who are good candidates for surgical valve replacement.1
PERCUTANEOUS AORTIC VALVE REPLACEMENT: THREE TECHNIQUES
The antegrade technique
In the antegrade technique, an approach that has been studied but is no longer being used, access to the femoral vein is gained and the catheter with the prosthetic aortic valve is advanced, traversing the interatrial septum and the mitral valve, and is positioned within the diseased aortic valve.15,23,24 The main advantage of this approach is that the femoral vein can accommodate the large catheter sheath and that subsequent management of the access site is by manual compression only.15,23,24 The main disadvantages are the potential for mitral valve injury and severe mitral regurgitation, and the technical challenge of delivering the aortic valve prosthesis to the correct aortic position.15,23,25–27
The retrograde technique
In the retrograde (ie, transfemoral) technique, access to the femoral artery is gained and the catheter with the prosthetic aortic valve is advanced to the stenotic aortic valve.8,11,26,28–30 This approach is faster and technically easier than the antegrade approach, but it can be associated with injury to the aortofemoral vessels and with failure of the prosthesis to cross the aortic arch or the stenotic aortic valve.11,23,30
The transapical technique
In the transapical technique, the valve delivery system is inserted via a small incision made between the ribs. The apex of the left ventricle is punctured with a needle, and the prosthetic valve is positioned within the stenotic aortic valve.27,31–33 The main advantage of this approach is that it allows more direct access to the aortic valve and eliminates the need for a large peripheral vascular access site in patients with peripheral vascular disease, small tortuous vasculature, or a history of major vascular complications or vascular repairs.31–33 Potential disadvantages are related to the left ventricular apical puncture and include adverse ventricular remodeling, left ventricular aneurysm or pseudoaneurysm, pericardial complications, pneumothorax, malignant ventricular arrhythmias, coronary artery injury, and the need for general anesthesia and chest tubes.27,31–35
Common features of the three approaches
The three percutaneous approaches have certain final steps in common.11,23,30,33 The position of final deployment of the prosthetic valve is determined by the patient’s native valvular structure and anatomy and is optimized by using fluoroscopic imaging of the native aortic valve calcification as an anatomical marker, along with guidance from supra-aortic angiography and transesophageal echocardiography.11,23,30,33 Ideally, the aortic valve prosthesis is placed at mid-position in the patient’s aortic valve, taking care to not to impinge on the coronary ostia or to impede the motion of the anterior mitral leaflet.11,23,30,33 In all three procedures, the prosthesis is then deployed by maximally inflating, rapidly deflating, and immediately withdrawing the delivery balloon. This final step is carried out during temporary high-rate right ventricular apical pacing, which produces ventricular tachycardia at 180 to 220 beats/min for up to 10 seconds.11,23,30,33 This leads to an immediate decrease in stroke volume, resulting in minimal forward flow through the aortic valve, which in turn facilitates precise positioning of the prosthetic valve.
So far, only the Cribier-Edwards valve has been deployed via all three techniques. The CoreValve has been deployed only via the retrograde technique. The Edwards SAPIEN valve has been deployed with retrograde and transapical approaches (see www.edwards.com/Products/TranscatheterValves/SapienTHV.htm and www.corevalve.com for animations depicting these techniques).
EXPERIENCE WITH THE CRIBIER-EDWARDS VALVE
The Cribier-Edwards valve has three leaflets made from equine pericardial tissue sutured inside a balloon-expandable stainless steel 14-mm stent (Table 1).11,23,33 With the use of a specially designed mechanical crimping device, the aortic valve prosthesis is mounted over a 3-cm-long balloon catheter, expandable to a diameter of 22 to 26 mm (NuMed Inc, Hopkinton, NY).11,23,30,33
After this prosthesis was tested in animal models,14,15 a trial for compassionate use in humans was begun, called the Initial Registry of Endovascular Implantation of Valves in Europe (I-REVIVE) trial. This trial was later continued as the Registry of Endovascular Critical Aortic Stenosis Treatment (RECAST) trial.23 All patients were formally evaluated by two cardio-thoracic surgeons and were deemed inappropriate for surgical aortic valve replacement.23
The success rate with the antegrade percutaneous approach was 85% (23 of 27 patients) and 57% for the retrograde approach (4 of 7 patients).11,23,30–33 Procedural limitations were migration or embolization of the prosthetic valve, failure to cross the stenotic aortic valve, and paravalvular aortic regurgitation.23 Anatomic and functional success was evidenced by improvement in aortic valve area, increase in left ventricular ejection fraction, and improved New York Heart Association functional class, all of which were sustained at up to 24 months.23
Webb et al11 reported similar results with retrograde implantation of the Cribier-Edwards valve in a cohort of 50 patients.11 The main difference between the two studies was the expected occurrence of aortofemoral complications with the retrograde approach.11,26 Procedural success increased from 76% in the first 25 patients to 96% in the second 25, and the 30-day mortality rate fell from 16% to 8%, which reflected the learning curve. Importantly, no patients needed conversion to open surgery during the first 30 days, and at a median follow-up of 359 days 35 (81%) of 43 patients who underwent successful transcatheter aortic valve replacement were still alive.11 Additionally, significant improvement was noted in left ventricular ejection fraction, mitral regurgitation, and New York Heart Association functional class, and these improvements persisted at 1 year.11
Lichtenstein et al31 and Walther et al32 successfully implanted the Cribier-Edwards valve using the transapical approach in a very high-risk elderly population with poor functional class. All patients were deemed unsuitable for standard surgical valve replacement and also for percutaneous transfemoral aortic valve implantation because of severe aorto-iliac disease. In both studies, the short-term and mid-term results were encouraging.
These experiences with the Cribier-Edwards valve showed that device- and technique-related shortcomings could be addressed. To date, more than 500 percutaneous aortic valve replacement procedures have been done with the Cribier-Edwards valve worldwide, with a greater than 95% technical success rate in the latest cohorts.36 Importantly, use of a larger (26-mm) prosthetic valve has been associated with a lower rate of prosthetic valve migration or embolization, and with a significantly lower rate of paravalvular aortic regurgitation.11,23
EXPERIENCE WITH THE COREVALVE SYSTEM
The CoreValve ReValving system is based on retrograde implantation of the CoreValve prosthesis—a self-expanding aortic valve prosthesis composed of three bovine pericardial leaflets mounted and sutured within a self-expanding 50-mm-long nitinol stent (Table 1).28–30 The inner diameter is 21 to 22 mm.28–30 This prosthesis has three distinct structural segments.28–30 The bottom portion exerts a high radial force that expands and pushes aside the calcified leaflets and avoids recoil; the central portion carries the valve, and it tapers to avoid the coronary artery ostia; and the upper portion flares to fixate and stabilize the deployed aortic valve prosthesis in the ascending aorta, thus preventing migration or embolization of the device.28–30 The main difference between the CoreValve and the Cribier-Edwards valve is that the Core-Valve is self-expanding, which theoretically permits it to conform to different aortic sizes and to anchor well in the aortic annulus.28–30 This feature allows the CoreValve to be used in patients with severe aortic insufficiency and other noncalcific aortic valvular conditions. The CoreValve has not yet been deployed via antegrade or transapical technique.
The first-generation CoreValve prosthesis was first implanted in a human recipient in 2005.29 Since then, improvements have been made, leading to the development of second- and third-generation devices. A pilot study of implantation of the first-generation CoreValve28 via the retrograde approach in elderly patients with poor functional class and severe aortic stenosis had a short-term procedural success rate of 84% (21 of 25 patients), with a significant reduction in the mean aortic valve gradient and improved functional class at 30-day follow-up.28 At 30 days, 17 (94%) of 18 patients had no or only mild aortic regurgitation.28 Procedural limitations and complications were similar to those with the Cribier-Edwards valve.
In a study of second- and third-generation devices (50 patients received a second-generation device, and 36 received a third-generation device),30 again in elderly patients with poor functional class and severe aortic stenosis, the short-term success rate of the device was 88% (76 of 86) in each group. After the procedure, the mean aortic valve gradient decreased significantly and functional class improved significantly.30 Immediate after implantation, no patient had more than moderate aortic regurgitation, and in 51 patients (66%) the aortic regurgitation remained unchanged or improved after CoreValve implantation.30 These results were maintained at 30-day follow-up.
CoreValve was approved in May 2007 for clinical use in Europe.36 Of note, CoreValve has also been used to treat severe aortic regurgitation of a degenerated bioprosthetic aortic valve in an 80-year-old man with multiple comorbidities.37
EXPERIENCE WITH THE EDWARDS SAPIEN VALVE
The Edwards SAPIEN valve is a modification of the initial Cribier-Edwards valve and is the latest percutaneous aortic valve prosthesis to enter clinical trials (Table 1). It is a trileaflet balloon-expandable stainless steel valve made from bovine pericardial tissue, available in two sizes (23 mm and 26 mm). In September 2007, it was approved for use in Europe with the RetroFlex transfemoral delivery system. The Ascendra transapical delivery system for the Edward SAPIEN valve has received approval in Europe.
The multicenter Placement of Aortic Transcatheter Valves (PARTNER) trial in North America is continuing to enroll patients, with enrollment projected to be complete by the end of 2008. The aim of this prospective randomized clinical trial is to enroll 1,040 patients in two separate treatment arms. The surgical arm of the trial is comparing the Edwards SAPIEN valve with standard surgical aortic valve replacement, with the objective of demonstrating non-inferiority. The medical management arm of the trial is comparing percutaneous valve replacement against medical therapy or balloon valvuloplasty in patients considered too high-risk for conventional surgical valve replacement.
The primary end point in both arms is death at 1 year; secondary end points focus on long-term (1-year) composite cardiovascular events, valve performance, and quality-of-life indicators. Preliminary data on the first 100 patients (74 via the transfemoral [ie, retrograde] and 26 via the transapical approach) who underwent percutaneous Edwards SAPIEN valve implantation for compassionate use showed device durability and symptom relief at up to 2 years.38 Overall procedural success was 91%, but, as with other trials, there was a steep learning curve, so that excluding the first 25 patients increased the procedural success rate to 96%.38 Aortic valve size and hemodynamics, left ventricular systolic function, mitral regurgitation, and functional class were all significantly improved. Mild aortic regurgitation was common, but none of the patients had severe aortic regurgitation. Importantly, the 15% 30-day death rate was significantly lower than the expected rate of 33%. The 6-month survival rate was 78%, but the 2-year rate was 60% in this high-risk elderly cohort.
Walther et al39 recently reported outcomes on their first 50 patients who underwent transapical implantation of the Edwards SAPIEN valve. The operators were able to implant the prosthesis in all 50 patients, but 3 required early conversion to open surgery with sternotomy. The overall survival at 30 days was 92%, but in the last 25 patients the 30-day survival rate was 96%, with a 1-year survival rate of 80%.
PUTTING THE DATA IN PERSPECTIVE
As noted in this review, a number of factors make a strong case for timely aortic valve replacement: the aging population, the increase in incidence and prevalence of aortic stenosis,1,3,4,27,40 the multiple comorbidities in older patients, and the eventually aggressive natural course of aortic stenosis.1,3,4,27,40–43 Yet current standards dictate not to proceed with standard surgical aortic valve replacement in patients who are truly asymptomatic and who have normal left ventricular systolic function,1,40 mainly because the risks of surgical valve replacement outweigh the benefits in this population.1,40 Aortic valve surgery carries a risk of early death of 15% for patients ages 80 to 84 and of 18% for patients age 85.3,9,10,12,43–45
These figures seem high when compared with death rates of 12% in recent studies of percutaneous valve replacement in similar patients.11,23,30,33 The rates become lower as the learning curve improves.11,21,23,27,30,33 Thus, as the design of aortic valve prostheses and the techniques to implant them are refined and tested for safety, the risk-benefit balance may change in favor of earlier intervention in aortic stenosis with a percutaneous approach.11,21,27,46 Some experts believe that in 10 years 10% to 30% of patients undergoing conventional valve replacement will be candidates for a percutaneous approach.
Of the techniques used to date, the retrograde approach seems most amenable to widespread acceptance, given its inherent advantage of being faster and easier.11,21,30 Limitations with the retrograde approach seen in earlier trials—challenges and complications associated with large-bore arterial vascular access, difficulty traversing the aortic arch with bulky devices, and the inability to cross the stenotic aortic valve to deploy the prosthesis even after balloon valvuloplasty11,21,30—are correctable with refinements in the devices and in technique.
New types of prosthetic aortic valves entering early human studies are improving on current devices, for example, by using collapsible, inflatable valve frames for retrievability before final deployment.
Surgical aortic valve replacement remains the gold standard treatment for patients with symptomatic aortic stenosis. And while studies of percutaneous aortic valve replacement show great promise for this less-invasive treat-men, enthusiasm about percutaneous aortic valve replacement should be tempered by an awareness of persistent limitations of this approach, such as vascular and mechanical complications and operator inexperience, which still need attention.
- Bonow RO, Carabello BA, Kanu C, et al. ACC/AHA 2006 guidelines for the management of patients with valvular heart disease: a report of the American College of Cardiology/American Heart Association Task Force on Practice Guidelines (writing committee to revise the 1998 Guidelines for the Management of Patients With Valvular Heart Disease): developed in collaboration with the Society of Cardiovascular Anesthesiologists: endorsed by the Society for Cardiovascular Angiography and Interventions and the Society of Thoracic Surgeons. Circulation 2006; 114:e84–231.
- Freeman RV, Otto CM. Spectrum of calcific aortic valve disease: pathogenesis, disease progression, and treatment strategies. Circulation 2005; 111:3316–3326.
- Iung B, Baron G, Butchart EG, et al. A prospective survey of patients with valvular heart disease in Europe: The Euro Heart Survey on Valvular Heart Disease. Eur Heart J 2003; 24:1231–1243.
- Nkomo VT, Gardin JM, Skelton TN, Gottdiener JS, Scott CG, Enriquez-Sarano M. Burden of valvular heart diseases: a population-based study. Lancet 2006; 368:1005–1011.
- Goodney PP, O'Connor GT, Wennberg DE, Birkmeyer JD. Do hospitals with low mortality rates in coronary artery bypass also perform well in valve replacement? Ann Thorac Surg 2003; 76:1131–1137.
- Cribier A, Savin T, Saoudi N, Rocha P, Berland J, Letac B. Percutaneous transluminal valvuloplasty of acquired aortic stenosis in elderly patients: an alternative to valve replacement? Lancet 1986; 1:63–67.
- Vahanian A, Palacios IF. Percutaneous approaches to valvular disease. Circulation 2004; 109:1572–1579.
- Webb JG, Munt B, Makkar RR, Naqvi TZ, Dang N. Percutaneous stent-mounted valve for treatment of aortic or pulmonary valve disease. Catheter Cardiovasc Interv 2004; 63:89–93.
- Alexander KP, Anstrom KJ, Muhlbaier LH, et al. Outcomes of cardiac surgery in patients =80 years: results from the National Cardiovascular Network. J Am Coll Cardiol 2000; 35:731–738.
- Mittermair RP, Muller LC. Quality of life after cardiac surgery in the elderly. J Cardiovasc Surg (Torino) 2002; 43:43–47.
- Webb JG, Pasupati S, Humphries K, et al. Percutaneous transarterial aortic valve replacement in selected high-risk patients with aortic stenosis. Circulation 2007; 116:755–763.
- Iung B, Cachier A, Baron G, et al. Decision-making in elderly patients with severe aortic stenosis: why are so many denied surgery? Eur Heart J 2005; 26:2714–2720.
- Bonhoeffer P, Boudjemline Y, Saliba Z, et al. Percutaneous replacement of pulmonary valve in a right-ventricle to pulmonary-artery prosthetic conduit with valve dysfunction. Lancet 2000; 356:1403–1405.
- Andersen HR, Knudsen LL, Hasenkam JM. Transluminal implantation of artificial heart valves. Description of a new expandable aortic valve and initial results with implantation by catheter technique in closed chest pigs. Eur Heart J 1992; 13:704–708.
- Cribier A, Eltchaninoff H, Bash A, et al. Percutaneous transcatheter implantation of an aortic valve prosthesis for calcific aortic stenosis: first human case description. Circulation 2002; 106:3006–3008.
- Otto CM, Mickel MC, Kennedy JW, et al. Three-year outcome after balloon aortic valvuloplasty. Insights into prognosis of valvular aortic stenosis. Circulation 1994; 89:642–650.
- Safian RD, Berman AD, Diver DJ, et al. Balloon aortic valvuloplasty in 170 consecutive patients. N Engl J Med 1988; 319:125–130.
- Percutaneous balloon aortic valvuloplasty. Acute and 30-day follow-up results in 674 patients from the NHLBI Balloon Valvuloplasty Registry. Circulation 1991; 84:2383–2397.
- Safian RD, Mandell VS, Thurer RE, et al. Postmortem and intraoperative balloon valvuloplasty of calcific aortic stenosis in elderly patients: mechanisms of successful dilation. J Am Coll Cardiol 1987; 9:655–660.
- Agarwal A, Kini AS, Attanti S, et al. Results of repeat balloon valvuloplasty for treatment of aortic stenosis in patients aged 59 to 104 years. Am J Cardiol 2005; 95:43–47.
- Kapadia SR, Wazni OM, Tan WA, et al. Aortic valvuloplasty in 1990's: experience from a single center in United States. Circulation 1999; 100 18 suppl 1:1–448.
- Lieberman EB, Bashore TM, Hermiller JB, et al. Balloon aortic valvuloplasty in adults: failure of procedure to improve long-term survival. J Am Coll Cardiol 1995; 26:1522–1528.
- Cribier A, Eltchaninoff H, Tron C, et al. Treatment of calcific aortic stenosis with the percutaneous heart valve: mid-term follow-up from the initial feasibility studies: the French experience. J Am Coll Cardiol 2006; 47:1214–1223.
- Cribier A, Eltchaninoff H, Tron C, et al. Early experience with percutaneous transcatheter implantation of heart valve prosthesis for the treatment of end-stage inoperable patients with calcific aortic stenosis. J Am Coll Cardiol 2004; 43:698–703.
- Rajagopal V, Kapadia SR, Tuzcu EM. Advances in the percutaneous treatment of aortic and mitral valve disease. Minerva Cardioangiol 2007; 55:83–94.
- Webb JG, Chandavimol M, Thompson CR, et al. Percutaneous aortic valve implantation retrograde from the femoral artery. Circulation 2006; 113:842–850.
- Salemi A. Percutaneous valve interventions. Curr Opin Anaesthesiol 2007; 20:70–74.
- Grube E, Laborde JC, Gerckens U, et al. Percutaneous implantation of the CoreValve self-expanding valve prosthesis in high-risk patients with aortic valve disease: the Siegburg first-in-man study. Circulation 2006; 114:1616–1624.
- Grube E, Laborde JC, Zickmann B, et al. First report on a human percutaneous transluminal implantation of a self-expanding valve prosthesis for interventional treatment of aortic valve stenosis. Catheter Cardiovasc Interv 2005; 66:465–469.
- Grube E, Schuler G, Buellesfeld L, et al. Percutaneous aortic valve replacement for severe aortic stenosis in high-risk patients using the second- and current third-generation self-expanding CoreValve prosthesis: device success and 30-day clinical outcome. J Am Coll Cardiol 2007; 50:69–76.
- Lichtenstein SV, Cheung A, Ye J, et al. Transapical transcatheter aortic valve implantation in humans: initial clinical experience. Circulation 2006; 114:591–596.
- Walther T, Falk V, Borger MA, et al. Minimally invasive transapical beating heart aortic valve implantation—proof of concept. Eur J Cardiothorac Surg 2007; 31:9–15.
- Ye J, Cheung A, Lichtenstein SV, et al. Six-month outcome of transapical transcatheter aortic valve implantation in the initial seven patients. Eur J Cardiothorac Surg 2007; 31:16–21.
- Turgut T, Deeb M, Moscucci M. Left ventricular apical puncture: a procedure surviving well into the new millennium. Catheter Cardiovasc Interv 2000; 49:68–73.
- Zuguchi M, Shindoh C, Chida K, et al. Safety and clinical benefits of transsubxiphoidal left ventricular puncture. Catheter Cardiovasc Interv 2002; 55:58–65.
- Sinha AK, Kini AS, Sharma SK. Percutaneous valve replacement: a paradigm shift. Curr Opin Cardiol 2007; 22:471–477.
- Wenaweser P, Buellesfeld L, Gerckens U, Grube E. Percutaneous aortic valve replacement for severe aortic regurgitation in degenerated bioprosthesis: the first valve in valve procedure using the CoreValve ReValving system. Catheter Cardiovasc Interv 2007; 70:760–764.
- Pasupati S, Humphries K, AlAli A, et al. Balloon expandable aortic valve (BEAV) implantation. The first 100 Canadian patients. Circulation 2007; 116 suppl:357.
- Walther T, Falk V, Kempfert J, et al. Transapical minimally invasive aortic valve implantation; the initial 50 patients. Eur J Cardiothorac Surg 2008; 33:983–988. Epub 2008 February 21.
- Carabello BA. Clinical practice. Aortic stenosis. N Engl J Med 2002; 346:677–682.
- Pellikka PA, Nishimura RA, Bailey KR, Tajik AJ. The natural history of adults with asymptomatic, hemodynamically significant aortic stenosis. J Am Coll Cardiol 1990; 15:1012–1017.
- Ross J, Braunwald E. Aortic stenosis. Circulation 1968; 38:61–67.
- Kvidal P, Bergstrom R, Horte LG, Stahle E. Observed and relative survival after aortic valve replacement. J Am Coll Cardiol 2000; 35:747–756.
- Society of Thoracic Surgeons National Cardiac Surgery Database. Available at www.sts.org/documents/pdf/Spring2005STS-ExecutiveSummary.pdf. Accessed 9/11/2008.
- Birkmeyer JD, Siewers AE, Finlayson EV, et al. Hospital volume and surgical mortality in the United States. N Engl J Med 2002; 346:1128–1137.
- Wenger NK, Weber MA, Scheidt S. Valvular heart disease at elderly age: new vistas. Am J Geriatr Cardiol 2006; 15:273–274.
Stenosis of the aortic valve has a long, latent, asymptomatic phase, but when symptoms finally occur, clinical deterioration can be rapid. For patients with severe stenosis, the standard treatment has long been replacement of the aortic valve via open heart surgery. But many patients with severe stenosis are considered too high-risk for this procedure.
Until about 5 years ago, these patients had no other option but medical therapy or percutaneous aortic balloon valvuloplasty as a palliative measure or as a bridge to open heart surgery. But 5 years of experience with percutaneous techniques to implant prosthetic aortic valves show that this less-invasive approach may become a viable option for patients with severe symptomatic aortic valve stenosis.
In this review, we discuss current prosthetic valves and percutaneous techniques and their relative advantages and limitations and the potential future role of this new treatment option.
THE NEED FOR A LESS-INVASIVE APPROACH
Calcific aortic stenosis is the most common valvular heart disease, affecting 2% to 4% of adults over age 65 in the United States alone.1,2 The aging of our population and the lack of drug therapies to prevent, halt, or effectively slow aortic valve stenosis are leading to a greater burden of this condition.1,3,4 Already in the United States more than 50,000 surgical aortic valve replacements are performed every year for severe aortic stenosis.1,2 The associated in-hospital death rate is 8.8% in patients over age 65 years, and as high as 13% in low-volume centers.1,5
The steady increase in the number of patients requiring aortic valve replacement, the high surgical risk in patients with multiple comorbidities, the reluctance of some patients to undergo the trauma and pain associated with open heart surgery via sternotomy, and the fact that percutaneous procedures are less traumatic and offer faster recovery and fewer hospital days—all these are forces that have been driving the development of percutaneous techniques for the treatment of aortic stenosis.6–11 In addition, a recent study12 showed that 33% of patients over age 75 were deemed too high-risk for open heart surgery and thus were left untreated.12
The evolution of percutaneous aortic valve replacement
The idea of percutaneous treatment of aortic stenosis was first put into clinical practice in 1985, when Cribier performed an aortic balloon valvuloplasty.6 This was followed in 200013 by the first successful implantation of a catheter-based stent valve in a human, and in 2002 by the first successful percutaneous aortic valve replacement in a human.13–15 In the following sections, we discuss the percutaneous approaches in current use for the treatment of degenerative aortic stenosis.
AORTIC BALLOON VALVULOPLASTY
Percutaneous aortic balloon valvuloplasty, partial dilation of the stenotic aortic valve with a balloon inserted via a catheter,1,16–19 improves symptoms but has failed to show a sustained benefit on rates of mortality or morbidity.1,16–18 The restenosis rate is high, and symptoms recur in most patients within months to a year.1,16–18 Procedural complication rates are about 10%, and complication rates at the catheter access site are even higher.1,16–18 The 30-day death rate in the National Heart, Lung, and Blood Institute’s Balloon Valvuloplasty Registry, which included more than 600 patients, was 14%.18 In a retrospective study of 212 patients who underwent single or repeat percutaneous aortic balloon valvuloplasty,20 the 1-year mortality rate was 36% for the entire cohort, with a median survival of 3 years. Patients who underwent a repeat procedure (33%) had 1-year mortality rate of 42%, compared with 16% in patients who did not undergo a repeat procedure.20
Percutaneous aortic balloon valvuloplasty serves best as palliative therapy in severely symptomatic patients, and as a bridge to surgery in hemodynamically unstable adult patients.21,22 Percutaneous aortic balloon valvuloplasty is not an option in patients who are good candidates for surgical valve replacement.1
PERCUTANEOUS AORTIC VALVE REPLACEMENT: THREE TECHNIQUES
The antegrade technique
In the antegrade technique, an approach that has been studied but is no longer being used, access to the femoral vein is gained and the catheter with the prosthetic aortic valve is advanced, traversing the interatrial septum and the mitral valve, and is positioned within the diseased aortic valve.15,23,24 The main advantage of this approach is that the femoral vein can accommodate the large catheter sheath and that subsequent management of the access site is by manual compression only.15,23,24 The main disadvantages are the potential for mitral valve injury and severe mitral regurgitation, and the technical challenge of delivering the aortic valve prosthesis to the correct aortic position.15,23,25–27
The retrograde technique
In the retrograde (ie, transfemoral) technique, access to the femoral artery is gained and the catheter with the prosthetic aortic valve is advanced to the stenotic aortic valve.8,11,26,28–30 This approach is faster and technically easier than the antegrade approach, but it can be associated with injury to the aortofemoral vessels and with failure of the prosthesis to cross the aortic arch or the stenotic aortic valve.11,23,30
The transapical technique
In the transapical technique, the valve delivery system is inserted via a small incision made between the ribs. The apex of the left ventricle is punctured with a needle, and the prosthetic valve is positioned within the stenotic aortic valve.27,31–33 The main advantage of this approach is that it allows more direct access to the aortic valve and eliminates the need for a large peripheral vascular access site in patients with peripheral vascular disease, small tortuous vasculature, or a history of major vascular complications or vascular repairs.31–33 Potential disadvantages are related to the left ventricular apical puncture and include adverse ventricular remodeling, left ventricular aneurysm or pseudoaneurysm, pericardial complications, pneumothorax, malignant ventricular arrhythmias, coronary artery injury, and the need for general anesthesia and chest tubes.27,31–35
Common features of the three approaches
The three percutaneous approaches have certain final steps in common.11,23,30,33 The position of final deployment of the prosthetic valve is determined by the patient’s native valvular structure and anatomy and is optimized by using fluoroscopic imaging of the native aortic valve calcification as an anatomical marker, along with guidance from supra-aortic angiography and transesophageal echocardiography.11,23,30,33 Ideally, the aortic valve prosthesis is placed at mid-position in the patient’s aortic valve, taking care to not to impinge on the coronary ostia or to impede the motion of the anterior mitral leaflet.11,23,30,33 In all three procedures, the prosthesis is then deployed by maximally inflating, rapidly deflating, and immediately withdrawing the delivery balloon. This final step is carried out during temporary high-rate right ventricular apical pacing, which produces ventricular tachycardia at 180 to 220 beats/min for up to 10 seconds.11,23,30,33 This leads to an immediate decrease in stroke volume, resulting in minimal forward flow through the aortic valve, which in turn facilitates precise positioning of the prosthetic valve.
So far, only the Cribier-Edwards valve has been deployed via all three techniques. The CoreValve has been deployed only via the retrograde technique. The Edwards SAPIEN valve has been deployed with retrograde and transapical approaches (see www.edwards.com/Products/TranscatheterValves/SapienTHV.htm and www.corevalve.com for animations depicting these techniques).
EXPERIENCE WITH THE CRIBIER-EDWARDS VALVE
The Cribier-Edwards valve has three leaflets made from equine pericardial tissue sutured inside a balloon-expandable stainless steel 14-mm stent (Table 1).11,23,33 With the use of a specially designed mechanical crimping device, the aortic valve prosthesis is mounted over a 3-cm-long balloon catheter, expandable to a diameter of 22 to 26 mm (NuMed Inc, Hopkinton, NY).11,23,30,33
After this prosthesis was tested in animal models,14,15 a trial for compassionate use in humans was begun, called the Initial Registry of Endovascular Implantation of Valves in Europe (I-REVIVE) trial. This trial was later continued as the Registry of Endovascular Critical Aortic Stenosis Treatment (RECAST) trial.23 All patients were formally evaluated by two cardio-thoracic surgeons and were deemed inappropriate for surgical aortic valve replacement.23
The success rate with the antegrade percutaneous approach was 85% (23 of 27 patients) and 57% for the retrograde approach (4 of 7 patients).11,23,30–33 Procedural limitations were migration or embolization of the prosthetic valve, failure to cross the stenotic aortic valve, and paravalvular aortic regurgitation.23 Anatomic and functional success was evidenced by improvement in aortic valve area, increase in left ventricular ejection fraction, and improved New York Heart Association functional class, all of which were sustained at up to 24 months.23
Webb et al11 reported similar results with retrograde implantation of the Cribier-Edwards valve in a cohort of 50 patients.11 The main difference between the two studies was the expected occurrence of aortofemoral complications with the retrograde approach.11,26 Procedural success increased from 76% in the first 25 patients to 96% in the second 25, and the 30-day mortality rate fell from 16% to 8%, which reflected the learning curve. Importantly, no patients needed conversion to open surgery during the first 30 days, and at a median follow-up of 359 days 35 (81%) of 43 patients who underwent successful transcatheter aortic valve replacement were still alive.11 Additionally, significant improvement was noted in left ventricular ejection fraction, mitral regurgitation, and New York Heart Association functional class, and these improvements persisted at 1 year.11
Lichtenstein et al31 and Walther et al32 successfully implanted the Cribier-Edwards valve using the transapical approach in a very high-risk elderly population with poor functional class. All patients were deemed unsuitable for standard surgical valve replacement and also for percutaneous transfemoral aortic valve implantation because of severe aorto-iliac disease. In both studies, the short-term and mid-term results were encouraging.
These experiences with the Cribier-Edwards valve showed that device- and technique-related shortcomings could be addressed. To date, more than 500 percutaneous aortic valve replacement procedures have been done with the Cribier-Edwards valve worldwide, with a greater than 95% technical success rate in the latest cohorts.36 Importantly, use of a larger (26-mm) prosthetic valve has been associated with a lower rate of prosthetic valve migration or embolization, and with a significantly lower rate of paravalvular aortic regurgitation.11,23
EXPERIENCE WITH THE COREVALVE SYSTEM
The CoreValve ReValving system is based on retrograde implantation of the CoreValve prosthesis—a self-expanding aortic valve prosthesis composed of three bovine pericardial leaflets mounted and sutured within a self-expanding 50-mm-long nitinol stent (Table 1).28–30 The inner diameter is 21 to 22 mm.28–30 This prosthesis has three distinct structural segments.28–30 The bottom portion exerts a high radial force that expands and pushes aside the calcified leaflets and avoids recoil; the central portion carries the valve, and it tapers to avoid the coronary artery ostia; and the upper portion flares to fixate and stabilize the deployed aortic valve prosthesis in the ascending aorta, thus preventing migration or embolization of the device.28–30 The main difference between the CoreValve and the Cribier-Edwards valve is that the Core-Valve is self-expanding, which theoretically permits it to conform to different aortic sizes and to anchor well in the aortic annulus.28–30 This feature allows the CoreValve to be used in patients with severe aortic insufficiency and other noncalcific aortic valvular conditions. The CoreValve has not yet been deployed via antegrade or transapical technique.
The first-generation CoreValve prosthesis was first implanted in a human recipient in 2005.29 Since then, improvements have been made, leading to the development of second- and third-generation devices. A pilot study of implantation of the first-generation CoreValve28 via the retrograde approach in elderly patients with poor functional class and severe aortic stenosis had a short-term procedural success rate of 84% (21 of 25 patients), with a significant reduction in the mean aortic valve gradient and improved functional class at 30-day follow-up.28 At 30 days, 17 (94%) of 18 patients had no or only mild aortic regurgitation.28 Procedural limitations and complications were similar to those with the Cribier-Edwards valve.
In a study of second- and third-generation devices (50 patients received a second-generation device, and 36 received a third-generation device),30 again in elderly patients with poor functional class and severe aortic stenosis, the short-term success rate of the device was 88% (76 of 86) in each group. After the procedure, the mean aortic valve gradient decreased significantly and functional class improved significantly.30 Immediate after implantation, no patient had more than moderate aortic regurgitation, and in 51 patients (66%) the aortic regurgitation remained unchanged or improved after CoreValve implantation.30 These results were maintained at 30-day follow-up.
CoreValve was approved in May 2007 for clinical use in Europe.36 Of note, CoreValve has also been used to treat severe aortic regurgitation of a degenerated bioprosthetic aortic valve in an 80-year-old man with multiple comorbidities.37
EXPERIENCE WITH THE EDWARDS SAPIEN VALVE
The Edwards SAPIEN valve is a modification of the initial Cribier-Edwards valve and is the latest percutaneous aortic valve prosthesis to enter clinical trials (Table 1). It is a trileaflet balloon-expandable stainless steel valve made from bovine pericardial tissue, available in two sizes (23 mm and 26 mm). In September 2007, it was approved for use in Europe with the RetroFlex transfemoral delivery system. The Ascendra transapical delivery system for the Edward SAPIEN valve has received approval in Europe.
The multicenter Placement of Aortic Transcatheter Valves (PARTNER) trial in North America is continuing to enroll patients, with enrollment projected to be complete by the end of 2008. The aim of this prospective randomized clinical trial is to enroll 1,040 patients in two separate treatment arms. The surgical arm of the trial is comparing the Edwards SAPIEN valve with standard surgical aortic valve replacement, with the objective of demonstrating non-inferiority. The medical management arm of the trial is comparing percutaneous valve replacement against medical therapy or balloon valvuloplasty in patients considered too high-risk for conventional surgical valve replacement.
The primary end point in both arms is death at 1 year; secondary end points focus on long-term (1-year) composite cardiovascular events, valve performance, and quality-of-life indicators. Preliminary data on the first 100 patients (74 via the transfemoral [ie, retrograde] and 26 via the transapical approach) who underwent percutaneous Edwards SAPIEN valve implantation for compassionate use showed device durability and symptom relief at up to 2 years.38 Overall procedural success was 91%, but, as with other trials, there was a steep learning curve, so that excluding the first 25 patients increased the procedural success rate to 96%.38 Aortic valve size and hemodynamics, left ventricular systolic function, mitral regurgitation, and functional class were all significantly improved. Mild aortic regurgitation was common, but none of the patients had severe aortic regurgitation. Importantly, the 15% 30-day death rate was significantly lower than the expected rate of 33%. The 6-month survival rate was 78%, but the 2-year rate was 60% in this high-risk elderly cohort.
Walther et al39 recently reported outcomes on their first 50 patients who underwent transapical implantation of the Edwards SAPIEN valve. The operators were able to implant the prosthesis in all 50 patients, but 3 required early conversion to open surgery with sternotomy. The overall survival at 30 days was 92%, but in the last 25 patients the 30-day survival rate was 96%, with a 1-year survival rate of 80%.
PUTTING THE DATA IN PERSPECTIVE
As noted in this review, a number of factors make a strong case for timely aortic valve replacement: the aging population, the increase in incidence and prevalence of aortic stenosis,1,3,4,27,40 the multiple comorbidities in older patients, and the eventually aggressive natural course of aortic stenosis.1,3,4,27,40–43 Yet current standards dictate not to proceed with standard surgical aortic valve replacement in patients who are truly asymptomatic and who have normal left ventricular systolic function,1,40 mainly because the risks of surgical valve replacement outweigh the benefits in this population.1,40 Aortic valve surgery carries a risk of early death of 15% for patients ages 80 to 84 and of 18% for patients age 85.3,9,10,12,43–45
These figures seem high when compared with death rates of 12% in recent studies of percutaneous valve replacement in similar patients.11,23,30,33 The rates become lower as the learning curve improves.11,21,23,27,30,33 Thus, as the design of aortic valve prostheses and the techniques to implant them are refined and tested for safety, the risk-benefit balance may change in favor of earlier intervention in aortic stenosis with a percutaneous approach.11,21,27,46 Some experts believe that in 10 years 10% to 30% of patients undergoing conventional valve replacement will be candidates for a percutaneous approach.
Of the techniques used to date, the retrograde approach seems most amenable to widespread acceptance, given its inherent advantage of being faster and easier.11,21,30 Limitations with the retrograde approach seen in earlier trials—challenges and complications associated with large-bore arterial vascular access, difficulty traversing the aortic arch with bulky devices, and the inability to cross the stenotic aortic valve to deploy the prosthesis even after balloon valvuloplasty11,21,30—are correctable with refinements in the devices and in technique.
New types of prosthetic aortic valves entering early human studies are improving on current devices, for example, by using collapsible, inflatable valve frames for retrievability before final deployment.
Surgical aortic valve replacement remains the gold standard treatment for patients with symptomatic aortic stenosis. And while studies of percutaneous aortic valve replacement show great promise for this less-invasive treat-men, enthusiasm about percutaneous aortic valve replacement should be tempered by an awareness of persistent limitations of this approach, such as vascular and mechanical complications and operator inexperience, which still need attention.
Stenosis of the aortic valve has a long, latent, asymptomatic phase, but when symptoms finally occur, clinical deterioration can be rapid. For patients with severe stenosis, the standard treatment has long been replacement of the aortic valve via open heart surgery. But many patients with severe stenosis are considered too high-risk for this procedure.
Until about 5 years ago, these patients had no other option but medical therapy or percutaneous aortic balloon valvuloplasty as a palliative measure or as a bridge to open heart surgery. But 5 years of experience with percutaneous techniques to implant prosthetic aortic valves show that this less-invasive approach may become a viable option for patients with severe symptomatic aortic valve stenosis.
In this review, we discuss current prosthetic valves and percutaneous techniques and their relative advantages and limitations and the potential future role of this new treatment option.
THE NEED FOR A LESS-INVASIVE APPROACH
Calcific aortic stenosis is the most common valvular heart disease, affecting 2% to 4% of adults over age 65 in the United States alone.1,2 The aging of our population and the lack of drug therapies to prevent, halt, or effectively slow aortic valve stenosis are leading to a greater burden of this condition.1,3,4 Already in the United States more than 50,000 surgical aortic valve replacements are performed every year for severe aortic stenosis.1,2 The associated in-hospital death rate is 8.8% in patients over age 65 years, and as high as 13% in low-volume centers.1,5
The steady increase in the number of patients requiring aortic valve replacement, the high surgical risk in patients with multiple comorbidities, the reluctance of some patients to undergo the trauma and pain associated with open heart surgery via sternotomy, and the fact that percutaneous procedures are less traumatic and offer faster recovery and fewer hospital days—all these are forces that have been driving the development of percutaneous techniques for the treatment of aortic stenosis.6–11 In addition, a recent study12 showed that 33% of patients over age 75 were deemed too high-risk for open heart surgery and thus were left untreated.12
The evolution of percutaneous aortic valve replacement
The idea of percutaneous treatment of aortic stenosis was first put into clinical practice in 1985, when Cribier performed an aortic balloon valvuloplasty.6 This was followed in 200013 by the first successful implantation of a catheter-based stent valve in a human, and in 2002 by the first successful percutaneous aortic valve replacement in a human.13–15 In the following sections, we discuss the percutaneous approaches in current use for the treatment of degenerative aortic stenosis.
AORTIC BALLOON VALVULOPLASTY
Percutaneous aortic balloon valvuloplasty, partial dilation of the stenotic aortic valve with a balloon inserted via a catheter,1,16–19 improves symptoms but has failed to show a sustained benefit on rates of mortality or morbidity.1,16–18 The restenosis rate is high, and symptoms recur in most patients within months to a year.1,16–18 Procedural complication rates are about 10%, and complication rates at the catheter access site are even higher.1,16–18 The 30-day death rate in the National Heart, Lung, and Blood Institute’s Balloon Valvuloplasty Registry, which included more than 600 patients, was 14%.18 In a retrospective study of 212 patients who underwent single or repeat percutaneous aortic balloon valvuloplasty,20 the 1-year mortality rate was 36% for the entire cohort, with a median survival of 3 years. Patients who underwent a repeat procedure (33%) had 1-year mortality rate of 42%, compared with 16% in patients who did not undergo a repeat procedure.20
Percutaneous aortic balloon valvuloplasty serves best as palliative therapy in severely symptomatic patients, and as a bridge to surgery in hemodynamically unstable adult patients.21,22 Percutaneous aortic balloon valvuloplasty is not an option in patients who are good candidates for surgical valve replacement.1
PERCUTANEOUS AORTIC VALVE REPLACEMENT: THREE TECHNIQUES
The antegrade technique
In the antegrade technique, an approach that has been studied but is no longer being used, access to the femoral vein is gained and the catheter with the prosthetic aortic valve is advanced, traversing the interatrial septum and the mitral valve, and is positioned within the diseased aortic valve.15,23,24 The main advantage of this approach is that the femoral vein can accommodate the large catheter sheath and that subsequent management of the access site is by manual compression only.15,23,24 The main disadvantages are the potential for mitral valve injury and severe mitral regurgitation, and the technical challenge of delivering the aortic valve prosthesis to the correct aortic position.15,23,25–27
The retrograde technique
In the retrograde (ie, transfemoral) technique, access to the femoral artery is gained and the catheter with the prosthetic aortic valve is advanced to the stenotic aortic valve.8,11,26,28–30 This approach is faster and technically easier than the antegrade approach, but it can be associated with injury to the aortofemoral vessels and with failure of the prosthesis to cross the aortic arch or the stenotic aortic valve.11,23,30
The transapical technique
In the transapical technique, the valve delivery system is inserted via a small incision made between the ribs. The apex of the left ventricle is punctured with a needle, and the prosthetic valve is positioned within the stenotic aortic valve.27,31–33 The main advantage of this approach is that it allows more direct access to the aortic valve and eliminates the need for a large peripheral vascular access site in patients with peripheral vascular disease, small tortuous vasculature, or a history of major vascular complications or vascular repairs.31–33 Potential disadvantages are related to the left ventricular apical puncture and include adverse ventricular remodeling, left ventricular aneurysm or pseudoaneurysm, pericardial complications, pneumothorax, malignant ventricular arrhythmias, coronary artery injury, and the need for general anesthesia and chest tubes.27,31–35
Common features of the three approaches
The three percutaneous approaches have certain final steps in common.11,23,30,33 The position of final deployment of the prosthetic valve is determined by the patient’s native valvular structure and anatomy and is optimized by using fluoroscopic imaging of the native aortic valve calcification as an anatomical marker, along with guidance from supra-aortic angiography and transesophageal echocardiography.11,23,30,33 Ideally, the aortic valve prosthesis is placed at mid-position in the patient’s aortic valve, taking care to not to impinge on the coronary ostia or to impede the motion of the anterior mitral leaflet.11,23,30,33 In all three procedures, the prosthesis is then deployed by maximally inflating, rapidly deflating, and immediately withdrawing the delivery balloon. This final step is carried out during temporary high-rate right ventricular apical pacing, which produces ventricular tachycardia at 180 to 220 beats/min for up to 10 seconds.11,23,30,33 This leads to an immediate decrease in stroke volume, resulting in minimal forward flow through the aortic valve, which in turn facilitates precise positioning of the prosthetic valve.
So far, only the Cribier-Edwards valve has been deployed via all three techniques. The CoreValve has been deployed only via the retrograde technique. The Edwards SAPIEN valve has been deployed with retrograde and transapical approaches (see www.edwards.com/Products/TranscatheterValves/SapienTHV.htm and www.corevalve.com for animations depicting these techniques).
EXPERIENCE WITH THE CRIBIER-EDWARDS VALVE
The Cribier-Edwards valve has three leaflets made from equine pericardial tissue sutured inside a balloon-expandable stainless steel 14-mm stent (Table 1).11,23,33 With the use of a specially designed mechanical crimping device, the aortic valve prosthesis is mounted over a 3-cm-long balloon catheter, expandable to a diameter of 22 to 26 mm (NuMed Inc, Hopkinton, NY).11,23,30,33
After this prosthesis was tested in animal models,14,15 a trial for compassionate use in humans was begun, called the Initial Registry of Endovascular Implantation of Valves in Europe (I-REVIVE) trial. This trial was later continued as the Registry of Endovascular Critical Aortic Stenosis Treatment (RECAST) trial.23 All patients were formally evaluated by two cardio-thoracic surgeons and were deemed inappropriate for surgical aortic valve replacement.23
The success rate with the antegrade percutaneous approach was 85% (23 of 27 patients) and 57% for the retrograde approach (4 of 7 patients).11,23,30–33 Procedural limitations were migration or embolization of the prosthetic valve, failure to cross the stenotic aortic valve, and paravalvular aortic regurgitation.23 Anatomic and functional success was evidenced by improvement in aortic valve area, increase in left ventricular ejection fraction, and improved New York Heart Association functional class, all of which were sustained at up to 24 months.23
Webb et al11 reported similar results with retrograde implantation of the Cribier-Edwards valve in a cohort of 50 patients.11 The main difference between the two studies was the expected occurrence of aortofemoral complications with the retrograde approach.11,26 Procedural success increased from 76% in the first 25 patients to 96% in the second 25, and the 30-day mortality rate fell from 16% to 8%, which reflected the learning curve. Importantly, no patients needed conversion to open surgery during the first 30 days, and at a median follow-up of 359 days 35 (81%) of 43 patients who underwent successful transcatheter aortic valve replacement were still alive.11 Additionally, significant improvement was noted in left ventricular ejection fraction, mitral regurgitation, and New York Heart Association functional class, and these improvements persisted at 1 year.11
Lichtenstein et al31 and Walther et al32 successfully implanted the Cribier-Edwards valve using the transapical approach in a very high-risk elderly population with poor functional class. All patients were deemed unsuitable for standard surgical valve replacement and also for percutaneous transfemoral aortic valve implantation because of severe aorto-iliac disease. In both studies, the short-term and mid-term results were encouraging.
These experiences with the Cribier-Edwards valve showed that device- and technique-related shortcomings could be addressed. To date, more than 500 percutaneous aortic valve replacement procedures have been done with the Cribier-Edwards valve worldwide, with a greater than 95% technical success rate in the latest cohorts.36 Importantly, use of a larger (26-mm) prosthetic valve has been associated with a lower rate of prosthetic valve migration or embolization, and with a significantly lower rate of paravalvular aortic regurgitation.11,23
EXPERIENCE WITH THE COREVALVE SYSTEM
The CoreValve ReValving system is based on retrograde implantation of the CoreValve prosthesis—a self-expanding aortic valve prosthesis composed of three bovine pericardial leaflets mounted and sutured within a self-expanding 50-mm-long nitinol stent (Table 1).28–30 The inner diameter is 21 to 22 mm.28–30 This prosthesis has three distinct structural segments.28–30 The bottom portion exerts a high radial force that expands and pushes aside the calcified leaflets and avoids recoil; the central portion carries the valve, and it tapers to avoid the coronary artery ostia; and the upper portion flares to fixate and stabilize the deployed aortic valve prosthesis in the ascending aorta, thus preventing migration or embolization of the device.28–30 The main difference between the CoreValve and the Cribier-Edwards valve is that the Core-Valve is self-expanding, which theoretically permits it to conform to different aortic sizes and to anchor well in the aortic annulus.28–30 This feature allows the CoreValve to be used in patients with severe aortic insufficiency and other noncalcific aortic valvular conditions. The CoreValve has not yet been deployed via antegrade or transapical technique.
The first-generation CoreValve prosthesis was first implanted in a human recipient in 2005.29 Since then, improvements have been made, leading to the development of second- and third-generation devices. A pilot study of implantation of the first-generation CoreValve28 via the retrograde approach in elderly patients with poor functional class and severe aortic stenosis had a short-term procedural success rate of 84% (21 of 25 patients), with a significant reduction in the mean aortic valve gradient and improved functional class at 30-day follow-up.28 At 30 days, 17 (94%) of 18 patients had no or only mild aortic regurgitation.28 Procedural limitations and complications were similar to those with the Cribier-Edwards valve.
In a study of second- and third-generation devices (50 patients received a second-generation device, and 36 received a third-generation device),30 again in elderly patients with poor functional class and severe aortic stenosis, the short-term success rate of the device was 88% (76 of 86) in each group. After the procedure, the mean aortic valve gradient decreased significantly and functional class improved significantly.30 Immediate after implantation, no patient had more than moderate aortic regurgitation, and in 51 patients (66%) the aortic regurgitation remained unchanged or improved after CoreValve implantation.30 These results were maintained at 30-day follow-up.
CoreValve was approved in May 2007 for clinical use in Europe.36 Of note, CoreValve has also been used to treat severe aortic regurgitation of a degenerated bioprosthetic aortic valve in an 80-year-old man with multiple comorbidities.37
EXPERIENCE WITH THE EDWARDS SAPIEN VALVE
The Edwards SAPIEN valve is a modification of the initial Cribier-Edwards valve and is the latest percutaneous aortic valve prosthesis to enter clinical trials (Table 1). It is a trileaflet balloon-expandable stainless steel valve made from bovine pericardial tissue, available in two sizes (23 mm and 26 mm). In September 2007, it was approved for use in Europe with the RetroFlex transfemoral delivery system. The Ascendra transapical delivery system for the Edward SAPIEN valve has received approval in Europe.
The multicenter Placement of Aortic Transcatheter Valves (PARTNER) trial in North America is continuing to enroll patients, with enrollment projected to be complete by the end of 2008. The aim of this prospective randomized clinical trial is to enroll 1,040 patients in two separate treatment arms. The surgical arm of the trial is comparing the Edwards SAPIEN valve with standard surgical aortic valve replacement, with the objective of demonstrating non-inferiority. The medical management arm of the trial is comparing percutaneous valve replacement against medical therapy or balloon valvuloplasty in patients considered too high-risk for conventional surgical valve replacement.
The primary end point in both arms is death at 1 year; secondary end points focus on long-term (1-year) composite cardiovascular events, valve performance, and quality-of-life indicators. Preliminary data on the first 100 patients (74 via the transfemoral [ie, retrograde] and 26 via the transapical approach) who underwent percutaneous Edwards SAPIEN valve implantation for compassionate use showed device durability and symptom relief at up to 2 years.38 Overall procedural success was 91%, but, as with other trials, there was a steep learning curve, so that excluding the first 25 patients increased the procedural success rate to 96%.38 Aortic valve size and hemodynamics, left ventricular systolic function, mitral regurgitation, and functional class were all significantly improved. Mild aortic regurgitation was common, but none of the patients had severe aortic regurgitation. Importantly, the 15% 30-day death rate was significantly lower than the expected rate of 33%. The 6-month survival rate was 78%, but the 2-year rate was 60% in this high-risk elderly cohort.
Walther et al39 recently reported outcomes on their first 50 patients who underwent transapical implantation of the Edwards SAPIEN valve. The operators were able to implant the prosthesis in all 50 patients, but 3 required early conversion to open surgery with sternotomy. The overall survival at 30 days was 92%, but in the last 25 patients the 30-day survival rate was 96%, with a 1-year survival rate of 80%.
PUTTING THE DATA IN PERSPECTIVE
As noted in this review, a number of factors make a strong case for timely aortic valve replacement: the aging population, the increase in incidence and prevalence of aortic stenosis,1,3,4,27,40 the multiple comorbidities in older patients, and the eventually aggressive natural course of aortic stenosis.1,3,4,27,40–43 Yet current standards dictate not to proceed with standard surgical aortic valve replacement in patients who are truly asymptomatic and who have normal left ventricular systolic function,1,40 mainly because the risks of surgical valve replacement outweigh the benefits in this population.1,40 Aortic valve surgery carries a risk of early death of 15% for patients ages 80 to 84 and of 18% for patients age 85.3,9,10,12,43–45
These figures seem high when compared with death rates of 12% in recent studies of percutaneous valve replacement in similar patients.11,23,30,33 The rates become lower as the learning curve improves.11,21,23,27,30,33 Thus, as the design of aortic valve prostheses and the techniques to implant them are refined and tested for safety, the risk-benefit balance may change in favor of earlier intervention in aortic stenosis with a percutaneous approach.11,21,27,46 Some experts believe that in 10 years 10% to 30% of patients undergoing conventional valve replacement will be candidates for a percutaneous approach.
Of the techniques used to date, the retrograde approach seems most amenable to widespread acceptance, given its inherent advantage of being faster and easier.11,21,30 Limitations with the retrograde approach seen in earlier trials—challenges and complications associated with large-bore arterial vascular access, difficulty traversing the aortic arch with bulky devices, and the inability to cross the stenotic aortic valve to deploy the prosthesis even after balloon valvuloplasty11,21,30—are correctable with refinements in the devices and in technique.
New types of prosthetic aortic valves entering early human studies are improving on current devices, for example, by using collapsible, inflatable valve frames for retrievability before final deployment.
Surgical aortic valve replacement remains the gold standard treatment for patients with symptomatic aortic stenosis. And while studies of percutaneous aortic valve replacement show great promise for this less-invasive treat-men, enthusiasm about percutaneous aortic valve replacement should be tempered by an awareness of persistent limitations of this approach, such as vascular and mechanical complications and operator inexperience, which still need attention.
- Bonow RO, Carabello BA, Kanu C, et al. ACC/AHA 2006 guidelines for the management of patients with valvular heart disease: a report of the American College of Cardiology/American Heart Association Task Force on Practice Guidelines (writing committee to revise the 1998 Guidelines for the Management of Patients With Valvular Heart Disease): developed in collaboration with the Society of Cardiovascular Anesthesiologists: endorsed by the Society for Cardiovascular Angiography and Interventions and the Society of Thoracic Surgeons. Circulation 2006; 114:e84–231.
- Freeman RV, Otto CM. Spectrum of calcific aortic valve disease: pathogenesis, disease progression, and treatment strategies. Circulation 2005; 111:3316–3326.
- Iung B, Baron G, Butchart EG, et al. A prospective survey of patients with valvular heart disease in Europe: The Euro Heart Survey on Valvular Heart Disease. Eur Heart J 2003; 24:1231–1243.
- Nkomo VT, Gardin JM, Skelton TN, Gottdiener JS, Scott CG, Enriquez-Sarano M. Burden of valvular heart diseases: a population-based study. Lancet 2006; 368:1005–1011.
- Goodney PP, O'Connor GT, Wennberg DE, Birkmeyer JD. Do hospitals with low mortality rates in coronary artery bypass also perform well in valve replacement? Ann Thorac Surg 2003; 76:1131–1137.
- Cribier A, Savin T, Saoudi N, Rocha P, Berland J, Letac B. Percutaneous transluminal valvuloplasty of acquired aortic stenosis in elderly patients: an alternative to valve replacement? Lancet 1986; 1:63–67.
- Vahanian A, Palacios IF. Percutaneous approaches to valvular disease. Circulation 2004; 109:1572–1579.
- Webb JG, Munt B, Makkar RR, Naqvi TZ, Dang N. Percutaneous stent-mounted valve for treatment of aortic or pulmonary valve disease. Catheter Cardiovasc Interv 2004; 63:89–93.
- Alexander KP, Anstrom KJ, Muhlbaier LH, et al. Outcomes of cardiac surgery in patients =80 years: results from the National Cardiovascular Network. J Am Coll Cardiol 2000; 35:731–738.
- Mittermair RP, Muller LC. Quality of life after cardiac surgery in the elderly. J Cardiovasc Surg (Torino) 2002; 43:43–47.
- Webb JG, Pasupati S, Humphries K, et al. Percutaneous transarterial aortic valve replacement in selected high-risk patients with aortic stenosis. Circulation 2007; 116:755–763.
- Iung B, Cachier A, Baron G, et al. Decision-making in elderly patients with severe aortic stenosis: why are so many denied surgery? Eur Heart J 2005; 26:2714–2720.
- Bonhoeffer P, Boudjemline Y, Saliba Z, et al. Percutaneous replacement of pulmonary valve in a right-ventricle to pulmonary-artery prosthetic conduit with valve dysfunction. Lancet 2000; 356:1403–1405.
- Andersen HR, Knudsen LL, Hasenkam JM. Transluminal implantation of artificial heart valves. Description of a new expandable aortic valve and initial results with implantation by catheter technique in closed chest pigs. Eur Heart J 1992; 13:704–708.
- Cribier A, Eltchaninoff H, Bash A, et al. Percutaneous transcatheter implantation of an aortic valve prosthesis for calcific aortic stenosis: first human case description. Circulation 2002; 106:3006–3008.
- Otto CM, Mickel MC, Kennedy JW, et al. Three-year outcome after balloon aortic valvuloplasty. Insights into prognosis of valvular aortic stenosis. Circulation 1994; 89:642–650.
- Safian RD, Berman AD, Diver DJ, et al. Balloon aortic valvuloplasty in 170 consecutive patients. N Engl J Med 1988; 319:125–130.
- Percutaneous balloon aortic valvuloplasty. Acute and 30-day follow-up results in 674 patients from the NHLBI Balloon Valvuloplasty Registry. Circulation 1991; 84:2383–2397.
- Safian RD, Mandell VS, Thurer RE, et al. Postmortem and intraoperative balloon valvuloplasty of calcific aortic stenosis in elderly patients: mechanisms of successful dilation. J Am Coll Cardiol 1987; 9:655–660.
- Agarwal A, Kini AS, Attanti S, et al. Results of repeat balloon valvuloplasty for treatment of aortic stenosis in patients aged 59 to 104 years. Am J Cardiol 2005; 95:43–47.
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- Rajagopal V, Kapadia SR, Tuzcu EM. Advances in the percutaneous treatment of aortic and mitral valve disease. Minerva Cardioangiol 2007; 55:83–94.
- Webb JG, Chandavimol M, Thompson CR, et al. Percutaneous aortic valve implantation retrograde from the femoral artery. Circulation 2006; 113:842–850.
- Salemi A. Percutaneous valve interventions. Curr Opin Anaesthesiol 2007; 20:70–74.
- Grube E, Laborde JC, Gerckens U, et al. Percutaneous implantation of the CoreValve self-expanding valve prosthesis in high-risk patients with aortic valve disease: the Siegburg first-in-man study. Circulation 2006; 114:1616–1624.
- Grube E, Laborde JC, Zickmann B, et al. First report on a human percutaneous transluminal implantation of a self-expanding valve prosthesis for interventional treatment of aortic valve stenosis. Catheter Cardiovasc Interv 2005; 66:465–469.
- Grube E, Schuler G, Buellesfeld L, et al. Percutaneous aortic valve replacement for severe aortic stenosis in high-risk patients using the second- and current third-generation self-expanding CoreValve prosthesis: device success and 30-day clinical outcome. J Am Coll Cardiol 2007; 50:69–76.
- Lichtenstein SV, Cheung A, Ye J, et al. Transapical transcatheter aortic valve implantation in humans: initial clinical experience. Circulation 2006; 114:591–596.
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- Ye J, Cheung A, Lichtenstein SV, et al. Six-month outcome of transapical transcatheter aortic valve implantation in the initial seven patients. Eur J Cardiothorac Surg 2007; 31:16–21.
- Turgut T, Deeb M, Moscucci M. Left ventricular apical puncture: a procedure surviving well into the new millennium. Catheter Cardiovasc Interv 2000; 49:68–73.
- Zuguchi M, Shindoh C, Chida K, et al. Safety and clinical benefits of transsubxiphoidal left ventricular puncture. Catheter Cardiovasc Interv 2002; 55:58–65.
- Sinha AK, Kini AS, Sharma SK. Percutaneous valve replacement: a paradigm shift. Curr Opin Cardiol 2007; 22:471–477.
- Wenaweser P, Buellesfeld L, Gerckens U, Grube E. Percutaneous aortic valve replacement for severe aortic regurgitation in degenerated bioprosthesis: the first valve in valve procedure using the CoreValve ReValving system. Catheter Cardiovasc Interv 2007; 70:760–764.
- Pasupati S, Humphries K, AlAli A, et al. Balloon expandable aortic valve (BEAV) implantation. The first 100 Canadian patients. Circulation 2007; 116 suppl:357.
- Walther T, Falk V, Kempfert J, et al. Transapical minimally invasive aortic valve implantation; the initial 50 patients. Eur J Cardiothorac Surg 2008; 33:983–988. Epub 2008 February 21.
- Carabello BA. Clinical practice. Aortic stenosis. N Engl J Med 2002; 346:677–682.
- Pellikka PA, Nishimura RA, Bailey KR, Tajik AJ. The natural history of adults with asymptomatic, hemodynamically significant aortic stenosis. J Am Coll Cardiol 1990; 15:1012–1017.
- Ross J, Braunwald E. Aortic stenosis. Circulation 1968; 38:61–67.
- Kvidal P, Bergstrom R, Horte LG, Stahle E. Observed and relative survival after aortic valve replacement. J Am Coll Cardiol 2000; 35:747–756.
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- Percutaneous balloon aortic valvuloplasty. Acute and 30-day follow-up results in 674 patients from the NHLBI Balloon Valvuloplasty Registry. Circulation 1991; 84:2383–2397.
- Safian RD, Mandell VS, Thurer RE, et al. Postmortem and intraoperative balloon valvuloplasty of calcific aortic stenosis in elderly patients: mechanisms of successful dilation. J Am Coll Cardiol 1987; 9:655–660.
- Agarwal A, Kini AS, Attanti S, et al. Results of repeat balloon valvuloplasty for treatment of aortic stenosis in patients aged 59 to 104 years. Am J Cardiol 2005; 95:43–47.
- Kapadia SR, Wazni OM, Tan WA, et al. Aortic valvuloplasty in 1990's: experience from a single center in United States. Circulation 1999; 100 18 suppl 1:1–448.
- Lieberman EB, Bashore TM, Hermiller JB, et al. Balloon aortic valvuloplasty in adults: failure of procedure to improve long-term survival. J Am Coll Cardiol 1995; 26:1522–1528.
- Cribier A, Eltchaninoff H, Tron C, et al. Treatment of calcific aortic stenosis with the percutaneous heart valve: mid-term follow-up from the initial feasibility studies: the French experience. J Am Coll Cardiol 2006; 47:1214–1223.
- Cribier A, Eltchaninoff H, Tron C, et al. Early experience with percutaneous transcatheter implantation of heart valve prosthesis for the treatment of end-stage inoperable patients with calcific aortic stenosis. J Am Coll Cardiol 2004; 43:698–703.
- Rajagopal V, Kapadia SR, Tuzcu EM. Advances in the percutaneous treatment of aortic and mitral valve disease. Minerva Cardioangiol 2007; 55:83–94.
- Webb JG, Chandavimol M, Thompson CR, et al. Percutaneous aortic valve implantation retrograde from the femoral artery. Circulation 2006; 113:842–850.
- Salemi A. Percutaneous valve interventions. Curr Opin Anaesthesiol 2007; 20:70–74.
- Grube E, Laborde JC, Gerckens U, et al. Percutaneous implantation of the CoreValve self-expanding valve prosthesis in high-risk patients with aortic valve disease: the Siegburg first-in-man study. Circulation 2006; 114:1616–1624.
- Grube E, Laborde JC, Zickmann B, et al. First report on a human percutaneous transluminal implantation of a self-expanding valve prosthesis for interventional treatment of aortic valve stenosis. Catheter Cardiovasc Interv 2005; 66:465–469.
- Grube E, Schuler G, Buellesfeld L, et al. Percutaneous aortic valve replacement for severe aortic stenosis in high-risk patients using the second- and current third-generation self-expanding CoreValve prosthesis: device success and 30-day clinical outcome. J Am Coll Cardiol 2007; 50:69–76.
- Lichtenstein SV, Cheung A, Ye J, et al. Transapical transcatheter aortic valve implantation in humans: initial clinical experience. Circulation 2006; 114:591–596.
- Walther T, Falk V, Borger MA, et al. Minimally invasive transapical beating heart aortic valve implantation—proof of concept. Eur J Cardiothorac Surg 2007; 31:9–15.
- Ye J, Cheung A, Lichtenstein SV, et al. Six-month outcome of transapical transcatheter aortic valve implantation in the initial seven patients. Eur J Cardiothorac Surg 2007; 31:16–21.
- Turgut T, Deeb M, Moscucci M. Left ventricular apical puncture: a procedure surviving well into the new millennium. Catheter Cardiovasc Interv 2000; 49:68–73.
- Zuguchi M, Shindoh C, Chida K, et al. Safety and clinical benefits of transsubxiphoidal left ventricular puncture. Catheter Cardiovasc Interv 2002; 55:58–65.
- Sinha AK, Kini AS, Sharma SK. Percutaneous valve replacement: a paradigm shift. Curr Opin Cardiol 2007; 22:471–477.
- Wenaweser P, Buellesfeld L, Gerckens U, Grube E. Percutaneous aortic valve replacement for severe aortic regurgitation in degenerated bioprosthesis: the first valve in valve procedure using the CoreValve ReValving system. Catheter Cardiovasc Interv 2007; 70:760–764.
- Pasupati S, Humphries K, AlAli A, et al. Balloon expandable aortic valve (BEAV) implantation. The first 100 Canadian patients. Circulation 2007; 116 suppl:357.
- Walther T, Falk V, Kempfert J, et al. Transapical minimally invasive aortic valve implantation; the initial 50 patients. Eur J Cardiothorac Surg 2008; 33:983–988. Epub 2008 February 21.
- Carabello BA. Clinical practice. Aortic stenosis. N Engl J Med 2002; 346:677–682.
- Pellikka PA, Nishimura RA, Bailey KR, Tajik AJ. The natural history of adults with asymptomatic, hemodynamically significant aortic stenosis. J Am Coll Cardiol 1990; 15:1012–1017.
- Ross J, Braunwald E. Aortic stenosis. Circulation 1968; 38:61–67.
- Kvidal P, Bergstrom R, Horte LG, Stahle E. Observed and relative survival after aortic valve replacement. J Am Coll Cardiol 2000; 35:747–756.
- Society of Thoracic Surgeons National Cardiac Surgery Database. Available at www.sts.org/documents/pdf/Spring2005STS-ExecutiveSummary.pdf. Accessed 9/11/2008.
- Birkmeyer JD, Siewers AE, Finlayson EV, et al. Hospital volume and surgical mortality in the United States. N Engl J Med 2002; 346:1128–1137.
- Wenger NK, Weber MA, Scheidt S. Valvular heart disease at elderly age: new vistas. Am J Geriatr Cardiol 2006; 15:273–274.
KEY POINTS
- Aortic stenosis is the most common valvular condition, affecting 3% of the general population; its incidence and prevalence are increasing as the population ages.
- Many patients with severe aortic valve stenosis are considered too high-risk for standard surgical valve replacement but may be candidates for percutaneous valve replacement.
- Of the approaches now undergoing refinement, the most promising is retrograde (ie, femoral arterial) placement of the Edwards SAPIEN valve or the CoreValve.
- The technology is still evolving, and the learning curve is substantial, yet cautious enthusiasm about percutaneous aortic valve replacement is justified.