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Original Articles: Adult Cardiac

Melody Valve-in-Ring Procedure for Mitral Valve Replacement: Feasibility in Four Annuloplasty Types

^a Division of Cardiology, The Children's Hospital of Philadelphia, Department of Pediatrics, University of Pennsylvania School of Medicine, Philadelphia, Pennsylvania
^b Department of Surgery, University of Pennsylvania School of Medicine, Philadelphia, Pennsylvania
^c Gorman Cardiovascular Research Group, University of Pennsylvania, Glenolden, Pennsylvania

Accepted for publication December 6, 2011.

^_* Address correspondence to Dr Gorman, Gorman Cardiovascular Research Group, University of Pennsylvania, 500 S Ridgeway Ave, Glenolden, PA 19036 (Email: gormanr{at}uphs.upenn.edu).

	Abstract

Top Abstract Introduction Material and Methods Results Comment Acknowledgments References

 
Background: The recurrence of regurgitation after surgical mitral valve (MV) repair remains a significant clinical problem. Mitral annuloplasty rings are commonly used in MV repair procedures. The purpose of this study was to demonstrate the feasibility of transvenous valve-in-ring (VIR) implantation using the Melody valve (Medtronic, Minneapolis, MN), which is a valved-stent designed for percutaneous pulmonary valve replacement, and 4 distinct types of annuloplasty ring (AR) in an ovine model.

Methods: Ten sheep underwent surgical MV annuloplasty ring placement (n = 10): CE-Physio, Edwards Lifesciences, Irvine, CA [n = 5]; partial ring [n = 3]; flexible ring [n = 1]; and saddle ring [n = 1]). All animals underwent cardiac catheterization, hemodynamic assessment, and Melody VIR implantation through a transfemoral venous, transatrial septal approach 1 week after surgery. Follow-up hemodynamic, angiographic, and echocardiographic data were recorded.

Results: Melody VIR implantation was technically successful in all but 1 animal. In this animal a 26-mm partial AR proved too large for secure anchoring of the Melody valve. In the remaining 9 animals, fluoroscopy showed the Melody devices securely positioned within the annuloplasty rings. Echocardiography revealed no perivalvular leak, and angiography revealed no left ventricular outflow tract obstruction, vigorous left ventricular function, and no aortic valve insufficiency. The median procedure time was 55.5 (range, 45 to 78) minutes.

Conclusions: This study demonstrates the feasibility of a purely percutaneous approach to MV replacement in patients with preexisting annuloplasty rings, regardless of ring type. This approach may be of particular benefit to patients with failed repair of ischemic mitral regurgitation.

	Introduction

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Mitral valve repair (MVR) has become the preferred surgical therapy for mitral regurgitation (MR) irrespective of the cause of valve dysfunction. Restoration of the mitral annulus to its normal size and shape using an annuloplasty ring (AR) is the most widely applied and reliable MVR procedure. Currently, there are several different types of ARs available, which can be loosely divided into the following 4 general categories: (1) rigid complete "flat" rings; (2) partial rings; (3) flexible rings; and (4) saddle-shaped rings. While no randomized, prospective data exist, valve repair is thought to result in superior valve function, reduced need for anticoagulation, and improved survival when compared with valve replacement [1]. Improved durability over bioprosthetic heart valves has also been proposed as an advantage of repair [1]. However, recent studies have called into question the durability of MVR for functional, ischemic, and degenerative etiologies [2–6], and durable repair of congenital systemic atrioventricular valve dysfunction (mitral, tricuspid, or common atrioventricular [AV] valve) is equally problematic [7, 8]. Repair of ischemic regurgitation (IMR) with undersized annuloplasty has an extremely high rate of early recurrent MR, with up to 30% of patients suffering return of hemodynamically important MR within 6 months of surgery [2, 9]. Recurrence of significant MR after repair for degenerative disease has also been documented to approach 4% per year in some reports [3–5, 9, 10]. Due to very complex pathologies, recurrence of regurgitation after valve repair for congenital anomalies is also common [8, 11], necessitating high-risk surgical valve replacement in children, often with a mechanical device in the supraannular position [12].

Over the last decade, the development of novel valve technologies has made percutaneous replacement of the aortic and pulmonary valves a clinical reality [13–16]. However, percutaneous replacement of the mitral valve (MV) is not currently possible due to inherent anatomic features of the MV that make fixation and perivalvular seal with currently available devices a challenge. Recent clinical reports and animal studies have demonstrated that the presence of a surgically placed annuloplasty ring or a bioprosthetic valve makes MV replacement with valved stents feasible with current devices. This technique has been termed the valve-in-ring (VIR) or valve-in-valve (VIV) procedure and has been performed surgically, through transatrial [17] and transapical [18–20] approaches using the Sapien transcatheter heart valve (Edwards Lifesciences, Irvine, CA). Given the growing awareness of the limitations of valve repair durability, VIR offers a potential remedial procedure for adult and pediatric patients who develop recurrent MR after MV repair and are poor candidates for re-repair or conventional surgical valve replacement.

In this study we report on the feasibility of performing VIR by a completely percutaneous approach using the Melody transcatheter valve (Medtronic, Minneapolis, MN) in a sheep model of mitral valve repair, using 4 distinct types of annuloplasty ring that are commonly used in MVR procedures. A purely percutaneous approach to the VIR procedure reduces the invasiveness of the procedure, which may be advantageous for high-risk patients.

	Material and Methods

Top Abstract Introduction Material and Methods Results Comment Acknowledgments References

 
After approval by The University of Pennsylvania's Animal Care and Use Committee, 10 male Dorsett hybrid sheep were subjected to study. All animals had surgical mitral valve ring annuloplasty. One week after surgery, all animals were brought to the catheterization laboratory for the percutaneous, transvenous Melody VIR procedure. Hemodynamic and echocardiographic data were recorded before and after VIR.

Surgical Mitral Annuloplasty
A left thoracotomy was performed, and 1 of 4 different annuloplasty rings was implanted in all animals using standard techniques (Fig 1): (1) Complete rigid ring (Physio; Edwards Lifesciences), 24 mm (n = 2), 26 mm (n = 2), 28 mm ring [n = 1]); (2) partial rigid ring (modified Physio), 24 mm (n = 2), 26 mm (n = 1); (3) saddle-shaped ring (Profile 3D ring; Medtronic Inc), 24 mm (n = 1); and (4) flexible ring (Duran AnCore ring; Medtronic Inc), 25 mm (n = 1).

View larger version (103K): [in this window] [in a new window]   Fig 1. Fluoroscopic images of the 4 types of annuloplasty rings used for the Melody valve-in-ring procedure, including the following: (A) complete rigid rings; (B) partial rings; (C) saddle rings; and (D) flexible rings. Photos of each ring are shown in the insets.

View larger version (162K): [in this window] [in a new window]   Fig 2. Transvenous, transseptal approach to Melody valve-in-ring delivery. (A) The Melody device is crimped on the delivery balloon and advanced from the femoral vein, across the atrial septum, and positioned centrally in the partial annuloplasty ring. (B) Next, the Melody valve is deployed by balloon inflation. (C) Follow-up angiography reveals no significant mitral regurgitation, no left ventricular outflow tract obstruction, and (D) no aortic valve insufficiency. (LV = left ventricle.)

Statistical Analysis
Hemodynamic measurements before and after VIR were summarized using standard descriptive statistics and reported as mean ± standard deviation. Comparisons were made using paired Student's t test. A p value 0.05 was considered significant.

	Results

Top Abstract Introduction Material and Methods Results Comment Acknowledgments References

 
All animals (n = 10) underwent successful surgical placement of an annuloplasty ring. There were no surgical or postoperative complications.

The only significant differences noted between the pre VIR and post VIR hemodynamic measures were an increased cardiac output (p < 0.01) and an increased systolic pulmonary artery pressure (p = 0.04). Otherwise, no significant differences were noted (as shown in Table 1). Nine out of 10 (90%) VIR procedures resulted in secure Melody valve implantation into the annuloplasty ring. The 1 failure occurred when implanting into the 26-mm partial annuloplasty ring. The Melody valve was too small to securely engage the partial ring and thus the device embolized during 2 separate deployment attempts. The median procedure time was 55.5 (range, 45 to 78) minutes.

After euthanasia, necropsy demonstrated that the Melody valves were anchored securely. There was a complete circumferential seal around the Melody valve stent, regardless of AR type (Fig 3).

View larger version (129K): [in this window] [in a new window]   Fig 3. Row A shows the intraoperative images after surgical mitral annuloplasty with 4 different types of annuloplasty ring. Row B shows necropsy pictures of the atrial side of the Melody valve-in-ring complex. Note that there is a complete circumferential seal formed between the Melody valve and the annular tissue, even in the absence of a complete ring (column 2). Row C shows the necropsy pictures of the ventricular side of the Melody valve-in-ring complex. In all cases, the mitral leaflet tissue "hugs" the outside of the Melody device. Although the Melody valve leaflets appear "gnarled" and "rolled," in most cases the valves functioned well, with only 1 having hemodynamically significant mitral regurgitation.

	Comment

Top Abstract Introduction Material and Methods Results Comment Acknowledgments References

Many promising percutaneous MV repair technologies have been developed [5, 22]. However, one-stage percutaneous MV replacement remains elusive [23, 24]. Minimally invasive surgical (transapical or transatrial) MV replacement by VIV and, more recently VIR, procedures have been published [17, 20] that underscore the potential of repurposing "failing" surgical hardware (bioprosthetic valves and annuloplasty rings) as "landing zones" for subsequent minimally invasive valve replacement. Our experience supports and further refines this concept and demonstrates that a purely percutaneous approach to VIR implantation is feasible in all types of annuloplasty devices, including complete, partial, rigid, flexible, and saddle-shaped rings.

In patients with ischemic IMR the VIR procedure has the potential to be truly transformative. The optimal treatment for IMR remains controversial. The recent documentation of high recurrence rates of IMR after ring annuloplasty [5] has resulted in equipoise between the relative merits of repair versus replacement in this expanding cohort of patients. In fact, there is an ongoing National Institutes of Health-funded clinical trial conducted within the Cardiothoracic Surgical Trials Network that has been developed to assess whether repair or replacement is best suited for patients with severe IMR. The availability of a fully percutaneous VIR procedure that is safe, is fast, and effectively reframes the debate between repair and replacement in IMR. Annuloplasty could be performed in nearly all patients, maximizing the number who would experience the potential benefits of repair while at the same time setting the stage for a quick, minimally invasive remedial procedure (VIR) should symptomatic MR recur after surgery.

This was a proof of principle study designed to test the feasibility of percutaneous VIR into 4 different mitral AR types. The Melody valves used in this experiment will, in all likelihood, not be the optimal design for treating the majority of patients with failed MVR procedures as the majority of patients having such surgeries receive annuloplasty devices with nominal sizes of 28 mm or greater. We believe that the VIR procedure will be an important addition to the treatment of recurrent MR and believe that a product with a wide variety of sizes needs to be designed specifically for this indication.

Additionally, the devices were previously handled and thus not optimal for functionality testing. Furthermore, they are undersized relative to the normal adult mitral annulus (maximum functional diameter = 22 mm), and are not intended for use in the systemic circulation, where the afterload is generally much higher than in the pulmonary circulation. Despite this, the Melody valves were sufficient to demonstrate the feasibility of the transvenous VIR procedure in all types of annuloplasty rings, and they functioned well in the short term. This was an acute study, therefore we cannot comment on the durability of Melody devices in the mitral position in the longer term.

This report demonstrates a purely percutaneous, transvenous approach to mitral VIR replacement using the Melody valve in 4 different types of annuloplasty ring. The relative ease of access to the mitral space from the venous side with standard catheter sizes and techniques is encouraging in terms of the feasibility of this approach in patients. All reports to date describing the VIR and VIV procedures, including this one, have employed valves that were developed for use in either the aortic or pulmonary positions. It is likely that devices designed specifically for mitral VIR and VIV procedures will further increase the ease of valve deliverability, durability, and functionality in the mitral position, potentially resulting in widespread acceptance of this new treatment strategy.

	Acknowledgments

Top Abstract Introduction Material and Methods Results Comment Acknowledgments References

 
This work was supported by grants from the National Heart, Lung and Blood Institute of the National Institutes of Health, Bethesda, MD (HL63954, HL73021 and 103723). R. Gorman and J. Gorman are supported by individual Established Investigator Awards from the American Heart Association, Dallas, TX. The Melody valves used in this study were donated by Medtronic, Inc. The authors had full control of the design of the study, methods used, outcome parameters and results, analysis of data, and production of this report.

	References

Top Abstract Introduction Material and Methods Results Comment Acknowledgments References

 

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This Article Abstract Full Text (PDF) Alert me when this article is cited Alert me if a correction is posted Citation Map Services Email this article to a friend Similar articles in this journal Similar articles in PubMed Alert me to new issues of the journal Add to Personal Folders Download to citation manager Author home page(s): Jeremy R. McGarvey Manabu Takebe Robert C. Gorman Joseph H. Gorman, III Permission Requests Citing Articles Citing Articles via Google Scholar Google Scholar Articles by Kondo, N. Articles by Gillespie, M. J. Search for Related Content PubMed PubMed Citation Articles by Kondo, N. Articles by Gillespie, M. J. Related Collections Valve disease