Non-resectional cordal repair for Barlow mitral valve disease.

BACKGROUND: The redundant leaflet tissue and annular pathology of Barlow disease can make surgical repair challenging. We examined perioperative and late outcomes of a large cohort of patients with Barlow disease undergoing surgical repair. METHODS: Patients included in this analysis underwent mitral valve repair from 01/2004-11/2021 by a single surgeon. RESULTS: Of 2798 patients undergoing mitral valve operations, 46% (N.=1292) had degenerative pathology and 7% (N.=184) had Barlow disease. Of the 179 Barlow patients, median age at surgery was 62 (51-70) years; 64% were male (115/179). Rates of non-resectional cordal repair and resectional repair were 86% (154/179) and 14% (25/179). Among patients undergoing non-resectional repair, the median number of cordal pairs inserted on the anterior and posterior leaflets was 2 (2-3) and 4 (3-4). Incidence of return to bypass for systolic anterior motion of the mitral valve, perioperative death, stroke, and renal failure was 2% (4/179), 1% (2/179), 0% (0/179), and 0% (0/179). Rates of clinical and echocardiographic follow-up were 93% (165/177) and 89% (157/177). Median time to latest postoperative clinical and echocardiographic follow-up was 2.4 (0.8-6.1) and 2.1 (0.6-4.7) years. Mitral regurgitation grade at latest follow-up or time of repair failure was none/trace, mild, mild to moderate, and severe in 63% (98/157), 26% (41/157), 8% (12/157), and 4% (6/157); five of six patients with severe MR underwent reoperation. Since 2011 97% (139/144) of patients underwent cordal repair without resection. CONCLUSIONS: Non-resectional artificial cordal repair is safe and feasible in almost all patients with Barlow valves and is associated with excellent mid-term results.

How To Do It: Mitral Valve Translocation.

Mitral valve translocation (MVT) is a novel procedure that was developed to treat patients with severe, symptomatic, secondary mitral regurgitation (MR). MVT enhances leaflet coaptation by insertion of an autologous pericardial patch interposed between the mitral annulus and the native mitral leaflets. The patch substantially increases total leaflet surface area and creates supranormal coaptation. In addition, it relieves leaflet tethering by transposing the native valve deeper into the ventricle and decreases the circumference of the annulus. The enhanced coaptation produced by MVT may protect against recurrent MR in patients with continued adverse left ventricular remodeling. The procedural steps include detachment of the intact native mitral valve at the annulus, placement of interrupted pledgeted sutures around the annulus to secure the proximal aspect of the patch, and attachment of the native valve to the distal aspect of the patch using running suture. Follow-up of patients who have undergoing MVT is ongoing, with satisfactory short-term results, including sustained MR grades of ≤mild and 14 mm coaptation at 12 months.

Effectiveness of telemedicine in a mitral valve center of excellence.

BACKGROUND: The COVID-19 pandemic necessitated a drastic increase in the use of telemedicine. There is little information about the effectiveness of telemedicine in cardiac surgery. We examined clinical outcomes and patient satisfaction among patients who had in-person versus telemedicine preoperative appointments in a subspecialized mitral valve surgical practice. METHODS: We retrospectively reviewed all patients who had elective mitral valve operations between January 2019 and February 2021. Patients were categorized into 2 groups based on the format of the preoperative appointment (telemedicine or in-person). Preoperative characteristics and clinical outcomes were compared between the two groups. All patients who had a telemedicine appointment were sent an online survey to assess their satisfaction with the process. RESULTS: Among 286 patients analyzed, 197 (69%) had in-person preoperative evaluations and 89 (31%) had telemedicine evaluations. The in-person and telemedicine groups had similar preoperative and operative characteristics. Outcomes did not differ between the 2 groups, including ventilation time (3.7 vs. 4.1 h, p = .399), total length of stay (5 vs. 5 days, p = .949), 30-day mortality (0% vs. 1%, p = .311), and readmissions within 30 days (13% vs. 8%, p = .197). Among patients who completed the survey, 91% were "satisfied" or "very satisfied" with the telemedicine preoperative appointment. CONCLUSION: Patients who had telemedicine preoperative appointments before mitral valve operations during the COVID-19 pandemic had similarly excellent clinical outcomes to patients who had in-person preoperative appointments before the pandemic. Patients had relatively high levels of satisfaction with telemedicine and almost half preferred telemedicine for future visits.

Intraoperative echocardiographic assessment of mitral valve translocation.

OBJECTIVES: The aim of this study was to present a rigorous method to analyse the intraoperative echocardiographic images from the novel mitral translocation procedure, which assesses the changes in mitral structure and function and compares this data to a control group of patients who have no mitral regurgitation (MR). METHODS: Transoesophageal echocardiography was post-processed using dedicated 3D software. Ten patients with normal mitral valves (MV) undergoing non-mitral cardiac surgery served as controls. Mitral coaptation area, mid-leaflet coaptation length and mitral annular circumference were measured in 3D. RESULTS: Twenty-three consecutive patients with severe secondary MR underwent MV translocation. All patients had none/trace MR post-translocation. The mean coaptation surface area increased from 63 to 427 mm2 (P < 0.001) and coaptation length increased from 1.0 to 10.5 mm (P < 0.001). The control group coaptation surface area (136 mm2) and length (2.5 mm) were greater than pre-translocation (P = 0.019; P < 0.001) and less than post-translocation (P < 0.001; P < 0.001). 3D mitral annular circumference in the translocation group decreased 15% (130-110 mm) (P < 0.001). Post-translocation, the mean gradient was 2(2-3) mmHg with the diastolic mitral orifice area of 3.4 ± 0.3 cm2 by planimetry and 3.5 ± 0.3 cm2 by pressure half-time. The coaptation to septum distance remained unchanged (P = 0.305) without systolic anterior leaflet motion. CONCLUSIONS: This echocardiographic analysis method demonstrates that MV translocation abolishes secondary MR, increases coaptation area and length and produces acceptable diastolic function. This method of analysis should allow precise structural and quantitative assessment of the durability of the repair in future long-term follow-up.

Translocation of the Mitral Valve in an Acute Large Animal Model.

Current repair options for functional mitral regurgitation (FMR) are not durable and do not adequately address underlying pathophysiology including leaflet tethering and insufficient coaptation. The feasibility of mitral valve translocation as a repair strategy for FMR was examined in normal swine. Seven pigs (median 62 kg, IQR 55-65 kg) with normal cardiac function were implanted with a 1-cm frustum-shaped pericardial patch inserted between the native mitral annulus and intact mitral leaflets. Operative survival was 100% with no post-procedure mitral stenosis, systolic anterior motion, or central mitral regurgitation observed on echocardiography. Post-translocation mean gradient was 3.5 mmHg (IQR 1.5-4 mmHg); trace or mild suture line leaks on the atrial suture line were noted in 5/7 pigs. Median leaflet coaptation increased from 2.4 (IQR 2.1-4.3 mm) to 12.4 mm (IQR 10.8-13.4 mm) after translocation (P = 0.016). Translocation dramatically increases leaflet coaptation without impairing diastolic function in animals with normal left ventricular function and is a promising technique for repair of FMR. Implantation of a 1.0-cm circumferential pericardial patch (mitral valve translocation) increases leaflet coaptation in a normal animal model.

Quantitating Mitral Regurgitation in Clinical Trials: The Need for a Uniform Approach.

BACKGROUND: There is an established relationship between the degree of mitral regurgitation (MR) and prognosis. Quantitation of MR severity guides therapeutic approaches. Inconsistent definitions and categorization of MR severity in clinical studies limit meaningful comparisons among trials and compromise development of an effective evidence base. The purpose of this study was to quantify heterogeneity in grading systems for MR severity in the contemporary literature. METHODS: This was a systematic review of randomized controlled trials and propensity score-adjusted clinical studies of mitral valve interventions (surgical or percutaneous). A total of 35 articles from 2015 to 2020 were included (15 randomized controlled trials and 20 propensity score-adjusted clinical studies). RESULTS: There were 22 studies that reported MR severity in numeric categories, either values from the historical "plus" system or numeric MR grades, whereas 9 studies reported MR severity using text-only descriptive categories. Among the studies that used numeric categories, 2+ MR was defined as moderate in 64% of studies, mild in 27%, and mild-moderate in 9%, and 3+ MR was defined as moderate in 14%, moderate-severe in 52%, and severe in 14%. CONCLUSIONS: There was substantial variability in MR severity definition and reporting in contemporary clinical studies of mitral valve interventions. We recommend that the historical plus numeric grading system be abandoned and that inclusion and outcome criteria in MR clinical trials be based on US and European guideline-recommended categories as none or trace, mild, moderate, and severe. Adoption of these simple recommendations will improve the consistency and quality of MR clinical trial design and reporting.

Mitral Valve Translocation: Optimization of Patch Geometry in an Ex Vivo Model of Secondary Mitral Regurgitation.

Optimal translocation patch width for functional mitral regurgitation (FMR) treatment was evaluated in an air-filled ex vivo system. FMR was created in 19 isolated swine hearts by annular dilation and papillary muscle displacement. Frustum-shaped pericardial patches of varying widths (Group 1 = 0.5 cm; Group 2 = 1.0 cm; Group 3 = 1.5 cm) were implanted and imaged via a 3D-structured light scanner. Median leaflet coaptation decreased (P < 0.001) from 5.5 ± 2.0 mm at baseline to 2.4 ± 1.3 mm following FMR creation. Translocation repair increased coaptation length over FMR levels by 2.2 mm in Group 1 (P < 0.001), 4.6 mm in Group 2 (P < 0.001), and 4.7 mm in Group 3 (P < 0.001). After repair, no significant differences were found between groups for annular height, circularity index, tenting height, tenting area, and non-coapting surface area. The supranormal coaptation and minimal valve geometric changes support using a 1.0- or 1.5-cm translocation patch for FMR treatment. Implantation of a 1.0-cm or 1.5-cm circumferential pericardial patch (mitral valve translocation) increases leaflet coaptation length without significantly altering valve geometry.

Mitral Valve Translocation: A Novel Operation for the Treatment of Secondary Mitral Regurgitation.

BACKGROUND: Conventional annuloplasty repair of secondary (functional) ischemic mitral regurgitation (IMR) is associated with a 60% recurrence of moderate or greater mitral regurgitation at 2 years. We developed a novel repair technique for IMR that addresses the underlying geometric alterations of the mitral valve apparatus and compared outcomes with those of conventional repair in a swine model. METHODS: Chronic IMR was induced by percutaneous embolization of the circumflex artery. Swine with severe IMR (median 9 weeks after infarction) underwent undersized rigid annuloplasty (n = 5) or translocation repair (n = 6). Translocation repair consisted of detaching the mitral valve en bloc at the annulus, creating a 1 cm wide frustum-shaped pericardial patch, and suturing the outer circumference of the patch to the annulus and inner circumference to the mitral valve. RESULTS: Operative survival was 92% (11 of 12). All animals had none/trace residual central mitral regurgitation, and mean inflow gradients were similar (1 mm Hg [interquartile range, 1 to 2] vs 2 mm Hg [interquartile range, 1 to 2]; P = .75) in the annuloplasty and translocation groups, respectively. Median coaptation length marginally improved in conventional swine (3 to 4 mm, P = .05), but dramatically improved in translocation swine (3 to 8 mm, P = .003). Posterior leaflet angle increased from 39 to 80 degrees (P = .05) in annuloplasty swine but decreased from 50 to 31 degrees (P = .03) in translocation swine. The posterior leaflet was immobile after annuloplasty but had preserved motion after translocation (excursion, 1 degree vs 24 degrees; P = .045). CONCLUSIONS: Mitral valve translocation effectively treats mitral regurgitation by relieving leaflet tethering. Compared with annuloplasty, mitral valve translocation creates a larger surface of coaptation and preserves leaflet mobility without compromising diastolic function.

Transseptal Puncture Learning Curve for Transcatheter Edge-to-Edge Mitral Valve Repair.

OBJECTIVE: This study examined the learning curve for transseptal puncture (TSP) during transcatheter edge-to-edge mitral valve repair (TEER) performed by a dedicated mitral valve structural heart team. Effective TSP is mandatory for TEER but can be time-consuming and associated with complications including pericardial effusion and cardiac tamponade. METHODS: TSP was performed on 107 consecutive patients (76 ± 1 years, 52% male) undergoing TEER between 2014 and 2019. TSP was performed by each structural heart team member (1 cardiologist, 2 cardiac surgeons) on a rotating case-by-case basis. No team member had prior independent TSP experience. Data collected included total procedure time, TSP time (time elapsed between procedure start and septal crossing), and number of TSP attempts before successful puncture. Cumulative sum (CUSUM) of deviations from the mean across sequential cases were used to examine learning curves. RESULTS: Median total procedure time was 107 min, and the median TSP time was 14 min. Greater case number was significantly associated with both lower TSP time (r s = -0.22, P = 0.022) and lower total procedure time (r s = -0.29, P = 0.003). The majority of patients required only 1 TSP attempt (79%). There was a significant quadratic relationship between case number and the CUSUM for TSP time, with the learning curve peaking at 49 cases. CONCLUSIONS: TSP for TEER has a substantial learning curve, requiring >50 cases to achieve acceptable efficiency. Even once proficiency is demonstrated, TSP remains a time-consuming component of TEER. Improvements in transseptal access technology may significantly decrease the time needed to master TSP and may improve the safety and precision of the procedure.

Initial Clinical Experience With Mitral Valve Translocation for Secondary Mitral Regurgitation.

BACKGROUND: Functional (secondary) mitral regurgitation (FMR) results from altered geometry of the mitral valve apparatus. Repair with restrictive mitral annuloplasty is associated with high rates of recurrent mitral regurgitation (MR). We developed a novel operative repair for FMR that translocates the intact mitral valve towards the apex. METHODS: The mitral valve was detached circumferentially and translocated into the ventricle with a frustum-shaped glutaraldehyde-treated autologous pericardial patch. Clinical and echocardiographic follow-up was performed. RESULTS: Fifteen consecutive patients with FMR (mean age, 59 years; 67% female) had mitral valve translocation between 2018 and 2020. Preoperative mean ejection fraction, left ventricular end-diastolic dimension, and systolic pulmonary artery pressure were 40% ± 11%, 59 ± 8 mm, and 49 ± 21 mm Hg, respectively; 33% had atrial fibrillation. Cardiomyopathy was ischemic in 4 and nonischemic in 11. Concomitant procedures included tricuspid valve operation (n = 8), coronary artery bypass grafting (n = 4), and atrial fibrillation ablation (n = 5). Post bypass transesophageal echocardiogram demonstrated none/trace MR in all patients and mean gradient of 3 mm Hg (interquartile range, 2-4 mm Hg). Mean leaflet extent of coaptation was 14 ± 2 mm (range, 11-17 mm). There was no postoperative mortality, stroke, or renal failure. Predismissal echocardiography showed none/trace MR in 14 patients and mild MR in 1. One patient underwent successful late rerepair of a suture line leak. Twelve patients were alive at latest follow-up and MR at 1 and 6 months was mild or less in all patients with mean leaflet extent of coaptation of 14 ± 2 mm (range, 12-16 mm) at 6 months. CONCLUSIONS: Mitral valve translocation creates a large surface of coaptation and effectively corrects FMR. Further study is needed to demonstrate the long-term durability and clinical utility of this operation.

Development of a Reproducible Swine Model of Chronic Ischemic Mitral Regurgitation: Lessons Learned.

BACKGROUND: Durability of mitral valve repair for ischemic mitral regurgitation (IMR) remains poor. We established a swine model of chronic IMR, and describe the methods and lessons learned from this model. METHODS: Thirty-five swine underwent percutaneous myocardial infarction with ethanol ablation of the circumflex or obtuse marginal (OM) arteries. Swine were followed with routine echocardiography for the development of severe IMR. Once severe IMR was established, swine underwent mitral valve operations on cardiopulmonary bypass. After operation, swine were survived up to 7 weeks. Angiographic and echocardiographic features of swine who developed severe IMR (IMR swine) and those who did not (non-IMR swine) were compared. RESULTS: The median number of OM arteries was 3, with 2 OM arteries infarcted. Acute survival after the myocardial infarction was 74% (26 of 35) with 3 (9%) early, postoperative deaths. Among the 23 swine with follow-up to determine IMR status, 14 of 23 (61%) developed significant IMR. Among IMR pigs, left ventricular (LV) ejection fraction decreased from 65% pre-myocardial infarction to 45% pre-mitral valve intervention (P < .001). Among non-IMR swine, LV ejection fraction decreased nonsignificantly from baseline (60%) to latest follow-up (55%) (P = .443). LV end-diastolic dimension (P = .039), wall motion score (P = .027), global circumferential strain (P = .014), and global longitudinal strain (P = .023) were significantly worse in IMR compared with non-IMR swine. CONCLUSIONS: A reproducible percutaneous model of severe IMR in swine is feasible with a guided anesthetic and perioperative approach. This model can serve as a platform to better understand the mechanism of IMR and subsequently to test novel repair techniques.

A Novel Quantitative Ex Vivo Model of Functional Mitral Regurgitation.

OBJECTIVE: Durability of mitral valve (MV) repair for functional mitral regurgitation (FMR) remains suboptimal. We sought to create a highly reproducible, quantitative ex vivo model of FMR that functions as a platform to test novel repair techniques. METHODS: Fresh swine hearts (n = 10) were pressurized with air to a left ventricular pressure of 120 mmHg. The left atrium was excised and the altered geometry of FMR was created by radially dilating the annulus and displacing the papillary muscle tips apically and radially in a calibrated fashion. This was continued in a graduated fashion until coaptation was exhausted. Imaging of the MV was performed with a 3-dimensional (3D) structured-light scanner, which records 3D structure, texture, and color. The model was validated using transesophageal echocardiography in patients with normal MVs and severe FMR. RESULTS: Compared to controls, the anteroposterior diameter in the FMR state increased 32% and the annular area increased 35% (P < 0.001). While the anterior annular circumference remained fixed, the posterior circumference increased by 20% (P = 0.026). The annulus became more planar and the tenting height increased 56% (9 to 14 mm, P < 0.001). The median coaptation depth significantly decreased (anterior leaflet: 5 vs 2 mm; posterior leaflet: 7 vs 3 mm, P < 0.001). The ex vivo normal and FMR models had similar characteristics as clinical controls and patients with severe FMR. CONCLUSIONS: This novel quantitative ex vivo model provides a simple, reproducible, and inexpensive benchtop representation of FMR that mimics the systolic valvular changes of patients with FMR.

Long-term Performance of Fresh Autologous Pericardium for Mitral Valve Leaflet Repair.

BACKGROUND: Glutaraldehyde-fixed autologous or bovine pericardial patches used for mitral valve leaflet reconstruction have been associated with late calcification. Fresh autologous pericardium (FAP) may be a durable alternative. METHODS: Transthoracic echocardiography was used to assess valve function (regurgitation, mean pressure gradient, patch pliability, and calcification) in patients undergoing FAP mitral leaflet repairs. Pliability was scored between 1 (similar to native leaflets) and 4 (rigid). Calcification was scored between 1 (echobrightness similar to native leaflets) and 4 (very bright). RESULTS: Between 2002 and 2018, 62 consecutive patients (50% male, 51 ± 2 years, 69% infective endocarditis) underwent mitral valve repair with FAP, and Patch placement was on the anterior (31 of 62), posterior (27 of 62), or both (1 of 62) leaflets. Late echocardiographic follow-up was available for 43 of 62 patients (median follow-up, 3.6 years; range, 0.5-6 years). Average pliability scores were unchanged between discharge (1.2 ± 0.1) and follow-up (1.2 ± 0.2, P = .79). Average brightness scores increased modestly (predischarge, 1.6 ± 0.1; follow-up, 1.8 ± 0.1; P = .01). Three patients had recurrent severe mitral regurgitation, and 2 underwent reoperation, 1 at 1 year postoperatively for recurrent endocarditis and 1 at 6 years postoperatively for degenerative disease progression. At reoperation, patches were pliable, free from calcification, and comparable in thickness to adjacent native leaflet. One patient developed suture line leak, which was repaired. No other evidence of patch dehiscence, retraction, or aneurysm was observed. The 10-year freedom from reoperation of 82% and survival rate of 84% are comparable to repair with glutaraldehyde-fixed or bovine pericardial patches. CONCLUSIONS: FAP is an excellent substrate for complex mitral valve leaflet patch repairs and can be used with the expectation of durable, long-term valve function, without evidence of late patch calcification, stiffness, or aneurysmal degeneration.

Degenerative Mitral Valve Repair Simplified: An Evolution to Universal Artificial Cordal Repair.

BACKGROUND: Resectional and artificial cordal repair techniques are effective strategies for degenerative mitral valve (MV) repair. However, resectional repair requires a tailored approach using various techniques, whereas cordal repair offers a simpler, easily reproducible repair. The approach described in this study approach has evolved from resectional to cordal over time, and outcomes are compared between the eras. METHODS: Clinical and echocardiographic outcomes of all patients undergoing MV repair for degenerative mitral regurgitation (MR) from January 2004 to September 2017 were reviewed. Patients were stratified by era: from January 2004 to June 2011 (era 1; n = 405), resectional techniques were used in 62% and artificial cordal techniques were used in 38%. From July 2011 to September 2017 (era 2; n = 438), artificial cordal repair was used in 98% of patients. The primary outcome was repair failure, defined as greater than moderate MR or MV reoperation. RESULTS: Of 847 patients with degenerative MR, successful repair was achieved in 843 patients (99.5% repair rate). Leaflet prolapse was posterior in 66%, anterior in 8%, and bileaflet in 26%. Cardiopulmonary bypass time and cross-clamp times were shorter in era 2 (CPB: 109 [IQR, 92-128] minutes vs 97 [IQR, 76-121] minutes; P < .001; cross-clamp: 88 [IQR, 73-106] minutes vs. 79 [IQR, 61-99] minutes; P < .001). Predismissal echocardiography demonstrated no MR or trace MR in 95%, mild MR in 4.7%, and moderate MR in 0.3% of patients. Operative mortality was similar in the eras (0.5% vs 0.5%; P > .999). The rates of 5-year freedom from repair failure (95.1% vs 95.5%; P = .707), stroke (96.8% vs 95.3%; P = .538), and endocarditis (99.3% vs 99.7%; P = .604) were similar between the eras. CONCLUSIONS: Artificial cordal repair for all patients with degenerative MR simplifies MV repair and yields equivalent, excellent outcomes compared with a tailored resectional approach.