Mechanical effects of MitraClip on leaflet stress and myocardial strain in functional mitral regurgitation – A finite element modeling study

Zhang, Yue; Wang, Vicky Y.; Morgan, Ashley E.; Kim, Jiwon; Handschumacher, Mark D.; Moskowitz, Chaya S.; Levine, Robert A.; Ge, Liang; Guccione, Julius M.; Weinsaft, Jonathan W.; Ratcliffe, Mark B.

doi:10.1371/journal.pone.0223472

Cited by 19 publications

(17 citation statements)

References 38 publications

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“…While exact causality for MR recurrence cannot be discerned from our current results, it is also possible that MitraClip induced annular remodeling alters valve coaptation geometry, augments angular displacement between the mitral valves and sub-valvular apparatus, and/or induces myocardial tethering – each of which can contribute to MR. Consistent with the latter, recent computational modeling data from our group demonstrated that MitraClip augmented leaflet stress immediately adjacent to the device as well as LV myocardial stretch adjacent to the mitral annulus: [8] Our current results provide proof of concept that device-induced annular remodeling occurs in vivo, severity of which can be discerned on 3D TEE as a means of predicting therapeutic response to MitraClip. Whereas a large majority (70/80) of our study population underwent repair using the MitraClip NT/NTr device, our finding of an impact of MitraClip on annular remodeling is of relevance in context of new modifications of the device (XTr) that grasp a wider amount of leaflet tissue, and would thus be expected to apply a greater magnitude of force on the mitral annulus.…”

Section: Discussionsupporting

confidence: 85%

“…MitraClip induced leaflet tension may alter annular geometry – thus contributing to recurrent MR via distortion of valve coaptation and tethering of peri-annular myocardium. Consistent with this, computational modeling studies have shown MitraClip to augment leaflet stress adjacent to the device and also to affect broader aspects of the mitral apparatus - including decreased annular size and increased stretch (displacement) of peri-annular LV myocardium [8]. It remains unclear whether clinical application of MitraClip produces in vivo alterations in mitral annular geometry, and how such remodeling impacts patient outcomes.…”

Section: Introductionmentioning

confidence: 97%

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Transcatheter MitraClip repair alters mitral annular geometry – device induced annular remodeling on three-dimensional echocardiography predicts therapeutic response

Kim

Palumbo

Khalique

et al. 2019

Cardiovasc Ultrasound

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BackgroundEchocardiography (echo) is widely used to guide therapeutic decision-making for patients being considered for MitraClip. Relative utility of two- (2D) and three-dimensional (3D) echo predictors of MitraClip response, and impact of MitraClip on mitral annular geometry, are uncertain.MethodsThe study population comprised patients with advanced (> moderate) MR undergoing MitraClip. Mitral annular geometry was quantified on pre-procedural 2D transthoracic echocardiography (TTE) and intra-procedural 3D transesophageal echocardiography (TEE); 3D TEE was used to measure MitraClip induced changes in annular geometry. Optimal MitraClip response was defined as ≤mild MR on follow-up (mean 2.7 ± 2.5 months) post-procedure TTE.ResultsEighty patients with advanced MR underwent MitraClip; 41% had optimal response (≤mild MR). Responders had smaller pre-procedural global left ventricular (LV) end-diastolic size and mitral annular diameter on 2D TTE (both p ≤ 0.01), paralleling smaller annular area and circumference on 3D TEE (both p = 0.001). Mitral annular size yielded good diagnostic performance for optimal MitraClip response (AUC 0.72, p < 0.01). In multivariate analysis, sub-optimal MitraClip response was independently associated with larger pre-procedural mitral annular area on 3D TEE (OR 1.93 per cm2/m2 [CI 1.19–3.13], p = 0.007) and global LV end-diastolic volume on 2D TTE (OR 1.29 per 10 ml/m2 [CI 1.02–1.63], p = 0.03). Substitution of 2D TTE derived mitral annular diameter for 3D TEE data demonstrated a lesser association between pre-procedural annular size (OR 5.36 per cm/m2 [CI 0.95–30.19], p = 0.06) and sub-optimal MitraClip response. Matched pre- and post-procedural TEE analyses demonstrated MitraClip to acutely decrease mitral annular area and circumference (all p < 0.001) as well as mitral tenting height, area, and volume (all p < 0.05): Magnitude of MitraClip induced reductions in mitral annular circumference on intra-procedural 3D TEE was greater among patients with, compared to those without, sub-optimal MitraClip response (>mild MR) on followup TTE (p = 0.017); greater magnitude of device-induced annular reduction remained associated with sub-optimal MitraClip response even when normalized for pre-procedure annular circumference (p = 0.028).ConclusionsMitraClip alters mitral annular geometry as quantified by intra-procedural 3D TEE. Pre-procedural mitral annular dilation and magnitude of device-induced reduction in mitral annular size on 3D TEE are each associated with sub-optimal therapeutic response to MitraClip.

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Section: Discussionsupporting

confidence: 85%

Section: Introductionmentioning

confidence: 97%

Transcatheter MitraClip repair alters mitral annular geometry – device induced annular remodeling on three-dimensional echocardiography predicts therapeutic response

Kim

Palumbo

Khalique

et al. 2019

Cardiovasc Ultrasound

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“…The implantation of Mitraclip has mechanical effects including an increase in mitral leaflet stress and sub‐valvular radial strain proportional to the increase in the left ventricular chamber size as shown in an animal study with functional MR 12 . Since functional MR, secondary to left ventricular and annular dilatation and papillary muscle displacement, is commonly a result of CAD/acute coronary syndrome, this increased stress in already vulnerable myocardium could lead to worse postprocedural outcomes partially because of higher severity of residual MR and a higher risk of recurrence of severe MR 12 …”

Section: Discussionmentioning

confidence: 99%

Impact of preexisting coronary arterial disease in patients undergoing percutaneous mitral valve repair (MitraClip)

Gifft

Omran

Ghrair

et al. 2020

Cathet Cardio Intervent

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Introduction Percutaneous mitral valve repair with Mitraclip device has been approved for the treatment of symptomatic mitral valve regurgitation in patients deemed high surgical risk. It's unclear whether the presence of preexisting coronary arterial disease (CAD) affects the postprocedural outcomes of Mitraclip. Methods The study population was extracted from the 2016 Nationwide Readmissions Data (NRD) using the International Classification of Diseases, Tenth Revision, Clinical Modifications/Procedure Coding System (ICD‐10‐CM/PCS) for Mitraclip, preexisting CAD, and postprocedural complications. Study primary endpoints included in‐hospital all‐cause mortality, cardiogenic shock, acute myocardial infarction (AMI), acute kidney injury (AKI), stroke, acute respiratory failure, length of hospital stay (LOS), and 30‐day readmission rate. Results A total of 2,539 discharges that had Mitraclip during the index hospitalization, 62.3% had history of preexisting CAD. Mean age was 78.5 years and 46.6% were female. Overall, the presence of preexisting CAD was associated with higher AMI (1.6 vs. 0.4%, p < .01), however, there was no significant differences in terms of in‐hospital all‐cause mortality (2.2 vs. 2.6%, p = .52), cardiogenic shock (3.4 vs. 4.1%, p = .39), AKI (14.7 vs. 13.6%, p = .43), stroke (0.9 vs. 0.5%, p = .31), acute respiratory failure (9.7 vs. 8.8%, p = .43), LOS (5.3 vs. 5.3 days, p = .85) or 30‐day readmission rate (14.6 vs. 14.4%, p = .92). These results persisted after adjustment for baseline characteristics. The subgroup of CAD patients who received percutaneous coronary intervention (PCI) was associated with higher in‐hospital mortality (22.5 vs. 2.0%, p < .01), cardiogenic shock (25.0 vs. 3.3%, p < .01), AMI (22.5 vs. 0.8%, p < .01), AKI (55.0 vs. 13.7%, p < .01), stroke (10.0 vs. 0.6%, p < .01), acute respiratory failure (45.0 vs. 8.8%, p < .01), and longer LOS (21.5 vs. 5.1 days, p < .01), however there was no significant difference in 30‐day readmission rate (15.0 vs. 14.5%, p = .95). Conclusions Preexisting CAD was associated with higher in‐hospital AMI post‐Mitraclip but with comparable mortality and other morbidities. Patients who received PCI during the same index hospitalization had higher in‐hospital mortality and morbidity.

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“…The MitraClip™ (Abbott, Santa Clara) is currently the sole percutaneous device that is commercially approved to treat functional mitral regurgitation and more than 80,000 patients have undergone repair with this device in the past decade ( Abbott 2019 ). To reduce regurgitation, the device approximates the anterior and posterior mitral valve leaflets to create a double-barrel mitral orifice, a process that is relatively straightforward to simulate in a finite element setting ( Zhang et al 2019 ). The process to assess credibility of these simulations can be classified into three categories: First, the approach should show a general agreement between the expected behavior and the predicted metrics.…”

Section: Regulatory Perspective—medical Device Innovationmentioning

confidence: 99%

“…An important missing link is the longitudinal assessment of chronic disease management. From an analysis point of view, this involves not only simulate and analyze the acute changes in the stretch and stress profiles in response to the intervention ( Zhang et al 2019 ), but to predict and understand the chronic changes in form and function ( Rausch et al 2017 ). Another future direction is to integrate simulation results, animal models, and clinical data using physics-based machine learning towards a more holistic understanding of disease progression and the long-term effects of intervention.…”

Section: Regulatory Perspective—medical Device Innovationmentioning

confidence: 99%

Precision medicine in human heart modeling

Peirlinck

Costabal

Jiang

et al. 2021

Biomech Model Mechanobiol

107

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Precision medicine is a new frontier in healthcare that uses scientific methods to customize medical treatment to the individual genes, anatomy, physiology, and lifestyle of each person. In cardiovascular health, precision medicine has emerged as a promising paradigm to enable cost-effective solutions that improve quality of life and reduce mortality rates. However, the exact role in precision medicine for human heart modeling has not yet been fully explored. Here, we discuss the challenges and opportunities for personalized human heart simulations, from diagnosis to device design, treatment planning, and prognosis. With a view toward personalization, we map out the history of anatomic, physical, and constitutive human heart models throughout the past three decades. We illustrate recent human heart modeling in electrophysiology, cardiac mechanics, and fluid dynamics and highlight clinically relevant applications of these models for drug development, pacing lead failure, heart failure, ventricular assist devices, edge-to-edge repair, and annuloplasty. With a view toward translational medicine, we provide a clinical perspective on virtual imaging trials and a regulatory perspective on medical device innovation. We show that precision medicine in human heart modeling does not necessarily require a fully personalized, high-resolution whole heart model with an entire personalized medical history. Instead, we advocate for creating personalized models out of population-based libraries with geometric, biological, physical, and clinical information by morphing between clinical data and medical histories from cohorts of patients using machine learning. We anticipate that this perspective will shape the path toward introducing human heart simulations into precision medicine with the ultimate goals to facilitate clinical decision making, guide treatment planning, and accelerate device design.

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Mechanical effects of MitraClip on leaflet stress and myocardial strain in functional mitral regurgitation – A finite element modeling study

Cited by 19 publications

References 38 publications

Transcatheter MitraClip repair alters mitral annular geometry – device induced annular remodeling on three-dimensional echocardiography predicts therapeutic response

Transcatheter MitraClip repair alters mitral annular geometry – device induced annular remodeling on three-dimensional echocardiography predicts therapeutic response

Impact of preexisting coronary arterial disease in patients undergoing percutaneous mitral valve repair (MitraClip)

Precision medicine in human heart modeling

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