Suture Forces in Undersized Mitral Annuloplasty: Novel Device and Measurements

Siefert, Andrew; Pierce, Eric T.; Lee, Madonna; Jensen, Morten Ø.; Aoki, Chikashi; Takebayashi, Satoshi; Esmerats, Joan Fernández; Gorman, Robert C.; Gorman, Joseph H.; Yoganathan, Ajit P.

doi:10.1016/j.athoracsur.2014.02.036

Cited by 19 publications

(26 citation statements)

References 10 publications

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“…[17] Transducers are designed to report suture tension as a positive force tracing. Before use in this study, the transducers were calibrated with known forces exceeding those anticipated in vivo , as previously described.…”

Section: Methodsmentioning

confidence: 99%

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How Local Annular Force and Collagen Density Govern Mitral Annuloplasty Ring Dehiscence Risk

Pierce

Siefert

Paul

et al. 2016

The Annals of Thoracic Surgery

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Background Annuloplasty ring dehiscence is a well described mechanism of mitral valve repair failure. Defining the mechanisms underlying dehiscence may facilitate its prevention. Methods Factors governing suture dehiscence were examined using an ovine model. Following undersized ring annuloplasty in live animals (N=5), Cyclic Force (FC) acting on sutures during cardiac contraction were measured using custom transducers. FC was measured at 10 suture positions, throughout cardiac cycles with peak left ventricular pressure (LVPmax) of 100, 125, and 150mmHg. Suture pullout testing was conducted on explanted mitral annuli (N=12) to determine suture holding strength at each position. Finally, relative collagen density differences at suture sites around the annulus were assessed by two-photon excitation fluoroscopy. Results Anterior FC exceeded posterior at each LVPmax (e.g. 2.8±1.3 vs. 1.8±1.2N at LVPmax=125mmHg, p<0.01). Anterior holding strength exceeded posterior (6.4±3.6 vs. 3.9±1.6N, p<0.0001). Based on FC at LVPmax=150mmHg, margin of safety before suture pullout was vastly higher between the trigones (exclusive) versus elsewhere (4.8±0.9 versus 1.9±0.5N, p<0.001). Margin of safety exhibited strong correlation to collagen density (R2=0.947). Conclusions Despite lower cyclic loading on posterior sutures, the weaker posterior mitral annular tissue creates higher risk of dehiscence, apparently due to reduced collagen content. Sutures placed atop the trigones are less secure than predicted, due to a combination of reduced collagen and higher overall rigidity in this region. These findings highlight the inter-trigonal tissue as the superior anchor, and have implications on the design and implantation techniques for next-generation mitral prostheses.

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Section: Methodsmentioning

confidence: 99%

“…All in vivo experimental procedures for ring implantation (1C–D) and measurement were performed as we previously described. [17]…”

Section: Methodsmentioning

confidence: 99%

How Local Annular Force and Collagen Density Govern Mitral Annuloplasty Ring Dehiscence Risk

Pierce

Siefert

Paul

et al. 2016

The Annals of Thoracic Surgery

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“…11). 45 Similar to the methods illustrated in Fig. 7, a fluid bulb and aortic cross-clamp are used to statically pressurize the LV prior to evaluating select experimental endpoints.…”

Section: Modeling the Effects Of MV Annuloplastymentioning

confidence: 99%

Bench Models for Assessing the Mechanics of Mitral Valve Repair and Percutaneous Surgery

Siefert

Siskey

2014

Cardiovasc Eng Tech

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Rapid preclinical evaluations of mitral valve (MV) mechanics are currently best facilitated by bench models of the left ventricle (LV). This review aims to provide a comprehensive assessment of these models to aid interpretation of their resulting data, inform future experimental evaluations, and further the translation of results to procedure and device development. For this review, two types of experimental bench models were evaluated. Rigid LV models were characterized as fluid-mechanical systems capable of testing explanted MVs under static and or pulsatile left heart hemodynamics. Passive LV models were characterized as explanted hearts whose left side is placed in series with a static or pulsatile flow-loop. In both systems, MV function and mechanics can be quantitatively evaluated. Rigid and passive LV models were characterized and evaluated. The materials and methods involved in their construction, function, quantitative capabilities, and disease modeling were described. The advantages and disadvantages of each model are compared to aid the interpretation of their resulting data and inform future experimental evaluations. Repair and percutaneous studies completed in these models were additionally summarized with perspective on future advances discussed. Bench models of the LV provide excellent platforms for quantifying MV repair mechanics and function. While exceptional work has been reported, more research and development is necessary to improve techniques and devices for repair and percutaneous surgery. Continuing efforts in this field will significantly contribute to the further development of procedures and devices, predictions of long-term performance, and patient safety.

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“…We recently demonstrated novel transducers capable of quantifying tension in individual sutures in the beating heart, post-mitral annuloplasty. 2 We have expanded these methods to evaluate the effects of ring size, shape, and ventricular function on suture forces, to identify physiologic and device-specific factors that may affect suture dehiscence risk. As part of this study, a Profile3D ring (size:26; Medtronic, Dublin, Ireland), instrumented with transducers, was implanted in a healthy 45kg subject (annulus size:30).…”

Section: Clinical Summarymentioning

confidence: 99%

“…Implantation (Figure 1) was analogous to clinical annuloplasty, using ten 2-0 Ti·Cron TM sutures (Covidien, Dublin, Ireland) with approximately 10mm suture width and 1.5mm depth; transducers did not affect ring or suture function. 2 Animal care complied with protocols approved by the Institutional Animal Care and Use Committee at University of Pennsylvania, according to guidelines for humane care (National Institutes of Health Publication 85–23, revised 1996).…”

Section: Clinical Summarymentioning

confidence: 99%

Real-time recording of annuloplasty suture dehiscence reveals a potential mechanism for dehiscence cascade

Pierce

Gentile

Siefert³

et al. 2016

The Journal of Thoracic and Cardiovascular Surgery

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Suture Forces in Undersized Mitral Annuloplasty: Novel Device and Measurements

Cited by 19 publications

References 10 publications

How Local Annular Force and Collagen Density Govern Mitral Annuloplasty Ring Dehiscence Risk

How Local Annular Force and Collagen Density Govern Mitral Annuloplasty Ring Dehiscence Risk

Bench Models for Assessing the Mechanics of Mitral Valve Repair and Percutaneous Surgery

Real-time recording of annuloplasty suture dehiscence reveals a potential mechanism for dehiscence cascade

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