In Silico Performance of a Recellularized Tissue-Engineered Transcatheter Aortic Valve

Noble, Christopher; Choe, Joshua A.; Uthamaraj, Susheil; DeHerrera, Milton; Lerman, Amir; Young, Melissa

doi:10.1115/1.4043209

Cited by 10 publications

(2 citation statements)

References 37 publications

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“…The study of prosthetic valvular replacements, particularly of the AV, is another area where in silico models are making great strides. Using computational flow or imaging-based models, researchers have created unique metrics that evaluate valvular replacement performance, addressing aspects such as leaflet thrombosis, abnormal flow patterns, blood damage, hinge design outcomes, paravalvular leakage, and left ventricular dynamics, while also creating novel preoperative, patient-specific planning protocols and prediction tools for surgical or transcatheter interventions ( 22 – 32 ). These models provide detailed views through unique quantifications, developing deeper intuition behind the valvular mechanics.…”

Section: In Silico Modelingmentioning

confidence: 99%

Heart Valve Biomechanics: The Frontiers of Modeling Modalities and the Expansive Capabilities of Ex Vivo Heart Simulation

Park

Zhu

Imbrie-Moore

et al. 2021

Front. Cardiovasc. Med.

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The field of heart valve biomechanics is a rapidly expanding, highly clinically relevant area of research. While most valvular pathologies are rooted in biomechanical changes, the technologies for studying these pathologies and identifying treatments have largely been limited. Nonetheless, significant advancements are underway to better understand the biomechanics of heart valves, pathologies, and interventional therapeutics, and these advancements have largely been driven by crucial in silico, ex vivo, and in vivo modeling technologies. These modalities represent cutting-edge abilities for generating novel insights regarding native, disease, and repair physiologies, and each has unique advantages and limitations for advancing study in this field. In particular, novel ex vivo modeling technologies represent an especially promising class of translatable research that leverages the advantages from both in silico and in vivo modeling to provide deep quantitative and qualitative insights on valvular biomechanics. The frontiers of this work are being discovered by innovative research groups that have used creative, interdisciplinary approaches toward recapitulating in vivo physiology, changing the landscape of clinical understanding and practice for cardiovascular surgery and medicine.

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Section: In Silico Modelingmentioning

confidence: 99%

Heart Valve Biomechanics: The Frontiers of Modeling Modalities and the Expansive Capabilities of Ex Vivo Heart Simulation

Park

Zhu

Imbrie-Moore

et al. 2021

Front. Cardiovasc. Med.

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“…In the arena of semilunar heart valves, in specific, our results may also provide a comprehensive benchmark for comparing the mechanical behaviour of tissue-engineered versus native valves. A recent study on modelling the behaviour of tissueengineered AVs employs a rate of 0.02 s -1 (Noble et al 2019), citing preceding studies using the same range of rates. In view of the current study, the documented mechanical behaviour at 0.02 s -1 may not be directly representative of the in vivo behaviour.…”

Section: Implications For Future Developmentsmentioning

confidence: 99%

Rate-dependent mechanical behaviour of semilunar valves under biaxial deformation: From quasi-static to physiological loading rates

Anssari-Benam¹,

Tseng

Holzapfel

et al. 2020

Journal of the Mechanical Behavior of Biomedical Materials

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In this study we investigate the rate-dependency of the mechanical behaviour of semilunar heart valves under biaxial deformation, from quasi-static to physiological loading rates. This work extends and complements our previous undertaking, where the rate-dependency in the mechanical behaviour of semilunar valve specimens was documented in sub-physiological rate domains (Acta Biomater. 2019, https://doi.org/10.1016/j.actbio.2019.02.008). For the first time we demonstrate herein that the stress-stretch curves obtained from specimens under physiological rates too are markedly different to those at sufficiently lower rates and at quasistatic conditions. The results importantly underline that the mechanical behaviour of semilunar heart valves is rate dependent, and the physiological mechanical behaviour of the valves may not be correctly obtained via material characterisation tests at arbitrary low deformation rates.Presented results in this work provide an inclusive dataset for material characterisation and modelling of semilunar heart valves across a 10,000 fold deformation rate, both under equibiaxial and 1:3 ratio deformation rates. The important application of these results is to inform the development of appropriate mechanical testing protocols, as well as devising new models, for suitable determination of the rate-dependent constitutive mechanical behaviour of the semilunar valves.

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Evaluation of Pericardial Tissues from Assorted Species as a Tissue-Engineered Heart Valve Material

Noble

Morse

Lerman

et al. 2022

Med Biol Eng Comput

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In Silico Performance of a Recellularized Tissue-Engineered Transcatheter Aortic Valve

Cited by 10 publications

References 37 publications

Heart Valve Biomechanics: The Frontiers of Modeling Modalities and the Expansive Capabilities of Ex Vivo Heart Simulation

Heart Valve Biomechanics: The Frontiers of Modeling Modalities and the Expansive Capabilities of Ex Vivo Heart Simulation

Rate-dependent mechanical behaviour of semilunar valves under biaxial deformation: From quasi-static to physiological loading rates

Evaluation of Pericardial Tissues from Assorted Species as a Tissue-Engineered Heart Valve Material

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