Mechanical modeling of the maturation process for tissue-engineered implants: Application to biohybrid heart valves

The development of tissue-engineered cardiovascular implants can improve the lives of large segments of our society who suffer from cardiovascular diseases. Regenerative tissues are fabricated using a process called tissue maturation. Furthermore, it is highly challenging to produce cardiovascular r...

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Veröffentlicht in:Computers in biology and medicine 2023-12, Vol.167, p.107623-107623, Article 107623
Hauptverfasser: Sesa, M., Holthusen, H., Lamm, L., Böhm, C., Brepols, T., Jockenhövel, S., Reese, S.
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Sprache:eng
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Zusammenfassung:The development of tissue-engineered cardiovascular implants can improve the lives of large segments of our society who suffer from cardiovascular diseases. Regenerative tissues are fabricated using a process called tissue maturation. Furthermore, it is highly challenging to produce cardiovascular regenerative implants with sufficient mechanical strength to withstand the loading conditions within the human body. Therefore, biohybrid implants for which the regenerative tissue is reinforced by standard reinforcement material (e.g. textile or 3d printed scaffold) can be an interesting solution. In silico models can significantly contribute to characterizing, designing, and optimizing biohybrid implants. The first step towards this goal is to develop a computational model for the maturation process of tissue-engineered implants. This paper focuses on the mechanical modeling of textile-reinforced tissue-engineered cardiovascular implants. First, an energy-based approach is proposed to compute the collagen evolution during the maturation process. Then, the concept of structural tensors is applied to model the anisotropic behavior of the extracellular matrix and the textile scaffold. Next, the newly developed material model is embedded into a special solid-shell finite element formulation with reduced integration. Finally, our framework is used to compute two structural problems: a pressurized shell construct and a tubular-shaped heart valve. The results show the ability of the model to predict collagen growth in response to the boundary conditions applied during the maturation process. Consequently, the model can predict the implant’s mechanical response, such as the deformation and stresses of the implant. •Development of finite element framework to model tissue-engineering processes.•An energy-based approach is introduced to compute collagen density evolution.•Model embedded into an efficient and accurate solid-shell element formulation.•Studied the maturation process of a shell construct and an idealized heart valve.
ISSN:0010-4825
1879-0534
DOI:10.1016/j.compbiomed.2023.107623