Computational modeling of vascular tissue damage for the development of safe interventional devices

Mathieu Oude Vrielink, Peter H.M. Timmermans, Bertus F.A. van de Wetering, Ron Hovenkamp, Olaf van der Sluis (Corresponding author)

Research output: Contribution to journalArticleAcademicpeer-review

Abstract

During intravascular procedures, medical devices interact mechanically with vascular tissue. The device design faces a trade-off: although a high bending stiffness improves its maneuvrability and deliverability, it may also trigger excessive supra-physiological loading that may result in tissue damage. In particular, the collagen fibers in vascular walls are load-bearing but may rupture on a microscopic scale due to mechanical interaction. When the mechanical load increases even further, tissue rupture or puncture occurs. To mitigate tissue damage, the current work focusses on the development of computational Finite Element (FE) based models wherein state-of-the-art constitutive tissue models are applied toward the design of safe devices. Several experiments are presented for tissue characterization in which device-mimicking indenters are pressed onto a porcine tissue. In these experiments, the Mullins effect, which is related to tissue damage, is observed. Consequently, the mechanical behavior of tissue, including the evolution of damage-induced energy dissipation, is accurately described by adopting a hyperelastic model incorporating the damage approach by Weisbecker et al. (2012). From the experimentally validated computational model, a novel design criterion is established, which allows for safe device development. Furthermore, an energy density criterion for the onset of puncture is proposed. With these tools, several frequently used work-horse guidewires are numerically evaluated.
Original languageEnglish
Article number106818
Number of pages14
JournalJournal of the Mechanical Behavior of Biomedical Materials
Volume163
Early online date23 Nov 2024
DOIs
Publication statusE-pub ahead of print - 23 Nov 2024

Keywords

  • vascular tissue
  • damage
  • pseudo-elastic
  • hyperelastic
  • FEM
  • indentation
  • tip load
  • device-tissue interaction

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