Multi-objective optimization of auxetic coronary stents based on finite element simulation and surrogate modeling.

Key Points

The optimized PLA-RH stent demonstrates a 60.12% reduction in bending stiffness while enhancing radial performances.
Surrogate modeling and finite element simulation were utilized to evaluate various auxetic stent structures and materials.
Improved radial recoil and force were noted for the re-entrant hexagon stent made from PLA.
The proposed methodologies signal advancements in the design of bioresorbable scaffolds and stents.

Abstract

High cost of clinical trials hinders further enhancement of comprehensive mechanical properties of bioresorbable scaffolds (BRS). Therefore, a multi-objective optimization method combining surrogate modeling and finite element simulation is proposed, based on the evaluation of stents with various auxetic structures and materials. The results demonstrated that re-entrant hexagon stent made of PLA (PLA-RH stent) was a more ideal candidate, with superior radial recoil and force. Following optimization, PLA-RH stent decreased bending stiffness by 60.12%, without compromising radial performances. This method enables more precise and efficient optimization and the proposed auxetic structure introduces innovative concepts for future design of stents.

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Multi-objective optimization of auxetic coronary stents based on finite element simulation and surrogate modeling.

Key Points

Abstract

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