In silico assessment of the bone regeneration potential of complex porous scaffolds

Mechanical environment plays a crucial role in regulating bone regeneration in bone defects. Assessing the mechanobiological behavior of patient-specific orthopedic scaffolds in-silico could help guide optimal scaffold designs, as well as intra- and post-operative strategies to enhance bone regenera...

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Detalles Bibliográficos
Autores: Asbai-Ghoudan, R. (Reduan)|||/items/a2a5210b-c356-465e-b204-9195272f76d2, Nasello, G. (Gabriele)|||/items/67d1473e-beeb-4b99-8061-79ba8b5f61d3, Pérez, M.A. (María Ángeles)|||/items/ea6b9fa1-64a3-42d1-bb56-673410bfbe0c, Verbruggen, S.W. (Stefaan W.)|||/items/49d0318a-d77c-40e8-a3ee-7ee525725c5f, Ruiz-de-Galarreta-Moriones, S.(Sergio)|||/items/3320edac-66b8-4179-b4c1-ded047961ad3, Rodríguez-Florez, N. (Naiara)|||/items/0e6cedfb-6a96-4e19-b698-c97e11c6d94c
Tipo de recurso: artículo
Fecha de publicación:2023
País:España
Institución:Universidad de Navarra
Repositorio:Dadun. Depósito Académico Digital de la Universidad de Navarra
Idioma:inglés
OAI Identifier:oai:dadun.unav.edu:10171/67845
Acceso en línea:https://hdl.handle.net/10171/67845
Access Level:acceso abierto
Palabra clave:Bone regeneration
FE-Based model
Mechanical stimulus
Mechanobiology
Scaffolds
Triply periodic minimal surfaces
Descripción
Sumario:Mechanical environment plays a crucial role in regulating bone regeneration in bone defects. Assessing the mechanobiological behavior of patient-specific orthopedic scaffolds in-silico could help guide optimal scaffold designs, as well as intra- and post-operative strategies to enhance bone regeneration and improve implant longevity. Additively manufactured porous scaffolds, and specifically triply periodic minimal surfaces (TPMS), have shown promising structural properties to act as bone substitutes, yet their ability to induce mechanobiologially-driven bone regeneration has not been elucidated. The aim of this study is to i) explore the bone regeneration potential of TPMS scaffolds made of different stiffness biocompatible materials, to ii) analyze the influence of pre-seeding the scaffolds and increasing the post-operative resting period, and to iii) assess the influence of patient-specific parameters, such as age and mechanosensitivity, on outcomes. To perform this study, an in silico model of a goat tibia is used. The bone ingrowth within the scaffold pores was simulated with a mechano-driven model of bone regeneration. Results showed that the scaffold's architectural properties affect cellular diffusion and strain distribution, resulting in variations in the regenerated bone volume and distribution. The softer material improved the bone ingrowth. An initial resting period improved the bone ingrowth but not enough to reach the scaffold's core. However, this was achieved with the implantation of a pre-seeded scaffold. Physiological parameters like age and health of the patient also influence the bone regeneration outcome, though to a lesser extent than the scaffold design. This analysis demonstrates the importance of the scaffold's geometry and its material, and highlights the potential of using mechanobiological patient-specific models in the design process for bone substitutes.