Document Type
Article
Publication Date
1-2023
Publisher
Elsevier
Source Publication
Materials Letters
Source ISSN
0167-577X
Original Item ID
DOI: 10.1016/j.matlet.2022.133413
Abstract
A modular reinforced bone scaffold with enhanced mechanical properties has recently been developed by our group. It includes: 1) A load-bearing module: a skeleton which is made of a slowly degradable material, undertaking mechanical necessities of the scaffold, and 2) A bio-reactive module: a porous and biodegradable component undertaking biological necessities of the scaffold. The load-bearing module is placed into the bio-reactive module to reinforce it. This paper is dedicated to optimizing the load-bearing module for a certain customized alveolar bone defect. More specifically, a 3D-printed skeleton, made of polycaprolactone (PCL), is optimized based on the boundary conditions of the defect shape using the finite element method (FEM) to minimize the weight (to minimize the amount of PCL) and maximize the mechanical properties and porosity of the skeleton. Gelatin foam has been incorporated into the optimized skeleton through the aminolysis process to form the bio-reactive module. The mechanical characterization confirmed that the optimized load-bearing module has a bridge-like shape and can significantly improve the mechanical properties of the scaffold. Also, in vitro studies showed that the fabricated scaffold can improve cell proliferation and osteogenesis. This kind of scaffold can be useful for the treatment of critical-sized defects.
Recommended Citation
Omidi, Meisam; Almeida, Luis Eduardo; and Tayebi, Lobat, "Optimization of the Modular Reinforced Bone Scaffold for Customized Alveolar Bone Defects" (2023). School of Dentistry Faculty Research and Publications. 568.
https://epublications.marquette.edu/dentistry_fac/568
Comments
Accepted version. Materials Letters, Vol. 331 (January 15, 2023). DOI. © Elsevier 2024. Used with permission.