Preclinical biological and physicochemical evaluation of two-photon engineered 3D biomimetic copolymer scaffolds for bone healing
Kampleitner, Carina and Changi, Katayoon and Felfel, Reda M. and Scotchford, Colin A. and Sottile, Virginie and Kluger, Rainer and Hoffmann, Oskar and Grant, David M. and Epstein, Michelle M. (2020) Preclinical biological and physicochemical evaluation of two-photon engineered 3D biomimetic copolymer scaffolds for bone healing. Biomaterials Science, 8 (6). pp. 1683-1694. ISSN 2047-4830 (https://doi.org/10.1039/c9bm01827a)
Preview |
Text.
Filename: Kampleitner_etal_BS_2020_Preclinical_biological_and_physicochemical_evaluation_of_two_photon_engineered_3D_biomimetic_copolymer_scaffolds.pdf
Final Published Version License: Download (2MB)| Preview |
Abstract
A major challenge in orthopedics is the repair of large non-union bone fractures. A promising therapy for this indication is the use of biodegradable bioinspired biomaterials that stabilize the fracture site, relieve pain and initiate bone formation and healing. This study uses a multidisciplinary evaluation strategy to assess immunogenicity, allergenicity, bone responses and physicochemical properties of a novel biomaterial scaffold. Two-photon stereolithography generated personalized custom-built scaffolds with a repeating 3D structure of Schwarz Primitive minimal surface unit cell with a specific pore size of ∼400 μm from three different methacrylated poly(d,l-lactide-co-ϵ-caprolactone) copolymers with lactide to caprolactone monomer ratios of 16:4, 18:2 and 9:1. Using in vitro and in vivo assays for bone responses, immunological reactions and degradation dynamics, we found that copolymer composition influenced the scaffold physicochemical and biological properties. The scaffolds with the fastest degradation rate correlated with adverse cellular effects and mechanical stiffness correlated with in vitro osteoblast mineralization. The physicochemical properties also correlated with in vivo bone healing and immune responses. Overall these observations provide compelling support for these scaffolds for bone repair and illustrate the effectiveness of a promising multidisciplinary strategy with great potential for the preclinical evaluation of biomaterials.
-
-
Item type: Article ID code: 86497 Dates: DateEvent21 March 2020Published27 January 2020Published Online17 January 2020AcceptedSubjects: Medicine > Biomedical engineering. Electronics. Instrumentation Department: Faculty of Engineering > Mechanical and Aerospace Engineering Depositing user: Pure Administrator Date deposited: 16 Aug 2023 11:53 Last modified: 20 Nov 2024 20:36 URI: https://strathprints.strath.ac.uk/id/eprint/86497