Experimental study of a 3D printed permanent implantable porous Ta-coated bone plate for fracture fixation
Metal plates have always been the gold standard in the clinic for internal fracture fixation due to their high strength advantages. However, high elastic modulus can cause stress shielding and lead to bone embrittlement. This study used an electron beam melting method to prepare personalized porous...
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Autores principales: | , , , , , , , , , , , |
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Formato: | article |
Lenguaje: | EN |
Publicado: |
KeAi Communications Co., Ltd.
2022
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Materias: | |
Acceso en línea: | https://doaj.org/article/352f805f2d8f499490523cf589e62944 |
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Sumario: | Metal plates have always been the gold standard in the clinic for internal fracture fixation due to their high strength advantages. However, high elastic modulus can cause stress shielding and lead to bone embrittlement. This study used an electron beam melting method to prepare personalized porous Ti6Al4V (pTi) bone plates. Then, chemical vapor deposition (CVD) technology coats tantalum (Ta) metal on the pTi bone plates. The prepared porous Ta-coated bone plate has an elastic modulus similar to cortical bone, and no stress shielding occurred. In vitro experiments showed that compared with pTi plates, Ta coating significantly enhances the attachment and proliferation of cells on the surface of the scaffold. To better evaluate the function of the Ta-coated bone plate, animal experiments were conducted using a coat tibia fracture model. Our results showed that the Ta-coated bone plate could effectively fix the fracture. Both imaging and histological analysis showed that the Ta-coated bone plate had prominent indirect binding of callus formation. Histological results showed that new bone grew at the interface and formed good osseointegration with the host bone. Therefore, this study provides an alternative to bio-functional Ta-coated bone plates with improved osseointegration and osteogenic functions for orthopaedic applications. |
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