Fachinformationsdienst BAUdigital

A platform for research: civil engineering, architecture and urbanism

    3D-Printed Composite Bone Bricks For Large Bone Tissue Applications

    New search for: Daskalakis Evangelos
    New search for: Liu Fengyuan
    New search for: Acar Anil A.
    New search for: Dinea Edera-Elena
    New search for: Cooper Glen
    New search for: Weightman Andrew
    New search for: Koç Bahattin
    New search for: Blunn Gordon
    New search for: Jorge Bártolo Paulo

    This study investigates the use of low cost, customizable, biodegradable, polymer-ceramic composite porous structures (bone bricks) for large bone tissue regeneration. Different ceramic materials (hydroxyapatite (HA), β-tri-calcium phosphate (TCP) and Bioglass (45S5) were mixed with poly-ε-caprolactone (PCL). Bone bricks with different material compositions were produced using an extrusion-based additive manufacturing system. Produced bone bricks were morphologically and mechanically assessed. Results allowed to establish a correlation between scaffolds architecture and material composition and scaffolds performance. Reinforced scaffolds showed improved mechanical properties. Best mechanical properties were obtained with PCL/TCP bone bricks and topologies based on 38 double zig zag filaments and 14 spirals.

    Access

    Download

    Access

    Download

    Page navigation

    Document information
    Similar titles

    Export, share and cite

    3D-Printed Composite Bone Bricks For Large Bone Tissue Applications

    New search for: Daskalakis Evangelos
    New search for: Liu Fengyuan
    New search for: Acar Anil A.
    New search for: Dinea Edera-Elena
    New search for: Cooper Glen
    New search for: Weightman Andrew
    New search for: Koç Bahattin
    New search for: Blunn Gordon
    New search for: Jorge Bártolo Paulo

    This study investigates the use of low cost, customizable, biodegradable, polymer-ceramic composite porous structures (bone bricks) for large bone tissue regeneration. Different ceramic materials (hydroxyapatite (HA), β-tri-calcium phosphate (TCP) and Bioglass (45S5) were mixed with poly-ε-caprolactone (PCL). Bone bricks with different material compositions were produced using an extrusion-based additive manufacturing system. Produced bone bricks were morphologically and mechanically assessed. Results allowed to establish a correlation between scaffolds architecture and material composition and scaffolds performance. Reinforced scaffolds showed improved mechanical properties. Best mechanical properties were obtained with PCL/TCP bone bricks and topologies based on 38 double zig zag filaments and 14 spirals.

    Access

    Download

    3D-Printed Composite Bone Bricks For Large Bone Tissue Applications

    New search for: Daskalakis Evangelos
    New search for: Liu Fengyuan
    New search for: Acar Anil A.
    New search for: Dinea Edera-Elena
    New search for: Cooper Glen
    New search for: Weightman Andrew
    New search for: Koç Bahattin
    New search for: Blunn Gordon
    New search for: Jorge Bártolo Paulo

    This study investigates the use of low cost, customizable, biodegradable, polymer-ceramic composite porous structures (bone bricks) for large bone tissue regeneration. Different ceramic materials (hydroxyapatite (HA), β-tri-calcium phosphate (TCP) and Bioglass (45S5) were mixed with poly-ε-caprolactone (PCL). Bone bricks with different material compositions were produced using an extrusion-based additive manufacturing system. Produced bone bricks were morphologically and mechanically assessed. Results allowed to establish a correlation between scaffolds architecture and material composition and scaffolds performance. Reinforced scaffolds showed improved mechanical properties. Best mechanical properties were obtained with PCL/TCP bone bricks and topologies based on 38 double zig zag filaments and 14 spirals.

    Access

    Download

    Access

    Download

    Page navigation

    Document information
    Similar titles

    Export, share and cite

    Document information
    Title:

    3D-Printed Composite Bone Bricks For Large Bone Tissue Applications

    Contributors:

    Daskalakis Evangelos (author) / Liu Fengyuan (author) / Acar Anil A. (author) / Dinea Edera-Elena (author) / Cooper Glen (author) / Weightman Andrew (author) / Koç Bahattin (author) / Blunn Gordon (author) / Jorge Bártolo Paulo (author)

    Published in:

    MATEC Web of Conferences, Vol 318, p 01009 (2020)

    Publication date:

    2020

    ISSN:

    2261-236X

    DOI:

    https://doi.org/10.1051/matecconf/202031801009

    Type of media:

    Article (Journal)

    Type of material:

    Electronic Resource

    Language:

    Unknown

    Keywords:

    Engineering (General). Civil engineering (General) , TA1-2040

    Metadata by DOAJ is licensed under ​CC BY-SA 1.0

    Similar titles

    Bioactive Composite Materials for Bone Tissue Applications

    Ferreira, B. J. M. L. / Duarte, M. G. G. M. / Gil, M. H. et al. | British Library Online Contents | 2006

    Hydroxyapatite/Biopolymers Composite Scaffolds for Bone Tissue Engineering

    Fook, A.C.B.M. / Fideles, T.B. / Barbosa, R.C. et al. | British Library Online Contents | 2012

    3D‐printed cryomilled poly(ε‐caprolactone)/graphene composite scaffolds for bone tissue regeneration

    Dias, Daniela / Vale, A. Catarina / Cunha, Eunice Paula Freitas et al. | BASE | 2021

    Free access

    Laminated electrospun nHA/PHB-composite scaffolds mimicking bone extracellular matrix for bone tissue engineering

    Chen, Zhuoyue / Song, Yue / Zhang, Jing et al. | British Library Online Contents | 2017

    Development of 3D-printed PLGA/TiO2 nanocomposite scaffolds for bone tissue engineering applications

    Rasoulianboroujeni, M. / Fahimipour, F. / Shah, P. et al. | British Library Online Contents | 2019

    Back to top