Bioceramic scaffolds fabrication: indirect 3D printing combined with ice-templating vs. robocasting

journal article in Web of Science

English

Ice-templating combined with indirect 3D printing is proposed as a promising method for preparation of scaffolds with multiscale porosity, including a well-defined interconnected macro-channel network. Robocasting was used as a comparative technique to produce scaffolds with comparable porosity at the introduced macroporosity and the inter-grain microporosity levels. Porosity, phase composition and mechanical stability were measured and compared for bio-scaffolds prepared by both techniques. Comparable total porosities could only be achieved in robocasting by choosing a significantly lower sintering temperature (950 degrees C vs. 1200 degrees C). The compressive strength of robocast scaffolds was significantly greater (6.5 +/- 1.19 MPa vs. 2.3 +/- 1.00 MPa, respectively). However, the increased level of interconnected multiscale porosity coupled to a finer grain size of ice-templated samples sintered at 1200 degrees C (similar to 500 nm vs. 2.5 mu m for robocast parts) could prove to be beneficial for the development of highly porous bioactive scaffolds with enhanced biological performance.

Ice-templating, Robocasting,Indirect 3D printing, Whitlockite, Hydroxyapatite

ROLEČEK, J.; PEJCHALOVÁ, L.; MARTÍNEZ-VÁZQUEZ, F.; MIRANDA GONZÁLEZ, P.; SALAMON, D.

1. 4. 2019

0955-2219

Journal of the European Ceramic Society

39

4

United Kingdom of Great Britain and Northern Ireland

1595

1602

8

https://www.sciencedirect.com/science/article/pii/S0955221918307246?via%3Dihub