3D printing technologies have changed the manufacturing of tissue
engineering scaffolds upside down, giving new possibilities to obtain complex shapes
that perfectly resemble patient defects using old bioceramics or new materials
especially developed as inks for 3D printing.
Bioceramics have been commonly used in tissue regeneration, mainly bone, due to
their high biocompatibility and in some cases, bioactivity. Moreover, they can have
different compositions and proportions, which give rise to a wide variety of properties.
The main types of bioceramics are calcium phosphates and bioactive glasses, but there
are other ceramics such as zirconia and alumina.
The 3D printing of bioceramics is usually performed by mixing particles or powders of
ceramics with a polymer to obtain proper viscosity, and they can be printed through
DIW, SLA or SLS. After printing, they can be sintered to obtain a pure ceramic body,
or left as a composite. Additionally, there is a direct ceramic printing method based on
SLS that does not need a polymer for printing.
These results indicated that 3D printing of bioceramics has the potential to produce
large-scale tissue engineering scaffolds with accurate structure and functionality;
however, further studies are needed to improve the biological response to the 3D
printed scaffolds
Keywords: Aluminia, Bioglass, Bone regeneration, Bioceramics, Composites, Calcium phosphates, DIW, FDM, SLA, SLS, Silica, Sol-gel, Zirconia, 3D printing.
