3D-Printed Bioceramic Scaffolds with High Strength and High Precision

Due to the increasing cases of bone damage and graft demand, bone-repair technology has great social economic benefits manufacturing artificial implants become a focus in domain regenerative therapy. Considering that traditional process cannot effectively control overall size scaffold, diameter shape micropores, interoperability 3D printing emerged as focal point research within realm tissue engineering. However, accuracy extrusion-based biological techniques is low. In this research, we utilized three-dimensional develop high-precision magnesium-containing silicate (CSi-Mg) scaffolds. The precision innovative method was scrutinized influence pore on scaffold strength systematically analyzed. Furthermore, architecture sidewalls these 3D-printed scaffolds evaluated terms mechanical properties. CSi-Mg post 3-week immersion simulated body fluid, demonstrated high modulus elasticity (exceeding 404 MPa) significant compressive (beyond 47 MPa). it exhibited commendable bioactivity biodegradability. These results suggest hold promise for addressing challenging defect cases.