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Zirconia-calcium silicate bioactive composites for dental applications using DLP additive manufacturing

Ahmed Binobaid, Michele De Lisi, Josette Camilleri, Hany Hassanin, Khamis Essa

2024Bioprinting11 citationsDOIOpen Access PDF

Abstract

Zirconia has outstanding mechanical strength which made it a favourable material dental implants material. However, its use is limited by challenges in bone bonding and elasticity. This paper introduces a novel bioprinting ceramic material by mixing calcium silicate with zirconia to enhance bioactivity. Using the high precision and speed of Digital Light Processing (DLP), this study develops a novel zirconia-calcium silicate slurry for dental applications. The study reports the preparation of zirconia-calcium silicate, formulation of resin compositions, and optimization of the bioprinting, debinding and sintering. Employing a full factorial Design of Experiments (DOE), a systematic approach was implemented to identify optimal printing conditions such as the layer thickness, exposure time, and power. The results show that slurries formulated with BYK-111 as the dispersant and ACMO/PEGDA/TPO resin, coupled with 80 wt.% solid loading, achieved the most favourable rheological properties, cure depth, and printing accuracy. The optimal printing conditions were 0.75 s exposure time, 300% exposure power, and 30 μm layer thickness, ensured a relative density of the sintered implants exceeding 95%. This study advances dental implant materials by introducing a novel DLP biomaterial with a slurry formulation, presenting significant implications for clinical applications and future research in developing advanced dental and medical implants. • Developed zirconia-calcium silicate biocomposite slurries for dental applications. • Optimized Digital Light Processing (DLP) parameters for enhanced printing accuracy. • 80 wt.% solid loading showed superior dimensional accuracy at lower exposure power. • Excessive exposure time and power caused geometric inaccuracies due to over-curing. • Slurry cured at 500 ms and 750 ms achieved optimal print accuracy and structural integrity.

Topics & Concepts

Cubic zirconiaMaterials scienceSilicateCalcium silicateComposite materialCalciumDentistryChemical engineeringCeramicMetallurgyEngineeringMedicineBone Tissue Engineering MaterialsTitanium Alloys Microstructure and PropertiesAdditive Manufacturing and 3D Printing Technologies
Zirconia-calcium silicate bioactive composites for dental applications using DLP additive manufacturing | Litcius