A Nano-CuO doped sodium aluminosilicate composite ceramic with high efficiency against streptococcus mutans for dental restorative materials

Ceramic-based materials are widely used as dental restorative materials due to their excellent corrosion resis-tance and low shrinkage. However, the pathogenicity caused by abnormal adhesion and colonization of these dental restorative materials by bacteria in the oral cavity significantly affects the restorative results. Therefore, we report an efficient anti-Streptococcus mutans (S. mutans) ceramic material achieved by introducing small copper oxide nanoparticles into the sodium aluminosilicate ceramic material. Our results show that the com-posite ceramic can efficiently kill S. mutans (up to 99.99% antibacterial rate) and has excellent biocompatibility. By examining copper ion release assay, SEM observation, MTT, total protein, and DNA content after co-culture of bacteria, we speculate that copper ions in the composite ceramic disrupt the permeability of S. mutans mem-brane, affect the respiratory system of bacteria, and disrupt DNA proliferation thereby affecting the regular life activity of bacteria and eventually killing S. mutans. Based on our work, it is feasible to develop an efficient antimicrobial material for restorative dentistry by introducing copper ions into the ceramic materials, providing a new perspective for designing high-performance antimicrobial dental restorative materials.

Automated summary

This study successfully developed an efficient anti-Streptococcus mutans material by introducing small copper oxide nanoparticles into the sodium aluminosilicate ceramic material. The composite ceramic showed high antibacterial capability (up to 99.99% antibacterial rate) against S. mutans and excellent biocompatibility. The introduction of copper ions disrupted the permeability of S. mutans membrane, affected the respiratory system of bacteria, and disrupted DNA proliferation, leading to the killing of S. mutans.