Unveiling the mechanisms behind surface degradation of dental resin composites in simulated oral environments

Dental resin composites are widely used as restorative materials due to their natural aesthetic and versatile properties. However, there has been limited research on the degradation mechanisms of these composites in gastric acid environments, which would be common in patients with gastroesophageal reflux. This study aims to investigate the degradation behavior of dental composites immersed in simulated oral environments, including acid, saliva, and water. Mechanical and morphological properties of the composites, upon immersion in the simulated environments, were thoroughly examined using hardness testing and SEM imaging. Qualitative analyses of the ions leached from the polymer matrix and fillers were conducted using XPS and ICP-MS. In addition, the thermodynamic stability of the inorganic fillers of the composites in aqueous solutions across a wide range of pH values was theoretically studied through construction of Pourbaix diagrams. This study proposed a mechanism for composite leaching involving interactions between the matrix's hydrophilic groups and the aqueous immersion media, leading to swelling and chemical degradation of the composites. Furthermore, it was demonstrated that filler leaching was followed by ion exchange with Ca and P, resulting in the formation of hard calcified layers on the composite surface. The current findings provide valuable insights into the development of new composite materials with improved durability and resistance to degradation, especially for patients suffering from gastroesophageal reflux.

Automated summary

This study investigates the degradation behavior of dental resin composites in simulated oral environments. The mechanical and morphological properties of the composites were examined using hardness testing and SEM imaging. Qualitative analyses of the leached ions and theoretical studies on the stability of inorganic fillers were conducted. The study proposes a mechanism for composite leaching and demonstrates the formation of calcified layers on the composite surface. These findings contribute to the development of more durable and resistant composite materials, particularly for patients with gastroesophageal reflux.