The effect of simulated food liquids on the surface structure and solubility of various esthetic restorations

Year 2024, Volume: 7 Issue: 4, 436 - 443, 30.07.2024

Abdurrahman Yalçın , Elif Pınar Bakır , Şeyhmus Bakır

https://doi.org/10.32322/jhsm.1504516

Abstract

Aims: The aim of this study is to investigate the surface roughness and solubility of restorative materials when exposed to foodstuffs in the oral environment using simulated food liquids as defined by the Food and Drug Administration.
Methods: In this study, a total of four esthetic restorative materials were used: one universal compomer (Dyract XP, Dentsply), one conventional microhybrid composite (FiltekTM Z250, 3M ESPE), one nanofilled, and one high-viscosity glass ionomer cement (ChemFil Rock, Dentsply). A total of 160 samples, each 8 mm in diameter and 2 mm in thickness, were prepared using molds. The initial weights of the samples were recorded in micrograms using a precision balance to determine solubility values. Initial surface roughness values were measured using an atomic force microscope device. The samples were immersed in four different simulated food liquids (ethanol, heptane, citric acid, and distilled water) for a period of 7 days. After removal from the solutions, the samples were desiccated to a constant weight, and the second set of weights was recorded. Subsequently, the second surface roughness values were measured
Results: Among the materials immersed in the simulated food solutions, ChemFil Rock exhibited the highest solubility and increase in surface roughness. Citric acid was found to be the solution that caused the highest increase in surface roughness values and solubility for this material (p<0.005). It was observed that Dyract XP was more affected by heptane solution, while Filtek Z-250 and G-aenial anterior materials were more affected by ethanol.
Conclusion: All the restorative materials used in our study were found to be affected by simulated food liquids to varying degrees in terms of surface roughness and solubility.

Keywords

Esthetic restorative materials, simulated food liquids, surface roughness, solubility

Ethical Statement

Ethics committee approval is not required for this study.

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