Microstructural investigation of hybrid CAD/CAM restorative dental materials by micro-CT and SEM

TL;DR

This study uses micro-CT and SEM to analyze the microstructures of various hybrid CAD/CAM dental materials, revealing differences in filler distribution, porosity, and macrostructure that impact their properties.

Contribution

It provides a comparative microstructural analysis of hybrid CAD/CAM dental materials using advanced imaging techniques, highlighting differences based on manufacturing methods.

Findings

3D-printed hybrid shows agglomerations and layered macrostructure

Millable hybrid materials have more homogeneous filler distribution

Direct composite exhibits air bubbles and irregularities

Abstract

Objectives: An increasing number of CAD/CAM (computer-aided design/computer-aided manufacturing) hybrid materials have been introduced to the dental market in recent years. In addition, CAD/CAM hybrid materials for additive manufacturing (AM) are becoming more attractive in digital dentistry. Studies on material microstructures using micro-computed tomography ($\mu$-CT) combined with scanning electron microscopy (SEM) have only been available to a limited extent so far. Methods: One CAD/CAM three-dimensional- (3D-) printable hybrid material (VarseoSmile Crown plus) and two CAD/CAM millable hybrid materials (Vita Enamic; Voco Grandio), as well as one direct composite material (Ceram.x duo), were included in the present study. Cylindrical samples with a diameter of 2 mm were produced from each material and investigated by means of synchrotron radiation $\mu$-CT at a voxel size of 0.65 $\mu$m. Different samples from the same materials, obtained by cutting and polishing, were investigated by SEM. Results: The 3D-printed hybrid material showed some agglomerations and a more irregular distribution of fillers, as well as a visible layered macrostructure and a few spherical pores due to the printing process. The CAD/CAM millable hybrid materials revealed a more homogenous distribution of ceramic particles. The direct composite material showed multiple air bubbles and microstructural irregularities based on manual processing. Significance: The $\mu$-CT and SEM analysis of the materials revealed different microstructures even though they belong to the same class of materials. It could be shown that $\mu$-CT and SEM imaging are valuable tools to understand microstructure and related mechanical properties of materials.