In vitro marginal and internal adaptation of metal-ceramic crowns with cobalt-chrome and titanium framework fabricated with CAD/CAM and casting technique

###EgeUn###Aim: The purpose of this study was to compare the marginal and internal fit of Co-Cr and titanium ceramic crowns fabricated with 2 different techniques: CAD/CAM milling and traditional casting (TC). Materials and Methods: Ten traditional casting of Co-Cr (TCC), 10 CAD/CAM milling of Co-Cr (MC), 10 traditional casting of titanium (TCT), 10 CAD/CAM milling of titanium ceramic crowns (MT) were fabricated. Silicone replicas were obtained to measure internal gap volume, marginal gap and internal adaptation that was evaluated at 3 regions: axial wall, axio-occlusal angle, and occlusal surface. Measurements were made with a X-ray micro computerized tomography (micro-CT) and analyzed with Bonferroni and Dunnet T3 post-hoc tests (a = 0.05). Results: One-way ANOVA revealed no statistically significant differences among the groups for measurements at the marginal gap (P 0.05). At axial wall region the mean values of TCT group were higher than those of groups but only statistically not significant for TCC group (P < 0.05). TCC group statistically gives better results than MC group in axio-occlusal and occlusal regions (P < 0.05). The mean measurement of internal gap volume were 20.59 0.83 mm(3) for TCC, 22.73 0.82 mm(3) for MC, 22.83 1.11 mm(3) for TCT and 20.51 1.16 mm(3) for MT. Mean internal gap volume values MT group were smaller than those of groups but only statistically not significant for TCC group (P 0.05). Conclusion: All groups performed similar marginal adaptation. The cement film thickness at axio-occlusal angle point and occlusal region were higher for MC crowns

Effects of Sandblasting and Silicoating on Bond Strength between Titanium and Porcelain

WOS: 000443749400015PubMed ID: 30156204Purpose: The aim of this study was to evaluate the effects of the different sized alumina particles (50 and 150 mu m) and tribochemical silica-modified alumina particles (110 mu m) on titanium (Ti) surface to identify the most effective method of increasing the bond strength between porcelain and Ti. Materials and Methods: Thirty rectangular plates (15 mm x 50 mm x 1 mm) of commercially pure Ti (Cp Ti) Grade 5 (GC Dental Industrial Corporation, Tokyo, Japan) were divided into three groups for different surface modification procedures (n = 10). Ti bonder porcelain, opaque, and dentin layers were fired separately on Ti plates. All specimens were placed in a bending jig for four-point bending test. The load and crosshead displacement data were collected to calculate the strain energy release rate as a G value. Results: Lowest mean G values in J/m(2) were in the group sandblasted with 150 mu m Al2O3 particles (Group 2) (18.6 +/- 5), followed by the group sandblasted with 50 mu m Al2O3 particles (Group 3) (20.8 +/- 6.1) and the group sandblasted with 110 mu m silicoated Al2O3 particles (Group 1) (24.5 +/- 4.1). The one-way ANOVA and Bonferroni post hoc tests indicated that there was a statistically significant difference between Group 1 and Group 2 (P 0.05). Conclusion: The size of alumina particles is not a factor that is directly effective in enhancing the bond strength of Ti-porcelain systems. The bond strength of Ti-porcelain systems can be extremely improved by the application of sandblasting with silica-coated alumina particles