Resistance of core materials against torsional forces on differently conditioned titanium posts

Statement of problem. The separation of core materials from titanium posts, which have a low modulus of elasticity, has been identified as a problem in restorative dentistry.

Purpose. This study evaluated the resistance to torsional forces of various core materials adapted to differently conditioned titanium posts.

Material and methods. Seven hundrd and twenty specimens were tested consisting of. 6 core materials and 5 surface conditioning techniques for 2 kinds of opaquers with 10 specimens in each group (6 X 5 X 2 X 10=600) plus 6 core materials and 2 opaquers were tested and considered as control groups on nonconditioned titanium posts, each group containing 10 specimens (6 X 2 X 10=120). The custom-made pure titanium posts were conditioned with the following products: Silicoater Classical, Silicoater MD, Rocatec, Kevloc, and Siloc surface-conditioning systems. Subsequently, 6 core materials with different compositions (Durafill, Adaptic, Coradent, Ti-Core, Hytac Aplitip, and Photac-Fil Aplitip) were applied to titanium posts that were previously coated with 2 types of light-polymerized opaquers, either Artglass or Dentacolor. Sixty air-abraded titanium posts (250 mum, 30 seconds) were used as controls for each core material. Following thermocycling (5degrees-55degreesC, 30 seconds, 5000 cycles), maximum torsional forces were determined with an electronic torque movement key. Data were statistically analyzed by 1-way analysis of variance followed by 2-way analysis of variance (P

Results. Significantly higher mean torsional forces were observed with respect to Siloc (20.4 Newton decimeter [dNm]), Silicoater Classical (18.6 dNm), Silicoatcr MD (18.2 dNm), and Rocatec (17.0 dNm) systems compared with the mean for the untreated control group (14.6 dNm) (P.001). The Kevloc system in combination with the Artglass opaquer and Photac-Fil Aplitip (0.00 dNm) core material showed no resistance against torsional forces. Significant differences were observed between hybrid core materials and microfilled composite, compomer, or resin-modified glass ionomer core materials (P

Conclusion. Within the limitations of this study, the resistance to torsional forces for the core materials on titanium posts increased with the use of chemical surface-conditioning techniques and varied in accordance with the opaquer type. Type of core material also significantly influenced the resistance after thermocycling.