Abstract
Objectives: The aim of this research is to determine the effects of the variations in the implant angulation and the selection of abutment type on the mechanical potential of prosthetic components and to compare the deformations of abutment screws through micro-CT analysis. Materials and Methods: Forty titanium implants, each measuring 4.1 mm in diameter and 12 mm in length, were positioned in acrylic resin models in both straight and angled positions. The specimens were classified into four groups (n = 10): (1) straight-placed implant with titanium-base (Ti-base) abutment crown (Ti-1), (2) angulated-placed implant with Ti-base abutment crown (Ti-2), (3) straight-placed implant with multi-unit abutment crown (MU-1), and (4) angulated-placed implant with multi-unit abutment crown (MU-2). All groups underwent thermal aging (5,000 cycles, 5°C-50°C, 30-s dwell time) in distilled water for 24 h. A quasi-static load was applied to each specimen utilising a universal testing machine, and the highest force values at deformation were documented. The failure mode was ascertained by micro-CT and scanning electron microscopy (SEM) imaging. Results: The mean failure load values observed in the study were 2589 N for group Ti-1, 1768 N for group Ti-2, 3318 N for group MU-1, and 2213 N for group MU-2. Group MU-1 exhibited a higher failure load value than group Ti-1, Ti-2, and MU-2. Screw bending was observed in all groups. Groups Ti-2, MU-1, and MU-2 showed a significant difference in the change of angle values on the abutment screws, while group Ti-1 did not show any statistical difference (p=0.001; p < 0.05). Conclusion: The type of abutment and the angle of implant placement can affect the maximum load capacity of the implant-abutment complex. Both Ti-base and multi-unit abutments exhibited notable resistance forces.