Abstract
Objective This study aimed to evaluate the influence of abutment geometry, specifically axial wall angulation and diameter, on the tensile strength of cemented prosthetic crowns using two types of abutments (Smart and Ideale) with identical heights but different diameters and angulation of the cementable abutment portion. Materials and methods Forty implant-abutment (IA) sets with a Morse taper connection were divided into four groups (n = 10): Sm1 (Smart, 3.5 mm), Id1 (Ideale, 3.3 mm), Sm2 (Smart, 4.5 mm), and Id2 (Ideale, 4.5 mm). Metal copings were cast using a nickel-chromium alloy and cemented with zinc phosphate cement under standardized conditions. Tensile testing was performed to determine the force required to remove each crown. Data were analyzed using parametric tests, with significance set at p < 0.05. Results All groups passed the Shapiro-Wilk normality test (p > 0.05). The Id2 group showed the highest mean tensile strength (235.1 ± 9.785 Ncm), followed by Sm2 (191.4 ± 8.870 Ncm), Id1 (150.8 ± 7.745 Ncm), and Sm1 (137.0 ± 7.666 Ncm). Statistically significant differences were observed between several group comparisons, indicating that both abutment angulation and diameter influence prosthesis retention. Conclusion Abutments with smaller axial angulation (Ideale model) and larger diameters demonstrated superior mechanical retention. These factors should be considered when selecting abutments for cemented implant-supported prostheses to ensure optimal retention and clinical performance.