This study focuses on the modeling and static analysis of dental implants fabricated from different biomedical materials, aiming to evaluate their mechanical performance and suitability for clinical applications. Dental implants are critical components in restorative dentistry, designed to provide a stable foundation for prosthetic teeth. The choice of biomaterials significantly influences the implants' strength, durability, and biocompatibility. In this research, a comprehensive finite element analysis (FEA) approach is employed to simulate the static loading conditions that dental implants typically encounter in the oral environment. Various biomedical materials, including titanium, zirconia, and polyetheretherketone (PEEK), are analyzed to compare their mechanical properties and stress distributions under load. The findings reveal significant differences in performance among the materials, highlighting the advantages and limitations of each in terms of strength, deformation, and potential failure modes. This research contributes valuable insights into the selection of appropriate materials for dental implants, promoting enhanced patient outcomes and longevity of the prosthetic devices. The results not only facilitate better design choices for dental implants but also serve as a foundation for future studies aimed at improving biomaterials and implant technologies in dentistry.