Abstract
The long-term success of dental implants is greatly influenced by the use of appropriate materials while applying the “All-on-4” concept in the edentulous jaw. This study aims to evaluate the stress distribution in the “All-on-4” prosthesis across different material combinations using three-dimensional finite element analysis (FEA) and to evaluate which opposing arch material has destructive effects on which prosthetic material while offering certain recommendations to clinicians accordingly. Acrylic and ceramic-based hybrid prosthesis have been modelled on a rehabilitated maxilla using the “All-on-4” protocol. Using different materials and different supports in the opposing arch (natural tooth, and implant/ceramic, and acrylic), a multi-vectorial load has been applied. To measure stresses in bone, maximum and minimum principal stress values were calculated, while Von Mises stress values were obtained for prosthetic materials. Within a single group, the use of an acrylic implant-supported prosthesis as an antagonist to a full arch implant-supported prosthesis yielded lower maximum (Pmax) and minimum (Pmin) principal stresses in cortical bone. Between different groups, maxillary prosthesis with polyetheretherketone as framework material showed the lowest stress values among other maxillary prostheses. The use of rigid materials with higher moduli of elasticity may transfer higher stresses to the peri implant bone. Thus, the use of more flexible materials such as acrylic and polyetheretherketone could result in lower stresses, especially upon atrophic bones.
Highlights
Due to the current disadvantages of traditional complete dentures, advancing technology and science have been redirected to producing new solutions
Using three-dimensional finite element analysis, this study aims to examine the stress distribution in the maxillary “All-on-4” prosthesis across different material combinations to offer certain recommendations to clinicians
Researchover showing the effect of have different prosthetic material on stress distribution in implant-supported completethe arch prosthesis clinicians to use different material combinations
Summary
Due to the current disadvantages of traditional complete dentures, advancing technology and science have been redirected to producing new solutions. Utilizing the current advances in dental implants in conjunction with the All-on-4 treatment concept generally reduces the treatment time, the risk of morbidity, and other possible risks in the edentulous patient. This protocol, which emerged specially to overcome the complicated prosthetic and surgical problems caused by anatomical limitations, has increased its prevalence and has been used frequently [1]. The properties of the material and spatial geometric configuration model of each component have a significant impact on the transference of functional loads and stress distribution in a bone–implant–. Finding suitable dental materials that overcome biomechanical deficiencies and optimize function and aesthetics are desired by many clinicians [3]
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
