Influence of different polymeric materials of implant and attachment on stress distribution in implant-supported overdentures: a three-dimensional finite element study

Influence of different polymeric materials of implant and attachment on stress distribution in implant-supported overdentures: a three-dimensional finite element study

Abstract Purpose Investigating high performance thermoplastic polymers as substitutes to titanium alloy, in fabrication of implants and attachments to support mandibular overdenture, aiming to overcome stress shielding effect of titanium alloy implants. Aim of study Assessment of stress distribution...

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Main Authors: Sherif Elsayed, Yousra Ahmed, Mohamed I. El-Anwar, Enas Elddamony, Reem Ashraf
Format: Article
Language:English
Published: BMC 2025-01-01
Series:BMC Oral Health
Online Access:https://doi.org/10.1186/s12903-025-05440-5
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author Sherif Elsayed
Yousra Ahmed
Mohamed I. El-Anwar
Enas Elddamony
Reem Ashraf
author_facet Sherif Elsayed
Yousra Ahmed
Mohamed I. El-Anwar
Enas Elddamony
Reem Ashraf
author_sort Sherif Elsayed
collection DOAJ
description Abstract Purpose Investigating high performance thermoplastic polymers as substitutes to titanium alloy, in fabrication of implants and attachments to support mandibular overdenture, aiming to overcome stress shielding effect of titanium alloy implants. Aim of study Assessment of stress distribution in polymeric prosthetic components and bone around polymeric implants, in case of implant-supported mandibular overdenture. Materials and methods 3D finite element model was established for mandibular overdenture, supported bilaterally by two implants at canine region, and retained by two ball attachments. Linear static stress analysis was carried out by ANSYS 2020 R1. Three identical models were created with different materials for modeling of prosthetic components (implant body, gingival former, ball attachment and matrix). The Monolithic principle was applied as the same material was used in modelling all the prosthetic components in each model (Titanium alloy grade V, poly-ether-ether-ketone (PEEK) and poly-ether-ketone-ketone (PEKK)). Simultaneous Force application of 60 N was carried out bilaterally at the first molar occlusal surface area using 3 runs (vertical, lateral and oblique). Results PEEK and PEKK prosthetic components exhibited the highest total deformation and critical Maximum von Mises stresses values in implant body and gingival former under lateral and oblique loads. The stress values approached the fatigue limit of both polymeric materials presenting low factor of safety (< 1.5). The Peri-implant cortical bone in case of PEEK and PEKK showed nearly double maximum principal stresses compared with the titanium model. Conversely, Maximum von Mises stresses in spongy bone were lower in polymeric models than those of titanium ones. Additionally maximum equivalent strain values in spongy peri-implant bone of polymeric models were also lower than those of titanium model. Conclusion Critical high stresses were induced in implant body and gingival former under oblique or lateral loadings, accordingly, fatigue failure of both PEEK and PEKK polymer prosthetic elements was estimated due to low factor of safety. Both PEEK and PEKK Polymer models offered no advantage over titanium one regarding stress shielding effect, due to low stress and strain values generated at spongy peri-implant bone in polymer models.
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issn 1472-6831
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publishDate 2025-01-01
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series BMC Oral Health
spelling doaj-art-c6b7e3abbf4b4d0bbd688241558f55dc2025-02-02T12:45:05ZengBMCBMC Oral Health1472-68312025-01-0125111910.1186/s12903-025-05440-5Influence of different polymeric materials of implant and attachment on stress distribution in implant-supported overdentures: a three-dimensional finite element studySherif Elsayed0Yousra Ahmed1Mohamed I. El-Anwar2Enas Elddamony3Reem Ashraf4Al-Ryada University for Science and TechnologyDepartment of Prosthetic Dentistry, Removable Prosthodontics Division, Faculty of Dentistry, King Salman International UniversityMechanical Engineering Department, National Research Centre (NRC)Department of Prosthetic Dentistry, Biomaterials Division, Faculty of Dentistry, King Salman International UniversityDepartment of Prosthetic Dentistry, Biomaterials Division, Faculty of Dentistry, King Salman International UniversityAbstract Purpose Investigating high performance thermoplastic polymers as substitutes to titanium alloy, in fabrication of implants and attachments to support mandibular overdenture, aiming to overcome stress shielding effect of titanium alloy implants. Aim of study Assessment of stress distribution in polymeric prosthetic components and bone around polymeric implants, in case of implant-supported mandibular overdenture. Materials and methods 3D finite element model was established for mandibular overdenture, supported bilaterally by two implants at canine region, and retained by two ball attachments. Linear static stress analysis was carried out by ANSYS 2020 R1. Three identical models were created with different materials for modeling of prosthetic components (implant body, gingival former, ball attachment and matrix). The Monolithic principle was applied as the same material was used in modelling all the prosthetic components in each model (Titanium alloy grade V, poly-ether-ether-ketone (PEEK) and poly-ether-ketone-ketone (PEKK)). Simultaneous Force application of 60 N was carried out bilaterally at the first molar occlusal surface area using 3 runs (vertical, lateral and oblique). Results PEEK and PEKK prosthetic components exhibited the highest total deformation and critical Maximum von Mises stresses values in implant body and gingival former under lateral and oblique loads. The stress values approached the fatigue limit of both polymeric materials presenting low factor of safety (< 1.5). The Peri-implant cortical bone in case of PEEK and PEKK showed nearly double maximum principal stresses compared with the titanium model. Conversely, Maximum von Mises stresses in spongy bone were lower in polymeric models than those of titanium ones. Additionally maximum equivalent strain values in spongy peri-implant bone of polymeric models were also lower than those of titanium model. Conclusion Critical high stresses were induced in implant body and gingival former under oblique or lateral loadings, accordingly, fatigue failure of both PEEK and PEKK polymer prosthetic elements was estimated due to low factor of safety. Both PEEK and PEKK Polymer models offered no advantage over titanium one regarding stress shielding effect, due to low stress and strain values generated at spongy peri-implant bone in polymer models.https://doi.org/10.1186/s12903-025-05440-5
spellingShingle Sherif Elsayed
Yousra Ahmed
Mohamed I. El-Anwar
Enas Elddamony
Reem Ashraf
Influence of different polymeric materials of implant and attachment on stress distribution in implant-supported overdentures: a three-dimensional finite element study
BMC Oral Health
title Influence of different polymeric materials of implant and attachment on stress distribution in implant-supported overdentures: a three-dimensional finite element study
title_full Influence of different polymeric materials of implant and attachment on stress distribution in implant-supported overdentures: a three-dimensional finite element study
title_fullStr Influence of different polymeric materials of implant and attachment on stress distribution in implant-supported overdentures: a three-dimensional finite element study
title_full_unstemmed Influence of different polymeric materials of implant and attachment on stress distribution in implant-supported overdentures: a three-dimensional finite element study
title_short Influence of different polymeric materials of implant and attachment on stress distribution in implant-supported overdentures: a three-dimensional finite element study
title_sort influence of different polymeric materials of implant and attachment on stress distribution in implant supported overdentures a three dimensional finite element study
url https://doi.org/10.1186/s12903-025-05440-5
work_keys_str_mv AT sherifelsayed influenceofdifferentpolymericmaterialsofimplantandattachmentonstressdistributioninimplantsupportedoverdenturesathreedimensionalfiniteelementstudy
AT yousraahmed influenceofdifferentpolymericmaterialsofimplantandattachmentonstressdistributioninimplantsupportedoverdenturesathreedimensionalfiniteelementstudy
AT mohamedielanwar influenceofdifferentpolymericmaterialsofimplantandattachmentonstressdistributioninimplantsupportedoverdenturesathreedimensionalfiniteelementstudy
AT enaselddamony influenceofdifferentpolymericmaterialsofimplantandattachmentonstressdistributioninimplantsupportedoverdenturesathreedimensionalfiniteelementstudy
AT reemashraf influenceofdifferentpolymericmaterialsofimplantandattachmentonstressdistributioninimplantsupportedoverdenturesathreedimensionalfiniteelementstudy

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