Experimental & FEM Analysis of Orthodontic Mini-Implant Design on Primary Stability

Experimental & FEM Analysis of Orthodontic Mini-Implant Design on Primary Stability

The main objective of this research is to establish a connection between orthodontic mini-implant design, pull-out force and primary stability by comparing two commercial mini-implants or temporary anchorage devices, Tomas<sup>®</sup>-pin and Perfect Anchor. Mini-implant geometric analys...

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Main Authors: Elmedin Mešić, Enis Muratović, Lejla Redžepagić-Vražalica, Nedim Pervan, Adis J. Muminović, Muamer Delić, Mirza Glušac
Format: Article
Language:English
Published: MDPI AG 2021-06-01
Series:Applied Sciences
Subjects:
mini-implants
primary stability
pull-out test
Abaqus
FEM analysis
Online Access:https://www.mdpi.com/2076-3417/11/12/5461
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spelling doaj-41a1b10217fe406aa6fd97bae8b8a6df2021-07-01T00:02:53ZengMDPI AGApplied Sciences2076-34172021-06-01115461546110.3390/app11125461Experimental & FEM Analysis of Orthodontic Mini-Implant Design on Primary StabilityElmedin Mešić0Enis Muratović1Lejla Redžepagić-Vražalica2Nedim Pervan3Adis J. Muminović4Muamer Delić5Mirza Glušac6Department of Mechanical Design, Faculty of Mechanical Engineering, University of Sarajevo, 71000 Sarajevo, Bosnia and HerzegovinaDepartment of Mechanical Design, Faculty of Mechanical Engineering, University of Sarajevo, 71000 Sarajevo, Bosnia and HerzegovinaDepartment of Orthodontics, Faculty of Dentistry with Clinics, University of Sarajevo, 71000 Sarajevo, Bosnia and HerzegovinaDepartment of Mechanical Design, Faculty of Mechanical Engineering, University of Sarajevo, 71000 Sarajevo, Bosnia and HerzegovinaDepartment of Mechanical Design, Faculty of Mechanical Engineering, University of Sarajevo, 71000 Sarajevo, Bosnia and HerzegovinaDepartment of Mechanical Design, Faculty of Mechanical Engineering, University of Sarajevo, 71000 Sarajevo, Bosnia and HerzegovinaPractice Limited to Orthodontics, 75000 Tuzla, Bosnia and HerzegovinaThe main objective of this research is to establish a connection between orthodontic mini-implant design, pull-out force and primary stability by comparing two commercial mini-implants or temporary anchorage devices, Tomas<sup>®</sup>-pin and Perfect Anchor. Mini-implant geometric analysis and quantification of bone characteristics are performed, whereupon experimental in vitro pull-out test is conducted. With the use of the CATIA (Computer Aided Three-dimensional Interactive Application) CAD (Computer Aided Design)/CAM (Computer Aided Manufacturing)/CAE (Computer Aided Engineering) system, 3D (Three-dimensional) geometric models of mini-implants and bone segments are created. Afterwards, those same models are imported into Abaqus software, where finite element models are generated with a special focus on material properties, boundary conditions and interactions. FEM (Finite Element Method) analysis is used to simulate the pull-out test. Then, the results of the structural analysis are compared with the experimental results. The FEM analysis results contain information about maximum stresses on implant–bone system caused due to the pull-out force. It is determined that the core diameter of a screw thread and conicity are the main factors of the mini-implant design that have a direct impact on primary stability. Additionally, stresses generated on the Tomas<sup>®</sup>-pin model are lower than stresses on Perfect Anchor, even though Tomas<sup>®</sup>-pin endures greater pull-out forces, the implant system with implemented Tomas<sup>®</sup>-pin still represents a more stressed system due to the uniform distribution of stresses with bigger values.https://www.mdpi.com/2076-3417/11/12/5461mini-implantsprimary stabilitypull-out testAbaqusFEM analysis
collection DOAJ
language English
format Article
sources DOAJ
author Elmedin Mešić
Enis Muratović
Lejla Redžepagić-Vražalica
Nedim Pervan
Adis J. Muminović
Muamer Delić
Mirza Glušac
spellingShingle Elmedin Mešić
Enis Muratović
Lejla Redžepagić-Vražalica
Nedim Pervan
Adis J. Muminović
Muamer Delić
Mirza Glušac
Experimental & FEM Analysis of Orthodontic Mini-Implant Design on Primary Stability
Applied Sciences
mini-implants
primary stability
pull-out test
Abaqus
FEM analysis
author_facet Elmedin Mešić
Enis Muratović
Lejla Redžepagić-Vražalica
Nedim Pervan
Adis J. Muminović
Muamer Delić
Mirza Glušac
author_sort Elmedin Mešić
title Experimental & FEM Analysis of Orthodontic Mini-Implant Design on Primary Stability
title_short Experimental & FEM Analysis of Orthodontic Mini-Implant Design on Primary Stability
title_full Experimental & FEM Analysis of Orthodontic Mini-Implant Design on Primary Stability
title_fullStr Experimental & FEM Analysis of Orthodontic Mini-Implant Design on Primary Stability
title_full_unstemmed Experimental & FEM Analysis of Orthodontic Mini-Implant Design on Primary Stability
title_sort experimental & fem analysis of orthodontic mini-implant design on primary stability
publisher MDPI AG
series Applied Sciences
issn 2076-3417
publishDate 2021-06-01
description The main objective of this research is to establish a connection between orthodontic mini-implant design, pull-out force and primary stability by comparing two commercial mini-implants or temporary anchorage devices, Tomas<sup>®</sup>-pin and Perfect Anchor. Mini-implant geometric analysis and quantification of bone characteristics are performed, whereupon experimental in vitro pull-out test is conducted. With the use of the CATIA (Computer Aided Three-dimensional Interactive Application) CAD (Computer Aided Design)/CAM (Computer Aided Manufacturing)/CAE (Computer Aided Engineering) system, 3D (Three-dimensional) geometric models of mini-implants and bone segments are created. Afterwards, those same models are imported into Abaqus software, where finite element models are generated with a special focus on material properties, boundary conditions and interactions. FEM (Finite Element Method) analysis is used to simulate the pull-out test. Then, the results of the structural analysis are compared with the experimental results. The FEM analysis results contain information about maximum stresses on implant–bone system caused due to the pull-out force. It is determined that the core diameter of a screw thread and conicity are the main factors of the mini-implant design that have a direct impact on primary stability. Additionally, stresses generated on the Tomas<sup>®</sup>-pin model are lower than stresses on Perfect Anchor, even though Tomas<sup>®</sup>-pin endures greater pull-out forces, the implant system with implemented Tomas<sup>®</sup>-pin still represents a more stressed system due to the uniform distribution of stresses with bigger values.
topic mini-implants
primary stability
pull-out test
Abaqus
FEM analysis
url https://www.mdpi.com/2076-3417/11/12/5461
work_keys_str_mv AT elmedinmesic experimentalfemanalysisoforthodonticminiimplantdesignonprimarystability
AT enismuratovic experimentalfemanalysisoforthodonticminiimplantdesignonprimarystability
AT lejlaredzepagicvrazalica experimentalfemanalysisoforthodonticminiimplantdesignonprimarystability
AT nedimpervan experimentalfemanalysisoforthodonticminiimplantdesignonprimarystability
AT adisjmuminovic experimentalfemanalysisoforthodonticminiimplantdesignonprimarystability
AT muamerdelic experimentalfemanalysisoforthodonticminiimplantdesignonprimarystability
AT mirzaglusac experimentalfemanalysisoforthodonticminiimplantdesignonprimarystability
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