Finite element analysis of bioscrew fixation in ACL reconstruction / Ahmad Zainalabidin Zolkepli

Bio-screw is an interference screw used in Anterior Cruciate Ligament (ACL) reconstruction. ACL reconstruction is a process of replacing the broken ACL with a graft made from soft tissue from the other parts of human body. The screw is used to fix the graft in the tunnel. Bio-screw is a screw made f...

Full description

Saved in:
Bibliographic Details
Main Author: Zolkepli, Ahmad Zainalabidin
Format: Thesis
Language:English
Published: 2010
Subjects:
Online Access:https://ir.uitm.edu.my/id/eprint/31856/1/31856.pdf
Tags: Add Tag
No Tags, Be the first to tag this record!
id my-uitm-ir.31856
record_format uketd_dc
spelling my-uitm-ir.318562020-07-06T08:05:33Z Finite element analysis of bioscrew fixation in ACL reconstruction / Ahmad Zainalabidin Zolkepli 2010 Zolkepli, Ahmad Zainalabidin Electronics Bio-screw is an interference screw used in Anterior Cruciate Ligament (ACL) reconstruction. ACL reconstruction is a process of replacing the broken ACL with a graft made from soft tissue from the other parts of human body. The screw is used to fix the graft in the tunnel. Bio-screw is a screw made from bio-absorbable material that is Poly-L Lactide Acid (PLLA). It replace the use of metal interference screw for its bioabsorbable properties and the strength it posses. However, its capability to fix the graft to the femoral tunnel is questioned by the clinical. Thus, experimental study had been done to answer it. In this project, the mechanical behavior of samples of screws with different diameters and lengths in the bone tunnel with respect to the ACL reconstruction is studied. In spite using experimental study, finite element modeling is used to study the behavior. The distal femur and the bio-screw is remodeled using computer aided design (CAD) software and the stress distribution between the screw and the bone tunnel is obtained using the finite element software. In this project, a tensile force of 200 N is used as the loading conditions because it is the approximation of the graft tension at full extension of the knee during gait. It is found that the maximum Von Mises stress occurs on the tunnel is 29 MPa which is far away from the bone's yield strength that is 182 MPa. The maximum Von Mises stress occurs on the screw is 15.5 MPa which is also far from the screw's yield strength that is 26 MPa. The maximum deformation occurs on the screw caused by the 200 N tensile force is recorded to be 0.021 which is too small. It can be concluded that the bio-screw is capable to fix the graft in the tunnel. Further study using different contact condition is suggested to clarify the effects of bio-screw in the tunnel 2010 Thesis https://ir.uitm.edu.my/id/eprint/31856/ https://ir.uitm.edu.my/id/eprint/31856/1/31856.pdf text en public degree Universiti Teknologi MARA Shah Alam Faculty of Mechanical Engineering, Universiti Teknologi MARA Shah Alam Abdullah, Abdul Halim
institution Universiti Teknologi MARA
collection UiTM Institutional Repository
language English
advisor Abdullah, Abdul Halim
topic Electronics
spellingShingle Electronics
Zolkepli, Ahmad Zainalabidin
Finite element analysis of bioscrew fixation in ACL reconstruction / Ahmad Zainalabidin Zolkepli
description Bio-screw is an interference screw used in Anterior Cruciate Ligament (ACL) reconstruction. ACL reconstruction is a process of replacing the broken ACL with a graft made from soft tissue from the other parts of human body. The screw is used to fix the graft in the tunnel. Bio-screw is a screw made from bio-absorbable material that is Poly-L Lactide Acid (PLLA). It replace the use of metal interference screw for its bioabsorbable properties and the strength it posses. However, its capability to fix the graft to the femoral tunnel is questioned by the clinical. Thus, experimental study had been done to answer it. In this project, the mechanical behavior of samples of screws with different diameters and lengths in the bone tunnel with respect to the ACL reconstruction is studied. In spite using experimental study, finite element modeling is used to study the behavior. The distal femur and the bio-screw is remodeled using computer aided design (CAD) software and the stress distribution between the screw and the bone tunnel is obtained using the finite element software. In this project, a tensile force of 200 N is used as the loading conditions because it is the approximation of the graft tension at full extension of the knee during gait. It is found that the maximum Von Mises stress occurs on the tunnel is 29 MPa which is far away from the bone's yield strength that is 182 MPa. The maximum Von Mises stress occurs on the screw is 15.5 MPa which is also far from the screw's yield strength that is 26 MPa. The maximum deformation occurs on the screw caused by the 200 N tensile force is recorded to be 0.021 which is too small. It can be concluded that the bio-screw is capable to fix the graft in the tunnel. Further study using different contact condition is suggested to clarify the effects of bio-screw in the tunnel
format Thesis
qualification_level Bachelor degree
author Zolkepli, Ahmad Zainalabidin
author_facet Zolkepli, Ahmad Zainalabidin
author_sort Zolkepli, Ahmad Zainalabidin
title Finite element analysis of bioscrew fixation in ACL reconstruction / Ahmad Zainalabidin Zolkepli
title_short Finite element analysis of bioscrew fixation in ACL reconstruction / Ahmad Zainalabidin Zolkepli
title_full Finite element analysis of bioscrew fixation in ACL reconstruction / Ahmad Zainalabidin Zolkepli
title_fullStr Finite element analysis of bioscrew fixation in ACL reconstruction / Ahmad Zainalabidin Zolkepli
title_full_unstemmed Finite element analysis of bioscrew fixation in ACL reconstruction / Ahmad Zainalabidin Zolkepli
title_sort finite element analysis of bioscrew fixation in acl reconstruction / ahmad zainalabidin zolkepli
granting_institution Universiti Teknologi MARA Shah Alam
granting_department Faculty of Mechanical Engineering, Universiti Teknologi MARA Shah Alam
publishDate 2010
url https://ir.uitm.edu.my/id/eprint/31856/1/31856.pdf
_version_ 1783734143286247424