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Multi-pelvis characterisation of articular cartilage geometry

Multi-pelvis characterisation of articular cartilage geometry
Multi-pelvis characterisation of articular cartilage geometry
The shape of the acetabular cartilage follows the contact stress distribution across the joint. Accurate characterisation of this geometry may be useful for the development of acetabular cup devices that are more biomechanically compliant. In the present study, the geometry of the acetabular cartilage was characterised by taking plaster moulds of the acetabulum from 24 dry bone human pelvises and digitising the mould shapes using a 3D laser scanner. The articular bone surface geometry was analysed, and the shape of the acetabulum was approximated by fitting a best-fit sphere. To test the hypothesis that the acetabulum is non-spherical, a best-fit ellipsoid was also fitted to the geometry. In each case, points around the acetabular notch edge that disclosed the articular surface geometry were identified and vectors were drawn between these and the best-fit sphere or ellipsoid centre. The significantly larger z -radii (into the pole) of the ellipsoids indicated that the acetabulum was non-spherical and could imply that the kinematics of the hip joint is more complex than purely rotational motion and the traditional ball-and-socket replacement may need to be updated to reflect this motion. The acetabular notch edges were observed to be curved, with males exhibiting deeper, wider and shorter notches than females, although the difference was not statistically significant (mean: p = 0.30) and supports the use of non-gender specific models in anatomical studies.
0954-4119
Gillard, Faye
f6982854-337d-497a-aa41-bf1f3b9ff541
Dickinson, Alexander
10151972-c1b5-4f7d-bc12-6482b5870cad
Schneider, Urs
f63b875b-a3df-446d-8bfe-1614922fce11
Taylor, Andrew
39974814-4868-4c73-a3fa-2adfa4be3e46
Browne, Martin
6578cc37-7bd6-43b9-ae5c-77ccb7726397
Gillard, Faye
f6982854-337d-497a-aa41-bf1f3b9ff541
Dickinson, Alexander
10151972-c1b5-4f7d-bc12-6482b5870cad
Schneider, Urs
f63b875b-a3df-446d-8bfe-1614922fce11
Taylor, Andrew
39974814-4868-4c73-a3fa-2adfa4be3e46
Browne, Martin
6578cc37-7bd6-43b9-ae5c-77ccb7726397

Gillard, Faye, Dickinson, Alexander, Schneider, Urs, Taylor, Andrew and Browne, Martin (2013) Multi-pelvis characterisation of articular cartilage geometry. Proceedings of the Institution of Mechanical Engineers, Part H: Journal of Engineering in Medicine, 227 (12). (doi:10.1177/0954411913500265).

Record type: Article

Abstract

The shape of the acetabular cartilage follows the contact stress distribution across the joint. Accurate characterisation of this geometry may be useful for the development of acetabular cup devices that are more biomechanically compliant. In the present study, the geometry of the acetabular cartilage was characterised by taking plaster moulds of the acetabulum from 24 dry bone human pelvises and digitising the mould shapes using a 3D laser scanner. The articular bone surface geometry was analysed, and the shape of the acetabulum was approximated by fitting a best-fit sphere. To test the hypothesis that the acetabulum is non-spherical, a best-fit ellipsoid was also fitted to the geometry. In each case, points around the acetabular notch edge that disclosed the articular surface geometry were identified and vectors were drawn between these and the best-fit sphere or ellipsoid centre. The significantly larger z -radii (into the pole) of the ellipsoids indicated that the acetabulum was non-spherical and could imply that the kinematics of the hip joint is more complex than purely rotational motion and the traditional ball-and-socket replacement may need to be updated to reflect this motion. The acetabular notch edges were observed to be curved, with males exhibiting deeper, wider and shorter notches than females, although the difference was not statistically significant (mean: p = 0.30) and supports the use of non-gender specific models in anatomical studies.

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Accepted/In Press date: 5 July 2013
Published date: 25 November 2013
Related URLs:
Organisations: Bioengineering Group

Identifiers

Local EPrints ID: 355033
URI: http://eprints.soton.ac.uk/id/eprint/355033
DOI: doi:10.1177/0954411913500265
ISSN: 0954-4119
PURE UUID: 4353925f-a6bb-4b22-a8b9-fad2541c1a35
ORCID for Alexander Dickinson: ORCID iD orcid.org/0000-0002-9647-1944
ORCID for Martin Browne: ORCID iD orcid.org/0000-0001-5184-050X

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Date deposited: 25 Jul 2013 14:22
Last modified: 15 Mar 2024 03:27

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Contributors

Author: Faye Gillard
Author: Alexander Dickinson ORCID iD
Author: Urs Schneider
Author: Andrew Taylor
Author: Martin Browne ORCID iD

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