Effect of sample geometry on the apparent biaxial mechanical behaviour of planar connective tissues

Stephen D. Waldman; J. Michael Lee

doi:10.1016/j.biomaterials.2005.05.056

Effect of sample geometry on the apparent biaxial mechanical behaviour of planar connective tissues

Stephen D. Waldman, J. Michael Lee

Medicine

Résultat de recherche: Article › examen par les pairs

51 Citations (Scopus)

Résumé

Mechanical testing methodologies developed for engineering materials may result in artifactual material properties if applied to soft planar connective tissues. The use of uniaxial tissue samples with high aspect ratios or biaxial samples with slender cruciform arms could lead to preferential loading of only the discrete subset of extracellular fibres that fully extend between the grips. To test this hypothesis, cruciform biaxial connective tissue samples that display distinctly different material properties (bovine pericardium, fish skin), as well as model textile laminates with predefined fibrous orientations, were repeatedly tested with decreasing sample arm lengths. With mechanical properties determined at the sample centre, results demonstrated that the materials appeared to become stiffer and less extensible with less slender sample geometries, suggesting that fibre recruitment increases with decreasing sample arm length. Alterations in the observed shear behaviour and rigid body rotation were also noted. The only truly reliable method to determine material properties is through in vivo testing, but this is not always convenient and is typically experimentally demanding. For the in vitro determination of the biaxial material properties, appropriate sample geometry should be employed in which all of the fibres contribute to the mechanical response.

Langue d'origine	English
Pages (de-à)	7504-7513
Nombre de pages	10
Journal	Biomaterials
Volume	26
Numéro de publication	35
DOI	https://doi.org/10.1016/j.biomaterials.2005.05.056
Statut de publication	Published - déc. 2005

Note bibliographique

Funding Information:
This work was supported by a grant from the Natural Sciences and Engineering Research Council (NSERC) and a student fellowship from the Heart and Stroke Foundation of Canada (HSFC). Model textile materials were created with the support of Mr. Gordon Hall and Dr. Derek Jones, Faculty of Dentistry, Dalhousie University. Surface marker isolation and tracking video analysis macros in NIH Image were developed by Mr. Rajesh Khanna. The public domain NIH Image program (US National Institutes of Health) is available from the Internet by anonymous FTP from ⟨ zippy.nimh.nih.gov ⟩.

ASJC Scopus Subject Areas

Bioengineering
Ceramics and Composites
Biophysics
Biomaterials
Mechanics of Materials

PubMed: MeSH publication types

Comparative Study
Evaluation Study
Journal Article
Research Support, Non-U.S. Gov't

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10.1016/j.biomaterials.2005.05.056

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abstract = "Mechanical testing methodologies developed for engineering materials may result in artifactual material properties if applied to soft planar connective tissues. The use of uniaxial tissue samples with high aspect ratios or biaxial samples with slender cruciform arms could lead to preferential loading of only the discrete subset of extracellular fibres that fully extend between the grips. To test this hypothesis, cruciform biaxial connective tissue samples that display distinctly different material properties (bovine pericardium, fish skin), as well as model textile laminates with predefined fibrous orientations, were repeatedly tested with decreasing sample arm lengths. With mechanical properties determined at the sample centre, results demonstrated that the materials appeared to become stiffer and less extensible with less slender sample geometries, suggesting that fibre recruitment increases with decreasing sample arm length. Alterations in the observed shear behaviour and rigid body rotation were also noted. The only truly reliable method to determine material properties is through in vivo testing, but this is not always convenient and is typically experimentally demanding. For the in vitro determination of the biaxial material properties, appropriate sample geometry should be employed in which all of the fibres contribute to the mechanical response.",

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N2 - Mechanical testing methodologies developed for engineering materials may result in artifactual material properties if applied to soft planar connective tissues. The use of uniaxial tissue samples with high aspect ratios or biaxial samples with slender cruciform arms could lead to preferential loading of only the discrete subset of extracellular fibres that fully extend between the grips. To test this hypothesis, cruciform biaxial connective tissue samples that display distinctly different material properties (bovine pericardium, fish skin), as well as model textile laminates with predefined fibrous orientations, were repeatedly tested with decreasing sample arm lengths. With mechanical properties determined at the sample centre, results demonstrated that the materials appeared to become stiffer and less extensible with less slender sample geometries, suggesting that fibre recruitment increases with decreasing sample arm length. Alterations in the observed shear behaviour and rigid body rotation were also noted. The only truly reliable method to determine material properties is through in vivo testing, but this is not always convenient and is typically experimentally demanding. For the in vitro determination of the biaxial material properties, appropriate sample geometry should be employed in which all of the fibres contribute to the mechanical response.

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Effect of sample geometry on the apparent biaxial mechanical behaviour of planar connective tissues

Résumé

Note bibliographique

ASJC Scopus Subject Areas

PubMed: MeSH publication types

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