The influence of swelling and matrix degradation on the microstructural integrity of tendon

Tendon is multi-level fibre composite material, responsible for the transmission of forces from muscles to the skeleton. It is composed of a hierarchical arrangement of collagenous units surrounded by a proteoglycan-rich matrix, arranged to support strain transfer, and thus contribute to the mechani...

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Published inActa biomaterialia Vol. 2; no. 5; pp. 505 - 513
Main Authors Screen, Hazel R.C., Chhaya, Vivek H., Greenwald, Steve E., Bader, Dan L., Lee, David A., Shelton, Julia C.
Format Journal Article
LanguageEnglish
Published England Elsevier Ltd 01.09.2006
Subjects
Animals
Biomechanical Phenomena
Fibre
Fibril
In Vitro Techniques
Male
Microscopy, Electron
Rats
Rats, Wistar
Strain
Stress, Mechanical
Swelling
Tendon
Tendons - physiology
Tendons - ultrastructure
Fibre
Swelling
Fibril
Tendon
Strain
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Summary:Tendon is multi-level fibre composite material, responsible for the transmission of forces from muscles to the skeleton. It is composed of a hierarchical arrangement of collagenous units surrounded by a proteoglycan-rich matrix, arranged to support strain transfer, and thus contribute to the mechanical behaviour of tendon. This study examines the effect of swelling and enzymatic degradation on structural integrity at different levels of the tendon hierarchy. Biochemical and microstructural analysis are used to examine the effects of incubation on the composition and swelling of the matrix, prior to a mechanical characterisation of sample integrity. Results indicated significant swelling of tendon fibrils and interfibrillar matrix after incubation in phosphate buffered saline, leading to a reduction in ultimate tensile load, with failure initiated between fibrils and sub-fibrils. In contrast, incubation with the enzyme chondroitinase ABC resulted in a total removal of glycosaminoglycan from the samples, and a subsequent reduction in the extent of swelling. These fascicles also demonstrated an increase in failure loads, with failure predominating between fibres. The findings from this work confirm the importance of the non-collagenous matrix components in controlling strain transfer within tendon structures. It also highlights the necessity to maintain samples within a suitable and controlled environment prior to testing.
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ISSN:1742-7061
1878-7568
DOI:10.1016/j.actbio.2006.05.008