Hostname: page-component-586b7cd67f-t7fkt Total loading time: 0 Render date: 2024-11-30T23:32:04.075Z Has data issue: false hasContentIssue false

Effects of frozen storage temperature on the elasticity of tendons from a small murine model

Published online by Cambridge University Press:  26 April 2010

K. L. Goh*
Affiliation:
School of Engineering, Monash University, 46150, Selangor Darul Ehsan, Malaysia
Y. Chen
Affiliation:
School of Chemical & Biomedical Engineering, Nanyang Technological University, 637459, Singapore
S. M. Chou
Affiliation:
School of Mechanical & Aerospace Engineering, Nanyang Technological University, 639798, Singapore
A. Listrat
Affiliation:
Growth and Muscle Metabolism Laboratory, Institut National de la Recherche Agronomique, 63122 St Genes-Champanelle, France
D. Bechet
Affiliation:
Human Nutrition Research Center, Institut National de la Recherche Agronomique, 63122 St Genes-Champanelle, France
T. J. Wess
Affiliation:
School of Optometry & Vision Sciences, Cardiff University, Cardiff, CF24 4LU, UK
*
Get access

Abstract

The basic mechanism of reinforcement in tendons addresses the transfer of stress, generated by the deforming proteoglycan (PG)-rich matrix, to the collagen fibrils. Regulating this mechanism involves the interactions of PGs on the fibril with those in the surrounding matrix and between PGs on adjacent fibrils. This understanding is key to establishing new insights on the biomechanics of tendon in various research domains. However, the experimental designs in many studies often involved long sample preparation time. To minimise biological degradation the tendons are usually stored by freezing. Here, we have investigated the effects of commonly used frozen storage temperatures on the mechanical properties of tendons from the tail of a murine model (C57BL6 mouse). Fresh (unfrozen) and thawed samples, frozen at temperatures of −20°C and −80°C, respectively, were stretched to rupture. Freezing at −20°C revealed no effect on the maximum stress (σ), stiffness (E), the corresponding strain (ε) at σ and strain energy densities up to ε (u) and from ε until complete rupture (up). On the other hand, freezing at −80°C led to higher σ, E and u; ε and up were unaffected. The results implicate changes in the long-range order of radially packed collagen molecules in fibrils, resulting in fibril rupture at higher stresses, and changes to the composition of extrafibrillar matrix, resulting in an increase in the interaction energy between fibrils via collagen-bound PGs.

Type
Full Paper
Copyright
Copyright © The Animal Consortium 2010

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

Bevilacqua, A, Zaritzky, N, Calvelo, A 1979. Histological measurements of ice in frozen beef. Journal of Food Technology 14, 237251.CrossRefGoogle Scholar
Chevalier, D, Le Bail, A, Ghoul, M 2000. Freezing and ice crystals formed in a cylindrical food model: part I. Freezing at atmospheric pressure. Journal of Food Engineering 46, 277285.CrossRefGoogle Scholar
Derwin, KA, Soslowsky, LJ 1999. A quantitative investigation of structure-function relationships in a tendon fascicle model. Journal of Biomechanical Engineering 121, 598604.CrossRefGoogle Scholar
Giannini, S, Buda, R, Di Caprio, F, Agati, P, Bigi, A, De Pasquale, V, Ruggeri, A 2008. Effects of freezing on the biomechanical and structural properties of human posterior tibial tendons. International Orthopaedics 32, 145151.Google Scholar
Goh, KL, Meakin, JR, Aspden, RM, Hukins, DWL 2005. Influence of fibril taper on the function of collagen to reinforce the extra-cellular matrix. Proceedings of the Royal Society of London B272, 19791983.Google Scholar
Goh, KL, Meakin, JR, Aspden, RM, Hukins, DWL 2007. Stress transfer in collagen fibrils reinforcing connective tissues: effects of collagen fibril slenderness and relative stiffness. Journal of Theoretical Biology 245, 305311.CrossRefGoogle ScholarPubMed
Goh, KL, Holmes, DF, Lu, H-Y, Richardson, S, Kadler, KE, Purslow, PP, Wess, TJ 2008. Ageing changes in the tensile properties of tendons: influence of collagen fibril volume fraction. Journal of Biomechanical Engineering 130 021011, 18.CrossRefGoogle ScholarPubMed
Gondret, F, Hernandez, P, Remignon, H, Combes, S 2009. Skeletal muscle adaptations and biomechanical properties of tendons in response to jump exercise in rabbits. Journal of Animal Science 87, 544553.CrossRefGoogle ScholarPubMed
Hickey, DS, Hukins, DWL 1979. Effect of methods of preservation on the arrangement of collagen fibrils in connective tissue matrices: an X-ray diffraction study of annulus fibrosus. Connective Tissue Research 6, 223228.CrossRefGoogle ScholarPubMed
Hukins, DWL, Aspden, RM 1985. Composition and properties of connective tissues. Trends in Biochemical Sciences 10, 260264.Google Scholar
Laing, JH, Cameron, GJ, Wess, TJ 2003. Molecular organisation of collagen fibrillar structures – a review. Recent Research Developments in Molecular Biology 1, 5171.Google Scholar
Laissue, P, L’Hôte, D, Serres, C, Vaiman, D 2009. Mouse models for identifying genes modulating fertility parameters. Animal 3, 5571.CrossRefGoogle ScholarPubMed
Lin, TW, Cardenas, L, Soslowsky, LJ 2004. Biomechanics of tendon injury and repair. Journal of Biomechanics 37, 865877.CrossRefGoogle ScholarPubMed
Miyawaki, O, Abe, T, Yano, T 1992. Freezing and ice structure formed in protein gels. Bioscience, Biotechnology and Biochemistry 56, 953957.CrossRefGoogle ScholarPubMed
Moussa, M, Babilé, R, Fernandez, X, Remignon, H 2007. Biochemical and biomechanical properties of tendons in two commercial types of chickens. Animal 1, 983988.CrossRefGoogle ScholarPubMed
Muldrew, K, McGann, LE 1990. Mechanisms of intracellular ice formation. Biophysical Journal 57, 525532.CrossRefGoogle ScholarPubMed
Pardo, JM, Suess, F, Niranjan, K 2002. An investigation into the relationship between freezing rate and mean ice crystal size for coffee extracts. Trans IChemE – Food and Bioproducts Processing 80, 176182.CrossRefGoogle Scholar
Puxkandl, R, Zizak, I, Paris, O, Keckes, J, Tesch, W, Bernstorff, S, Purslow, P, Fratzl, P 2002. Viscoelastic properties of collagen: synchrotron radiation investigations and structural model. Philosophical Transactions of the Royal Society of London B357, 191197.CrossRefGoogle Scholar
Redaelli, A, Vesentini, S, Soncini, M, Vena, P, Mantero, S, Montevecchi, FM 2003. The possible role of decorin glycosaminoglycans in fibril to fibril force transfer in relative mature tendons – a computational study from molecular to microstructural level. Journal of Biomechanics 36, 15551569.Google Scholar
Screen, HRC, Chhaya, VH, Greenwald, SE, Bader, DL 2006. The influence of swelling and matrix degradation on the microstructural integrity of tendon. Acta Biomaterialia 2, 505513.CrossRefGoogle ScholarPubMed
Sikoryn, TA, Hukins, DWL 1988. Failure of the longitundinal ligaments of the spine. Journal of Materials Science Letters 7, 13451349.CrossRefGoogle Scholar
Sun, CQ 2009. Thermo-mechanical behavior of low-dimensional systems: the local bond average approach. Progress in Materials Science 54, 179307.CrossRefGoogle Scholar
Tiller, WA, Rutter, JW 1956. The effect of growth conditions upon the solidification of a binary allow. Canadian Journal of Physics 34, 96121.CrossRefGoogle Scholar
Supplementary material: PDF

Goh supplementary material

Goh supplementary material

Download Goh supplementary material(PDF)
PDF 151.8 KB