There is still no agreement on the nature of tissues' viscoelasticity and on its reliable modeling. We speculate that disagreements between previous observations stem from difficulties of separating between viscoelastic and preconditioning effects, since both are manifested by similar response features. Here, this and related issues were studied in the tendon as a prototype for other soft tissues. Sheep digital tendons were preconditioned under strain that was higher by 1% than the one used in subsequent testing. Each specimen was then subjected to stress relaxation, and quick release or creep. A stochastic microstructural viscoelastic theory was developed based on the collagen fibers' properties and on their gradual recruitment with stretch. Model parameters were estimated from stress relaxation data and predictions were compared with the creep data. Following its validation, the new recruitment viscoelasticity (RVE) model was compared, both theoretically and experimentally, with the quasilinear viscoelastic (QLV) theory. The applied preconditioning protocol produced subsequent pure viscoelastic response. The proposed RVE model provided excellent fit to both stress relaxation and creep data. Both analytical and numerical comparisons showed that the new RVE theory and the popular QLV one are equivalent under deformation schemes at which no fibers buckle. Otherwise, the equivalence breaks down; QLV may predict negative stress, in contrast to data of the quick release tests, while RVE predicts no such negative stress. The results are consistent with the following conclusions: (1) fully preconditioned tendon exhibits pure viscoelastic response, (2) nonlinearity of the tendon viscoelasticity is induced by gradual recruitment of its fibers, (3) a new structure-based RVE theory is a reliable representation of the tendon viscoelastic properties under both stress relaxation and creep tests, and (4) the QLV theory is equivalent to the RVE one (and valid) only under deformations in which no fibers buckle. The results also suggest that the collagen fibers themselves are linear viscoelastic.
Skip Nav Destination
Article navigation
November 2009
Research-Article
Recruitment Viscoelasticity of the Tendon
Yoram Lanir
Yoram Lanir
e-mail: yoram@bm.technion.ac.il
Faculty of Biomedical Engineering,
Technion-lsrael Institute of Technology,
Haifa 32000, Israel
Faculty of Biomedical Engineering,
Technion-lsrael Institute of Technology,
Haifa 32000, Israel
Search for other works by this author on:
Yoram Lanir
e-mail: yoram@bm.technion.ac.il
Faculty of Biomedical Engineering,
Technion-lsrael Institute of Technology,
Haifa 32000, Israel
Faculty of Biomedical Engineering,
Technion-lsrael Institute of Technology,
Haifa 32000, Israel
1Corresponding author.
Contributed by the Bioengineering Division of ASME for publication in the JOURNALOF BIOMECHANICAL ENGINEERING. Manuscript received January 15, 2009; final manuscript received April 15, 2009; published online October 21, 2009. Review conducted by Michael Sacks.
J Biomech Eng. Nov 2009, 131(11): 111008 (8 pages)
Published Online: October 21, 2009
Article history
Received:
January 15, 2009
Revised:
April 15, 2009
Citation
Raz, E., and Lanir, Y. (October 21, 2009). "Recruitment Viscoelasticity of the Tendon." ASME. J Biomech Eng. November 2009; 131(11): 111008. https://doi.org/10.1115/1.3212107
Download citation file:
Get Email Alerts
How Irregular Geometry and Flow Waveform Affect Pulsating Arterial Mass Transfer
J Biomech Eng (December 2024)
Phenomenological Muscle Constitutive Model With Actin–Titin Binding for Simulating Active Stretching
J Biomech Eng (January 2025)
Image-Based Estimation of Left Ventricular Myocardial Stiffness
J Biomech Eng (January 2025)
Related Articles
Tendon Fascicles Exhibit a Linear Correlation Between Poisson's Ratio and Force During Uniaxial Stress Relaxation
J Biomech Eng (March,2013)
Time-Dependent Mechanical Behavior of Sheep Digital Tendons, Including the Effects of Preconditioning
J Biomech Eng (February,2002)
Experimental Characterization and Finite Element Implementation of Soft Tissue Nonlinear Viscoelasticity
J Biomech Eng (November,2012)
Nonlinear Model for Viscoelastic Behavior of Achilles Tendon
J Biomech Eng (November,2010)
Related Chapters
Processing/Structure/Properties Relationships in Polymer Blends for the Development of Functional Polymer Foams
Advances in Multidisciplinary Engineering
Characterization of Tissue Viscoelasticity from Shear Wave Speed Dispersion
Biomedical Applications of Vibration and Acoustics in Imaging and Characterizations
Tendon End Anchor Testing
Commentary on Articles CC-2000, CC-3000 and CC-4000