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Home / Equine Research Bank / J Biomech / Axial speed of sound is related to tendon’s nonlinear ...
Journal of biomechanics2011; 45(2); 263-268; doi: 10.1016/j.jbiomech.2011.10.032

Axial speed of sound is related to tendon’s nonlinear elasticity.

Abstract: Axial speed of sound (SOS) measurements have been successfully applied to noninvasively evaluate tendon load, while preliminary studies showed that this technique also has a potential clinical interest in the follow up of tendon injuries. The ultrasound propagation theory predicts that the SOS is determined by the effective stiffness, mass density and Poisson's ratio of the propagating medium. Tendon stiffness characterizes the tissue's mechanical quality, but it is often measured in quasi-static condition and for entire tendon segments, so it might not be the same as the effective stiffness which determines the SOS. The objectives of the present study were to investigate the relationship between axial SOS and tendon's nonlinear elasticity, measured in standard laboratory conditions, and to evaluate if tendon's mass density and cross-sectional area (CSA) affect the SOS level. Axial SOS was measured during in vitro cycling of 9 equine superficial digital tendons. Each tendon's stiffness was characterized with a tangent modulus (the continuous derivative of the true stress/true strain curve) and an elastic modulus (the slope of this curve's linear region). Tendon's SOS was found to linearly vary with the square root of the tangent modulus during loading; tendon's SOS level was found correlated to the elastic modulus's square root and inversely correlated to the tendon's CSA, but it was not affected by tendon's mass density. These results confirm that tendon's tangent and elastic moduli, measured in laboratory conditions, are related to axial SOS and they represent one of its primary determinants.
Copyright © 2011 Elsevier Ltd. All rights reserved.
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Publication Date: 2011-11-10 PubMed ID: 22078274DOI: 10.1016/j.jbiomech.2011.10.032Google Scholar: Lookup
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  • Journal Article
  • Research Support
  • Non-U.S. Gov't

Summary

This research summary has been generated with artificial intelligence and may contain errors and omissions. Refer to the original study to confirm details provided. Submit correction.

The research article explores the relationship between the speed of sound (SOS) through a tendon and the tendon’s nonlinear elasticity. The study also probes how mass density and cross-sectional area of the tendon affect the SOS level.

Objective of the Study

  • The main objectives of the study were to understand the relationship between the axial speed of sound and tendon’s nonlinear elasticity, and evaluate the impact of tendon’s mass density and cross-sectional area on the SOS level.

Methodology

  • Axial SOS was measured during in vitro cycling of 9 equine superficial digital tendons.
  • Stiffness of each tendon was characterized using the tangent modulus (continuous derivative of the true stress/true strain curve) and the elastic modulus (slope of the linear region of this curve).

Findings

  • The researchers found that tendon’s axial SOS linearly varies with the square root of the tangent modulus during loading.
  • The SOS level of a tendon correlates with the square root of the elastic modulus and is inversely correlated to the tendon’s cross-sectional area.
  • The research also established that tendon’s mass density does not significantly affect the SOS.

Implications

  • This research confirms that the tendon’s tangent and elastic moduli, measured in standard laboratory conditions, are linked to the axial SOS. These moduli seemingly act as a primary determinant of SOS.
  • This understanding could potentially be used in clinical evaluations following tendon injuries and for non-invasive evaluation of tendon load.

Cite This Article

APA
Vergari C, Ravary-Plumioën B, Evrard D, Laugier P, Mitton D, Pourcelot P, Crevier-Denoix N. (2011). Axial speed of sound is related to tendon’s nonlinear elasticity. J Biomech, 45(2), 263-268. https://doi.org/10.1016/j.jbiomech.2011.10.032

Publication

Journal of biomechanics
ISSN: 1873-2380
NlmUniqueID: 0157375
Country: United States
Language: English
Volume: 45
Issue: 2
Pages: 263-268

Researcher Affiliations

Vergari, Claudio
  • Université Paris-Est, Ecole Nationale Vétérinaire d'Alfort, USC BPLC 957, Maisons-Alfort F-94704, France. c.vergari@gmail.com
Ravary-Plumioën, Bérangère
    Evrard, Delphine
      Laugier, Pascal
        Mitton, David
          Pourcelot, Philippe
            Crevier-Denoix, Nathalie

              MeSH Terms

              • Animals
              • Elasticity / physiology
              • Horses
              • Sound
              • Tendon Injuries / physiopathology
              • Tendons / physiology
              • Weight-Bearing / physiology

              Citations

              This article has been cited 7 times.
              1. Sun M, Li H, Hou Y, Huang N, Xia X, Zhu H, Xu Q, Lin Y, Xu L. Multifunctional tendon-mimetic hydrogels.. Sci Adv 2023 Feb 17;9(7):eade6973.
                doi: 10.1126/sciadv.ade6973pubmed: 36800416google scholar: lookup
              2. Wagner FC, Gerlach K, Geiger SM, Gittel C, Böttcher P, Mülling CKW. Biplanar High-Speed Fluoroscopy of Pony Superficial Digital Flexor Tendon (SDFT)-An In Vivo Pilot Study.. Vet Sci 2021 May 27;8(6).
                doi: 10.3390/vetsci8060092pubmed: 34072030google scholar: lookup
              3. Wearing SC, Kuhn L, Pohl T, Horstmann T, Brauner T. Transmission-Mode Ultrasound for Monitoring the Instantaneous Elastic Modulus of the Achilles Tendon During Unilateral Submaximal Vertical Hopping.. Front Physiol 2020;11:567641.
                doi: 10.3389/fphys.2020.567641pubmed: 33343380google scholar: lookup
              4. Harper SE, Roembke RA, Zunker JD, Thelen DG, Adamczyk PG. Wearable Tendon Kinetics.. Sensors (Basel) 2020 Aug 26;20(17).
                doi: 10.3390/s20174805pubmed: 32858833google scholar: lookup
              5. Keuler EM, Loegering IF, Martin JA, Roth JD, Thelen DG. Shear Wave Predictions of Achilles Tendon Loading during Human Walking.. Sci Rep 2019 Sep 17;9(1):13419.
                doi: 10.1038/s41598-019-49063-7pubmed: 31530823google scholar: lookup
              6. Wulf M, Shanker M, Schuetz M, Lutz M, Langton CM, Hooper SL, Smeathers JE, Brauner T, Wearing SC. Lower material stiffness in rupture-repaired Achilles tendon during walking: transmission-mode ultrasound for post-surgical tendon evaluation.. Knee Surg Sports Traumatol Arthrosc 2018 Jul;26(7):2030-2037.
                doi: 10.1007/s00167-017-4624-5pubmed: 28660438google scholar: lookup
              7. Ellison M, Kobayashi H, Delaney F, Danielson K, Vanderby R Jr, Muir P, Forrest LJ. Feasibility and repeatability for in vivo measurements of stiffness gradients in the canine gastrocnemius tendon using an acoustoelastic strain gauge.. Vet Radiol Ultrasound 2013 Sep-Oct;54(5):548-54.
                doi: 10.1111/vru.12052pubmed: 23663072google scholar: lookup
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