Slow stretching that mimics embryonic growth rate stimulates structural and mechanical development of tendon-like tissue in vitro.

Nicholas S Kalson, David F Holmes, Andreas Herchenhan, Yinhui Lu, Toby Starborg, Karl E Kadler

    Research output: Contribution to journalArticlepeer-review

    Abstract

    A distinctive feature of embryonic tendon development is the steady increase in collagen fibril diameter and associated improvement of tissue mechanical properties. A potential mechanical stimulus for these changes is slow stretching of the tendon during limb growth. Testing this hypothesis in vivo is complicated by the presence of other developmental processes including muscle development and innervation. Here we used a cell culture tendon-like construct to determine if slow stretch can explain the increases in fibril diameter and mechanical properties that are observed in vivo. Non-stretched constructs had an ultrastructural appearance and mechanical properties similar to those of early embryonic tendon. However, slowly stretching during 4 days in culture increased collagen fibril diameter, fibril packing volume, and mechanical stiffness, and thereby mimicked embryonic development. 3D EM showed cells with improved longitudinal alignment and elongated nuclei, which raises the hypothesis that nuclear deformation could be a novel mechanism during tendon development.
    Original languageEnglish
    Pages (from-to)2520-2528
    Number of pages8
    JournalDevelopmental dynamics : an official publication of the American Association of Anatomists
    Volume240
    Issue number11
    DOIs
    Publication statusPublished - Nov 2011

    Keywords

    • 3D-reconstruction
    • Bio-artificial tendon
    • Collagen
    • Development
    • Elasticity
    • Electron microscopy
    • Fibril
    • Mechanical properties
    • Tendon
    • Tension

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