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Related Concept Videos

Fibril-associated Collagen01:11

Fibril-associated Collagen

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Fibril-associated collagens are a type of collagens present in the extracellular matrix with interrupted triple helices or FACIT (Fibril-associated collagens interrupted triple-helices). FACIT help connect and attach the collagen fibrils with each other as well as with other proteins of the extracellular matrix.
For example, the type II collagen fibrils in cartilage have covalently bound type IX fibril-associated collagens at regular intervals. Other types of fibril-associated collagens are...
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Preparation of 3D Collagen Gels and Microchannels for the Study of 3D Interactions In Vivo
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Crack Propagation Versus Fiber Alignment in Collagen Gels: Experiments and Multiscale Simulation.

Sarah M Vanderheiden, Mohammad F Hadi, V H Barocas

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    |September 11, 2015
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    Summary
    This summary is machine-generated.

    Computational models can predict how fiber organization affects collagenous tissue failure. Aligned collagen gels preferentially fail between notches, unlike isotropic gels, validating this multiscale modeling approach for engineered tissues.

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    Area of Science:

    • Biomaterials Science
    • Computational Mechanics
    • Tissue Engineering

    Background:

    • The mechanical properties and failure behavior of collagenous tissues are significantly influenced by their fiber organization.
    • Predicting tissue failure under complex in vivo loading conditions computationally remains a challenge.

    Purpose of the Study:

    • To apply a multiscale model of collagen gel mechanics to predict failure in double-notched gels.
    • To compare the failure behavior of aligned versus isotropic collagen gels computationally and experimentally.

    Main Methods:

    • A multiscale computational model of collagen gel mechanics was employed.
    • Double-notched gels (aligned and isotropic) were subjected to tensile testing.
    • Computational predictions were compared with laboratory experimental results.

    Main Results:

    • Aligned gels exhibited a greater tendency to fail by connecting the two notches compared to isotropic gels.
    • The transition point for failure mode shifted significantly with fiber alignment.
    • Model predictions for failure type strongly correlated with experimental outcomes (Fisher's exact test, p < 0.05).

    Conclusions:

    • The multiscale modeling approach accurately predicts failure modes in collagenous materials.
    • Fiber organization critically influences tissue failure, as demonstrated in this model system.
    • This strategy holds potential for predicting the failure of native and engineered tissues under various conditions.