• Title of article

    Elastic energy storage in an unmineralized collagen type I molecular model with explicit solvation and water infiltration

  • Author/Authors

    Kwansa، نويسنده , , Albert L. and Freeman، نويسنده , , Joseph W.، نويسنده ,

  • Issue Information
    روزنامه با شماره پیاپی سال 2010
  • Pages
    7
  • From page
    691
  • To page
    697
  • Abstract
    Collagen type I is a structural protein that provides tensile strength to tendons and ligaments. Type I collagen molecules form collagen fibers, which are viscoelastic and can therefore store energy elastically via molecular elongation and dissipate viscous energy through molecular rearrangement and fibrillar slippage. The ability to store elastic energy is important for the resiliency of tendons and ligaments, which must be able to deform and revert to their initial lengths with changes in load. earlier paper by one of the present authors, molecular modeling was used to investigate the role of mineralization upon elastic energy storage in collagen type I. Their collagen model showed a similar trend to their experimental data but with an over-estimation of elastic energy storage. Their simulations were conducted in vacuum and employed a distance-dependent dielectric function. In this study, we performed a re-evaluation of Freeman and Silverʹs model data incorporating the effects of explicit solvation and water infiltration, in order to determine whether the model data could be improved with a more accurate representation of the solvent and osmotic effects. We observed an average decrease in the modelʹs elastic energy storage of 45.1%±6.9% in closer proximity to Freeman and Silverʹs experimental data. This suggests that although the distance-dependent dielectric implicit solvation approach was favored for its increased speed and decreased computational requirements, an explicit representation of water may be necessary to more accurately model solvent interactions in this particular system. In this paper, we discuss the collagen model described by Freeman and Silver, the present model building approach, the application of the present model to that of Freeman and Silver, and additional assumptions and limitations.
  • Keywords
    Molecular model , macromolecule , Hydration , Protein , Tendon
  • Journal title
    Journal of Theoretical Biology
  • Serial Year
    2010
  • Journal title
    Journal of Theoretical Biology
  • Record number

    1540012