• Title of article

    Morphology and degradation properties of PCL/HYAFF11® composite scaffolds with multi-scale degradation rate

  • Author/Authors

    V. Guarino، نويسنده , , M. Lewandowska، نويسنده , , M. Bil، نويسنده , , B. Polak، نويسنده , , L. Ambrosio، نويسنده ,

  • Issue Information
    روزنامه با شماره پیاپی سال 2010
  • Pages
    12
  • From page
    1826
  • To page
    1837
  • Abstract
    The analysis of scaffold degradation is a promising strategy for understanding the dynamic changes in texture and pore morphology which accompany polymer resorption, and for collecting same fundamental indicators regarding the potential fate of the scaffold in the biological environment. In this study, we investigate the morphology and degradation properties of three composite scaffolds based on poly(ε-caprolactone) (PCL) embedded with benzyl ester of hyaluronic acid (HYAFF11®) phases, and, in turn, different reinforcement systems – i.e., calcium phosphate particles or continuous poly(lactic acid) (PLA) fibres. Scanning electron microscopy (SEM) and μ-tomography supported by digital image analysis enabled a not invasive investigation of the scaffold morphology, providing a quantitative assessment of porosity (which ranged from 63.1 to 82.8), pore sizes (which varied from 170.5 to 230.4 μm) and pore interconnectivity. Thermal analyses (DSC and TGA) and Raman spectroscopy demonstrated the multi-scale degradation of the composite with highly tailoring degradation kinetics depending on the component material phases and scaffold architecture changes, due to their conditioning in simulated in vivo environment (i.e., SBF solution). These results demonstrate that the judicious mixing of materials with faster (i.e., HYAFF11) and slower (i.e., PLA and PCL) degradation kinetics, different size and shape (i.e., domains, particles or long fibres), certainly concurs to design a smart composite scaffold with time-controlled degradation which can support the regeneration of a large variety of tissues, from the cartilage to the bone.
  • Keywords
    A. Polymer–matrix composites (PMCs) , B. Porosity/voids , B. Thermal properties , E. Filament winding
  • Journal title
    COMPOSITES SCIENCE AND TECHNOLOGY
  • Serial Year
    2010
  • Journal title
    COMPOSITES SCIENCE AND TECHNOLOGY
  • Record number

    1043560