• Title of article

    Bioresorption mechanisms of chitosan physical hydrogels: A scanning electron microscopy study

  • Author/Authors

    Malaise، نويسنده , , Sébastien and Rami، نويسنده , , Lila and Montembault، نويسنده , , Alexandra and Alcouffe، نويسنده , , Pierre and Burdin، نويسنده , , Béatrice and Bordenave، نويسنده , , Laurence and Delmond، نويسنده , , Samantha and David Wilson، نويسنده , , Laurent، نويسنده ,

  • Issue Information
    روزنامه با شماره پیاپی سال 2014
  • Pages
    11
  • From page
    374
  • To page
    384
  • Abstract
    Tissue-engineered biodegradable medical devices are widely studied and systems must present suitable balance between versatility and elaboration simplicity. In this work, we aim at illustrating that such equilibrium can be found by processing chitosan physical hydrogels without external cross-linker. Chitosan concentration, degree of acetylation, solvent composition, and neutralization route were modulated in order to obtain hydrogels exhibiting different physico-chemical properties. The resulting in vivo biological response was investigated by scanning electron microscopy. “Soft” hydrogels were obtained from chitosan of high degree of acetylation (35%) and by the neutralization with gaseous ammonia of a chitosan acetate aqueous solutions presenting low polymer concentration (Cp = 1.6% w/w). “Harder” hydrogels were obtained from chitosan with lower degree of acetylation (5%) and after neutralization in sodium hydroxide bath (1 M) of hydro-alcoholic chitosan solutions (50/50 w/w water/1,2-propanediol) with a polymer concentration of 2.5% w/w. Soft and hard hydrogels exhibited bioresorption times from below 10 days to higher than 60 days, respectively. We also evidenced that cell colonization and neo-vascularization mechanisms depend on the hydrogel-aggregated structure that is controlled by elaboration conditions and possibly in relation with mechanical properties. Specific processing conditions induced micron-range capillary formation, which can be assimilated to colonization channels, also acting on the resorption scenario.
  • Keywords
    capillary , biomaterial , Bioresorption , Cell colonization , Tuneable , Hydrogel
  • Journal title
    Materials Science and Engineering C
  • Serial Year
    2014
  • Journal title
    Materials Science and Engineering C
  • Record number

    2104737