• Title of article

    Graded delamination behavior of human stratum corneum

  • Author/Authors

    Kenneth S. Wu، نويسنده , , Morgan M. Stefik، نويسنده , , K.P. Ananthapadmanabhan، نويسنده , , Reinhold H. Dauskardt، نويسنده ,

  • Issue Information
    روزنامه با شماره پیاپی سال 2006
  • Pages
    10
  • From page
    5861
  • To page
    5870
  • Abstract
    An in vitro adhesion test method has been adapted to quantify the through-thickness intercellular delamination energy of isolated human stratum corneum (SC). Both untreated and delipidized tissues were tested. Measured delamination energies were found to increase from 3 J/m2 near the surface to 15 J/m2 for the inner layers of the tissue. For delipidized SC, the location of the initial debond was located closer to the center of the tissue. Delamination energy values were elevated compared to untreated specimens, increasing from 7 J/m2 near the surface to 18 J/m2 for the inner layers of the SC. Further tests were run to measure delamination energies of SC as a function of hydration (15–100% relative humidity (RH)) at 25 °C and as a function of temperature (10–90 °C) at several hydrations (15, 45, 100% RH). Delamination energies were observed to decrease with increasing hydration and increasing temperature with the most significant changes occurring for 100% RH conditioned SC. Additional SC was treated with pH-buffered solutions (pH 4.2, 6.7, 9.9) and selected surfactant solutions (1%, 10% wt/wt sodium dodecyl sulfate (SDS)) for comparison to untreated controls. While statistically significant differences were observed, the SC was found to be resistant to large changes in delamination energy with pH and 1% wt/wt SDS treatments with values in the range 4.2–5.1 J/m2 compared to control values of 4.4 J/m2. More substantially elevated values were observed for SC treated with a 10% wt/wt SDS solution (6.6 J/m2) and a chloroform–methanol extraction (11.2 J/m2).
  • Keywords
    mechanical properties , epithelial cell , Stratum corneum , Tissue treatment , Fracture toughness
  • Journal title
    Biomaterials
  • Serial Year
    2006
  • Journal title
    Biomaterials
  • Record number

    547252