• Title of article

    Chemotherapeutic implants via subcritical CO2 modification

  • Author/Authors

    Heather M. Powell، نويسنده , , Olukemi Ayodeji، نويسنده , , Taryn L. Summerfield، نويسنده , , David M. Powell، نويسنده , , Douglas A. Kniss، نويسنده , , David L. Tomasko، نويسنده , , John J. Lannutti، نويسنده ,

  • Issue Information
    روزنامه با شماره پیاپی سال 2007
  • Pages
    8
  • From page
    5562
  • To page
    5569
  • Abstract
    Polymer-based biomaterials have a broad range of current applications in medicine. Many implants generate a favorable biomedical outcome solely by providing short-term mechanical stability that allows healing of the surrounding tissues. An example is polymeric reconstructive resorbable plates having initial strengths sufficient to stabilize bone segments while allowing the osteosynthesis needed to restore original function following tumor resection. Simultaneous, localized delivery of the widely employed chemotherapeutic paclitaxel following tumor removal presents a particularly desirable goal in this context. By using compressed/subcritical CO2 at moderate pressures (as opposed to the more familiar supercritical pressures) to embed paclitaxel in clinically utilized reconstructive plating, the form of the implant can be preserved while adding an inherently localized chemotherapeutic function. In vitro tests demonstrate the efficacy of the embedded paclitaxel against adherent MCF-7 breast cancer cells within the immediate area of the polylactic acid (PLA). CO2 can be utilized to add dual structural-chemotherapeutic function to polymeric surfaces without a change in form. The ability to ‘piggyback’ chemotherapeutic function into nearly any polymeric surface should find widespread utility.
  • Keywords
    chemotherapy , Controlled drug release , in vitro test , Polylactic acid , degradation
  • Journal title
    Biomaterials
  • Serial Year
    2007
  • Journal title
    Biomaterials
  • Record number

    547840