• Title of article

    The use of single particle mechanical properties for predicting the compressibility of pharmaceutical materials

  • Author/Authors

    Govedarica، نويسنده , , Biljana and Ili?، نويسنده , , Ilija and ?ibanc، نويسنده , , Rok and Dreu، نويسنده , , Rok and Sr?i?، نويسنده , , Stane، نويسنده ,

  • Issue Information
    روزنامه با شماره پیاپی سال 2012
  • Pages
    9
  • From page
    43
  • To page
    51
  • Abstract
    The studyʹs primary goal was to examine the possible use of single particle mechanical properties to estimate the compressibility behaviour of a tabletʹs excipients during compaction. Nanoindentation was utilised to measure individual mechanical properties (Youngʹs modulus, nanoindentation hardness, energy of elastic and plastic deformation). On the bulk scale, studied excipientsʹ compressibility was determined by Heckel and Walker models. Single particle hardness was found to provide direct information regarding an excipientʹs plasticity since an excellent correlation was established with the Walker model on the bulk level. A moderate correlation was obtained with the Heckel model due to its lack of fit for brittle materials. The indentation energy on a single level effectively differentiates materials in which plastic deformation dominates from those materials in which brittle fractures prevail. Elastic properties of materials can be successfully predicted by measuring the energy of elastic deformation on a single scale since an excellent correlation was observed with the bulk parameters such as energy of elastic deformation and the tabletsʹ elastic relaxation index. nd that individual mechanical properties of a tabletʹs excipients greatly control the materialsʹ deformation behaviour during tablet production despite of numerous other processes occurring during compression in the tablet die such as friction, bonding and local mechanical stress.
  • Keywords
    Heckel model , Nanoindentation , Walker model , Single and bulk mechanical properties , Deformation mechanism
  • Journal title
    Powder Technology
  • Serial Year
    2012
  • Journal title
    Powder Technology
  • Record number

    1701819