Design and fabrication of tubular scaffolds via direct writing in a melt electrospinning mode

Research output: Contribution to journalResearch articleContributedpeer-review

Contributors

  • Toby D. Brown - , Queensland University of Technology (Author)
  • Anna Slotosch - , Queensland University of Technology, RWTH Aachen University (Author)
  • Laure Thibaudeau - , Queensland University of Technology (Author)
  • Anna Taubenberger - , Queensland University of Technology (Author)
  • Daniela Loessner - , Queensland University of Technology (Author)
  • Cedryck Vaquette - , Queensland University of Technology (Author)
  • Paul D. Dalton - , Queensland University of Technology (Author)
  • Dietmar W. Hutmacher - , Queensland University of Technology (Author)

Abstract

Flexible tubular structures fabricated from solution electrospun fibers are finding increasing use in tissue engineering applications. However it is difficult to control the deposition of fibers due to the chaotic nature of the solution electrospinning jet. By using non-conductive polymer melts instead of polymer solutions the path and collection of the fiber becomes predictable. In this work we demonstrate the melt electrospinning of polycaprolactone in a direct writing mode onto a rotating cylinder. This allows the design and fabrication of tubes using 20 μm diameter fibers with controllable micropatterns and mechanical properties. A key design parameter is the fiber winding angle, where it allows control over scaffold pore morphology (e.g. size, shape, number and porosity). Furthermore, the establishment of a finite element model as a predictive design tool is validated against mechanical testing results of melt electrospun tubes to show that a lesser winding angle provides improved mechanical response to uniaxial tension and compression. In addition, we show that melt electrospun tubes support the growth of three different cell types in vitro and are therefore promising scaffolds for tissue engineering applications.

Details

Original languageEnglish
Pages (from-to)1-16
Number of pages16
JournalBiointerphases
Volume7
Issue number1-4
Publication statusPublished - 2012
Peer-reviewedYes
Externally publishedYes

External IDs

PubMed 22589056