2018-10-192018-10-192212827110.1016/j.procir.2017.04.031http://hdl.handle.net/11285/630649The use of vascular grafts is indicated in a wide range of medical treatments. While autologous tissue is the graft of choice in most surgical bypass procedures, the next best option is the use of synthetic vascular grafts. While significant advances have been reported in the use of electrospinning for vascular grafts both at in vitro and in vivo level, most of the work is limited to straight, tubular shapes with uniform diameters. In order to generate resorbable scaffolds with curving and bifurcated tubular shapes with non-uniform diameters, this study proposes combination of directed electrical field and dynamic positioning of electrospun fibers aimed at a custom, 3D printed mandrel. The proposed approach produced a woven membrane of electrospun fibers. In this study, the fibers used were polycaprolactone. They were spun onto a 3D printed (in ABS plastic) bifurcated tubular mandrel. Preliminary mechanical testing of these bifurcated grafts is reported, with maximum indentation force between 0.7 and 2.3 N. In tension tests, the scaffolds showed an average maximum strength of 0.60 MPa (no indexing condition in the B direction) and 1.37 MPa (indexing in the B direction). © 2016 The Authors. Published by Elsevier B.V.info:eu-repo/semantics/openAccesshttp://creativecommons.org/licenses/by-nc-nd/4.03D printersABS resinsElectrospinningIndexing (of information)Mechanical testingScaffolds (biology)Spinning (fibers)Tensile testingTissueTissue engineeringAutologous tissueBifurcated graftsElectrospun fibersMaximum strengthMedical treatmentSynthetic vascular graftTubular scaffoldVascular graftsGrafts7 INGENIERÍA Y TECNOLOGÍAConferencia65207212