Electrospun polymer nanofibers show promise as components of scaffolds for tissue engineering because of their ability to orient regenerating cells. Our research focuses on aligned electrospun fiber scaffolds for nerve regeneration. Critical to this are highly aligned fibers, which are frequently difficult to manufacture reproducibly. Here we show that three variables: the distance between the spinneret tip and collector, the addition of DMF to the solvent, and placement of an aluminum sheet on the spinneret together greatly improve the alignment of electrospun poly-L-lactide (PLLA) nanofibers. We identified the most important variable as tip-to-collector distance. Nanofiber alignment was maximal at 30cm compared to shorter distances. DMF:chloroform (1:9) improved nanofiber uniformity and was integral to maintaining a uniform stream over the 30cm tip-to-collector distance. Other ratios caused splattering of the solution or flattening or beading of the fibers and non-uniform fiber diameter. The aluminum sheet helped to stabilize the electric field and improve fiber alignment provided that it was placed at 1cm behind the tip, while other distances destabilized the stream and worsened alignment. This study demonstrates that control of these variables produces dramatic improvement in reproducibly obtaining high alignment and uniform morphology of electrospun PLLA nanofibers.
Keywords: Distance; Electric field; Electrospinning; Nanofibers; Poly-L-lactide; Volatility.
Published by Elsevier B.V.