Abstract
Polymeric electrospun nanofibers have extensive applications in filtration, sensing, drug delivery, and tissue engineering that often require the fibers to be patterned or integrated with a larger device. Here, we describe a highly versatile in situ strategy for three-dimensional electrospun fiber patterning using collectors with an insulative surface layer and conductive recessed patterns. We show that two-layer collectors with pattern dimensions down to 100-micrometers are easily fabricated using available laboratory equipment. We use finite element method simulation and experimental validation to demonstrate that the fiber patterning strategy is effective for a variety of pattern dimensions and fiber materials. Finally, the potential for this strategy to enable new applications of electrospun fibers is demonstrated by incorporating electrospun fibers into dissolving microneedles for the first time. These studies provide a framework for the adaptation of this fiber patterning strategy to many different applications of electrospun fibers.
Highlights
Polymeric electrospun nanofibers have extensive applications in filtration, sensing, drug delivery, and tissue engineering that often require the fibers to be patterned or integrated with a larger device
Electrospun fibers are a unique material with broad capabilities in filtration, sensing, drug delivery, and tissue engineering due to the versatility of materials that can be processed
Electrospun fibers are useful in many different biological applications including tissue engineering and drug delivery because of the wide range of biocompatible materials that can be electrospun and the variety of strategies for incorporating physicochemically diverse agents[9,10,11,12]
Summary
Polymeric electrospun nanofibers have extensive applications in filtration, sensing, drug delivery, and tissue engineering that often require the fibers to be patterned or integrated with a larger device. We describe a highly versatile in situ strategy for three-dimensional electrospun fiber patterning based on two-layer collectors with an insulative surface and conductive recessed patterns. These preliminary experiments demonstrated that patterned conductive collectors with an insulative surface layer could be used to generate patterned electrospun fibers on a range of length scales.
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