Pyridine as an additive to improve the deposition of continuous electrospun filaments

Electrospun filaments are leading to a new generation of medical yarns that have the ability to enhance tissue healing through their biophysical cues. We have recently developed a technology to fabricate continuous electrospun filaments by depositing the submicron fibres onto a thin wire. Here we in...

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Veröffentlicht in:	PloS one 2019-04, Vol.14 (4), p.e0214419
Hauptverfasser:	Lach, Antonina A, Morris, Hayley L, Martins, Joana A, Stace, Edward T, Carr, Andrew J, Mouthuy, Pierre-Alexis
Format:	Artikel
Sprache:	eng
Schlagworte:	Alkaloids Biomaterials Biomedical materials Biomedical research Biophysical Phenomena Cold drawing Collectors Crystalline polymers Deposition Electric Conductivity Electric properties Electrospinning Engineering Fibers Filament yarns Filaments Humans Hypotheses Materials Mechanical properties Morphology Nanofibers - chemistry Polydioxanone - chemistry Polyesters - chemistry Polymers Production management Pyridine Pyridines Pyridines - chemistry Rheumatology Solutions - chemistry Surgery Sutures Technology Tensile Strength Tissue Scaffolds - chemistry Yarn Yarns
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creator	Lach, Antonina A Morris, Hayley L Martins, Joana A Stace, Edward T Carr, Andrew J Mouthuy, Pierre-Alexis
description	Electrospun filaments are leading to a new generation of medical yarns that have the ability to enhance tissue healing through their biophysical cues. We have recently developed a technology to fabricate continuous electrospun filaments by depositing the submicron fibres onto a thin wire. Here we investigate the influence of pyridine on the fibre deposition. We have added pyridine to polydioxanone solutions at concentrations ranging from 0 to 100 ppm, increasing the conductivity of the solutions almost linearly from 0.04 uS/cm to 7 uS/cm. Following electrospinning, this led to deposition length increasing from 1 cm to 14 cm. The samples containing pyridine easily underwent cold drawing. The strength of drawn filaments increased from 0.8 N to 1.5 N and this corresponded to a decrease in fibre diameter, with values dropping from 2.7 μm to 1 μm. Overall, these findings are useful to increase the reliability of the manufacturing process of continuous electrospun filaments and to vary their biophysical properties required for their application as medical yarns such as surgical sutures.
doi_str_mv	10.1371/journal.pone.0214419
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subjects	Alkaloids Biomaterials Biomedical materials Biomedical research Biophysical Phenomena Cold drawing Collectors Crystalline polymers Deposition Electric Conductivity Electric properties Electrospinning Engineering Fibers Filament yarns Filaments Humans Hypotheses Materials Mechanical properties Morphology Nanofibers - chemistry Polydioxanone - chemistry Polyesters - chemistry Polymers Production management Pyridine Pyridines Pyridines - chemistry Rheumatology Solutions - chemistry Surgery Sutures Technology Tensile Strength Tissue Scaffolds - chemistry Yarn Yarns
title	Pyridine as an additive to improve the deposition of continuous electrospun filaments
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