Coelectrospinning of chitosan/alginate fibers by dual-jet system for modulating material surfaces

•The ratios of coelectrospun chitosan/alginate fibers are controlled by flow rates.•Surface properties can be modulated by the composition ratios of composite fibers.•Composite chitosan/alginate fibers demonstrate superior biocompatibilities.•Fiber compositions are dynamically regulated by the cross...

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Bibliographic Details
Published inCarbohydrate polymers Vol. 95; no. 2; pp. 716 - 727
Main Authors Hu, Wei-Wen, Yu, Hsing-Ning
Format Journal Article
LanguageEnglish
Published Kidlington Elsevier Ltd 20.06.2013
Elsevier
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Summary:•The ratios of coelectrospun chitosan/alginate fibers are controlled by flow rates.•Surface properties can be modulated by the composition ratios of composite fibers.•Composite chitosan/alginate fibers demonstrate superior biocompatibilities.•Fiber compositions are dynamically regulated by the crosslinking levels of alginate. Chitosan and alginate are two frequently used biomaterials for tissue engineering. In this study, electrospinning technique was applied for their nanofiber fabrications to mimic extracellular environment (ECM). Polyethylene oxide (PEO) was applied to increase viscosities of polymer solutions to obtain nanofibers with appropriate morphologies. To modulate surface properties, a dual jet system was developed to coelectrospin chitosan and alginate nanofibers on one substrate. Because the deposition rates of electrospun fibers linearly correlated to the perfusion rates of polymer solutions, the composition ratios of nanofibers were thus manipulated, which determined both the chemical properties and hydrophobicity of fibrous mats. In vitro cell culture results suggested that the cell morphology highly depended on the fiber composition, and the composite nanofibers demonstrated higher biocompatibility than that on pure fibers. Finally, the degradation of alginate fibers was controlled by the crosslinking process. Reducing calcium ions resulted in partial fiber degradation, by which the composition ratios of nanofibers varied with time. This dynamically changed environment performed a promising property to improve viability of surface cells. Through this tunable system, surface properties of scaffolds can be finely adjusted to benefit tissue engineering applications.
Bibliography:http://dx.doi.org/10.1016/j.carbpol.2013.02.083
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ISSN:0144-8617
1879-1344
DOI:10.1016/j.carbpol.2013.02.083