Controlled Encapsulation of Hydrophobic Liquids in Hydrophilic Polymer Nanofibers by Co-electrospinning

There are many technical situations, such as various biological or medical applications, in which a hydrophobic fluid must be encapsulated inside a hydrophilic polymer shell in the form of tiny microscopic pieces. A novel approach is presented, based on the co‐electrospinning of the hydrophilic poly...

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Published inAdvanced functional materials Vol. 16; no. 16; pp. 2110 - 2116
Main Authors Díaz, J. E., Barrero, A., Márquez, M., Loscertales, I. G.
Format Journal Article
LanguageEnglish
Published Weinheim WILEY-VCH Verlag 20.10.2006
WILEY‐VCH Verlag
Subjects
core/shell
Drug delivery
Electospinning
Encapsulation
Nanofibers
Nanofibers, core/shell
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Summary:There are many technical situations, such as various biological or medical applications, in which a hydrophobic fluid must be encapsulated inside a hydrophilic polymer shell in the form of tiny microscopic pieces. A novel approach is presented, based on the co‐electrospinning of the hydrophilic polymer melt (outside) and the hydrophobic fluid (inside), which results in beaded micro‐ and nanofibers, such that the hydrophobic fluid is efficiently encapsulated inside the beads. For the selected fluid couple, the low liquid–liquid surface tension and the high viscosity of the melt prevent the varicose break‐up of inner fluid in the coaxial electrified jet until the very end of the co‐electrospinning process. The resulting fibers present beads filled with the hydrophobic fluid, separated by a rather uniform distance whose length depends partially on the melt flow rate. The bead diameter grows with the inner flow rate, going from a monosized to a bisized distribution. In the case under study, the maximum relative (inner‐to‐outer) flow rate is one. The diameter of the solid fibers between beads scales well with existing theories for simple electrospinning. Co‐electrospinning of a hydrophilic polymer and a hydrophobic fluid (oil) results in fabrication of beaded micro‐ and nanofibers (see figure) with the oil efficiently encapsulated inside the beads. The bead size is rather uniform, with either a monomodal or a bimodal distribution. The “load” of oil can be simply adjusted by controlling the fluid flow rates.
Bibliography:ArticleID:ADFM200600204
Spanish Ministry of Science and Technology - No. DPI2004-05246-C04; No. NAN2004-09312-C03
ark:/67375/WNG-JCRXVCB6-7
We thank Mr. A. Gómez, from E. S. Ingenieros de Sevilla, Spain, for measuring the surface tension of the different liquids, and Ms. E. Rojo from University of Basque Country, Spain, for kindly helping us with the rheological characterization of the melts. Finally, we acknowledge Prof. Juan Fernández de la Mora for helping us to improve the experimental setup. We acknowledge the support of the Spanish Ministry of Science and Technology under projects DPI2004-05246-C04 and NAN2004-09312-C03, and of Yflow SL.
istex:AE1CB1E15FF3406D4B2FC16BC9E6C9CE2FE2746A
Yflow SL.
We thank Mr. A. Gómez, from E. S. Ingenieros de Sevilla, Spain, for measuring the surface tension of the different liquids, and Ms. E. Rojo from University of Basque Country, Spain, for kindly helping us with the rheological characterization of the melts. Finally, we acknowledge Prof. Juan Fernández de la Mora for helping us to improve the experimental setup. We acknowledge the support of the Spanish Ministry of Science and Technology under projects DPI2004‐05246‐C04 and NAN2004‐09312‐C03, and of Yflow SL.
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ISSN:1616-301X
1616-3028
DOI:10.1002/adfm.200600204