Fragrance encapsulation in polymeric matrices by emulsion electrospinning

[Display omitted] •One-step method for a volatile fragrance (limonene) encapsulation.•Encapsulation efficiencies of the limonene higher than 50%.•Release of the limonene over 15days in ambient conditions. We present the successful application of emulsion electrospinning for the encapsulation of a mo...

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Vydáno v:	European polymer journal Ročník 49; číslo 12; s. 3806 - 3813
Hlavní autoři:	Camerlo, Agathe, Vebert-Nardin, Corinne, Rossi, René M., Popa, Ana.-M.
Médium:	Journal Article
Jazyk:	angličtina
Vydáno:	Kidlington Elsevier Ltd 01.12.2013 Elsevier
Témata:	alcohols Applied sciences Chemical Sciences colloidal properties cosmetics Electrospinning Emulsion emulsions Encapsulation Exact sciences and technology food packaging Fragrance Limonene Machinery and processing nanofibers odors Physics Plastics Poly(vinyl alcohol) Polymer industry, paints, wood polyvinyl alcohol Spinning Technology of polymers Encapsulation Electrospinning Limonene Poly(vinyl alcohol) Emulsion Fragrance 1,8-p-Menthadiene Oil water emulsion Control release polymer Nanofiber Volatile organic compound Experimental study Nanoencapsulation Optimization Operating conditions Polyvinylalcohol Morphology Kinetics Release
ISSN:	0014-3057, 1873-1945
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Abstract	[Display omitted] •One-step method for a volatile fragrance (limonene) encapsulation.•Encapsulation efficiencies of the limonene higher than 50%.•Release of the limonene over 15days in ambient conditions. We present the successful application of emulsion electrospinning for the encapsulation of a model for highly volatile fragrances, namely (R)-(+)-limonene in a poly(vinyl alcohol) (PVA) fibrous matrix. The influence of the emulsion formulation and of its colloidal properties on the fiber morphology, as well as on the limonene encapsulation efficiency, is described. The release profile of the fragrance from the electrospun nanofibers over a fifteen days range shows that this type of nanofibrous matrices with a high fragrance loading capacity is of great potential for applications in various fields, such as cosmetics or food packaging.
AbstractList	We present the successful application of emulsion electrospinning for the encapsulation of a model for highly volatile fragrances, namely (R)-(+)-limonene in a poly(vinyl alcohol) (PVA) fibrous matrix. The influence of the emulsion formulation and of its colloidal properties on the fiber morphology, as well as on the limonene encapsulation efficiency, is described. The release profile of the fragrance from the electrospun nanofibers over a fifteen days range shows that this type of nanofibrous matrices with a high fragrance loading capacity is of great potential for applications in various fields, such as cosmetics or food packaging. [Display omitted] •One-step method for a volatile fragrance (limonene) encapsulation.•Encapsulation efficiencies of the limonene higher than 50%.•Release of the limonene over 15days in ambient conditions. We present the successful application of emulsion electrospinning for the encapsulation of a model for highly volatile fragrances, namely (R)-(+)-limonene in a poly(vinyl alcohol) (PVA) fibrous matrix. The influence of the emulsion formulation and of its colloidal properties on the fiber morphology, as well as on the limonene encapsulation efficiency, is described. The release profile of the fragrance from the electrospun nanofibers over a fifteen days range shows that this type of nanofibrous matrices with a high fragrance loading capacity is of great potential for applications in various fields, such as cosmetics or food packaging. We present the successful application of emulsion electrospinning for the encapsulation of a model for highly volatile fragrances, namely (R)-(+)-limonene in a poly(vinyl alcohol) (PVA) fibrous matrix. The influence of the emulsion formulation and of its colloidal properties on the fiber morphology, as well as on the limonene encapsulation efficiency, is described. The release profile of the fragrance from the electrospun nanofibers over a fifteen days range shows that this type of nanofibrous matrices with a high fragrance loading capacity is of great potential for applications in various fields, such as cosmetics or food packaging. © 2013 Elsevier Ltd. All rights reserved.
Author	Popa, Ana.-M. Camerlo, Agathe Vebert-Nardin, Corinne Rossi, René M.
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Keywords	Encapsulation Electrospinning Limonene Poly(vinyl alcohol) Emulsion Fragrance 1,8-p-Menthadiene Oil water emulsion Control release polymer Nanofiber Volatile organic compound Experimental study Nanoencapsulation Optimization Operating conditions Polyvinylalcohol Morphology Kinetics Release
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Snippet	[Display omitted] •One-step method for a volatile fragrance (limonene) encapsulation.•Encapsulation efficiencies of the limonene higher than 50%.•Release of... We present the successful application of emulsion electrospinning for the encapsulation of a model for highly volatile fragrances, namely (R)-(+)-limonene in a...
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SubjectTerms	alcohols Applied sciences Chemical Sciences colloidal properties cosmetics Electrospinning Emulsion emulsions Encapsulation Exact sciences and technology food packaging Fragrance Limonene Machinery and processing nanofibers odors Physics Plastics Poly(vinyl alcohol) Polymer industry, paints, wood polyvinyl alcohol Spinning Technology of polymers
Title	Fragrance encapsulation in polymeric matrices by emulsion electrospinning
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