Materials Sciences and Applications

Volume 6, Issue 2 (February 2015)

ISSN Print: 2153-117X   ISSN Online: 2153-1188

Google-based Impact Factor: 0.97  Citations  

Morphology and Thermal Properties of Core-Shell PVA/PLA Ultrafine Fibers Produced by Coaxial Electrospinning

HTML  XML Download Download as PDF (Size: 2107KB)  PP. 189-199  
DOI: 10.4236/msa.2015.62022    6,318 Downloads   8,638 Views  Citations

ABSTRACT

Coaxial electrospinning process was used to produce biodegradable membranes made of coreshell fibers of a poly(lactic acid) (PLA) shell and a poly(vinyl alcohol) (PVA) core. Scanning electron microscopy analyses of these structures showed that the PLA shell can present certain porosity depending on the process condition. FTIR-ATR and contact angle measurements also suggested imprisonment of the PVA core within the PLA shell. This type of structure was also confirmed by means of transmissions electron microscopy. The morphology of these fibers was dependent on the flow rate of both core and shell solutions, and homogeneous and smooth surface was only attained when the flow rate of the external PLA solution was 4 times the flow rate of the internal PVA solution. The increase in the PLA solution flow rate increases the diameter of the core-shell fiber which reaches up to 1.7 μm. Nevertheless, fibers with smaller average diameter could also be produced (200 nm). These core-shell fibers presented improved hydrophilicity as compared with monolithic PLA fibers.

Share and Cite:

Gonçalves, R. , da Silva, F. , Picciani, P. and Dias, M. (2015) Morphology and Thermal Properties of Core-Shell PVA/PLA Ultrafine Fibers Produced by Coaxial Electrospinning. Materials Sciences and Applications, 6, 189-199. doi: 10.4236/msa.2015.62022.

Cited by

[1] Novel polycaprolactone (PCL)‐type I collagen core‐shell electrospun nanofibers for wound healing applications
… Research Part B …, 2023
[2] Type I collagen–poly (vinyl alcohol) electrospun nanofibers: FTIR study of the collagen helical structure preservation
Polymer-Plastics …, 2022
[3] Obtention of Antimicrobial Fibers Type Core/Shell Pla/Pvoh-Lae By Coaxial Electrospinning
… Ecuadorian Journal of …, 2021
[4] Obtention of Antimicrobial Fibers Type Core/Shell Pla/Pvoh-Lae By Coaxial Electrospinning Obtención de Fibras Antimicrobianas Tipo Pared/Núcleo Pla …
… Ecuadorian Journal of …, 2021
[5] Effect of electrospinning parameters on production of polyvinyl alcohol/polylactic acid nanofiber using a mutual solvent
2021
[6] Coaxial electrospinning of PVA/Nigella seed oil nanofibers: Processing and morphological characterization
2021
[7] Polymeric membrane based on polyactic acid and babassu oil for wound healing
2021
[8] Poly-(lactic acid) and fibrin bioactive cellularized scaffold for use in bone regenerative medicine: Proof of concept
2021
[9] Coaxial and emulsion electrospinning of extracted hyaluronic acid and keratin based nanofibers for wound healing applications
2021
[10] Enhanced physical properties of Bi 4 Ti 3 O 12 modified Bi 0.5 (Na 0.4 K 0.1) TiO 3 lead-free piezoelectric ceramics using crystallographic orientation techniques
2020
[11] Eco-Friendly Polyvinyl Alcohol/Polylactic Acid Core/Shell Structured Fibers as Controlled-Release Fertilizers for Sustainable Agriculture
2020
[12] Gamma irradiated electro-conductive polylactic acid/polyaniline nanofibers
2020
[13] Design of active electrospun mats with single and core-shell structures to achieve different curcumin release kinetics
2020
[14] Core-sheath gelatin based electrospun nanofibers for dual delivery release of biomolecules and therapeutics
2020
[15] Enhanced physical properties of Bi4Ti3O12 modified Bi0. 5 (Na0. 4K0. 1) TiO3 lead-free piezoelectric ceramics using crystallographic orientation techniques
Journal of Electroceramics, 2020
[16] DEVELOPMENT OF CORE/SHELL STRUCTURED COMPOSITE NANOFIBERS VIA COAXIAL ELECTROSPINNING METHOD
2019
[17] CHẾ TẠO HỆ GỐM KHÔNG CHÌ ĐỊNH HƯỚNG 0, 8Bi0, 5Na0, 5TiO3–0, 2Bi0, 5K0, 5TiO3
2019
[18] Biomedical Applications of Electrospun Polymer Composite Nanofibres
2019
[19] Growth factor releasing core-shell polymeric scaffolds for tissue engineering applications
2019
[20] Polycaprolactone/poly (L-lactic acid) composite micro/nanofibrous membrane prepared through solution blow spinning for oil adsorption
2019
[21] Controlled Release of Metformin Hydrochloride from Core-Shell Nanofibers with Fish Sarcoplasmic Protein
2019
[22] CTGF Loaded Electrospun Dual Porous Core-Shell Membrane For Diabetic Wound Healing
2019
[23] NGHIÊN CỨU CHẾ TẠO HỆ GỐM KHÔNG CHÌ ĐỊNH HƯỚNG 0.8 Bi0. 5Na0. 5TiO3–0.2 Bi0. 5K0. 5TiO3
2019
[24] Core-shell structured hyaluronic acid and keratin nanofibers for wound dressing
2019
[25] DEVELOPMENT OF BIOCOMPATIBLE POLYMER BASED FIBROUS MATERIALS FOR MEDICAL AND BIOLOGICAL USE
Thesis, 2018
[26] Carvacrol loaded electrospun fibrous films from zein and poly (lactic acid) for active food packaging
Food Hydrocolloids, 2018
[27] Modified iron phosphate/polyvinyl alcohol composite film for controlled-release fertilisers
RSC Advances, 2018
[28] Effects of the glycerophosphate-polylactic copolymer formation on electrospun fibers
Applied Surface Science, 2018
[29] Simultaneous Enhancement of Strength and Toughness of PLA Induced by Miscibility Variation with PVA
Polymers, 2018
[30] Design of Porous, Core-Shell, and Hollow Nanofibers
Handbook of Nanofibers, 2018
[31] Fabrication of core-shell structured nanofibers of poly (lactic acid) and poly (vinyl alcohol) by coaxial electrospinning for tissue engineering
European Polymer Journal, 2017
[32] Energy Transfer and-conversion by Functionalized Nano-bio-fibers for Biomedical Applications
2017
[33] Morphology and hydroscopic properties of acrylic/thermoplastic polyurethane core–shell electrospun micro/nano fibrous mats with tunable porosity
RSC Advances, 2016
[34] Morphology and hydroscopic properties of acrylic/thermoplastic polyurethane core–shell electrospun micro/nano fibrous mats with tunable porosity
RSC Advances, 2016
[35] Microfibrillar Conduits of Poly (ethylene glycol) Modified-PLLA Made by Electrospinning for Use in Peripheral Nervous Tissue Regeneration
Journal of Bionanoscience, 2016
[36] Desenvolvimento de menbranas fibrosas para a libertação controlada e localizada de antibióticos
2016
[37] Desenvolvimento de membranas fibrosas para a libertação controlada e localizada de antibióticos
2016

Journals Menu
Follow SCIRP
Contact us
+1 323-425-8868
customer@scirp.org
WhatsApp +86 18163351462(WhatsApp)
Click here to send a message to me 1655362766
Paper Publishing WeChat

Copyright © 2024 by authors and Scientific Research Publishing Inc.

Creative Commons License

This work and the related PDF file are licensed under a Creative Commons Attribution 4.0 International License.