Hidrogéis de PVP e blendas de PVP/polianidridos como potenciais curativos para feridas crônicas / PVP hydrogels and PVP/Polyanhydride blends as potential materials for chronic wounds dressings

Bonacin, Renata Fogaça

07 October 2011

Hidrogéis compreendem uma importante classe de materiais poliméricos adequados à aplicação como curativos de feridas e queimaduras. A estrutura tridimensional hidrofílica dos hidrogéis permite que estes mantenham a umidade ideal no leito das feridas, absorvam o exsudato e não causem danos ao novo tecido durante as trocas dos curativos. No caso dos hidrogéis, essas trocas podem ser menos frequentes. Além disso, curativos que auxiliem na remoção de tecidos necrosados e ainda sejam capazes de oferecer tratamentos extras que acelerem o processo de cicatrização são desejáveis. Este trabalho apresenta a produção de materiais à base de hidrogel capazes de auxiliar neste processo de diferentes maneiras. Primeiramente, são apresentados hidrogéis formados a partir de nanofibras de poli(N-vinil-2-pirrolidona) (PVP) produzidas por eletrofiação, seguido da reticulação através da utilização de radiação UV-C ou reação de Fenton. A utilização da eletrofiação como técnica auxiliar na formação dos hidrogéis permitiu o controle da porosidade através da formação de fibras de diferentes diâmetros. A evidência de tal propriedade foi constatada através da produção de materiais que apresentam diferentes perfis de liberação da proteína modelo albumina de soro bovino (BSA). O hidrogel de PVP nanoestruturado foi capaz de liberar e manter a atividade da colagenase, uma importante enzima aplicada no tratamento de feridas via desbridamento enzimático, durante as 48 horas em que foi avaliado. Além disso, hidrogéis bactericidas nanoestruturados foram produzidos a partir de nanocompósitos de PVP e nanopartículas de prata (AgNP) produzidos por eletrofiação. Esses hidrogéis apresentaram propriedades térmicas semelhantes aos hidrogéis sem AgNP, diminuindo, contudo, a sua capacidade de intumescimento. Esses hidrogéis mostraram-se ativos contra bactérias gram-positivas e gram-negativas a partir de 100 ppm de AgNPs. Adicionalmente, foi estudada a formação de um hidrogel modelo composto PVP/AgNP/Imidazol, almejando-se a produção de um material bactericida-fungicida a base de hidrogel. Este hidrogel apresentou atividade conta três espécies de Candida a partir de 500 ppm de imidazol no material. Embora exista a formação de um complexo estável entre AgNP e Imidazol, cálculos teóricos e a constatação da atividade fungicida corroboram com o fato de que derivados imidazólicos podem ser liberados a partir deste hidrogel híbrido. A produção de hidrogéis físicos compostos por blendas de PVP/Polianidridos sintetizados a partir de derivados de hidroxicinamatos e ácido salicílico, capazes de liberar moléculas de interesse biológico quando parcialmente degradados hidroliticamente, também é descrita neste trabalho. Os resultados indicam que interações hidrofóbicas entre a PVP e os polianidridos sintetizados podem ser responsáveis pela formação dos hidrogéis físicos e pela miscibilidade das blendas produzidas. Os hidrogéis físicos de PVP/Polianidridos foram obtidos na forma de filmes por evaporação do solvente. Micro- e nanofibras também foram obtidas por eletrofiação. Desta maneira, o presente trabalho contribui com o desenvolvimento de uma geração de curativos multifuncionais aplicados no tratamento de feridas crônicas e queimaduras. / Hydrogels comprise an important class of polymeric materials that finds application as wound and burn dressings. The hydrophilic three-dimensional structure of hydrogels helps to provide the ideal humidity at the wound bed, to remove exsudates and to prevent damages to the new tissue during dressing substitution. Furthermore, these wound dressings are able to remove necrotic tissues and, therefore, capable to offer extra treatments that would benefit the healing processes. This work describes the production of hydrogel based materials that are able to act in wound healing by different ways. First, it is presented hydrogels composed of poly(N-vinyl-2-pyrrolidone) (PVP) nanofibers produced by electrospinning, followed by its crosslinking using UV-C radiation or Fenton reaction. The use of electrospinning in the hydrogel formation allowed porosity control by obtaining fibers of different diameters. This was evidenced by achieving materials that present different release profiles of the model protein bovine serum albumin (BSA). The nanostructured PVP hydrogel was capable of releasing and maintaining collagenase activity during 48 hour of evaluation. This is an important enzyme that find application in wound healing based on enzymatic debridement. Moreover, nanostructured bactericidal hydrogels were produced from PVP and silver nanoparticles (AgNP) composite through electrospinning, resulting in hydrogels with thermal properties similar to those hydrogels without AgNP, decreasing its swelling ability. These hydrogels were active against gram-positives and gram-negatives bacteria starting from 100 ppm of AgNP. In addition, the production of a model hydrogel composed by PVP/AgNP/Imidazole was investigated, aiming at a bactericidal-fungicidal hydrogel based material. This hydrogel was active against three Candida having 500 ppm of imidazole into the structure. In spite of the formation of a stable complex between AgNP and imidazole, theoretic calculations and the observed fungicidal activity corroborate with the fact that imidazoles derivatives can be released from this hybrid hydrogel. Physical hydrogels composed of PVP/Polyanhydrides blends were synthesized from hydroxycinammates derivatives and salicylic acid. These materials which were capable of releasing molecules with biological potential upon hydrolysis, are also described in this work. The results indicate that hydrophobic interactions between PVP and the synthesized polyanhydrides could be responsible for the hydrogel formation and blend miscibility as well. PVP/Polyanhydride physical hydrogels were obtained from cast films. Micro- and nanofibers were also obtained by electrospinning. Thus, the present work contributes with the development of the new generation of smart dressings for wound and burn healing.

Curativos

Electrospinning

Eletrofiação

Hidrogéis

Hydrogels

Nanopartículas de prata

Nanotechnology

Nanotecnologia

Polianidridos

Polyanhydrides

PVP

PVP

Silver nanoparticles

Wound dressings

Valorização de biomassa lignocelulósica e de polímero reciclado: materiais preparados a partir da eletrofiação de PET, fibra de sisal e seus componentes majoritários / Valuation of lignocellulosic biomass and recycled polymer: materials prepared from the electrospinning of PET, sisal fiber and its major

Santos, Rachel Passos de Oliveira

02 June 2017

O objetivo do presente estudo foi agregar valor a fibras de sisal, a dois dos componentes principais de fibras lignocelulósicas (celulose e lignina) e a PET reciclado, via produção de materiais com elevado valor agregado. Neste contexto, foram investigadas condições que levassem a mats constituídos por nanofibras/fibras ultrafinas, alinhadas (coletor rotativo) e não alinhadas (coletor estático), a partir da eletrofiação de soluções contendo essas matérias-primas, combinadas ou não [PET/sisal, PET/celulose e/ou lignina, PET/CNC (combinado ou não com OM)], em TFA. Parâmetros de solução, como razão PET/componente da biomassa e tempo de dissolução, foram diversificados, assim como parâmetros de processo (taxa de vazão da solução e velocidade de rotação do coletor utilizado, por exemplo). Os resultados de DMA indicaram a influência positiva do alinhamento das fibras nos superiores valores de E\' [tanto para os mats de PET/sisal, quanto para os mats de PET/celulose e/ou lignina e PET/CNC (combinado ou não com OM)] e também foi possível observar que não houve uma influência significativa desse alinhamento na Tg do PET nestes materiais. Como exemplo, o valor de E\' (a 30 °C) para o mat de fibras alinhadas, com razão de sisal/PET = 0,40 (S/PET0,40 – A dir), caracterizado na direção preferencial de alinhamento das fibras, foi superior (765,0 MPa), em comparação ao valor apresentado pelo mat de fibras orientadas aleatoriamente, de composição correspondente, S/PET0,40 (E’ = 358,0 ± 1,5 MPa). A molhabilidade dos mats foi intrinsicamente dependente da razão fibra de sisal/PET e variou de altamente hidrofóbico (PETref, ACA de 134°), a super hidrofílico (S/PET0,40, ACA de 0°). Observou-se que, as principais influências da presença de lignina foram na morfologia achatada das fibras e no aumento do alongamento na ruptura dos materiais, de aproximadamente 90%, comparativamente a PETref. A presença da celulose resultou principalmente em um elevado diâmetro médio das fibras (valores de até 365,9 ± 139,7 nm) e módulo de Young dos materiais (com valores de até 360,4 ± 41,5 MPa), comparativamente ao apresentado pelos mats contendo PET e este polímero combinado com lignina. Os resultados mostraram que os CNCs exerceram uma ação efetiva como agentes de reforço, principalmente nos mats constituídos por fibras orientadas aleatoriamente de PET, considerando as propriedades mecânicas apresentadas por esses materiais (como resistência à ruptura de 4,6 ± 0,5 MPa), em comparação ao mat PETref (resistência à ruptura = 1,8 ± 0,2 MPa). O OM atuou como agente compatibilizante entre o PET reciclado e os CNCs, principalmente com relação ao superior valor de módulo de Young de PET/OM/CNC (354,2 ± 46,1 MPa), em comparação ao valor apresentado por PET/CNC (19,9 ± 3,9 MPa). Assim, os objetivos do presente trabalho foram atingidos com a preparação via eletrofiação, até onde se tem conhecimento, pela primeira vez, de mats de fibras alinhadas e não alinhadas baseadas em biomassa lignocelulósica nativa e dois de seus principais constituintes (celulose e lignina). Os materiais preparados apresentam uma vasta gama de possíveis aplicações, como sistemas de filtração de ar, por exemplo. / The aim of the present investigation was to add value to sisal fibers, to two of the major components of lignocellulosic fibers (cellulose and lignin) and recycled PET via preparation of materials with high added value. In this context, conditions that lead to mats of nanofibers and ultrathin fibers were investigated, aligned (rotating drum collector) and nonaligned (stationary collector), via electrospinning of solutions containing these raw materials, combined or not {PET/sisal fiber, PET/cellulose and/or lignin, PET/CNC [combined or not with castor oil (CO)]} in TFA. Solution parameters such as the ratio of PET/biomass component and dissolution times were diverse, as well as process parameters (e.g. solution flow rate and rotational speed of the collector). The DMA results indicated the positive influence of fiber alignment on the higher storage modulus – E’ [for mats of PET/sisal, PET/cellulose and/or lignin and PET/CNC (combined or not with CO)] and it was also possible to observe no significant influence of fiber alignment on the Tg of PET for these mats. The value of E’ (at 30 °C) for the aligned fibers mat with sisal/PET ratio = 0.40 (S/PET0.40 - A dir), characterized in the preferred direction of fiber alignment, was higher (765.0 MPa) when compared to the value presented by the randomly oriented fibers mat of the corresponding composition, S/PET0.40 (E’ = 358.0 ± 1.5 MPa). The wettability of the mats was intrinsically dependent on the sisal/PET fiber ratio and ranged from highly hydrophobic (PETref, ACA of 134°) to super hydrophilic (S/PET0.40, ACA of 0°). It was observed that the main influences of the presence of lignin was on the flat fibers morphology and on the increase of the elongation-at-break of the materials of approximately 90% compared to PETref. The presence of cellulose resulted mainly in a high average fiber diameter (values up to 365.9 ± 139.7 nm) and elastic modulus of the materials (values up to 360.4 ± 41.5 MPa) compared to the ones presented by mats containing PET and by this polymer combined with lignin. The results showed that the CNCs were efficient as reinforcing agents, especially in the mats composed of randomly oriented fibers of PET, considering the mechanical properties presented by these materials (such as ultimate tensile strength of 4.6 ± 0.5 MPa) compared to PETref mat (ultimate tensile strength = 1.8 ± 0.2 MPa). CO acted as a compatibilizing agent between recycled PET and CNCs, mainly regarding the superior elastic modulus value of PET/OM/CNC (354.2 ± 46.1 MPa) compared to PET/CNC mat (19.9 ± 3.9 MPa). Therefore, the goals of the present study were reached for the first time with the preparation of aligned and nonaligned fiber mats based on native lignocellulosic biomass and two of its main constituents (cellulose and lignin), to the best of our knowledge. The prepared materials have a wide range of possible applications, such as air filtration systems, for example.

Cellulose

Celulose

Electrospinning

Eletrofiação

Fibra de sisal

Fibras ultrafinas

Lignin

Lignina

Nanofibers

Nanofibras

PET reciclado

Recycled PET

Sisal fiber

Ultrathin fibers

Propriedades físico-químicas de polímeros eletrofiados com ligas semicondutoras de selênio-gálio / Physical-chemical properties of electrospinning polymers with semiconductor alloys of selenium-gallium

Gotardo, Anderson

01 November 2018

Submitted by Marilene Donadel (marilene.donadel@unioeste.br) on 2019-02-07T15:18:50Z No. of bitstreams: 1 Anderson_Gotardo_2018.pdf: 8740713 bytes, checksum: a5124905fb476303a65a06e329454980 (MD5) / Made available in DSpace on 2019-02-07T15:18:50Z (GMT). No. of bitstreams: 1 Anderson_Gotardo_2018.pdf: 8740713 bytes, checksum: a5124905fb476303a65a06e329454980 (MD5) Previous issue date: 2018-11-01 / Coordenação de Aperfeiçoamento de Pessoal de Nível Superior - CAPES / Surface phenomena such as adsorption, formation of colloids, heterogeneous catalysis, have varied applications spread in the industry. An important property to achieve efficiency in the processes of surface chemistry is the high ratio area/volume of the materials involved in each process. In search of this property, in conjunction with others, a large number of publications report the use of the electrospinning technique as having unique characteristics in the production of fibers, with diameters of the order of nanometers, and fibers aggregates, in the form of membranes or films, with high specific area. In this work an alloy consisted of selenium and gallium was added into an Ecovio® polymer solution before electrospinning. The effects of alloy concentration on the properties of the composite material (membranes) was investigated by means of thermal analysis, X-ray diffraction, IR spectroscopy (FTIR-ATR), SEM analysis, and PAS (UV-vis) spectroscopy. The formed composite shown dependency of alloy cristallinity and although it has not been directly measured the surface area seems to be increased. The thermogravimetric analysis evidenced an increase in the thermal stability of the composite material. Although the FTIR spectrosocopy was inconclusive as to the incorporation of the alloy into the polymer, the SEM morphological analysis shown that the particules of the alloy material were partialy or fully incorporated into the composite. XRD also evince the incorporation of the alloy into the polymer. Photoacoustic spectroscopy allowed the determination of gap energy in the composite, further evidence that the alloy was incorporated into the polymer. / Fenômenos de superfície como adsorção, formação de coloides, catálise heterogênea, têm variadas aplicações difundidas na indústria. Uma propriedade importante para se obter eficiência nos processos da química de superfície é a razão área/volume dos materiais envolvidos em cada processo. Buscando por essa propriedade, conjugada com outras, um elevado número de publicações reporta o uso da técnica da eletrofiação como tendo características únicas na produção de fibras, com diâmetros da ordem de nanometros, e agregados de fibras, na forma de membranas ou filmes, com elevada área específica. Neste trabalho, uma liga constituída de selênio e gálio foi adicionado a uma solução polimérica de Ecovio® antes da eletrofiação. Os efeitos da concentração de liga sobre as propriedades do material compósito (membranas) foram investigados por meio de análise térmica, difração de Raios X (DRX), espectroscopia de infravermelho, microscopia eletrônica de varredura (MEV) e espectroscopia fotoacústica (EFA) na região de Ultravioleta e visível. O compósito formado mostrou dependência com cristalinidade da liga e, embora não tenha sido medido diretamente, a área superficial parece estar aumentada. A análise termogravimétrica evidenciou aumento na estabilidade térmica do material compósito. Embora a espectroscopia de infravermelho tenha sido inconclusiva quanto à incorporação da liga no polímero, a análise morfológica da MEV mostrou que as partículas do material da liga foram parciais ou totalmente incorporadas ao compósito. A difração de Raios X também evidencia a incorporação da liga no polímero. A espectroscopia fotoacústica permitiu a determinação da energia do gap no compósito, mais uma evidência de que a liga foi incorporada ao polímero.

Eletrofiação

Ecovio

Propriedades físico-quimicas

Selênio-gálio

Electrospinning

Physico-chemical properties

Selenium-gallium

CIENCIAS EXATAS E DA TERRA::QUIMICA

Produção de nanofibras alinhadas de polímeros biodegradáveis para crescimento e regeneração de células neurais / Production of aligned biodegradable polymer nanofibers for neural cell growth and regeneration

Alcobia, Daniel de Souza

03 December 2013

A eletrofiação é uma celebrada técnica de processamento de polímeros, capaz de produzir fibras de diâmetro nanométrico. A montagem comum do sistema de eletrofiação permite a captação de fibras aleatórias sob a forma de um não-tecido. Diversas modificações nessa montagem permitem a obtenção de diferentes morfologias de fibras. Tais modificações são revisadas e discutidas neste trabalho. Na produção de suportes de crescimento de células neurais, é interessante que seja incorporada alguma anisotropia no meio. Assim, um aparato de eletrofiação, capaz de produzir fibras alinhadas, foi construído e a variação dos parâmetros de seu processamento permitiu a obtenção de diferentes qualidades de alinhamento das fibras para dois polímeros biodegradáveis. Diversos parâmetros influenciaram a qualidade desse alinhamento, porém a velocidade de captação das fibras mostrou ser o mais impactante, em acordo com dados reportados na literatura. A morfologia das fibras foi avaliada quanto ao seu diâmetro, com o auxílio de micrografias de MEV e do software de edição de imagens ImageJ. Adicionalmente buscou-se avaliar a qualidade do alinhamento de tais fibras. Para tanto, foi desenvolvida uma metodologia de quantificação de qualidade de alinhamento de fibras, baseado nas micrografias e na ferramenta de FFT do ImageJ. A metodologia proposta foi capaz de ordenar de maneira objetiva e consistente a qualidade do alinhamento das fibras obtidas, mesmo quando a análise visual (usada como referência) se provava ineficiente. A metodologia proposta foi incorporada num plugin para ImageJ, via algoritmo computacional escrito em Java. Com o uso do plugin, foi possível processar diversas micrografias, obtidas em diferentes pontos das malhas eletrofiadas e com variadas magnificações, a fim de se criar uma estatística dos resultados obtidos para qualidade de alinhamento das fibras, algo inédito na literatura. Malhas eletrofiadas com diferentes qualidades de alinhamento de suas fibras foram utilizadas como substrato na cultura de células precursoras neurais, provenientes de neuroesferas. Foi feita a cultura de células progenitoras neurais, provenientes de neuroesferas, tendo como substrato malhas eletrofiadas com diferentes qualidades de alinhamento, a fim de se avaliar o impacto dos contatos físicos das fibras sobre a migração e diferenciação de tais células. / Electrospinning is a celebrated technique of polymer processing, able to produce fibers with nanometric diameter. Common assembly of electrospinning apparatus allows collection of random fibers in a non-woven matt. Several modifications on this assembly enable different fiber morphologies to be obtained. Such modifications are revised and discussed in this work. In the production of cell growth scaffolds, its interesting that some anisotropy is incorporated in the medium. Therefore, an electrospinning apparatus capable of producing aligned fibers was constructed. Variation of processing parameters of said apparatus enabled different alignment qualities of fibers to be attained for two biodegradable polymers. Many parameters influenced on the quality of said alignment; fiber collection speed, however, proved more impacting, in accordance with literature data. Fiber morphology was assessed in regard to its diameter with the aid of MEV micrographs and ImageJ software. Furthermore, assessment of fiber alignment quality was sought. For this matter, it has been developed a quantification methodology for fiber alignment quality, based on micrographs and ImageJ\'s FFT tool. The proposed methodology was able to objectively and consistently rank fiber alignment quality, even when visual analysis (used as reference) failed to do so. This methodology was incorporated in a plugin for ImageJ, via Java script algorithm. With the aid of this plugin it was feasible to process several micrographs, taken from electrospun mats at different spots and magnifications. This helped create statistics about obtained results of fiber alignment quality, on an unprecedented approach in written literature. Electrospun mats with varying quality in fiber alignment were used as substrate in the culture of neural precursor cells from neurospheres to assess the influence of contact guidance on migration and differentiation of such cells

Cell scaffolds

Células neurais

Electrospinning

Eletrofiação

Fiber alignment

Fibras alinhadas

Neural cells

Polimeros

Polymer

Quantificação

Quantification

Suportes celulares

DEVELOPMENT OF AN ELECTROSPUN AND 3D PRINTED CELLULAR DELIVERY DEVICE FOR DERMAL WOUND HEALING

Clohessy, Ryan M

01 January 2017

The goal of this research was to develop a system of individualized medicine that could be applied to dermal wounds serving as a wound dressing and synthetic extracellular matrix while delivering stem cells to the wound bed. First, fabrication parameters for electrospinning polymer fibers were determined. This involved evaluating fiber morphology with respect to polymer selection and solution concentration. Next, construct fabrication was examined to produce an integrated void space, or cargo area, suitable to maintain stem cells. In vitro studies to ensure stem cell viability and phenotype were conducted, and results supported the notion that cells could be administered to the wound site through construct pre-seeding. Lastly, in vivostudies were conducted to evaluate the construct as an applied biomaterial and as a cellular delivery device. Wound closure and quality were assessed, and neo-vascularization quantified. This project will provide insight into the tissue engineering field regarding cell-based therapies and dermal wound healing.

electrospinning

3D printing

polyglycolic acid

dermal scaffold

stem cell delivery

Biomaterials

Biomedical Devices and Instrumentation

Heparan sulphate releasing biomaterials for tissue engineering

Emma Luong-van

Unknown Date

Tissue repair is a complex process that is difficult to emulate. The addition of the glycosaminoglycan heparan sulfate (HS), a multi-potential regulator of numerous growth factors and cytokines endogenously expressed during the repair process, may represent a valuable tool for tissue engineering. The addition of exogenous HS into wound site has previously been shown to promote tissue repair in a number of models, however, the incorporation of HS into controlled release systems or biomaterials for tissue engineering had not been explored prior to the work presented here. Thus, this thesis explores the incorporation of HS and its analogue heparin into synthetic biodegradable polymer biomaterials with different potential applications, either as a slow releasing drug reservoir, or as a drug releasing cell scaffold. Polycaprolactone was used to make microcapsules and electrospun fibers for HS or heparin entrapment. These materials were characterized for their drug release profiles, biocompatibility and bioactivity. Microcapsules encapsulating heparin or HS were made by the oil - in - water solvent evaporation method which allowed fabrication of slow releasing drug reservoirs. Either pure water or a poly(vinyl alcohol) solution was used in the drug phase which resulted in capsules with similar size and drug loading. However the internal morphology and drug release profiles showed differences depending on the drug phase, in either case release was sustained for over 30 days. These capsules elicited no pro-inflammatory response from macrophages in vitro, and the released HS retained its bioactivity to induce the proliferation of human mesenchymal stem cells, an important cell type for bone tissue engineering. Heparin and HS were incorporated into electrospun fibers as a drug releasing scaffold for two different tissue engineering applications. Heparin fibers were studied as a drug releasing membrane that could be used in vascular repair to prevent the unwanted proliferation of vascular smooth muscle cells. Heparin release was sustained from the fibers for at least 2 weeks. The fibers did not induce a pro-inflammatory response from macrophages in vitro and the released heparin retained the ability to inhibit the proliferation in vascular smooth muscle cells. HS fibers were studied as a tissue engineering scaffold for bone repair using human mesenchymal stem cells. HS release was maintained for over 30 days which is thought to be an appropriate time for bone repair applications. The release profiles depended on the HS concentration in the spinning solution which affected the morphology of the fibers. The fibers did not elicit a pro-inflammatory response in cultured macrophages and supported the proliferation and mineralization of human mesechymal stem cells. The HS fibers were then taken through to an in vivo model to study ectopic bone formation of pre-osteoblast cells on HS releasing scaffolds. The fibers produced a chronic inflammatory response in vivo, which lead to the clearance of implanted cells and no mineralization of the scaffold. The HS and heparin materials made in this work showed sustained release over appropriate time frames for different tissue repair applications. The released HS and heparin maintained bioactivity and showed good biocompatibility in vitro, however, further in vivo studies are required to fully test their efficacy for tissue engineering.

06 Biological Sciences

Heparan sulphate

heparin

regenerative medicine

polycaprolactone

drug delivery

microencapsulation

electrospinning

bone repair

vascular repair

Mechanical properties of PVDF/MWCNT fibers prepared by flat/cylindrical near-field electrospinning

Ke, Chien-An

04 September 2012

This study presents near-field electrospinning (NFES) on flat and hollow cylindrical process to fabricate permanent piezoelectricity of polyvinylidene fluoride (PVDF)/ multi-walled carbon nanotube (MWCNT) piezoelectric nanofibers. Then the mechanical properties of fibers were measured. PVDF is a potential piezoelectric polymer material combining desirable mechanical, thermal, electrical properties with excellent chemical resistance. The existing researches mostly focused on piezoelectric thin film process. However, the research of characteristic about piezoelectric fiber is little. The methods of measurement of the mechanical properties (Young¡¦s modulus, hardness, and tensile strength¡Belongation) of the electrospun PVDF/MWCN composite nanofiber were carried out by using nano-indention test (MTS Nanoindenter Windows XP System) and tensile test (Microforce Testing System). By setting electric field (1¡Ñ107 V/m), rotating velocity (900 rpm) of the hollow cylindrical glass tube on a motion X-Y stage (2 mm/sec) and PVDF solution concentration (16 wt%), and MWCNT (0.03 wt%), in-situ electric poling, mechanical stretching and morphology of PVDF nanofiber were demonstrated. After the experiments of nano-indention test and tensile strength test, it is suggested that the good mechanical properties in NFES on cylindrical process. The results show that the mechanical properties of composite nanofiber are better than the conventional NFES process. The Young¡¦s modulus of 16% PVDF fiber prepared by cylindrical process is 0.89 GPa and hardness is 26.5 MPa. The mechanical properties were increased 56.2% and 49.4% after adding 0.03% of MWCNT, corresponding to 1.39 GPa and 39.6 MPa. The tensile strength was increased 32.7% and elongation at breaking point was increased 35% after adding 0.03% MWCNT.

Multi-walled carbon nanotube

Polyvinylidene Fluoride

Young¡¦s modulus

Hardness

Cylindrical process

Near-field electrospinning

Tensile strength

Elongation

Synthesis Of Silver Nanoparticles And Cable Like Structures Through Coaxial Electrospinning

Cinar, Simge

01 December 2009

The aim of this study is to demonstrate the possibility of production of nanocables as an alternative to the other one dimensional metal/polymer composite structures like nanowires and nanorods. There is no certain definition of nanocables / however they could be considered as assemblies of nanowires. Nanocable structure can be defined as a core-shell structure formed by a polymeric shell and a metal core that runs continuously within this shell. To produce nanocables, two main steps were carried out. Firstly, monodispersed silver metal nanoparticles to be aligned within the cable core were produced. Investigations on reduction reactions in the presence of strong and weak reducing agents and different capping agents revealed the importance of the kinetics of reduction in the production of monodispersed nanoparticles. Use of capping agents to give a positive reduction potential, resulted in the slow reduction rates that was critical for fine tuning of the final particle sizes between 1-10 nm. Hydrazine hydrate and oleylamine/ oleic acid systems were used as strong and weak reducing agents, respectively. By using weak reducing agent, monodisperse spherical silver nanoparticles with the diameter of 2.7 nm were produced. It was shown that particles with controlled diameter and size distribution can be obtained by tuning the system parameters. Secondly, particles produced as such were electrospun within the core of the polymer nanofibers and long continuous nanocables were produced. Polyvinyl pyrrolidone and polycaprolactone were used in shell part of nanocables. Transmission electron microscopy (TEM), scanning electron microscopy (SEM), photon correlation spectroscopy (PCS), X-ray diffraction (XRD) and surface plasmon resonance spectroscopy (SPR) analyses were carried out in order to understand the mechanism by which the nanoparticles were reduced and for further characterization of the product.

QD Polymers, Macromolecules 380-388

Production And Characterization Of Nanofibers From Polycaprolactam And Ethylene-butyl Acrylate-maleic Anhydride Terpolymer Mixture

Biber, Erkan

01 April 2010

The impact strength of Nylon 6 was improved by adding Ethylene- n-Butyl acrylate- maleic anhydride (E-nBA-MAH) terpolymer with various concentrations from 0% (w/w) to 15% (w/w). The bare interaction energy between two polymers was investigated by using melting point depression approach utilizing both the Flory-Huggins (FH) theory and the Sanchez-Lacombe Equation of State (SL EOS). The solution of the mixture was electrospun, and the effects of process parameters on the expected radii of nanofibers were investigated. The effects of process parameters such as polymer concentration in solution, electrical field, diameter of syringe needle, feed rate, and collector geometry on nanofibers were studied. The statistical analysis to relate these parameters on the diameter of nanofibers was carried out by using Johnson SB distribution. The ratio of elastic modulus to viscosity coefficient of nanofibers was worked out by using AFM and combined viscoelastic models. The experiments were carried out on single fiber. The ratio came out to be a function of nanofiber diameter and terpolymer concentration. Isothermal crystallization kinetics and WAXS diffraction patterns of blends revealed and also SEM images supported that after 5% addition of elastomeric terpolymer, the interaction between the components of the blend gets weaker. The elastic modulus of the blend with 5% of terpoymer was greater than that of the neat Nylon 6, but the elastic modulus decreased for the blends containing more than 5% terpolymer.

TP Polymers, Plastics 1080-1185

The Development of Elastomeric Biodegradable Polyurethane Scaffolds for Cardiac Tissue Engineering

Parrag, Ian

01 September 2010

In this work, a new polyurethane (PU) chain extender was developed to incorporate a Glycine-Leucine (Gly-Leu) dipeptide, the cleavage site of several matrix metalloproteinases. PUs were synthesized with either the Gly-Leu-based chain extender (Gly-Leu PU) or a phenylalanine-based chain extender (Phe PU). Both PUs had high molecular weight averages (Mw > 125,000 g/mol) and were phase segregated, semi-crystalline polymers (Tm ~ 42°C) with a low soft segment glass transition temperature (Tg < -50°C). Uniaxial tensile testing of PU films revealed that the polymers could withstand high ultimate tensile strengths (~ 8-13 MPa) and were flexible with breaking strains of ~ 870-910% but the two PUs exhibited a significant difference in mechanical properties. The Phe and Gly-Leu PUs were electrospun into porous scaffolds for degradation and cell-based studies. Fibrous Phe and Gly-Leu PU scaffolds were formed with randomly organized fibers and an average fiber diameter of approximately 3.6 µm. In addition, the Phe PU was electrospun into scaffolds of varying architecture to investigate how fiber alignment affects the orientation response of cardiac cells. To achieve this, the Phe PU was electrospun into aligned and unaligned scaffolds and the physical, thermal, and mechanical properties of the scaffolds were investigated. The degradation of the Phe and Gly-Leu PU scaffolds was investigated in the presence of active MMP-1, active MMP-9, and a buffer solution over 28 days to test MMP-mediated and passive hydrolysis of the PUs. Mass loss and structural assessment suggested that neither PU experienced significant hydrolysis to observe degradation over the course of the experiment. In cell-based studies, Phe and Gly-Leu PU scaffolds successfully supported a high density of viable and adherent mouse embryonic fibroblasts (MEFs) out to at least 28 days. Culturing murine embryonic stem cell-derived cardiomyocytes (mESCDCs) alone and with MEFs on aligned and unaligned Phe PU scaffolds revealed both architectures supported adherent and functionally contractile cells. Importantly, fiber alignment and coculture with MEFs improved the organization and differentiation of mESCDCs suggesting these two parameters are important for developing engineered myocardial constructs using mESCDCs and PU scaffolds.

Biodegradable Polyurethanes

Cardiac Tissue Engineering

Matrix Metalloproteinases

Electrospinning

Embryonic Stem Cells

Cardiomyocytes

Fibroblasts

Fibrous Scaffolds

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