Montagem de equipamento, desenvolvimento, caracterização e aplicações médico-farmacológicas de nanofibras eletrofiadas à base de blendas de quitosana / Design and assembly of equipment, development, characterization and medical-pharmacological applications of electrospun nanofibers based on chitosan blends

Bizarria, Maria Trindade Marques

20 August 2018

Orientadores: Lucia Helena Innocentini Mei, Marcos Akira D'Ávila / Tese (doutorado) - Universidade Estadual de Campinas, Faculdade de Engenharia Química / Made available in DSpace on 2018-08-20T02:05:21Z (GMT). No. of bitstreams: 1 Bizarria_MariaTrindadeMarques_D.pdf: 4483205 bytes, checksum: 44e9caae2b1e4e2bd5569681573ba911 (MD5) Previous issue date: 2012 / Resumo: A obtenção de nanofibras de polímeros biocompatíveis, baseadas em quitosana, bem como a montagem de equipamento capaz de produzi-las, foi o principal objeto deste trabalho. Com este propósito, buscou-se de início reunir os dispositivos eletrônicos e mecânicos indispensáveis à prática da eletrofiação e um equipamento básico, de baixo custo, mas funcional foi construído. Com base na literatura, o ácido acético glacial a 90% em água deionizada foi o solvente utilizado para preparo das soluções de quitosana. Para viabilizar o processo da produção das nanofibras pela técnica da eletrofiação utilizaram-se blendas de soluções de quitosana com soluções de outros polímeros biocompatíveis em vez de soluções de quitosana pura. Assim, blendas de soluções de quitosana com soluções aquosas do poli(óxido de etileno) - PEO , bem como, com soluções aquosas de Poli(álcool vinílico) - PVA, em diversas proporções, foram eletrofiadas. O Poli(óxido de etileno) mostrou superior desempenho, como auxiliar na fiação da quitosana, permitindo a obtenção de fibras com até 80% de quitosana, e com diâmetros inferiores àqueles obtidos com as blendas de soluções de quitosana/PVA. A adição de um eletrólito (NaCl) às soluções blendas de quitosana/PEO proporcionou um processo fácil ininterrupto, sendo assim, buscou-se um melhor entendimento sobre as propriedades das soluções da quitosana e do PEO que norteiam comportamentos mais ou menos favoráveis ao processo da eletrofiação, caracterizando-se essas soluções através de estudos de viscosidade, de medidas de tensão superficial e de condutividade elétrica. A morfologia das fibras obtidas foi caracterizada por microscopia eletrônica de varredura (MEV) e, as propriedades térmicas, das membranas nanoestruturadas resultantes da eletrofiação das soluções de Quitosana/PEO, foram avaliadas por análise termogravimétrica (TGA) e calorimetria diferencial exploratória (DSC). A biocompatibilidade das membranas com teor de quitosana mais elevado (80% quitosana/20% PEO) foi avaliada através de testes de citotoxicidade in vitro, biocompatibilidade in vivo e adesão e crescimento celular in vitro. Adicionalmente, foram conduzidos experimentos visando avaliar o desempenho destas mesmas membranas como carreadoras de fármacos sendo que, a incorporação de nanopartículas de prata (AgNPs), bem como de digluconato de clorexidina apresentaram resultados promissores / Abstract: The development of biocompatible polymer nanofibers based on chitosan and the design and assembly of equipment capable of producing them were the main objectives of this work. For this purpose, the basic electronic and mechanical devices were obtained and a low-cost functional electrospinning setup was built. Based on the literature, glacial acetic acid with concentration of 90% in deionized water was the solvent used to prepare the chitosan solutions. In order to enable the nanofiber production by electrospinning, blends of chitosan solutions with other biocompatible polymers were used instead of pure chitosan solutions. Thus, blends of chitosan solutions with aqueous solutions of poly (ethylene oxide) PEO as well as with aqueous solutions of poly (vinyl alcohol) PVA, in various proportions, were electrospun. The PEO presented superior performance as an aid to obtain chitosan fibers, resulting in fibers with up to 80% of chitosan, and with smaller diameters than those obtained with solutions of blends of chitosan / PVA. The addition of an electrolyte (NaCl) to the chitosan/PEO solution blends has provided an easy and uninterrupted process. Thus, to obtain a better understanding about the properties of chitosan and PEO solutions that lead to more or less favorable behaviors to the electrospinning process, these solutions were characterized by performing viscosity studies and measurements of surface tension and electrical conductivity. The morphology of the fibers was evaluated by scanning electron microscopy (SEM) and the thermal properties of nanostructured membranes resulting from electrospinning of chitosan/PEO solutions were evaluated by thermogravimetric analysis (TGA) and differential scanning calorimetry (DSC).The biocompatibility of the higher-content-chitosan membranes (80%chitosan /20% PEO) was evaluated by tests of in vitro cytotoxicity, in vivo biocompatibility and in vitro cell adhesion and growth. In addition, experiments were conducted to evaluate the performance of the same membrane as a carrier of drugs. In this way, the incorporation of silver nanoparticles (AgNPs) and chlorhexidine digluconate showed promising results / Doutorado / Ciencia e Tecnologia de Materiais / Doutor em Engenharia Química

Eletrofiação

Nanofibras

Membranas

Quitosana

Poli (oxido de etileno) - PEO

Electrospinning

Nanofibers

Membranes

Chitosan

Poly (ethylene oxide) - PEO

Structure and Dynamics of Polyhedral Oligomeric Silsesquioxane (POSS) and Poly(Ethylene Glycol) (PEG) Based Amphiphiles as Langmuir Monolayers at the Air/Water Interface

Lee, Woojin

08 April 2008

Throughout the study of polymeric Langmuir monolayers at the air/water (A/W) interface, the Wilhelmy plate and Langmuir-Blodgett (LB) techniques along with Brewster angle microscopy (BAM) have been identified as key methods for acquiring structural, thermodynamic, rheological and morphological information. These techniques along with surface light scattering (SLS), a method for probing a monolayer's dynamic dilational rheological properties, will be used to characterize homopolymers, poly(ethylene oxide) (PEO) and poly(ethylene glycol) (PEG), and a new class of novel polymeric surfactants, telechelic (POSS-PEG-POSS) and hemi-telechelic (POSS-PEG) polyhedral oligomeric silsesquioxane (POSS) derivatives of PEG. PEO with number average molar mass, Mn > ~ 18 kg·mol-1 form stable spread Langmuir films at the A/W interface, while oligomeric PEG have ï -A isotherms that deviate from high molar mass PEO. Nonetheless, SLS reveals that the dynamic dilational viscoelastic properties of any Mn PEG(PEO) only depend on ï and not Mn. Likewise, POSS-PEG-POSS telechelics exhibit molar mass dependent ï -A isotherms, where low ï regimes (ï < 1 mN·m-1) have PEG-like behavior, but high ï regimes were dominated by POSS-POSS interactions. SLS studies reveal that the dynamic dilational moduli of POSS-PEG-POSS are greater than either PEO or an analogous POSS compound, trisilanolcyclohexyl-POSS. The ability to control rheological properties and the hydrophilic-lipophilic balance even allows one POSS-PEG-POSS (PEG Mn = 1 kg·mol-1) to form Y-type LB-multilayer films. For POSS-PEG systems, comparisons at comparable POSS:PEG ratios reveal short PEG chains (PEG Mn ~ 0.5 kg·mol-1) yield similar viscoelastic properties as POSS-PEG-POSS (PEG Mn ~ 1 kg·mol-1), while longer PEG chains (PEG Mn ~ 2 kg·mol-1) yield lower modulus films than comparable POSS-PEG-POSS. These differences are attributed to brush-like PEG conformations in short POSS-PEG versus mushroom-like PEG conformations in long POSS-PEG at the A/W interface. These results provide insight for designing PEG-based amphiphilic nanoparticles with controlled interfacial rheology. / Ph. D.

Viscoelasticity

Langmuir monolayers

Poly(ethylene oxide) (PEO)

Poly(ethylene glycol) (PEG)

Hemi-telechelic POSS-PEG

Telechelic POSS-PEG-POSS

Ultra-large sheet formation by 1D to 2D hierarchical self-assembly of a “rod–coil” graft copolymer with a polyphenylene backbone

Huang, Yinjuan, Yuan, Rui, Xu, Fugui, Mai, Yiyong, Feng, Xinliang, Yan , Deyue

17 July 2017

This communication reports a unique ultra-large sheet formation through hierarchical self-assembly of a rod–coil graft copolymer containing a rigid polyphenylene backbone and flexible poly(ethylene oxide) (PEO) side chains. The hierarchical self-assembly process involved a distinctive morphological transition of 1D helical to 2D superstructures. The graft copolymer offers a new chance for the challenging bottom-up fabrication of ultra-large self-assembled nanosheets in solution, as well as a novel system for fundamental studies on 2D self-assembly of polymers.

Stabspulen-Pfropfcopolymer

Polyphenylen-Grundgerüst

Bottom-up-Herstellung

rod–coil graft copolymer containing

polyphenylene backbone

bottom-up fabrication

ddc:540

rvk:VA 1120

Ultra-large sheet formation by 1D to 2D hierarchical self-assembly of a “rod–coil” graft copolymer with a polyphenylene backbone

Huang, Yinjuan, Yuan, Rui, Xu, Fugui, Mai, Yiyong, Feng, Xinliang, Yan, Deyue

17 July 2017

This communication reports a unique ultra-large sheet formation through hierarchical self-assembly of a rod–coil graft copolymer containing a rigid polyphenylene backbone and flexible poly(ethylene oxide) (PEO) side chains. The hierarchical self-assembly process involved a distinctive morphological transition of 1D helical to 2D superstructures. The graft copolymer offers a new chance for the challenging bottom-up fabrication of ultra-large self-assembled nanosheets in solution, as well as a novel system for fundamental studies on 2D self-assembly of polymers.

info:eu-repo/classification/ddc/540

ddc:540