Resumo em Inglês:

Abstract Soy Protein Isolate (SPI) has been evaluated as useful candidate for the development of protein-based bioplastic materials processed by injection molding. The influence of sorbitol (SB) as plasticizer in mechanical properties and water uptake capacity was evaluated in SPI-based bioplastics. A mixing rheometer that allows monitoring torque and temperature during mixing and a small-scale-plunger-type injection molding machine were used to obtain SPI/Plasticizer blends and SPI-based bioplastics, respectively. Dynamic measurements were carried out to obtain mechanical spectra of different bioplastics. Moreover, the mechanical characterization was supplemented with uniaxial tensile tests. Additionally, the influence of SB in water uptake capacity was also evaluated. The introduction of SB leads to increase the rigidity of bioplastics as well as the water uptake capacity after 24h, however it involves a decrease in strain at break. Final bioplastics are plastic materials with both adequate properties for the substitution of conventional petroleum plastics and high biodegradability.

Resumo em Inglês:

Abstract Poly(vinyl acetate) (PVAc) particles find many uses in the biomedical field, including the use as particle embolizers. Particularly, embolizing particles can combine physical and chemical effects when they are doped with pharmaceuticals. For this reason, the adsorption of bovine serum albuminum (BSA) and lysozyme (used as model biomolecules) on PVAc particles produced through suspension polymerization is studied in the present manuscript in a broad range of pH values. It is shown that significant amounts of BSA and lysozyme can be adsorbed onto PVAc particles in the vicinities of the isoelectric point of the biomolecules (0.65mg of BSA and 1.0mg of lysozyme per g of PVAc), allowing for production of chemoembolizers through adsorption. Particularly, it is shown that lysozyme still presents residual activity after the adsorption process, which can constitute very important characteristic for real biomedical applications.

Resumo em Inglês:

Abstract The use of epoxidized rubber as compatibilizer in silica-filled rubber compounds has been proposed in literature. However, the investigation of the reaction kinetics between the epoxy groups and the hydroxyl groups at the silica surface is not yet described. It is a difficult task, mainly because of the high dilution of the system due the difficulty of incorporating high levels of silica in a matrix containing epoxidized rubbers of high molecular weight. In this work, a mixture of precipitated silica and an epoxidized liquid rubber (EpLHPB) was prepared and the reaction between silanols and epoxy groups was followed by DSC under isothermal conditions, at 150, 160 and 170 °C. An autocatalytic data treatment was applied to determine the kinetic parameters of the reaction. Furthermore, it was possible to estimate the amount of epoxy groups required for the saturation of the external surface of the silica, resulting in 5.4 epoxy groups/nm2.

Resumo em Inglês:

Abstract Iron oxide magnetic nanoparticles (NP's) converted to the core- shell structres by reacting with by n-(2-aminoethyl)-3-aminopropyl trimethoxysilane (AEAP) incorporated in polyurethane flexible (PUF) foam formulations. Fourier transform spectra, thermal gravimetric analysis, scanning electron images, thermo-mechanical analysis and magnetic properties of the prepared nanocomposites were studied. Obtained data shown that by the increasing of the amine modified magnetic iron oxide NP's up to 3% in the polymer matrix, thermal and magnetic properties improved in comparison with pristine foams. In addition, due to the presence of functional groups on the magnetic NP's surface, hard phases formation decrease in the bulk polymer and cause decreasing of glass transition temperature.

Resumo em Inglês:

Abstract α-Tocopherol is the most bioavailable and active compound found in vitamin E with potential application in pharmaceutical, alimentary and cosmetic industries. However, its low solubility in aqueous medium and environmental instability limit its dosage. In this paper, we report the preparation of α-tocopherol loaded nanoparticles (TOC-NP) based on amphiphilic thermosensitive triblock copolymers PNIPAM-b-PCL-b-PNIPAM. The nanoparticles exhibited a core – shell structure, were positively charged and presented average diameters below 300 nm. TOC-NP presented controlled release of α-tocopherol at room temperature along 140h, and exhibited antioxidant properties in aqueous medium.

Resumo em Inglês:

Abstract This paper uses a new kinetic modeling and simulations to analyse the effect of temperature on the polystyrene properties obtained by atom-transfer radical polymerization (ATRP). Differently from what has been traditionaly published in ATRP modeling works, it was considered “break” reactions in the mechanism aiming to reproduce the process at high temperatures. Results suggest that there is an upper limit temperature (130 °C), above which the polymer architecture loses the control. In addition, for the system considered in this work, the optimum operating temperature was 100 °C, because at this temperature polymer with very low polydispersity index is obtained, at considerable fast polymerization rate. Therefore, this present paper provides not only a tool to study ATRP processes by simulations, but also a tool for analysis and optimization, being a basis for future works dealing with this monomer and process.

Resumo em Inglês:

Abstract The modification of lignocellulosic fibers can enhance their interaction with other materials and alkaline hydrogen peroxide (AHP) is a reagent widely used to promote such modification. This work aimed to modify oat hulls fibers by reactive extrusion using AHP (7 g 100 g-1 of hulls). The modified oat hulls displayed performances comparable to those observed by other researchers using conventional AHP method (without extrusion). The AHP treated oat hulls showed increased luminosity compared to the extruded ones. Fourier transform infrared spectroscopy showed differences between the modified and unmodified structures. The removal of surface compounds resulted in a more open morphology, with greater surface area and greater porosity. Reactive extrusion can be an alternative method for fiber modification with several advantages, such as short processing time and no wastewater generation.

Resumo em Inglês:

Abstract Whiskers have been used as a nanomaterial dispersed in polymer matrices to modify the microscopic and macroscopic properties of the polymer. These nanomaterials can be isolated from cellulose, one of the most abundant natural renewable sources of biodegradable polymer. In this study, whiskers were isolated from sugarcane bagasse and corn cob straw fibers. Initially, the cellulose fiber was treated through an alkaline/oxidative process followed by acid hydrolysis. Dimethylformamide and dimethyl sulfoxide were used to replace the aqueous medium for the dispersion of the whiskers. For the solvent exchange, dimethylformamide or dimethyl sulfoxide was added to the aqueous dispersion and the water was then removed by fractional distillation. FTIR, TGA, XRD, TEM, Zeta and DLS techniques were used to evaluate the efficiency of the isolation process as well as the morphology and dimensions of the whiskers. The dimensions of the whiskers are comparable with values reported in the literature, maintaining the uniformity and homogeneity in both aqueous and non-aqueous solvents.

Resumo em Inglês:

Abstract The tribological properties of poly-ether-ether-ketone (PEEK) containing 30% of carbon fiber were studied in an oil-lubricated environment and different surface finishing of the metallic counterbody. Four different finishing processes, commonly used in the automotive industry, were chosen for this study: turning, grinding, honing and polishing. The test system used was tri-pin on disc with pins made of PEEK and counterbody made of steel; they were fully immersed in ATF Dexron VI oil. Some test parameters were held constant, such as the apparent pressure of 2 MPa, linear velocity of 2 m/s, oil temperature at 85 °C, and the time - 120 minutes. The lubrication regime for the apparent pressure of 1 MPa to 7 MPa range was also studied at different sliding speeds. A direct correlation was found between the wear rate, friction coefficient and the lubrication regime, wherein wear under hydrodynamic lubrication was, on average, approximately 5 times lower, and the friction coefficient 3 times lower than under boundary lubrication.

Resumo em Inglês:

Abstract Four waterborne hyperbranched alkyd-acrylic resins (HBRAA) were synthesized by miniemulsion polymerization from a hyperbranched alkyd resin (HBR), methyl methacrylate (MMA), butyl acrylate (BA) and acrylic acid (AA), by using benzoyl peroxide (BPO) and ammonium persulfate (AP) as initiators. The reaction between HBR and acrylic monomers was evidenced by differential scanning calorimetric (DSC), nuclear magnetic resonance (NMR) and gel permeation chromatography (GPC). The conversion percentage, glass transition temperature (Tg), content of acrylic polymer (determined by soxhlet extraction) and molecular weight increased with the content of acrylic monomers used in the synthesis. The main structure formed during the synthesis was the HBRAA. The analysis by dynamic light scattering (DLS) showed that the particle size distribution of HBRAA2, HBRAA3 and HBRAA4 resins were mainly monomodal. The film properties (gloss, flexibility, adhesion and drying time) of the HBRAA were good.

Resumo em Português:

Resumo Nesse trabalho foi desenvolvido filme de PHB/quitosana com aplicação promissora em embalagens de alimentos e medicamentos. Esses filmes foram preparados via casting solution e após esterilização térmica ou radiolítica suas propriedades foram avaliadas a partir da microscopia eletrônica de varredura, ensaio de tração, calorimetria exploratória diferencial e análise termogravimétrica. Foram constatadas alterações na morfologia dos filmes de PHB/quitosana após os processos de esterilização. As propriedades mecânicas da blenda se mantiveram aproximadamente constantes após esterilização térmica. Porém, após irradiação as blendas apresentaram-se quebradiças. As propriedades térmicas da blenda foram alteradas apenas para as doses de 50 e 75 kGy, em que foi observado uma redução no valor da entalpia de cristalização, grau de cristalinidade, cristalinidade relativa e taxa de cristalização da blenda. Foi observado que a degradação térmica dos filmes de PHB e das blendas, antes e após os processos de esterilização apresentaram um único estágio (250-300 °C).

Resumo em Inglês:

Abstract In this work was developed PHB/chitosan film with promising application in food and medicine packaging. These films were prepared by the casting solution and after radiolytic or thermal sterilization their properties were evaluated by scanning electron microscopy, tensile testing, differential scanning calorimetry and thermogravimetric analysis. PHB/chitosan films changed their morphology after sterilization processes. Mechanical properties of the blend remained approximately constant after thermal sterilization. But, after irradiation the blends presented brittle. Thermal properties of the blend were changed only for the doses of 50 and 75 kGy, in which case was observed a reduction in the crystallization enthalpy value, the degree of crystallinity, relative crystallinity and crystallization rate of the blend. It was observed thermal degradation of the PHB films and blends, before and after sterilization processes presented a single stage (250-300 °C).

Resumo em Português:

Resumo A Engenharia de Tecidos envolve o desenvolvimento de novos materiais ou dispositivos capazes de interações específicas com os tecidos biológicos, buscando a utilização de materiais biocompatíveis que devem servir como arcabouço para o crescimento de células in vitro, organizando e desenvolvendo o tecido que posteriormente será implantado no paciente. Uma variedade de arcabouços como hidrogéis poliméricos, sintéticos e naturais, têm sido investigados para a expansão de condrócitos in vitro, visando o reparo da cartilagem lesionada. Um hidrogel de interesse particular na regeneração de cartilagem é o ácido hialurónico (AH). Trata-se de um biopolímero atraente para a fabricação de arcabouços artificiais para Engenharia de Tecidos por ser biocompatível e biodegradável. A biocompatibilidade do AH deve-se ao fato de estar presente na matriz extracelular nativa, deste modo, cria-se um ambiente propício que facilita a adesão, proliferação e diferenciação celular, além da existência de sinalização celular específica, o que contribui para a regeneração do tecido. O uso de hidrogel composto de ácido hialurónico e quitosana (QUI) também tem sido investigado em aplicações de Engenharia de Tecidos de cartilagem, com resultados promissores. Baseando-se nestas informações, o objetivo este trabalho foi investigar as alternativas disponíveis para regeneração tecidual da cartilagem e conhecer mais detalhadamente as relações entre células e biomateriais.

Resumo em Inglês:

Abstract Tissue Engineering involves the development of new materials or devices capable of specific interactions with biological tissues, searching the use of biocompatible materials as scaffolds for cell growth in vitro, organizing and developing tissue that is subsequently implanted into the patient. A variety of scaffolds such as polymeric hydrogels, natural and synthetic, have been investigated for the expansion of chondrocytes in vitro in order to repair the damaged cartilage. A hydrogel of particular interest in cartilage regeneration is hyaluronic acid (HA). HA are attractive biopolymers for manufacturing artificial scaffolds for Tissue Engineering, it is biocompatible and biodegradable. The biocompatibility of HA is due to the fact that it is present in native extracellular matrix, thus creates an environment, which facilitates the adhesion, proliferation and differentiation, in addition to the existence of specific cell signaling, which contributes to tissue regeneration. The use of hydrogel composed of hyaluronic acid and chitosan (CHI) has also been investigated for applications in Tissue Engineering of soft tissues, like cartilage, with promising results. Based on this information, this study aims to investigate the alternatives available for cartilage tissue regeneration and meet more detail the relationships between cells and biomaterials.