Calorimetric and SEM studies of PHB-PET polymeric blends

Conselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq)

PHB/PZT composite

Flexible standing films of piezoelectric composite made of lead zirconate titanate (PZT) ceramic powder and Poly(3-hydroxybutyrate) (PHB) in powder form were obtained by mixing both polymers mechanically and pressed at 180°C. The piezoelectric coefficient d33 were investigated as function of PZT content, poling temperature and electric field. The highest value for d 33 coefficient was around 6pC/N for 50 vol% of PZT content in the composite. As PHB is a biodegradable polymer the composite has potential application as sensor minimizing the environmental problems.

Biodegradação de polipropileno (PP), de polihidroxibutirato (PHB) e da blenda PP/PHB (1:1) por microrganismos de rio poluído e efluente bruto de refinaria de petróleo

Conselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq)

Otimização da modificação de cadeia do PHB com anidrido maleico e estudo de comportamento térmico

Conselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq)

Estudo de comportamento térmico e de biodegradação de PHBV4% modificado com hidroxiácido

Conselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq)

Análises físico-químicas e biológicas de diferentes scaffolds à base de polihidroxibutirato e polihidroxibutirato-co-valerato

Fundação de Amparo à Pesquisa do Estado de São Paulo (FAPESP)

Análises físico-químicas e biológicas de diferentes scaffolds à base de polihidroxibutirato e polihidroxibutirato-co-valerato

Fundação de Amparo à Pesquisa do Estado de São Paulo (FAPESP)

Biological materials : Part A. tuning LCST of raft copolymers and gold/copolymer hybrid nanoparticles and Part B. biobased nanomaterials

The research described in this dissertation is comprised of two major parts. The first part studied the effects of asymmetric amphiphilic end groups on the thermo-response of diblock copolymers of (oligo/di(ethylene glycol) methyl ether (meth)acrylates, OEGA/DEGMA) and the hybrid nanoparticles of these copolymers with a gold nanoparticle core. Placing the more hydrophilic end group on the more hydrophilic block significantly increased the cloud point compared to a similar copolymer composition with the end group placement reversed. For a given composition, the cloud point was shifted by as much as 28 °C depending on the placement of end groups. This is a much stronger effect than either changing the hydrophilic/hydrophobic block ratio or replacing the hydrophilic acrylate monomer with the equivalent methacrylate monomer. The temperature range of the coil-globule transition was also altered. Binding these diblock copolymers to a gold core decreased the cloud point by 5-15 °C and narrowed the temperature range of the coil-globule transition. The effects were more pronounced when the gold core was bound to the less hydrophilic block. Given the limited numbers of monomers that are approved safe for in vivo use, employing amphiphilic end group placement is a useful tool to tune a thermo-response without otherwise changing the copolymer composition. The second part of the dissertation investigated the production of value-added nanomaterials from two biorefinery “wastes”: lignin and peptidoglycan. Different solvents and spinning methods (melt-, wet-, and electro-spinning) were tested to make lignin/cellulose blended and carbonized fibers. Only electro-spinning yielded fibers having a small enough diameter for efficient carbonization ( Peptidoglycan (a bacterial cell wall material) was copolymerized with poly-(3-hydroxybutyrate), a common polyhydroxyalkanoate produced by bacteria with the objective of determining if a useful material could be obtained with a less rigorous work-up on harvesting polyhydroxyalkanoates. The copolyesteramide product having 25 wt.% peptidoglycan from a highly purified peptidoglycan increased thermal stability by 100-200 °C compared to the poly-(3-hydroxybutyrate) control, while a less pure peptidoglycan, harvested from B. megaterium (ATCC 11561), gave a 25-50 °C increase in thermal stability. Both copolymers absorbed more moisture than pure poly-(3-hydroxybutyrate). The results suggest that a less rigorously harvested and purified polyhydroxyalkanoate might be useful for some applications.

Bio-based PLA_PHB plasticized blend films: Processing and structural characterization

Bio-based films formed by poly(lactic acid) (PLA) and poly(3-hydroxybutyrate) (PHB) plasticized with an oligomer of the lactic acid (OLA) were used as supporting matrices for an antibacterial agent (carvacrol). This paper reports the main features of the processing and physico-chemical characterization of these innovative biodegradable material based films, which were extruded and further submitted to filmature process. The effect of the addition of carvacrol and OLA on their microstructure, chemical, thermal and mechanical properties was assessed. The presence of these additives did not affect the thermal stability of PLA_PHB films, but resulted in a decrease in their crystallinity and in the elastic modulus for the active formulations. The obtained results showed the effective presence of additives in the PLA or the PLA_PHB matrix after processing at high temperatures, making them able to be used in active and bio-based formulations with antioxidant/antimicrobial performance.

Processing and characterization of plasticized PLA/PHB blends for biodegradable multiphase systems

Blends of poly(lactic acid) (PLA) and poly(3-hydroxybutyrate) (PHB) plasticized with a lactic acid oligomer (OLA) added at three different concentrations (15, 20 and 30 wt% by weight), were prepared by an optimized extrusion process to improve the processability and mechanical properties of these biopolymers for flexible film manufacturing. Morphological, chemical, thermal, mechanical, barrier and migration properties were investigated and formulations with desired performance in eco-friendly films were selected. The efficiency of OLA as plasticizer for PLA_PHB blends was demonstrated by the significant decrease of their glass transition temperatures and a considerable improvement of their ductile properties. The measured improvements in the barrier properties are related to the higher crystallinity of the plasticized PLA_PHB blends, while the overall migration test underlined that all the proposed formulations maintained migration levels below admitted levels. The PLA_PHB blend with 30 wt% OLA was selected as the optimum formulation for food packaging, since it offered the best compromise between ductility and oxygen and water vapor barrier properties with practically no migration.

Synthesis and evaluation of novel polymer modifiers for biodegradable polymers

The effects of ester plasticizers and copolymers on the mechanical properties of the natural biodegradable polymers, poly(3-hydroxybutyrate) [PHB] and poly(lactic acid) [PLA] have been studied after subjecting to melt processing conditions. Ester plasticizers were synthesized from citric, tartaric and maleic acids using various alcohols. A variety of PLA copolymers have also been prepared from poly(ethylene glycol) derivatives using stannous octanoate catalysed ring opening polymerisations of DL-lactide. A novel PLA star copolymer was also prepared from an ethoxylated pentaerythritol. The structures of these copolymers were determined by NMR spectroscopy. The plasticizing effect of the synthesised additives at various concentrations was determined. While certain additives were capable of improving the mechanical properties of PLA, none were effective in PHB. Moreover, it was found that certain combinations of additives exhibited synergistic effects. Possible mechanisms are discussed. Biotic and abiotic degradation studies showed that the plasticizers (esters and copolymers) did not inhibit the biodegradability of PHB or PLA in compost at 60°C. Simple toxicity tests carried out on compost extract and its ability to support the growth of cress seeds was established. PLA was found to be susceptible to limited thermal degradation under melt processing conditions. Conventional phenolic antioxidants showed no significant effect on this process, suggesting that degradation was not predominantly a free radical process. PLA also underwent photo-oxidative degradation with UV light and the process could be accelerated in the presence of a photoactivator such as iron (III) diisononyl dithiocarbamate. The mechanisms for the above processes are discussed. Finally, selected compounds were prepared on a pilot plant scale. Extruded and blown films were prepared containing these additives with conventional polymer processing equipment. The mechanical properties were similar to those obtained with laboratory produced compression moulded films.

In vitro hydrolytic degradation of centrifugally spun polyhydroxybutyrate-pectin composite fibres

BACKGROUND: Centrifugal spinning is a novel fibre-forming process that readily permits the incorporation of additives while avoiding the thermal damage often associated with conventional melt spinning. Centrifugal spinning of a viscous solution of poly(3-hydroxybutyrate) (PHB) mixed with pectin was used to fabricate a range of fibres containing different concentrations of this biologically active agent. The influence of this blending on fibre morphology and in vitro degradation in an accelerated hydrolytic model at 70 ?C and pH of 10.6 is reported. RESULTS: Blending influenced the physiochemical properties of the fibres, andthis significantly affected thedegradation profile of both the fibre and its PHB constituent. A greater influence on degradation was exerted by the type of pectin and its degree of esterification than by variations in its loading. CONCLUSION: Centrifugal spinning permits the fabrication of composite fibrous matrices from PHB and pectin. Incorporation of the polysaccharide into the fibres can be used to manipulate degradation behaviour and demonstrates a model for doping of matrices with active biological constituents. The unique features of the centrifugal spinning process, as illustrated by the structure of the fibres and the degradation profiles, suggest possible applications of centrifugally spun biopolymers as wound scaffolding devices and in tissue engineering.

Ruptura celular, extração e encapsulamento de Astaxantina de Haematococcus pluvialis (Volvocales, Chlorophyta)

O interesse na produção de astaxantina de fontes naturais vem aumentando significativamente, devido principalmente à sua capacidade como potente agente antioxidante. Na obtenção da astaxantina por via biotecnológica, a microalga Haematococcus pluvialis é um dos micro-organismos industrialmente mais interessantes. Entretanto, como a maioria dos carotenoides, a astaxantina é uma molécula altamente insaturada que pode ser facilmente degradada por processos térmicos. Em função desta instabilidade, uma possibilidade que se abre, a fim de proteger sua atividade biológica de fatores ambientais e reforçar a sua estabilidade física, é o encapsulamento. Neste sentido, este trabalho vem contribuir em inovações relacionadas ao desenvolvimento de tecnologia para ruptura celular, extração e nanoencapsulamento de astaxantina produzida por via biotecnológica, mais especificamente de astaxantina obtida através do cultivo de H. pluvialis. Neste estudo, os cultivos foram realizados em meio BBM e acetato de sódio e conduzidos a temperatura constante de 25±1 ºC em fotobiorreatores de 1 L com aeração por borbulhamento de ar de 300 mL.min-1 , agitação manual diária e sob iluminância constante de 444 µmol fótons.m-2 s -1 durante 15 dias, sendo inoculados com suspensão de microalgas previamente preparada, na proporção de 10%, e pH ajustado em 7,0. A biomassa foi recuperada dos cultivos por centrifugação e seca a 35 °C por 48 h. Em seguida, foram empregadas diferentes técnicas de ruptura celular (química, mecânica e enzimática). Após a ruptura, foi realizada a extração dos carotenoides e a quantificação dos carotenoides totais (µg.g-1 ) e da extratibilidade (%). Entre os solventes testados no método de ruptura química, o diclorometano foi o selecionado para a extração dos pigmentos carotenoides. Dentre as técnicas mecânicas de ruptura celular, a maceração da biomassa congelada com terra diatomácea resultou na maior extratibilidade e carotenoides totais (66,01% e 972,35 μg.g-1 ). A melhor condição de lise da parede celular de H. pluvialis, utilizando o preparado enzimático Glucanex® , ocorreu em pH do meio reacional de 4,5 a 55 ºC, com atividade inicial de β-1,3-glucanase de 0,6 U.mL-1 e um tempo de reação de 30 min, alcançando-se 17,73% de atividade lítica relativa. Nestas condições, com a reação enzimática assistida por ultrassom sem congelamento prévio da biomassa, atingiu-se 83,90% e 1235,89 µg.g -1 , respectivamente, para extratibilidade e carotenoides totais. Dentre as técnicas combinadas testadas, a maceração com terra diatomácea associada à lise enzimática apresentou valores de extratibilidade e carotenoides totais de, respectivamente, 93,83% e 1382,12 µg.g-1 . No encapsulamento do extrato contendo astaxantina obtido por lise enzimática associada por ultrassom, envolvendo a coprecipitação com PHBV (poli(3-hidroxibutirato-cohidroxivalerato)) em fluidos supercríticos, o aumento da pressão tendeu a reduzir o diâmetro da partícula formada, enquanto que o aumento da relação biomassa contendo astaxantina:diclorometano usada na etapa de extração incrementou o percentual de encapsulamento e a eficiência de encapsulamento para ambas pressões testadas (80 e 100 bar). Os maiores valores de percentual de encapsulamento (17,06%) e eficiência de encapsulamento (51,21%) foram obtidos nas condições de 80 bar e relação biomassa:diclorometano de 10 mg.mL -1 . Nestas condições, o diâmetro médio de partícula foi de 0,228 µm. Com base nos resultados obtidos, técnicas para a obtenção de astaxantina de H. pluvialis e seu encapsulamento foram desenvolvidas com sucesso, podendo ser extendidas a outros produtos intracelulares de microalgas.

Efficient P(3HB) extraction from Burkholderia sacchari cells using non-chlorinated solvents

© 2015. This manuscript version is made available under the CC-BY-NC-ND 4.0 license http://creativecommons.org/licenses/by-nc-nd/4.0/

Design of biobased additives for tuning the properties of biopolymers

This work mainly arises from the necessity to support the rapid introduction of different biobased polymers that the industrial sector has been facing lately. Indeed, while considerable efforts are being made to find environmentally and economically sustainable materials, less attention is paid to their need to be properly compounded to fulfil increasingly rigorous technical and quality requirements. Therefore, there is a strong demand for the development of a novel generation of compatible additives able to improve the properties of biobased polymers while respecting sustainability. With this in mind, a new class of biobased plasticizers is herein proposed. Five different ketal-diesters were selectively synthesized starting from levulinic acid, a promising renewable chemical platform. These molecules were added to poly(vinyl chloride) as model polymer to test their plasticizing effectiveness. Complete morphological, thermal and viscoelastic characterizations showed a clear correlation between the structural features of the ketal-esters and the properties of the material. In addition, no significant leaching was found in both hydrophilic and lipophilic environments. Importantly, the proposed ketal-diesters performed comparably and, in some cases, even better than commercial plasticizers. The same molecules were then added to bacterial poly(3-hydroxybutyrate), a semicrystalline polyester characterized by poor thermal and mechanical properties. Morphology assessments showed no phase separation and the plasticizing effectiveness was confirmed by thermal and viscoelastic analyses, while leaching tests showed low extraction values. Readily usable fractions with controlled structure and tailored properties were obtained from highly heterogeneous industrial grade Kraft lignin. These fractions were then added to poly(vinyl alcohol). Promising preliminary results in terms of compatibility were achieved, with thermograms showing only one glass transition temperature. Finally, a fully biobased glycerol-trilevulinate was successfully synthesized by means of a mild and solvent-free route. Its plasticizing effectiveness was evaluated on poly(vinyl chloride), showing a significant decrease of the glass transition temperature of the material.