Biodegradable Thermoplastic Elastomers

Asplund, Basse

January 2007

<p>A novel strategy for synthesising segmented poly(urethane urea) (PUU) without using a chain extender but nevertheless with the opportunity to vary the hard segment content has been developed. The strategy is based on amine formation from isocyanate upon reaction with water. By adding a dissolved soft segment to an excess of diisocyanate followed by the addition of water in the gas phase, amines are formed <i>in situ</i>. Urea linkages are then formed when these amines react with the excess of isocyanate groups. The gas phase addition facilitates addition in a slow and continuous manner. The hard segment content can easily altered by varying the diisocyanate/soft segment ratio. Even though the strategy is shown to be applicable to different diisocyanates, the focus has been on the potentially biodegradable methyl-2,6-diisocyanatehexanoate (LDI) and 1.4-butanediisocyanate (BDI) and various well known biodegradable polyesters and polycarbonates. </p><p>All the synthesised materials exhibited pronounced phase separation and hydrogen bonding within the hard domains. However, a major increase in hydrogen bonding strength was seen when a symmetric diisocyanate was used instead of an asymmetric. Based on FTIR measurements, PUUs with BDI and a polydisperse hard segment can exhibit the same degree of phase separation and hydrogen bonding as the monodisperse product.</p><p>The elastic properties of this new group of PUUs were exceptional with an elongation at break from 1600% to almost 5000% and the elastic modulus could be varied from a few MPa up to a couple of hundreds. </p><p>Hydrolytic degradation was greater in the polyester-based than in the polycarbonate-based PUUs due to the more reactive ester bonds. Low mass loss but a considerable loss in molecular weight was seen in the polyester PUUs. The tensile strength decreased dramatically due to the loss of strain hardening.</p><p>An MTT seeding assay using human fibroblasts and an in vivo biocompatibility study were performed and no signs of cytotoxicity were seen and the inflammatory response was comparable to other inert polymers.</p><p>A biodegradable PUU with properties that can be tailored through an easy synthesis is here presented. </p>

Chemistry

poly(urethane)

poly(urethane urea)

biomaterial

biodegradable

polymer

thermoplastic elastomer

haemocomatible

tissue engineering

biocompatible

Kemi

Biodegradable Thermoplastic Elastomers

Asplund, Basse

January 2007

A novel strategy for synthesising segmented poly(urethane urea) (PUU) without using a chain extender but nevertheless with the opportunity to vary the hard segment content has been developed. The strategy is based on amine formation from isocyanate upon reaction with water. By adding a dissolved soft segment to an excess of diisocyanate followed by the addition of water in the gas phase, amines are formed in situ. Urea linkages are then formed when these amines react with the excess of isocyanate groups. The gas phase addition facilitates addition in a slow and continuous manner. The hard segment content can easily altered by varying the diisocyanate/soft segment ratio. Even though the strategy is shown to be applicable to different diisocyanates, the focus has been on the potentially biodegradable methyl-2,6-diisocyanatehexanoate (LDI) and 1.4-butanediisocyanate (BDI) and various well known biodegradable polyesters and polycarbonates. All the synthesised materials exhibited pronounced phase separation and hydrogen bonding within the hard domains. However, a major increase in hydrogen bonding strength was seen when a symmetric diisocyanate was used instead of an asymmetric. Based on FTIR measurements, PUUs with BDI and a polydisperse hard segment can exhibit the same degree of phase separation and hydrogen bonding as the monodisperse product. The elastic properties of this new group of PUUs were exceptional with an elongation at break from 1600% to almost 5000% and the elastic modulus could be varied from a few MPa up to a couple of hundreds. Hydrolytic degradation was greater in the polyester-based than in the polycarbonate-based PUUs due to the more reactive ester bonds. Low mass loss but a considerable loss in molecular weight was seen in the polyester PUUs. The tensile strength decreased dramatically due to the loss of strain hardening. An MTT seeding assay using human fibroblasts and an in vivo biocompatibility study were performed and no signs of cytotoxicity were seen and the inflammatory response was comparable to other inert polymers. A biodegradable PUU with properties that can be tailored through an easy synthesis is here presented.

Chemistry

poly(urethane)

poly(urethane urea)

biomaterial

biodegradable

polymer

thermoplastic elastomer

haemocomatible

tissue engineering

biocompatible

Kemi

Síntese e caracterização de filmes de nanopartículas de prata dispersas em poli(uretano-ureia) para separação de gases petroquímicos / Synthesis and characterization of films of silver nanoparticles dispersed in poly(urethane-urea) for the separation of petrochemical gases

Antoniel Carlos Carolino Campos

29 November 2013

Coordenação de Aperfeiçoamento de Pessoal de Nível Superior / A utilização de novos materiais aplicados aos processos de separação por membranas tem sido objeto de constante pesquisa acadêmica e tecnológica. Na permeação de gases petroquímicos, a modificação de estruturas poliméricas e o uso de membranas de transporte facilitado por adição de sais contendo metais ou nanopartículas destacam-se dentre as opções disponíveis. Os objetivos deste trabalho foram avaliar alterações químicas, estruturais e térmicas na matriz polimérica de poli(uretano-ureia) (PUU) provocadas pela adição de nanopartículas de prata (AgNps) e obter dados de pemeabilidade de gases petroquímicos (C2H4, C2H6, CO2 e N2) para avaliar a influência das AgNps no transporte desses gases através do filme polimérico. Alterações nos espectros de FTIR nas bandas de estiramento das ligações C-O-C e C=O (uretânica e ureica), e deslocamentos nos picos de difração, demonstram que houve interação entre as AgNps e o oxigênio éter do PUU. A interação com as AgNps diminuiu a estabilidade térmica dos domínios flexíveis do polímero, região onde são encontrados os grupos éteres. As imagens de TEM mostraram que houve baixa dispersão das Nps na matriz polimérica. A interação das AgNps com o grupo éter diminuiu a permeabilidade de todos os gases, porém a redução da permeabilidade do CO2 e do C2H4 foi muito mais significativa, mostrando a interferência das AgNps na sorção desses dois gases. O transporte facilitado de olefinas através dos filmes poliméricos não foi observado, em parte, causado pela baixa dispersão das AgNps na matriz polimérica. Apesar da interação, não foi possível responder se a superfície das Nps estava ativada para o transporte facilitado. Contudo, através dos resultados do trabalho foi possível propor um mecanismo de interação entre as AgNps e o PUU, e verificar como a presença das Nps pode alterar a interação da matriz polimérica com gases petroquímicos / The use of new materials applied to processes of membrane separation has been the target of constant academic and technological researches. In permeation of petrochemical gases, the modification of polymeric structure to form facilitated transport membranes are one of the worthy available options. In this sense, the goal of this work is, not only evaluate the influence of the addition of silver nanoparticles (AgNps) in the chemical, morphological and thermal properties of poly(urethane urea) (PUU) films, but also obtain permeability data for some petrochemical gases (C2H4, C2H6, CO2 e N2). FTIR spectra exhibited changes in the C-O-C and C=O stretching bands profile of (from urethane and urea groups) and XRD analyses exhibited shifts in peaks. These results demonstrate the AgNps interacted with the ether oxygen of PUU. The interaction with AgNps reduced the thermal stability of polymer soft segments, where the ether linkages are located. TEM images showed a lower dispersion of Np in the polymer matrix. The interaction between AgNps and ether groups also decreased the permeability of all gases. Reduction of CO2 and C2H4 permeability were clear, demonstrating the hindrance of AgNps in the sorption of both gases. The olefin transport facilitated through the polymeric films was not verified. . This is partially caused by the lower dispersion of AgNps in the polymer matrix. Although an interaction between the AgNps and ether oxygen was observed, it was not possible to confirm if the Nps surface was really activated to facilitated transport. However, considering the results obtained it was possible to propose the interaction mechanism between AgNps and PUU; and also to indicate how the presence of Nps can change the interaction between the polymeric matrix and the petrochemical gases

poli(uretano-urea)

Nanopartículas de prata

permeação de gás

Silver nanoparticles

poly(urethane-urea)

gas permeation

Síntese e caracterização de filmes de nanopartículas de prata dispersas em poli(uretano-ureia) para separação de gases petroquímicos / Synthesis and characterization of films of silver nanoparticles dispersed in poly(urethane-urea) for the separation of petrochemical gases

Antoniel Carlos Carolino Campos

29 November 2013

Coordenação de Aperfeiçoamento de Pessoal de Nível Superior / A utilização de novos materiais aplicados aos processos de separação por membranas tem sido objeto de constante pesquisa acadêmica e tecnológica. Na permeação de gases petroquímicos, a modificação de estruturas poliméricas e o uso de membranas de transporte facilitado por adição de sais contendo metais ou nanopartículas destacam-se dentre as opções disponíveis. Os objetivos deste trabalho foram avaliar alterações químicas, estruturais e térmicas na matriz polimérica de poli(uretano-ureia) (PUU) provocadas pela adição de nanopartículas de prata (AgNps) e obter dados de pemeabilidade de gases petroquímicos (C2H4, C2H6, CO2 e N2) para avaliar a influência das AgNps no transporte desses gases através do filme polimérico. Alterações nos espectros de FTIR nas bandas de estiramento das ligações C-O-C e C=O (uretânica e ureica), e deslocamentos nos picos de difração, demonstram que houve interação entre as AgNps e o oxigênio éter do PUU. A interação com as AgNps diminuiu a estabilidade térmica dos domínios flexíveis do polímero, região onde são encontrados os grupos éteres. As imagens de TEM mostraram que houve baixa dispersão das Nps na matriz polimérica. A interação das AgNps com o grupo éter diminuiu a permeabilidade de todos os gases, porém a redução da permeabilidade do CO2 e do C2H4 foi muito mais significativa, mostrando a interferência das AgNps na sorção desses dois gases. O transporte facilitado de olefinas através dos filmes poliméricos não foi observado, em parte, causado pela baixa dispersão das AgNps na matriz polimérica. Apesar da interação, não foi possível responder se a superfície das Nps estava ativada para o transporte facilitado. Contudo, através dos resultados do trabalho foi possível propor um mecanismo de interação entre as AgNps e o PUU, e verificar como a presença das Nps pode alterar a interação da matriz polimérica com gases petroquímicos / The use of new materials applied to processes of membrane separation has been the target of constant academic and technological researches. In permeation of petrochemical gases, the modification of polymeric structure to form facilitated transport membranes are one of the worthy available options. In this sense, the goal of this work is, not only evaluate the influence of the addition of silver nanoparticles (AgNps) in the chemical, morphological and thermal properties of poly(urethane urea) (PUU) films, but also obtain permeability data for some petrochemical gases (C2H4, C2H6, CO2 e N2). FTIR spectra exhibited changes in the C-O-C and C=O stretching bands profile of (from urethane and urea groups) and XRD analyses exhibited shifts in peaks. These results demonstrate the AgNps interacted with the ether oxygen of PUU. The interaction with AgNps reduced the thermal stability of polymer soft segments, where the ether linkages are located. TEM images showed a lower dispersion of Np in the polymer matrix. The interaction between AgNps and ether groups also decreased the permeability of all gases. Reduction of CO2 and C2H4 permeability were clear, demonstrating the hindrance of AgNps in the sorption of both gases. The olefin transport facilitated through the polymeric films was not verified. . This is partially caused by the lower dispersion of AgNps in the polymer matrix. Although an interaction between the AgNps and ether oxygen was observed, it was not possible to confirm if the Nps surface was really activated to facilitated transport. However, considering the results obtained it was possible to propose the interaction mechanism between AgNps and PUU; and also to indicate how the presence of Nps can change the interaction between the polymeric matrix and the petrochemical gases

poli(uretano-urea)

Nanopartículas de prata

permeação de gás

Silver nanoparticles

poly(urethane-urea)

gas permeation

Caracterização de filmes formados por dispersões aquosas de poli(uretano-uréia)s para aplicação em membranas para permeação de gases / Characterizations of films formed from aqueous dispersions of poly(urethane-urea)s for use as membranes for gas permeation

Juliana Henriques Costa Pereira

28 February 2012

Coordenação de Aperfeiçoamento de Pessoal de Nível Superior / Entre os polímeros considerados promissores para a remoção seletiva de CO2, destacam-se aqueles que contêm os grupos glicol etilênico (EG). Nesta dissertação, foram obtidos filmes a partir de dispersões aquosas de poliuretano (PU), sintetizadas em trabalho anterior, à base de poli(glicol propilênico) (PPG), copolímero em bloco à base de poli(glicol etilênico) (PEG) e PPG (EG-b-PG), ácido dimetilolpropiônico (DMPA), diisocianato de isoforona (IPDI) e etilenodiamina (EDA). PPG, EG-b-PG e DMPA formaram as regiões flexíveis nas proporções de: PPG 100% e 0% EG-b-PG, PPG 75% e 25% EG-b-PG, PPG 50% e 50% EG-b-PG e PPG 25% e 75% EG-b-PG em termos de equivalentes-gramas. A influência da quantidade dos segmentos de PEG foi avaliada por ensaios de permeação com os gases CO2, CH4 e N2. Os filmes obtidos das dispersões foram caracterizados por espectrometria de infravermelho com transformadas de Fourier (FTIR), análise termogravimétrica (TGA), difração de raios x (DRX) e espalhamento de raios X a baixo ângulo (SAXS). Espectros de FTIR mostraram que os segmentos de EG influenciaram a frequência da banda de carbonila. Curvas de perda de massa (TG) mostraram perfis semelhantes de degradação, enquanto que as curvas derivadas apresentaram diferenças. DRX e SAXS mostraram que os segmentos de PEG promoveram uma maior ordenação na estrutura da membrana. Testes de permeação de gases mostraram que o aumento do teor de PEG aumentou o valor da permeabilidade para o CO2, indicando que os segmentos de PEG interagiram favoravelmente com este gás. Em relação ao CH4 e N2, houve uma diminuição na permeabilidade quando comparados com os valores encontrados para o CO2, sendo atribuído a perda de mobilidade segmental. Em termos de seletividade, para o par CO2/CH4 foi obtido um valor médio de 61,7 para a membrana contendo o maior teor de PEG, e o par CO2/N2 um valor médio de 121,5, sendo superior aos valores encontrados na literatura, tornando o material promissor / Among the polymers considered promising for the selective removal of CO2 from natural gas, those containing ethylene glycol groups (EG) are the most distinguished. In this study cast films were obtained from aqueous dispersions of polyurethane (PU), synthesized in a previous work with poly (propylene glycol) (PPG), block copolymer based on poly(ethylene glycol) (PEG) and PPG, dimethylolpropionic acid (DMPA), isophorone diisocyanate (IPDI) and ethylenediamine (EDA). Segments of PPG, EG-b-PG and DMPA formed the flexible domains in the proportions of: PPG 100% and 0% EG-b-PG, PPG 75% and 25% EG-b-PG, PPG 50% and 50% EG-b-PG and PPG 25% and 75% EG-b-PG, in terms of equivalent-grams. The influence of the amount of PEG segments in permeation properties of CO2, CH4 and N2 was verified by permeability essays. The membranes were obtained as cast films from the dispersions and was characterized by infrared spectrometry (FTIR), termogravimetric analysis (TGA), X ray diffractometry (XRD) and small angle X ray scattering (SAXS). FTIR spectra showed that PEG segments influenced carbonyl band frequency. Loss of mass curves with temperature (TG) showed similar profiles of degradation, whereas DTG curves presented more stages. PEG segments conferred higher thermal stability for the materials. XRD and SAXS analysis showed that PEG promoted ordination to the membranes. In gas permeation tests, it was verified that the increase in copolymer amount increased permeability value for CO2, being attributed to the fact that the segments of poly(ethylene glycol) interacted favorably with this gas. In relation to CH4 and N2, there was a significant decrease in permeability when compared to the values found for CO2, being assigned to a loss of segmental mobility with increasing content of EG. In terms of selectivity, the pair CO2/CH4 had a mean value of 61,7 for the membrane containing the highest amount of EG groups, and the pair CO2/N2 produced a mean value of 121,5 for the same one, being superior than those found in the literature, making a promising material

Permeação de gases

dispersões aquosas

poliuretanos

poli(uretano-uréia)s

Poli(glicol etilênico)

Gas permeation

aqueous dispersion

polyurethane

poly(urethane-urea)s

poly(ethylene glycol)

Caracterização de filmes formados por dispersões aquosas de poli(uretano-uréia)s para aplicação em membranas para permeação de gases / Characterizations of films formed from aqueous dispersions of poly(urethane-urea)s for use as membranes for gas permeation

Juliana Henriques Costa Pereira

28 February 2012

Coordenação de Aperfeiçoamento de Pessoal de Nível Superior / Entre os polímeros considerados promissores para a remoção seletiva de CO2, destacam-se aqueles que contêm os grupos glicol etilênico (EG). Nesta dissertação, foram obtidos filmes a partir de dispersões aquosas de poliuretano (PU), sintetizadas em trabalho anterior, à base de poli(glicol propilênico) (PPG), copolímero em bloco à base de poli(glicol etilênico) (PEG) e PPG (EG-b-PG), ácido dimetilolpropiônico (DMPA), diisocianato de isoforona (IPDI) e etilenodiamina (EDA). PPG, EG-b-PG e DMPA formaram as regiões flexíveis nas proporções de: PPG 100% e 0% EG-b-PG, PPG 75% e 25% EG-b-PG, PPG 50% e 50% EG-b-PG e PPG 25% e 75% EG-b-PG em termos de equivalentes-gramas. A influência da quantidade dos segmentos de PEG foi avaliada por ensaios de permeação com os gases CO2, CH4 e N2. Os filmes obtidos das dispersões foram caracterizados por espectrometria de infravermelho com transformadas de Fourier (FTIR), análise termogravimétrica (TGA), difração de raios x (DRX) e espalhamento de raios X a baixo ângulo (SAXS). Espectros de FTIR mostraram que os segmentos de EG influenciaram a frequência da banda de carbonila. Curvas de perda de massa (TG) mostraram perfis semelhantes de degradação, enquanto que as curvas derivadas apresentaram diferenças. DRX e SAXS mostraram que os segmentos de PEG promoveram uma maior ordenação na estrutura da membrana. Testes de permeação de gases mostraram que o aumento do teor de PEG aumentou o valor da permeabilidade para o CO2, indicando que os segmentos de PEG interagiram favoravelmente com este gás. Em relação ao CH4 e N2, houve uma diminuição na permeabilidade quando comparados com os valores encontrados para o CO2, sendo atribuído a perda de mobilidade segmental. Em termos de seletividade, para o par CO2/CH4 foi obtido um valor médio de 61,7 para a membrana contendo o maior teor de PEG, e o par CO2/N2 um valor médio de 121,5, sendo superior aos valores encontrados na literatura, tornando o material promissor / Among the polymers considered promising for the selective removal of CO2 from natural gas, those containing ethylene glycol groups (EG) are the most distinguished. In this study cast films were obtained from aqueous dispersions of polyurethane (PU), synthesized in a previous work with poly (propylene glycol) (PPG), block copolymer based on poly(ethylene glycol) (PEG) and PPG, dimethylolpropionic acid (DMPA), isophorone diisocyanate (IPDI) and ethylenediamine (EDA). Segments of PPG, EG-b-PG and DMPA formed the flexible domains in the proportions of: PPG 100% and 0% EG-b-PG, PPG 75% and 25% EG-b-PG, PPG 50% and 50% EG-b-PG and PPG 25% and 75% EG-b-PG, in terms of equivalent-grams. The influence of the amount of PEG segments in permeation properties of CO2, CH4 and N2 was verified by permeability essays. The membranes were obtained as cast films from the dispersions and was characterized by infrared spectrometry (FTIR), termogravimetric analysis (TGA), X ray diffractometry (XRD) and small angle X ray scattering (SAXS). FTIR spectra showed that PEG segments influenced carbonyl band frequency. Loss of mass curves with temperature (TG) showed similar profiles of degradation, whereas DTG curves presented more stages. PEG segments conferred higher thermal stability for the materials. XRD and SAXS analysis showed that PEG promoted ordination to the membranes. In gas permeation tests, it was verified that the increase in copolymer amount increased permeability value for CO2, being attributed to the fact that the segments of poly(ethylene glycol) interacted favorably with this gas. In relation to CH4 and N2, there was a significant decrease in permeability when compared to the values found for CO2, being assigned to a loss of segmental mobility with increasing content of EG. In terms of selectivity, the pair CO2/CH4 had a mean value of 61,7 for the membrane containing the highest amount of EG groups, and the pair CO2/N2 produced a mean value of 121,5 for the same one, being superior than those found in the literature, making a promising material

Permeação de gases

dispersões aquosas

poliuretanos

poli(uretano-uréia)s

Poli(glicol etilênico)

Gas permeation

aqueous dispersion

polyurethane

poly(urethane-urea)s

poly(ethylene glycol)