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Comportamento de celulas osteoblasticas sobre biomateriais polimericos / Osteoblast cells behavior on polymeric biomaterialLucchesi, Carolina 02 August 2010 (has links)
Orientadores: Paulo Pinto Joazeiro, Eliana Aparecida de Rezende Duek / Tese (doutorado) - Universidade Estadual de Campinas, Instituto de Biologia / Made available in DSpace on 2018-08-15T19:20:15Z (GMT). No. of bitstreams: 1
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Previous issue date: 2010 / Resumo: Os polímeros biorreabsorvíveis, tais como, PHB, PCL e PLGA, têm sido estudados como dispositivo para engenharia de tecidos por serem biocompatíveis, suportarem o crescimento e diferenciação celular e os produtos de sua degradação serem atóxicos. No entanto, a escolha do biomaterial depende das necessidades exigidas para uma determinada aplicação. Os suportes para engenharia de tecidos devem se basear na construção de réplicas biológicas in vitro, como que o biomaterial se tornasse parte integrada para transplante in vivo para a recuperação de perdas ou mau funcionamento de tecidos ou órgãos, devendo subseqüentemente, atuar sem agredir o restante do organismo, isto é, sem o risco de rejeição ou complicação. Muitas estratégias têm sido desenvolvidas com o intuito de substituir tecidos ou órgãos danificados, incluindo a aplicação de suportes tridimensionais (3D), os quais devem possuir características estruturais e mecânicas para guiar a proliferação e espalhamento de células in vitro e in vivo. Os suportes, feitos de materiais sintéticos ou naturais, servem como substitutos para a matriz extracelular (MEC) nativa. Ênfase especial é dada as técnicas com controle computadorizado, como a fabricação sólida com forma livre (SFF), conhecida como prototipagem rápida (RP), a qual permite preparar suportes 3D com geometrias complexas, tanto externamente como internamente, além de ser uma técnica rápida e de baixo custo. Além disso, grande parte dos polímeros possuem superfície hidrofóbica, característica inadequada para a maior parte dos diferentes tipos celulares, o que dificulta aplicação na engenharia de tecidos. Uma alternativa a este problema é o tratamento da superfície por plasma. Este tratamento induz modificação restrita ao topo da superfície, conferindo carater hidrofílico à superfície, dependendo do gás utilizado. Neste estudo, arcabouços de polímeros biorreabsorvíveis PCL, PLGA e PHB foram preparados por diferentes técnicas, casting e sinterização seletiva a laser, avaliando-se o comportamento de células osteoblásticas diferenciadas sobre os biomateriais poliméricos tridimensionais. Inicialmente o trabalho foi desenvolvido com os polímeros PCL e PLGA preparando-se blendas poliméricas, as quais demonstraram melhorar as características gerais dos polímeros, quando utilizados como dispositivos para tecido ósseo, como as propriedades
mecânicas. Com o intuito de aprimorar o design tridimensional do material, optou-se pela realização da técnica de sinterização seletiva a laser. No entanto, a técnica exige uma grande quantidade de material e devido ao alto do custo do PCL e PLGA, este foi substituído pelo polímero PHB, o qual é produzido pela indústria nacional Biocycle possuindo um baixo custo e ainda ser biocompatível. Os dados são apresentados em capítulos independentes. Arcabouços porosos de PCL, PLGA e suas blendas foram preparados pela técnica de evaporação do solvente, onde sais de citrato de sódio com granulometria de 180-250 µm, foram adicionados a solução para a promoção dos poros, sendo posteriormente lavados do arcabouço. Células osteoblásticas provenientes de calota craniana de ratos Wistar foram semeadas sobre os arcabouços, sendo avaliado o comportamento de citoxicidade do material e o comportamento de adesão e morfologia celular através de ensaios bioquímicos e MEV. Os arcabouços de PHB foram obtidos por uma das técnicas de RP, a sinterização seletiva a laser (SSL), sendo sua superfície modificada por plasma pelos gases oxigênio e nitrogênio. Células osteoblásticas provenientes de calota craniana de coelhos foram semeadas sobre os arcabouços realizando-se o estudo in vitro, através de análises bioquímicas pela técnica do MTT, para viabilidade e adesão celular, quantificação de colágeno por Sírius Red e Microscopia Eletrônica de Varredura (MEV). Para o estudo in vivo, após o cultivo celular sobre os arcabouços, defeitos ósseos foram provocados em coelhos e os arcabouços contendo as células foram então implantados, avaliando-se a interação PHB/osteoblasto/tecido, através da análise histológica. Todos os arcabouços estudados, PCL, PLGA e suas blendas, assim como o PHB, não apresentaram índices de citotoxicidade, permitiram às células a capacidade de adesão, proliferação e síntese de matriz, mantendo seu fenótipo osteoblástico. As amostras de PHB tratadas por plasma de Nitrogênio mostrou melhorar a capacidade de adesão celular. Os arcabouços de PHB contendo células mostraram-se os mais adequados para o preenchimento de defeitos ósseos, melhorando o processo de regeneração apresentando uma boa osteointegração. A sinterização seletiva a laser apresentou-se uma excelente técnica para a obtenção de PHB 3D para a Engenharia de Tecidos. / Abstract: The bioresorbable polymers as, PHB, PCL and PLGA have been studied as device for Tissue Engineering for their biocompatibility and to support the cell growth and differentiation and their degradation products are nontoxics. However, the choice of the biomaterial depends on the needs demanded for a certain application. The scaffolds for tissue engineering have to be designed to mimetize the biological conditions in vitro to became part integrated for transplant for the recovery of tissue or organs lost or without function, and subsequently, to work in a cordial way with the remaining of the organism without the rejection risk or complication. A lot of strategies have been developed with to substitute damaged tissues or organs, and it has been used the application of three-dimensional supports (3D), which should possess structural and mechanical applications to guide the cells proliferation and spread in vitro and in vivo. The scaffolds, made from synthetic or natural materials, serve as substitutes for the extracellular matrix (ECM) native. Special emphasis is given the techniques with computerized control, as the free solid form (SFF), known as rapid prototyping (RP), which allows to prepare three-dimensional supports with complex geometries, so much externally as internally, besides to be a fast technique with low cost. Besides, great part of the polymers possess hydrophobic surface, inadequate characteristic for most of the different cell types, which is not desirable for tissue engineering applications. An alternative to this problem is the surface treatment by plasma. Plasma treatment induces restricted modification to the top of the surface, improving the surface hydrophilicity, depending on the gas used. In this study, scaffolds of bioresorbable polymer PCL, PLGA e PHB were prepared by different techniques, casting and selective laser sintering, being evaluated the osteoblast cells behavior on the 3D polymer scaffolds. Previously we developed the studies preparing the polymeric blends with PCL and PLGA, which demonstrated improve the general characteristic of the material, as the mechanical properties, as devices for bone tissue. With the intention to improve the design of the scaffolds, we chose for the selective laser sintering technique. However, the technique demands a great amount of material and due to the high cost of PCL and PLGA, those weres substituted by PHB polymer, which is produced by Brazilian industry Biocycle with low cost and still to be biocompatible. For those reasons the data are presented in independent chapters. PCL, PLGA porous scaffolds and their blends were prepared those scaffolds by casting solvent, and sodium citrate with 180-250 µm were added to the solution for porous formation when the salt was washed later of the scaffolds. Osteoblast cells from rat Wistar calvaria were seemed on the scaffolds, being evaluated the behavior of cell adhesion and viability behavior, cell morphology through biochemical assays, and scanning electron microscopy. Three-dimensional PHB scaffolds were obtained by selective sintering laser (SSL), with the surface modified by nitrogen and oxygen plasma. Osteoblast cells obtained from rabbit calvaria were seemed on the scaffolds to the in vitro studies, through biochemical analyses by MTT test for cell viability and cell adhesion, collagen quantification of by Sirius Red colorimetric assay and scanning electron microscopy (SEM). For the in vivo studies, bone defects were provoked in rabbits and they were filling out with 3D PHB with osteoblast cells culture prior implant. We evaluated the PHB/osteoblast/tissue, interaction through the histological analysis. All the scaffolds studied PCL, PLGA and their blends, as well as the PHB did not showed cytotoxicity effects, allowed cells adhere, proliferated, and matrix synthesized, maintaining their osteoblastic phenotype. The PHB samples treated by nitrogen plasma have been showed to improve the cell adhesion. The PHB scaffolds with cell seeded previously demonstrated to be more suitable for filling out bone defects, improving the regeneration process showing a good osteointegration. The selective laser sintering was excellent technique to obtain PHB scaffolds for Tissue Engineering. / Doutorado / Biologia Celular / Doutor em Biologia Celular e Estrutural
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Self-Consistency of the Lauritzen-Hoffman and Strobl Models of Polymer Crystallization Evaluated for Poly(ε-caprolactone) Fractions and Effect of Composition on the Phenomenon of Concurrent Crystallization in Polyethylene BlendsSheth, Swapnil Suhas 17 October 2013 (has links)
Narrow molecular weight fractions of Poly(ε-caprolactone) were successfully obtained using the successive precipitation fractionation technique with toluene/n-heptane as a solvent/nonsolvent pair. Calorimetric studies of the melting behavior of fractions that were crystallized either isothermally or under constant cooling rate conditions suggested that the isothermal crystallization of the samples should be used for a proper evaluation of the molecular weight dependence of the observed melting temperature and degree of crystallinity in PCL. The molecular weight and temperature dependence of the spherulitic growth rate of fractions was studied in the context of the Lauritzen-Hoffman two-phase model and the Strobl three-phase model of polymer crystallization. The zero-growth rate temperatures, determined from spherulitic growth rates using four different methods, are consistent with each other and increase with chain length. The concomitant increase in the apparent secondary nucleation constant was attributed to two factors. First, for longer chains there is an increase in the probability that crystalline stems belong to loose chain-folds, hence, an increase in fold surface free energy. It is speculated that the increase in loose folding and resulting decrease in crystallinity with increasing chain length are associated with the ester group registration requirement in PCL crystals. The second contribution to the apparent nucleation constant arises from chain friction associated with segmental transport across the melt/crystal interface. These factors were responsible for the much stronger chain length dependence of spherulitic growth rates at fixed undercooling observed here with PCL than previously reported for PE and PEO. In the case of PCL, the scaling exponent associated with the chain length dependence of spherulitic growth rates exceeds the upper theoretical bound of 2 predicted from the Brochard-DeGennes chain pullout model. Observation that zero-growth and equilibrium melting temperature values are identical with each other within the uncertainty of their determinations casts serious doubt on the validity of Strobl three-phase model.
A novel method is proposed to determine the Porod constant necessary to extrapolate the small angle X-ray scattering intensity data to large scattering vectors. The one-dimensional correlation function determined using this Porod constant yielded the values of lamellar crystal thickness, which were similar to these estimated using the Hosemann-Bagchi Paracrystalline Lattice model. The temperature dependence of the lamellar crystal thickness was consistent with both LH and the Strobl model of polymer crystallization. However, in contrast to the predictions of Strobl’s model, the value of the mesomorph-to-crystal equilibrium transition temperature was very close to the zero-growth temperature. Moreover, the lateral block sizes (obtained using wide angle X-ray diffraction) and the lamellar thicknesses were not found to be controlled by the mesomorph-to-crystal equilibrium transition temperature. Hence, we concluded that the crystallization of PCL is not mediated by a mesophase.
Metallocene-catalyzed linear low-density (m-LLDPE with 3.4 mol% 1-octene) and conventional low-density (LDPE) polyethylene blends of different compositions were investigated for their melt-state miscibility and concurrent crystallization tendency. Differential scanning calorimetric studies and morphological studies using atomic force microscopy confirm that these blends are miscible in the melt-state for all compositions. LDPE chains are found to crystallize concurrently with m-LLDPE chains during cooling in the m-LLDPE crystallization temperature range. While the extent of concurrent crystallization was found to be optimal in blends with highest m-LLDPE content studied, strong evidence was uncovered for the existence of a saturation effect in the concurrent crystallization behavior. This observation leads us to suggest that co-crystallization, rather than mere concurrent crystallization, of LDPE with m-LLDPE can indeed take place. Matching of the respective sequence length distributions in LDPE and m-LLDPE is suggested to control the extent of co-crystallization. / Ph. D.
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Controllable degradation product migration from biomedical polyester-ethersHöglund, Anders January 2007 (has links)
The use of degradable biomedical materials has during the past decades indeed modernized medical science, finding applications in e.g. tissue engineering and drug delivery. The key question is to adapt the material with respect to mechanical properties, surface characteristics and degradation profile to suit the specific application. Degradation products are generally considered non-toxic and they are excreted from the human body. However, large amounts of hydroxy acids may induce a pH decrease and a subsequent inflammatory response at the implantation site. In this study, macromolecular design and a combination of cross-linking and adjusted hydrophilicity are utilized as tools to control and tailor degradation rate and subsequent release of degradation products from biomedical polyester-ethers. A series of different homo- and copolymers of -caprolactone (CL) and 1,5-dioxepan-2-one (DXO) were synthesized and their hydrolytic degradation was monitored in phosphate buffer solution at pH 7.4 and 37 °C for up to 546 days. The various materials comprised linear DXO/CL triblock and multiblock copolymers, PCL linear homopolymer and porous structure, and random cross-linked homo- and copolymers of CL/DXO using 2,2’-bis-(ε-caprolactone-4-yl) propane (BCP) as a cross-linking agent. The results showed that macromolecular engineering and controlled hydrophilicity of cross-linked networks were useful implements for customizing the release rate of acidic degradation products in order to prevent the formation of local acidic environments and thereby reduce the risk of inflammatory responses in the body. / QC 20101109
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Design of polyester and porous scaffoldsOdelius, Karin January 2005 (has links)
The use of synthetic materials for tissue and organ reconstruction, i. e. tissue engineering, has become a promising alternative to current surgical therapies and may overcome the shortcomings of the methods in use today. The challenge is in the design and reproducible fabrication of biocompatible and bioresorbable polymers, with suitable surface chemistry, desirable mechanical properties, and the wanted degradation profile. These material properties can be achieved in various manners, including the synthesis of homo- and copolymers along with linear and star-shaped architectures. In many applications the materials’ three-dimensional structure is almost as important as its composition and porous scaffolds with high porosity and interconnected pores that facilitate the in-growth of cells and transportation of nutrients and metabolic waste is desired. In this work linear and star-shaped polymers have been synthesized by ring-opening polymerization using a stannous-based catalyst and a spirocyclic tin initiator. A series of linear copolymers with various combinations of 1,5-dioxepane-2-one (DXO), Llactide (LLA) and ε-caprolactone (CL) have been polymerized using stannous octoate as catalyst. It is shown that the composition of the polymers can be chosen in such a manner that the materials’ mechanical and thermal properties can be predetermined. A solvent-casting and particulate leaching scaffold preparation technique has been developed and used to create three-dimensional structures with interconnected pores. The achieved physical properties of these materials’ should facilitate their use in both soft and hard tissue regeneration. Well defined star-shaped polyesters have been synthesized using a spirocyclic tin initiator where L-lactide was chosen as a model system for the investigation of the polymerization kinetics. Neither the temperature nor the solvent affects the molecular weight or the molecular weight distribution of the star-shaped polymers, which all show a molecular weight distribution below 1.19 and a molecular weight determined by the initial monomer-to-initiator concentration. / QC 20101217
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Novel methods to synthesize aliphatic polyesters of vivid architecturesSrivastava, Rajiv January 2005 (has links)
Cross-linked films of ε-caprolactone (CL) and 1,5-dioxepan-2-one (DXO) having various mole fractions of monomers and different cross-link densities were prepared using 2,2’-bis-(-caprolactone-4-yl) propane (BCP) as cross-linking agent and Sn(Oct)2 as catalyst. Reaction parameters were examined to optimize the film-forming conditions. Networks obtained were elastomeric materials, easy to cast and remove from the mould. Effect of CL content and cross-link density on the final properties of the polymer network was evaluated. Thermal, mechanical and surface properties of the films were controlled by monomer feed composition and cross-link density. The films have potential to be used for tissue engineering applications as shown by preliminary cell growth studies. To avoid organometallic catalysts in the synthesis of poly(1,5-dioxepan-2-one) (PDXO), the enzyme-catalyzed ring-opening polymerization (ROP) of DXO was performed with lipase-CA (derived from Candida antarctica) as a biocatalyst. A linear relationship between number-average molecular weight (Mn) and monomer conversion was observed, which suggested that the product molecular weight can be controlled by the stoichiometry of the reactants. The monomer consumption followed a first-order rate law with respect to monomer and no chain termination occurred. Effect of reaction water content, enzyme concentration and polymerization temperature on monomer conversion and polymer properties was studied. An initial activation by heating the enzyme was sufficient to start the polymerization as monomer conversion occurred at room temperature afterwards. Terminal-functionalized polyesters and tri-block polyesters were synthesized by lipase-CA catalyzed ROP of DXO and CL in the presence of an appropriate alcohol as initiator. Alcohol bearing unsaturation introduced a double bond at the chain end of the polyester, which is a useful pathway to synthesize comb polymers. Dihydroxyl compounds were used as macro-initiators to form tri-block polyesters. The enzyme-catalyzed polymerization of lactones has been shown to be a useful method to synthesize metal-free polyesters. / QC 20101221
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Crystallization and Melting Studies of Poly(ε-caprolactone) and Poly(ethylene oxide) using Flash™ Differential Scanning Calorimetry and Preparation and Characterization of Poly(δ-valerolactone) FractionsVincent, Matthew Ryan 03 July 2019 (has links)
The isothermal crystallization and melting temperatures of poly(ε-caprolactone) were correlated using fast differential scanning calorimetry. The melting kinetics was found to be independent of isothermal crystallization temperature and time. The conventional Hoffman-Weeks method could not be used to determine the equilibrium melting temperature because the observed melting temperatures were greater than the crystallization temperatures by a constant, so the Gibbs-Thomson method was used instead, yielding an equilibrium melting temperature of 103.4 ± 2.3°C. A modification was proposed to the non-linear Hoffman-Weeks equation that included a non-linear undercooling dependence for the kinetic fold surface free energy upon crystallization and permitted accurate modeling of the observed melting behavior.
The isothermal crystallization rates of four narrow molecular weight poly(ethylene oxide) fractions were characterized using fast differential scanning calorimetry for crystallization temperatures spanning 100°C range with the lower limit approaching the glass transition. A transition from homogeneous to heterogeneous primary nucleation was observed at −5°C. The kinetic analysis suggested that the crystal growth geometry depends strongly on temperature, where rod-like structures begin to appear near the glass transition temperature, highly branched solid sheaves grow throughout the homogeneous primary nucleation temperature range, and spherulites grow in the heterogenous primary nucleation range.
Poly(δ-valerolactone) was synthesized using microwave-assisted techniques. Narrow molecular weight fractions were obtained using successive precipitation fractionation. Preliminary isothermal crystallization studies suggest that conventional thermal analysis methods are not adequate to measure the melting temperatures accurately due to reorganization during heating. / Doctor of Philosophy / Plastics may be classified into two general categories: those which form ordered domains upon solidification, i.e. undergo crystallization, and those which remain disordered upon solidification, i.e. form glasses. This work is focused on studying the crystallization and melting processes in two linear polymers, poly(ε-caprolactone) and poly(ethylene oxide), using new experimental technology. In the case of poly(ε-caprolactone), the experimental data could not be rationalized by existing theories, and we have proposed modifications to these theories that explained the results. In the case of poly(ethylene oxide), the application of new experimental technology resulted in previously unreported data that indicated novel behavior at very low crystallization temperatures. In the last portion of this work, poly(δ-valerolactone) was made using a novel approach. Conventional experimental approaches to measuring the crystallization and melting behavior were shown to be inadequate.
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Biodegradable hydrogels based on water-soluble chitosan for cell transplantGámiz González, Mª Amparo 02 November 2016 (has links)
[EN] The aim of tissue engineering is to develop functional biological substitutes to replace or restore damaged tissues by preparing three-dimensional scaffolds able to accommodate cells plus signaling factors to promote the regeneration of damaged tissue. There is a special interest in developing scaffolds that while providing a favourable environment for cells also possess a degradation rate that can be adapted to the tissue's rate of regeneration. Scaffolds should be porous and possess a pore morphology adapted to the application for which they are designed. They must also be able to hold large quantities of water (hydrogels) while presenting suitable cell/biomaterial interaction.
The aim of this thesis is to create chitosan-based three-dimensional porous structures with tunable degradation rates with particular interest in fast degradation rate. Hydrogels of block-copolymer networks were prepared to crosslink the chitosan (CHT) or carboxymethyl chitosan (CmCHT) with either a hydrophobic polymer of low molecular weight, such as poly(ε-caprolactone), (PCL) or a hydrophilic polymer such as poly(ethylene glycol), (PEG). The hypothesis was that the degradation of the cross-linker polymer leaves behind large water-soluble polymer chains (protonated chitosan or carboxymethyl chitosan).
However, in spite of chitosan's favourable properties, the polymer has relatively slow biodegradation times in enzymatic media that contain lysozyme and even slower in hydrolytic conditions.
Chitosan's physical and chemical properties largely depend on its deacetylation degree (DD). In order to analyze these properties, chitosan was synthesized with various DD ranging from 85% to 45%. Water absorption was seen to rise rapidly as deacetylation was reduced. This would appear to contradict the fact that chitin water absorption (low DD) is much lower than that of chitosan. In order to understand this behaviour, it was analyzed the dependence of the degree of network swelling on the parameters determined by the Flory Rhener theory, the elastic properties of the network and the density of the cross-linking according to the sample's water content.
The thermal stability of chitosan according to its DD was analysed by thermogravimetry. Different methods were applied to obtain the activation energy. Electrospinning was chosen as the porous membrane preparation technique as it provides thin membranes that can be handled with fiber sizes in the order of microns. The influence of the electrospinning and cross-linking processes on the thermal stability of chitosan was analyzed.
Chitosan and carboxymethyl chitosan hydrogels covalently cross-linked with short chains of poly(ε-caprolactone), (PCL) and poly(ethylene glycol) (PEG) were synthesized. The formation of networks was confirmed by solubility tests with appropriate solvents for each polymer. Hydrogels that absorbed large quantities of water were obtained, with values that ranged between 90 and 5000%. The calorimetric tests together with the Studies on the kinetics of hydrolytic and enzymatic biodegradation showed three different systems: CmCHT-PEG system that can be classified as stable hydrogel, CHT-PCL system as semidegradable hydrogel and degradable hydrogels with degradation kinetics in the order of days for the CmCHT-PCL system. Finally, biological studies were carried out on porous CmCHT-PCL hydrogels. Mesenchymal stem cells (MSCs) from pig adipose tissue were then cultivated and the results showed that these networks can be used in the organism in tissue engineering applications with degradation times of around a week. / [ES] La ingeniería tisular tiene como finalidad desarrollar sustitutos biológicos funcionales que reemplacen o restauren los tejidos dañados. Se trata de preparar andamiajes tridimensionales (scaffolds) que sean capaces de albergar células y factores de señalización que favorezcan la regeneración del tejido dañado. Existe un especial interés en el desarrollo de scaffolds que proporcionando un entorno favorable a las células, tengan una tasa de degradación que se adapte a velocidad de regeneración del tejido. Los scaffolds deben ser porosos y poseer una morfología del poro adaptada a la aplicación para la que son diseñados. Deben ser capaces de albergar gran cantidad de agua (hidrogeles) al tiempo que presentan una interacción célula/biomaterial adecuada.
El objetivo de esta tesis es el de crear estructuras porosas tridimensionales basadas en quitosano con velocidades de degradación ajustables con particular interés en velocidades de degradación altas. Se han preparado hidrogeles de redes de copolimeros en bloque entrecruzando el quitosano, (CHT) o el carboximetil quitosano, (CmCHT) con un polímero hidrófobo de bajo peso molecular como la poli(ε-caprolactona), (PCL) o bien con un polímero hidrófilo como es el poli(etilenglicol), (PEG). La hipótesis de trabajo fue que la degradación del polímero que actúa como entrecruzador debe dejar grandes cadenas del polímero (quitosano protonado o carboximetil quitosano) que son solubles en agua.
A pesar de las buenas propiedades del quitosano, el polímero presenta tiempos de biodegradación bastante lentos en medio enzimático conteniendo lisozima y aún más lentos en condiciones hidrolíticas.
Las propiedades físico-químicas del quitosano dependen en gran medida del grado de desacetilación, DD. Con el fin de analizar dichas propiedades se ha llevado a cabo la síntesis de quitosano con DD variando entre 85% y el 45%. Se ha comprobado que la absorción de agua aumenta rápidamente a medida que el grado de desacetilación disminuye. Esto parece contradecir el hecho de que la absorción de agua de la quitina (DD bajo) es mucho menor que la de quitosano. Para entender dicho comportamiento se han analizado los parámetros que determinan la teoría de Flory Rhener, las propiedades elásticas de la red y la densidad de entrecruzamiento en función del contenido en agua de la muestra. La estabilidad térmica del quitosano en función de DD ha sido analizada por termogravimetría. Se han aplicado diferentes métodos para obtener la energía de activación. Como técnica de preparación de membranas porosas se ha elegido el electrohilado, ya que permite obtener membranas delgadas y manipulables con tamaños de fibra del orden de micras. Se ha analizado la influencia de los procesos de electrohilado y entrecruzamiento en la estabilidad térmica del quitosano.
Se han sintetizado hidrogeles de quitosano, y carboximetil quitosano entrecruzados covalentemente con cadenas cortas de poli(ε-caprolactona), y poli(etilenglicol). La formación de las redes se ha confirmado mediante ensayos de solubilidad con buenos solventes para cada polímero. En todos los casos se han obtenido hidrogeles que absorben gran cantidad de agua con valores que oscilan entre 90 y 5000%. Los estudios de las cinéticas de biodegradación tanto hidrolítica como enzimática revelan la obtención de tres sistemas que se pueden clasificar como hidrogeles estables, para los hidrogeles formados por CmCHT-PEG, hidrogeles semidegradables para el sistema CHT-PCL y finalmente hidrogeles degradables con cinéticas de degradación del orden de días, para el sistema CmCHT-PCL. Finalmente se ha llevado a cabo estudios biológicos de los hidrogeles porosos de CmCHT-PCL. Se realizaron cultivos con células mesenquimales del tejido adiposo de cerdo (MSCs). Los resultados han revelado que dichas redes pueden ser utilizadas como sistemas de liberación de células en el organismo con tiempos de degradación / [CA] L'enginyeria tissular té com a finalitat desenvolupar substituts biològics funcionals que reemplacen o restauren els teixits danyats. Es tracta de preparar suports tridimensionals (esquelets o scaffolds) que siguen capaços d'albergar cèl.lules i factors de senyalització que afavorisquen la regeneració del teixit danyat. Hi ha un interès especial en el desenvolupament d'esquelets que, proporcionant un entorn favorable a les cèl.lules, tinguen una taxa de degradació que s'adapte a la velocitat de regeneració del teixit. Els scaffolds han de ser porosos i han de tenir una morfologia del porus adaptada a l'aplicació per a la qual són dissenyats. Han de ser capaços d'albergar una gran quantitat d'aigua (hidrogels) alhora que presenten una interacció cèl.lula/biomaterial adequada.
L'objectiu d'aquesta tesi és crear estructures poroses tridimensionals basades en quitosan amb velocitats de degradació sintonizables amb un interés particular de rutes de degradació altes. S'han preparat hidrogels de xarxes de copolímers en bloc entrecreuant el quitosan o el carboximetil quitosan amb un polímer hidròfob de baix pes molecular com la poli (ε-caprolactona), o bé amb un polímer hidròfil com és el poli (etilenglicol). Es tracta d'aconseguir que quan el polímer que actua com a entrecreuador es degrade, deixe grans cadenes del polímer (quitosan protronat o carboximetil quitosan) que són solubles en aigua.
A pesar de les bones propietats del quitosan, el polímer presenta cinètiques de biodegradació lentes en condicions enzimàtiques quan conté lisozima i encara més lentes en condicions hidrolítiques.
Les propietats fisicoquímiques del quitosan depenen en gran mesura del grau de desacetilació, DD. A fi d'analitzar aquestes propietats, s'ha dut a terme la síntesi de quitosan amb un DD que variava entre el 85% i el 45%.
S'ha comprovat que l'absorció d'aigua augmenta ràpidament a mesura que el grau de desacetilació disminueix. Això sembla que contradiu el fet que l'absorció d'aigua de la quitina (DD baixos) és molt menor que no la de quitosan. Per a entendre aquest comportament s'ha analitzat la dependència del grau d'unflament de la xarxa amb els paràmetres que determina la teoria de Flory Rhener, les propietats elàstiques de la xarxa i la densitat d'entrecreuament en funció del contingut en aigua de la mostra. L'estabilitat tèrmica del quitosan en funció del DD ha sigut analitzada per termogravimetria. S'han aplicat diversos mètodes per obtenir l'energia d'activació. Com a tècnica de preparació de membranes poroses s'ha utilitzat l'electrofilatura, ja que permet obtenir membranes primes i manipulables amb grandàries de fibra de l'ordre de micres. S'ha analitzat la influència dels processos d'electrofilatura i entrecreuament amb l'estabilitat tèrmica del quitosan.
S'han sintetitzat hidrogels de quitosan i carboximetil quitosan entrecreuats covalentment amb cadenes curtes de poli(ε-caprolactona) i poli(etilenglicol). La formació de les xarxes s'ha confirmat per mitjà d'assajos de solubilitat amb bons solvents per a cada polímer. En tots els casos s'han obtingut hidrogels que absorbeixen una gran quantitat d'aigua, compresa en valors que oscil.len entre el 90 i el 5.000%. Els estudis de les cinètiques de biodegradació tant hidrolítica com enzimàtica revelen l'obtenció de tres sistemes que es poden classificar com a hidrogels estables (per als hidrogels formats per CmCHT-PEG), hidrogels semidegradables (per al sistema CHT-PCL) i, finalment, hidrogels degradables amb cinètiques de degradació de l'ordre de dies (per al sistema CmCHT-PCL). Finalment s'ha dut a terme estudis biològics dels hidrogels porosos de CmCHT-PCL. Es van realitzar cultius amb cèl.lules mesenquimals del teixit adipós de porc (MSCs). Els resultats han revelat que aquestes xarxes poden ser utilitzades com a sistemes d'alliberament de cèl.lules en l'organisme amb temps de degradació de l'ordre d'una setm / Gámiz González, MA. (2016). Biodegradable hydrogels based on water-soluble chitosan for cell transplant [Tesis doctoral]. Universitat Politècnica de València. https://doi.org/10.4995/Thesis/10251/73070
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Cascade bi-enzymatique autosuffisante in vivo : le jeu des plasmides / In vivo self-sufficient bi-enzymatic cascades : the plasmid gameMenil, Sidiky 31 January 2018 (has links)
Une attention croissante est portée aux cascades multi enzymatiques pour l’élaboration de procédés de synthèse plus efficaces. Cependant, le contrôle de l’expression hétérologue de plusieurs gènes dans un même hôte s’avère difficile et peut mener à un déséquilibre du flux réactionnel. Pour exploiter au mieux les avantages d’une cascade in vivo, il est nécessaire d’ajuster les activités de chaque étape, et de construire des catalyseurs cellulaires capables de programmer la stœchiométrie des enzymes. Nous avons développé dans ce projet une approche originale pour moduler le ratio de deux enzymes in cellulo en jouant sur le nombre de copies de plasmides par cellule (PCN). Nous avons choisi comme modèle un système autosuffisant associant une Alcool Déshydrogénase (ADH) et une Baeyer-Villiger MonoOxygenase (BVMO), NADP(H)-dépendantes. Plusieurs plasmides recombinants portant les deux gènes ont été conçus et combinés dans E. coli. Les souches de co-expression construites ont été comparées en termes de PCN, de production d’enzymes et d’activité. Nous avons montré l’importance d’un choix judicieux de la combinaison de plasmides ainsi que l’existence d’une corrélation entre ratios d’enzymes et activité. Nos biocatalyseurs s’étendent sur une gamme allant du système inactif à un système affichant un TTN d’environ 6000. Ce système a permis la synthèse de lactones d’intérêt industriel, la dihydrocoumarine et la caprolactone, à partir d’indanol et de cyclohexanol. Enfin, sur ce modèle de combinaison de plasmides, trois nouveaux biocatalyseurs cellulaires, associant l’ADH à diverses BVMOs, ont été créés afin d’élargir la gamme d’esters et de lactones synthétisables à partir d’alcools. / Growing attention is paid to multienzymatic cascades to develop more efficient synthetic processes. However, in in cellulo process, the control of the simultaneous heterologous expression of several genes in the same host is often difficult and can lead to imbalances in the reaction flow. To exploit the benefits of cascades, activities of each step have to be adjusted and thus, cellular biocatalysts capable of programming enzymes stoichiometry have to be constructed. In this work, to modulate the stoichiometry of two enzymes in vivo, we developed an original approach based on the copy number per cell of plasmids (PCN) used as vectors. The PCN is regulated in bacteria by three main mechanisms leading, according to the replicon, to low, medium or high PCN. As proof of concept, we chose a self-sufficient system combining an Alcohol Dehydrogenase (ADH) and a Baeyer-Villiger MonoOxygenase (BVMO), both NADP(H)-dependent. Several recombinant plasmids harboring both genes were designed and combined in E. coli. Coexpression strains constructed were compared in terms of PCN, enzyme production and activity. We showed the importance of a judicious choice of plasmids combination and the existence of a correlation between enzymes ratios and activity. Our biocatalysts ranged from an inactive system to a system with a TTN of about 6000. This system allowed the synthesis of lactones of industrial interest, dihydrocoumarin and caprolactone, via double oxidation of indanol and cyclohexanol. Finally, based on this plasmids combination model, three new cellular biocatalysts combining ADH with various BVMOs were designed to broaden the range of esters and lactones synthesizable from alcohols.
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A contribution to the selection of suitable cells, scaffold and biomechanical environment for ligament tissue engineering / Une contribution à la sélection de cellules adaptés, biomatériaux et d’environments biomécaniques appropriés pour l’ingéniere tissulaire ligamentaireLiu, Xing 01 July 2019 (has links)
L'ingénierie tissulaire du ligament constitue une approche prometteuse pour réparer ou remplacer un ligament endommagé. Les trois piliers essentiels de l'ingénierie tissulaire ligamentaire sont la matrice de support (aussi appelée scaffold), la source cellulaire, ainsi que l'apport de stimulations biomécaniques/biochimiques : ces trois piliers ont été partiellement étudiés par le passé dans le but de s’orienter vers une régénération ligamentaire. Dans la présente étude, le polymère synthétique poly (L-lactide-co-ε-caprolactone) (PLCL) et la soie ont été proposés et comparés comme de potentiels candidats pour la constitution d’une matrice de support. Une série de matrices tressées multicouches à base de PLCL et de soie, ainsi qu'un nouveau composite soie/PLCL ont été développés et comparés. Les caractérisations physico-chimiques et biologiques ont démontré que le PLCL et la soie constituent des candidats pertinents, tant sur les plans mécaniques que biologiques, pour la constitution d’une matrice de support. De plus, nous avons montré que le composite soie/PLCL offrait des propriétés mécaniques et une biocompatibilité accrue par rapport aux autres matrice testées, et constituait probablement le candidat le plus approprié pour l'ingénierie tissulaire du ligament. Les cellules souches mésenchymateuses (CSM) de la gelée de Wharton (WJ-MSCs) ainsi que les cellules souches mésenchymateuses de la moelle osseuse (BM-MSCs) ont été évaluées et comparées en tant que sources cellulaires potentielles pour la régénération ligamentaire. Les caractéristiques biologiques de ces cellules incluent l’adhésion cellulaire, la prolifération, la migration et la synthèse de matrice extracellulaire. Ces deux types de cellules ont montré une bonne biocompatibilité dans leurs interactions avec les matrices de support en PLCL et en soie. Aucune différence significative n'a été observée entre les WJ-MSCs et les BM-MSCs. Enfin, l'effet de la stimulation biomécanique sur la différentiation des CSM en tissu ligamentaire a été évalué par le biais d’un bioréacteur de traction-torsion. Bien que peu de cellules aient été détectées la matrice après 7 jours de stimulation, des CSM de forme allongée le long des fibres ont été détectées, ce qui permet de penser qu'il est possible de promouvoir la différenciation des biosubstituts matrice-cellules grâce à la stimulation mécanique en bioréacteur. En conclusion, cette étude démontre le potentiel prometteur de l’association de cellules souches mésenchymateuses issues de la gelée de Wharton ou de la moelle osseuse avec une matrice de support composite soie/PLCL pour la régénération ligamentaire dans le futur. / Ligament tissue engineering offers a potential approach to recover or replace injured ligament. The three essential elements that have been investigated towards ligament regeneration consist in a suitable scaffold, an adapted cell source, and the supply of biomechanical/biochemical stimulations. In the current study, synthetic polymer poly (L-lactide-co-ε-caprolactone) (PLCL) and silk have been evaluated as suitable candidates to constitute an adapted scaffold. A series of multilayer braided scaffolds based on PLCL and silk, as well as an original silk/PLCL composite scaffold, have been developed and compared. The conducted physicochemical and biological characterizations have demonstrated that both PLCL and silk constitute adapted candidate material to form ligament scaffolds from the mechanical and biological points of view. Moreover, it has been observed that silk/PLCL composite scaffold resulted in adequate mechanical properties and biocompatibility, and therefore could constitute suitable candidate scaffolds for ligament tissue engineering. Both Wharton’s Jelly mesenchymal stem cells (WJ-MSCs) and Bone marrow mesenchymal stem cells (BM-MSCs) have been evaluated to be cell source for ligament regeneration. MSCs behaviors including cell attachment, proliferation, migration and extracellular matrix synthesis have been investigated. In the present study, both MSCS showed a good biocompatibility to interact with PLCL and silk scaffolds. No significant differences have been detected between WJ-MSCs and BM-MSCs. Finally, the effect of biomechanical stimulation on MSCs differentiation towards ligament tissue has been carried out with a tension-torsion bioreactor. Although few cells were detected on scaffold after 7 days of stimulation, MSCs were observed to exhibit an elongated shape along the longitudinal direction of fibers, which may indicate that an adapted mechanical stimulation could promote MSC-scaffold constructs differentiation towards ligamentous tissue. As a conclusion, this study demonstrates the potential of WJ-MSCs and BM-MSCs combined with a new silk/PLCL composite scaffold towards ligament regeneration.
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New main group and rare earth complexes and their applications in the ring-opening polymerisation of cyclic estersCushion, Michael Gregory January 2011 (has links)
This Thesis describes the synthesis and characterisation of new Main Group and Rare Earth alkyl, amide, alkoxide and borohydride complexes and their use as catalysts for the ring-opening polymerisation (ROP) of ε-caprolactone and rac-lactide. <strong>Chapter 1</strong> introduces ROP from an industrial and academic perspective, as well as polymer characterisation techniques. A literature review is given, with an emphasis placed on Main Group catalysts. <strong>Chapter 2</strong> describes the synthesis and characterisation of new homo- and hetero-scorpionate Main Group complexes. An introduction to homo- and hetero-scorpionate ligands is given, as well as a discussion of the ε-caprolactone and rac-lactide ROP activity displayed by the new complexes. <strong>Chapter 3</strong> describes the synthesis and characterisation of new neutral and cationic Main Group borohydride complexes supported by the tris(pyrazolyl)methane and tris(pyrazolyl)hydroborate ligands. A review of borohydride complexes is also given. The ε-caprolactone and rac-lactide ROP activity shown by the complexes presented is also discussed. <strong>Chapter 4</strong> describes the synthesis and characterisation of new mono- and di-cationic yttrium complexes supported by the tris(pyrazolyl)methane and triazacyclononane ligands. An introduction to the synthesis of neutral and cationic Rare Earth complexes is given. An overview of immortal ROP is also provided. The activity of the new complexes towards the immortal ROP of rac-lactide is also discussed. <strong>Chapter 5</strong> contains experimental details and characterising data for the new complexes reported in this thesis. CD Appendix</strong> contains .cif files for all of the new crystallographically characterised complexes.
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