Thermisch schaltbare Hydrogele - Synthese - Charakterisierung - Anwendung

Gramm, Stefan

14 August 2006

Gegenstand dieser Arbeit war die Synthese von thermisch schaltbaren Kammcopolymeren auf Basis von N-(Isopropylacrylamid) (NiPAAm) und Polyethylenglykolmakromonomeren (PEGMA). Die intensive Charakterisierung der aus diesen Copolymeren hergestellten Schichten und deren Anwendung als Zellkultursubstrate war ein weiteres Forschungsziel dieser Arbeit. Die mit Hilfe der neuartigen Schichten erhaltenen Zellkultursubstrate wurden anhand verschiedener adhärenter Zelllinien erfolgreich getestet. Alle getesten Zelltypen (Mausfibroblasten, humane Endothelzellen der Nabelschnurvene und humane korneale Endothelzellen) proliferierten auf den angebotenen Zellkultursubstraten bei 37°C und konnten durch senken der Temperatur geerntet werden.

info:eu-repo/classification/ddc/540

ddc:540

Développement d’une lentille cornéenne médicamentée

Latreille, Pierre-Luc

08 1900

L’utilisation de lentilles cornéennes peut servir à améliorer le profil d’administration d’un principe actif dans les yeux. Avec une efficacité d’administration de 5% par l’utilisation de gouttes, on comprend rapidement que l’administration oculaire doit être améliorée. Cette faible administration a donné naissance à plusieurs tentatives visant à fabriquer des lentilles cornéennes médicamentées. Cependant, à cause de multiples raisons, aucune de ces tentatives n’a actuellement été mise sur le marché. Nous proposons dans cette étude, une possible amélioration des systèmes établis par le développement d’une lentille cornéenne à base de 2-(hydroxyéthyle)méthacrylate (HEMA), dans laquelle des microgels, à base de poly N-isopropylacrylamide (pNIPAM) thermosensible encapsulant un principe actif, seront incorporé. Nous avons donc débuté par développer une méthode analytique sensible par HPCL-MS/MS capable de quantifier plusieurs molécules à la fois. La méthode résultante a été validée selon les différents critères de la FDA et l’ICH en démontrant des limites de quantifications et de détections suffisamment basses, autant dans des fluides simulés que dans les tissus d’yeux de lapins. La méthode a été validée pour sept médicaments ophtalmiques : Pilocarpine, lidocaïne, proparacaïne, atropine, acétonide de triamcinolone, timolol et prednisolone. Nous avons ensuite fait la synthèse des microgels chargés négativement à base de NIPAM et d’acide méthacrylique (MAA). Nous avons encapsulé une molécule modèle dans des particules ayant une taille entre 200 et 600 nm dépendant de la composition ainsi qu’un potentiel zêta variant en fonction de la température. L’encapsulation de la rhodamine 6G (R6G) dans les microgels a été possible jusqu’à un chargement (DL%) de 38%. L’utilisation des isothermes de Langmuir a permis de montrer que l’encapsulation était principalement le résultat d’interactions électrostatiques entre les MAA et la R6G. Des cinétiques de libérations ont été effectuées à partir d’hydrogels d’acrylamide chargés en microgels encapsulant la R6G. Il a été trouvé que la libération des hydrogels chargés en microgels s’effectuait majoritairement selon l’affinité au microgel et sur une période d’environ 4-24 heures. La libération à partir de ces systèmes a été comparée à des formules d’hydrogels contenant des liposomes ou des nanogels de chitosan. Ces trois derniers (liposomes, microgels et nanogels) ont présenté des résultats prometteurs pour différentes applications avec différents profils de libérations. Enfin, nous avons transposé le modèle développé avec les gels d’acrylamide pour fabriquer des lentilles de contact de 260 à 340 µm d’épaisseur à base de pHEMA contenant les microgels avec une molécule encapsulée devant être administrée dans les yeux. Nous avons modifié la composition de l’hydrogel en incorporant un polymère linéaire, la polyvinylpyrrolidone (PVP). L’obtention d’hydrogels partiellement interpénétrés améliore la rétention d’eau dans les lentilles cornéennes. L’encapsulation dans les microgels chargés négativement a donné de meilleurs rendements avec la lidocaïne et cette dernière a été libérée de la lentille de pHEMA en totalité en approximativement 2 heures qu’elle soit ou non encapsulée dans des microgels. Ainsi dans cette étude pilote, l’impact des microgels n’a pas pu être déterminé et, de ce fait, nécessitera des études approfondies sur la structure et les propriétés de la lentille qui a été développée. En utilisant des modèles de libération plus représentatifs de la physiologie de l’œil, nous pourrions conclure avec plus de certitude concernant l’efficacité d’un tel système d’administration et s’il est possible de l’optimiser. / The development of corneal contact lenses initially aimed to correct vision troubles but more recently targets to improve administration of ophthalmic drugs. Eye drops from ophthalmic solutions has a poor administration efficiency of 5% or less and is currently the most used method to deliver drugs to the eye. Such administration technique needs to be improved and contact lenses could be the solution according to many opticians. However, no marketed therapeutic contact lenses has been marketed up to date. In this project we have developed a model of a contact lens made of 2-(hydroxyethyl)methacrylate embedding microgels of poly N-isopropylacrylamide (pNIPAM), encapsulating a model drug. We first developed an analytical method capable to quantify simultaneously seven ophthalmic drugs: Pilocarpine, lidocaine, proparacaine, atropine, triamcinolone acetonide, timolol and prednisolone. This method was developed on a HPLC-MS/MS device and was validated according to FDA and ICH criteria. Using this method, we achieved very low detection and quantitation limits with high precision and accuracy in both simulated lachrymal fluids and in rabbit ocular tissues. Each seven drugs was validated using this method. We proceeded with the synthesis of negatively charged microgels of NIPAM using methacrylic acid (MAA) as comonomer. Resulting size were ranging between 200-600 nm and zeta potential was found to increase (absolute value) with temperature. The microgels were used to encapsulate a model molecule, rhodamine 6G (R6G), in different medium and were loaded in the microgel up to 38% (drug loading, DL%). Using Langmuir isotherms to measure affinity and adsorption of R6G, it was found well correlated to MAA content in microgels, suggesting electrostatic interaction was the main parameter for drug loading. Release kinetics was performed using a model hydrogel of acrylamide embedding the R6G-loaded microgels. The measured release was found to follow an affinity-based mechanism for over 4-24 hours. The release kinetics were then compared to a formulation of liposomes and nanogels of chitosan embedded in hydrogel. All formulations exhibited interesting release profiles making them promising systems for different therapeutic applications. Finally, we changed the acrylamide gels for pHEMA designed to reproduce contact lenses containing drug-loaded microgels. The hydrogel composition, in terms of monomer / cross-linker ratio, was first optimized to fit contact lenses properties of 260-340 µm thick contact lenses. We also made use of semi-interpenetrated polyvinylpirrolidone (PVP) in the pHEMA hydrogel matrix to increase its water content. The highest DL% of negatively charged microgels were obtained using lidocaine and were used for release studies, where the total content of lidocaine was released in approximately 2 hours with and without microgels. In the end, this was a pilot study aiming to evaluate the potential of microgel usability in contact lenses. However, the impact of microgels on release was not fully conclusive. Additional studies should be undertaken to achieve a better comprehension and characterization of the release mechanism such as using more eye relevant physiological models. Such studies would provide further insights on the use of such materials for eye drug delivery and its applicability.

Lentilles cornéennes

Microgels

Libération contrôlée

HPLC-MS/MS

Nanostructures

Hydrogel

Corneal contact lenses

Controlled release

Développement de liquides synoviaux synthétiques bio-inspirés

Faivre, Jimmy

07 1900

No description available.

Ecouvillon moléculaire

Acide hyaluronique

Tribologie

Friction

Lubrification

Usure

Hydrogel

Articulations

Liquide synovial

Cartilage

Bottle-brush polymers

Tribology

Wear

Joints

Synovial fluid

Reticulação da poli (N-vinil-2-pirrolidona) e copolímeros por processos químicos / Poly (N-vinyl-2- pyrrolidone) and copolymers crosslinking by chemical process

Barros, Janaina Aline Galvão

05 October 2007

Hidrogéis são materiais poliméricos com habilidade em intumescer em água e fluidos biológicos sem, contudo, se dissolver. Devido às suas propriedades de maciez e biocompatibilidade, estes materiais têm tido um crescimento enorme na área de engenharia de tecido, encapsulamento de células e liberação de drogas. Este trabalho visa a produção de hidrogéis de poli(N-vinil-2-pirrolidona) e seus copolímeros a partir de reticulações químicas. Como metodologia alternativa de produção de hidrogéis de poli(N-vinil-2-pirrolidona), foi estudada a reticulação do PVP por reação de Fenton, sendo que as concentrações dos reagentes foram avaliadas a fim de produzir um hidrogel com características semelhantes aos hidrogéis de PVP por radiação ionizante. O grande diferencial desta metodologia foi a rápida cinética de gelificação apresentada, creditanto um potencial de aplicação inédito. A partir de reticulações químicas mais brandas, foi estudada a produção de hidrogéis de copolímeros de N-vinil-2-pirrolidona e aldeídos com quitosana, e íons divalentes. Além de estudadas as propriedades relativas ao hidrogel tais como: conteúdo de gel, grau de intumescimento, cinética de reação, citotoxicidade, densidade de reticulação, massa molar média entre as ligações cruzadas e tamanho de poro. / Hydrogels are polymeric materials that have the ability to absorb water and biological fluids in their three-dimensional polymeric matrix without dissolution. Due to their interesting properties, such as softness and biocompatibility, there is a growing interest in their application in tissue engineering, cell encapsulation and drug delivery system. This work aims at the study of hydrogels from poly(N-vinyl-2-pyrrolidone) and copolymers produced by chemical crosslinking methods. PVP crosslinking by Fenton reaction was studied as an alternative methodology to produce poly(N-vinyl-2-pyrrolidone) hydrogels. The reagents concentrations were evaluated, in order to produce a hydrogel with the same properties of the hydrogels prepared by high energy radiation. The advantage of this methodology is its fast jellification kinetic, warranting new potential unprecedented applications. From mild chemical crosslinking methods, the production of hydrogels from copolymers of N-vinyl-2-pyrrolidone and aldehydes with chitosan, and divalent ions was studied. Hydrogels properties as: gel content, swelling ratio, reaction kinetics, cytotoxicity, crosslinking density, molecular weight and pore size were investigated.

Copolímeros

Copolymers

Crosslinking

Fenton reaction

Hidrogel

Hydrogel

Poli(N-vinil-2-pirrolidona)

Polímeros

Poly(N-vinyl-2-pyrrolidone)

Polymers

Reação de Fenton

Reticulação

Desenvolvimento de hidrogéis inteligentes como meio de liberação controlada de fármaco / Development of smart hydrogels as controlled drug delivery systems

Takahashi, Suélen Harumi

18 August 2014

O objetivo principal deste trabalho foi a formação de um material que possa responder aos estímulos pH e elétrico na liberação controlada de fármaco. Assim, hidrogéis condutores foram obtidos pela combinação do hidrogel de ácido acrílico com o polímero condutor polipirrol. O polipirrol foi eletroquimicamente polimerizado no interior do hidrogel e o material obtido (AA-PPi) conservou a propriedade de intumescimento que é característico dos hidrogéis e a eletroatividade, dos polímeros condutores. Além disso, o grau de intumescimento variou com a força iônica e pH. A liberação da safranina pelo hidrogel de AA-PPi foi estudada combinando os estímulos de pH e potencial e o resultado mais interessante foi a obtenção do perfil cuja velocidade de liberação foi constante, indicando uma cinética de ordem zero. Liberação do tipo liga-desliga foi estudada com o intuito de verificar se o AA-PPi pode ser controlado por pH e/ou potencial elétrico. Foi observado que dependendo da combinação de pH e potencial, o hidrogel pode ser controlado, por variação de pH ou de potencial elétrico. Outro hidrogel sintetizado foi o do hidrogel de AA contendo o poli(3,4-etilenodioxitiofeno):poli(estireno sulfonado), este por sua vez foi polimerizado quimicamente. Porém os resultados preliminares indicaram incompatibilidade entre os dois polímeros / The aim of this work was to obtain a material that can respond to both pH and potential stimuli for drug release. Thus, eletroactive hydrogels were synthesized by the combination of the properties of acrylic acid hydrogels with the conducting polymer polypyrrole. The polypyrrole was electrochemically polymerized into the hydrogel (AA-PPi), and the material retained the swelling properties that is characteristic of hydrogels and electroactivity of conducting polymers. Furthermore, the degree of swelling varied with the ionic strength and pH. The safranin release by AA-PPi was mensured under the combination of pH and potential stimuli and the most interesting result was obtained from the linear profile indicating a zero-order kinetics. On-off release profile was studied in order to verify if the AA-PPi can be controled by pH and/or electric potential. Depending on the combination of pH or electrochemical potential, the hydrogel had pH or electrochemical control. Other hydrogel synthesized was from AA hydrogel containing poly(3,4- ethylenedioxythiophene):polystyrene sulfonate, this, in other hand, was chemically polymerized. However, preliminary results indicate incompatibility between the two polymers

Ácido acrílico

Acrylic acid

Conducting polymer

Controlled drug delivery

Electrochemistry

Eletroquímica

Hidrogel

Hydrogel

Liberação controlada

Multi-estímulo

Multi-stimuli

Polímero condutor

Polipirrol

Polypyrrole

Biological Applications of Elastin- and Mussel-Inspired Polymers

Sydney E. Hollingshead (5929754)

03 January 2019

<div>Wounds are created in soft and hard tissue through surgery or disease. As the wound heals, the tissue is held in place using sutures or staples for soft tissue or plates, pins, or screws for hard tissues. These fixation methods inherently damage the surrounding healthy tissue. Surgical adhesives are a non-damaging alternative to these methods. In order to be effective, surgical adhesives must be biocompatible,</div><div>adhere strongly in a moist environment, and have mechanical properties similar to those of the native tissue.</div><div><br></div><div><div>To address the design criteria for surgical adhesives, we look to nature to find inspiration from compounds that provide these properties. Mussels use catechol-based</div><div>molecules to adhere to surfaces in wet and turbulent environments. Incorporating catechols into polymer systems can provide adhesion even in moist biological environments.</div><div>Mimics of elastomeric proteins from soft tissue can be used as backbones for soft and flexible adhesive systems. In particular, elastin-inspired proteins have a well-defined modular sequence that allows for a range of design choices. In this work, we explored the behavior of elastin- and mussel-inspired natural and synthetic polymers in biologically relevant environments.</div></div><div><br></div><div><div>First, the cytocompatibility of a catechol-containing poly(lactic acid) (cPLA) hard tissue adhesive was studied. The cPLA polymer was reacted with iron- or periodatebased</div><div>crosslinkers and compared to PLA. Fibroblasts grown directly on cPLA or cultured with leachate from cPLA had high viability but slower growth than cells on PLA. The periodate crosslinker was significantly cytotoxic, and cells grown on cPLA crosslinked with periodate had reduced metabolism and slowed growth. Cells grown on or in leachate from iron-crosslinked cPLA had similar viability, metabolism, and growth to cells on or in leachate from cPLA. The iron-crosslinked cPLA is a promising</div><div>cytocompatible adhesive for hard tissue applications.</div></div><div><br></div><div><div>Second, two elastin-like proteins (ELP) were developed that had pH-sensitive properties in solution and when crosslinked into hydrogels. Both ELPs had a large number of ionizable tyrosine and lysine residues, and one design also had a large number of ionizable histidine and aspartic acid residues. The stiffness of the hydrogels was maximized at pH values near the isoelectric point of the protein. The stoichometric ratio of crosslinker used affected hydrogel stiffness but did not significantly alter the pH-sensitivity of the gel. The crosslinked gel shrank when swelled at physiological pH. The pH-sensitive mechanical properties of hydrogels made from the two ELPs did not vary significantly. The tyrosine and lysine residues in one ELP were also</div><div>chemically blocked through acetylation to lower the isolectric point of the protein. The acetylated hydrogels had maximum stiffness at a pH near the isoelectric point of the acetylated ELP. The stiffness of both the native and acetylated gels were within the range of soft tissue. Through a combination of crosslinker ratio and chemical modification, the pH-responsive properties of the elastin-inspired hydrogels could be tuned.</div></div><div><br></div><div><div>Finally, adhesive proteins were created that were inspired by both elastin and mussels. An ELP was modified to include catechol groups (mELP). The ELP and mELP were optimized for adhesive use in a soft tissue system. A warm and humid environment was used to study the adhesion of these proteins on pig skin. Iron and (hydroxymethyl) phosphine crosslinkers increased the adhesive strength of both proteins, and periodate increased the adhesive strength of mELP. The adhesive strengths of the proteins were maximized when mELP was mixed with iron or when either protein were mixed with (hydroxymethyl)phosphine crosslinkers. These maximized adhesives were 12-17 times stronger than a commercially available sealant. In addition,</div><div>the iron and mELP adhesive formulation achieved high adhesive strengths even when cured for only ten minutes. This adhesive formula shows promise for adhesive</div><div>applications on soft tissue.</div></div>

Elastin-Like Polypeptide (ELP)

Mussel-Inspired Adhesion

L-3,4-dihydroxyphenylalanine (DOPA)

Surgical Adhesive

Hydrogel

pH-Sensitive

Smart materials.

Poly(Lactic Acid) (PLA)

Cytocompatibility

Thermomécanique des milieux continus : modèles théoriques et applications au comportement de l'hydrogel en ingénierie biomédicale / Continuum thermomechanics : theoretical models and applications on hydrogel behaviour in biomedical engineering

Santatriniaina, Nirina

06 October 2015

Dans la première partie on propose un outil mathématique pour traiter les conditions aux limites dynamiques d'un problème couplé d'EDP. La simulation avec des conditions aux limites dynamiques nécessite quelques fois une condition de "switch" en temps des conditions aux limites de Dirichlet en Neumann. La méthode numérique (St DN) a été validée avec des mesures expérimentales pour le cas de la contamination croisée en industrie micro-électronique. Cet outil sera utilisé par la suite pour simuler le phénomène de « self-heating » dans les polymères et les hydrogels sous sollicitations dynamiques. Dans la deuxième partie, on s'intéresse à la modélisation du phénomène de self-heating dans les polymères, les hydrogels et les tissus biologiques. D'abord, nous nous sommes focalisés sur la modélisation de la loi constitutive de l'hydrogel de type HEMA-EGDMA. Nous avons utilisé la théorie des invariants polynomiaux pour définir la loi constitutive du matériau. Ensuite, nous avons mis en place un modèle théorique en thermomécanique couplée d'un milieu continu classique pour analyser la production de chaleur dans ce matériau. Deux potentiels thermodynamiques ont été proposés et identifiés avec les mesures expérimentales. Une nouvelle forme d'équation du mouvement non-linéaire et couplée a été obtenue (un système d'équation aux dérivées partielles parabolique et hyperbolique non-linéaire couplé avec des conditions aux limites dynamiques). Dans la troisième partie, une méthode numérique des équations thermomécaniques (couplage parabolique-hyperbolique) pour les modèles a été utilisée. Cette étape nous a permis, entre autres, de résoudre ce système couplé. La méthode est basée sur la méthode des éléments finis. Divers résultats expérimentaux obtenus sur ce phénomène de self-heating sont présentés dans ce travail suivi d'une étude de corrélations des résultats théoriques et expérimentaux. Dans la dernière partie de ce travail, ces divers résultats sont repris et leurs conséquences sur la modélisation du comportement de l'hydrogel naturel utilisé dans le domaine biomédical sont discutées. / In the first part, we propose a mathematical tool for treating the dynamic boundary conditions. The simulation within dynamic boundary condition requires sometimes ''switch'' condition in time of the Dirichlet to Neumann boundary condition (St DN). We propose a numerical method validated with experimental measurements for the case of cross-contamination in microelectronics industry. This tool will be used to compute self-heating in the polymers and hydrogels under dynamic loading. In the second part we focus on modeling the self-heating phenomenon in polymers, hydrogels and biological tissues. We develop constitutive law of the hydrogel type HEMA-EGDMA, focusing on the heat e.ects (dissipation) in this material. Then we set up a theoretical model of coupled thermo-mechanical classic continuum for a better understanding of the heat production in this media. We use polynomial invariants theory to define the constitutive law of the media. Two original thermodynamic potentials are proposed. Original non-linear and coupled governing equations were obtained and identified with the experimental measurements (non-linear parabolic-hyperbolic system with the dynamic boundary condition). In the third part, numerical methods were used to solve thermo-mechanical formalism for the model. This step deals with a numerical method of a coupled partial di.erential equation system of the self-heating (parabolic-hyperbolic coupling). Then, is step allows us, among other things, to propose an appropriate numerical methods to solve this system. The numerical method is based on the finite element methods. Numerous experimental results on the self-heating phenomenon are presented in this work together with correlations studies between the theoretical and experimental results. In the last part of the thesis, these various results will be presented and their impact on the modeling of the behavior of the natural hydrogel used in the biomedical field will be discussed.

Thermomécanique

Self-Heating

Hydrogel

Tissus biologiques

Edp

Couplageparabolique-Hyperbolique

Calorimétrie

Caractérisations

Méthodes numériques

Thermomechanics

Self-Heating

Hydrogels

Biological tissues

PDEs

Parabolic-hyperbolic coupling

Characterizations

Numerical methods

Control of the rheological properties of hydrogels made by self-assocation of amphiphilic copolymers, blocks and grafts, anionics or cationics / Contrôle des propriétés rhéologiques d'hydrogels formés par auto-assemblage de copolymères amphiphiles, à blocs et greffés, anioniques ou cationiques

Lauber, Lionel

19 September 2016

L’objectif de ce travail était de contrôler les propriétés rhéologiques de solutions aqueuses de copolymères amphiphiles. Dans l’eau, ces copolymères s’auto-associent et leurs propriétés peuvent être contrôlées en partie par leur dynamique d’échange. Il avait précédemment était montré que cette dynamique pouvait être contrôlée par le pH et la quantité d’unités acide acrylique dans des triblocs BAB (THx) où le bloc A est du poly(acide acrylique) (PAA) et les blocs B sont des copolymères statistiques (MHx) d’acrylate de n-butyle (nBA) et d’acide acrylique (AA). Tout d’abord, l’étude de l’auto-association en solution des blocs B seuls (MHx) a montré un lien fort entre leur agrégation et celle des diblocs de type BA (DHx). Cette agrégation est contrôlée par la quantité de charge des blocs B. Par la suite, des mélanges de triblocs (BAB) THx contenant différentes proportions (x) d’unités AA ont permis la formation de réseaux hybrides dont les propriétés rhéologiques sont maîtrisées par formulation plutôt que via la chimie. Des propriétés rhéologiques similaires aux triblocs BAB (THx) ont été obtenues avec des copolymères greffés possédant un squelette hydrophile PAA et des greffons B. Leurs propriétés rhéologiques sont principalement contrôlées par la structure chimique des blocs B, mais aussi par le taux de greffage. Ces copolymères greffés devraient être plus simples à obtenir à l’échelle industrielle que des triblocs. Pour finir, l’approche consistant à incorporer des unités hydrophiles dans les blocs hydrophobes de copolymères amphiphiles pour en contrôler la dynamique d’échange a été appliquée avec succès à des copolymères à base de méthacrylate de diméthylaminoéthyle et de méthacrylate de n-butyle. Leurs propriétés rhéologiques peuvent être contrôlées à nouveau par le pH, mais dans une gamme différente des polymères à base d’acide acrylique, et aussi dans une certaine mesure par la température. / The aim of this work was to control the rheological properties of aqueous solutions of amphiphilic copolymers. In water, these copolymers self-assemble and part of their properties can be controlled by their dynamic of exchange. As previously reported, the exchange dynamics can be controlled by the pH and the acrylic acid (AA) content for BAB triblock copolymers (THx) consisting of a poly(acrylic acid) (PAA) A block and two statistical B blocks (MHx) of n-butyl acryle (nBA) and AA.First, the study of the self-association of B blocks (MHx) alone showed a strong relationship between their aggregation and the one of BA diblocks (DHx). This aggregation was mainly controlled by the amount of charges within the B blocks.Then, mixtures of BAB triblocks (THx) with different contents of AA units, x, formed hybrid networks the rheological properties of which were controlled by formulation rather than chemistry.Similar rheological properties were obtained using graft copolymers consisting of a PAA hydrophilic backbone and B grafts. Their rheological properties were mainly controlled by the chemical structure of the B grafts and by the grafting density. Such graft copolymers should be easier to produce at an industrial scale than triblock copolymers.To finish, the strategy consisting of incorporating hydrophilic units inside the hydrophobic blocks of amphiphilic copolymers to control their exchange dynamics was successfully applied to copolymers made of dimethylaminoethyl methacraylate and n-butyl methacrylate. Their rheological properties were controlled by the pH on a different pH-range than the AA based polymers, and, to some extent, by the temperature.

Rhéologie

Auto-association

Hydrogel

Copolymère amphiphile

Diffusion de la lumière

Thermosensible

Acide acrylique

DMAEMA

Rheology

Self-assembly

Hydrogels

Amphiphilic copolymers

Light scattering

Thermosensitive

Acrylic acid

541.345 13

Enzymatically initiated synthesis of biomimetic receptors based on molecularly imprinted polymers by free radical polymerization / Synthèse de récepteurs biomimétiques basés sur les polymères à empreintes moléculaires par polymérisation radicalaire libre initiée par catalyse enzymatique

Daoud Attieh, Mira

01 April 2016

Depuis de nombreuses années, l’utilisation d’enzyme pour la synthèse de polymères naturels ou synthétiques a largement été développée en tant que procédé alternatif plus vert et plus respectueux de l’environnement. En effet, comparée aux méthodes conventionnelles de synthèse, les enzymes offrent une sélectivité élevée, une capacité à réagir dans des conditions de réaction douces, ainsi que la possibilité de recyclage du biocatalyseur. D’autre part, les polymères à empreintes moléculaires (MIPs) sont des matériaux synthétiques avec des propriétés de reconnaissance moléculaire spécifique envers une molécule cible. Récemment, les MIPs ont été utilisés dans les applications environnementales et biomédicales de part leur propriétés de reconnaissance moléculaire, leur spécificité et sélectivité. Cependant, leur application reste limitée en raison de leur faible biocompatibilité et de la présence de résidu de polymérisation potentiellement nocif. Ce travail de thèse a pour objectif de proposer une méthode alternative pour la synthèse de MIPs basée sur le concept de chimie verte. La peroxydase de raifort (HRP) est utilisée pour initier la co-polymérisation en milieux aqueux de monomères fonctionnels méthacrylates et d’agents réticulants en catalysant la génération des radicaux libres. Différents hydrogels ont été synthétisés et caractérisés, en particulier une cytotoxicité plus faible a été obtenue comparée à celle des polymères synthétisés traditionnellement. La synthèse a été optimisée afin de pouvoir contrôler la taille des particules et le rendement de polymérisation. Des MIPs sous forme de nanoparticules ont été préparés en milieu aqueux pour plusieurs molécules de faible poids moléculaire ainsi que pour des protéines par polymérisation radicalaire libre initiée par HRP. L’effet de la méthode d’initiation a été évalué en comparant les propriétés de ces MIPs à ceux préparées par les méthodes traditionnellement. L’immobilisation de l’HRP a été aussi effectuée pour synthétiser des hydrogels et des MIPs. L’enzyme immobilisée a pu être réutilisée pour synthétiser des MIPs avec les mêmes performances en termes de morphologie, rendement, spécificité et sélectivité. Ces nouveaux matériaux offrent de nombreuses perspectives pour des applications environnementales et biomédicales. / Enzyme-catalyzed synthesis of natural and synthetic polymers has been developed since several decades, as an eco-friendly process. Compared to the conventional methods, enzymes offer high selectivity, ability to operate under mild conditions and to recycle the catalyst. On the other hand, molecularly imprinted polymers (MIPs) are synthetic materials with specific recognition properties for target molecules. They have recently attracted increasing attention in environmental and newly in biomedical applications for their specificity and selectivity. However, concerns about MIP toxicity for human and environment safety are of great importance. Herein, carrying forward the concept of green chemistry, an enzyme-mediated synthesis approach is described to prepare molecularly imprinted nanoparticles (MIP-NPs) in aqueous media. Horseradish peroxidase (HRP) is used to initiate the polymerization of methacrylate-based monomers and cross-linkers by catalyzing the generation of free radicals. Different hydrogels are synthesized and characterized. “Greener” hydrogels are obtained with lower cytotoxicity than that of polymers synthesized by traditional way. The hydrogels synthesis is optimized in order to control the particles sizes and polymerization yields. Moreover, water-compatible MIP nanoparticles for the recognition of different small molecules and proteins are prepared in aqueous media by HRP-initiated free radical polymerization and compared to MIPs prepared by the thermal or photopolymerization methods. HRP immobilization is also performed for hydrogels synthesis as well as MIP preparation. The reusability of immobilized enzyme is investigated for the preparation of several MIP batches with the same morphology, yield as well as good specificity and selectivity. We believe that this new synthesis method for MIPs will provide new opportunities to enlarge the use of molecular imprinting technology in biomedical and environmental applications.

Hydrogel

Polymérisation radicalaire libre

Catalyse enzymatique

Peroxydase de raifort

Chimie verte

Molecularly imprinted polymers

Water-compatible nanoparticles

Free radical polymerization

Enzymatic catalysis

Horseradish peroxidase (HRP)

Reticulação da poli (N-vinil-2-pirrolidona) e copolímeros por processos químicos / Poly (N-vinyl-2- pyrrolidone) and copolymers crosslinking by chemical process

Janaina Aline Galvão Barros

05 October 2007

Hidrogéis são materiais poliméricos com habilidade em intumescer em água e fluidos biológicos sem, contudo, se dissolver. Devido às suas propriedades de maciez e biocompatibilidade, estes materiais têm tido um crescimento enorme na área de engenharia de tecido, encapsulamento de células e liberação de drogas. Este trabalho visa a produção de hidrogéis de poli(N-vinil-2-pirrolidona) e seus copolímeros a partir de reticulações químicas. Como metodologia alternativa de produção de hidrogéis de poli(N-vinil-2-pirrolidona), foi estudada a reticulação do PVP por reação de Fenton, sendo que as concentrações dos reagentes foram avaliadas a fim de produzir um hidrogel com características semelhantes aos hidrogéis de PVP por radiação ionizante. O grande diferencial desta metodologia foi a rápida cinética de gelificação apresentada, creditanto um potencial de aplicação inédito. A partir de reticulações químicas mais brandas, foi estudada a produção de hidrogéis de copolímeros de N-vinil-2-pirrolidona e aldeídos com quitosana, e íons divalentes. Além de estudadas as propriedades relativas ao hidrogel tais como: conteúdo de gel, grau de intumescimento, cinética de reação, citotoxicidade, densidade de reticulação, massa molar média entre as ligações cruzadas e tamanho de poro. / Hydrogels are polymeric materials that have the ability to absorb water and biological fluids in their three-dimensional polymeric matrix without dissolution. Due to their interesting properties, such as softness and biocompatibility, there is a growing interest in their application in tissue engineering, cell encapsulation and drug delivery system. This work aims at the study of hydrogels from poly(N-vinyl-2-pyrrolidone) and copolymers produced by chemical crosslinking methods. PVP crosslinking by Fenton reaction was studied as an alternative methodology to produce poly(N-vinyl-2-pyrrolidone) hydrogels. The reagents concentrations were evaluated, in order to produce a hydrogel with the same properties of the hydrogels prepared by high energy radiation. The advantage of this methodology is its fast jellification kinetic, warranting new potential unprecedented applications. From mild chemical crosslinking methods, the production of hydrogels from copolymers of N-vinyl-2-pyrrolidone and aldehydes with chitosan, and divalent ions was studied. Hydrogels properties as: gel content, swelling ratio, reaction kinetics, cytotoxicity, crosslinking density, molecular weight and pore size were investigated.

Copolímeros

Hidrogel

Poli(N-vinil-2-pirrolidona)

Polímeros

Reação de Fenton

Reticulação

Copolymers

Crosslinking

Fenton reaction

Hydrogel

Poly(N-vinyl-2-pyrrolidone)

Polymers