Synthèse de particules composites anisotropes polymère / inorganique par polymérisation RAFT en émulsion / Synthesis of anisotropic polymer / inorganic composite particles via RAFT-mediated emulsion polymerization

Cenacchi Pereira, Ana Maria

05 June 2014

Ces travaux décrivent l'élaboration de latex hybrides de polymère / nanotubes d'Imogolite et polymère / nanofeuillets d'hydroxydes doubles lamellaires (HDL) en milieu aqueux dispersé. Les deux charges inorganiques ont été choisies pour leurs propriétés thermiques, mécaniques et pour leur anisotropie de forme, ce qui pourrait permettre l'élaboration de films nanostructurés. Les latex ont été synthétisés par une stratégie originale basée sur le procédé de polymérisation RAFT en émulsion. Cette stratégie consiste à utiliser des copolymères hydrophiles (macroRAFT), comportant à la fois des unités d'acide acrylique et un groupe trithiocarbonate terminal, comme agents de couplage et stabilisants. Dans un premier temps, ces macroRAFTs ont été adsorbés à la surface des nanoparticules inorganiques, puis l'extension de ces chaînes a été réalisée par la polymérisation d'un monomère hydrophobe selon un procédé semi-batch. Des nanotubes d'Imogolite décorés de particules de latex ou des nanotubes d'Imogolite encapsulés ont été obtenus, selon les conditions de synthèse adoptées. L'effet de différents paramètres sur la morphologie finale des particules hybrides a été étudié. La nature de l'agent macroRAFT s'est avérée être un paramètre clé pour le succès de l'encapsulation. La même stratégie a été utilisée en vue de l'encapsulation des HDL. Quelles que soient les conditions investiguées, des latex stables contenant des particules d'HDL encapsulées par du polymère ont été formés. Dans tous les cas, la morphologie des latex nanocomposites a été caractérisée par MET et cryo-MET et reliée à la méthode de modification de la surface et aux conditions de polymérisation. Enfin, les propriétés mécaniques ainsi que la microstructure des films hybrides de polymère / nanotubes d'Imogolite ont été étudiées par DMA et MET, respectivement, et reliées à la morphologie des particules de latex / This work describes the elaboration of hybrid latexes of polymer / Imogolite nanotubes and polymer / layered double hydroxyde (LDH) nanosheets in aqueous dispersed media. The two inorganic materials were chosen as fillers for their thermal and mechanical properties and especially for their shape anisotropy, which could lead to the formation of nanostructured films. The latexes were synthesized through an original polymerization strategy based on the RAFT process in emulsion. The strategy consists in the use of hydrophilic random copolymers, containing acrylic acid units and a thiocarbonylthio end group, as both coupling agents and stabilizers. These copolymers, herein named macroRAFT agents, were tethered to the surface of the inorganic nanoparticles and chain extended by the polymerization of a hydrophobic monomer in a semi-batch process. Polymer-decorated Imogolite nanotubes or encapsulated nanotube bundles were obtained according to the process conditions. The effect of different parameters on the final morphology and latex stability was studied, and the macroRAFT nature was proven to be the key factor to achieve encapsulation. The same strategy was then applied to LDH materials. The different conditions tested all led to the encapsulation of the nanosheets. In both cases, the morphology of the nanocomposite latexes was characterized by TEM and cryo-TEM and correlated with the surface modification and the experimental conditions. The mechanical properties and the microstructure of hybrid films of polymer / Imogolite were studied by DMA and TEM, respectively, and correlated with the latex particles morphology

Nanotubes

Imogolite

Encapsulation

RAFT

Latex

Nanocomposites

Hydroxydes double lamellaires (HDL)

Nanotubes

Imogolite

Encapsulation

RAFT

Latexes

Nanocomposites

Layered double hydroxides (LDH)

546

Développement de biocapteurs ampérométriques pour la détermination de l’activité de la transcétolase et pour la détection d’inhibiteurs de cette enzyme / Development of amperometric biosensors for the determination of the activity of transketolase and for the detection of inhibitors of this enzyme

Touisni, Nadia

13 December 2013

Depuis peu, des travaux ont montré que chez l’Homme, la transcétolase (TK, EC 2.2.1.1.) dont le cofacteur est la thiamine diphosphate (forme active de la vitamine B1), est une enzyme impliquée dans de nombreuses maladies telles que, le diabète, certains cancers, ou encore des maladies neurologiques, comme le syndrome de Wernicke-Korsakoff et la maladie d’Alzheimer. Pour des applications thérapeutiques, des inhibiteurs spécifiques de cette enzyme sont actuellement conçus et synthétisés dans les milieux académiques et industriels. Afin de déterminer l’activité de la TK (dans un but de diagnostic) d’une part, et de détecter des inhibiteurs potentiels de cette enzyme (dans un but thérapeutique) d’autre part, il est nécessaire de disposer de tests alliant rapidité, sensibilité et faible coût. Nous avons envisagé d’utiliser des biocapteurs ampérométriques qui combinent l’ensemble de ces avantages, et qui, de plus, n’ont jamais été mis en oeuvre avec la TK. Pour la détermination de l’activité des TK d’E. coli et humaine libres en solution, nous avons tout d’abord élaboré un premier biocapteur à galactose oxydase (GAOx, EC 1.1.3.9), dans lequel cette enzyme est immobilisée sur la laponite. Puis, dans le but de detecter des inhibiteurs de la TK, avec un système réutilisable, nous avons developpé un biocapteur à GAOx-TK d’E. coli, les deux enzymes étant co-immobilisées à la surface de l’électrode. Pour cela la TK a été immobilisée dans des Hydroxydes Doubles Lamellaires (HDL). Ce biocapteur bicouche et bi-enzymatique GAOx-TK, nous a permis d’évaluer l’effet d’inhibiteurs, tels que différents analogues du cofacteur et de substrats pris comme modèles. / Some recent studies have shown that human transketolase (TK, EC 2.2.1.1.), which thiamine diphosphate (active form of vitamin B1) is the cofactor, is involved in numerous disease such as diabete, some cancers and neurodegenerative diseases as Alzheimer’s disease and Wernicke-Korsakoff syndrome. For therapeutic purposes, TK inhibitors have been designed and synthesized in both academic and industrial fields. To determine TK activity (diagnostic) on the one hand, and to detect potential inhibitors of this enzyme (therapeutic) on the other hand, it is necessary to develop fast, sensitive and low cost assays. In this context, we designed some original amperometric biosensors that combine these advantages and were never studied with TK from now. We performed a first galactose oxidase (GAOx, EC 1.1.3.9) biosensor for E. coli and human TK activities detection. For that purpose, GAOx was immobilized on laponite matrix. Then, we designed a GAOx-TK biosensor by co-immobilization of GAOX and TK on the electrode surface that enabled the detection TK inhibitors with a reusable system. Thence, TK was immobilized in Layered Double Hydroxides (HDL). This bilayer and bi-enzymic biosensors, allowed us to determine the inhibitor potencies of several cofactors and substrates analogues as model compounds.

Biocapteurs ampérométriques

Transcétolase

Thiamine diphosphate

Galactose oxydase

Inhibiteurs

Immobilisation d’enzymes

Hydroxydes Doubles Lamellaires (HDL)

Amperometric biosensor

Transketolase

Thiamine diphosphate

Galactose oxidase

Inhibitors

Enzyme immobilization

Layered Double Hydroxides (LDH)

Materiais derivados de hidróxidos duplos lamelares: síntese, caracterização e aplicação em adsorção e processos avançados de oxidação / Layered double hydroxides-derived materials: synthesis, characterization and application in adsorption and advanced oxidation processes

Santos, Rodrigo Morais Menezes dos [UNESP]

15 January 2016

Submitted by RODRIGO SANTOS (rodrigo_ilct@yahoo.com.br) on 2016-01-27T16:19:53Z No. of bitstreams: 1 Dissertação Rodrigo Morais Menezes dos Santos.pdf: 4136391 bytes, checksum: 50ec17cef563517b2a5199c9c72d9a0f (MD5) / Approved for entry into archive by Sandra Manzano de Almeida (smanzano@marilia.unesp.br) on 2016-01-27T18:53:38Z (GMT) No. of bitstreams: 2 santos_rmm_me_araiq_int.pdf: 4136391 bytes, checksum: 50ec17cef563517b2a5199c9c72d9a0f (MD5) santos_rmm_me_araiq_par.pdf: 1040758 bytes, checksum: a18d1d9fa74ec9c42cb002b3084f4a61 (MD5) / Made available in DSpace on 2016-01-27T18:53:38Z (GMT). No. of bitstreams: 2 santos_rmm_me_araiq_int.pdf: 4136391 bytes, checksum: 50ec17cef563517b2a5199c9c72d9a0f (MD5) santos_rmm_me_araiq_par.pdf: 1040758 bytes, checksum: a18d1d9fa74ec9c42cb002b3084f4a61 (MD5) Previous issue date: 2016-01-15 / Fundação de Amparo à Pesquisa do Estado de São Paulo (FAPESP) / A contaminação de recursos hídricos por diversos poluentes orgânicos, como os corantes têxteis, tem causado sérios problemas ambientais. Alguns processos de descontaminação utilizam materiais sólidos para adsorção/sorção, com características apropriadas para a implantação em escala industrial, apresentando alta eficiência e baixo custo. Os Processos Avançados de Oxidação (AOP), como a fotocatálise heterogênea, também têm sido empregados na descontaminação de águas, convertendo os poluentes orgânicos em substâncias mais facilmente degradáveis, inertes ou inofensivas. Materiais multifuncionais como os Hidróxidos Duplos Lamelares (HDL) e seus derivados se mostram promissores tanto em processos adsortivos como fotocatalíticos. No presente trabalho foi dado enfoque ao processo de adsorção de um azocorante têxtil, utilizando HDL do sistema ZnAl-CO3 e o óxido misto obtido no tratamento térmico a 450°C. Os materiais apresentaram características interessantes e alta capacidade de remoção do corante. As isotermas de adsorção apresentaram boa correlação com o modelo de Langmuir e o cálculo de seus parâmetros revelou que a capacidade máxima adsortiva do material calcinado foi cerca de 6 vezes superior ao material não calcinado, 1587,1 mg⋅g-1 e 261,8 mg⋅g-1, respectivamente. A maior capacidade de adsorção/sorção foi atribuída ao melhoramento das propriedades texturais e ao comportamento da “regeneração” da estrutura HDL pelo precursor calcinado. Os resultados revelaram que o controle cinético do processo é uma etapa de adsorção química, e os parâmetros termodinâmicos calculados mostraram que o processo de adsorção é espontâneo e endotérmico. Os experimentos de conversão fotocatalítica de corante mostraram que os derivados da calcinação dos HDL são materiais promissores para serem utilizados nos AOP. A formação do nanocompósito ZnAl2O4/ZnO no material calcinado a 850°C, mostrou os melhores resultados de conversão, pela estratégia de acoplamento de bandas para separação de cargas, que diminui os problemas relacionados com a recombinação dos portadores de carga, além da maior absorbância no UV. Dessa forma, os resultados obtidos mostram a multifuncionalidade desses materiais, e fornecem novas evidências sobre a reconstrução de HDL pelo “efeito memória”, tópico de intensa discussão na literatura. / The contamination of water resources by several organic pollutants, including textile dyes, which have caused serious environmental problems. Solid materials for adsorption with appropriate features to be employed in industrial scale, such as high efficiency and low cost have been used in some decontamination processes. The Advanced Oxidation Processes (AOP) including heterogeneous photocatalysis, have also been used in water treatment, converting the organic pollutants into easily degradable, inert or harmless substances. Multifunctional materials, such as the Layered Double Hydroxides (LDH) and their derivatives, show potential in both adsorptive and photocatalytic processes. In this work the textile azo dye adsorption process using a ZnAl-CO3 LDH and the mixed oxide obtained from thermal treatment at 450 °C were focused. The materials presented interesting features and high removal capacity for the dye. The adsorption isotherms showed good correlation with the Langmuir isotherm model and the calculated parameters revealed that the maximum adsorption capacity of the calcined material was about 6 times higher than the non-calcined material, 1587.1 mg⋅g-1 and 261.8 mg⋅g-1, respectively. The higher adsorption capacity was assigned to the improvement of the textural properties and to the LDH-structure recovery from the calcined precursor. The results showed kinetic control of the process is a chemical adsorption step, and the calculated thermodynamic parameters showed the adsorption process is spontaneous and endothermic. The dye photocatalytic conversion experiments presented that the derivatives of the LDH calcination are promising materials to be used in the AOP. The formation of a ZnAl2O/ZnO nanocomposite from calcination at 850 °C showed the best conversion results from the coupling semiconductors for charge separation strategy that diminish some problems associated with charge carrier recombination and its higher UV absorbance. Thus, the results show the multi-functionality of these materials, giving some light to the discussion about LDH recovery by "memory effect" that remains a topic of intense debate in the literature. / FAPESP: 2013/25043-4

Hidróxidos Duplos Lamelares (HDL)

Adsorção/Sorção

Processos Avançados de Oxidação (AOP)

Regeneração

Efeito memória

Layered Double Hydroxides (LDH)

Adsorption

Advanced Oxidation Process (AOP)

Recovery

Memory effect

Nouveaux matériaux biohybrides multifonctionnels pour la biocatalyse / New multifunctional biohybrid materials for biocatalysis

Mahdi, Rima

11 December 2015

Ces travaux de thèse pluridisciplinaires à l‘interface entre biocatalyse et nanomatériaux visent la conception de matériaux biohybrides innovants par assemblage dans des conditions douces de matériaux inorganiques de type hydroxydes doubles lamellaires (HDL) avec des enzymes. La première partie de ce mémoire est consacrée à la caractérisation des interactions physico-chimiques entre les HDL et la fructose-6-phosphate aldolase (FSA) catalysant la formation stéréosélective de liaisons C-C pour conduire à des polyols chiraux. Les structures lamellaires HDL permettent un confinement efficace de systèmes enzymatiques grâce à leur structure bidimensionnelle poreuse, leurs propriétés physico-chimiques favorables à l‘échange ionique et leur biocompatibilité. Différentes stratégies d‘immobilisation de la FSA dans des matrices d‘HDL ont été explorées, le taux d‘immobilisation et l‘activité biocatalytique étant fortement dépendant de la méthode d‘assemblage et de la nature des phases HDL. Le taux d‘immobilisation de l‘enzyme obtenu par coprécipitaton est supérieur à celui obtenu par adsorption. Dans une deuxième partie, un bioréacteur a été élaboré par un assemblage hiérarchisé constitué de la FSA, de nanoplaquettes d‘HDL et de billes de polysaccharide, ce dernier jouant le rôle de matrice macrostructurante. De façon notable, le taux d‘encapsulation de l‘enzyme dans la matrice macroscopique est amélioré lorsque le biocatalyseur est pré-encapsulé dans les nanoplaquettes d‘HDL. Ceci est attribué aux interactions électrostatiques favorables entre les chaînes de polysaccharide et les HDL, facilitant une charge de matière plus importante. L‘efficacité catalytique du bioréacteur obtenu et sa recyclabilité ont été démontrés. Dans la troisième partie de cette thèse, nous décrivons pour la première fois la conception de bionanoréacteurs enzymes@HDL par co-immobilisation de systèmes bi- ou tétra-enzymatiques dans les HDL permettant de réaliser des cascades multienzymatiques biomimétiques. L‘immobilisation des différentes enzymes prises séparément a d‘abord été optimisée afin de déterminer les conditions de co-immobilisation et de réaliser les cascades biocatalytiques en phase hétérogène. Ces bionanoréacteurs, dont nous avons démontré la recyclabilité, ont été appliqués pour la synthèse de sucres phosphorylés de série D. Enfin, une cascade multienzymatique a été conçue de novo en solution aqueuse et optimisée pour synthétiser différents sucres phosphorylés rares de série L. / This multidisciplinary thesis at the biocatalysis/nanomaterial interface perfectly aims at designing innovative biohybrid materials by the assembly of inorganic materials the Layered Double Hydroxides (LDH) with enzymes under mild conditions. The first part of this thesis is devoted to the characterization of physico-chemical interactions between the LDH and the fructose-6-phosphate aldolase (FSA) catalyzing the stereoselective C-C bond formation to provide chiral polyols. LDH structures allow the effective confinement of enzymatic systems thanks to their opened two-dimensional structure as well as their chemical surface properties at the nanoscale and their biocompatibility. The FSA immobilization in different LDH matrices by different methods was studied. Biocatalytic activity is highly dependent on the method of assembling, modulating the final amount of FSA. The retaining activity rate of co-precipitated material was higher than that obtained for the adsorbed enzyme. In a second part, a bionanoreactor was developed based on a hierarchized assembly of FSA, LDH nanoplatelets and polysaccharide beads acting as a macrostructuring matrices. Significantly, the encapsulated enzyme rate in the beads was improved when the biocatalyst was pre-encapsulated in LDH nanoplatelets. This is attributed to favorable electrostatic interactions between the polysaccharide chains and LDH, facilitating a higher catalyst loading. The catalytic efficiency of the prepared bioreactor and its recyclability were demonstrated. In the third part of this thesis, we describe for the first time the design of bionanoreactors ―enzymes@LDH‖ by co-immobilisation of two and four enzymes in LDH allowing biomimetic multienzymatic cascades. We first studied the immobilization of the different enzymes taken separately. Then we worked on the optimization of the biocatalytic cascades in heterogeneous phase. These bionanoreactors, for which we have shown the recyclability, have been applied to the synthesis of D-series phosphorylated sugars. Finally, a multienzymatic cascade was de novo designed in aqueous homogeneous solution. It was optimized for the synthesis of rare L-phosphorylated sugars.

Biocatalyse

Hydroxydes Doubles Lamellaires (HDL)

Fructose-6-phosphate aldolase

Matériaux biohybrides

Cascade enzymatique

Bionanoréacteur

Immobilisation d‘enzymes

Biocatalysis

Layered Double Hydroxides (LDH)

Fructose-6-phosphate aldolase

Biohybrid materials

Enzymatic cascade

Bionanoreactor

Enzyme immobilization