Stimuli-responsive Materials From Thiol-based Networks

Brenn, William Alexander

01 June 2017

No description available.

Engineering

Materials Science

Polymer Chemistry

Polymers

Physical and Biological Properties of Synthetic Polycations in Alginate Capsules

Kleinberger, Rachelle

04 1900

The use of cell transplantation to treat enzyme deficiency disorders is limited by the immune response targeted against foreign tissue or the use of life-long immunosuppressants. Hiding cells from the immune system in an encapsulation device is promising. Cells encapsulated within an anionic calcium alginate hydrogel bead are protected through a semi-permeable membrane formed by polycation, poly-L-lysine (PLL). A final layer of alginate is added to hide the cationic PLL surface but this has proved to be difficult creating capsules which are prone to fibrotic overgrowth, blocking exchange of nutrients, waste and therapeutic enzymes through the capsule. For long term applications these capsules need to be both biocompatible and mechanically robust. This thesis aims to address the biocompatibility issue of high cationic surface charge by synthesizing polycations of reduced charge using N-(3- aminopropyl)methacrylamide hydrochloride (APM) and N-(2- hydroxypropyl)methacrylamide (HPM) and study the associated mechanical properties of the capsules using micropipette aspiration. Micropipette aspiration was applied and validated for alginate based capsules (gel and liquid core) to quantify stiffness. Varying ratios of APM were used to control the overall charge of the polycations formed while HPM was incorporated as a neutral, hydrophilic, nonfouling comonomer. The molecular weight (MW) was controlled by using reversible addition-fragmentation chain transfer (RAFT) polymerization. The biocompatibility of these polymers was tested by cell adhesion and proliferation of 3T3 fibroblasts onto APM/HPM copolymer functionalized surfaces and by solution toxicity against C2C12 myoblasts. The ability for the APM/HPM copolymers to bind to alginate and form capsules was also assessed, along with the integrity and stiffness of the capsule membrane with or without additional covalent cross-linking by reactive polyanion, poly(methacrylic acid-co-2-vinyl-4,4- dimethylazlactone) (PMV60). Thermo-responsive block copolymers of N-isopropylacrylamide (NIPAM) and 2- hydroxyethylacrylamide (HEA) were also synthesized as potential drug delivery nanoparticles, showing control over micelle morphology with varying NIPAM to HEA ratios. / Thesis / Doctor of Science (PhD) / The treatment of enzyme deficiency disorders by cell transplantation is limited by the immune attack of foreign tissue in absence of immunosuppressants. Cells protected in an encapsulation device has shown promise. Poly-L-lysine, a widely used membrane material in these protective capsules, binds to the anionic gel entrapping living cells because it is highly cationic. The high cationic charge is difficult to hide causing the immune system to build tissue around the capsule, preventing the encapsulated cells from exchanging nutrients and therapeutic enzymes. This thesis aims to replace poly-L-lysine by synthesizing a series of more biocompatible materials of decreasing cationic charge. These materials were studied for the ability to support tissue growth and form stable capsules. The membrane strength was measured using an aspiration method validated for these types of capsules. Reducing the cationic charge of the materials increased the biocompatibility of the capsule membrane but also made for weaker membranes.

Cell Encapsulation

Polycations

Alginate beads

mechanical properties

Polyelectrolyte Complexation

Polymer chemistry

RAFT polymerization

Block copolymers

Thermo-responsive polymers

Micropipette Aspiration

Covalent cross-linking

Micelle morphology

Step-Growth Polymerization Towards the Design of Polymers: Assembly and Disassembly of Macromolecules

June, Stephen Matthew

01 May 2012

Step-growth polymerization provided an effective method for the preparation of several high performance polymers. Step-growth polymerization was used for syntheses of poly(siloxane imides), polyesters, poly(triazole esters), poly(triazole ether esters), and epoxy networks. Each of these polymeric systems exhibited novel structures, and either photoreactive capabilities, or high performance properties. There is an increasing trend towards the development of photoactive adhesives. In particular these polymers are often used in flip bonding, lithography, stimuli responsive polymers, drug delivery, and reversible adhesives. The ability to tailor polymer properties carefully with exposure to light allows for very unique stimuli responsive properties for many applications. This dissertation primarily investigates photoreactive polymers for reversible adhesion for use in the fabrication of microelectronic devices. In particular cyclobutane diimide functionality within polyimides and poly(siloxane imides) and o-nitro benzyl ester functionality within polyesters acted effectively as chromophores to this end. Thermal solution imidization allowed for the effective synthesis of polyimides and poly(siloxane imides). 1,2,3,4-Cyclobutane tetracarboxylic dianhydride acted as the chromophore within the polymer backbone. The polyimides obtained exhibited dispersibility only in dipolar, aprotic, high boiling solvents such as DMAc or NMP. The obtained poly(siloxane imides) demonstrated enhanced dispersibility in lower boiling organic solvents such as THF and CHCl₃. Dynamic mechanical analysis and tensile testing effectively measure the mechanical properties of the photoactive poly(siloxane imides) and confirmed elastomeric properties. Atomic force microscopy confirmed microphase separation of the photoactive poly(siloxane imides). ¹H NMR spectroscopy confirmed formation of maleimide peaks upon exposure to narrow band UV light with a wavelength of 254 nm. This suggested photo-cleavage of the cyclobutane diimide units within the polymer backbone. Melt transesterification offered a facile method for the synthesis of o-nitro benzyl ester-containing polyesters. ¹H NMR spectroscopy confirmed the structures of the photoactive polyesters and size exclusion chromatography confirmed reasonable molecular weights and polydispersities of the obtained samples. ¹H NMR spectroscopy also demonstrated a decrease in the integration of the resonance corresponding to the o-nitro benzyl ester functionality relative to the photo-stable m-nitro benzyl ester functionality upon exposure to high-intensity UV light, suggesting photo-degradation of the adhesive. ASTM wedge testing verified a decrease in fracture energy of the adhesive upon UV exposure, comparable to the decrease in fracture energy of a commercial hot-melt adhesive upon an increase in temperature. Click chemistry was used to synthesize polyesters and segmented block copolyesters. Triazole-containing homopolyesters exhibited a marked increase (~40 °C) in Tg, relative to structurally analogous classical polyesters synthesized in the melt. However, the triazole-containing homopolyesters exhibited insignificant dispersibility in many organic solvents and melt-pressed films exhibited poor flexibility. Incorporation of azide-functionalized poly(propylene glycol) difunctional oligomers in the synthesis of triazole-containing polyesters resulted in segmented block copolyesters which exhibited enhanced dispersibility and film robustness relative to the triazole-containing homopolyesters. The segmented triazole-containing polyesters all demonstrated a soft segment Tg near -62 °C, indicating microphase separation. Dynamic mechanical analysis confirmed the presence of a rubbery plateau, with increasing plateau moduli as a function of hard segment content, as well as increasing flow temperatures as a function of hard segment content. Tensile testing revealed increasing tensile strength as a function of hard segment, approaching 10 MPa for the 50 wt % HS sample. Atomic force microscopy confirmed the presence of microphase separated domains, as well as semicrystalline domains. These results indicated the effectiveness of click chemistry towards the synthesis of polyesters and segmented block copolyesters. Click chemistry was also used for the synthesis of photoactive polyesters and segmented block polyesters. The preparation of 2-nitro-p-xylylene glycol bispropiolate allowed for the synthesis of triazole-containing polyesters, which exhibited poor dispersibility and flexibility of melt-pressed films. The synthesis of segmented photoactive polyesters afforded photoactive polyesters with improved dispersibility and film robustness. ¹H NMR spectroscopy confirmed the photodegradation of the o-nitro benzyl functional groups within the triazole-containing polyesters, which indicated the potential utility of these polyesters for reversible adhesion. Synthesis of the glycidyl ether of 2,2,4,4-tetramethyl-1,3-cyclobutane diol (CBDOGE) allowed for the subsequent preparation of epoxy networks which did not contain bisphenol-A or bisphenol-A derivatives. Preparation of analogous epoxy networks from the glycidyl ether of bisphenol-A (BPA-GE) provided a method for control experiments. Tensile testing demonstrated that, dependent on network Tg, the epoxy networks prepared from CBDOGE exhibited similar Young's moduli and tensile strain at break as epoxy networks prepared from BPAGE. Dynamic mechanical analysis demonstrated similar glassy moduli for the epoxy networks, regardless of the glycidyl ether utilized. Tg and rubbery plateau moduli varied as a function of diamine molecular weight. Melt rheology demonstrated a gel time of 150 minutes for the preparation of epoxy networks from CBDO-GE and 78 minutes for the preparation of epoxy networks from BPA-GE, with the difference attributed to increased sterics surrounding CBDO-GE. These results indicated the suitability of CBDO-GE as a replacement for BPA-GE in many applications. / Ph. D.

Polycondensation

Polyaddition

Step-Growth Polymers

Epoxy Networks

Microbial Fuel Cells

Photo-active Polymers

Poly(siloxane imides)

Polyesters

"Click" Chemistry

Stimuli Responsive Polymers

Bisphenol-A

BPA

Développement de tensioactifs à base d’acides biliaires pegylés pour des applications pharmaceutiques

Le Dévédec, Frantz

03 1900

Les acides biliaires sont reconnus comme des tensioactifs d’origine biologique potentiellement applicables dans le domaine pharmaceutique. Leurs structures en font une plateforme idéale pour l’obtention de nouvelles architectures polymères. Des composés synthétisés par polymérisation anionique de dérivés d’oxirane comme l’oxyde d’éthylène, offre des dérivés amphiphiles pegylés démontrant des propriétés d’agrégation intéressantes en vue d’une amélioration de la biocompatibilité et de la capacité d’encapsulation médicamenteuse. Une large gamme d’acides biliaires pegylés (BA(EGn)x) a été préparée avec comme objectif premier leurs applications dans la formulation de principes actifs problématiques. Pour cela, une caractérisation rigoureuse du comportement de ces dérivés (modulation de la longueur (2 < n < 19) et du nombre de bras (2 < x < 4) de PEG) en solution a été réalisée. Dans le but d’améliorer la biodisponibilité de principes actifs lipophiles (cas de l’itraconazole), des nanoémulsions spontanées, composées de BA(EGn)x et d’acide oléique, ont été développées. L’évaluation in vitro, de la toxicité (cellulaire), et de la capacité de solubilisation des systèmes BA(EGn)x, ainsi que les paramètres pharmacocinétiques in vivo (chez le rat), suggèrent une livraison contrôlée par nos systèmes auto-assemblés lors de l’administration orale et intraveineuse. Aussi, la synthèse de copolymères en blocs en étoile à base d’acide cholique pegylés a été effectuée par polymérisation anionique par addition d’un second bloc au caractère hydrophobe de poly(éther d’allyle et de glycidyle) (CA(EGn-b-AGEm)4). Selon le ratio de blocs hydrophiles-hydrophobes CA(EGn-b-AGEm)4, des réponses thermiques en solution (LCST) ont été observées par un point de trouble (Cp) entre 8 oC et 37 oC. Un mécanisme de formation d’agrégats en plusieurs étapes est suggéré. La thiolation des allyles des PAGE permet une fonctionnalisation terminale à haute densité, comparable aux dendrimères. Les caractérisations physico-chimiques des CA(EGn-b-AGEm-NH2)4 et CA(EGn-b-AGEm-COOH)4 indiquent la formation de structures auto-assemblées en solution, sensibles à la température ou au pH. Cette fonctionnalisation élargie le domaine d’application des dérivés d’acides biliaires pegylés en étoile vers la transfection d’ADN, la livraison de siRNA thérapeutiques ou encore à une sélectivité de livraison médicamenteux (ex. sensibilité au pH, greffage ligands). / Bile acids are natural compounds and may have potential for pharmaceutical applications. Their structures provide an interesting platform for polymerization to obtain well-defined architectures. The anionic polymerization of oxirane derivatives, mainly PEG derivatives, endowed new aggregation properties and improvement of biocompatibility of the new amphiphilic polymers based on bile acids. A library of pegylated bile acids (BA(EGn)x) was prepared for the formulation of lipophilic drugs. The aqueous physicochemical behaviors of these derivatives (modulation of the length (2 < n < 19) and the number (2 < x < 4) of PEG arm) were investigated. In order to improve the bioavailability of insoluble active compounds (itraconazole, an antifungal drug), a binary system based on the association of BA(EGn)x and oleic acid, formed self-emulsifying drug delivery systems. The in vitro evaluation of cell toxicity and solubilization capacities of the BA(EGn)x systems followed by the in vivo evaluation in rats of the pharmacokinetic parameters demonstrated the advantages of our self-assembled system for controlled drug delivery for both oral and intravenous administration. Star-shaped block copolymers of pegylated cholic acid (CA(EGn-b-AGEm)4) were prepared by the introduction of a second hydrophobic block of PAGE poly(allyl glycidyl ether). They demonstrated thermosensitivity (8 oC < LCST < 37 oC) in aqueous solution, suggesting a mechanism based on the formation of aggregates in two steps. The PAGE block with pendant groups may facilitate futher functionalization. The thiolation of allyl yields a new class of charged PEGylated star polymers (with multiple amines or carboxylic groups). CA(EGn-b-AGEm-NH2)4 and CA(EGn-b-AGEm-COOH)4 derivatives showed self-assembled structures in solution with temperature and pH responsiveness, respectively. This functionalization may lead to broader application of pegylated star derivatives in DNA transfection systems, siRNA delivery systems or as selective delivery system (pH-dependent).

Acides biliaires

PEG

Polymère en étoile

Polymérisation anionique

Système de relargage de médicaments

Bile acids

Star polymers

drug delivery system

anionic polymerization

itraconazole

thermo responsive polymers

Développement de tensioactifs à base d’acides biliaires pegylés pour des applications pharmaceutiques

Le Dévédec, Frantz

03 1900

Les acides biliaires sont reconnus comme des tensioactifs d’origine biologique potentiellement applicables dans le domaine pharmaceutique. Leurs structures en font une plateforme idéale pour l’obtention de nouvelles architectures polymères. Des composés synthétisés par polymérisation anionique de dérivés d’oxirane comme l’oxyde d’éthylène, offre des dérivés amphiphiles pegylés démontrant des propriétés d’agrégation intéressantes en vue d’une amélioration de la biocompatibilité et de la capacité d’encapsulation médicamenteuse. Une large gamme d’acides biliaires pegylés (BA(EGn)x) a été préparée avec comme objectif premier leurs applications dans la formulation de principes actifs problématiques. Pour cela, une caractérisation rigoureuse du comportement de ces dérivés (modulation de la longueur (2 < n < 19) et du nombre de bras (2 < x < 4) de PEG) en solution a été réalisée. Dans le but d’améliorer la biodisponibilité de principes actifs lipophiles (cas de l’itraconazole), des nanoémulsions spontanées, composées de BA(EGn)x et d’acide oléique, ont été développées. L’évaluation in vitro, de la toxicité (cellulaire), et de la capacité de solubilisation des systèmes BA(EGn)x, ainsi que les paramètres pharmacocinétiques in vivo (chez le rat), suggèrent une livraison contrôlée par nos systèmes auto-assemblés lors de l’administration orale et intraveineuse. Aussi, la synthèse de copolymères en blocs en étoile à base d’acide cholique pegylés a été effectuée par polymérisation anionique par addition d’un second bloc au caractère hydrophobe de poly(éther d’allyle et de glycidyle) (CA(EGn-b-AGEm)4). Selon le ratio de blocs hydrophiles-hydrophobes CA(EGn-b-AGEm)4, des réponses thermiques en solution (LCST) ont été observées par un point de trouble (Cp) entre 8 oC et 37 oC. Un mécanisme de formation d’agrégats en plusieurs étapes est suggéré. La thiolation des allyles des PAGE permet une fonctionnalisation terminale à haute densité, comparable aux dendrimères. Les caractérisations physico-chimiques des CA(EGn-b-AGEm-NH2)4 et CA(EGn-b-AGEm-COOH)4 indiquent la formation de structures auto-assemblées en solution, sensibles à la température ou au pH. Cette fonctionnalisation élargie le domaine d’application des dérivés d’acides biliaires pegylés en étoile vers la transfection d’ADN, la livraison de siRNA thérapeutiques ou encore à une sélectivité de livraison médicamenteux (ex. sensibilité au pH, greffage ligands). / Bile acids are natural compounds and may have potential for pharmaceutical applications. Their structures provide an interesting platform for polymerization to obtain well-defined architectures. The anionic polymerization of oxirane derivatives, mainly PEG derivatives, endowed new aggregation properties and improvement of biocompatibility of the new amphiphilic polymers based on bile acids. A library of pegylated bile acids (BA(EGn)x) was prepared for the formulation of lipophilic drugs. The aqueous physicochemical behaviors of these derivatives (modulation of the length (2 < n < 19) and the number (2 < x < 4) of PEG arm) were investigated. In order to improve the bioavailability of insoluble active compounds (itraconazole, an antifungal drug), a binary system based on the association of BA(EGn)x and oleic acid, formed self-emulsifying drug delivery systems. The in vitro evaluation of cell toxicity and solubilization capacities of the BA(EGn)x systems followed by the in vivo evaluation in rats of the pharmacokinetic parameters demonstrated the advantages of our self-assembled system for controlled drug delivery for both oral and intravenous administration. Star-shaped block copolymers of pegylated cholic acid (CA(EGn-b-AGEm)4) were prepared by the introduction of a second hydrophobic block of PAGE poly(allyl glycidyl ether). They demonstrated thermosensitivity (8 oC < LCST < 37 oC) in aqueous solution, suggesting a mechanism based on the formation of aggregates in two steps. The PAGE block with pendant groups may facilitate futher functionalization. The thiolation of allyl yields a new class of charged PEGylated star polymers (with multiple amines or carboxylic groups). CA(EGn-b-AGEm-NH2)4 and CA(EGn-b-AGEm-COOH)4 derivatives showed self-assembled structures in solution with temperature and pH responsiveness, respectively. This functionalization may lead to broader application of pegylated star derivatives in DNA transfection systems, siRNA delivery systems or as selective delivery system (pH-dependent).

Acides biliaires

PEG

Polymère en étoile

Polymérisation anionique

Système de relargage de médicaments

Bile acids

Star polymers

drug delivery system

anionic polymerization

itraconazole

thermo responsive polymers

New stimuli-responsive block random copolymers and their aggregation

Savoji, Mohammad T.

08 1900

Les polymères sensibles à des stimuli ont été largement étudiés ces dernières années notamment en vue d’applications biomédicales. Ceux-ci ont la capacité de changer leurs propriétés de solubilité face à des variations de pH ou de température. Le but de cette thèse concerne la synthèse et l’étude de nouveaux diblocs composés de deux copolymères aléatoires. Les polymères ont été obtenus par polymérisation radicalaire contrôlée du type RAFT (reversible addition-fragmentation chain-transfer). Les polymères à bloc sont formés de monomères de méthacrylates et/ou d’acrylamides dont les polymères sont reconnus comme thermosensibles et sensible au pH. Premièrement, les copolymères à bloc aléatoires du type AnBm-b-ApBq ont été synthétisés à partir de N-n-propylacrylamide (nPA) et de N-ethylacrylamide (EA), respectivement A et B, par polymérisation RAFT. La cinétique de copolymérisation des poly(nPAx-co-EA1-x)-block-poly(nPAy-co-EA1-y) et leur composition ont été étudiées afin de caractériser et évaluer les propriétés physico-chimiques des copolymères à bloc aléatoires avec un faible indice de polydispersité . Leurs caractères thermosensibles ont été étudiés en solution aqueuse par spectroscopie UV-Vis, turbidimétrie et analyse de la diffusion dynamique de la lumière (DLS). Les points de trouble (CP) observés des blocs individuels et des copolymères formés démontrent des phases de transitions bien définies lors de la chauffe. Un grand nombre de macromolécules naturels démontrent des réponses aux stimuli externes tels que le pH et la température. Aussi, un troisième monomère, 2-diethylaminoethyl methacrylate (DEAEMA), a été ajouté à la synthèse pour former des copolymères à bloc , sous la forme AnBm-b-ApCq , et qui offre une double réponse (pH et température), modulable en solution. Ce type de polymère, aux multiples stimuli, de la forme poly(nPAx-co-DEAEMA1-x)-block-poly(nPAy-co-EA1-y), a lui aussi été synthétisé par polymérisation RAFT. Les résultats indiquent des copolymères à bloc aléatoires aux propriétés physico-chimiques différentes des premiers diblocs, notamment leur solubilité face aux variations de pH et de température. Enfin, le changement d’hydrophobie des copolymères a été étudié en faisant varier la longueur des séquences des blocs. Il est reconnu que la longueur relative des blocs affecte les mécanismes d’agrégation d’un copolymère amphiphile. Ainsi avec différents stimuli de pH et/ou de température, les expériences effectuées sur des copolymères à blocaléatoires de différentes longueurs montrent des comportements d’agrégation intéressants, évoluant sous différentes formes micellaires, d’agrégats et de vésicules. / Stimuli-responsive polymers and their use in biomedical applications have been widely investigated in recent years. These polymers change their physical properties such as water-solubility, when subjected to certain stimuli, for example change in temperature or pH. The main purpose of this work is to study new diblock copolymers consisting of two random copolymers, i.e., diblock random copolymers. Polymers with well-defined structures and tunable properties have been made using reversible addition−fragmentation chain-transfer (RAFT) polymerization, one of the controlled radical polymerization techniques. The blocks are made of acrylamide- and/or methacrylate-based monomers, which commonly show thermo-responsiveness and hence, double stimuli-responsive behavior is shown. First, a diblock random copolymer in the form of AnBm-b-ApBq was synthesized with N-n-propylacrylamide (nPA) and N-ethylacrylamide (EA) as A and B using RAFT polymerization. Kinetic study of the copolymerization process confirmed the controlled character of the copolymerization. The diblock random copolymers with the compositions of poly(nPAx-co-EA1-x)-block-poly(nPAy-co-EA1-y) and low polydispersity were obtained. With UV-visible spectroscopy and dynamic light scattering (DLS) we investigate their thermoresponsive characteristics in aqueous solutions. Individual blocks showed tunable cloud points, and the diblock copolymer exhibited a well-separated two-step phase transition upon heating. Macromolecules in nature can often respond to a combination of external stimuli, most commonly temperature and pH, rather than a single stimulus. Therefore, a second type of diblock random copolymer in the form of AnBm-b-ApCq was synthesized by combining a pH- and temperature-responsive block with another, only temperature-responsive block, producing responsiveness to multiple stimuli. This polymer with the composition of poly(nPAx-co-DEAEMA1-x)-block-poly(nPAy-co-EA1-y) where DEAEMA stands for 2-diethylaminoethyl methacrylate with well-defined structure and tunable properties has also been made using sequential RAFT polymerization. The resulting diblock random copolymer changes its physico-chemical properties, such as water-solubility, in a quite controlled manner when subjected to the changes in temperature or pH. What happens when blocks of different lengths change their relative hydrophilicity? It is known that the relative length of the blocks in amphiphilic diblock copolymers affects the aggregation mechanism. We compared three diblock copolymers with different block and chain lengths in aqueous solution when they change their relative hydrophilicity due to the change in the external stimuli. The variation of the length and chemical composition of the blocks allows the tuning of the responsiveness of the block copolymers toward both pH and temperature and determines the formation of either micelles or vesicles during the aggregation.

Block random copolymers

thermo- and pH-responsive polymers

RAFT polymerization

dual behavior copolymers

micelles

vesicles

copolymères à blocaléatoires

thermo- et pH-sensible

polymérisation RAFT

copolymères à réponse variable

micelles et vésicules

Synthèse et caractérisation des nanoparticules intelligentes / Synthesis and characterization of smart nanoparticles

Jamal Al Dine, Enaam

07 June 2017

L’un des enjeux majeurs en nanomédecine est de développer des systèmes capables à la fois de permettre un diagnostic efficace et également de servir de plateforme thérapeutique pour combattre les infections et les neuro-dégénérescences. Dans cette optique, et afin d’améliorer la détection de tumeurs, des agents de contraste ont été développés dans le but d’augmenter le rapport signal sur bruit. Parmi ces agents, les nanoparticules (NPs) d’oxyde de fer superparamagnétiques (SPIOs) et les quantum dots (QDs) sont des candidats idéaux et ont reçu une grande attention depuis une vingtaine d’années. De surcroit, leurs propriétés spécifiques dues à leurs dimensions nanométriques et leurs formes permettent de moduler leur bio-distribution dans l’organisme. L’opportunité de revêtir ces NPs biocompatibles par des couches de polymères devraient permettre d’améliorer la stabilité de ces nanomatériaux dans l’organisme. Et par conséquent, favoriser leur biodistribution et également leur conférer de nouvelles applications en l’occurrence des applications biomédicales. Dans ce travail de thèse, nous avons développé de nouveaux systèmes thermo-répondant basés sur un cœur SPIOs ou QDs qui sont capables, à la fois, de transporter un principe actif anticancéreux, i.e. la doxorubicine (DOX) et de le relarguer dans le milieu physiologique à une température contrôlée. Deux familles de NPs ont été synthétisées. La première concerne des NPs de Fe3O4 SPIO qui ont été modifiées en surface par un copolymère thermorépondant biocompatible à base de 2-(2-methoxy) méthacrylate d’éthyle (MEO2MA), oligo (éthylène glycol) méthacrylate (OEGMA). La seconde famille, consiste en des NPs de ZnO recouverte du même copolymère. Pour la première fois, le copolymère de type P(MEO2MAX-OEGMA100-X) a été polymérisé par activateur-régénéré par transfert d’électron-polymérisation radicalaire par transfert d’atome (ARGET-ATRP). La polymérisation et copolymérisation ont été initiées à partir de la surface. Les NPs cœur/coquilles ont été caractérisées par microscopie électronique à transmission (TEM), analyse thermogravimétrique (TGA), etc. Nous avons montré que l’efficacité du procédé ARGET-ATRP pour modifier les surfaces des NPs de SiO2, Fe3O4 et de ZnO. L’influence de la configuration de la chaîne de copolymère et des propriétés interfaciales avec le solvant ou le milieu biologique en fonction de la température a été étudiée. Nous avons montré que les propriétés magnétiques des systèmes coeur/coquilles à base de Fe3O4 ne sont influencées que par la quantité de polymère greffée contrairement au QDs qui vient leur propriété optique réduire au-delà de la température de transition. Ce procédé simple et rapide que nous avons développé est efficace pour le greffage de nombreux copolymères à partir de surfaces de chimie différentes. Les expériences de largage et relarguage d’un molécule modèle telle que la DOX ont montré que ces nanosystèmes sont capables de relarguer la DOX à une température bien contrôlée, à la fois dans l’eau que dans des milieux complexes tels que les milieux biologique. De plus, les tests de cytocompatibilité ont montré que les NPs coeur/coquilles ne sont pas cytotoxiques en fonction de leur concentration dans le milieu biologique. A partir de nos résultats, il apparaît que ces nouveaux nanomatériaux pourront être envisagés comme une plateforme prometteuse pour le traitement du cancer / One of the major challenges in nanomedicine is to develop nanoparticulate systems able to serve as efficient diagnostic and/or therapeutic tools against sever diseases, such as infectious or neurodegenerative disorders. To enhance the detection and interpretation contrast agents were developed to increase the signal/noise ratio. Among them, Superparamagnetic Iron Oxide (SPIO) and Quantum Dots (QDs) nanoparticles (NPs) have received a great attention since their development as a liver contrasting agent 20 years ago for the SPIO. Furthermore, their properties, originating from the nanosized dimension and shape, allow different bio-distribution and opportunities beyond the conventional chemical imaging agents. The opportunity to coat those biocompatible NPs by a polymer shell that can ensure a better stability of the materials in the body, enhance their bio-distribution and give them new functionalities. It has appeared then that they are very challenging for medicinal applications. In this work, we have developed new responsive SPIO and QDs based NPs that are able to carry the anticancer drug doxorubicin (DOX) and release it in physiological media and at the physiological temperature. Two families of NPs were synthesized, the first one consist in superparamagnetic Fe3O4 NPs that were functionalized by a biocompatible responsive copolymer based on 2-(2-methoxy) ethyl methacrylate (MEO2MA), oligo (ethylene glycol) methacrylate (OEGMA). The second family consists in the ZnO NPs coated by the same copolymer. For the first time, P(MEO2MAX-OEGMA100-X) was grown by activator regenerated by electron transfer–atom radical polymerization (ARGET-ATRP) from the NPs surfaces by surface-initiated polymerization. The core/shell NPs were fully characterized by the combination of transmission electron microscopy (TEM), thermogravimetric analysis (TGA), and by the physical properties of the nanostructures studied. We demonstrate the efficiency of the ARGET-ATRP process to graft polymers and copolymers at the surface of Fe3O4 and ZnO NPs. The influence of the polymer chain configuration (which leads to the aggregation of the NPs above the collapse temperature of the copolymer (LCST)) was studied. We have demonstrated that the magnetic properties of the core/shell Fe3O4-based nanostructures were only influenced by the amount of the grafted polymer and no influence of the aggregation was evidenced. This simple and fast developed process is efficient for the grafting of various co-polymers from any surfaces and the derived nanostructured materials display the combination of the physical properties of the core and the macromolecular behavior of the shell. The drug release experiments confirmed that DOX was largely released above the co-polymer LCST. Moreover, the cytocompatibility test showed that those developed NPs do not display any cytotoxicity depending on their concentration in physiological media. From the results obtained, it can be concluded that the new nanomaterials developed can be considered for further use as multi-modal cancer therapy tools

Nanoparticules cœur/coquilles

ARGET-ATRP

Polymère répondant

Quantum dots

Nanoparticules superparamagnétique

Nanomédecine

Traitement du cancer

Libération de médicament

Core/shell nanoparticles

ARGET-ATRP

Responsive polymers

Quantum dots

Superparamagnetic nanoparticles

Nanomedicine

Cancer therapy

Drug release

620.5

615.6

616.075 48

Functional nanoparticles for biomedical applications / Les nanoparticules fonctionnelles pour des applications biomédicales

Beyazit, Selim

12 December 2014

Cette thèse décrit le développement de nouvelles méthodes pour obtenir des nanoparticules fonctionnelles polyvalentes qui peuvent potentiellement être utilisées pour des applications biomédicales telles que la vectorisation de médicaments, des essais biologiques et la bio-imagerie. Les nanomatériaux sont des outils polyvalents qui ont trouvé des applications comme vecteurs de médicaments, la bio-imagerie ou les biocapteurs. En particulier, les nanoparticules de type core-shell ont attiré beaucoup d'attention en raison de leur petite taille, une relation surface/volume élevée, et une biocompatibilité. Dans ce contexte, nous proposons dans la première partie de la thèse (Chapitre 2), une nouvelle méthode pour obtenir des nanoparticules core-shell via la polymérisation radicalaire en émulsion et vivante combinées. Des particules cœurs de polystyrène de 30 à 40 nm, avec une distribution de taille étroite et portant à la surface des groupements iniferter ont été utilisés pour amorcer la polymérisation supplémentaire d'une couche de polymère. Des nanoparticules core-shell ont été préparées de cette façon. Différents types d’enveloppes : anionique, zwitterioniques, à empreintes moléculaires, thermosensibles, ont ainsi été greffées. Notre méthode est une plate-forme polyvalente permettant d'ajouter des fonctionnalités multiples soit dans le noyau et/ou l'enveloppe pour les études d'interaction cellulaire et de toxicité, ainsi que des matériaux récepteurs pour l'imagerie cellulaire. Dans la deuxième partie de la thèse (Chapitre 3), nous décrivons un procédé nouveau et polyvalent pour la modification de surface des nanoparticules de conversion ascendante (UCP). Ce sont des nanocristaux fluorescents dopés de lanthanides qui ont récemment attiré beaucoup d'attention. Leur fluorescence est excitée dans le proche infrarouge, ce qui les rend idéales comme marqueurs dans des applications biomédicales telles que les tests biologiques et la bio-imagerie, l'auto-fluorescence étant réduite par rapport à des colorants organiques et les quantum dots. Cependant, les UCP sont hydrophobes et non-compatible avec les milieux aqueux, donc une modification de leur surface est essentielle. La stratégie que nous proposons utilise l'émission UV ou visible après excitation en proche infrarouge des UCP, comme source de lumière secondaire pour la photopolymérisation localisée de couches minces hydrophiles autour les UCP. Notre méthode offre de grands avantages comme la facilité d'application et la fonctionnalisation de surface rapide pour fixer divers ligands, et fournit une plateforme pour préparer des UCP encapsulée de polymères pour des différentes applications. Des hydrogels stimuli-sensibles sont des matériaux qui changent leurs propriétés physicochimiques en réponse à des stimuli externes tels que la température, le pH ou la lumière. Ces matériaux intelligents jouent un rôle critique dans des applications biomédicales telles que la vectorisation de médicaments ou l'ingénierie tissulaire. La troisième partie de cette thèse (Chapitre 4) propose un nouveau procédé de préparation d'hydrogels photo et pH sensible. Deux composantes, l'un photosensible à base dl'acide 4-[(4-méthacryloyloxy) phénylazo] benzoïque et l'autre cationic contenant des unités 2-(diéthylamino)éthyl méthacrylate, ont été synthétisés. Leur association donne des particules monodispersées de 100 nm photo et pH sensibles. Ces nanoparticules peuvent être potentiellement utilisées pour la vectorisation de médicaments, en particulier de biomolécules telles que protéines ou siARN. En conclusion, nous avons conçu plusieurs nouvelles méthodes efficaces, polyvalentes, génériques et facilement applicables pour obtenir des nanoparticules et nanocomposites de polymères fonctionnels qui peuvent être appliqués dans de différents domaines biomédicaux comme la vectorisation de médicaments, les biocapteurs, les tests biologiques et la bio-imagerie. / This thesis describes the development of novel methods to obtain versatile, functional nanoparticles that can potentially be used for biomedical applications such as drug delivery, bioassays and bioimaging. Nanomaterials are versatile tools that have found applications as drug carriers, bioimaging or biosensing. In particular, core-shell type nanoparticles have attracted much attention due to their small size, high surface to volume ratio and biocompatibility. In this regard, we propose in the first part of the thesis (Chapter 2), a novel method to obtain core-shell nanoparticles via combined radical emulsion and living polymerizations. Polystyrene core seeds of 30-40 nm, with a narrow size distribution and surface-bound iniferter moieties were used to further initiate polymerization of a polymer shell. Core-shell nanoparticles were prepared in this way. Different types of shells : anionic, zwitterionic, thermoresponsive or molecularly imprinted shells, were thus grafted. Our method is a versatile platform with the ability to add multi-functionalities in either the core for optical sensing or/and the shell for cell interaction and toxicity studies, as well as receptor materials for cell imaging. In the second part of the thesis (Chapter 3), we describe a novel and versatile method for surface modification of upconverting nanoparticles (UCPs). UCPs are lanthanide-doped fluorescent nanocrystals that have recently attracted much attention. Their fluorescence is excitated in the near infrared, which makes them ideal as labels in biomedical applications such as bioimaging and bioassays, since the autofluorescence background is minimized compared to organic dyes and quantum dots. However, UCPs are hydrophobic and non-compatible with aqueous media, therefore prior surface modification is essential. The strategy that we propose makes use oft he UV or Vis emission light of near-infrared photoexcited upconverting nanoparticles, as secondary light source for the localized photopolymerization of thin hydrophilic shells around the UCPs. Our method offers great advantages like ease of application and rapid surface functionalization for attaching various ligands and therefore can provide a platform to prepare polymeric-encapsulated UCPs for applications in bioassays, optical imaging and drug delivery. Stimuli responsive hydrogels are materials that can change their physico-chemical properties in response to external stimuli such as temperature, pH or light. These smart materials play critical roles in biomedical applications such as drug delivery or tissue engineering. The third part of the thesis (Chapter 4) proposes a novel method for obtaining photo and pH-responsive supramolecularly crosslinked hydrogels. Two building blocks, one containing photoresponsive 4-[(4-methacryloyloxy)phenylazo] benzoic acid and the other, consisting of cationic 2-(diethylamino)ethyl methacrylate units, were first synthesized. Combining the two building blocks yielded photo and pH responsive monodisperse 100-nm particles. These nanoparticles can be eventually utilized for drug delivery, especially delivery of biomolecules such as siRNAs or proteins. In conclusion, we have designed several new efficient, versatile, generic and easily applicable methods to obtain functionalized polymer nanoparticles and nanocomposites that can be applied in various biomedical domains like drug delivery, biosensing, bioassays and bioimaging.

Polymères stimuli-sensibles

Nanoparticules cœur-coquille

Nanoparticules de conversion ascendante

Polymérisation radicalaire contrôlée

Bio-imagerie

Nanomatériaux

Imagerie cellulaire

Ingénierie tissulaire

Applications biomédicales

UCP

Stimuli-responsive polymers

Core-shell nanoparticles

Upconverting nanoparticles

Controlled radical polymerisation

Supramolecular chemistry

New stimuli-responsive block random copolymers and their aggregation

Savoji, Mohammad T.

08 1900

No description available.

Block random copolymers

thermo- and pH-responsive polymers

RAFT polymerization

dual behavior copolymers

micelles

vesicles

copolymères à blocaléatoires

thermo- et pH-sensible

polymérisation RAFT

copolymères à réponse variable

micelles et vésicules

SMART CAPSULE WITH STIMULI-RESPONSIVE POLYMERS FOR TARGETED SAMPLING FROM THE GASTROINTESTINAL TRACT

Sina Nejati (17029686)

25 September 2023

<p dir="ltr">The gastrointestinal (GI) tract and its diverse microbial community play a significant role in overall health, impacting various aspects such as metabolism, physiology, nutrition, and immune function. Disruptions in the gut microbiota have been associated with metabolic diseases, colorectal cancer, diabetes, obesity, inflammatory bowel disease, Alzheimer's disease, and depression. Despite recognizing the importance of the gut microbiota, the interrelationship between microbiota, diet, and disease prevention remains unclear. Current techniques for monitoring the microbiome often rely on fecal samples or invasive endoscopic procedures, limiting the understanding of spatial variations in the gut microbiota and posing invasiveness challenges. To address these limitations, this dissertation focuses on the design and development of an electronic-free smart capsule platform capable of targeted sampling of GI fluid within specific regions of the GI tract. The capsule can be retrieved for subsequent bacterial culture and sequencing analysis. The capsule design is based on stimuli-responsive polymers and superabsorbent hydrogels, chosen for their proven safety, compatibility, and scalability. By leveraging the pH variation across the GI tract, the pH-sensitive polymeric coatings dissolve at the desired region, activating the sampling process. The superabsorbent hydrogel inside the capsule collects the sampled GI fluid and facilitates capsule closure upon completion of sampling. Systematic studies were conducted to identify suitable pH-responsive polymer coatings, superabsorbent hydrogels, and processing conditions that effectively operated within the physiological conditions of the GI tract. The technology's effectiveness and safety were validated through rigorous <i>in vitro</i> and <i>in vivo</i> studies using pig models. These studies demonstrated the potential of the technology for targeted sampling of GI fluid in both small and large intestinal regions, enabling subsequent bacterial culture and gene sequencing analysis. Additionally, the capsule design was enhanced with the integration of a metal tracer, enabling traceability throughout the GI tract using X-ray imaging and portable metal detectors for ambulatory screening. This technology holds promise as a non-invasive tool for studying real-time metabolic and molecular interactions among the host, diet, and microbiota in challenging-to-access GI regions. Its application in clinical studies can provide new insights into diet-host-microbiome interactions and contribute to addressing the burden faced by patients and their families dealing with GI-related diseases.</p>

Functional materials

Polymers and plastics

Microbiome

Colon Sampling

pH-responsive polymers

Gastrointestinal Tract

irritable bowel disease (IBD)

Irritable Bowel Syndrome

3D Printing

Small Intestine

Sampling

Capsule