Microgéis termo-responsivos preparados a partir dos polímeros do amido

Leite, Daiani Canabarro

January 2017

Esta tese apresenta os estudos realizados quanto à síntese e caracterização de microgéis termo-responsivos de N-isopropilacrilamida (NIPAM) e macromoléculas de origem amilácea em sua composição, sistemas ainda pouco explorados na literatura. Inicialmente, nanopartículas de amido (SNP) foram preparadas por nanoprecipitação para incorporação nos microgéis de interesse, através da dissolução dos grânulos do amido em DMSO/H2O, aplicação de ultrassom e precipitação em não-solvente. As SNPs preparadas foram utilizadas como copolímero para formação de microgéis híbridos do tipo SNP-co-p(NIPAM) através de polimerização em emulsão na presença e na ausência de surfactante. A influência das SNPs nas propriedades dos microgéis foi estudada por MEV, DLS, PZ e SAXS, onde foram observadas mudanças no comportamento físico-químico e estrutura supramolecular dos microgéis. No geral, observaram-se deslocamentos da temperatura de transição de fase para valores maiores (até 35 °C, cerca de 3 °C acima do valor determinado para sistemas contendo p(NIPAM) puro), aumento da estabilidade coloidal e organização dos polímeros presentes no microgel em uma arquitetura caroço-casca. As propriedades de inchamento dos microgéis também foram estudadas através da teoria de Flory-Rehner, onde a temperatura theta e o grau de polimerização entre dois pontos de reticulação foram determinados através do ajuste apropriado do parâmetro de interação (χ). Paralelamente, visando um sistema diferente do descrito acima, foi estudado um novo agente de reticulação baseado nos polímeros do amido, a amilose e a amilopectina. Para isso, os polímeros do amido que compõem as nanopartículas foram modificados para a utilização como agente de reticulação na síntese de microgéis de p(NIPAM). Nesta etapa, uma reação de substituição dos grupos hidroxila dos polímeros do amido foi realizada com o cloreto de acriloíla de forma a inserir insaturações na estrutura dos polímeros, para que estes fossem aplicados como reticulante. O sucesso da reação de modificação foi verificado através de RMN 1H e FTIR, no qual um maior grau de substituição foi obtido quando um tempo maior de reação foi empregado. Microgéis de p(NIPAM) foram então preparados através de polimerização em emulsão utilizando os reticulantes sintetizados. Observou-se a influência do grau de substituição e da concentração do reticulante nos microgéis, analisados por MEV, DLS e UV-Vis com controle de temperatura. As principais mudanças foram relativas à temperatura de transição de fase e tamanho dos microgéis. Utilizando o agente de reticulação com maior grau de substituição, foi possível deslocar a temperatura de transição de fase dos microgéis preparados para valores maiores (35 °C, cerca de 3 °C acima do valor determinado para sistemas contendo p(NIPAM) puro). Observou-se também uma resposta mecânica da rede do microgel, que refletiu no tamanho das partículas, influenciada pela concentração dos agentes de reticulação e do grau de substituição. Quanto maior a concentração e o grau de substituição do agente de reticulação, maior a resistência ao intumescimento observado no microgel. / This thesis presents the studies regarding the synthesis and characterization of thermoresponsive microgels of N-isopropylacrylamide (NIPAM) and amylaceous-based macromolecules, which are systems still little explored in the literature. At first, starch nanoparticles (SNP) were prepared by nanoprecipitation, through dissolution of starch granules in DMSO/H2O, ultrasound application and non-solvent precipitation. SNPs were then used as copolymer in SNP-co-p(NIPAM) hybrid microgels synthesized by emulsion polymerization in the presence and absence of surfactant. The influence of SNPs in microgel properties were studied by SEM, DLS, ZP, and SAXS, where changes in the physicalchemical behavior and supramolecular structure were observed. Summing up, shifts in the phase transition temperature up to 35 °C, increased colloidal stability, and microgel polymers organization into a core-shell structure were observed. Microgels swelling behaviour were also studied by the Flory-Rehner theory, where the theta-temperature and the degree of polymerization between two crosslinker points were determined through interaction parameter (χ) fitting. In parallel, a new starch-based crosslinker was studied. For this purpose, starch polymers (amylose and amylopectin within the SNPs) were modified in order to use them as crosslinker in p(NIPAM) microgel synthesis. In this step, a substitution reaction in hydroxyl groups of SNP was carried out with acryloyl chloride, where double bonds were attached in polymers structure, making it suitable as a crosslinker. Reaction performances were evaluated through 1H NMR and FTIR. Then, p(NIPAM) microgels were prepared by emulsion polymerization using the crosslinker synthesized. The degree of substitution and the crosslinker concentration influence were verified and analyzed by SEM, DLS and UV-Vis with temperature control. The main observed changes were related to the phase transition temperature e microgels size. Using the crosslinker with higher substitution degree, it was possible the shift of the phase transition temperature to higher values (~35 °C). A mechanical response, observed trough microgels size, was found, driven by the crosslinker concentration and substitution degree. As higher the concentration and substitution degree of the crosslinker, higher was the swelling resistance observed in microgel structure.

Amilopectina

Amilose

Nanoparticulas

Amido

Polimeros : Termodinamica

Starch polymers

Phase transition temperature

Microgel

N-isopropylacrylamide

Thermo-responsive polymer

Starch nanoparticles

Amylopectin

Amylose

Microgéis termo-responsivos preparados a partir dos polímeros do amido

Leite, Daiani Canabarro

January 2017

Esta tese apresenta os estudos realizados quanto à síntese e caracterização de microgéis termo-responsivos de N-isopropilacrilamida (NIPAM) e macromoléculas de origem amilácea em sua composição, sistemas ainda pouco explorados na literatura. Inicialmente, nanopartículas de amido (SNP) foram preparadas por nanoprecipitação para incorporação nos microgéis de interesse, através da dissolução dos grânulos do amido em DMSO/H2O, aplicação de ultrassom e precipitação em não-solvente. As SNPs preparadas foram utilizadas como copolímero para formação de microgéis híbridos do tipo SNP-co-p(NIPAM) através de polimerização em emulsão na presença e na ausência de surfactante. A influência das SNPs nas propriedades dos microgéis foi estudada por MEV, DLS, PZ e SAXS, onde foram observadas mudanças no comportamento físico-químico e estrutura supramolecular dos microgéis. No geral, observaram-se deslocamentos da temperatura de transição de fase para valores maiores (até 35 °C, cerca de 3 °C acima do valor determinado para sistemas contendo p(NIPAM) puro), aumento da estabilidade coloidal e organização dos polímeros presentes no microgel em uma arquitetura caroço-casca. As propriedades de inchamento dos microgéis também foram estudadas através da teoria de Flory-Rehner, onde a temperatura theta e o grau de polimerização entre dois pontos de reticulação foram determinados através do ajuste apropriado do parâmetro de interação (χ). Paralelamente, visando um sistema diferente do descrito acima, foi estudado um novo agente de reticulação baseado nos polímeros do amido, a amilose e a amilopectina. Para isso, os polímeros do amido que compõem as nanopartículas foram modificados para a utilização como agente de reticulação na síntese de microgéis de p(NIPAM). Nesta etapa, uma reação de substituição dos grupos hidroxila dos polímeros do amido foi realizada com o cloreto de acriloíla de forma a inserir insaturações na estrutura dos polímeros, para que estes fossem aplicados como reticulante. O sucesso da reação de modificação foi verificado através de RMN 1H e FTIR, no qual um maior grau de substituição foi obtido quando um tempo maior de reação foi empregado. Microgéis de p(NIPAM) foram então preparados através de polimerização em emulsão utilizando os reticulantes sintetizados. Observou-se a influência do grau de substituição e da concentração do reticulante nos microgéis, analisados por MEV, DLS e UV-Vis com controle de temperatura. As principais mudanças foram relativas à temperatura de transição de fase e tamanho dos microgéis. Utilizando o agente de reticulação com maior grau de substituição, foi possível deslocar a temperatura de transição de fase dos microgéis preparados para valores maiores (35 °C, cerca de 3 °C acima do valor determinado para sistemas contendo p(NIPAM) puro). Observou-se também uma resposta mecânica da rede do microgel, que refletiu no tamanho das partículas, influenciada pela concentração dos agentes de reticulação e do grau de substituição. Quanto maior a concentração e o grau de substituição do agente de reticulação, maior a resistência ao intumescimento observado no microgel. / This thesis presents the studies regarding the synthesis and characterization of thermoresponsive microgels of N-isopropylacrylamide (NIPAM) and amylaceous-based macromolecules, which are systems still little explored in the literature. At first, starch nanoparticles (SNP) were prepared by nanoprecipitation, through dissolution of starch granules in DMSO/H2O, ultrasound application and non-solvent precipitation. SNPs were then used as copolymer in SNP-co-p(NIPAM) hybrid microgels synthesized by emulsion polymerization in the presence and absence of surfactant. The influence of SNPs in microgel properties were studied by SEM, DLS, ZP, and SAXS, where changes in the physicalchemical behavior and supramolecular structure were observed. Summing up, shifts in the phase transition temperature up to 35 °C, increased colloidal stability, and microgel polymers organization into a core-shell structure were observed. Microgels swelling behaviour were also studied by the Flory-Rehner theory, where the theta-temperature and the degree of polymerization between two crosslinker points were determined through interaction parameter (χ) fitting. In parallel, a new starch-based crosslinker was studied. For this purpose, starch polymers (amylose and amylopectin within the SNPs) were modified in order to use them as crosslinker in p(NIPAM) microgel synthesis. In this step, a substitution reaction in hydroxyl groups of SNP was carried out with acryloyl chloride, where double bonds were attached in polymers structure, making it suitable as a crosslinker. Reaction performances were evaluated through 1H NMR and FTIR. Then, p(NIPAM) microgels were prepared by emulsion polymerization using the crosslinker synthesized. The degree of substitution and the crosslinker concentration influence were verified and analyzed by SEM, DLS and UV-Vis with temperature control. The main observed changes were related to the phase transition temperature e microgels size. Using the crosslinker with higher substitution degree, it was possible the shift of the phase transition temperature to higher values (~35 °C). A mechanical response, observed trough microgels size, was found, driven by the crosslinker concentration and substitution degree. As higher the concentration and substitution degree of the crosslinker, higher was the swelling resistance observed in microgel structure.

Amilopectina

Amilose

Nanoparticulas

Amido

Polimeros : Termodinamica

Starch polymers

Phase transition temperature

Microgel

N-isopropylacrylamide

Thermo-responsive polymer

Starch nanoparticles

Amylopectin

Amylose

Microgéis termo-responsivos preparados a partir dos polímeros do amido

Leite, Daiani Canabarro

January 2017

Esta tese apresenta os estudos realizados quanto à síntese e caracterização de microgéis termo-responsivos de N-isopropilacrilamida (NIPAM) e macromoléculas de origem amilácea em sua composição, sistemas ainda pouco explorados na literatura. Inicialmente, nanopartículas de amido (SNP) foram preparadas por nanoprecipitação para incorporação nos microgéis de interesse, através da dissolução dos grânulos do amido em DMSO/H2O, aplicação de ultrassom e precipitação em não-solvente. As SNPs preparadas foram utilizadas como copolímero para formação de microgéis híbridos do tipo SNP-co-p(NIPAM) através de polimerização em emulsão na presença e na ausência de surfactante. A influência das SNPs nas propriedades dos microgéis foi estudada por MEV, DLS, PZ e SAXS, onde foram observadas mudanças no comportamento físico-químico e estrutura supramolecular dos microgéis. No geral, observaram-se deslocamentos da temperatura de transição de fase para valores maiores (até 35 °C, cerca de 3 °C acima do valor determinado para sistemas contendo p(NIPAM) puro), aumento da estabilidade coloidal e organização dos polímeros presentes no microgel em uma arquitetura caroço-casca. As propriedades de inchamento dos microgéis também foram estudadas através da teoria de Flory-Rehner, onde a temperatura theta e o grau de polimerização entre dois pontos de reticulação foram determinados através do ajuste apropriado do parâmetro de interação (χ). Paralelamente, visando um sistema diferente do descrito acima, foi estudado um novo agente de reticulação baseado nos polímeros do amido, a amilose e a amilopectina. Para isso, os polímeros do amido que compõem as nanopartículas foram modificados para a utilização como agente de reticulação na síntese de microgéis de p(NIPAM). Nesta etapa, uma reação de substituição dos grupos hidroxila dos polímeros do amido foi realizada com o cloreto de acriloíla de forma a inserir insaturações na estrutura dos polímeros, para que estes fossem aplicados como reticulante. O sucesso da reação de modificação foi verificado através de RMN 1H e FTIR, no qual um maior grau de substituição foi obtido quando um tempo maior de reação foi empregado. Microgéis de p(NIPAM) foram então preparados através de polimerização em emulsão utilizando os reticulantes sintetizados. Observou-se a influência do grau de substituição e da concentração do reticulante nos microgéis, analisados por MEV, DLS e UV-Vis com controle de temperatura. As principais mudanças foram relativas à temperatura de transição de fase e tamanho dos microgéis. Utilizando o agente de reticulação com maior grau de substituição, foi possível deslocar a temperatura de transição de fase dos microgéis preparados para valores maiores (35 °C, cerca de 3 °C acima do valor determinado para sistemas contendo p(NIPAM) puro). Observou-se também uma resposta mecânica da rede do microgel, que refletiu no tamanho das partículas, influenciada pela concentração dos agentes de reticulação e do grau de substituição. Quanto maior a concentração e o grau de substituição do agente de reticulação, maior a resistência ao intumescimento observado no microgel. / This thesis presents the studies regarding the synthesis and characterization of thermoresponsive microgels of N-isopropylacrylamide (NIPAM) and amylaceous-based macromolecules, which are systems still little explored in the literature. At first, starch nanoparticles (SNP) were prepared by nanoprecipitation, through dissolution of starch granules in DMSO/H2O, ultrasound application and non-solvent precipitation. SNPs were then used as copolymer in SNP-co-p(NIPAM) hybrid microgels synthesized by emulsion polymerization in the presence and absence of surfactant. The influence of SNPs in microgel properties were studied by SEM, DLS, ZP, and SAXS, where changes in the physicalchemical behavior and supramolecular structure were observed. Summing up, shifts in the phase transition temperature up to 35 °C, increased colloidal stability, and microgel polymers organization into a core-shell structure were observed. Microgels swelling behaviour were also studied by the Flory-Rehner theory, where the theta-temperature and the degree of polymerization between two crosslinker points were determined through interaction parameter (χ) fitting. In parallel, a new starch-based crosslinker was studied. For this purpose, starch polymers (amylose and amylopectin within the SNPs) were modified in order to use them as crosslinker in p(NIPAM) microgel synthesis. In this step, a substitution reaction in hydroxyl groups of SNP was carried out with acryloyl chloride, where double bonds were attached in polymers structure, making it suitable as a crosslinker. Reaction performances were evaluated through 1H NMR and FTIR. Then, p(NIPAM) microgels were prepared by emulsion polymerization using the crosslinker synthesized. The degree of substitution and the crosslinker concentration influence were verified and analyzed by SEM, DLS and UV-Vis with temperature control. The main observed changes were related to the phase transition temperature e microgels size. Using the crosslinker with higher substitution degree, it was possible the shift of the phase transition temperature to higher values (~35 °C). A mechanical response, observed trough microgels size, was found, driven by the crosslinker concentration and substitution degree. As higher the concentration and substitution degree of the crosslinker, higher was the swelling resistance observed in microgel structure.

Amilopectina

Amilose

Nanoparticulas

Amido

Polimeros : Termodinamica

Starch polymers

Phase transition temperature

Microgel

N-isopropylacrylamide

Thermo-responsive polymer

Starch nanoparticles

Amylopectin

Amylose

Photopolymerization Synthesis of Magnetic Nanoparticle Embedded Nanogels for Targeted Biotherapeutic Delivery

Denmark, Daniel Jonwal

21 June 2017

Conventional therapeutic techniques treat the patient by delivering a biotherapeutic to the entire body rather than the target tissue. In the case of chemotherapy, the biotherapeutic is a drug that kills healthy and diseased cells indiscriminately which can lead to undesirable side effects. With targeted delivery, biotherapeutics can be delivered directly to the diseased tissue significantly reducing exposure to otherwise healthy tissue. Typical composite delivery devices are minimally composed of a stimuli responsive polymer, such as poly(N-isopropylacrylamide), allowing for triggered release when heated beyond approximately 32 °C, and magnetic nanoparticles which enable targeting as well as provide a mechanism for stimulus upon alternating magnetic field heating. Although more traditional methods, such as emulsion polymerization, have been used to realize these composite devices, the synthesis is problematic. Poisonous surfactants that are necessary to prevent agglomeration must be removed from the finished polymer, increasing the time and cost of the process. This study seeks to further explore non-toxic, biocompatible, non-residual, photochemical methods of creating stimuli responsive nanogels to advance the targeted biotherapeutic delivery field. Ultraviolet photopolymerization promises to be more efficient, while ensuring safety by using only biocompatible substances. The reactants selected for nanogel fabrication were N-isopropylacrylamide as monomer, methylene bisacrylamide as cross-linker, and Irgacure 2959 as ultraviolet photo-initiator. The superparamagnetic nanoparticles for encapsulation were approximately 10 nm in diameter and composed of magnetite to enable remote delivery and enhanced triggered release properties. Early investigations into the interactions of the polymer and nanoparticles employ a pioneering experimental setup, which allows for coincident turbidimetry and alternating magnetic field heating of an aqueous solution containing both materials. Herein, a low-cost, scalable, and rapid, custom ultraviolet photo-reactor with in-situ, spectroscopic monitoring system is used to observe the synthesis as the sample undergoes photopolymerization. This method also allows in-situ encapsulation of the magnetic nanoparticles simplifying the process. Size characterization of the resulting nanogels was performed by Transmission Electron Microscopy revealing size-tunable nanogel spheres between 50 and 800 nm by varying the ratio and concentration of the reactants. Nano-Tracking Analysis indicates that the nanogels exhibit minimal agglomeration as well as provides a temperature-dependent particle size distribution. Optical characterization utilized Fourier Transform Infrared and Ultraviolet Spectroscopy to confirm successful polymerization. When samples of the nanogels encapsulating magnetic nanoparticles were subjected to an alternating magnetic field a temperature increase was observed indicating that triggered release is possible. Furthermore, a model, based on linear response theory that innovatively utilizes size distribution data, is presented to explain alternating magnetic field heating results. The results presented here will advance targeted biotherapeutic delivery and have a wide range of applications in medical sciences like oncology, gene delivery, cardiology and endocrinology.

stimuli-responsive polymer

linear response theory

drug delivery

magnetic nanoparticle

composite device

alternating magnetic field

Materials Science and Engineering

Physics

Polymer Chemistry

Novel Linear and Star Poly(vinylidene fluoride)-Based Polymers: Synthesis, Characterization and Applications

Algarni, Fatimah

24 November 2022

Poly(vinylidene fluoride) PVDF is a semi-crystalline fluoropolymer that attracted researchers' attention more than a decade ago due to its remarkable properties, such as mechanical strength, thermal stability, chemical resistance, good processability, and excellent aging resistance. Due to these excellent properties, PVDF is applied in many applications such as membranes and filtration, biomedical applications, drug delivery, batteries, energy generation, energy storage, sensors, actuators, and energy harvesting applications. The dissertation was inspired by PVDF’s outstanding properties and applications. First of all, the effect of chain topology of on the crystallization and polymorphism between linear and star PVDF homopolymers were studied. Well-defined linear and stars PVDF homopolymers architectures were synthesized by reversible addition−fragmentation chain transfer (RAFT) polymerization. The non-isothermal crystallization study showed an increase in the amount of ferroelectric β-phase with respect to the paraelectric α-phase as the number of arms in the PVDF stars increases. This finding is explained by the increased topological complexity in the stars of several arms, which leads to the preferential formation of the less thermodynamically stable ferroelectric β-phase. Moreover, the isothermal crystallization kinetics of the PVDF stars was faster than the linear PVDF as a result of their speedier nucleation. Secondly, we report the synthesis of poly(n-isopropylacrylamide)-b-poly(vinylidene fluoride) (PNIPAM-b-PVDF), amphiphilic block copolymers with linear and star architectures by RAFT sequential living polymerization. Due to the presence of a lower critical solution temperature (LCST) for PNIPAM (coil-globule transition around 32 °C), the synthesized PNIPAM-b-PVDF block copolymers have thermo-responsive behavior, therefore, potential application in the fabrication of thermo-responsive membranes. All fabricated membranes by nonsolvent-induced phase separation (NIPS) method exhibited thermo-responsive behavior with water permeability and PEG rejection experiments. Moreover, the several heating-cooling cycles showed that the thermal-responsive behavior of these membranes are reversible and stable. Finally, a suggested potential future work is given to synthesize other PVDF-based block copolymers via sequential living polymerizations.

polyvinylidene fluoride

RAFT polymerization

Radical polymerization

Linear and Star Architectures

crystallization kinetics

polymorphism

topology

poly(n-isopropylacrylamide)

thermo-responsive polymer

membrane applications.

Lipid Bilayers Supported by Multi-Stimuli Responsive Polymers

Kaufmann, Martin

25 March 2013

Artificial lipid bilayers formed on solid surface supports are widespread model systems to study physical, chemical, as well as biological aspects of cell membranes and fundamental interfacial interactions. The approach to use a thin polymer film representing a cushion for lipid bilayers prevents incorporated membrane proteins from pinning to the support and mimics the native environment of a lipid bilayer in certain aspects of the extracellular matrix and intracellular structures. A key component for cell anchorage to extracellular fibronectin is the transmembrane adhesion receptor alpha(5)beta(1) integrin. Its transport dynamics and clustering behavior plays a major role in the assembly of focal adhesions, which mediate mechanical forces and biochemical signals of cells with their surrounding. The system investigated herein is envisioned to use extrinsically controlled stimuli-responsive polymer cushions to tune the frictional drag between polymer cushion and mobile membranes with incorporated integrins to actively regulate lipid membrane characteristics. To attain this goal, a temperature- and pH-responsive polymer based on poly(N-isopropylacrylamide) copolymers containing varying amounts of carboxyl-group-terminated comonomers at different aliphatic spacer lengths (PNIPAAm-co-carboxyAAM) was surface-grafted to a poly(glycidyl methacrylate) anchorage layer. The swelling transitions were characterized using atomic force microscopy, ellipsometry and quartz crystal microbalance with dissipation monitoring (QCM-D) and found to be tunable over a wide range of temperature and pH. In agreement with the behavior of the polymers in solution, longer alkyl spacers decreased the phase transition temperature T(P) and higher contents of carboxylic acid terminated comonomers increased T(P) at alkaline conditions and decreased T(P) at acidic conditions. Remarkably, the point where the degree of carboxyl group deprotonation balances the T(P)-lowering effect of the alkyl spacer was distinctive for each alkyl spacer length. These findings illustrate how the local and global balance of hydrophilic and hydrophobic interactions along the copolymer chain allows to adjust the swelling transition to temperatures below, comparable, or above those observed for PNIPAAm homopolymers. Additionally, it could be shown that surface-grafting leads to a decrease in T(P) for PNIPAAm homopolymers (7°C) and copolymers (5°C - 10°C). The main reason is the increase in local polymer concentration of the swollen film constrained by dense surface anchorage in comparison to the behavior of dilute free chains in solution. In accordance with the Flory-Huggins theory, T(P) decreases with increasing concentration up to the critical concentration. Biological functionalization of the PNIPAAm-co-carboxyAAm thin films was demonstrated for the cell adhesion ligand peptide cRGD via carbodiimide chemistry to mimic extracellular binding sites for the cell adhesion receptors integrin. The outcome of QCM-D measurements of cRGD-functionalized surfaces showed a maintained stimuli-responsiveness with slight reduction in T(P). A drying/rehydration procedure of a 9:1 lipid mixture of the cationic lipid dioleoyl-trimethylammoniumpropane (DOTAP) and the zwitterionic dioleoyl-phosphatidylcholine (DOPC) was utilized to form lipid bilayer membranes on PNIPAAm-co-carboxyAAM cushions. Fluorescence recovery after photobleaching (FRAP) revealed that lipid mobility was distinctively higher (6.3 - 9.6) µm2 s-1 in comparison to solid glass support ((3.0 - 5.9) µm2 s-1). In contradiction to the initial expectations, modulation of temperature and pH led to poor variations in lipid mobility that did not correlate with the PNIPAAm cushion swelling state. The results suggested a weak coupling of the lipid bilayer with PNIPAAm polymer cushions that can be slightly tuned by electrostatic interactions. The transmembrane adhesion receptor alpha(5)beta(1) integrin was reconstituted into liposomes consisting of DOPC/sphingomyelin/cholesterol 2:2:1 for the formation of polymer cushioned bilayers. PNIPAAm- co-carboxyAAM and maleic acid (MA) copolymers were used as cushions, both with the option for cRGD functionalization. On the MA copolymer cushions, fusion of proteoliposomes resulted in supported bilayers with mobile lipids as confirmed by FRAP. However, incorporated integrins were immobile. In an attempt to explain this observation, the medium-sized cytoplasmic integrin domain was accounted to hamper the movement by steric interactions with the underlying polymer chains in conjunction with electrostatic interactions of the cationic cytoplasmic domain with the oppositely charged MA copolymer. On the PNIPAAm-co-carboxyAAM cushion only a drying/rehydration procedure lead to bilayer formation. However, again the integrins were immobile, presumably due to the harsh treatment during preparation. Nevertheless, the results of the investigated set of PNIPAAm copolymer films suggest their application as temperature- and pH-responsive switchable layers to control interfacial phenomena in bio-systems at different physiological conditions. The PNIPAAm-co-carboxyAAm cushioned bilayer system represents a promising step towards extrinsically controlled membrane – substrate interactions.

Polymerkissen

Stimuliresponsive Polymerfilme

PNIPAAm

QCM-D

Lipiddoppelschichten

alpha(5)beta(1) Integrin

FRAP

polymer cushion

stimuli responsive polymer films

PNIPAAm

QCM-D

lipid bilayer

alpha(5)beta(1) integrin

FRAP

ddc:540

rvk:VK 8007

Etude des propriétés interfaciales et luminescentes de microgels stimulables. / Study of interfacial and luminescent properties of stimuli-sensitive microgels

Pinaud, Florent

09 June 2015

Les microgels sont des particules colloïdales de polymère réticulé gonflées par un solvant. Déformables et poreuses, elles peuvent changer d’état de gonflement lors de l’application d’un stimulus. Ce travail de thèse a pour but de développer de nouveaux concepts tirant profit des propriétés stimulables et de la déformabilité intrinsèque des microgels tout en approfondissant les connaissances sur le comportement de ces objets en solution et aux interfaces. Les microgels de poly(N-alkylacrylamide) sont utilisés comme modèles. Dans un premier temps, notre travail a porté sur l’étude d’un nouveau type de microgels électrochimiluminescents grâce à l’incorporation d’un complexe métallique de ruthénium dans la matrice polymère. A la transition de phase, ces microgels présentent une exaltation de l’intensité ECL jusqu’à 2 ordres de grandeur, en lien avec la distance entre les sites redox. Le concept est ensuite transposé à des microgels sensibles aux saccharides et à des systèmes comportant deux luminophores, un donneur ECL et un accepteur d’énergie pouvant donner lieu à un transfert d’énergie par résonance. La deuxième partie de la thèse est consacrée à l’adsorption de microgels à une interface liquide-liquide plane, en vue de mieux comprendre l’origine de la stabilité des émulsions stabilisées par ce genre d’objets. De façon analogue aux protéines flexibles, les microgels changent de conformation à l’interface, passant d’un état étendu à un état comprimé, à l’origine de variations de l’élasticité interfaciale. Les microgels ainsi adsorbés sont fonctionnalisés de façon régiosélective dans l’eau et permettent de produire des microgels non symétriques, dits Janus, susceptibles de s’auto-assembler. / Microgels are colloidal particles made of cross-linked polymer swollen by a solvent. Soft and porous, they can adapt their swelling degree in response to a stimulus. The main objective of this work is to develop new concepts taking advantage of microgels’ stimuli-responsive properties and intrinsicsoftness while deepening understanding of their properties in solution and at interfaces. Poly(Nalkylacrylamide) microgels are used as a model. Initially our work focused on the study of a new type of electrochemiluminescent (ECL) microgels thanks to the incorporation of a ruthenium complex in the polymer matrix. At the volume phase transition, these microgels exhibit an amplification of the ECL intensity up to 2 orders of magnitude, related to the decrease of the distance between redox sites. This concept is then transposed to saccharides-sensitive microgels and systems bearing two luminophores, an ECL donor and an energy acceptor in order to give rise to resonance energy transfer. The second part of this manuscript is devoted to adsorption of microgels at a planar liquid-liquid interface, to improve knowledge on the origin of the stability of emulsions stabilized by such objects. Such as flexible proteins, microgels can change their conformation at the interface, from an extended to a compressed state, causing variation in the interfacial elasticity. When microgels are adsorbed they can also be functionalized regioselectively in water to produce non-symmetrical microgels, called Janus, able to self-assemble.

Microgels

Microgels Janus

Élasticité interfaciale

Film de Langmuir

Émulsion de Pickering

Transfert d’énergie

Photoluminescence

Électrochimiluminescence

Polymère stimulable

Particule déformable

Microgels

Janus microgels

Interfacial elasticity

Langmuir film

Pickering emulsion

Energy transfer

Photoluminescence

Electrochemiluminescence

Stimuli-responsive polymer

Soft particle

From photosensitive glycopolymers to smart drug delivery systems / Des glycopolymères photosensibles aux systèmes de libération stimulable de principes actifs

Soliman, Soliman Mehawed Abdellatif

31 October 2014

Des glycopolymères greffés et dibloc, amphiphiles et photosensibles, à base de poly(acrylate d'o-nitrobenzyle) (PNBA) hydrophobe et photoclivable et de dextrane hydrophile ont été préparés avec succès en utilisant notammennt une réaction d'Huisgen (Cycloaddition Azoture-Alcyne catalysée par le Cuivre (I) - CuAAC chimie click). Dans un premier temps, la polymérisation de l'acrylate d'o-nitrobenzyle a été contrôlée avec succès grâce aux développements récents de la polymérisation radicalaire vivante par transfert d'un seul électron (SET-LRP). Nous avons alors obtenu un PNBA fonctionnalisé à son extrémitié par un brome. Ce brome a ensuite été substitué par un groupe azido. En parallèle, le dextrane a été modifié pour y introduire plusieurs fonctions alcyne (dextrane alcyne) ou une seule sur son extrémité réductrice (dextrane α-alcyne). Nous avons ensuite fait réagir ces dérivés de dextrane avec le PNBA-N3 pour obtenir respectivement les glycopolymères greffés et dibloc. Tous les glycopolymères ont été caractérisés par chromatographie d'exclusion stérique (SEC), Résonnance Magnétique Nucléaire 1H, 13C, 2D DOSY 1H et par spectrométrie FT-IR. Dans un deuxième temps, nous avons optimisé les conditions pour obtenir des nanoparticules peu disperses à partir des précédents glycopolymères. Dans certains cas, des nanoparticules ont également été obtenues en utilisant le dextrane alcyne et le PNBA-N3 dans un procédé d'émulsion/évaporation de solvant organique. La stabilité de toutes les nanoparticules vis-à-vis de solutions aqueuses de diverses forces ioniques ou d'un tensioactif compétitif a été étudiée. Enfin, l'effet de la lumière sur ces nanoparticules photosensibles a été mis en évidence à l'aide de la lampe UV. Plus précisément, nous avons pu suivre la destruction des nanoparticules par spectroscopie de fluorescence et diffusion de lumière dynamique en encapsulant le Rouge du Nil (sonde fluorescente) au sein de ces particules / Photosensitive grafted and diblock amphiphilic glycopolymers based on hydrophobic photosensitive poly(o-nitrobenzyl acrylate) (PNBA) and hydrophilic dextran were successfully prepared via grafting onto techniques through a Huisgen-type Copper(I) catalyzed Azide-Alkyne Cycloaddition (CuAAC click chemistry). Firstly, recent developments in the single-electron transfer–living radical polymerization (SET–LRP) provided us an access to control the o-nitrobenzyl acrylate polymerization and we obtained PNBA with bromide end function. Then, this bromide end function was replaced by azido (N3) group. In a parallel way, we modified dextran by introducing several alkyne groups all long the polysaccharide chain (alkynated dextran) or only one group at the reducing end-chain (α-alkyne dextran). In the second step, alkynated dextran and α-alkyne dextran were reacted with PNBA-N3 by CuAAC to obtain grafted or diblock glycopolymers. All glycopolymers were characterized by Size Exclusion Chromatography, 1H, 13C, 2D DOSY 1H NMR and FT-IR spectroscopy. Secondly, conditions to formulate nanoparticles from the previous glycopolymers were optimized. In some case, we also carried out an emulsion/evaporation process using dextran alkynated and PNBA-N3 to produce nanoparticles. Then, stability of nanoparticles were studied over rang of ionic strengths as well as stability in presence of a competitive surfactant. Finally, the effect of light on these photosensitive nanoparticles was studied using UV-lamp. More precisely, we loaded these nanoparticules by Nile Red fluorescent dye and followed thier destruction by using fluorescence spectroscopy and Dynamic Light Scattering

Glycopolymère

Greffé

Dibloc

Photosensible

Amphiphile

Nanoparticule

Acrylate o-nitrobenzyle

SET-LRP

Dextrane

Chimie click

Glycopolymer

Grafted

Diblock

Photosensitive

Amphiphilic

Nanoparticle

O-nitrobenzyl acrylate

SET-LRP

Dextran

Click chemistry

Light-responsive polymer

547.7

668.9

Lipid Bilayers Supported by Multi-Stimuli Responsive Polymers

Kaufmann, Martin

08 February 2013

Artificial lipid bilayers formed on solid surface supports are widespread model systems to study physical, chemical, as well as biological aspects of cell membranes and fundamental interfacial interactions. The approach to use a thin polymer film representing a cushion for lipid bilayers prevents incorporated membrane proteins from pinning to the support and mimics the native environment of a lipid bilayer in certain aspects of the extracellular matrix and intracellular structures. A key component for cell anchorage to extracellular fibronectin is the transmembrane adhesion receptor alpha(5)beta(1) integrin. Its transport dynamics and clustering behavior plays a major role in the assembly of focal adhesions, which mediate mechanical forces and biochemical signals of cells with their surrounding. The system investigated herein is envisioned to use extrinsically controlled stimuli-responsive polymer cushions to tune the frictional drag between polymer cushion and mobile membranes with incorporated integrins to actively regulate lipid membrane characteristics. To attain this goal, a temperature- and pH-responsive polymer based on poly(N-isopropylacrylamide) copolymers containing varying amounts of carboxyl-group-terminated comonomers at different aliphatic spacer lengths (PNIPAAm-co-carboxyAAM) was surface-grafted to a poly(glycidyl methacrylate) anchorage layer. The swelling transitions were characterized using atomic force microscopy, ellipsometry and quartz crystal microbalance with dissipation monitoring (QCM-D) and found to be tunable over a wide range of temperature and pH. In agreement with the behavior of the polymers in solution, longer alkyl spacers decreased the phase transition temperature T(P) and higher contents of carboxylic acid terminated comonomers increased T(P) at alkaline conditions and decreased T(P) at acidic conditions. Remarkably, the point where the degree of carboxyl group deprotonation balances the T(P)-lowering effect of the alkyl spacer was distinctive for each alkyl spacer length. These findings illustrate how the local and global balance of hydrophilic and hydrophobic interactions along the copolymer chain allows to adjust the swelling transition to temperatures below, comparable, or above those observed for PNIPAAm homopolymers. Additionally, it could be shown that surface-grafting leads to a decrease in T(P) for PNIPAAm homopolymers (7°C) and copolymers (5°C - 10°C). The main reason is the increase in local polymer concentration of the swollen film constrained by dense surface anchorage in comparison to the behavior of dilute free chains in solution. In accordance with the Flory-Huggins theory, T(P) decreases with increasing concentration up to the critical concentration. Biological functionalization of the PNIPAAm-co-carboxyAAm thin films was demonstrated for the cell adhesion ligand peptide cRGD via carbodiimide chemistry to mimic extracellular binding sites for the cell adhesion receptors integrin. The outcome of QCM-D measurements of cRGD-functionalized surfaces showed a maintained stimuli-responsiveness with slight reduction in T(P). A drying/rehydration procedure of a 9:1 lipid mixture of the cationic lipid dioleoyl-trimethylammoniumpropane (DOTAP) and the zwitterionic dioleoyl-phosphatidylcholine (DOPC) was utilized to form lipid bilayer membranes on PNIPAAm-co-carboxyAAM cushions. Fluorescence recovery after photobleaching (FRAP) revealed that lipid mobility was distinctively higher (6.3 - 9.6) µm2 s-1 in comparison to solid glass support ((3.0 - 5.9) µm2 s-1). In contradiction to the initial expectations, modulation of temperature and pH led to poor variations in lipid mobility that did not correlate with the PNIPAAm cushion swelling state. The results suggested a weak coupling of the lipid bilayer with PNIPAAm polymer cushions that can be slightly tuned by electrostatic interactions. The transmembrane adhesion receptor alpha(5)beta(1) integrin was reconstituted into liposomes consisting of DOPC/sphingomyelin/cholesterol 2:2:1 for the formation of polymer cushioned bilayers. PNIPAAm- co-carboxyAAM and maleic acid (MA) copolymers were used as cushions, both with the option for cRGD functionalization. On the MA copolymer cushions, fusion of proteoliposomes resulted in supported bilayers with mobile lipids as confirmed by FRAP. However, incorporated integrins were immobile. In an attempt to explain this observation, the medium-sized cytoplasmic integrin domain was accounted to hamper the movement by steric interactions with the underlying polymer chains in conjunction with electrostatic interactions of the cationic cytoplasmic domain with the oppositely charged MA copolymer. On the PNIPAAm-co-carboxyAAM cushion only a drying/rehydration procedure lead to bilayer formation. However, again the integrins were immobile, presumably due to the harsh treatment during preparation. Nevertheless, the results of the investigated set of PNIPAAm copolymer films suggest their application as temperature- and pH-responsive switchable layers to control interfacial phenomena in bio-systems at different physiological conditions. The PNIPAAm-co-carboxyAAm cushioned bilayer system represents a promising step towards extrinsically controlled membrane – substrate interactions.

info:eu-repo/classification/ddc/540

ddc:540

Applications of Styrenic Thermoplastic Elastomers in Stimuli Responsive Dynamically Porous Materials and Ice Anti-Slip Composites

Namdari, Navid

January 2021

No description available.

Engineering

Materials Science

Mechanical Engineering

Polymers

Thermoplastic elastomers

responsive polymers

optical functional polymers

slip-resistance

winter safety

surface texturing

ice traction

nanocomposite surfaces