Préparation et caractérisation de nouveaux amphiphiles fonctionnalisés par des oligo-et polysaccharides / Preparation and characterization of new amphiphilic functionalized by (oligo-and polysaccharides)

Dal -Bó, Alexandre Gonçalves

25 April 2011

Ce travail de thèse décrit la préparation et l'étude des propriétés d'auto-assemblage de nouveaux amphiphiles fonctionnalisés par des sucres. Des glycosides propargyliques du lactose et de la N-acétyl-glucosamine ont été conjugués par chimie click (cycloaddition de Huisgen catalysée par des sels de cuivre) à des dérivés de poly(ethyleneglycol) dont une des extrémités a au préalable été modifiée par une fonction azide et l'autre par un bloc hydrophobe de type polyphénylène ou bien aliphatique. Après une caractérisation par résonance magnétique nucléaire et spectrométrie de masse, les propriétés d'auto-assemblage de ces amphiphiles ont été étudiées par diffusion dynamique de la lumière (DLS), diffraction des rayons-X aux petits angles (SAXS) et microscopie électronique. Il a été montré qu'en phase aqueuse, les systèmes amphiphiles dérivés du PEG 900 s'auto-assemblent pour former de micelles de taille extrêmement régulière dont le diamètre moyen est de l'ordre de 10 nm. La présence et la biodisponibilité des sucres à la surface de ces nanoparticules ont également pu être démontrées par diffusion dynamique de la lumière avec les lectines PNA et WGA. Les interactions spécifiques observées entre les lectines et micelles associées aux propriétés d'encapsulation de ce type de nanoparticules permettent d'imaginer de futures applications pour la délivrance de médicaments ou encore l'imagerie médicale. / This thesis reports the preparation and characterization of new rod-coil amphiphiles functionalized with oligo- and polysaccharides through Huisgen 1,3-dipolar cycloaddition reactions between species functionalized by an azide group on one side and an terminal alkyne on the other catalyzed by copper. The amphiphiles were synthesized and characterized based on different hydrophobic parts conjugated with the polymer poly(ethylene oxide) PEO with a hydrophilic spacer arm and the oligo- and polyssaccharides 2-propargyl-2-acetamido-2-deoxy-β-D-glucopyranose (GlcNAc) and propargyl β-D-galactopyranosyl-(14)-β-D-glucopyranose (Lac). The amphiphiles synthesized were characterized in terms of their chemical structure and composition through nuclear magnetic resonance (NMR), Fourier transform infrared (FTIR) spectroscopy, mass spectroscopy (MALDI-TOF-MS and ESI-MS) and high resolution mass spectroscopy (HRMS). After the dissolution in water, the amphiphiles self-associate in highly regular micelles with an average diameter of 2RH ~ 10 nm. Dynamic light scattering (DLS), transmission electron microscopy (TEM) and small angle x-ray scattering (SAXS) were used in order to investigate the structure and dynamics of these saccharide amphiphiles. The presence of carbohydrate epitopes on the surface of the micelles and their bioavailability for the segmentation of lectin were also demonstrated by DLS. Specific interactions of GlcNAc and Lac residues with lectins from wheat germ agglutinin (WGA) and peanut agglutinin (PNA), respectively, reveal the potential applications of such amphiphilic derivatives of carbohydrates as vectorizing systems, both simple and specific to a drug delivery site.

Nanoparticles

Amphiphiles

Oligo-et polysaccharides

Amphiphilic

Oligo-and polysaccharides

Nanoparticles

540

530

Copolímeros de metacrilato de alquila e metacrilato de sacarose sintetizados via ATRP / Copolymers of alkyl methacrylate and sucrose methacrylate synthesized by ATRP

Almeida, Paula de, 1988-

27 August 2018

Orientador: Maria Isabel Felisberti / Dissertação (mestrado) - Universidade Estadual de Campinas, Instituto de Química / Made available in DSpace on 2018-08-27T10:33:06Z (GMT). No. of bitstreams: 1 Almeida_Paulade_M.pdf: 6180977 bytes, checksum: f368e755fcabe313d658156fe84a828e (MD5) Previous issue date: 2015 / Resumo: Neste trabalho foram sintetizados copolímeros anfifílicos e em bloco baseados em metacrilato de sacarose (SMA) e nos metacrilatos de alquila (MAlq): metacrilato de etila (EMA), metacrilato de n-butila (BMA) e metacrilato de n-hexila (HMA), via polimerização radicalar por transferência de átomo (ATRP). Para tal, utilizou-se o sistema catalítico catalisador/desativador/iniciador/ligante constituído de CuBr/CuBr2/2,2,2-tribromoetanol/1,1,4,7,10,10-hexametiltrietilenotetramina. Este sistema catalítico é inédito para a polimerização do EMA, BMA e HMA e dos copolímeros. A polimerização dos MAlq pode ser considerada viva, pois seguiu cinética de polimerização de pseudo-primeira ordem, gerando-se polímeros com polidispersidade estreita (PDI<1,3), massa molar pré-determinada e funcionalizados. A constante de velocidade de polimerização segue a ordem kEMA>kBMA>kHMA, ordem inversa do relatado para a polimerização radicalar livre. Os copolímeros inéditos [P(MAlq-b-SMA)] foram sintetizados, apresentando distribuição bimodal de massa molar, devido à copolimerização parcial dos macroiniciadores. Supõe-se que as cadeias dos macroiniciadores fiquem encapsuladas em agregados dos copolímeros durante a síntese, impossibilitando sua reação. As análises de GPC utilizando os solventes DMF e THF para um mesmo copolímero resultaram em massas molares diferindo entre si de cerca de 10 vezes, sugerindo que os copolímeros se agregam ou se auto-organizam em solução de DMF/THF a 5DMF:95THF (v/v). O caráter anfifílico foi comprovado pela estabilização de uma emulsão de água e benzeno. Demais propriedades físico-químicas dos copolímeros, tais como solubilidade, intumescimento, temperatura de transição vítrea, variação da capacidade calorífica e estabilidade térmica, são distintas a dos respectivos macroiniciadores, evidenciando as mudanças de propriedades dos polímeros devido à inserção de SMA / Abstract: In the present work, amphiphilic block copolymers based on sucrose methacrylate (SMA) and the alkyl methacrylates (MAlq): ethyl methacrylate (EMA), n-butyl methacrylate (BMA) and n-hexyl methacrylate (HMA), were synthesized by atom transfer radical polymerization (ATRP), employing the CuBr/CuBr2/2,2,2-tribromoethanol/1,1,4,7,10,10-hexamethyltriethylenetetramine as a catalyst/ deactivator/initiator/ligant system. This is a novel system for polymerizing EMA, BMA, HMA and their copolymers. This MAlq polymerization may be considered "living", because it followed a pseudo-first order kinetics, which resulted in polymer with narrow polidispersity (PDI<1,3), controlled molar mass and preserved chain end functionality. The apparent rate constants of the polymerization were found to follow the kEMA>kBMA>kHMA order, which is the opposite order reported in free radical polymerization. The novel copolymers [P(MAlq-b-SMA)] were synthesized, showing bimodal molar mass distribution, due to partial PMAlq copolymerization. Possibly, PMAlq chains are encapsulated into copolymer aggregates during polymerization, stopping its reaction. GPC analysis with DMF and THF as solvents differed in molar mass about 10 times, suggesting that copolymers can organize in a 5DMF:95THF (v/v) DMF/THF solution. The stabilization of a water and benzene emulsion proved the copolymers amphiphilicity. Other copolymer physical-chemistry properties, such as solubility, swelling, glass transition temperature, heat capacity change and thermal stability are different when compared to the macroinitiators, which is an evidence of change in polymer properties due to SMA monomer insertion. / Mestrado / Físico-Química / Mestra em Química

Metacrilato de sacarose

Glicopolímero

Anfifílico

ATRP

Sucrose methacrylate

Glycopolymer

Amphiphilic

ATRP

Konformační chování větvených polymerů / Conformational behavior of branched polymers

Wang, Xiu

January 2017

This PhD thesis is devoted to the study of the conformational behavior of branched polymers in confined volumes. This behavior depends not only on polymer architecture and composition but also on steric confinement and on interaction of polymer segments with the confining wall. Better understanding of complex entropy-to-enthalpy interplay can elucidate the mechanism of the chromatographic separation at the microscopic level. An unambiguous size-exclusion chromatography (SEC) analysis of mixtures containing different polymer architectures is difficult because the sizes of polymer coils, which determine the separation, depend not only on molar mass but also on the polymer architecture. Modern chromatographic methods combine the SEC with the interaction chromatography (IC). They exploit the fact that polymer interactions with pore walls, which are the prerequisite for efficient IC separation, depend strongly on polymer architecture. The knowledge of the conformational behavior of linear and branched polymers in confined volumes and of their interactions with confining medium enables to find optimum conditions either for enhancing or for suppressing the role of individual factors that influence the separation. We have shown that the complex entropy-to-enthalpy interplay in polymer solutions in confined...

Protective Strategies for Enhancing Engraftment of Insulin Releasing Cells / 移植インスリン分泌組織の機能維持に適した環境の構築法

Takemoto, Naohiro

24 March 2014

京都大学 / 0048 / 新制・課程博士 / 博士(工学) / 甲第18289号 / 工博第3881号 / 新制||工||1595(附属図書館) / 31147 / 京都大学大学院工学研究科高分子化学専攻 / (主査)教授 岩田 博夫, 教授 木村 俊作, 教授 秋吉 一成 / 学位規則第4条第1項該当 / Doctor of Philosophy (Engineering) / Kyoto University / DFAM

Biomaterials

Amphiphilic polymer

Cell surface modification

Cell transplantation

500

Phase Behaviors and Janus Hierarchical Supramolecular Structures Based on Geometrically and Chemically Asymmetric Building Blocks

Sun, Hao-Jan

02 May 2012

No description available.

Organic Chemistry

Polymers

amphiphilic bisamide

amphiphile

supramolecular structure

hierarchical structure

Functionalized Hyperbranched Polymers And Nonionenes

Roy, Raj Kumar

07 1900

In 1980’s a new class of material named as dendrimer became popular both in the field of polymer science and engineering. Dendrimer is an example of symmetric, highly branched three dimensional globular nano-object. It possess several interesting physical and chemical properties like low solution and melt-viscosity, lower intermolecular chain entanglement, large number of end groups placed at the molecular periphery, relatively high solubility with respect to their linear counterpart. In order to get this perfectly branched structure, one has to go through the tedious multistep synthetic approach, repetitive chromatographic purification and protection-deprotection strategies in every step; all of which limits the large scale production and thus commercialization. On the other hand, hyperbranched polymer, a highly branched analogue of dendritic polymer with few defects in their branching architecture, which can be prepared in a single step, show similar physical and chemical properties as that of dendrimer. Polymerization of AB2 monomer is one of the well established method to generate hyperbranched polymer which upon polymerization, generates plenty of ‘B ’groups at the periphery along with a single ‘A’ group as a focal point in the resulting hyperbranched polymer as shown in Figure 1. From the structural point of view, hyperbranched polymers consist of three distinctly different compartments such as periphery, interior and a (single) focal point. During the past decade our lab have developed a novel melt trans-etherification process to generate polyethers and have utilized to access to a wide variety of hyperbranched structures. One of the challenges we addressed is to selectively functionalize the periphery of the hyperbranched polymer during the polymerization process. Polycondensation of ‘AB2’ monomer is not sufficient enough to generate a wide variety of hyperbranched polymer as the periphery of hyperbranched polymer is limited to the ‘B’ functional group unless it could be modified via ‘post-polymerization modifications’. Copolymerization of ‘AB2’ monomer with stoichiometric amount of ‘A-R’ monomer should result in hyperbranched polymer decorated with ‘R’ groups in the periphery that can be prepared in a single step. One of the prerequisite in the ‘AB2+A-R’ approach is that the comonomer ‘A-R’ should have silent ‘R’ group which does not interfere during the polymerization. During the copolymerization process with stoichiometric amount of ‘A-R’ monomer, ‘AB2’ monomer having one equivalent excess of ‘B’ can react with the ‘A’ group from ‘A-R’ monomer eventually generating the hyperbranched structure with peripheral ‘R’ groups. By appropriately choosing the ‘R’ group, one can access a wide class of hyperbranched polymer with the required functionality. Further by having a reactive ‘R’ group that is not participating in polymerization can act as a handle for post-polymerization modifications. For instance, copolymerization of 1-(6-Hydroxyhexyloxy)-3,5-bis(methoxymethyl)-2,4,6-trimethylbenzene (Hydroxy as ‘A’ and methoxy as ‘B’) and 6-bromo-1-hexanol where ‘OH’ and ‘-(CH2)6Br’ is ‘A’ and ‘R’ functional groups respectively, generates hyperbranched polymer with peripheral alkyl bromide functional groups as shown in Figure 2. The peripheral alkylbromides has been quantitatively transformed to quaternary ammonium or pyridinium salts using trimethyl amine or pyridine respectively. Thus by the post polymerization modification, we have transformed a hydrophobic hyperbranched polymer to a water soluble cationic hyperbranched polymer by simple and efficient post-polymerization modification. In a slightly different objective we Another problem that I have addressed is the difficulty associated with the aforementioned copolymerization approach. In spite of the fact that stoichiometric amounts of ‘A-R’ type monomer was taken in ‘AB2 + A-R’ approach, the extent of peripheral functionalization i.e. the incorporation of ‘R’ group is relatively lower. Further the molecular weight of the hyperbranched polymer obtained is also not high. One of the reasons we adopted ‘AB2 + A-R’ approach is to provide a functional handle for the subsequent post-polymerization modification. We modified the ‘AB2’ type monomer with a functionalizable handle to circumvent the lower amount of incorporation of the ‘A-R’ type monomer in ‘AB2 + A-R’ approach. Of all the readily functionalizable handles, click chemistry found to be a very useful tool for the post-polymerization modifications as the reactions conditions are mild, no side product, high selectivity, easy purification, etc. Another advantage of this reaction is that, we can incorporate any type of functional group starting from a single clickable parent hyperbranched polymer. In this particular project, I have Earlier design of the ‘AB2’ type monomer in our group, to prepare hyperbranched polymer via melt transetherification process, involved benzylic methoxy groups as ‘B’ in ‘AB2’ monomer leading to a hyperbranched polymer with peripheral methoxy groups. Transetherification under melt-conditions is an equilibrium reaction which was driven towards the hyperbranched polymer by continuous removal of methanol from the system as a volatile alcohol. In the new design of ‘AB2’ monomer; we have used benzylic allyloxy groups as ‘B’ in ‘AB2’ monomer, where in polymerization is driven by the continuous removal of allyl alcohol (instead of methanol as in the previous case), generates hyperbranched polymer with peripheral allyloxy group containing hyperbranched polymer. The allyloxy groups can be subsequently functionalized with a variety of thiol, we prepared a hydrocarbon-soluble octadecyl-derivative, amphiphilic systems using 2-mercaptoethanol and chiral amino acid (N-benzoyl cystine) hyperbranched structures by using thiol-ene click reactions (Figure 3). Polymers prepared from the parent hyperbranched polymer have significantly different physical properties like glass transition temperature (Tg), melting point (Tm) etc; thus considering the versatility of functionalization, parent polymer could be envisioned as a clickable hyperscaffold. More interestingly by functionalizing cystine derivative, we have demonstrated the possibility of biconjugation of the hyperbranched polymer. In summary, the limitations of ‘AB2+A-R’ copolymerization approach (low molecular weight Molecular weight and molecular weight distribution are very important parameters that influence the physical property and thus the application of the polymeric materials. As predicted by Flory, hyperbranched polymers are inherently polydisperse in nature and it tends to infinity when the percent of conversion is very high. Experimentally observed value of polydispersity is also significantly higher compared to their linear analogues. Control of the molecular weight and polydispersity of hyperbranched polymer by using a suitable amount of reactive multifunctional core has been demonstrated in this project. We have substantiated by using very little amount of ‘B3’ core along with ‘AB2’ monomer; wherein ‘B’ in ‘B3’ are more reactive than ‘B’ in ‘AB2’ monomer, regulate the molecular weight and polydispersity of the resulting hyperbranched polymer. As the ratio of core to monomer increases the molecular weight and polydispersity reduces in nearly linear fashion. In a slightly different objective, the core and periphery are functionalized with two different fluorophore by using orthogonal click reactions and demonstrated the possibility of energy transfer from periphery to the core of the hyperbranched polymer. In this section of my thesis, the self-assembly behavior of a periodically grafted amphiphilic copolymer has been studied. Polymer was synthesized via melt transesterification approach where hexaethylene glycol monomethyl ether (HEG) containing diester monomers are reacted with alkylyne diol monomers with varying carbon spacer (C12 and Another interesting problem, I approached is to functionalize the interior part of the hyperbranched polymer. In the case of dendrimer, as it is a step-wise synthesis, internal functionalization could be accomplished with the order of monomer addition i.e. by putting the internal functional group containing monomer first followed by other monomer not having those functional groups, whereas it is a bit challenging task for hyperbranched polymers especially when dealing with polycondensation of AB2 monomers, as it is a single step polymerization process. For a hyperbranched polymer in the polycondensation of ‘AB2’ monomer, the internal functional group should reside in between of the ‘A’ and ‘B’ functional group wherein the internal functional groups are silent during the process of polymerization. In order to do so, we have designed and synthesized a new AB2 monomer (a in Figure: 4). Here decanol is the volatile condensate that was removed during the transetherification reactions leading to a hyperbranched polymer having allyl group as the internal functional group and decyloxy as the peripheral functional group (b in Figure: 4). As a post-polymerization modification, the interior allyl groups were modified by thiol-ene click reaction with variety of thiol derivatives. In one example, the inherent hydrophobic nature of the parent hyperbranched polymer which is enhanced by the decyl chain at the molecular periphery, is converted to a alkaline water soluble hyperbranched polymer by the click reaction with mercapto succinic acid (d in Figure: 4) or mercapto propionic acid (c in Figure: 4) to the internal allyl groups, generating a novel amphiphilic hypersystem. This kind of amphiphilic systems are very interesting to study for their self-assembly behavior, in this particular case, the modified hyperbranched polymer adopts as a large spherical aggregates in alkaline water evidenced by FESEM (Figure: 4) and AFM images. Further investigation is being carried out to understand the exact nature of these aggregates. As the hyperbranched polymer contained ‘-S-‘ group in the interior, we utilized this as the scaffold for scavenging heavy metal ions like Hg2+ from aqueous solutions to the chloroform solution containing polymer. This hyperbranched polymer could trap Hg2+ ions even when present in ppm level of contamination.

Hyperbranched Polymers

Nonionenes

Amphiphilic Copolymers - Synthesis

Nonionic Analogues of Ionenes

Hyperbranched Polymer

Thiol-ene Clickable Hyperscaffolds

Organic Chemistry

Novel amphiphilic dendrimers as nanovectors for siRNA delivery

Wang, Yang

13 June 2014

Les dendrimères, font partie d'une famille particulière de polymères synthétiques, pouvant être utilisés comme nanovecteurs pour l'administration de médicaments grâce à leur structure polyvalente et leur action coopérative, ces fonctions étant confinées dans un volume de taille nanométrique. Notre groupe a récemment démontré que de petites unités dendritiques amphiphiles pouvaient s'auto-assembler en dendrimères supramoléculaires pouvant délivrer du siARN, avec une efficacité similaire à celle des dendrimères de grande génération construits de manière covalente. Dans cette thèse, ans le but de explorer des nouveaux dendrimères amphiphiles possédant des propriétés particulières d'auto-assemblage pour la délivrance de médicaments, j'ai synthétisé et caractérisé deux familles de dendrimères amphiphiles, à savoir des dendrimères bola-amphiphiliques de type PAMAM ainsi que des dendrimères amphiphiles biodégradables de type poly(aminoester). Leurs propriétés physico-chimiques et l'activité biologique pour la délivrance de siARN ont été étudiées. Nos résultats soulignent qu'elles constituent de nouveaux nanotransporteurs prometteurs pour la délivrance d'acide nucléique, voie dans laquelle nous poursuivons activement nos efforts. / Dendrimers, a special family of synthetic polymers, emerge as appealing nanovectors for drug delivery thanks to their unique precisely-controlled achitecture along with multivalency and cooperativity confined within a nanosized volume. Our group has recently demonstrated that small amphiphilic dendrons could self-assemble into supramolecular dendrimers, which mimick the covalently constructed high generation dendrimers and effectively deliver siRNA therapeutics in vitro and in vivo. In order to further explore novel amphiphilic dendrimers with special self-assembly properties for nucleic acid delivery, in this Ph.D thesis, I have synthesized and characterized two families of amphiphilic dendrimers, namely bola-amphiphilic PAMAM dendrimer and biodegradable amphiphilic poly(aminoester) dendrimer. Their physico-chemical properties and biological activity for siRNA delivery have been investigated. Our results demonstrate that they may constitute, via supramolecular self-assembling, effective and promising nanocarriers for nuclide acid delivery, in which we are actively pursuing our effort.

Dendrimères amphiphiliques

Dendrimères bola-Amphiphiliques

Dendrimères poly (aminoester)

Nanotransporteurs

Transport d'acide nucléique.

Amphiphilic dendrimers

Bola-Amphiphilic dendrimers

Poly(aminoester) dendrimers

Nanocarriers

SiRNA delivery.

540

Synthesis and Interfacial Behavior of Functional Amphiphilic Graft Copolymers Prepared by Ring-opening Metathesis Polymerization

Breitenkamp, Kurt E.

01 February 2009

This thesis describes the synthesis and application of a new series of amphiphilic graft copolymers with a hydrophobic polyolefin backbone and pendent hydrophilic poly(ethylene glycol) (PEG) grafts. These copolymers are synthesized by ruthenium benzylidene-catalyzed ring-opening metathesis polymerization (ROMP) of PEG-functionalized cyclic olefin macromonomers to afford polycyclooctene- graft -PEG (PCOE- g -PEG) copolymers with a number of tunable features, such as PEG graft density and length, crystallinity, and amphiphilicity. Macromonomers of this type were prepared first by coupling chemistry using commercially available PEG monomethyl ether derivatives and a carboxylic acid-functionalized cycloctene. In a second approach, macromonomers possessing a variety of PEG lengths were prepared by anionic polymerization of ethylene oxide initiated by cyclooctene alkoxide. This methodology affords a number of benefits compared to coupling chemistry including an expanded PEG molecular weight range, improved hydrolytic stability of the PEG-polycyclooctene linkage, and a reactive hydroxyl end-group functionality for optional attachment of biomolecules and probes. The amphiphilic nature of these graft copolymers was exploited in oil-water interfacial assembly, and the unsaturation present in the polycyclooctene backbone was utilized in covalent cross-linking reactions to afford hollow polymer capsules. In one approach, a bis -cyclooctene PEG derivative was synthesized and co-assembled with PCOE-g-PEG at the oil-water interface. Upon addition of a ruthenium benzylidene catalyst, a cross-linked polymer shell is formed through ring-opening cross-metathesis between the bis -cyclooctene cross-linker and the residual olefins in the graft copolymer. By incorporating a fluorescent-labeled cyclooctene into the graft copolymer, both oil-water interfacial segregation and effective cross-linking were confirmed using confocal laser scanning microscopy (CLSM). In a second approach, reactive functionality capable of chemical cross-linking was incorporated directly into the polymer backbone by synthesis and copolymerization of phenyl azide and acyl hydrazine-functional cyclooctene derivatives. Upon assembly, these reactive polymers were cross-linked by photolysis (in the phenyl azide case) or by addition of glutaraldehyde (in the acyl hydrazine case) to form mechanically robust polymer capsules with tunable degradability ( i.e. non-degradable or pH-dependent degradability). This process permits the preparation of both oil-in-water and water-in-oil capsules, thus enabling the encapsulation of hydrophobic or hydrophilic reagents in the capsule core. Furthermore, the assemblies can be sized from tens of microns to the 150 nm - 1 µm size range by either membrane extrusion or ultrasonication techniques. These novel capsules may be well-suited for a number of controlled release applications, where the transport of encapsulated compounds can be regulated by factors such as cross-link density, hydrolytic stability, and environmental triggers such as changes in pH.

Amphiphilic

Capsules

Graft copolymers

Metathesis

Polymers

Self-assembly

Amphiphilic graft copolymers

Ring-opening metathesis polymerization

Materials Science and Engineering

Polymer and Organic Materials

Quantum chemical studies of spectroscopy and electrochemistry of large conjugated molecular systems

Cho, Sangik

03 September 2009

The molecular identity of the green emission of polyfluorene is investigated in the view point of the molecular interactions between modeled segments. The semi-empirical quantum methods, ZINDO/S and AM1 (AM1-CIS), are used in combination to provide reasonable explanations for experimental spectroscopic properties of monodisperse fluorene oligomers and fluorene oligomers with a central keto defect in dilute solutions. Applying the same method, the molecular interactions between model segments are found to exist and are significant. However, the spectroscopic property change from the molecular interactions is negligible. In addition, the effects of mechanical stress and multi-defects on fluorene oligomers are investigated. On the other hand, the redox mechanisms proposed for the oxidation of an amphiphilic cyanine (C8S3) J-aggregates immobilized at ITO electrode and the subsequent dehydrogenated dimmer formation during cyclic voltammetry based on analysis of absorption spectra during the process are verified with the combined semi-empirical quantum methods similar to the previous methods. The absorption spectra assigned by experiment for electrochemical species involved in the proposed mechanism show reasonable match to the theoretically estimated absorption energies of the corresponding simplified model systems. In addition, the standard reduction potentials of the fairly large molecules, C8S3 monomer and its dehydrogenated dimer, are pursued with quantum mechanical calculations. The free energy difference between the oxidized and reduced states of the target systems is decomposed to electronic energy, solvation energy and temperature-dependent free energies terms. Based on AM1 ground state geometries and with the corresponding temperature dependent free energies, the electronic energies and the solvation energies are each evaluated by two different methods. The electronic energies are calculated with AM1 method and DFT calculation and, also, the solvation energies are obtained based on the atomic partial charges from AM1 and DFT wavefunctions with continuum dielectric solvent approximation. The four calculation schemes from the combinations of the electronic and solvation energy estimation methods are tested with the redox compounds with various molecular weights and the estimations are compared with the corresponding experimental redox potentials. The relative redox potentials between two different redox systems are found to be reasonably estimated with the four calculation schemes. / text

polyfluorene

green emission

ketone defect

C8S3

amphiphilic cyanine dye

Cyclic voltammetry

standard reduction potential

Copolymères diblocs amphiphiles et thermostimulables : synthèse contrôlée et étude préliminaire de leur auto-organisation / Amphiphilic and thermosensitive block copolymers : controlled synthesis and preliminary study of their self organization

Qayouh, Hicham

17 December 2013

Les travaux présentés dans ce manuscrit ont porté sur l'élaboration de nouveaux copolymères dibloc amphiphiles (poly(ε-caprolactone)-b-poly(méthacrylate d'oligo(éthylène glycol) méthyl éther) biodégradables, thermostimulables et susceptibles d'être employés dans des applications respectueuses de l'environnement comme le traitement des eaux contaminées. La particularité de ces copolymères provient d'une part de la différence de solubilité des deux blocs et d'autre part de l'association d'un bloc hydrophobe biodégradable à un bloc thermostimulable hydrophile. Les propriétés de ces copolymères en milieu aqueux ont ainsi été évaluées en fonction de la température. Ces composés ont été obtenus par la combinaison de deux techniques de polymérisation contrôlée en utilisant un amorceur difonctionnel. Pour cela, deux stratégies ont été testées : i) la polymérisation par ouverture de cycle (POC) de l'ε-caprolactone à partir d'un macro-amorceur de poly(méthacrylate d'oligo(éthylène glycol) méthyl éther) à terminaison OH après avoir mis au point les conditions expérimentales de la POC en comparant plusieurs catalyseurs. ii) par polymérisation radicalaire par transfert d'atome (ATRP) du méthacrylate d'oligo(éthylène glycol) amorcée à partir d'une poly(ε-caprolactone) à extrémité bromée. Les températures critiques inférieures de solubilité (LCST) de ces copolymères ont été déterminées par UV visible. Leurs comportements micellaires ont été étudiés par mesures HPPS / The development of new biodegradable diblock copolymers poly(ε-caprolactone)-b-poly[oligo(ethylene glycol)methyl ether methacrylate], which could be used in environmental friendly applications such as treatment of contaminated water has been the main goal of this work. For the preparation these copolymers, the ring-opening polymerization (ROP) and the Atom Transfer Radical Polymerization (ATRP) were combined by using a bifunctional initiator. The two-step route for the synthesis of these copolymers was using either ATRP or ROP as first step and the other polymerization secondly. Each polymerization was studied carefully in order to control the macromolecular parameters of the copolymers. On the one hand, the ATRP of methacrylates bearing oligo(ethylene glycol) was carried out by using poly(ε-caprolactone) with bromide end-group as macroinitiator. On the other hand, the ring opening polymerization of ε-caprolactone was initiated by the hydroxyl end-group of the poly[oligo(ethylene glycol)methyl ether methacrylate], using tin octoate, tin tetrakis(phenylethynyl) or bismuth triflate as catalysts. The Low Critical Solution Temperature (LCST) of these amphiphilic diblock copolymers in aqueous medium have been determined by UV-visible spectroscopy. Their micellar behaviors were also studied by measuring size by HPPS

Copolymères amphiphiles

Thermostimulables

Polymérisation contrôlée

ATRP

POC

Amphiphilic copolymers

Thermosensitive

Controlled polymerization

ATRP

ROP

547.28