Click Silicones

Yu, Gilbert

08 1900

Both the thermal and copper(I) catalyzed azide-alkyne Huisgen cycloadditions were explored as strategies to be used for silicone functionalization and crosslinking. The generality of these reactions was demonstrated (Chapter 2) using 1,3-bis(azidopropyl)tetramethyldisiloxane (BAPTMDS) as a model compound. The ligation of this compound with several alkyne-containing molecules, especially the copper(I) catalyzed process or “click” proved to be easy to perform, high yielding, and gave the 1,4-triazole regioisomer as the sole product. Thermal, metal catalyst-free, azide-alkyne cross-linking (Chapter 3) using a poly(azidopropylmethylsiloxane)-co-dimethylsiloxane as the base polymer and several polysubstituted alkyne molecules as crosslinkers was efficient. The reaction of the base polymer with an ethynyl-terminated disiloxane demonstrates that a silicone elastomer can be synthesized by simple heating and that the resulting material is stable, decomposing only at temperatures higher than 230 °C. Finally, direct bioconjugation of silicones to biotin using propargylamide and BAPTMDS was examined (Chapter 4). The result of the copper(I) catalyzed Huisgen ligation of biotin onto silicones was as efficient as the reactions in the previous chapters, revealing that the “click” process can successfully be applied to a broad range of silicones. / Thesis / Master of Science (MSc)

silicones

click process

silicione functionalization

silicone crosslinking

Latently-reactive conjugated polymer-coated single-walled carbon nanotubes

Fong, Darryl

January 2019

Latently-reactive conjugated polymer-coated single-walled carbon nanotubes / Single-walled carbon nanotubes (SWNTs) are intensely investigated nanomaterials that exhibit intriguing physical and optoelectronic properties. Although SWNTs are highly regarded in terms of their potential societal impact, commercialization of SWNT applications has been dampened by the difficulty in SWNT processability and purification. Current commercially viable carbon nanotube syntheses produce complex mixtures of metallic and semiconducting SWNTs, as well as amorphous carbon and metal catalyst particles. Furthermore, the ability to decorate carbon nanotube surfaces to modulate their properties is non-trivial, especially if concurrent preservation of optoelectronic properties is desired. To date, the issues of SWNT solubilization, sorting, and functionalization have been approached in a piecemeal fashion. Conjugated polymers, which are macromolecules that possess extended π-systems, have the potential to address all of these issues simultaneously. In my Thesis, I explore conjugated polymer structures to investigate (i) factors that influence dispersion selectivity, and (ii) the decoration of polymer-SWNT complexes by incorporating reactive moieties into the polymer structure. The work presented in this Thesis begins by examining the ability of conjugated polymers to sort SWNTs. To date, the selective dispersion of metallic SWNTs is unrealized. In Chapter 2, I examine the effect of the electronic nature of the conjugated backbone on the selective dispersion of SWNTs by preparing SWNT dispersions pre- and post-methylation of a pyridine-containing conjugated polymer. In doing so, I prepare a series of polymers with identical degrees of polymerization and dispersity (to minimize extraneous selectivity factors) and find that electron rich π-systems disperse only semiconducting SWNTs, while electron poor π-systems disperse relatively more metallic SWNTs. In Chapter 3, I challenge the conventional wisdom that complete backbone conjugation is required to selectively disperse semiconducting SWNTs by introducing non-conjugated linkers into the polymer backbone and demonstrating that nanotube sorting is still possible. I next examine conjugated polymers as tools that can simultaneously sort SWNTs and impart reactivity to the polymer-SWNT complex, while preserving SWNT optoelectronic properties. In Chapter 4, I incorporate azides into polyfluorene side chains and perform solution-phase Strain-Promoted Azide-Alkyne Cycloaddition (SPAAC). I show that the polymer-SWNT complex can be rapidly decorated with strained cyclooctyne derivatives, and that only pre-clicked polymer enables for sorting of semiconducting SWNTs. The sorted SWNT population can then be made water soluble post-SPAAC, enabling for the study of SWNT emission in solvents with very different polarity. In Chapter 5, I examine the reactivity of azide-containing polymer-SWNT thin films and show that thin film properties can be drastically altered. Interfacial chemistry enables for the spatially-resolved patterning of a Janus polymer-SWNT thin film containing both hydrophilic and hydrophobic regions. In Chapter 6, I devise a system to perform aqueous solution-phase chemistry on the polymer-SWNT complex. The water soluble polymer-SWNT complex allows for functionalization of the hydrophobic SWNT scaffold with polar and charged molecules. Clicking an acidochromic switch onto the polymer-SWNT surface enables for control over the SWNT emission properties. Lastly, in Chapter 7 I develop a conjugated polymer whose backbone can be functionalized using visible light. The visible-light mediated photoclick coupling of a conjugated polymer backbone enables for rapid polymer modification and is the first example of spatially-resolved conjugated polymer backbone functionalization. / Thesis / Doctor of Philosophy (PhD) / Carbon nanotubes are cylindrical shells of carbon that possess fascinating physical, optical, and electrical properties. Commercial syntheses of carbon nanotubes produce complex mixtures of impure material, and raw carbon nanotube samples further suffer from insolubility. A grand challenge preventing commercialization of carbon nanotube applications is simultaneously solubilizing, sorting, and functionalizing carbon nanotube structures while avoiding damage to the nanotube properties. To date, these issues have been tackled in a piecemeal fashion. In my Thesis, I explore conjugated polymer coatings as a solution to address these problems all at once. I investigate how modifying conjugated polymer structure can (i) influence carbon nanotube purification and (ii) produce latently-reactive polymer-nanotube complexes that can be used to decorate carbon nanotubes without damaging nanotube properties.

Conjugated Polymers

Carbon Nanotubes

Click Chemistry

Development of Orthogonal Catalytic Click Processes That Forge Functional Linkages:

Hackey, Meagan

January 2024

Thesis advisor: Amir H. Hoveyda / Chapter One: Development of a New Catalytic Click Reaction Involving Nitriles and Allenes (CuPDF)Catalytic click reactions, although small in number, have made a profound impact on chemistry research, including the fields of drug discovery, biological chemistry, and materials science. What is much needed are additional catalytic reactions that bring about the union of commonly occurring and robust functional groups, are mutually orthogonal to those that exist and offer a function other than connecting two fragments. We have developed a catalytic click process that connects a nitrile and a monosubstituted allene in the presence of commercially available B2(pin)2 and a readily accessible Cu(I) complex. The modification stage involves alkene isomerization by base and condensation with a hydrazine and both processes are performed in situ. The resulting linkages contain a robust diazaborinine that is fluorescent. We demonstrate that the click process, which we have named copper(I)-catalyzed phenoxydiazaborinine formation (CuPDF) is mutually orthogonal to copper(I)-catalyzed azide–alkyne cycloaddition (CuAAC) as well as sulfur-fluorine exchange (SuFEx). These click reactions can therefore be used for efficient synthesis of sequence-defined oligomers that may contain modifiable linkages and peptide-drug conjugates. For applications in aqueous media, we have also developed, copper(I)- and palladium-catalyzed quinoline formation (Cu/PdQNF). These latter processes generate fluorescent connectors as well. Chapter Two: Development of a Catalytic Click Reaction Involving Ketones and Allenes (CuAKA) We have developed another click reaction, this time bringing about the union of a ketone and, similar to CuPDF, a monosubstituted allene and B2(pin)2. We label this click reaction copper(I)-catalyzed allene–ketone addition or CuAKA. As a consequence of shared reactants, identifying catalysts that would allow CuAKA and CuPDF to be mutually orthogonal was at the center of our investigations. Our studies resulted in the identification of copper(I) complexes that can be used to perform a click reaction on a nitrile or a ketone. Furthermore, we found that mutual orthogonality can be achieved between CuAKA and CuAAC using an amino phosphine–Cu(I) catalyst. Computational and kinetics studies were performed that shed light on the origins of catalyst-controlled chemoselectivity. Importantly, similar to CuPDF, CuAKA can be performed in aqueous media. Chapter Three: Preparation of Multi-drug Conjugates with Mutually Orthogonal Click Reactions We show that with CuAAC, CuPDF and CuAKA, three mutually orthogonal click processes can be efficiently merged to assemble complex molecules efficiently with no protection/deprotection needed. With CuAKA, similar to CuAAC and CuPDF, being also orthogonal to SuFEx, a four-armed core molecule may be used in a similar fashion. A central finding in this part of study was the discovery that CuAKA, similar to CuAAC but unlike CuPDF, can be used to link molecules that contain acidic protons, such as phenol or a carboxylic acid moieties. Chapter Four: Controlled Rupture of CuAKA-Generated Linkages A distinct attribute of CuAKA is that it forms a linkage that is cleavable under mild aqueous oxidative conditions. We show that the tertiary hydroxy group accelerates the oxidation of the nearby C–B bond within the connector to generate a -hydroxy ketone that undergoes a retro-aldol reaction to effect rupture. We show that an aryl linker between the ketone and the carrier molecule, such a bile acid or a cell-penetrating peptide (CPP) may be used to achieve the steric and electronic parameters that are needed for optimal clicking and clipping rates. To demonstrate applicability, we used CuAKA was used for efficient linking of camptothecin, an anti-cancer agent with low selectivity, to a ketone attached to unprotected penetratin, a CPP. The ensuing release of the payload proceeded readily in a 68 mM aqueous solution of hydrogen peroxide at 37 °C with control experiments indicating that a proximal lysine residue accelerates the retro-aldol reaction. / Thesis (PhD) — Boston College, 2024. / Submitted to: Boston College. Graduate School of Arts and Sciences. / Discipline: Chemistry.

Allenes

Catalysis

Click Chemistry

Nitriles

Organic Synthesis

Self-assembly of temperature-responsive protein–polymer bioconjugates

Moatsou, D., Li, J., Ranji, A., Pitto-Barry, Anaïs, Ntai, I., Jewett, M.C., O'Reilley, R.K.

2016 June 1917

Yes / We report a simple temperature-responsive bioconjugate system comprising superfolder green fluorescent protein (sfGFP) decorated with poly[(oligo ethylene glycol) methyl ether methacrylate] (PEGMA) polymers. We used amber suppression to site-specifically incorporate the non-canonical azide-functional amino acid p-azidophenylalanine (pAzF) into sfGFP at different positions. The azide moiety on modified sfGFP was then coupled using copper-catalyzed “click” chemistry with the alkyne terminus of a PEGMA synthesized by reversible addition–fragmentation chain transfer (RAFT) polymerization. The protein in the resulting bioconjugate was found to remain functionally active (i.e., fluorescent) after conjugation. Turbidity measurements revealed that the point of attachment of the polymer onto the protein scaffold has an impact on the thermoresponsive behavior of the resultant bioconjugate. Furthermore, small-angle X-ray scattering analysis showed the wrapping of the polymer around the protein in a temperature-dependent fashion. Our work demonstrates that standard genetic manipulation combined with an expanded genetic code provides an easy way to construct functional hybrid biomaterials where the location of the conjugation site on the protein plays an important role in determining material properties. We anticipate that our approach could be generalized for the synthesis of complex functional materials with precisely defined domain orientation, connectivity, and composition. / Engineering and Physical Sciences Research Council (EPSRC), University of Warwick, National Science Foundation (U.S.) (NSF), United States. Defense Advanced Research Projects Agency (DARPA), Seventh Framework Programme (European Commission) (FP7), European Research Council (ERC)

Bioconjugates

Polymers

Green fluorescent protein

Click chemistry

Novel Approaches To The Synthesis of Clicked Block Copolymers

Flack, Matthew Alexander

16 January 2011

Block copolymers are widely used in both the academic and industrial communities due to their unique properties. With the development of living polymerization techniques, the synthesis of block copolymers with controlled molecular weights and unique architectures has reached an all time high. Here a novel approach to the synthesis of block copolymers, namely polystyrene-b-polyisoprene, using azide-alkyne click chemistry techniques is investigated. Both azido and alkyne-terminated polystyrene were synthesized using ATRP. Azido-terminated polystyrene was synthesized via a substitution reaction between NaN3 and bromo-terminated polystyrene. Alkyne-functionalized polystyrene was synthesized using propargyl 2-bromoisobutyrate as a functional initiator. ¹H NMR and SEC were used to analyze the degree of polymer functionalization. Anionic polymerization techniques were used to synthesize polyisoprene. Polyisoprenyl lithium was reacted with propylene oxide to obtain hydroxyl-terminated polyisoprene. Functionalization of ≥ 90% was demonstrated via flash column chromatography. The aforementioned hydroxyl-terminated polyisoprene was reacted with both 11-chloroundecanoyl bromide and 11-chloroundecanoyl chloride to synthesize halogen-terminated polyisoprene. As with polystyrene, a substitution reaction with NaN3 afforded azido-terminated polyisoprene. Alkyne-functionalized polystyrene was coupled with azido-terminated polyisoprene via click chemistry to create said block copolymers. The reactions were investigated using ¹H and ¹³C NMR, SEC, IR and in some cases TEM. The clicked block copolymers should provide precedent for the synthesis of supramolecular block copolymers. / Master of Science

Click chemistry

Polystyrene

Polyisoprene

Block copolymers

Bioorthogonal metal complex functionalization of late transition metal complexes via iClick reaction: A versatile tool to introduce luminophores and carrier groups / Bioorthogonale Funktionalisierung von Metallkomplexen später Übergangsmetallkomplexen über die iClick Reaktion: Ein vielseitiges Tool zur Einführung von Luminophoren und Trägergruppen

Moreth, Dominik

January 2024

The development of "click" reactions, including copper-catalyzed azide-alkyne cycloaddition (CuAAC) and its strain promoted variant has been essentially contributed to the synthesis of small molecules and bio(macro)molecule conjugates. In contrast, the inorganic click reaction ("iClick") as a catalyst-free cycloaddition reaction occurring within the inner coordination sphere of a metal-azido complex with dipolarophiles such as alkynes, gained significantly less attention. The objective of the present thesis was to utilize the iClick reaction to create a diverse array of biomolecule-functionalized transition metal complexes and to identify patterns in the reactivity and structure preference of the resulting triazolate products. While existing studies have predominantly explored the influence of various ligands on the reactivity and structure of triazolate products, the first part of this work focused on the influence of different metal centers on the speed of the iClick reaction. An isostructural series of Ni(II), Pd(II), Pt(II), and Au(III) azido complexes with a N^C^N pincer ligand was studied to discern trends in the iClick reaction kinetics with different electron-poor alkynes and the structural parameters of their triazolato products. Building from this knowledge, the attachment of functionalized alkynes was used to install biorelevant small molecules such as carbohydrates, coumarin and biotin. Through this approach, the resulting triazolato complexes were tested for the improvement of their photophysical properties, protein binding, and modulation of biological activity. / Die Entwicklung von „Klick“-Reaktionen, einschließlich der kupferkatalysierter Azid-Alkin Cycloaddition (CuAAC) und ihre spannungsinduzierten Variante trug wesentlich zur Synthese kleiner Moleküle und Bio(makro)molekülkonjugate bei. Im Gegensatz dazu ist die anorganische Klickreaktion („iClick“), eine katalysatorfreie Cycloaddition, die innerhalb der inneren Koordinationssphäre eines Metall-Azido-Komplexes mit Dipolarophilen wie Alkinen deutlich weniger bekannt. Das Ziel der vorliegenden Arbeit war es, die iClick-Reaktion zu nutzen, um ein vielfältiges Spektrum an biomolekülfunktionalisierten Übergangsmetallkomplexen zu identifizieren und Muster in der Reaktivität sowie der Strukturpräferenz der resultierenden Triazolatprodukte zu erkennen. Während bestehende Studien vor allem den Einfluss verschiedener Liganden auf die Reaktivität und Struktur von Triazolatprodukten untersucht haben, konzentrierte sich der erste Teil dieser Arbeit auf den Einfluss verschiedener Metallzentren auf die Geschwindigkeit der iClick-Reaktion.Eine isostrukturelle Serie von Ni(II)-, Pd(II)-, Pt(II)- und Au(III)-Azidokomplexen mit einem N^C^N-Pincer-Liganden wurde untersucht, um Trends in der iClick-Reaktionskinetik mit verschiedenen elektronenarmen Alkinen sowie die Strukturparameter ihrer Triazolato-Produkte zu erkennen. Auf Basis dieser Erkenntnisse wurde die Anbindung funktionalisierter Alkine verwendet, um biorelevante kleine Moleküle wie Kohlenhydrate, Cumarin und Biotin einzubinden. Durch diesen Ansatz wurden die resultierenden Triazolato-Komplexe auf die Verbesserung ihrer photophysikalischen Eigenschaften, ihrer Proteinbindung und die Modulation ihrer biologischen Aktivität hin untersucht.

Click-Chemie

Metallkomplexe

Leuchtstoff

ddc:546

Mise au point de nouvelles méthodes de conjugaison oligonucléotide/sucre et développement d'un microsystème d'analyse des interactions lectine/sucre / Development of new methods for carbohydrate/oligonucleotide conjugation and of a microarray to study the lectin/carbohydrate interactions

Pourceau, Gwladys

25 November 2010

Les interactions entre les sucres et les lectines sont généralement l'étape clé dans de nombreux phénomènes biologiques et pathologiques. Malgré leu r importance cruciale, ces interactions sont paradoxalement caractérisées par des constantes d'affinité faibles et nécessite une multiprésentation des motifs saccharidiques pour être significatives. Cette augmentation est appelée "effet cluster". En outre, les techniques d'analyse actuellement utilisées en laboratoire nécessitent des quantités importantes de produits, ce qui est difficilement compatible avec les méthodes de synthèse actuelle. Pour pallier ces difficultés, une approche originale basée sur l'utilisation conjointe de glycooligonucléotide et de puces à ADN a été proposée. Les glycoconjugués basés sur des squelettes phosphodiesters et couplés à des séquences d'ADN ont été synthétisés en utilisant la chimie des oligonucléotides, couplée à la "click chemistry". La séquence d'ADN quant à elle a permis l'ancrage sur une puce à ADN et donc la mesure de leur affinité vis-à-vis de différentes lectines. Ce manuscrit rapporte le développement des nouvelles méthodologies de synthèse des glycooligonucléotides ainsi que la préparation de nombreux glycoconjugués originaux, dont l'affinité pour différentes lectines a été mesurée via l'utilisation de la puce à ADN. L'influence de plusieurs paramètres a été étudiée: le nombre de résidus, l'arrangement spatial, la lipophilie etc. Il s'avère que l'arrangement spatial semble être l'un des points les plus importants dans la mise au point d'un glycoconjugué. / The interactions between carbohydrates and lectins are generally the "key step" in many biological and pathological phenomena. Despite their importance, these interactions are paradoxically characterized by low affinity constants and requires multipresence of saccharide to be significant. This increase is called "cluster effect". In addition, the analysis techniques currently used in the laboratory requires large quantities of products, which is hardly compatible with the current methods of synthesis. To circumvent these difficulties, a original approach based on the combined use of glycooligonucleotides and DNA microarrays has been proposed. Glycoconjugates based on phosphodiester skeletons linked to DNA sequences have been synthesized using the chemistry of oligonucleotides, coupled with the "click chemistry". The DNA sequence has allowed the anchoring on a DNA chip and therefore the measurement of their affinity versus different lectins.This manuscript reports the development of new synthetic methodologies for the glycooligonucleotides synthesis and the preparation of many original glycoconjugates, whose affinity for various lectins was measured through the use of DNA microarray. The influence of several parameters was studied: the number of residues, the spatial arrangement, etc. lipophilicity. The spatial arrangement appears to be one of the most important parameters in the development of a glycoconjugate.

Bioconjugaison

Oligonucléotide

Saccharide

Lectine

Click chemistry

Glycopuce

Bioconjugation

Oligonucleotide

Saccharide

Lectin

Click chemistry

Glycoarray

Développement de nouvelles réactions éco-compatibles : application à la synthèse de molécules bioactives / Development of new eco-compatible reactions : applications in synthesis of bioactive molecules

Marzag, Hamid

21 December 2013

La leucémie myéloïde chronique (LMC) est une affection hématologique maligne caractérisée par l’apparition dans la moelle osseuse et le sang, d’un nombre important de globules blancs dont certains sont immatures. A l’heure actuelle, le principal traitement est l’Imatinib, commercialisé sous le nom de Glivec®. Ce traitement conduit, chez certains patients, à l'émergence de souches résistantes, ce qui complique la thérapeutique et nécessite un large panel de molécules actives pour contourner les mécanismes de résistance. Par conséquent, la recherche de nouvelles molécules bioactives agissant sur de nouvelles cibles biologiques reste toujours un défi important et d’actualité. Au cours de ce projet de thèse, nous nous sommes intéressés au développement de nouveaux procédés de synthèse pour accéder et découvrir de nouvelles molécules bioactives, en série nucléosidique, pour contourner les mécanismes de résistances dans des modèles de LMC. Nous avons tout d’abord développé une nouvelle méthode de synthèse propre et efficace de nouveaux analogues de C-nucléosides en utilisant une catalyse par le fer. Nous avons ensuite réalisé plusieurs modifications post-synthétiques pour accéder à de nouveaux C-nucléosides hautement fonctionnalisés, en particulier les analogues de la thiophènefurine. Nous avons également développé un nouveau procédé de synthèse d’une famille de O-glycosides, en combinant l’activation par les ultrasons à la catalyse par le fer. Ce procédé a été exploité par la suite pour concevoir et synthétiser les analogues glycosidiques du résvératrol. Enfin, nous avons mis au point une méthode efficace et peu couteuse d’azidation de sucres protégés. / Chronic myeloid leukemia (CML) is a malignant hematological disorder characterized by the formation, in the blood and bone marrow, of an excessive number of white blood cells, some of which are immature. Currently, the main treatment of CML is based on tyrosine-kinase inhibitors, such as Imatinib, the first approved drug of this class of compounds and marketed as Gleevec ®. However, this treatment results, in some patients, to the emergence of resistance, which complicates the treatment and requires a wide range of active molecules to circumvent resistance mechanisms. Therefore, the search for new bioactive molecules featuring new mode of action still remains a challenging.In this thesis project, we were interested in the design and discovery of new bioactive molecules in nucleoside series to circumvent resistance mechanisms in CML models, as well as in the development of new synthetic methods for the preparation of these targeted molecules. We first developed a clean and efficient procedure for the synthesis of new C- nucleoside analogues using iron catalysis. Then, several post-synthetic modifications were carried out, starting from halogenated nucleoside derivatives, to access highly functionalized C- nucleosides, as new analogues of thiophenefurin . We also developed a new procedure for the synthesis of O-glycosides using a cooperative effect of iron catalysis and ultrasound activation. This method has been applied for the synthesis of resveratrol O-glycosides. Finally, we developed an effecient and inexpensive method for anomeric sugar azidation. This method was applied for the synthesis of 1,2,3-triazolyl glycosides using a one-pot azidation-click procedure.

Nucléosides

Glycosylation

Chimie click

Azidation

LMC

Nucleosides,

Glycosylation

Click chemistry

Azidation

CML

Desenvolvimento de metaloclusters terpiridínicos automontados para aplicação em dispositivos moleculares / Develop ing self -assembled terpyridine metal o clusters for application in molecular devices

Velho, Rodrigo Garcia

25 March 2014

Os Clusters de acetato de rutênio de fórmula geral [Ru3O(AcO)6L3]n proporcionam blocos de montagem interessantes para sistemas supramoleculares, exibindo características eletrocrômicas e redox reversível, cobrindo uma ampla faixa de potenciais em solventes aquosos e orgânicos. Nesta Tese, estas espécies foram combinadas com o ligante tridentado, 4\'-piridil-2,2\':6\',2\"-terpiridina (pytpy), produzindo complexos do tipo [Ru3O(AcO)6(pytpy)3]n e [Ru3O(AcO)6(py)2(pytpy)]n, que foram totalmente caracterizados em estado sólido e solução. Nestes complexos a terpiridina permanece disponível para ligar-se a íons metálicos como o Fe(II), gerando um complexo binuclear de baixo spin muito estável, do tipo {Fe[Ru3O(AcO)6(py)2(pytpy)]2}n. Este processo pode ser monitorado eletroquimicamente, partindo de íons Fe(III), que exibem uma baixa afinidade pela terpiridina central, e ciclando o potencial para gerar íons de Fe(II). Desta forma, pode-se executar um procedimento típico de click chemistry, que leva a uma estrutura estendida, Fe-cluster-pytpy na superfície do eletrodo. Este filme conserva a funcionalidade dos blocos de montagem, permitindo aplicações interessantes em dispositivos moleculares, tais como sensores e smart Windows. / Ruthenium acetate clusters of general formula [Ru3O(AcO)6L3]n provide interesting building blocks for assembling supramolecular systems, displaying reversible redox and electrochromic characteristics, over a wide range of potentials in aqueous and organic solvents. In this thesis, such species has been combined with the tritopic, 4\'-pyridil-2,2\':6\',2\"-terpiridine (pytpy) ligand, yielding complexes of the type [Ru3O(AcO)6(pytpy)3]n and [Ru3O(AcO)6(py)2(pytpy)]n, which have been fully characterized in solid state and solution. In these complexes, the terpyridine moiety remains available for binding metals ions, such as Fe(II), generating very stable, low spin binuclear complexes, of the type n. This process can be monitored electrochemically, starting from Fe(III) ions, which exhibits a much lower affinity for the terpyridine center, and cycling the potentials in order to generate Fe(II) ions. In this way, one can start a click chemistry, ending up with an extended structure of Fe-cluster-pytpy film at the electrode surface. This film preserves the functionality of the building block complexes, a llowing many possible applications in molecular devices, such as sensors and smart windows.

Click Chemistry

Click Chemistry

Clusters

Clusters

Dispositivos moleculares

Molecular devices

Supramolecular

Supramolecular

Terpiridina

Terpyridine

Synthèse et étude d'un complexe de cuivre(II) tensioactif, fluorophile et photoréductible : application à la chimie click en millieux biphasiques perfluorocarbure-eau et hydrocarbure-eau / Synthesis and study of a fluorous and photoreductible copper(II) complex with surfactant properties : application to click chemistry in biphasic perfluorocarbon-water and hydrocarbon-water systems

Jochyms, Quentin

17 December 2015

L'objectif de cette thèse était le développement d'un tensioactif organométallique pour catalyser la cycloaddition entre un alcyne et un azoture. Le but d'un tel système est de compartimenter le catalyseur et les réactifs dans deux phases différentes : le catalyseur dans une phase organique ou fluorée et les réactifs dans une phase aqueuse, afin de simplifier la purification en fin de réaction. D'abord, le complexe [Cu(TF6)(3-benzoylbenzoate)2] a été synthétisé. Puis, il a été montré que ce complexe non soluble dans l'eau présente de bonnes propriétés tensioactives à l'interface des systèmes DIPE-eau et PFD-eau, grâce à ces chaînes fluorées. Il est aussi photoréductible pour obtenir un complexe de cuivre (I). Enfin, il a été utilisé comme catalyseur dans des émulsions. Le complexe [Cu(TF6)(3-benzoylbenzoate)2], une fois réduit, montre une bonne activité en catalyse. Cependant, à la fin de la réaction, une quantité importante de cuivre est détectée dans la phase aqueuse pour des raisons encore non déterminées. Par ailleurs, il s'avère que c'est le cuivre présent dans l'eau qui est responsable de la catalyse et non le complexe à l'interface. / The aim of this thesis was to develop a new metallosurfactant for the catalysis between an alkyne and an azide. The goal of such a system was to keep separated the reactants and the catalyst in two different phases to facilitate the purification of the reaction mixture. The first step was to synthetized the complex [Cu(TF6)(3-benzoylbenzoate)2]. Then it was shown that this complex, insoluble in water and DIPE-water. This complex is also photoreductible to form a copper(I) complex. Finally, it was tested as catalyst in emulsion. When reduced, it showed good activity. However at the end of the reactions a certain amount of copper was found in the water phase for still unknown reason. Besides, it appeared that mainly the copper in the water phase was responsible for the reaction and not the complex at the interface.

Catalyse

Chimie click

Tensioactif

Perfluorcarbures

Photoréduction

Cuivre

Catalysis

Click chemistry

Surfactant

Fluorous

Photoreduction

Copper