Coordination and H-bonded networks based on thiacalix(4)arene derivatives / Réseaux de coordination et réseaux à base de liaisons hydrogènes à partir d'entités de thiacalix[4]arene

Ovsyannikov, Alexander

03 December 2012

Dans ce travail, l’approche de la tectonique moléculaire, basée à la fois sur la reconnaissance moléculaire et le processus itératif d’auto-assemblage à l’état cristallin, a été utilisée pour la formation de réseaux moléculaires de coordination, ainsi que de réseaux moléculaires à base de liaisons hydrogène. La synthèse de nouveaux tectons à base de dérivés de TCA (p-tert-butylthiacalix[4]arene et p-H-thiacalix[4]arene) offrant des groupements coordinants de type pyridine (avec différentes positions de l’azote sur les noyaux pyridiniques) et de dérivés de TMTCA (tetramercaptothiacalix[4]arene) portant aussi des groupement de type pyridine (avec différentes positions de l’azote sur les noyaux pyridiniques) mais aussi cyano, carboxylates, pyrazole et imidazole a été mise au point. Tous les tectons adoptent la conformation 1,3-alternée, permettant l'obtention de réseaux moléculaire de dimensionalité élevée. Les composés obtenus ont été caractérisés à la fois en solution et à l'état cristallin. Leur aptitude à former des réseaux de coordination en présence de métaux de transition (tels que Ag(I), Hg(II), Cd(II), Cu(II), Co(II), Fe(II)) a été explorée. La possibilité de formation de réseaux à base de liaison hydrogènes a été également testée en utilisant le carboxylate-bisamidinium type de reconnaissance. Beaucoup de nouveaux polymères de coordinations possédant diverses dimensionnalités, en particulier, 3D de type diamant, et certaines réseaux à base de liaisons hydrogènes ont été obtenus. La différence de la connectivité entre TCA et TMTCA vis-à-vis des cations métalliques a été étudiée et discutée. / In this work, the molecular tectonic strategy, based on the molecular recognition together with the iterative self-assembly process in the crystalline phase, has been used for the formation of molecular networks (coordination polymer and H-bonded networks). The synthesis of new tectons based on the TCA derivatives (p-tert-butylthiacalix[4]arene et p-H-thiacalix[4]arene) offering pyridyl binding sites with different position of N atom in the rings, as well as the TMTCA derivatives (tetramercaptothiacalix[4]arene) bearing pyridyl (also with different position of N atom in the rings), cyano, carboxylate, pyrazolyl, imidazolyl coordinating groups has been achieved. All tectons were fixed in 1,3-alternate conformation, allowing the formation of high dimensionality networks. The structures of obtained tectons were characterized in solution, as well as in the solid state. The propensity of these tectons to form coordination polymers upon the combination with different transition metal cations such as Ag(I), Hg(II), Cd(II), Cu(II), Co(II), Fe(II) has been expoled. The possibility to form the H-bonded networks has also been investigated using the carboxylate-bisamidinium type of recognition pair. New coordination polymers possessing different dimensionalities (especially 3D diamond like) and some H-bonded networks have been obtained. The differences in the connectivity of TCA and TMTCA towards the metal cations have been studied and discussed.

Thiacalix[4]arene

Tetramercaptothiacalix[4]arene

Polymères de coordination

Réseaux à base de liaisons hydrogene

Tectonique moléculaire

Chimie supramoléculaire

Thiacalix[4]arene

Tetramercaptothiacalix [4]arene

Coordination network

H-bonded network

Molecular tectonics

Supramolecular chemistry

547.7

547.2

Towards multifunctional supramolecular copolymers / Vers des copolymères supramoléculaires multifonctionnels

Xiang, Yunjie

08 July 2014

Le but de cette thèse était de comprendre l'organisation supramoléculaire et le possible réarrangement dynamique de copolymères supramoléculaires multifonctionnels. Ainsi, nous avons synthétisé diverses molécules présentant un coeur urée ou pérylène fonctionalisé par différentes chaines latérales afin de combiner des propriétés de structuration, de fluorescence et de bioreconnaissance dans une même chaine de polymère supramoléculaire. En combinant différentes techniques de spectroscopie, de diffusion du rayonnement et de microscopie, nous avons montré que des molécules avec un même coeur mais des chaines latérales différentes conduisaient à des nanostructures différentes comme des rubans vrillés, des plaques 20 ou encore des fibres branchées. Enfin, plusieurs unités monomériques avec un même coeur mais des chaines latérales différentes ont été mélangées pour former des copolymères supramoléculaires multifonctionnels. La formation préférentielle d'une nanostructure unique dictée par un des monomères a été démontrée selon un mécanisme de tri dit social ( « social self-sorting » ). / The goal of this thesis was to understand the supramolecular organization and the possible dynamic rearrangement of multifunctional supramolecular copolymers. To this end, we havedeveloped a series of building blocks based on urea or perylene cores with various lateral side chains for combining structuring, fluorescence, and biorecognition properties in a singlesupramolecular polymer chain. Using a combination of spectroscopy, scattering, and microscopy techniques, we have shown that molecules with a same core but different lateral chains can lead to the formation of various nanostructures su ch as twisted ribbons, 20 plates, or branched fibers. Ultimately, by combining monomeric units with different functional side chains, multifunctional supramolecular copolymers have been obtained. Whereas radiation scattering and imaging techniques were used to demonstrate that one of the monomer can dictate the formation of a preferential nanostructure, optical spectroscopies revealed that the polymerization process of our systems indeed occurs via social self-sorting.

Chimie supramoléculaire

Auto-assemblage

Spectroscopies optiques

Microscopies

Diffusion du rayonnement

Supramolecular chemistry

Self-assembly

Functional supramolecular polymers

Optical Spectroscopies

Microscopies

Scattering techniques

Social self-sorting

547.8

Organic Fluorine in Crystal Engineering : Consequences on Molecular and Supramolecular Organization

Dikundwar, Amol G

January 2013

The thesis entitled “Organic fluorine in crystal engineering: Consequences on molecular and supramolecular organization” consists of six chapters. The main theme of the thesis is to address the role of substituted fluorine atoms in altering the geometrical and electronic features in organic molecules and its subsequent consequences on crystal packing. The thesis is divided into three parts. Part I deals with compounds that are liquids under ambient conditions, crystal structures of which have been determined by the technique of in situ cryocrystallography. Part II demonstrates the utilization of in situ cryocrystallography to study kinetically trapped metastable crystalline phases that provide information about crystallization pathways. In part III, crystal structures of a series of conformationally flexible molecules are studied to evaluate the consequences of fluorine substitution on the overall molecular conformation. The genesis and stabilization of a particular molecular conformation has been rationalized in terms of variability in intermolecular interactions in the crystalline state. Part I. In situ cryocrystallography: Probing the solid state structures of ambient condition liquids. Chapter 1 discusses the crystal structures of benzoyl chloride and its fluorinated analogs. These compounds have been analysed for the propensity of adoption of Cl···O halogen bonded dimers and catemers. The influence of conformational and electronic effects of sequential fluorination on the periphery of the phenyl ring has been quantified in terms of the most positive electrostatic potential, VS,max (corresponding to σ-hole) on the Cl-atom. It is shown that fluorine also exhibits “amphoteric” nature like other heavier halogens, particularly in presence of electron withdrawing groups. Although almost all the derivatives pack through C–H···O, C–H···F, C–H···Cl, Cl···F, C–H···π and π···π interactions, the compound 2,3,5,6-tetrafluorobenzoyl chloride exhibited a not so commonly observed Cl···O halogen bonded catemer. On the other hand, the proposed Cl···O mediated dimer is not observed in any of the structures due to geometrical constraints in the crystal lattice. Chapter 2 presents the preferences of fluorine to form hydrogen bond (C–H···F) and halogen bonds (X···F; X= Cl, Br, I). Crystal structures of all three isomers of chloro-, bromo-and iodo-fluorobenzene have been probed in order to gain insights into packing interactions preferred by fluorine and other heavier halogens. It has been observed that homo halogen…halogen (Cl···Cl, Br···Br and I···I) contacts prevail in most of the structures with fluorine being associated with the hydrogen atom forming C–H···F hydrogen bond. The competition between homo and hetero halogen bonds (I···I vs I···F) is evident from the packing polymorphism exhibited by 4-iodo fluorobenzene observed under different cooling protocols. The crystal structures of pentafluoro halo (Cl, Br, I) benzenes were also determined in order to explore the propensity of formation of homo halogen bonds over hetero halogen bonds. Different dimeric and catemeric motifs based on X···F and F···F interactions were observed in these structures. Chapter 3 focuses on the effect of different cooling protocols in generating newer polymorphs of a given liquid. The third polymorph (C2/c, Z'=6) of phenylacetylene was obtained by sudden quenching of the liquid filled in capillary from a hot water bath (363 K) to the nitrogen bath (< 77 K). Also, different polymorphs were obtained for both 2¬fluoro phenylacetylene (Pna21, Z'=1) and 3-fluoro phenylacetylene (P21/c, Z'=3) when crystallized by sudden quenching in contrast to the generally followed method of slow cooling which results in isostructural forms (P21, Z'=1). The rationale for these kinetically stable “arrested” crystalline configurations is provided in part II of the thesis. Part II. Tracing crystallization pathways via kinetically captured metastable forms. Chapter 4 explains the utilization of the new approach of sudden quenching of liquids (detailed in chapter 3) to obtain kinetically stable (metastable) crystalline phases that appear to be closer to the unstructured liquids. Six different examples namely, phenylacetylene, 2-fluorophenylacetylene, 3-fluorophenylacetylene, 4-fluorobenzoyl chloride, 3-chloro fluorobenzene and ethyl chloroformate are discussed in this context. In each case, different polymorphs were obtained when the liquid was cooled slowly (100 K/h) and when quenched sharply in liquid nitrogen. The relationship between these metastable forms and the stable forms (obtained by slow cooling) combined with the mechanistic details of growth of stable forms from metastable forms provides clues about the crystallization pathways. Part III. Conformational analysis in the solid state: Counterbalance of intermolecular interactions with molecular and crystallographic symmetries. Chapter 5 describes the crystal structures of a series of conformationally flexible molecules namely, acetylene and diacetylene spaced aryl biscarbonates and biscarbamates. While most of the molecules adopt commonly anticipated anti (transoid) conformation, some adopt unusual cisoid and gauche conformations. It is shown that the unusually twisted conformation of one of the compounds [but-2-yne-bis(2,3,4,5,6¬pentafluorocarbonate)] is stabilized mainly by the extraordinarily short C–H···F intermolecular hydrogen bond. The strength of this rather short C–H···F hydrogen bond has been authenticated by combined single crystal neutron diffraction and X-ray charge density analysis. It has also been shown that the equi-volume relationship of H-and F-atoms (H/F isosterism) can be explored to access various possible conformers of a diacetylene spaced aryl biscarbonate. While biscarbonates show variety of molecular conformations due to absence of robust intermolecular interactions, all the biscarbamates adopt anti conformation where the molecules are linked with antiparallel chains formed with N–H···O=C hydrogen bonds. Chapter 6 presents a unique example where the commonly encountered crystallographic terms namely, high Z' structure, polymorphism, phase transformation, disorder, isosterism and isostructuralism are witnessed in a single molecular species (parent compound benzoylcarvacryl thiourea and its fluorine substituted analogs). The origin of all these phenomenon has been attributed to the propensity of formation of a planar molecular dimeric chain mediated via N–H···O [R2 (12)] and N–H···S [R2 (8)] dimers.

Crystal Engineering

Organic Fluorine

Polymorphism (Crystallography)

In Situ Cryocrystallography

Crystallography

Supramolecular Synthons

Crystallization

Crystals - Charge Density Analysis

Halogen Bonding

Molecular Crystals

Intermolecular Interactions

Supramolecular Chemistry

Organofluorine Chemistry

Fluoroination

Isosterism

Chemical Engineering

Self-Assembled Coordination Cages for Catalysis and Proton Conduction

Samanta, Dipak

January 2014

Biological systems construct varieties of self-assembled architectures with incredible elegance and precession utilizing proteins as subunits to accomplish widespread functions. Inspired by natural systems, construction of artificial model systems with such sophistication and delicacy has become an intriguing field of research over the last two decades using so-called self-assembly process. Judiciously selected complementary building units encoded with specific chemical and structural information can be self-assembled into pre-programmed abiological architectures in a manner similar to biological self-assembly. In this regard, kinetically labile metal-ligand coordination has become an efficient and powerful protocol for the construction of highly intricate structures with specific topology and functionality due to its simple design principle, high bond enthalpy, and predictable directionality. Two-component self-assembly is very widely used methodology and easy to monitor. Recently, multi-component self-assembly has come up as an alternative and effective pathway to achieve complex architectures connecting more than two components in a single step. However, formation of selective single product from multicomponents is entropically unfavorable. Only a very few 3D architectures have been known, that are obtained from a mixture of ditopic and tri- or tetratopic donors with metal acceptors with or without employing templates. Development of template-free multicomponent architectures is still in its infancy. Strong tendency of Pd(II)/Pt(II) to attain square-planar geometry around the metal center and kinetically labile nature of Pd(II)/Pd(II)-N(pyridine) bonds made them chemists’ favourite to engineer desired supramolecular coordination architectures with structural resemblance to Platonic or Archimedean solids by employing symmetrical pyridyl donors due to their predictable directionality. In case of poly-imidazole donors, free rotation of C-N bond connecting imidazole and phenyl ring allows various dispositions of the donating nitrogen with respect to the aromatic backbone, and therefore, the structural topology of the architectures, made of poly-imidazole ligands becomes much more interesting as compared to symmetrical Platonic or Archimedean solids. The physico-chemical properties of self-assembled coordination cages depend on the structures of the complexes. Presence of large internal cavity surrounded by aromatic core, provides an excellent environment for the encapsulation of varieties of guest molecule or as nano-reactors for different organic transformations. Structural investigation in terms of packing interactions, solvent molecules, intermolecular channels can sometimes determine the property of such self-assembled materials as well. Presence of acidic water as well as H-bonded 3D-networks of water molecules in molecular pockets make them potential material for proton conduction. In addition, metal-ligand coordination offers opportunity to introduce new functionality through pre-synthetic modification of the building constituents to influence the property of the supramolecular systems. Incorporation of unsaturated ethynyl functionality attached to the heavy transition metal is expected to exhibit efficient luminescence due to the facile metal to ligand charge transfer (MLCT). Hence, the final assemblies can be employed as chemosensors for electron-deficient nitroaromatics, which are the chemical signature of many of the commercially available explosives. The present investigation is focused on design and construction of discrete, nanoscopic coordination cages with unusual structural topology employing mainly imidazole-based donors with Pd(II)/Pt(II) acceptors and their applications in catalysis, chemosensing, and proton conduction. CHAPTER 1 of the thesis provides a general introduction to self-assembly focusing on the importance and advantages of metal-ligand directional bonding approach towards the construction of supramolecular architectures with various structural topologies. This chapter also includes a brief review on the applications of such coordination cages in various fields especially as ‘molecular flask’ for the observation of unique chemical phenomena and unusual reactions. Part A of CHAPTER 2 describes the synthesis of a new hollow Pd6 water soluble cage [{(tmen)Pd}6(timb)4](NO3)12 (1) via two-component self-assembly of a triimidazole donor and 90° Pd(II) acceptor [tmen = N,N,N’,N’-tetramethylethylenediamine, timb = 1,3,5-tris(1-imidazolyl)benzene]. The assembly was successfully crystallized with a hydrophilic dianionic benzoquinone derivative (formed in situ by the decomposition of DDQ) as [{(tmen)Pd}6(timb)4](NO3)10()2(H2O)18 (3), and a hydrophobic sterically demanding aromatic aldehyde as [{(tmen)Pd}6(timb)4](NO3)12{()4a}2(H2O)27 (5a) [where 2H2 = 2,3-dichloro-5,6-dihydroxycyclohexa-2,5diene-1,4-dione, 4a = 1-pyrenecarboxaldehyde,  = exohedral and  = endohedral] to confirm the hydrophobic nature of the cavity. Experiments were carried out to show that the hydrophobic confined nanospace of the cage (1) catalyses the Knoevenagel condensation of a series of different aromatic monoaldehydes with active methylene compounds in ‘green’ aqueous medium. The Knoevenagel condensation reaction is basically a dehydration reaction because water is a by-product. So the presence of water should, in principle, promote the backward reaction as per Le Chatelier’s principle. In general, these reactions with organic substrates are not performed in water. However, difficulty has been overcome using hydrophobic cavity of the cage. It has also been established that the cavity of the cage also enhances the rate of Diels-Alder reaction of 9-hydroxymethylanthracene with N-phenylmaleimide/N-cyclohexylmaleimide. Figure 1. Catalytic Knoevenagel condensation and Diels-Alder reaction using hydrophobic cavity of the cage (1) in aqueous medium. Part B of CHAPTER 2 reports unique three-component self-assembly incorporating both tri- and tetra-topic donors. Until now, a very few 3D-architectures have been known that are obtained from self-assembly of ditopic and tri- or tetratopic donors with metal acceptors. Scheme 1. Three-component self-assembly of a Pd7 cage (1) from cis-blocked Pd(II) 90° acceptor (M), tri-imidazole (timb) and tetra-imidazole (tim) donors. Self-assembled multicomponent discrete architecture composed of both tri- and tetra-topic donors is yet to be reported due to difficulty in prediction of the final structure from the mixture of ligands having multiple donor sites. The first example of self-sorted Pd7 molecular boat [{(tmen)Pd}7(timb)2(tim)2](NO3)14(H2O)20 (1) [tmen = N,N,N’,N’-tetramethylethylenediamine, timb = 1,3,5-tris(1-imidazolyl)-benzene, tim = 1,2,4,5-tetrakis(1-imidazolyl)benzene] was synthesized via three-component self-assembly of cis-(tmen)Pd(NO3)2, tetra- (tim) and tri-topic donors (timb) in a 7:2:2 ratio. The cavity of this cage was also utilized as a nanoreactor for catalytic Knoevenagel condensations of a series of aromatic aldehydes with 1,3-dimethylbarbituric acid (e) and Meldrum’s acid (f) in aqueous media. CHAPTER 3 presents the results of an investigation on how simple variation of length and coordination mode of linear donors can self-discriminate into markedly different complex architectures, from Pd8 molecular swing [{(tmen)Pd}8(tim)2(bpy)4](NO3)16 (1) or [{(tmen)Pd}8(tim)2(stt)5](NO3)6 (2) to Pd6 molecular boat [{(tmen)Pd}6(tim)2(bpe/dpe/pin/dpb)2](NO3)12, (3/4/5/6). Also by enhancing denticity [bidentate to tridentate (ptp)] as well as introducing asymmetry, they self-sort into Pd7 molecular tent [{(tmen)Pd}7(tim)2(ptp)2](NO3)14 (7) by employing it in a self-assembly of cis-(tmen)Pd(NO3)2 and tetraimidazole (tim) donor [where tmen = N,N,N’,N’-tetramethylethylenediamine, bpy = 4,4’-bipyridyl, stt = sodium terephthalate, bpe = trans-1,2-bis(4-pyridyl)ethylene, dpe = 1,2-di(pyridin-4-yl)ethane, pin = N-(pyridin-4-yl)isonicotinamide, dpb = 1,4-di(pyridin-4-yl)benzene, ptp = 6'-(pyridin-4-yl)-3,4':2',4''-terpyridine, and tim = 1,2,4,5-tetrakis(1- imidazolyl)benzene]. In these cases, control of the geometrical principles and stereo-electronic preferences of the building units allowed the formation of such intricate architectures. Some of these assemblies represent first examples of such types of structures, and their formation would not be anticipated by taking into account only the geometry of the donor and acceptor building units. In addition to their direct structural confirmation using single crystal X-ray diffraction analysis, propensity of the assemblies (1 and 3) to form inclusion complexes with large guest like C60 in solution was also demonstrated by fluorescence quenching experiment. The high KSV values for both the assemblies 1 (1.0 × 10-5 M-1) and 2 (1.6 × 10-6 M-1) with C60 indicated the propensity of these assemblies to form complexes with C60 in solution. Furthermore, inspection of crystal packing of other five complexes (2 and 4 - 7) revealed the presence of water molecules H-bonded with NO3– (O-H···O=N) and 3D H-bonded networks of water in the intermolecular pockets. Interestingly, the present complexes (2 and 4 - 7) show high conductivity across low-humidity range at ambient temperature and achieve a conductivity of ~10-3 Scm-1 at 75% relative humidity and 296 K. These supra-molecular architectures represent a new generation of discrete materials that display high proton conductivity under ambient conditions with activation energy comparable to that of Nafion. Scheme 2. Exclusive formation of Pd8 molecular swings (1 and 2), Pd6 molecular boats (3-6), and Pd7 molecular tent (7) via self-sorting. CHAPTER 4 presents self-selection by synergistic effect of morphological information and coordination ability of the ligands through specific coordination interactional algorithms within dynamic supramolecular systems involving a tetratopic Pd(II) acceptor and three different pyridine- and imidazole-based donors (La - Lc) [La = 1,3-bis((E)-2-(pyridin-3-yl)vinyl)benzene, Lb = 1,3-di(1H-imidazol-1-yl)benzene, and Lc = tris(4-(1H-imidazol-1-yl)phenyl)amine]. Three different cages, ‘paddle wheel’ cluster Pd2(La)4(NO3)4 (2a), molecular barrel Pd3(Lb)6(NO3)6 (2b) and molecular sphere Pd6(Lc)8(NO3)12 (2c) were first synthesized via two-component self-assembly of a tetratopic Pd(II) acceptor (1) and individual pyridine- and imidazole-based donors (La - Lc). When all the four components were allowed to interact in a complex reaction mixture, only one out of three cages was isolated. The inherent dynamic nature of the kinetically labile coordination bond allows constitutional adaptation through component exchange in the competition experiment involving multiple constituents to self-organize into specific combination and thereby, achieve the thermodynamically most stable assembly. The preferential binding affinity towards a particular partner was also established by transforming a non-preferred cage to a preferred cage by the interaction with the appropriate ligand and thus, this represents the first examples of two-step cage-to-cage transformation through constitutional evolution of Figure 2. Cage-to-cage transformation from non-preferred cage to preferred cage upon treatment with appropriate ligand; and Nyquist plots of the complexes (2b and 2c) under 98% RH condition and ambient temparature. dynamic systems induced by both coordination ability and geometry of the ligand. Moreover, computational study further supported the fact that coordination interaction of imidazole moiety to Pd(II) is enthalpically more preferred compared to pyridine which drives the selection process. In addition, analysis of crystal packing of both the complexes (2b and 2c) indicated the presence of strong H-bonds between NO3- and water molecules; as well as H-bonded 3D-networks of water. Interestingly, both the complexes exhibit promising proton conductivity (10-5 to ca. 10-3 S cm-1) at ambient temperature under relative humidity of ~98% with low activation energy. CHAPTER 5 covers design and synthesis of new organometallic building block 1,3,5-tris(4-trans-Pt(PEt3)2I(ethynyl)phenyl)benzene (1) incorporating Pt-ethynyl functionality and [2 + 3] self-assembly of its nitrate analogue 1,3,5-tris(4-trans-Pt(PEt3)2(ONO2)(ethynyl)phenyl)benzene (2) with “clip” type bidentate donors (L1 – L3) separately afforded three trigonal prismatic architectures (3a – 3c), respectively (Scheme 3), Scheme 3. Schematic presentation of three different donors (L1 – L3) and a new planar tritopic acceptor (2) and their [3 + 2] self-assembly into trigonal prismatic architectures (3a - 3c). [L1 = N1,N3-di(pyridin-3-yl)isophthalamide; L2 = 1,3-bis((E)-2-(pyridin-3-yl)vinyl)benzene; L3 = 1,3-bis(pyridin-3-ylethynyl)benzene]. All these prisms were characterized and their shapes/sizes are predicted through geometry optimization employing molecular mechanics universal force field (MMUFF) simulation. The extended -conjugation including the presence of Pt-ethynyl functionality make them electron rich as well as luminescent in nature. As expected, cages 3b and 3c exhibit fluorescent quenching in solution upon addition of picric acid [PA], which is a common constituent of many explosives. Interestingly, the non-responsive nature of fluorescent intensity towards other electron-deficient nitro-aromatic explosives (NAEs) makes them promising selective sensors for PA with a detection limit deep down to ppb. Complexes 3b – c represent the first examples of molecular metallocages as selective sensors for picric acid. Furthermore, solid-state quenching of fluorescent intensity of the thin film of 3b upon exposure to saturated vapor of picric acid draws special attention for infield application.

Catalysis

Proton Conduction

Coordination Cages

Self-Assembly (Chemistry)

Coordination Chemistry

Supramolecular Chemistry

Palladium Nanocages Self-Assembly

Coordination Driven Self-Assembly

Self-Assembled Coordination Cages

Metal Organic Architectures

Inorganic Chemistry

Synthèse et coordination de dérivés calixarène et de thiacalixarène en conformation 1,3-alternée / Synthesis and coordination of calixarene and thiacalixarene derivatives in 1,3-alternate conformation

Noamane, Mohamed Habib

13 December 2013

Les récepteurs moléculaires sont des architectures maintenues par des liaisons covalentes et capables de fixer sélectivement des substances (ioniques et/ou moléculaires) au moyen d’interactions intermoléculaires diverses, aboutissant ainsi à la formation d’un assemblage d’au moins de deux espèces nommé complexe moléculaire. Au cours de ce travail, des stratégies de synthèse de dérivés de calix[4]arène et de son analogue thiacalix[4]arène en conformation 1,3-alternée ont été mises au point. Ces composés ont été fonctionnalisés par des groupements pyridine, catéchol, imidazole, pyrazole et pour la première fois oxamate. Les composés obtenus ont été caractérisés à la fois en solution par RMN et à l’état cristallin. Les propriétés complexantes vis-à-vis des métaux de transition en solution sont présentées. Pour certains dérivés, le pouvoir extractant envers les métaux de transition a été étudié et discuté. Enfin, la formation de réseaux de coordination à l’état cristallin par auto-assemblage de dérivés de calixarène ou de thiacalixarène et le cation argent est présentée et commentée. / Molecular receptors are preorganised architectures held by covalent bonds and capable of binding selectively ionic and / or molecular substrates via various intermolecular interactions, leading to the formation of molecular complexes composed of at least two species.In this work, the synthesis of a library of calix[4]arene and its analogue thiacalix[4]arene in 1,3-alternate conformation based ligands and tectons has been investigated. These two types of platforms have been equipped with pyridine, catechol, imidazole, pyrazole and, for the first time, oxamate units as coordinating sites. All compounds prepared were characterized in solution and in some cases in the crystalline state. Their binding propensity in solution towards transition metals has been determined and discussed. For some derivatives, their metal extracting properties have been investigated and presented. Finally, the formation of extended periodic architectures of the coordination network type in the crystalline state by self-assembly of calixarene based tectons and silver cation was achieved and presented.

Calixarène

Thiacalixarène

Synthèse

Chimie Supramoléculaire

Chimie de coordination

Interactions non-covalentes

Réseaux de coordination

MOF

Complexation en solution

Extraction liquide-liquide

Calixarene

Thiacalixarene

Synthesis

Supramolecular chemistry

Coordination chemistry

Non-covalent interactions

Coordination networks

MOF

Complexation in solution

Liquid-liquid extraction

547.2

Tectonique moléculaire : conception et formation de polymères de coordination chiraux / Molecular tectonics : design and formation of chiral coordination polymers

Larpent, Patrick

20 December 2013

La formation de polymères de coordination poreux et chiraux ainsi que leur utilisation pour des processus énantiosélectifs est actuellement un des domaines de grand intérêt en chimie. La formation de ces matériaux est rendue possible par le biais des concepts développés dans le domaine de la tectonique moléculaire. Les travaux présentés dans cette thèse s’inscriventdirectement dans cette thématique. Les synthèses de tectons organiques chiraux sont présentées. Leur combinaison avec divers centres métalliques, via différentes méthodes de cristallisation, a permis l’obtention de monocristaux qui ont été étudiés par diffraction des rayons X sur monocristal. Dans un premier temps, des polymères de coordination homochiraux, obtenus par l’utilisation de tectons dotés de sites coordinants neutres sont présentés. Des réseaux de type cuboïde présentant des canaux monodimensionnels au sein de leur architecture sont notamment décrits. Par la suite, des édifices mono- et bi-dimensionnels de géométries diverses sont discutés. Pour certains de ces cristaux, des interactions de plus faible énergie que la liaison de coordination permettent la formation de réseaux moléculaires de plus haute dimensionnalité. Enfin, dans une dernière partie, l’utilisation de tectons dotés de sites coordinants chargés est discutée. Des réseaux tridimensionnels homochiraux poreux et robustes sont décrits. Ces derniers sont des candidats de choix pour des procédés énantiosélectifs de séparation. Leur propension à encapsuler des gaz (N2 et CO2) est présentée. / The synthesis and the use of porous chiral coordination polymers for enantioselective processes are of current interest and prime importance in chemistry. These crystalline materials are mainly obtained by combinations of well-designed organic tectons and properly chosen metallic components. This thesis deals with the synthesis of organic chiral building blocks and their combinations with a variety of metallic salts leading to chiral coordination networks. In a first part, the use of tectons bearing neutral coordinating sites is described. Homochiral cuboid architectures displaying monodimensional channels are presented. In the second part, mono- and bi-dimensional networks of various geometries are described. In some cases, within crystals, interactions lower in energy than the coordination bond are observed and are responsible for the formation of molecular networks of higher dimensionality. Finally, the use of organic tectons displaying charged interaction sites is presented. Their combination with metallatectons under thermal treatments affords robust tridimensional homochiralarchitectures displaying cavities. These materials are interesting candidates for enantioselective recognition and separation. Their gas adsorption propensity (N2 and CO2) is briefly discussed.

Chimie supramoléculaire

Tectonique moléculaire

Reconnaissance moléculaire

Synthèse organique

Chiralité

Polymères de coordination chiraux

Reconnaissance enantiosélective

Cristallisation

Diffraction des rayons X

Monocristaux

Supramolecular chemistry

Molecular tectonics

Molecular recognition

Organic synthesis

Chirality

Chiral coordination polymers

Enantioselective recognition

Crystallization

X-Ray diffraction

Single crystal

547.8

Control of molecular movement based on porphyrins / Contrôle du mouvement moléculaire à base de porphyrines

Meshkov, Ivan

31 March 2016

Les travaux décrits dans ce manuscrit s’intéressent au contrôle du mouvement moléculaire. Après une introduction dédiée à l’état de l’art des machines moléculaires, le premier chapitre s’intéresse à la conception de tourniquets moléculaires à base de complexes porphyriniques de P(V). Le mouvement moléculaire a pu être contrôlé de manière réversible soit par l’utilisation des sites de coordination présents à la périphérie du système soit par des variations de pH. Le deuxième chapitre s’intéresse aux propriétés photophysiques des porphyrines de P(V) obtenues et plus particulièrement à leur capacité à générer de l’oxygène singulet avec une application potentielle en Thérapie Photodynamique (PDT).Le troisième chapitre concerne l’élaboration d’un complexe contenant deux porphyrines de Zn(II) dont le mouvement relatif a pu être bloqué réversiblement par l’utilisation des positions axiales des cations métalliques. / The manuscript focuses on molecular machines and the control of their movement. Two different devices have been designed, synthetized and characterized. Moreover, a series of new potential photosensitizer was obtained.The introduction gives a general overview on molecular machines, reported during the past 20 years. The first chapter describes the synthesis of molecular turnstiles based on P(V) porphyrins. The molecular motion was controlled reversibly using either coordination chemistry or by changing the pH. The second part is dedicated to the study of the photophysical properties of P(V) porphyrins and especially their capacity to generate singlet oxygen under irradiation., making them potential photosensitizers that can be use in Photodynamic Therapy (PDT) or as catalyst. The third chapter is devoted to the study of a molecular break based on a Zn (II) porphyrin dimer. The control of the movement was performed using the coordination of a bidentate ligand in the axial position of the metal cations.

Machine moléculaire

Tourniquet moléculaire

Chimie supramoléculaire

Porphyrine de P(V)

Chimie de coordination

Oxygène singulet

Porphyrin de Zn(II)

Molecular machines

Molecular turnstiles

Supramolecular chemistry

P (V) porphyrins

Coordination chemistry

Singlet oxygen

Zn (II) porphyrins

541.3

541.2

Template-Assembled Synthetic G-Quartets (TASQ) hydrosolubles : du ligand de quadruplexes d'ADN et d'ARN à la plateforme catalytique / Water-soluble Template-assembled synthetic G-quartets (TASQ) : from DNA and RNA G-quadruplexes ligands to catalytic applications

Stefan, Loïc

04 December 2013

Formés à partir de brins d’ADN ou d’ARN riches en guanines, les quadruplexes résultent de l’empilement de tétrades de guanines constituées chacune par l’auto-assemblage dans un même plan de quatre guanines, stabilisées entre elles par un réseau de liaisons hydrogènes. En s’inspirant de cet édifice naturel, il est présenté au long de ce manuscrit de thèse la synthèse et l’étude de molécules de type TASQ (pour template-assembled synthetic G-quartet) hydrosolubles capables de former de manière intramoléculaire une tétrade de guanines synthétique : les DOTASQ, le PorphySQ et le PNADOTASQ. La première application développée pour ces composés est le ciblage des quadruplexes d’ADN et d’ARN, présents dans des régions clefs du génome (télomères, promoteurs d’oncogènes) et du transcriptome (5’-UTR et TERRA), et dont la stabilisation par un ligand pourrait ouvrir de nouvelles perspectives en terme de thérapie antitumorale ciblée. Les résultats in vitro sont présentés et permettent de démontrer que les TASQ hydrosolubles développés sont des composés offrant une bonne sélectivité pour les quadruplexes mais surtout une excellente sélectivité grâce à un mode d’action bioinspiré basé sur une reconnaissance biomimétique. La seconde application mise au point est l’utilisation des TASQ comme catalyseurs pour des réactions de peroxydation : leur architecture même leur permet de mimer l’activité catalytique de l’ADN (ou DNAzyme) ainsi que celle de protéines (enzyme) comme la horseradish peroxidase. Ce processus est dépendant de la formation intramoléculaire de la tétrade de guanines synthétique et ouvre de nombreuses perspectives en terme d’utilisation en biologie ainsi qu’en nanotechnologie. / Natural G-quartets, a cyclic and coplanar array of four guanine residues held together via Hoogsteen H-bond network, have recently received much attention due to their involvement in G-quadruplex-DNA, an alternative higher-order DNA structure strongly suspected to play important roles in key cellular events (chromosomal stability, regulation of gene expression). Besides this, synthetic G-quartets, which artificially mimic native G-quartets, have also been widely studied for their involvement in nanotechnological applications (i.e. nanowires, artificial ion channels, etc.). In contrast, intramolecular synthetic G-quartets, also named template-assembled synthetic G-quartet (TASQ), have been more sparingly investigated, despite a technological potential just as interesting.In this way, we designed and synthesized three series of innovative hydrosoluble TASQ: DOTASQ (for DOTA-Templated Synthetic G-Quartet), PorphySQ (containing a porphyrin template) and the most effective PNADOTASQ where PNA-guanine arms replace native DOTASQ alkyl-guanine arms. We report herein the results of both DNA and RNA interactions (notably their selective recognition of quadruplex-DNA according to a bioinspired process) and peroxidase-like hemin-mediated catalytic activities (either in an autonomous fashion as precatalysts for TASQzyme reactions, or in conjunction with quadruplex-DNA as enhancing agents for DNAzyme processes). These results provide a solid scientific basis for TASQ to be used as multitasking tools for bionanotechnological applications.

Biocatalyse

Chimie supramoléculaire

Conception biomimétique

DNAzyme

G-quadruplexe

Hemin

Smart-ligand

Structures non-usuelles d’ADN

TASQ

Tétrade de guanines

Biocatalysis

Biomimetics

DNAzyme

G-quadruplex

G-quartet

Hemin

Non-canonical DNA structures

Smart-ligand

Supramolecular chemistry

TASQ

541.2

547

Conception et synthèse de nouvelles plateformes moléculaires de type cryptophane. Application à l’encapsulation du xénon et de cations métalliques en solution aqueuse / Conception and Synthesis of New Molecular Platforms based on Cryptophanes. Application for the Encapsulation of Xenon and Metallic Cations in Aqueous Solution

Chapellet, Laure

04 December 2015

Les cryptophanes sont des récepteurs moléculaires qui présentent des propriétés de complexation intéressantes vis-à-vis de nombreux substrats. Ces quinze dernières années, les cryptophanes ont fait l’objet de beaucoup d’études portant sur leur utilisation pour l’obtention de biosondes pour l’IRM du xénon hyperpolarisé. De très nombreux progrès ont été réalisés, et des études in vivo semblent à présent envisageables, à condition de parvenir à synthétiser les biosondes en larges quantités. Plus récemment, un champ d’application parallèle s’est développé. Celui-ci porte sur la complexation des cations métalliques monovalents en solution aqueuse au sein de cryptophanes polyphénoliques. Ceci laisse envisager des applications pour la dépollution des eaux contaminées par des cations Cs+ ou Tl+. Cependant, ici encore, l’un des enjeux majeurs est la synthèse de larges quantités de cryptophanes présentant les caractéristiques recherchées. Les travaux réalisés au cours de cette thèse traitent de la conception et de la synthèse de nouvelles plateformes moléculaires pour l’obtention de biosondes au xénon hyperpolarisé et pour la complexation des cations métalliques monovalents Cs+ et Tl+. Les voies de synthèse mises au point permettent l’obtention de quantités appréciables d’un ensemble de nouvelles plateformes hydrosolubles pour chacune de ces applications. Les propriétés d’encapsulation de ces molécules hôtes envers leur substrat de prédilection ont été étudiées par RMN des noyaux encapsulés, par dichroïsme circulaire ou encore par titrage calorimétrique. Dans chaque cas, les nouvelles plateformes remplissent les caractéristiques recherchées et ouvrent la voie aux applications visées. / Cryptophanes are molecular receptors known for their complexation properties of various substrates. Over the last fifteen years, cryptophanes were the subject of numerous studies for they can be used to obtain biosensors for xenon MRI. This field has experienced significant growth and advances to the point were in vivo applications are now envisioned, provided that large amounts of biosensors can be synthesized. More recently, polyphenolic cryptophanes have been studied for their ability to encapsulate monovalent metallic cations like Cs+ and Tl+ in aqueous solution. This could lead to applications for depollution of contaminated water sources but would require, once again, the synthesis of large amounts of cryptophanes.The work carried out during this thesis focus on the conception and the synthesis of new molecular platforms that could either be used to obtain new hyperpolarized xenon biosensors or to encapsulate monovalent metallic cations as Cs+ and Tl+. Synthetic routes have been developed to produce good amounts of a variety of new hydrosoluble molecular platforms designed for each application. The encapsulation properties of these new host molecules were studied through NMR of the encapsulated nucleus, circular dichroism or isothermal calorimetry. In each case, the new platforms meet the expected requirements thus opening the door for the envisioned applications.

Cryptophane

Xénon hyperpolarisé

Imagerie par résonance magnétique

Chimie supramoléculaire

Encapsulation de cations métalliques

Césium

Thallium

Synthèse organique

Cryptophane

Hyperpolarized xenon

Magnetic resonance imaging

Supramolecular chemistry

Metallic cations encapsulation

Cesium

Thallium

Organic synthesis

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

Beyazit, Selim

12 December 2014

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

Polymères stimuli-sensibles

Nanoparticules cœur-coquille

Nanoparticules de conversion ascendante

Polymérisation radicalaire contrôlée

Bio-imagerie

Nanomatériaux

Imagerie cellulaire

Ingénierie tissulaire

Applications biomédicales

UCP

Stimuli-responsive polymers

Core-shell nanoparticles

Upconverting nanoparticles

Controlled radical polymerisation

Supramolecular chemistry