Tetrazoles are potent anion recognition elements in a variety of structural contexts

Pinter, Thomas

01 May 2015

In efforts to expand the limited amount of functional groups available for anion recognition, a series of highly acidic, strongly hydrogen bond-donating groups were envisaged as suitable candidates. These included the thoroughly studied N-aryl sulfonamides along with the less utilized N-acyl sulfonamides and tetrazoles. These groups were affixed to a well-understood supramolecular platform in calix[4]arene and their binding affinities for various halides and oxyanions probed. It was found that although in its least energetically favourable conformation that is orthogonal to the aryl group to which it was bound, the tetrazole proved a superior anion-binding element. Noting that tetrazoles prefer co-planarity with aryl neighbours, a series of pyrrolyl-tetrazole anion binding compounds were prepared, first a simple bidentate pyrrolyl-tetrazole which when tested for anion binding affinity demonstrated some of the strongest binding with anions for a bidentate compound ever observed, especially chloride. It was then conceived to hybridize this new binding motif with the well-known amidopyrrole moiety and two new tetrazolyl-amidopyrroles were constructed. When compared to an ester-functionalized pyrrolyl-tetrazole, binding strength with halides was not much different, leading to the postulation that the amide N-H may just be a spectator in the binding event, and the electron-withdrawing nature of the adjacent carbonyl was what led to the binding potency. Nonetheless, a new class of diversifiable anion binders with superior strength to analogous amidopyrroles has been constructed and could perhaps be used in a variety of functional applications. / Graduate

tetrazoles

anion-binding

Noncovalent interactions behind the direct and inverse Hofmeister effects

January 2018

acase@tulane.edu / Rational, synthetic design is implemented in a systematic study of the effect of host shape and properties and manifestations of the reverse Hofmeister effect. Hofmeister specific effects were observed at the molecular level wherein it was shown that key to the effectiveness of some “salting-in” anions is their complementarity to hydrophobic cavities and other binding surfaces. A gamut of responses was observed across a range of hosts possessing different structural and functional motifs. These observations were typically manifest at a relatively low (<20 mM) critical precipitation concentration (CPC). Furthermore, it was shown that at low concentrations, typical observations of screening effects are not observed, and binding-site competition is a predominant factor when multiple anions are present in solution. In terms of quantifying the ion recognition sites of different, similarly charged hosts there is little difference in anion affinity, but large differences are observed in 1/CPC values. Thus, subtle changes in the recognition site have dramatic changes in terms of manifestations of the reverse Hofmeister effect. This is (to the authors best knowledge) the first example of a systematic study sequentially modifying small molecular hosts and utilizing them to study reverse Hofmeister trends. In total 12 hosts and 6 host-guest complexes were examined. These studies demonstrate applications of the reverse Hofmeister effect to generate single crystal X-ray structures, with potential applications in protein and small molecule purifications, separations, and crystallizations. / 1 / Jacobs Jordan

Hofmeister effect

Supramolecular

anion binding

ITC and NMR spectroscopy binding studies of meso- octamethyl-calix[4]pyrrole and its derivatives

Gross, Dustin Eugene

03 September 2009

This dissertation reports on the recent discovery that calix[4]pyrrole not only functions as an anion receptor, but also has the ability to act as an ion pair receptor. It was discovered that in the solid state large diffuse cations, such as Cs+ and imidazolium, will occupy the electron-rich cone-like cavity that is formed upon anion binding to the NH region of the calix[4]pyrrole core. Also discussed are efforts devoted to improving the anion binding ability of calixpyrroles and fine-tuning their inherent selectivity. This has been probed through a variety of structural modifications. One of the most attractive of the modification strategies currently being explored involves expansion of the central binding cavity by using higher order β-fluorinated calix[n]pyrroles; n = 5, 6, and 8. An advantage of β-fluorinated calix[4]pyrrole is that it shows enhanced anion binding affinities toward several anions compared to the parent calix[4]pyrrole. Fluorinated calixpyrroles have also shown an ability to extract anions from aqueous environments into organic media. An alternative strategy has been to attach “straps” resulting in bicyclic systems, which further define the binding cavity achieving higher affinity and anion selectivity. The binding interactions of calixpyrrole and it derivative have been quantified using analytical techniques, such as nuclear magnetic resonance spectroscopy and isothermal titration calorimetry. The results of these latter studies will be discussed herein. / text

Supramolecular Chemistry

Anion Binding

Isothermal Titration Calorimetry

Polypyrrolic systems : anion binding, photophysical properties, and electron transfer / Anion binding, photophysical properties, and electron transfer

Karnas, Elizabeth Theresa

15 February 2012

Anion Binding has recently emerged as an important field of study due to the role these small inorganic species play in a plethora of biological processes. Chapter 1 of this thesis describes the biological relevance and scientific justifications for studying the ability of synthetic molecules to transport or extract anions under interfacial conditions. This chapter also serves to underscore the need to study both the thermodynamics and kinetics of anion binding as achieved using synthetic receptors. Methods for determining the thermodynamics of ion recognition are well-developed, and many equilibrium analyses of supramolecular binding events have been reported; however, the kinetics of such interactions are often neglected. Chapter 2 details the author's efforts to address this deficiency with respect to anion-binding and reports progress towards quantitative kinetic analyses of the interaction between cyclo[8]pyrrole (C8), an expanded porphyrin, and two test anions. It has been determined that stopped-flow analysis can provide on and off-rates, as well as activation parameters not accessible through thermodynamic means. Initial flash photolysis kinetic studies have also revealed that C8 has the potential to act as a photosensitizing agent through electron donation. This work is presented in Chapter 3, wherein the author discusses the construction of novel donor-acceptor dyads based on C8. As detailed in this chapter, time-resolved optical analyses have confirmed that photoinduced electron transfer occurs under conditions of photoexcitation and that the lifetime of the charge separated state is approximately 300 [mu]s. Finally, Chapter 4 describes a comprehensive set of spectroscopic work conducted by the author involving porphyrin and porphycenes that have a RuCp* (Cp*: pentamethylcyclopentadienyl) fragment either coordinated to the central porphyrinic core or directly attached to the "[pi]-face" of the macrocycle. These systems display unique intramolecular electron transfer properties that are ascribed to the metallated-porphyrin core acting as an electron acceptor, as opposed to a donor as is normally observed with porphyrins. / text

Anion binding

Expanded porphyrins

Electron transfer

Tetrathiafulvalene Schiff-base ligands and anion receptors

Bejger, Christopher Michael

12 November 2013

Over the last decade, the classic organic donor tetrathiafulvalene (TTF) has emerged as an important functionality in supramolecular systems and complex ligand chemistry. Due to synthetic advances, TTF is no longer a moiety strictly limited to the area of charge transfer salts in material science. In fact, many complex systems incorporating the electron rich donor system are known. More can be imagined. This doctoral dissertation describes the author's journey in designing, synthesizing, and studying various compounds in which the TTF moiety serves a practical purpose, oftentimes giving known molecules new functions. The reported findings have led to a greater understanding of anion binding effects on TTF-containing anion receptors, the use of transition metals to pre-organize [pi]-faces for through-space donor-acceptor interactions, and the introduction of actinide species to tetrathiafulvalene ligands. The first Chapter provides a brief introduction and a short history of TTF chemistry. It also provides an overview describing the fundamental properties of TTF compounds, including TTF dimeric behavior and redox properties. Chapter 2, as the major focus of this dissertation, details the use of a flexible TTF-modified macrocyclic ligand, which upon metallation can effectively preorganize two TTF units to interact when oxidized. Specifically, a new way to stabilize the through-space mixed-valence TTF dimer, in which a transition metal can affect the degree of interaction between the two TTF units, is described. The mixed-valence TTF species in question could see use as components in molecular machines and could play an important role as molecular organic conductors, and discussions along these lines are included in this chapter. These mixed valence complexes were investigated by spectroscopic (¹H-NMR, UV-Vis NIR titrations, and EPR analysis) and X-ray single crystallographic analyses involving both the neutral and oxidized products. Chapter 3 introduces the synthesis, characterization, and electrochemistry of the first TTF-ligand to form a complex with an actinide cation. Chapter 4 details the synthesis, binding studies and X-ray single crystallographic analyses of a TTF-based electrochemical sensor for dihydrogen phosphate anion detection. Experimental procedures and characterization data are reported in Chapter 5. / text

Tetrathiafulvalene

Anion binding

Organic mixed-valence

Synthesis, anion binding, and photophysiscal properties in polypyrrolic systems

Vargas-Zúñiga, Gabriela Idania

03 March 2014

Anion binding has emerged as an important field of study due to the role that anionic species play in nature. As a consequence, considerable effort has been focused on the generation of anion receptors. These receptors have been designed to recognize anions through interactions, such as hydrogen bonding, donor-acceptor, and hydrophofic effects, in order to achieve higher sensitivity and selectivity. Another approach involves ion pair recognition, wherein the anions and cations are bound to the same system. Specifically, receptors bearing both hydrogen bonding donor and cation coordination sites have been of great interest as systems that lead to anion recognition and enhanced anion selectivities. Chapter 1 of this dissertation describes efforts to develop systems on the basis of modified Schiff-base calixpyrroles. This modification was achieved by incorporating a “strap” across the macrocycle to produce the so-called strapped Schiff-base calixpyrroles. The strap bearing amides are known to act as hydrogen bonding donors that can isolate the binding site from the medium. On the other hand, Schiff-base calixpyrroles have been widely studied as multidentate ligands for metal cation coordination. Therefore, the synthetic combination of these two moieties might provide a system wherein an ion pair complex is formed. Strapped Schiff-base calixpyrrole palladium complex were found to bind selectively cyanide anions. The effects of direct substitution on one meso position on the optical and photophysical properties of porphycenes was recently found to be dependent of the electronic properties of the substituten (e.g., electron donor or electron withdrawing group). However, the effects on the electronic and optical properties properties as a result of substitution through a conjugated spacer are as yet unknown. This led to the synthesis of four meso substituted etioporphycenes, which are described in Chapter 2. Here, the substitution through an ethenyl group was stablished by analytical and structural means. This chapter provides of a description of the spectroscopic, structural and voltamperometric features of these compounds. Experimental procedures and characterization data are reported in Chapter 3. / text

Anion binding

Porphycenes

Schiff-base

Calixpyrrole

Capsules, secondary interactions and unusual multi-metallic complexes

Hart, John Stewart

January 2012

Research into inorganic supramolecular chemistry is burgeoning, in particular that which focuses on the formation of capsular molecules and the effects that these unique environments have on catalytic reactions. With the aim of producing new ligand designs that could not only support reactive metals, but also partake in supramolecular aggregation to provide a capsular microenvironment, new tripodal ligands and wide span imines and amines have been synthesised. Furthermore, the exploitation of hydrogen-bonding motifs formed through pyrrole-imine tautomerisation upon metallation of these ligands has been explored, with the aim of enhancing reactivity and stabilising reactive intermediates. In Chapter one, the concept of covalent and non-covalent capsules is introduced, and includes the different aspects affecting the encapsulation of molecules and their use as nanoreactors. The use of secondary interactions, e.g. hydrogen-bonding in metal complexes of tetrapodal and tripodal ligands is discussed. Chapter two describes the synthesis of a tripodal pyrrole-imine ligand and the formation of its multi-metallic complexes of Group one metals, transition metal and the f-block elements. The complete and partial tautomerisation of this ligand upon metal complexation is also examined. In Chapter three, the formation of hangman complexes of the tripodal pyrrole-imine ligand is described and is extrapolated to the chemistry of a new pyrrole-amide ligand. The synthesis of this latter ligand and its properties with regards to anion binding are also explored. Chapter four describes the formation of wide span diamine and diimine ligands and their propensity to form adducts with cobalt and zinc chlorometallates and unusual multimetallic palladium complexes. The final conclusions of the work presented in this thesis are drawn in Chapter five. Chapter six presents experimental details and characterising data for all of the new compounds presented in this thesis.

547

Silanediols As Hydrogen Bond Donor Catalysts

Schafer, Andrew Gerard

21 August 2014

No description available.

Chemistry

organocatalysis

silanediol

anion-binding

hydrogen bond donor

Synthèses et applications de nouveaux ligands pyrroliques et méthodologies de synthèse de phosphines P-chirogéniques / Synthesis and applications of new ligands derived from pyrrole and methodologies for the synthesis of P-chirogenic phosphines

Copey, Laurent

27 November 2014

Deux thématiques principales ont été étudiées au cours de cette thèse. La première partie porte sur la synthèse de complexes de manganèse dérivés de porphyrines et de salens. L'activité catalytique de ces complexes a été évaluée dans l'époxydation d'alcènes non-Fonctionnalisés. Suite à cette étude, les propriétés électroniques des ligands ont été étudiées, notamment par le biais de la complexation d'anions. Dans une deuxième étape, nous nous sommes intéressés à la synthèse de phosphines P-Chirogéniques. Afin de trouver un substitut à l'éphédrine, couramment utilisée dans ces synthèses, des dérivés du (1S,2S)-2-Aminocyclohexanol et de la D-Glucosamine ont été synthétisés. L'utilisation de groupements sulfonamides a permis l'obtention aisée d'oxazaphospholidines N-Tosylées. L'un ou l'autre diastéréoisomère de cet hétérocycle peut être obtenu en fonction du degré d'oxydation du réactif phosphoré utilisé. Avec cette stratégie, divers oxydes de phosphines ont été obtenus avec de bons rendements et de bonnes énantiosélectivités / This thesis is divided in two parts. The first part focuses on the synthesis of manganese complexes derived from porphyrins and salens. The catalytic activity of these complexes were evaluated toward the epoxidation of unfunctionalized alkenes. Next, the electronic properties of the ligands were evaluated using their anion binding properties. In a second part, we were interested in the synthesis of P-Chirogenic phosphines. In order to find a surrogate to ephedrine, that is commonly used in those syntheses, derivatives from (1S,2S)-2-Aminocyclohexanol and D-Glucosamine were synthesized. The use of sulfonamides allows the access to N-Tosylated oxazaphospholidines. Both diastereoisomers could be synthesized depending on the oxydation state of the phosphine precursor. Using this strategy, various phosphine oxides were obtained in good yields and enantioselectivities

Epoxydation

Complexation d’anions

D-glucosamine

Synthèse asymétrique

Epoxidation

Anion binding properties

D-glucosamine

Asymmetric synthesis

540

Bile Acid Derived Adaptive Dendrons And Anion Receptors

Ghosh, Sanjib

12 1900

Chapter 1. Bile acid derived adaptive dendrons Bile acids are naturally occurring rigid, chiral molecules with unique facial amphiphilicity making it an attractive build block for designing supramolecular systems. Synthesis of bile acid derived chiral dendrimers with acetates protecting the peripheral hydroxyl groups has already been reported by our group (Figure 1). These dendrons did not survive an attempted deprotection of the acetates, as the dendritic linkages were ester linkages. To keep the facial amphiphilicity of bile acid fragments intact, we have worked on two different synthetic strategies. Bile acid derived dendritic components having chloroacetate functional group were synthesized and the α-halo ketone was reacted with a bile acid carboxylate to generate a dendritic species with free hydroxyl group having a glyocolate spacer (Figure 2). At the same time we also were able to protect bile acid hydroxyl group as its corresponding benzyl ether and after dendron synthesis, benzyl groups were removed by hydrogenolysis to give bile acid derived dendritic components with free hydroxyl groups and simple ester linkages (Figure 2). Dye solubilization ability of these dendrons was tested. We observed that some of these structures had the ability to solubilize both a polar dye in a nonpolar solvent and/or a nonpolar dye in a polar solvent. We carried out different extraction techniques (liquid-liquid, solid-liquid) and transport experiments to establish that these dendrons can act as both as normal and inverse micellar mimics. Depending upon the polarity of the medium, this dendron (Figure 2, right) can adopt different conformation and hence this is described as an “adaptive dendron” (Figure 3). Chapter 2. Bile acid derived anion receptors We discovered that the self-condensation of 3α-chloroacetyloxy cholic acid produced a “cholaphane” with free hydroxyl groups in just two step from naturally occurring bile acid. This cyclic dimer (Figure 4) is an inside-out cyclodextrin analog having a polar interior and nonpolar outer surface. The structure of this molecule was confirmed by X-ray crystallography (Figure 5). This molecule showed a remarkable ability to bind two fluoride ions in its cavity (K1 = 1900 M-1 and K2 = 250 M-1 in CHCl3). The pair of doublets from the glycolate methylene hydrogen spacers were found to collapse to a singlet and they again reappear as a pair of doublets with increase in the concentration of fluoride. This anomalous behaviour of gylcolate methylene spacers were rationalized by MP2 calculation at the 6-31+G* level which showed that upon interaction with fluoride, electron density on C-H hydrogen decreased while that on the other geminal hydrogen increased. Detailed NMR study and interaction of fluoride with different acyclic compounds enabled us to determine the mode of fluoride binding. Based on the NMR data and calculation results, fluoride binding models were proposed involving O-H…F- and C-H…F- interactions. When the binding affinity of cyclic dimer was examined for other anions, this molecule showed weak affinity to chloride ions (K ~ 100 M-1) whereas for other bigger anion (HSO4-, H2PO4-) it showed no binding. Similar interactions were utilized to generate bile acid based tripodal geometry where those receptors were able to bind anions weakly (K ~ 100-200 M-1 for fluoride, chloride and bisulphate).

Bile Acids

Dendron

Anion Receptors

Dendrimers - Synthesis

Anion Binding

Adaptive Dendrons

Organic Chemistry