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Boronic acids : structural and mechanistic studies and application as macromolecular sensing systemsMetola, Pedro 09 February 2015 (has links)
Boronic acids, particularly those that carry an ortho-aminomethyl group, have been extensively utilized in the field of molecular recognition in recent years thanks to their ability to reversibly bind to a wide variety of polyol substrates. They have been shown to form cyclic boronate esters rapidly upon reaction with 1,2- and 1,3-diols, catechols, carbohydrates and hydroxycarboxylic acids, making them attractive as potential sensing units. While they have found broad application in this forum, the mechanism by which they work is still up for debate. This work begins in Chapter 1 with a review of the fundamentals of ¹¹B NMR spectroscopy and its application on the analysis of boronic acid-containing systems. The focus of Chapter 2 turns toward systems with an o-iminomethylphenylboronic acid moiety. This species can be formed easily through a three-component assembly, though physical understanding of this complex lags behind. With the fundamentals of ¹¹B NMR spectroscopy detailed previously, the results obtained when utilizing this technique to study both the structure and mode of interaction in these species will be presented. In Chapter 3 we give a comprehensive review of the data and conclusions that have been published by different groups about one of the most successful fluorescent sugar sensors of this kind, first introduced by Seiji Shinkai in 1994. Additionally, it delineates the experimental results obtained by our group when attempting to answer some of the remaining questions. In Chapter 4 we report the use of the aforementioned multi-component assembly as an enantioselective sensor for α-chiral primary amines. Using circular dichroism, the ee% of these analytes could be accurately determined with this system. Additionally, enantio- and chemodiscrimination was possible by employing chemometric tools like PCA and LDA. Finally, Chapter 5 is a compilation of efforts to expand the use of these sensing systems into synthetic organic chemistry research labs. In collaboration with Xumu Zhang at Rutgers University, we have implemented a previously developed system to analyze the product of an asymmetric hydrogenation of an imine to create a chiral amine. A proof of concept study on a novel automated circular dichroism plate reader prototype aimed to increasing sample throughput was completed at New York University with Professor Bart Kahr. / text
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Synthesis and application of novel boronates containing intramolecular N-B interactionsKelly, Andrew January 2008 (has links)
No description available.
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Sensing chiral amines via supramolecular chemistry and circular dichroism spectrometryDragna, Justin M. 14 August 2015 (has links)
In chapter 1 the principles behind circular dichroism spectroscopy and exciton coupled circular dichroism spectroscopy are outlined, and examples are cited that illustrate the utility of these methods in the determination of absolute configuration and ee of chiral amines. This provides background and context for this thesis, which mostly pertains to the sensing of chirality in amines. An exciton coupled circular dichroism method based on the induction of helical chirality in an organometallic host for sensing chiral amines is presented in chapter 2. The method can be used to determine absolute configuration by relating the sign of the first Cotton effect of the host-amine complex to the handedness of the amine. Analysis of the primary circular dichroism optical data is by principal component analysis allows for differentiation of the analytes based on their idendity and handedness. A novel circular dichroism method for detecting chiral amines is discussed in chapter 3. The method uses a highly efficient derivatization method to convert the primary amine into a bidentate imine. Three equivalents of the imine are then assembled together by coordination to Fe(II). The proximity and chiral orientation of the imines leads to exciton coupled circular dichroism, which is of utility in the determination of absolute configuration. Additionally, there is a metal-to-ligand charge transfer band in the visible region that can be used to develop calibration curves, which allow for the determination of the enantiomeric excess of unknown samples with an absolute error of ±5%. Chapter 4 details another imine based circular dichroism method for chiral amines. The method uses a commercially available aldehyde, Fe(II), and circular dichroism spectrometry to sense chirality in amines. It is shown that the circular dichroism signals in the ultraviolet spectrum vary predictably with the handedness of the chiral amine, which has potential applications in the determination of absolute configuration. By developing calibraton curves, signals in the visible spectrum can be used to determine enantiomeric excess with an absolute error of ±6%. Analyzing the primary circular dichroism optical data with linear discriminant analysis allows for differentiation between amines based on their identity and handedness. Finally, chapter 5 illustrates the potential of using the thermodynamic parameters of partitioning between water and octanol as a predictive tool for estimating the contributions of hydrophobicity to host-guest binding events. This is done by showing a relationship between the thermodynamics of partitioning and thermodynamics of hydrophobic binding events for a series of guests and cyclodextrin. A plot of the thermodynamic parameters of binding of a variety of guests to cyclodextrin as a function of the thermodynamic parameters of partitioning between water and octanol shows a linear relationship for a series of alcohols. / text
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Use of a Chiral Surfactant for Enantioselective Reduction of a KetoneDavidson, Tammy A., Mondal, Kalyan, Yang, Xiaoye 15 August 2004 (has links)
The influence of a chiral surfactant and a polymer-supported chiral additive on reduction of ketones using sodium borohydride will be described. Initial preparations involved methylation of (S)-leucinol to give (2S)-N,N-dimethyl-2-amino-4-methyl-1-pentanol (1) (67%). The chiral surfactant (2) was synthesized by reacting (1) with bromohexadecane (71%). The functionalized styrene for the polymer-supported chiral additive (5) was synthesized by reacting (1) with 4-vinylbenzyl chloride. Polymerization was carried out with 10% of the functionalized monomer (4), 5% cross-linking agent divinylbenzene, and 85% styrene with AIBN as the initiator. The activity of the chiral surfactant and polymeric additive were examined by using them as additives in a standard reduction of 2-pentanone with sodium borohydride to yield (R)- and (S)-2-pentanol (3) (20%). The resulting alcohol was analyzed by polarimetry (ee 9.5%) and also esterified with (2S)-methylbutyric acid prior to characterization by NMR. 13C NMR indicated an enantiomeric excess of 5.2% when the chiral surfactant was used, and 7% when the polymeric additive was used.
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Cobalt(II) Catalysts - Their Use in the Enantioselective Ring-opening of 1,2-DioxinesJenkins, Natalie Faye January 2003 (has links)
A series of new cobalt(II) beta-keto iminato complexes and cobalt(II) salens have been made and the effect of chirality in the northern, southern and peripheral quadrants of these catalysts, with respect to induced enantiomeric excess, during the ring-opening of 1,2-dioxines has been determined. Synthesis of a series of cobalt beta-keto iminato complexes was achieved after modification of literature procedures used for the synthesis of manganese beta-keto iminato complexes and this procedure was applied to generate ligands with ethyl, t-butyl, (-)-bornyl, (+)-menthyl and (-)-menthyl esters and a methyl side chain. Synthesis of the cobalt salens was also achieved using a modified literature procedure, in respect to the more complex aldehydes made. It was ascertained that chirality in the northern quadrant of these catalysts, obtained by the use of optically pure diamines, was of greatest importance in introducing enantiomeric excess into the products of ring-opening of 1,2-dioxines; namely gamma-hydroxy enones, and chirality in the southern and peripheral quadrants was of lesser, although still significant, importance. The reaction conditions were optimised and the conditions under which the highest enantiomeric excess was introduced were determined. The ideal solvent for the ring-opening was found to be THF with a catalyst concentration between 5 and 10 mol% at a temperature of -15oC. These conditions were found to be applicable to all catalysts and 1,2-dioxines tested. Enantiomeric excess as high as 76 % could be introduced when the optimised reaction conditions were used in large scale syntheses of cyclopropane (61). LC-MS studies indicate the presence of a solvent chelated species present in the reaction mixture when the solvent used is THF, however, the use of non-chelating solvents, such as dichloromethane, did not exhibit this same solvent chelated species. Catalyst dimers were also present in the mixture when analysed by LC-MS. The presence of oxygen in the reaction mixture was found to inhibit rearrangement of the dioxine with catalyst oxygen dimers (two molecules of catalyst bound to a single molecule of oxygen) present when analysed by LC-MS, however, the catalyst could be 're-activated' by de-aeration of the solution and was able to introduce the same enantiomeric excess, as prior to the addition of oxygen was unaffected. It was found that not only cobalt(II) tetradentate complexes were useful in the ring-opening of meso 1,2-dioxines. Achiral iron(II) salen and ruthenium(II) salen were also made and shown to be capable of ring-opening the dioxine. A purchased chiral manganese(III) salen was also shown to be capable of ring-opening the 1,2-dioxine, however, the time taken for the rearrangement to occur led to ring closure of the gamma-hydroxy enone and dehydration of the cyclic hemiacetal. The catalysts were also applied to the enantioselective ring-opening of epoxy-1,2-dioxines for the first time with a high level of success with enantiomeric excesses of between 60 and 90 % introduced with most of the catalysts. To show that these catalysts have the potential for use in the synthesis of potentially bioactive cyclopropyl amino acids, amines, acids and alcohols a small number were prepared, including both racemic and optically enriched or optically pure cyclopropanes. / Thesis (Ph.D.)--School of Chemistry and Physics, 2003.
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Origin of homochirality on Earth: Experimental and theoretical investigations / Origine de l'homochiralité sur la Terre: investigations théoriques et expérimentalesVandenbussche, Sophie J. A. 17 February 2009 (has links)
Chirality is the property of objects, including molecules, which are not superimposable on their materialized mirror image. Chiral molecules are omnipresent in living organisms and the constituents of biological macromolecules (proteins and nucleic acids) are chiral. Amino-acids (constituting proteins), ribose and 2-deoxy-ribose (the only chiral constituent of RNA and DNA nucleotides respectively) are furthermore generally present in living organisms only under one of their enantiomeric forms. This is referred to as the homochirality of the living world. The origin of this homochirality is still unexplained, even if many partial scenarios have been proposed in the literature. All scenarios involve the creation of a small enantiomeric excess for certain molecules, amplification of this excess and chirality transfer to other chiral molecules. The origin of homochirality on Earth is closely related to the origin of life, and is currently supposed to have preceded life. As no-one will ever be able to directly observe the phenomena which lead to homochirality, and
life, on our planet, the only scientific approach to try and help explain how this occurred is to build scenarios, and test them taking into account all available information on the physical and chemical conditions on the primitive Earth (Earth before life appeared). In our work, we investigated three scenarios related to the origin of homochirality on Earth. One of these scenarios also relates to a very precise step of the origin of life: the selection of beta-d-ribofuranose as component of RNA nucleotides.
Enantiomeric excesses (up to 15 %) of alpha-methylated alpha-amino-acids have been detected
in meteorites which fell on Earth during the 20th century. No enantiomeric excess is detected for the corresponding alpha-hydroxy-acids in the same meteoritic samples and small (2% at most) or no enantiomeric excesses have been measured for non-methylated alpha-amino-acids. In the first part of our work, we investigated if photolysis by circularly polarized light (CPL) in space could be at the origin of the presence (or absence) of an enantiomeric excess for these compounds. Experiments to reproduce UV-CPL photolysis are difficult to undertake: they require high-energy circularly polarized photons, hence the use of a synchrotron. In our work, we used quantum mechanical calculations to obtain
the electronic circular dichroïsm (ECD) spectra of two -methylated -amino-acids, their corresponding alpha-hydroxy-acids and one non-methylated alpha-amino-acid. Differences are
observed between these spectra, and we propose a scenario to explain the experimental measurements reported here above: the enantioselective photolysis, in the gas phase at low temperatures (20K at most), of the alpha-amino-acids by UV-CPL with lambda>210 nm. Under these conditions no photolysis of the alpha-hydroxy-acids would occur. This scenario concerns the first step in the origin of homochirality on Earth: the creation of a small enantiomeric excess for some chiral molecules.
The second scenario that we investigated relates to the enantiomeric amplification step of the origin of homochirality on Earth, for which the role of the alpha-amino-acid serine has been
suggested in the literature. Serine clusters have been observed in the gas phase by mass spectrometry. Among these clusters the octamer has been shown to be a magic number cluster and to have a preference for homochirality. An enantiomeric amplification via cycles of formation and dissociation of the octamer has been suggested. No complete scenario has however been proposed in the literature to explain how this could have occurred on the primitive Earth, but any scenario would most probably include an aqueous phase. We aimed at determining if the homochiral preference of serine octamers also exists in solution and therefore we first investigated if serine octamers exist in solution. For this study, we used nuclear magnetic resonance and infrared spectroscopies, which are well-adapted to the study of molecular assemblies in solution. We were able to demonstrate that most probably serine clusters are not present in solution, and if they are it could only be in extremely low concentration. The scenario suggested in the literature is discussed in the light of our results and of literature data on serine clusters.
As last hypothesis, we investigated a possible scenario for the selection of beta-d-ribofuranose
as component of RNA nucleotides. The currently known prebiotic synthesis pathways to ribose also lead to the formation of many other carbohydrates, and ribose is only a minor product of these syntheses. Our hypothesis is that beta-d-ribofuranose could have been selected through favorable interactions with -amino-acids already present on the primitive Earth under one enantiomeric form. Indeed, it is plausible that a peptidic world emerged before the presence of RNA and that homochiral -amino-acids were present on
Earth when RNA was synthesized. Under this hypothesis, we investigated the role that
alpha-l-amino-acids could have played in the selection of alpha-d-ribofuranose as component of
RNA nucleotides. This work is related to the last step of the origin of homochirality: chirality transfer. Our scenario was investigated via nuclear magnetic resonance studies of the interaction between alpha-amino-acids and carbohydrates. We were able to show that, in
the systems that we studied, when an interaction occurs it is very weak (affinity constant less than 1M−1) and non enantioselective. Our results most probably discard the role that alpha-amino-acids alone could have played in the selection of beta-d-ribofuranose as component
of RNA nucleotides, but does not discard the role that peptides could have played in this selection.
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Development of optical sensing protocols for the rapid determination of enantiomeric excess in high-throughput screeningLeung, Diana 27 June 2012 (has links)
Asymmetric synthesis has become an important tool to prepare enantiomerically pure compounds because it avoids the wasteful discarding of the undesired enantiomer. Combinatorial libraries allow for much faster screening for new and better asymmetric catalysts/auxiliaries, but they generate a large number of samples whose enantiomeric excess (ee) cannot be determined rapidly. This bottleneck currently limits the applicability of such approaches. We propose here the use of faster optical techniques for the determination of ee using common instrumentation, such as UV-vis spectrophotometers, and circular dichroism (CD) spectrophotometers. Our methods are easily transitioned to the microwell format commonly used in parallel/combinatorial chemistry endeavors, just by using common microplate readers: this allows for an even more rapid analysis of samples and a seamless integration in a high-throughput workflow.
We have shown that enantioselective indicator displacement assays can be developed to determine ee in a high-throughput fashion utilizing either a UV-vis spectrophotometer or a 96-well plate reader. Two chiral receptors and a commercial pH indicator were used to enantioselectively discriminate α-amino acids by monitoring the degree of indicator displacement. The two receptors were able to enantioselectively discriminate 13 of the 17 analyzed α-amino acids and accurately determine ee values of independent test samples with the use of ee calibration curves. Moreover, a sample of valine was synthesized through an asymmetric reaction, whose ee was then determined with our assay and compared to chiral HPLC and 1H NMR chiral shift reagent analysis, with excellent correlation. An artificial neural network was also successfully employed in the analyses, as an alternative to ee calibration curves. Both techniques consistently produced results accurate enough for preliminary determination of ee in a rapid manner, allowing for high throughput screening (HTS) of asymmetric reactions.
The use of circular dichroism spectroscopy with chiral BINAP was also explored to enantioselectively discriminate α-chiral ketones. The ketones were derivatized with pyridyl hydrazines to produce hydrazones, which were then bound to enantiomerically pure [Cu(I)(BINAP)]+, forming diastereomeric complexes with differential steric interactions leading to different degrees of twist in the BINAP moiety and characteristic signatures in the CD spectrum, as a function of sample ee. / text
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Cobalt(II) Catalysts - Their Use in the Enantioselective Ring-opening of 1,2-DioxinesJenkins, Natalie Faye January 2003 (has links)
A series of new cobalt(II) beta-keto iminato complexes and cobalt(II) salens have been made and the effect of chirality in the northern, southern and peripheral quadrants of these catalysts, with respect to induced enantiomeric excess, during the ring-opening of 1,2-dioxines has been determined. Synthesis of a series of cobalt beta-keto iminato complexes was achieved after modification of literature procedures used for the synthesis of manganese beta-keto iminato complexes and this procedure was applied to generate ligands with ethyl, t-butyl, (-)-bornyl, (+)-menthyl and (-)-menthyl esters and a methyl side chain. Synthesis of the cobalt salens was also achieved using a modified literature procedure, in respect to the more complex aldehydes made. It was ascertained that chirality in the northern quadrant of these catalysts, obtained by the use of optically pure diamines, was of greatest importance in introducing enantiomeric excess into the products of ring-opening of 1,2-dioxines; namely gamma-hydroxy enones, and chirality in the southern and peripheral quadrants was of lesser, although still significant, importance. The reaction conditions were optimised and the conditions under which the highest enantiomeric excess was introduced were determined. The ideal solvent for the ring-opening was found to be THF with a catalyst concentration between 5 and 10 mol% at a temperature of -15oC. These conditions were found to be applicable to all catalysts and 1,2-dioxines tested. Enantiomeric excess as high as 76 % could be introduced when the optimised reaction conditions were used in large scale syntheses of cyclopropane (61). LC-MS studies indicate the presence of a solvent chelated species present in the reaction mixture when the solvent used is THF, however, the use of non-chelating solvents, such as dichloromethane, did not exhibit this same solvent chelated species. Catalyst dimers were also present in the mixture when analysed by LC-MS. The presence of oxygen in the reaction mixture was found to inhibit rearrangement of the dioxine with catalyst oxygen dimers (two molecules of catalyst bound to a single molecule of oxygen) present when analysed by LC-MS, however, the catalyst could be 're-activated' by de-aeration of the solution and was able to introduce the same enantiomeric excess, as prior to the addition of oxygen was unaffected. It was found that not only cobalt(II) tetradentate complexes were useful in the ring-opening of meso 1,2-dioxines. Achiral iron(II) salen and ruthenium(II) salen were also made and shown to be capable of ring-opening the dioxine. A purchased chiral manganese(III) salen was also shown to be capable of ring-opening the 1,2-dioxine, however, the time taken for the rearrangement to occur led to ring closure of the gamma-hydroxy enone and dehydration of the cyclic hemiacetal. The catalysts were also applied to the enantioselective ring-opening of epoxy-1,2-dioxines for the first time with a high level of success with enantiomeric excesses of between 60 and 90 % introduced with most of the catalysts. To show that these catalysts have the potential for use in the synthesis of potentially bioactive cyclopropyl amino acids, amines, acids and alcohols a small number were prepared, including both racemic and optically enriched or optically pure cyclopropanes. / Thesis (Ph.D.)--School of Chemistry and Physics, 2003.
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Asymmetric catalysis using titanium and palladiumSesay, Simon J. January 1998 (has links)
This thesis describes, in detail, the synthesis of novel heterobidentate ligands. These ligands were subsequently used in palladium catalysed allylic substitution reactions to synthesise enantiomerically enriched alkylated products. The thesis also describes novel approaches to asymmetric catalysis, in particular asymmetric epoxidation derived from Katsuki-Sharpless methodology. Chapter 1 - This chapter reviews the literature, discussing the significant synthetic advancements in asymmetric catalysis in the past 10-15 years. Chapter 2 - This chapter describes in detail the synthesis of new heterobidentate ligands containing nitrogen and phosphorus ligating atoms. These ligands are based on imines containing enantiomerically pure asymmetric centres in an alpha position to the nitrogen moiety. Other ligands that were synthesised were derived from C2- symmetric diamines, also containing an asymmetric centre alpha position to the nitrogen, that produce ligands with the nitrogen functionality contained in a ring. Chapter 3 - This chapter describes the use of the novel ligands synthesised in Chapter 2 in palladium catalysed allylic substitution reactions. The racemic substrate, 1 ,3-diphenyl-3-acetoxy-1-propene, was alkylated to produce an enantiomeric enriched alkylated product. The alkylated product was obtained with up to 77 % enantiomeric excess. The reaction was conducted with a palladium catalyst in the presence of a novel ligand using dimethyl malonate as a nucleophile. The development and optimisation of these ligands within this reaction is discussed. Chapter 4 - This chapter discusses some novel approaches to asymmetric epoxidation. The epoxidation is based on methodology developed by Katsuki and Sharpless. This epoxidation relies on the substrate containing an up-unsaturated alcohol. The chapter discusses the use of a reversible nucleophile in the form of cyanide. The nucleophile is designed to react with a substrate to provide an upunsaturated cyanohydrin, suitable to undergo a Katsuki-Sharpless epoxidation. Once the asymmetric epoxidation is complete, the nucleophile would be removed. This chapter describes the attempts to develop the principle further. An improvement to the system would be to provide an environment capable of sustaining a dynamic kinetic resolution. Chapter 5 - This chapter contains the experimental which provides the exact details of the reactions reported in the thesis.
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Optical Sensors for Detection of Enantiomeric Excess ApplicationSheykhi, Sara 23 April 2019 (has links)
No description available.
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