Investigation of Secondary Coordination Sphere Effects for Cyanohydrin Hydration with Transition Metal Catalysts

Knapp, Spring Melody, Knapp, Spring Melody

January 2012

The synthesis of high value acrylic monomers is currently done industrially via cyanohydrin hydration using concentrated acids, resulting in large quantities of useless byproducts. This current process is energy intensive and lacks atom economy; therefore, alternative cyanohydrin hydration strategies are under investigation. Ideally, cyanohydrin hydration would be done using organometallic nitrile hydration catalysts. Cyanohydrin hydration with these catalysts is challenging, because it needs to be done at low temperatures and under acidic conditions to reduce cyanohydrin degradation and catalyst poisoning with cyanide. This dissertation describes the reactivity of [Ru(#951; / 10000-01-01

Bifunctional catalysis

Catalysis

Cyanohydrin

Nitrile hydration

Secondary Coordination Sphere Effects

Desenvolvimento de uma superfície bifuncional Pt/Au modificada com glicose oxidase para determinação de glicose em amostras alimentícias / Development of a bifunctional surface Pt/Au modified with glucose oxidase for glucose determination in food samples

Tony Rogério de Lima Dadamos

19 July 2013

A glicose é um açúcar redutor importante na dieta humana, sendo abundante em diversos alimentos, como sucos de frutas, mel, iogurtes e refrigerantes e pode ser facilmente ingerido e metabolizado. Ela fornece a energia para o corpo humano, entretanto, diversos desequilíbrios metabólicos estão associados com variações no teor de glicose no sangue, saliva ou urina. Sendo assim é preciso desenvolver métodos de baixo custo, simples e rápidos que permitam o monitoramento deste metabólito. Portanto, no presente trabalho foi desenvolvido e caracterizado um eletrodo composto por uma superfície bifuncional de Pt/Au, onde a superfície de Au foi modificada com uma monocamada auto-organizada de cistamina na qual foi ancorada a enzima glicose oxidase e a superfície da Pt com ferroceno, para determinação de glicose em amostras alimentícias. O eletrodo foi construído utilizando-se um eletrodo de platina, sobre o qual foram eletrodepositado nanoestruturas de ouro, através de voltametria linear em uma solução contendo o ânion tetracloroáurico. As nanoestruturas de ouro foram modificadas com o alcanotiol cistamina, formando uma camada auto-organizada, para servir de plataforma para ancoragem da glicose oxidase. O peróxido de hidrogênio, que é um dos produtos da reação enzimática foi determinado na platina modificada com ferroceno. Sendo assim, as nanoestruturas de ouro serviriam de sítios específicos para as enzimas, e a platina modificada com ferroceno servirá para quantificar o produto da reação enzimática. Para a detecção da glicose foram construídos três eletrodos, o eletrodo embutido (EE) para detecção de glicose em refrigerantes, o eletrodo por evaporação de platina (EEP) para detecção de glicose em amostras de iogurte e o ultramicroeletrodo (UME) para futuras aplicações de detecção de glicose por métodos não invasivos. Encontrou-se um limite de detecção de 2,4 µmol L-1 para o eletrodo EE, de 2,2 µmol L-1 para o eletrodo EEP e 0,03 µmol L-1 para o UME. Foram realizados diversos tratamentos estatísticos como erro relativo, desvio padrão e incertezas para verificar a resposta do eletrodo. Por fim, os eletrodos desenvolvidos foram aplicados na detecção de glicose em amostras de refrigerantes, chás e iogurtes, e obteve-se uma resposta satisfatória para a detecção do analito nestas amostras. / Glucose is a reducing sugar very important in the human diet and is abundant in many foods, such as fruit juices, honey, yogurt and soft drinks and can be easily ingested and metabolized. It provides the energy for the human body perform its healthy functioning. However, many metabolic imbalances associated with variations in the level of glucose in the blood, urine or saliva. Therefore it is necessary to develop methods cheap, simple and quick to allow the monitoring of this metabolite. Therefore, in the present work was developed and characterized an electrode composed of a bifunctional surface Pt/Au, where Au surface was modified with a selforganized monolayer of cystamine which was anchored in the enzyme glucose oxidase and the surface of Pt with ferrocene for the determination of glucose in food samples. The electrode was constructed using a platinum electrode, which was electrodeposited gold nanostructures, using the technique of linear voltammetry in a solution containing the anion tetrachloroauric. The gold nanostructures were modified with cystamine alkanethiol forming a self-organized layer to serve as a platform for anchoring the glucose oxidase. Hydrogen peroxide, which is a product of the enzyme reaction, was determined in the platinum modified with ferrocene. Therefore, the gold nanostructures serve as sites for specific enzymes, and platinum modified with ferrocene serve to quantify the product of the enzymatic reaction. For detection of glucose were built three electrodes, the electrode embedded (EE) for detecting glucose in soft drinks, the electrode by evaporating platinum (EEP) for detection of glucose in samples of yogurt and ultramicroelectrode (UME) for future sensing applications glucose through non-evasive. We found a detection limit of 2.4 µmol L-1 to the electrode EE, 2.2 µmol L-1 to the electrode EEP and 0.03 µmol L-1 for UME. Various statistical treatments were performed as relative error, standard deviation and uncertainties to check the response of the electrode. Finally, the electrodes developed were applied to the detection of glucose in samples of soft drinks, teas and yogurts, which gave a satisfactory response to the detection of the analyte in food samples.

glicose

sensor eletroquímico

superfície bifuncional

bifunctional surface

electrochemical sensor

glucose

Creation of bifunctional particles with spatially segregated proteins

Tang, Jennifer L

06 April 2012

We present a fabrication process to create bifunctional microparticles displaying two different proteins have been spatially segregated onto hemispheres. Silica and polystyrene microparticles with 2.0 m, 4.08 m, and 4.74 m diameters are processed with metal deposition to form two chemically distinct and segregated hemispheres. The surface of each hemisphere is then separately derivatized with proteins using different chemical conjugation strategies. These bifunctional Janus particles possess biologically relevant, native conformation proteins attached to a biologically-unreactive and safe substrate. They also display high densities of two types of spatially segregated proteins which may enable a range of capabilities that monofunctional particles cannot, such as improved targeting of drug carriers and bioimaging agents.

Janus particle

Segregated protein

Bifunctional

Nanoparticles

Smart materials

High-performance hybrid lithium-air batteries : from battery design to catalysts

Li, Longjun

01 July 2014

Growing environmental concerns and increasing demand for energy have stimulated extensive interest in electrical energy storage. Li-air batteries are appealing in this regard as they offer much higher energy density than the current Li-ion batteries, but the nonaqueous Li-air batteries suffer from poor cycle life arising from electrolyte decomposition and clogging of the air electrode by insoluble discharge products. Interestingly, hybrid Li-air batteries in which a solid electrolyte separates the lithium-metal anode in an aprotic electrolyte from the air electrode in an aqueous catholyte could overcome these problems. Lots of efforts have been made on developing efficient bifunctional catalysts to lower the overpotential and improve the stability of hybrid Li-air batteries, but the cycle life is still limited. This dissertation focuses on the development of advanced cell configurations and high-performance catalysts for hybrid Li-air batteries. First, a buffer catholyte solution with a moderate pH, based on phosphoric acid and supporting salts, has been developed to keep the solid electrolyte stable and reduce the internal resistance and overpotential. With a high operating voltage and the utilization of all the three protons of phosphoric acid, the buffer catholyte enables a Li-air cell with high energy density. Further increase in power density has been realized by increasing the solid-electrolyte conductivity and operating temperature to 40 °C. The biggest challenge with Li-air cells is the large overpotentials associated with the oxygen reduction reaction (ORR) and oxygen evolution reaction (OER). Noble-metal-free NiCo₂O₄ nanoflakes directly grown onto a nickel foam (NCONF@Ni) has been found to exhibit high OER activity that is comparable to that of the expensive, noble-metal IrO₂ catalyst. Furthermore, a novel 3-D O- and N-doped carbon nanoweb (ON-CNW) has been developed as an inexpensive, metal-free catalyst for ORR. With a hybrid Li-air cell, the ON-CNW exhibits performance close to that of commercial Pt/C. In addition, a novel hybrid Li-air cell configuration with decoupled ORR and OER electrodes has been developed. The hybrid Li-air cell with decoupled ORR and OER electrodes eliminates the degradation of ORR catalysts and carbon support in the highly oxidizing charge process and leads to high efficiency with good cycle life. / text

Lithium air batteries

Buffer catholyte

Bifunctional air electrodes

Characterisation of the Bifunctional Aspartate Kinase: Diaminopimelate Decarboxylase from Xylella fastidiosa

Dorsey, Emma Kathryn

January 2014

Xylella fastidiosa is a small, xylem-limited bacterium that causes a number of diseases in over 100 species of plants. Many of the species infected are economically important (such as coffee, grapevines, citrus, and almond) and billions of dollars worldwide are lost annually due to X. fastidiosa infection of crops. The bacterium colonises both plant and insect hosts, using the insect host to transfer it from plant to plant. Sequencing of the X. fastidiosa genome in 2000 discovered that while the genome is reduced, it contains a high number of putative bifunctional enzymes. One of these enzymes, aspartate kinase:diaminopimelate decarboxylase (AK:DapDc), occurs in only a handful of species and is predicted to catalyse the first and last steps of lysine biosynthesis. This study reports the first experimental characterisation of this enzyme. AK:DapDc was over-expressed in the pET30dSE plasmid in Escherichia coli BL21 DE3 cells. It was purified by Ni2+ His-Trap chromatography followed by size exclusion chromatography. Homology models of AK:DapDc were created in SWISS-MODEL, which indicate homology with the aspartate kinase from Arabidopsis thaliana and the diaminopimelate decarboxylase from E. coli. Circular dichroism, and analytical ultracentrifugation were used to obtain information about the secondary and quaternary structure of AK:DapDc. This data, in combination with the homology models, suggests that AK:DapDc exists as a dimer or tetramer in solution. A coupled enzyme assay to assay for diaminopimelate decarboxylase activity has been set up, and preliminary crystal screens have been carried out.

Xylella fastidiosa

bifunctional enzyme

Aspartate kinase

Diaminopimelate decarboxylase

protein characterisation

Conversion of methyl ethyl ketone (MEK) to valuable chemicals over multifunctional supported catalysts

Al-Auda, Zahraa Fadhil Zuhwar

January 1900

Doctor of Philosophy / Department of Chemical Engineering / Keith L. Hohn / The present work describes the conversion of bio-derived methyl ethyl ketone (MEK) into different useful chemicals. The first part discusses the direct conversion of MEK to butene over supported copper catalysts (Cu-Al₂O₃, Cu-zeolite Y sodium (Cu-ZYNa) and Cu-zeolite Y hydrogen (Cu-ZYH)) in a fixed bed reactor. In this reaction, MEK is hydrogenated to 2-butanol over metal sites, and further dehydrated on acid sites to produce butene. Experimental results showed that the selectivity of butene was the highest over Cu-ZYNa, and it was improved by finding the optimum reaction temperature, hydrogen pressure and the percentage of copper loaded on ZYNa. The highest selectivity of butene (97.9%) was obtained at 270 °C and 20 wt% Cu-ZYNa. Over Cu-Al₂O₃, the selectivity of butenes was less than Cu-ZYNa since subsequent hydrogenation of butene occurred to produce butane. It was also observed that with increasing H₂/MEK molar ratio, butane selectivity increased. However, when this ratio was decreased, hydrogenation of butene was reduced, but dimerization to C₈ alkenes and alkane began to be favored. The main products over 20% Cu-Al₂O₃ were butene and butane, and the maximum selectivity of butene (87%) was achieved at an H₂/MEK molar ratio of five. The lowest selectivity of butene was obtained using Cu-ZYH, reaching ~40%. It was found that the amount of acidity in Cu-ZYH is much higher than in Cu-ZYNa (from (NH₃-TPD) measurements). This could have caused the selectivity of butene to decrease as a result of dimerization, oligomerization and cracking reactions. The second part describes the conversion of MEK to higher ketones in one step using a multifunctional catalyst having both aldol condensation (aldolization and dehydration) and hydrogenation properties. 15% Cu supported zirconia (ZrO₂) was investigated in the catalytic gas phase reaction of MEK in a fixed bed reactor. The results showed that the main product was 5-methyl-3-heptanone in addition to 5-methyl-3-heptanol and 2-butanol with side products including other heavy products (C₁₂ and up). The effects of temperature and the molar ratio of reactants (H₂/MEK) on overall product selectivity were studied. It was found that with increasing temperature, the selectivity to C₈ ketone increased, while selectivity to 2-butanol decreased. The hydrogen pressure plays significant role on the selectivity of products. It was observed that with increasing the H₂/MEK molar ratio, 2-butanol selectivity increased due to hydrogenation reaction while decreasing this ratio leads to increasing aldol condensation products. In addition, it was noted that both conversion and selectivity to the main product increased using a low loading percentage of copper, 1% Cu-ZrO₂. The highest selectivity of 5-methyl-3-heptanone (~63%) was obtained at temperatures around 180 °C and a molar ratio of H₂/MEK of 2. Other metals (Ni, Pd and Pt) supported on ZrO₂ also produced 5-methyl 3-heptanone as the main product with slight differences in selectivity, suggesting that a hydrogenation catalyst is important for making the C₈ ketone, but the exact identity of the metal is less important. The third part discusses the conversion of C₈ ketones to C₈ alkenes and C₈ alkane over a catalyst consisting of a transition metal (Cu or Pt) loaded on alumina (Al₂O₃). These bifunctional catalysts provide both hydrogenation and dehydration functionalities. The main products over 20% Cu-Al₂O₃ were a mixture of 5-methyl-3-heptene, 5-methyl-2-heptene and 3-methyl heptane. However, using 1% Pt-Al₂O₃ the major product was 3-methyl heptane with a selectivity reaching over 97% and a conversion of 99.9 %. Both temperature and the hydrogen pressure play an important role on the conversion of C₈ ketone as well as the selectivity of products (C₈ alkenes and C₈ alkane). Over 20% Cu-Al₂O₃, it was observed that increasing the reaction temperature led to an increase in the selectivity to C₈ alkane as a result of hydrogenation of the C₈ alkene. Also, it was observed that with an increase in H₂/C₈ ketone molar ratio, C₈ alkane selectivity increased. However, when this ratio was decreased, the further hydrogenation of C₈ alkene to C₈ alkane was reduced. The highest selectivity of C₈ alkene (81.7%) was obtained at 220 °C and a H₂/C₈ ketone molar ratio of 2. In addition, an experiment was carried out using a low loading percentage of copper, and it was noted that both conversion and selectivity to the main products decreased over 1% Cu-Al₂O₃. Over 1% Pt-Al₂O₃, C₈ alkane was the major product with different temperatures indicating that further hydrogenation of C₈ alkene was promoted on 1% Pt-Al₂O₃. At low temperature, for both Cu-Al₂O₃ and Pt-Al₂O₃, significant amounts of C₈ alcohols are formed because subsequent reactions do not proceed at a fast enough rate. Also using 1% Pt-Al₂O₃, the main product selectivity is still C₈ alkane with all H₂/C₈ ketone ratios.

Methyl Ethyl Ketone

Bifunctional Catalyst

Multifunctional Catalyst

Butene

Hydroisomerization of alkanes over metal-loaded zeolite catalysts

Abudawood, Raed Hasan

January 2011

Zeolite catalysis plays an important role in many industrial applications due to their unique properties and has become widely used in the area of oil refining. Of particular interest is Zeolite Y, which can be hydrothermally treated into its ultrastable form, USY. USY offers a superior practicality, especially when dealuminated and metal-loaded. The importance of alkanes hydroisomerization arises from the continuingly stricter regulations imposed on the utilization of gasoline as an automotive fuel. The requirements to reduce the aromatics content in gasoline present a need to find an alternative way to maintain its research octane number (RON). An alternative to gasoline's high-octane aromatic content is to increase the RON for the paraffinic content of gasoline, which can be accomplished through hydroisomerization. Commercially, bifunctional metal-loaded zeolites are used to hydroisomerize the light naphtha stream produced at overheads of atmospheric distillation towers. However, no such process exists for the low-value heavy naphtha cut. This targeted process would, if successful, greatly improve refiner's profitability.In this work, bifunctional USY zeolite catalysts are studied in the hydroisomerization of a normal alkane (nC7, RON = 0). This nC7, found in heavy naphtha, has been used as the 'model' compound. The impact of different reaction conditions and catalyst properties on catalyst activity and stability, in addition to the catalyst selectivity to high octane isomers is one step towards determining optimum conditions and preferential catalyst formulations that favour octane maximization. Six platinum-loaded USY zeolite catalysts, four in-house and two commercial, were tested in an atmospheric glass fixed-bed reactor and a stainless steel reactor purpose-built during the course of this thesis. Reaction temperatures ranged from 170 to 250oC at pressures between 1 and 15 bar. The hydrogen to hydrocarbon molar ratio was fixed at 9, with feed space time ranging from 35.14 to 140.6 kg.s/mol. In-house catalysts were hydrothermally treated at different severities, while commercial ones were originally dealuminated through acid-leaching treatments.Results have shown commercial catalyst CBV-712 gave the best performance and highest octane values for product isomers (>30). In addition, there was no coke generation. The next best catalyst was the most severely steamed in-house catalyst (USY-D) that has shown a remarkable performance at high pressures, almost eclipsing the performance of CBV-712, yet produced higher levels of coke. Other USY catalysts tested were less robust during reactions, probably due to imbalance in their acidic to metallic functions, or diffusion limitations arising from their pore structures. The best catalysts were, nonetheless, highly sensitive to sulfur presence in the feed, which severely impacted their activity, especially their metallic functions, and thus require sulfur-free feeds in order to demonstrate their full capacities. Simple kinetic modelling of experimental data was performed using the initial rates method and estimation of kinetic parameters, whose values were in good agreement with previous literature.

622

Chemo-enzymatic synthesis of NAADP analogs for isolation and purification of theNAADP receptors

Su, Peiling

06 September 2019

No description available.

Chemistry

NAADP

NAADP receptor

bifunctional NAADP analogs

biotinylated NAADP probes

Development of Pharmacologically Distinct Opioid Analgesics

Patel, Shivani

29 September 2022

Opioid analgesics have been a major contribution to pain therapy with opioids being used as an effective treatment for various recalcitrant pain conditions. The drug class has come under increased scrutiny due to the raising concerns about the public health crisis of opioid misuse and addiction, thereby increasing the need for alternative and safer analgesics. The exploration of alternative pharmacotherapy for pain management has led to an increasing paradigm shift towards the development of a single-drug-multiple-target approach that takes inspiration from numerous naturally occurring drugs. The mu-opioid receptor has been the primary target for the management of pain; however, the voltage-gated sodium channel Nav1.7 is gaining attention as a putative antinociceptive target based on human genetic evidence. The proposed research aims to develop multi-target directed ligands (MTDL) that modulates two key targets for pain perception, the MOR, and Nav1.7 to generate analgesics with reduced side effects and enhanced analgesia. This will be achieved by exploiting polypharmacology to develop hybrid analgesia in two ways: (i) performing structure-activity relationship (SAR) studies to design a single drug with two pharmacophores that specifically interacts with both the targets (ii) exploiting in silico techniques by performing structure-based virtual ligand screening (VLS) of a chemical library. In our work, we report that through SAR studies and molecular docking studies that the designed compounds having in combination the pharmacophore of PZM21 and aryl sulfonamide demonstrate significant interactions between the active compounds and both the MOR and Nav1.7 proteins. This study also reports the first ever bifunctional virtual ligand screening where a library consisting of over a million compounds was screened for bifunctional activity at the MOR and the Nav1.7 ion channel. We also report the development of a novel mechanism-specific membrane potential assay to that can be used to screen for subtype selective Nav1.7 inhibitors. The research performed in this thesis will serve as a platform to explore the possibility of MTDL as potential therapeutic solutions to diseases of complex etiologies such as chronic pain. It will also serve as a starting point to exploring bifunctional VLS as a way to screen large chemical libraries for MTDLs.

Opioids

Mu Opioid Receptor

Nav1.7

Voltage Gated Sodium Ion Channel

Multi target directed ligands

Bifunctional compounds

PZM21

Aryl Sulfonamide

Structure Activity Relationship Studies

Bifunctional Virtual Ligand Screening

Immobilisation and application of bifunctional iminophosphorane organocatalysts

Goldys, Anna M.

January 2014

Bifunctional iminophosphoranes, containing a triaryl-substituted iminophosphorane and bis(3,5- trifluoromethyl)phenyl thiourea on a single enantiomer scaffold are novel asymmetric superbase organocatalysts reported by the Dixon group in 2014. This thesis describes our efforts to expand their scope and utility in a variety of challenging chemical transformations. Chapter 2 describes the development and application of immobilised bifunctional iminophosphorane organocatalysts. We have successfully immobilised bifunctional iminophosphoranes on a crosslinked polystyrene support and applied this sold-supported catalyst to three challenging asymmetric reactions; namely the nitro-Mannich reaction of phosphinoyl ketimines and the conjugate addition of alkylmalonates and N,N-dimethyl β-keto amides to nitrostyrene. Very good yields, enantio- and diasteroselectivities were obtained in all cases. We have also demonstrated their use in a range of conjugate additions of cyclic 1,3-dicarbonyl compounds to nitroalkenes, which suffered from very slow reaction rates under tertiary amine-based bifunctional catalysis. In all cases, the immobilised bifunctional iminophosphoranes performed very well in comparison to their homogeneous counterparts. We have also demonstrated catalyst recycling over 10 cycles and application in a continuous flow system with a productivity of 7.20 mmol _producth^-1g_catalyst^-1. to the ring-opening polymerisation (ROP) of cyclic esters. We have demonstrated the performance of bifunctional iminophosphorane organocatalysts in the ROP of L-lactide (LA), δ-valerolactone (VL) and ε-caprolactone (CL). The polymerisation of LA and VL proceeded rapidly and was well controlled, while only short lengths (> 100 DP) of poly(CL) could be prepared in a controlled fashion due to hypothesised competing initiation from the catalyst. We have shown that the polymerisation of LA using our catalyst may be considered a living polymerisation. Di-block co-polymers could also be successfully prepared via sequential monomer addition or through the use of macroinitiators. We then investigated the roles of the iminophosphorane and the thiourea component of the catalyst.

547