Global ETD Search

261	Rearrangements of Radical Anions Generated from Cyclopropyl Ketones Phillips, Janice Paige 11 November 1998 (has links) Cyclopropyl-containing substrates have been frequently utilized as "probes" for the detection of SET pathways in organic and biorganic systems. These reactions are based on the cyclorpropylcarbinyl → homoallyl rearrangement, which is fast and essentially irreversible. The implicit assumption in such studies is that if a "radical" species is produced, it will undergo ring opening. We have found that there are two important factors to consider in the design of SET probes: 1) ring strain, the thermodynamic driving force for the rearrangement, and 2) resonance energy, which may help or hinder rearrangement, depending on the specific system. Delocalization of spin and charge were found to be important factors pertaining to substituent effects on the rates of radical anion rearrangements. Previous studies from our lab have centered on highly conjugated phenyl cyclopropyl ketones. This work considers a series of compounds varying in their conjugative components from a highly conjugated spiro[2.5]octa-4,7-dien-6-one and derivatives to simple aliphatic ketones. Utilizing cyclic, linear sweep voltammetry, and preparative electrolysis techniques, it was discovered that all substrates yielded ring opened products with rates and selectivities that will prove useful and informative in the design of mechanistic probes based on the cyclorpropylcarbinyl → homoallyl rearrangement. Rates of homogeneous electron transfer from a series of hydrocarbon mediators to substrates were measured using homogeneous catalysis techniques. Standard reduction potentials and reorganization energies of substrates were derived using Marcus theory. Conjugative interactions with the cyclopropyl group are discussed. / Ph. D. Marcus theory Homogeneous catalysis Reaction mechanism and kinetics Cyclopropyl ketones Voltammetry Cathodic reduction Ring opening Radical anion
262	Ignition Studies of Diisopropyl Ketone, A Second-Generation Biofuel Pryor, Owen 01 January 2014 (has links) This thesis focuses on ignition of diisopropyl ketone (DIPK), a new biofuel candidate that is produced by endophytic conversion. The ignition delay times behind reflected shockwaves were modeled in a high-pressure shock tube. The ignition delay times were compared to other biofuels and gasoline surrogates. Parametric studies of the ignition delay experiments were performed between 1-10 atm and 900 -1200K. An OH optical sensor was developed in conjunction for the ignition delay experiments. The OH optical sensor uses a microwave discharge lamp to generate light at 308 nm that will then be shined through the combustion reaction. Using Beer-Lambert law the concentration of OH can be obtained during ignition and oxidation of hydrocarbon fuels in a shock tube. DIPK ignition delay time experiments are planned in two shock tubes (located at UCF and UF) to provide ignition and OH time-histories data for model validation. Aerospace Engineering
263	Influence of Nutritional Ketosis Achieved through Various Methods on Plasma Concentrations of Brain Derived Neurotropic Factor Kackley, Madison Lee January 2021 (has links) No description available. Kinesiology Nutrition Physiology Ketogenic diet brain derived neurotropic factor exogenous ketones
264	The Effects of Ketones on Brain Metabolism and Cognition Saito, Erin Reiko 10 July 2023 (has links) (PDF) The brain is one of the most energetically demanding organs within the human body and is cognitively susceptible to energetic deficits such that the rise in obesity, insulin resistance, and Alzheimer’s disease in recent decades pose a substantial threat to cognitive longevity. The therapeutic efficacy of ketones are well-established in epilepsy and are currently being applied to other disease states. Alzheimer’s disease is characterized by impairments in brain glucose uptake and metabolism in regions relevant to learning, memory, and cognition that progress with the disease. While brain glucose uptake is impaired, ketone uptake is unaltered, potentially enabling ketones to fuel the glucose-deficient brain. Using RNA-seq data acquired from multiple publicly available AD databases, we assessed glycolytic and ketolytic gene expression in post-mortem AD and cognitively normal control brains. Gene expression was normalized to brain region – parietal lobe, cerebellum, temporal cortex, frontal lobe, inferior frontal gyrus, parahippocampal gyrus, superior temporal gyrus – and cell type – neurons, astrocytes, oligodendrocytes, and microglia. We report impairments in glycolytic gene expression in regions of the brain relevant to memory and cognition in neurons and oligodendrocytes, but not ketolytic gene expression in neurons. The data are consistent with previous work and support clinical ketone intervention. The cognitive effects of ketogenic diets remain controversial, especially in healthy adults. To elucidate the effects of a ketogenic diet in healthy mice, C57BL6 mice were placed on a ketone-supplemented ketogenic diet for eight weeks. Recognition memory was assessed in a novel object recognition test and hippocampal bioenergetics were measured using high-resolution respirometry, western blot, and biochemical assays. The diet significantly improved recognition memory and enhanced hippocampal mitochondrial efficiency, measured by ATP production per unit of oxygen consumed, suggesting cognitive validity of the diet in middle-age. Long-term potentiation (LTP), the activity-dependent strengthening of synapses, within the hippocampus, is one of the molecular mechanisms of learning and memory formation. LTP of hippocampal Schaffer-collaterals was quantified in young adult C57BL/6 mice with field electrophysiology following ex vivo brain slice incubation with a β-hydroxybutyrate-rich ACSF. Mice were then placed on the ketone-supplemented diet for four weeks. Behavioral spatial memory was measured in the Morris water maze and Schaffer-collateral LTP was assessed with field electrophysiology. No meaningful changes in LTP and behavioral memory were observed with ketone treatment, suggesting ketogenic interventions may be more applicable in aging and pathologies that display cognitive deficits, rather than in healthy young adults. Together, these studies support the exploration of ketogenic interventions as a potential restorative measure in Alzheimer’s disease and preventative measure in aging, which may be impactful facing the rise of obesity and insulin resistance. ketones metabolism Alzheimer's disease hippocampus glycolysis ketolysis mitochondrial efficiency memory cognition long-term potentiation Life Sciences
265	Trialkyl Phosphine Derived Reagents for The Carbon Homologation of Aldehydes and Their Application to Meroterpene Synthesis Hurem, David January 2023 (has links) Chapter One presents an overview of phosphorus reagents for the carbon homologations of aldehydes and ketones leading to functionalized carbonyl derivatives. Select examples are provided to exemplify the utility of carbon homologation methodology in synthesis and asymmetric organocatalysis and in the total synthesis of natural products. The directing effect of acetals on regioselective ylide formation is explored in Chapter Two. Evidence is presented for ylide formation through a complex induced proximity effect with lithium bases under coordinating conditions. Moreover, four-carbon donors represent a limit for useful directed ylide formation with trialkylphosphine-derived Wittig salts in carbonyl homologation reactions. A facile approach to the synthesis of methyl vinyl ketones (MVKs), using acetonyl tripropylphosphoranes under mild conditions, is reported in Chapter Three. A library of diversely functionalized MVKs was synthesized as a demonstration of the scope and generality of the methodology. The application of MVKs as substrates for organocatalysis and as building blocks for useful polyketide intermediates is briefly highlighted. In Chapter Four, the two-carbon homologation methodology that was presented in the previous chapter is applied to the synthesis of the polyketide olivetol and a series of O-methyl derivatives. Cyclic diketone intermediates were aromatized with catalytic iodine and DMSO as a terminal oxidant. Modification of the solvent system allowed for the selective synthesis of mono- or dimethyl ethers of methyl olivetolate. The selectivity of this aromatization is further explored in the final chapter with more complex substrates. Chapter Five focuses on the synthesis of the meroterpene phytocannabinoids found in Cannabis sativa. A synthetic strategy involving the sequential condensation/[3+3]-annulation of citral with cyclic 1,3-diketones synthesized in the previous chapter. This afforded non-aromatic meroterpenes that were subjected to acid-mediated thermal rearrangement and catalytic oxidative aromatization. Evidence for chemoselectivity of the aromatization methodology was demonstrated and a synthesis of methyl cannabinolate is presented. / Thesis / Doctor of Philosophy (PhD) / Methodologies for the extension of aldehydes to functionalized olefins and their application to the synthesis of cannabinolic acid methyl ester are presented. homologation Wittig reaction methyl vinyl ketones natural product synthesis meroterpenoids cannabinoids
266	Solid-state NMR Studies of Ion Dynamics in Proton-Conducting Polymers and Composites Ye, Gang 08 1900 (has links) High resolution solid state 1H NMR is used to investigate proton mobility of Nafion, Sulfonated Polyether Ether Ketones(S-PEEK) and their composites, which provides better understanding of their proton conductivities. Proton exchange between sulfonic acid groups and water was observed in these materials. The proton mobility is dependent on both the temperature and the water content. Variable temperature experiments were used to determine the activation energy for proton transportation which generally increases with decrease in hydration level. The preparation of Nafion/SiO2 composites can cause large difference in proton diffusion coefficients and proton conductivities in dried states. This indicates that the amount of dopants needs to be optimized to minimize the blocking of proton diffusion pathways by dopant particles. Detailed information on the control of surface hydroxyl groups in Nafion/SiO2 is obtained through the combination of 29Si and 1H NMR. Although hydrated Nafion/ZrP composites show reduced proton activation energy, they present lower proton conductivity at 35°C than unmodified Nafion. For composites dried at 160°C, both the conversion of monohydrogen phosphate into pyrophosphate and the protonation of monohydrogen phosphate have been observed, which could be one of reasons for the decreased proton conductivity after rehydration. Under high humidification, a single or multiple sulfonic acid proton environments was observed in S-PEEKs, which explains the small proton conductivity difference between some of S-PEEKs. However, the observed conductivity difference for S-PEEKs cast from different solvents was attributed to distinct mobilities of polymer chains. In the crosslinked S-PEEK, not all the crosslinkers of ethylene glycol are fully crosslinked. Proton exchange between residual sulfonic acid and hydroxyls of the crosslinker was observed, which is the primary reason that the crosslinked S-PEEK, with very low residual degree of sulfonation (13 %), still shows proton conductivity comparable to those of S-PEEKs. / Thesis / Doctor of Philosophy (PhD) proton exchange proton mobility Nafion Sulfonated Polyether Ether Ketones proton conductivity NMR
267	The Synthesis and Structural Characterization of Main Group and Lanthanide Metal Compounds Supported by the Multidentate [N₃C] Donor Ligand tris[(1-isopropylbenzimidazol-2-yl)dimethylsilyl]methyl, [TismPriBenz]M Vaccaro, David Alexander January 2023 (has links) The Parkin group has recently synthesized tris[(1-isopropylbenzimidazol-2-yl)dimethylsilyl]methane, [TismPriBenz]H, a bulky tetradentate tripodal ligand, which upon deprotonation can coordinated to form a variety of carbatrane metal complexes.The [TismPriBenz] ligand has been previously shown to stabilize metal hydride complexes, for example [TismPriBenz]MgH and [TismPriBenz]ZnH, and the ligand also has been incorporated in complexes featuring all of the non-radioactive Group 12 and Group 13 metals, as well as a large range of transition metals. However, the reactivity of these complexes towards carbonyl compounds is largely unexplored. Additionally, beyond [TismPriBenz]Li, there has been no attempt to introduce the heavier alkali metals into the [TismPriBenz] framework, which could potentially provide more reactive starting materials to generate other previously inaccessible metal complexes of the ligand; for instance, prior to this report, there has been no example of a lanthanide complex of [TismPriBenz]. In Chapter 1, the reactivity of [TismPriBenz]MgH and [TismPriBenz]MgMe towards ketones, aldehydes, and esters is explored. Generally, these magnesium complexes are able to insert a C=O double bond into a Mg–Me or Mg–H bond respectively, providing access to a large class of magnesium alkoxides. Specifically, [TismPriBenz]MgR (R = H, Me) can insert benzaldehyde and benzophenone to give [TismPriBenz]MgOCRHPh or[TismPriBenz]MgOCRPh₂ respectively. Additionally, [TismPriBenz]MgMe has shown rare reactivity towards methyl ketones, in that it forms the magnesium enolate compounds [TismPriBenz]MgC(Me)=CH₂ and [TismPriBenz]MgC(Ph)=CH2 upon treatment with acetone or acetophenone. In fact, [TismPriBenz]MgC(Me)=CH₂ is only the fourth acetone enolate complex to be structurally characterized, and the first such magnesium example. In the presence of the ester compounds methyl formate and ethyl acetate, [TismPriBenz]MgH and [TismPriBenz]MgMe are able to follow the insertion of the carbonyl with immediate elimination of either an aldehyde or ketone to yield the simple alkoxides [TismPriBenz]MgOMe and [TismPriBenz]MgOEt, a reaction with little precedence in the literature. [TismPriBenz]MgMe is also able to prompt the Claisen condensation of ethyl acetate, forming the first [TismPriBenz] complex with a 6-member chelating ring, [TismPriBenz]Mg(κ²-OC(Me)HC(O)OEt). These various alkoxides have demonstrated the ability to catalyze the Tishchenko reaction, the dimerization of an aldehyde to make an ester, and have also shown promise as catalysts for hydroboration and retro-aldol reactions. Lastly, the [TismPriBenz]Mg compounds have shown interesting reactivity towards O₂, leading to the isolation of both the rare peroxide dimer {[TismPriBenz]Mg}₂(μ-O₂) and the alkyl peroxide [TismPriBenz]MgOOMe. In Chapter 2, the reactivity of the complex [TismPriBenz]Tl is further developed, providing access to previously known methyl and iodide compounds of magnesium, zinc, and cadmium. Additionally, [TismPriBenz]Tl has been shown to react directly with the alkali metals sodium, potassium, and rubidium to form the novel alkali metal complexes [TismPriBenz]M (M = Na, K, Rb). Furthermore, [TismPriBenz]Li can react with CsF to afford [TismPriBenz]Cs, completing the non-radioactive Group 1 [TismPriBenz]M series. This makes [TismPriBenz] one of only a handful of organic ligands to have structurally characterized compounds with all of the alkali metals from Li to Cs, and the only ligand that formsmonomeric complexes in each case. [TismPriBenz]K was also used as a starting material to synthesize the first [TismPriBenz] lanthanide complexes, [TismPriBenz]YbI and [TismPriBenz]YbCl₂. [TismPriBenz]YbI itself can further react with KN(SiMe₃)₂ and NaCp to give [TismPriBenz]YbN(SiMe₃)₂ and [TismPriBenz]YbCp respectively. Lastly, the ability of the [TismPriBenz]Zn halide series to form ion pair complexes was investigated. [TismPriBenz]ZnI can react with ZnI₂ to afford {[TismPriBenz]Zn}₂[Zn₃I₈], which contains the novel zinc halide species [Zn₃I₈]²⁻. Additionally, all of the [TismPriBenz]ZnX (X = Cl, Br, I) complexes are able to react with excess ZnX₂ in THF to give the series {[TismPriBenz]Zn}[Zn(THF)X₃]. Chemistry Rare earth metals Ketones Aldehydes Esters Alkoxides Carbonyl compounds Claisen condensation
268	MULTICOMPONENT REACTIONS OF SALICYLALDEHYDE, CYCLIC KETONES, AND ARYLAMINES THROUGH COOPERATIVE ENAMINE-METAL LEWIS ACID CATALYSIS Sarkisian, Ryan Gregory 29 August 2014 (has links) No description available. Chemistry
269	Release of Alcohols Through Photoenolization Konosonoks, Armands January 2005 (has links) No description available. Chemistry, Organic
270	A study of the electronic effects of various substituents on the course of an aromatic cyclodehydration reaction vs. a Elbs-type reaction Thornton, James Robert 23 December 2009 (has links) The acld-oata17zed oyclodehydrat1on reaction of 2-benzylphenyl l-naphthyl ketone gives two products! 9-(1-naphthyl)anthracene, the expected product and in addition lO-phenyl-l,2-benzanthracene. This second product is the one expected it the ketone were subjected to the conditions of an .Elba reaction. The effect of substituents on the course of this reaction was investigated by synthesizing six 2-benzylphenyl 1- and 2-naphthyl ketones and subjecting each of them to the acid catalyzed reaction and to Elba reaction conditions. Of the six ketones, two had unsubstituted benzyl groups, two had 3'-methyl groups in the benzyl group and the remaining two had ,'-tr1fluoromethyl groups. The original finding was confirmed and the other ketones that cyoilzed by either treatment gave the expected products. When 2-(3'-methylbenzyl) 2-naphthl1 ketone was subjected to Elbs reaction conditions, 9-(2-naphthyl)anthraoene, the product of aromatic oyclodehydrat1on, was obtained. An explanation oft the unusual experimental results is suggested. The results of treat1ng the ketones w1th alumina and w1th l1qu1d hydrogen fluoride are reported. / Ph. D. LD5655.V856 1963.T467 Ketones -- Reactivity -- Experiments

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