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THE STEREOCHEMISTRY OF SUBSTITUTED CYCLOPROPYL RADICALSUnknown Date (has links)
Source: Dissertation Abstracts International, Volume: 36-02, Section: B, page: 0716. / Thesis (Ph.D.)--The Florida State University, 1975.
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DECARBONYLATION OF RACEMIC ALDEHYDES WITH OPTICALLY ACTIVE RHODIUM COMPLEXESUnknown Date (has links)
Source: Dissertation Abstracts International, Volume: 37-07, Section: B, page: 3410. / Thesis (Ph.D.)--The Florida State University, 1976.
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TRANSFORMATIONS OF LABDANE SKELETON, OXIDATIONS OF ALLYLIC ALCOHOLS AND CRYSTAL AND MOLECULAR STRUCTURE OF PARTHEMOLLINUnknown Date (has links)
Source: Dissertation Abstracts International, Volume: 38-04, Section: B, page: 1724. / Thesis (Ph.D.)--The Florida State University, 1976.
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TRANSFORMATIONS OF PHOTOLEVOPIMARIC ACIDUnknown Date (has links)
Source: Dissertation Abstracts International, Volume: 35-12, Section: B, page: 5824. / Thesis (Ph.D.)--The Florida State University, 1974.
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Applications of Alkynogenic Fragmentation Products Derived from Vinylogous Acyl TriflatesUnknown Date (has links)
Carbon-carbon bond formation is the foundation to synthesizing complex molecules and has gathered the attention of many synthetic
chemists. One must keep in mind that these reactions are dependent on materials for a specific agenda when tackling a structural framework,
which may require additional steps to create, and at times, are difficult to prepare. As significant as C-C bond formation reactions are,
these minor setbacks may draw caution when synthesizing a complicated molecule whose structural framework cannot be easily accessed by the
unity of two fragments. On the other hand, the less familiar C-C bond cleavage reactions have, over time, demonstrated the potential to
generate unique structural building blocks that can be used to overcome certain obstacles that other synthetic methods cannot provide. Here,
we will be focusing on concerted anionic five-center fragmentation reactions using vinylogous acyl triflates. The generated alkynogenic
fragments will then be used in different applications. We will begin by looking at chemoselective “click” reactions. The strained-promoted
alkyne is synthesized by a tandem intramolecular nucleophilic addition / fragmentation. The expanded ring will contain a strained cycloalkyne
which will later be tethered to a terminal alkyne. The diyne will be used to provide an example of a “dual-click” coupling via SPAAC or CuAAC
in either sequential order. Next, we will expand the tandem fragmentation / olefination methodology developed in this work to include
dienynes. The dienyne provides the structural backbone needed to produce neopentylene indanes. This methodology is used to design new
ibuprofen derivatives that demonstrate rigidity and increase hydrophobicity to modulate the molecular pharmacology of ibuprofen. / A Dissertation submitted to the Department of Chemistry and Biochemistry in partial fulfillment of the
requirements for the degree of Doctor of Philosophy. / Fall Semester 2017. / August 24, 2017. / Includes bibliographical references. / Piotr Fajer, University Representative; Jack Saltiel, Committee Member; Lei Zhu, Committee
Member.
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Part 1. Diaziridinium Ions: First Reported Synthesis and Reactivity Studies. Part 2. Tropylium Ion Mediated alpha-Cyanation of Amines. Part 3. Multicatalytic Synthesis of Complex TetrahydrofuransAllen, Julia Margaret January 2011 (has links)
The first synthesis and full characterization of a new functionality, called the diaziridinium ion, is reported. The original synthetic intent behind its design was to explore its potential use as a non-metal based N-transfer reagent. During this study, we have uncovered a practical rearrangement to access 2,3-benzodiazepines reliably and efficiently. Efforts to achieve N-transfer from these species are described and are ongoing. We have identified the tropylium ion as a highly efficient organic-based amine oxidant and have demonstrated its practical use in a one-pot protocol for alpha-aminonitrile synthesis. We also report an application of this new oxidant towards an aza-Cope rearrangement. Finally, we report a multicatalytic method that uses bismuth(III) triflate to catalyze a nucleophilic addition to an aldehyde followed by hydroalkoxylation to generate highly functionalized tetrahydrofuran rings, a motif that is often encountered in natural product architectures.
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Part 1: Progress Toward the Total Synthesis of Platensimycin. Part 2: Aromatic Ions: Carbon-Based Nucleofuges and Chiral Cyclopropenones and FormamidesFisher, Ethan Lawrence January 2011 (has links)
This thesis describes progress toward to the total synthesis of the natural product platensimycin, the development of proficient carbon nucleofuges for the Tsuji-Trost allylation, and the use of chiral cyclopropenones and formamides for the kinetic resolution of alcohols by chlorodehydration. The first chapter describes efforts in the total synthesis of platensimycin. The synthesis attempted to use a thermal rearrangement, through a biradical intermediate, and then radical induced [3+2] cycloaddition between a vinyl cyclopropane and pendant olefin to create the core of platensimycin. A revised strategy was employed using a palladium(0) catalyzed Heck cascade and palladium(II) catalyzed alkoxypalladation. The second chapter describes the development of a carbon-based nucleofuge. A substituted cyclopentadienyl anion served as a competent leaving group in the Tsuji-Trost allylation. Various substrates were examined including carbon and nitrogen nucleophiles. The reaction mechanism with nitrogen nucleophiles is studied. The third chapter describes the synthesis of chiral cyclopropenones and their use in the kinetic resolution of alcohols by chlorodehydration. Chiral formamides are also studied for their use in chlorodehydration. Transition states for enantiodifferentiation are proposed.
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Part 1: Lanthanum(III) Triflate-Catalyzed Cyclopropanation via Intramolecular Methylene Transfer. Part 2: Reaction Design with Aromatic Ions - Nucleophilic Acyl Substitution and Organophotoredox CatalystsHardee, David James January 2011 (has links)
This thesis describes the development of novel synthetic methods in the areas of methylene transfer cyclopropanation and reaction design with aromatic cations. The first chapter presents a new cyclopropanation method involving intramolecular methylene transfer from an epoxide to an olefin. The lanthanum(III) triflate-catalyzed process proceeds with high stereoselectivity and a range of examples are presented to illustrate the reaction scope. An asymmetric cyclopropane synthesis combining enantioselective epoxidation and the methylene transfer protocol is also presented. The second chapter describes the application of aromatic cation activation for nucleophilic acyl substitution. The strategy is used to rapidly convert carboxylic acids to their corresponding acid chlorides with dichlorocyclopropene reagents. The effect of cyclopropene substituents and amine base additives on the rate of conversion is examined. A mild amidation protocol employing acid chloride formation is described and applied to acid-sensitive substrates and preparative peptide couplings. The final chapter discloses the development of aromatic cation photoredox catalysts. Investigations into the relationship between cyclopropenium substitution and ultraviolet/visible light absorption are presented. Cyclopropenium ions are shown to be effective photocatalysts for a variety of photoredox transformation.
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Total Synthesis of Maoecrystal VPeng, Feng January 2012 (has links)
This thesis describes in detail our journey toward Maoecrystal V, a potential anti-cancer diterpenoid. Maoecrsytal V was isolated in 2004 from a Chinese herbal medicine. It has a highly congested structure, in which there are three continuous quaternary carbon center embedded within a rigid pentacyclic scaffold. The first chapter of this thesis covers the isolation, bioactivity, and synthetic efforts from other groups. The second chapter discusses our first generation strategy toward Maoecrystal V. During our early studies, we successfully found the conditions for the key intramolecular Diels-Alder reaction. We also identified that the facial selectivity of this Diels-Alder reaction is a big challenge for our synthesis plan. The third chapter describes our solution to the core structure of Maoecrystal V. The exploration resulted in the discovery of a novel exo-glycal epoxide rearrangement. The last chapter describes the total synthesis of Maoecrystal V. The difficulties we met and our solution is discussed.
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Strategies and Tactics for the Synthesis of Polycyclic AlkaloidsElsohly, Adel Mahmoud January 2012 (has links)
The myrmicarin family of oligomeric natural products comprises one of the most ornate collections of polycyclic alkaloids known. The structural characterization of their unique scaffolds was accomplished through elegant spectroscopic studies. Furthermore, the synthesis of these alkaloids has attracted the attention of the synthetic community, with several syntheses of the monomeric myrmicarins completed. Significant effort has been put forth toward the synthesis of the higher order structures, though no successful approach has been reported to date. These isolation and characterization studies as well as synthetic approaches toward the family are reviewed. Chapter 2. The Evolution of Efficient, Enantioselective Total Syntheses of Monomeric Myrmicarin Alkaloids. In order to provide a family-level solution to the myrmicarin alkaloids, we adopted a strategy-level approach to their synthesis. Utilizing concepts from retrosynthetic analysis and diversity oriented synthesis, an enantioselective and highly streamlined synthesis of the monomeric myrmicarin alkaloids as well as potential dimerization precursors was established from a common intermediate with late stage diversification. Chapter 3. Dimerization Studies toward the Synthesis of Myrmicarin 430A. An alternative strategy for the synthesis of myrmicarin 430A is presented using a dienamine precursor. This approach allows for the stereoselective synthesis of the all trans stereotriad of the central cyclopentane moiety of myrmicarin 430A. Mechanistic aspects concerning the final bond closure are presented in light of quantum chemical calculations. Chapter 4. An Introduction to the Securinega Alkaloids and NHC Catalysis The Securinega alkaloids comprise a large family of tetracyclic alkaloids, many of which contain a conjugated butenolide moiety. While many distinct synthetic approaches have appeared for the synthesis of members of this family, only a relatively small number of approaches are applied to the synthesis of the butenolide portion of these natural products. The various synthetic endeavors to accessing this structural motif are presented. NHC catalysis is a growing field of research for its ability to promote unusual chemical transformations. As this field of research is of relevance to our latter studies, a brief overview of modern NHC catalysis is presented. Chapter 5. Development of an NHC-Catalyzed Cascade Reaction to Access the Core Architecture of the Securinega Alkaloids. In targeting the family of <italic>Securinega</italic> alkaloids, a retrosynthesis was devised that proposes a novel intramolecular cyclization approach of an ynal and ketone to deliver the bridging butenolide moiety of these natural products. The development of this reaction and its application toward the synthesis of various <italic>Securinega</italic> alkaloids is presented.
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