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A Practical Approach to Semicarbazone and Hydrazone Derivatives via Imino-isocyanatesGarland, Keira 04 April 2014 (has links)
Isocyanates have a broad spectrum of uses and they are used in the production of many products including polyurethane polymers, coatings, adhesives, paints and foams. While isocyanates are widely studied and well represented in the literature, nitrogen substituted isocyanates are quite rare. Amino and imino-isocyanates are examples of nitrogen substituted isocyanates. Previous work within the group studied the reactivity of these intermediates in the alkene aminocarbonylation reaction, and used hydrazones and hydrazides as precursors of nitrogen substituted isocyanates. From there, a second reaction pathway was studied. This involved the reactivity of hydrazones with nucleophiles to develop a simple exchange reaction. In this work, the substitution reactivity involving imino-isocyanates will be presented. This will include the scope of nucleophiles and hydrazones as well as a discussion on the formation of the imino-isocyanates. This reactivity allows for the facile formation of a variety of hydrazones with the flexibility to start from common hydrazone precursors.
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A Practical Approach to Semicarbazone and Hydrazone Derivatives via Imino-isocyanatesGarland, Keira January 2014 (has links)
Isocyanates have a broad spectrum of uses and they are used in the production of many products including polyurethane polymers, coatings, adhesives, paints and foams. While isocyanates are widely studied and well represented in the literature, nitrogen substituted isocyanates are quite rare. Amino and imino-isocyanates are examples of nitrogen substituted isocyanates. Previous work within the group studied the reactivity of these intermediates in the alkene aminocarbonylation reaction, and used hydrazones and hydrazides as precursors of nitrogen substituted isocyanates. From there, a second reaction pathway was studied. This involved the reactivity of hydrazones with nucleophiles to develop a simple exchange reaction. In this work, the substitution reactivity involving imino-isocyanates will be presented. This will include the scope of nucleophiles and hydrazones as well as a discussion on the formation of the imino-isocyanates. This reactivity allows for the facile formation of a variety of hydrazones with the flexibility to start from common hydrazone precursors.
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Synthesis of Beta-Aminocarbonyl Compounds and Hydrazine Derivatives Using Amino- and Imino-IsocyanatesClavette, Christian January 2015 (has links)
Over the past recent years, β-aminocarbonyls have been of great interest to medicinal chemists. As a practical method to obtain these moieties, alkene aminocarbonylation, accounting for the formation of a C-N and a C-C bond, has been the subject of limited research efforts (very specific intramolecular metal-catalyzed variants have been reported). Direct aminocarbonylation of alkenes constitutes a challenging and an important potential innovation in the synthesis of β-aminocarbonyls such as β-amino acids. The research efforts described in the present thesis have been primarily directed towards the development of concerted pathways for the amination of alkenes using hydrazine derivatives as bifunctional reagents. Building on our previous report on the reactivity of hydrazides, progress on the aminocarbonylation of alkenes along with the synthetic scope of this reactivity are herein provided. Therefore, the first part of the present thesis (Chapter 2) focuses primarily on the development of thermolytic conditions for the intramolecular aminocarbonylation of alkenes using amino-isocyanates. Alongside, development of imino-isocyanates have provided complementary synthetic tools for aminocarbonylation. The second part (Chapter 3) describes the work accomplished towards intermolecular aminocarbonylation of alkenes and the synthesis of complex azomethine imine products (Chapter 3). Finally, the last part of the discussion (Chapter 4) will be on the development of new hydrazide reagents for the intramolecular Cope-type hydroamination of alkenes. In doing so, description of the synthetic utility of amino-isocyanates as amphoteric reagents for cascade reactions and heterocyclic synthesis will be provided.
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Intermolecular [3+2] Cycloadditions of Imino-isocyanates to Access β-Amino Carbonyl CompoundsBongers, Amanda L. January 2017 (has links)
In modern synthetic organic chemistry, chemists are driven to develop efficient methods for important C-C and C-N bond formation reactions. The challenge lies with establishing new uses for readily available substrates. In this regard, the synthesis of β-aminocarbonyl compounds from alkenes remains a long-standing challenge. Innovation in reaction discovery often requires finding new reagents, or rare reagents with underappreciated value in synthesis. In Chapter 1, N-isocyanates and other heterocumulenes are introduced as versatile amphoteric reagents. Their amphoteric properties are valuable in the discovery of new synthetic approaches, especially in cycloaddition reactions. While C-isocyanates are bulk industrial chemicals, the formation and reactivity of N-isocyanates remains underexplored.
Chapter 2 describes the development of reactivity with rare imino-isocyanates. This includes methods to access the reagent in situ with a blocking group approach, and the establishment of intermolecular cycloaddition reactivity with a variety of alkenes. This stereospecific reaction provides complex N,N’-cyclic azomethine imines, and enables access to β-aminocarbonyl compounds from alkenes. β-Amino amides and esters, pyrazolidinones, and pyrazolones were accessed by reductive derivatization of the aminocarbonylation products. Exploration into the limits of this reactivity gave insight into fundamental properties of imino-isocyanates. This includes the first detection of imino-isocyanates by IR spectroscopy.
A kinetic resolution of the azomethine imines obtained from this alkene aminocarbonylation reaction was then developed, which gave access to enantioenriched β-amino carbonyl compounds (Chapter 3). This was accomplished by Brønsted acid catalysed reduction, with a selectivity factor of 13-43. This was the first example of the enantioselective reduction of azomethine imines, and represents a new activation mode for reactions of N,N’-cyclic azomethine imines. Using this reductive method, both enantiomers of the β-amino amide could be obtained from a racemic azomethine imine in ≥ 97% ee.
The discovery of new reactivity of imino-isocyanates with imines in described in Chapter 4, which allowed the synthesis of eight new azomethine imines with the triazolone core. Our initial scope studies revealed different trends with imines than with alkenes, including increased reactivity, which led to investigation of the mechanism of this reaction. In addition, this was shown to be a valuable new approach for the synthesis of triazolones from imines.
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