Intramolecular Cope-type Hydroamination of Alkenes and Alkynes Using Hydrazides

Hunt, Ashley D.

18 April 2011

Nitrogen-containing molecules are ubiquitous in both natural products and pharmaceutical drugs, thus an efficient method for the formation of these motifs is of great importance. Hydroamination, that is the addition of an N-H bond across an unsaturated carbon-carbon bond of an alkene or alkyne, stands out as a potential approach to obtain such molecules. To date, most research in this area relies on transition-metal catalysis to enable such reactivity. In efforts directed towards metal-free alternatives, we have developed a simple, metal-free hydroamination of alkenes using hydrazides. Further investigation into the corresponding reactivity of alkynes with hydrazides has provided access to novel azomethine imine products. In Chapter 2, expansion of the substrate scope with respect to the intramolecular hydroamination of alkenes using hydrazides, as well as studies directed towards elucidation of the mechanism of this reaction will be presented. The intramolecular hydroamination of alkynes using hydrazides and methods to access and isolate the azomethine imine products formed will be discussed in Chapter 3.

hydroamination

hydrazide

azomethine imine

alkene

alkyne

dipole

heterocycles

Intramolecular Cope-type Hydroamination of Alkenes and Alkynes Using Hydrazides

Hunt, Ashley D.

18 April 2011

Nitrogen-containing molecules are ubiquitous in both natural products and pharmaceutical drugs, thus an efficient method for the formation of these motifs is of great importance. Hydroamination, that is the addition of an N-H bond across an unsaturated carbon-carbon bond of an alkene or alkyne, stands out as a potential approach to obtain such molecules. To date, most research in this area relies on transition-metal catalysis to enable such reactivity. In efforts directed towards metal-free alternatives, we have developed a simple, metal-free hydroamination of alkenes using hydrazides. Further investigation into the corresponding reactivity of alkynes with hydrazides has provided access to novel azomethine imine products. In Chapter 2, expansion of the substrate scope with respect to the intramolecular hydroamination of alkenes using hydrazides, as well as studies directed towards elucidation of the mechanism of this reaction will be presented. The intramolecular hydroamination of alkynes using hydrazides and methods to access and isolate the azomethine imine products formed will be discussed in Chapter 3.

hydroamination

hydrazide

azomethine imine

alkene

alkyne

dipole

heterocycles

Intramolecular Cope-type Hydroamination of Alkenes and Alkynes Using Hydrazides

Hunt, Ashley D.

18 April 2011

Nitrogen-containing molecules are ubiquitous in both natural products and pharmaceutical drugs, thus an efficient method for the formation of these motifs is of great importance. Hydroamination, that is the addition of an N-H bond across an unsaturated carbon-carbon bond of an alkene or alkyne, stands out as a potential approach to obtain such molecules. To date, most research in this area relies on transition-metal catalysis to enable such reactivity. In efforts directed towards metal-free alternatives, we have developed a simple, metal-free hydroamination of alkenes using hydrazides. Further investigation into the corresponding reactivity of alkynes with hydrazides has provided access to novel azomethine imine products. In Chapter 2, expansion of the substrate scope with respect to the intramolecular hydroamination of alkenes using hydrazides, as well as studies directed towards elucidation of the mechanism of this reaction will be presented. The intramolecular hydroamination of alkynes using hydrazides and methods to access and isolate the azomethine imine products formed will be discussed in Chapter 3.

hydroamination

hydrazide

azomethine imine

alkene

alkyne

dipole

heterocycles

Intramolecular Cope-type Hydroamination of Alkenes and Alkynes Using Hydrazides

Hunt, Ashley D.

January 2011

Nitrogen-containing molecules are ubiquitous in both natural products and pharmaceutical drugs, thus an efficient method for the formation of these motifs is of great importance. Hydroamination, that is the addition of an N-H bond across an unsaturated carbon-carbon bond of an alkene or alkyne, stands out as a potential approach to obtain such molecules. To date, most research in this area relies on transition-metal catalysis to enable such reactivity. In efforts directed towards metal-free alternatives, we have developed a simple, metal-free hydroamination of alkenes using hydrazides. Further investigation into the corresponding reactivity of alkynes with hydrazides has provided access to novel azomethine imine products. In Chapter 2, expansion of the substrate scope with respect to the intramolecular hydroamination of alkenes using hydrazides, as well as studies directed towards elucidation of the mechanism of this reaction will be presented. The intramolecular hydroamination of alkynes using hydrazides and methods to access and isolate the azomethine imine products formed will be discussed in Chapter 3.

hydroamination

hydrazide

azomethine imine

alkene

alkyne

dipole

heterocycles

Verdazyl Radicals as Mediators in Living Radical Polymerizations and as Novel Substrates for Heterocyclic Syntheses

Chen, Eric Kuan-Yu

05 August 2010

Verdazyl radicals are a family of multicoloured stable free radicals. Aside from the defining backbone of four nitrogen atoms, these radicals contain multiple highly modifiable sites that grant them a high degree of derivatization. Despite having been discovered more than half a century ago, limited applications have been found for the verdazyl radicals and little is known about their chemistry. This thesis begins with an investigation to determine whether verdazyl radicals have a future as mediating agents in living radical polymerizations and progresses to their application as substrates for organic synthesis, an application that to date has not been pursued either with verdazyl or nitroxide stable radicals. The first part of this thesis describes the successful use of the 1,5-dimethyl-3-phenyl-6-oxoverdazyl radical as a mediating agent for styrene and n-butyl acrylate stable free radical polymerizations. The study of other verdazyl derivatives demonstrated the impact of steric and electronic properties of the verdazyl radicals on their ability to mediate polymerizations. The second part of this thesis outlines the initial discovery and the mechanistic elucidation of the transformation of the 1,5-dimethyl-3-phenyl-6-oxoverdazyl radical into an azomethine imine, which in the presence of dipolarophiles, undergoes a [3+2] 1,3-dipolar cycloaddition reaction to yield unique pyrazolotetrazinone structures. The reactivity of the azomethine imine and the scope of the reaction were also examined. The third part of this thesis describes the discovery and mechanistic determination of a base-induced rearrangement reaction that transforms the verdazyl-derived pyrazolotetrazinone cycloadducts into corresponding pyrazolotriazinones or triazole structures. The nucleophilicity, or the lack thereof, of the base employed leading to various rearrangement products was examined in detail. The final part of this thesis demonstrates the compatibility of the verdazyl-initiated cycloaddition and rearrangement reactions with the philosophy of diversity-oriented synthesis in generating libraries of heterocycles. A library of verdazyl-derived heterocycles was generated in a short amount of time and was tested non-specifically for biological activity against acute myeloid leukemia and multiple myeloma cell lines. One particular compound showed cell-killing activity at the 250 mM range, indicating future potential for this chemistry in the field of drug discovery.

stable free radical

living radical polymerization

verdazyl

cycloaddition

rearrangement

diversity-oriented synthesis

azomethine imine

0495

0490

Verdazyl Radicals as Substrates for the Synthesis of Novel Nitrogen-containing Heterocycles

Dang, Jeremy

16 September 2011

The emergence of verdazyl radicals as starting materials for organic synthesis is providing a unique opportunity to create a variety of distinctive heterocyclic scaffolds. These stable radicals have previously been used as spin probes, polymerization inhibitors, mediators of living radical polymerizations, and as substrates for molecular-based magnets. However, verdazyl radicals have never been employed to fulfill an organic synthetic role until recently. In an effort to pioneer the chemistry behind verdazyl radicals as novel organic substrates, our lab has been inspired to expand and explore the scope of reactions involving their synthetic utility. This thesis assesses the synthetic versatility of verdazyl radicals by constructing a library of structurally complex and diverse verdazyl-derived heterocycles in an approach called diversity-oriented synthesis. The synthetic versatility was further expanded to the preparation of a biphenyl-stacked biphenylophane, which exhibited interesting structural and conformational features as highlighted herein.

Verdazyl radicals

1,3-dipolar cycloaddition

azomethine imine

heterocyclic syntheses

pyrazolotetrazinanone

0490

Verdazyl Radicals as Mediators in Living Radical Polymerizations and as Novel Substrates for Heterocyclic Syntheses

Chen, Eric Kuan-Yu

05 August 2010

Verdazyl radicals are a family of multicoloured stable free radicals. Aside from the defining backbone of four nitrogen atoms, these radicals contain multiple highly modifiable sites that grant them a high degree of derivatization. Despite having been discovered more than half a century ago, limited applications have been found for the verdazyl radicals and little is known about their chemistry. This thesis begins with an investigation to determine whether verdazyl radicals have a future as mediating agents in living radical polymerizations and progresses to their application as substrates for organic synthesis, an application that to date has not been pursued either with verdazyl or nitroxide stable radicals. The first part of this thesis describes the successful use of the 1,5-dimethyl-3-phenyl-6-oxoverdazyl radical as a mediating agent for styrene and n-butyl acrylate stable free radical polymerizations. The study of other verdazyl derivatives demonstrated the impact of steric and electronic properties of the verdazyl radicals on their ability to mediate polymerizations. The second part of this thesis outlines the initial discovery and the mechanistic elucidation of the transformation of the 1,5-dimethyl-3-phenyl-6-oxoverdazyl radical into an azomethine imine, which in the presence of dipolarophiles, undergoes a [3+2] 1,3-dipolar cycloaddition reaction to yield unique pyrazolotetrazinone structures. The reactivity of the azomethine imine and the scope of the reaction were also examined. The third part of this thesis describes the discovery and mechanistic determination of a base-induced rearrangement reaction that transforms the verdazyl-derived pyrazolotetrazinone cycloadducts into corresponding pyrazolotriazinones or triazole structures. The nucleophilicity, or the lack thereof, of the base employed leading to various rearrangement products was examined in detail. The final part of this thesis demonstrates the compatibility of the verdazyl-initiated cycloaddition and rearrangement reactions with the philosophy of diversity-oriented synthesis in generating libraries of heterocycles. A library of verdazyl-derived heterocycles was generated in a short amount of time and was tested non-specifically for biological activity against acute myeloid leukemia and multiple myeloma cell lines. One particular compound showed cell-killing activity at the 250 mM range, indicating future potential for this chemistry in the field of drug discovery.

stable free radical

living radical polymerization

verdazyl

cycloaddition

rearrangement

diversity-oriented synthesis

azomethine imine

0495

0490

Verdazyl Radicals as Substrates for the Synthesis of Novel Nitrogen-containing Heterocycles

Dang, Jeremy

16 September 2011

The emergence of verdazyl radicals as starting materials for organic synthesis is providing a unique opportunity to create a variety of distinctive heterocyclic scaffolds. These stable radicals have previously been used as spin probes, polymerization inhibitors, mediators of living radical polymerizations, and as substrates for molecular-based magnets. However, verdazyl radicals have never been employed to fulfill an organic synthetic role until recently. In an effort to pioneer the chemistry behind verdazyl radicals as novel organic substrates, our lab has been inspired to expand and explore the scope of reactions involving their synthetic utility. This thesis assesses the synthetic versatility of verdazyl radicals by constructing a library of structurally complex and diverse verdazyl-derived heterocycles in an approach called diversity-oriented synthesis. The synthetic versatility was further expanded to the preparation of a biphenyl-stacked biphenylophane, which exhibited interesting structural and conformational features as highlighted herein.

Verdazyl radicals

1,3-dipolar cycloaddition

azomethine imine

heterocyclic syntheses

pyrazolotetrazinanone

0490

Synthesis of Azomethine Imines via Alkene Aminocarbonylation and their Derivatization into Pyrazolones

Lavergne, Kaitlyn

January 2015

Nitrogen-containing heterocyclic compounds are very important to the pharmaceutical and agrochemical industries, among others. Over the past few years, the Beauchemin group has been exploring reactivity of N-substituted isocyanates and as part of this has developed a metal-free alkene aminocarbonylation process relying on imino-isocyanates to form azomethine imines. The azomethine imines formed are interesting since they contain a cyclic β-aminocarbonyl motif. Catalysis of this reaction using basic additives allowed milder reaction conditions with electron-rich C=C bonds such as enol ethers. Efforts have also been made towards the derivatization of these azomethine imines into useful products. It was discovered that upon reduction and aromatization of azomethine imines, pyrazolones could be obtained. This is providing a novel modular approach to these compounds, which have relevance in pharmaceuticals and agrochemicals. This reactivity was extended to include imino-isothiocyanates.

Aminocarbonylation

Azomethine imine

Pyrazolones

Thioxo azomethine imines

Thiopyrazolones

Imino-isocyanates

Imino-isothiocyanates

Aminothiocarbonylation

Enol ethers

Intermolecular [3+2] Cycloadditions of Imino-isocyanates to Access β-Amino Carbonyl Compounds

Bongers, Amanda L.

January 2017

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.

isocyanate

aminocarbonylation

amino-isocyanate

imino-isocyanate

[3+2] cycloaddition

azomethine imine

β-amino carbonyl

alkene