Diversifying Homogenous Au(I)-Catalysis through New Reaction Discovery

Motika, Stephen

03 July 2017

Homogenous Au(I)-catalysis has become a valuable synthetic tool to activate a host of unsaturated carbon functional groups towards nucleophilic addition. Over the course of the past two decades, many have embarked on new journeys within this field. Notably, the advancements in this field hinge on the development of new ligand systems that impart novel reactivity at the metal. Our group has focused on this area, as we have successfully demonstrated the utility of 1,2,3-triazoles as ligands for gold and a host of other transition metals and Lewis acids. With respect to gold catalysis, these ligands enhance the stability of the metal center, thus inhibiting typical reductive decomposition pathways that have plagued this field. The enhanced stability comes with a price though as higher temperatures can be required. We’ve addressed this challenge by discovering an interesting synergy between triazole-gold and Lewis acids, allowing us to overcome the lower reactivity of these catalysts. During my time as a graduate student, I have focused heavily on enlisting these catalytic systems for new reaction discovery. In my first experimental chapter, I was able to develop an interesting reaction cascade in which triazole-gold and secondary amine catalysts were used. I started with a well-known gold-catalyzed Claisen rearrangement of propargyl vinyl ether, yielding functionalized allenes. The identical oxidation state between these allenes and synthetically appealing dienals was an impetus to develop a new isomerization strategy. After screening various conditions, I was able to successfully execute this design. Most of the work I have been involved in over the past two years has surrounded a gold-catalyzed hydroboration to yield interesting hetercocycles containing a N-B bond. The N-B bond offers some unique properties as it is isoelectronic to a C-C double bond. Despite the simplicity in this design, it would become apparent early on in this research that mitigating the reducing strength of the starting materials was absolutely critical. Starting materials that were too strongly reducing led to rapid catalyst decomposition. Through thorough reaction screening, we have been able to identify a catalytic system that performs extremely well in this context. Ultimately, our goal in this work is to access 1,2-azaborines, which are isosteres of benzene. This compound exhibits aromaticity, as determined through structural and quantitative analyses by several groups. However, subtle differences in properties between the azaborine and benzene, such as its polarity, have intrigued many researchers across various disciplines. Moreover, the ubiquity of its carbonaceous parent in biological systems has prompted many to pursue new synthetic routes to access 1,2-azaborines.

Gold Catalysis

Dual Catalysis

Hydroboration

1,2-Azaborine

Chemistry

Synthesis, Characterization and Catalytic Studies of Chiral Gold Acyclic Diaminocarbene Complexes

Zhang, Xiaofan

08 1900

Chiral gold complexes have been applied in homogeneous catalytic reactions since 1986, in some cases with high enantioselectivity. Acyclic diaminocarbene (ADC) ligands are acyclic analogues of N-heterocyclic carbenes (NHCs) that have larger N-CCarbene-N angles and stronger donating ability. ADCs have been developed as alternatives to phosphine and NHC ligands in homogeneous gold catalysis. In 2012, a new series of chiral gold(I) ADCs were first developed by Slaughter's group and were shown to give remarkable enantioselectivities in some reactions. Because of the hindered rotation of the N-CCarbene bonds of ADC, chiral ADC substituents can easily get close to the metal center in some conformations, although two rotameric structures are formed if the chiral amine is nonsymmetric. The selective of specific ADC conformations was the initial focus of this study. Formational selectivity of one diastereomer of an ADC ligand during synthesis was examines by measuring the relative rates of diastereomer formation in a 1H NMR kinetic study. The potential for converting multiple conformational isomers of ADCs into a single conformation, or at least a simpler mixture, was examined. This study used the analogy that anti- isomer has electronic and structural similarity with urea/thiourea, raising the possibility that 1,8-naphthyridine can be used to favor certain conformations through a self-assembled hydrogen-bonding complex. Gold(I) is a soft carbophilic Lewis acid able to active C-C π bonds to nucleophilic attack, and ADC-gold complexes are potentially useful in this regard. Therefore, biaryl gold(I) ADC complexes were examine with silver salt additives in catalytic 1,6-enyne cyclization reaction. A detailed study found that the counteranion affects the regioselectivities of these reactions more than substituents on the ancillary ADC ligands.

Acyclic diaminocarbene

Chiral gold catalysis

ADC conformational selectivity

Chemistry, Inorganic

In Situ Infrared Spectroscopy Study of Gold Oxidation Catalysis

Miller, Duane D.

05 October 2006

No description available.

Engineering, Chemical

gold titania

Au/TiO2

gold catalysis

CO oxidation

Gold-Catalyzed Cycloadditions: An Approach Toward Complex Molecular Frameworks via Transannular, Intermolecular, and Intramolecular Methods

Bailey, Lauren N.

03 May 2010

No description available.

Organic Chemistry

gold catalysis

[4 + 3] cycloadditions

transannular

cyclopropanation

The Synthesis And Characterization Of Novel Chiral Gold(I) N-Heterocyclic Carbene Complexes

Holmes, Michael R., II

24 July 2015

No description available.

Organic Chemistry

Synthetic Studies Toward Marine Natural Product Okadaic Acid and Its Analogs

Fang, Chao

22 July 2011

No description available.

Chemistry

okadaic acid

spiroketal synthesis

gold catalysis

belizeanic acid

Total Synthesis of Dinophysistoxin-2 and its Analogues

Pang, Yucheng

28 September 2011

No description available.

Chemistry

Dinophysistoxin-2

total synthesis

SAR

gold catalysis

Applications of Lewis Acid Gold(I) Catalysis in the Synthesis of Polycyclic Carbocycles and the Total Synthesis of (±)-Salvinorin A

Tran, Huy Minh

27 September 2022

For most of human history, precious metals such as gold, silver, and platinum were used as currency and jeweler. Beginning in the 20th century, with the onset of transition metal catalysis, chemists developed new methods to support industrial chemical synthesis. There are many notable examples, one is the Ziegler-Natta catalysts to perform olefin polymerization using titanium/aluminum-based systems. Another is the Fisher-Tropsch process to convert synthesis gas (CO/H2) into liquid hydrocarbons typically using cobalt, ruthenium, and iron. Also, the Haber-Bosch process where nitrogen and hydrogen gases are reacted in the presence of an iron catalyst to generate ammonia is a critically important process for the production of agricultural fertilizer worldwide. For precious transition metals such as gold, the first report of the metal being used in homogenous catalysis was in 1986. In this thesis, the application of gold homogenous into the synthesis of polycyclic carbocycles is being reported. This method was designed as a three-step one-pot sequence where an initial Diels-Alder reaction forms the first carbocycle with an embedded silyl enol ether moiety reactive to homogenous gold(I) catalysis. By selecting specific catalyst ligand and solvent conditions, selectivity between tri or steroid-like tetracycles was achieved via gold then Prins cyclizations or gold then Diels-Alder cyclizations. A combined total of 31 examples across 3 scopes was demonstrated using this divergent and modular strategy. This methodology aims to be applied in medicinal chemistry research in the synthesis of libraries of structurally related compounds baring resemblance to bioactive natural products. A related synthetic strategy was also used by our group in the total synthesis of salvinorin A. Initially isolated from Salvia divinorum in 1972, salvinorin A is trans neo-clerodane diterpene and was found to be a selective agonist of the kappa opioid receptor (κOR). This is unique compared to traditional morphine type opioids which are substrates of mu (μOR) and delta (δOR) opioid receptors. And as such, extensive work in medicinal chemistry has been published on utilizing salvinorin A as starting point towards the development of new analgesics. Our approach to synthesize salvinorin A centered around using a Diels-Alder reaction then gold cyclization to form the AB rings. The remaining C ring was formed via gold photoredox catalyzed radical cyclization, 1,2-addition of a furanyl organotitanium, and palladium catalyzed carbonylation. The formal synthesis of salvinorin A was completed in 21 steps by intercepting an intermediate in Hagiwara’s reported synthesis, and addition 3 steps would complete the total synthesis.

Organic Chemistry

Gold Catalysis

Total Synthesis

Organic Methodology

Development of New Biarylphosphane Coinage Metal Complexes for the Regioselective Synthesis of Fused Carbocycles

Levesque, Patrick Pierre

02 October 2012

In the last century, no less than five nobel prizes have been awarded for the construction of carbon-carbon bonds : The Grignard reaction (1912), the Diels-Alder reaction (1950), the Wittig reaction (1979), Olefin metathesis (2005) and palladium cross-coupling reactions (2011). The latter two are transition metal catalyzed transformations and their impact on the synthesis of pharmaceutically active compounds, bulk chemicals, fine chemicals, high tech materials as well as agricultural chemicals has been phenomenal. These reactions have changed the way the scientific community views the science of synthesis. Unlike palladium, gold has long been considered to be an expensive and inert metal and therefore, research on Au catalysis was scarse until the begining of the new millenium. Once the scientific community realized the treasure trove of reactivity that gold had to offer, the number of chemical transformations as well as total syntheses involving Au(I)/Au(III) catalysis has sky rocketed. A methodology initially developped by Toste and coworkers has shown that intramolecular addition of a silyl enol ether on alkynes proceeds via a 5-exo¬-dig¬ process. In the first part of this thesis, we will discuss how the ancilary ligand on Au(I) species can influence pathway selectivity for these cyclizations, therefore opening the door to selective 6-endo-dig cyclizations to generate fused carbocycles. With biological processes as well as other competing processes becoming ever more efficient, the future of chemical synthesis is threatened. If it is to survive, the focus of new chemical transformations will have to be on the cost and the greeness of the process. In the second part of this thesis, we will demonstrate how Ag(I) and Cu(I) complexes can offer even better 6-endo-dig¬ selectivity than analogous Au(I) complexes. Silver is about 56 times less expensive than gold, and copper is about 453 times less expensive than gold. Due to the greatly increased selectivity as well as the diminished cost of the catalysts, we have provided access to an attractive 6-endo-dig¬ cyclization process.

Biarylphosphane

Gold catalysis

Silver catalysis

Copper catalysis

6 endo-dig

5-exo dig

Carbocycly synthesis

Development of the 5-exo-dig/Prins Reaction and Efforts towards the Total Synthesis of (±)-Magellanine

Bétournay, Geneviève L.

02 November 2012

Gold catalysis has attracted much attention within the chemical community in recent years, and its importance as a synthetic tool has only started to be uncovered. This thesis describes the development of a gold(I) catalyzed transformation and its application to the synthesis of a structurally unique Lycopodium alkaloid, Magellanine. Although there have been a few reports on the synthesis of the magellanane core to date, the approach described herein would represent a new and efficient strategy to construct the angularly fused tetracyclic core. The 5 exo dig/Prins reaction that would be the key step of the synthesis was first developed and studied on a model substrate, enabling the verification of the hypothesis that this transformation could indeed form the A and B rings of Magellanine and be applied to its synthesis. This reaction formed the tricyclic products in good yields and in good exo:endo ratios. The synthesis of Magellanine was undertaken, but problems of isomerization prevented the synthesis of the desired 5 exo dig/Prins substrate, which contained the C and D rings of Magellanine with a cis relationship at the ring junction. However, an almost identical substrate, save for a trans configuration between the C and D rings instead of the cis configuration, was prepared and served in further establishing the applicability of this methodology to the synthesis of Magellanine by successfully undergoing the 5-exo-dig/Prins reaction and generating the tetracyclic products. Studies of the steps following the key transformation were performed on the model substrate, allowing for the evaluation of these steps prior to their use in the synthesis. The results of the studies indicate a possible need to revisit the order in which the steps should be carried out. Promising solutions to the different obstacle encountered during the work are presented, demonstrating how the synthesis of Magellanine through a route featuring the 5-exo-dig/Prins cyclization is attainable.

5-exo-dig

Prins

Gold catalysis

Synthesis

Magellanine

magellanane alkaloids

Lycopodium alkaloids

Organic