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2. Photocatalytic decarboxylative amidosulfonation enables direct transformation of carboxylic acids to sulfonamides

Author

Viet D. Nguyen, Hadi D. Arman, Vu T. Nguyen, Ngan T. H. Vuong, Graham C. Haug, and Oleg V. Larionov

Subjects
chemistry.chemical_classification, Sulfonyl, General Chemistry, Sulfinic acid, Combinatorial chemistry, Catalysis, Chemistry, chemistry.chemical_compound, chemistry, Nucleophile, Reagent, Acridine, Electrophile, Organic synthesis
Abstract

Sulfonamides feature prominently in organic synthesis, materials science and medicinal chemistry, where they play important roles as bioisosteric replacements of carboxylic acids and other carbonyls. Yet, a general synthetic platform for the direct conversion of carboxylic acids to a range of functionalized sulfonamides has remained elusive. Herein, we present a visible light-induced, dual catalytic platform that for the first time allows for a one-step access to sulfonamides and sulfonyl azides directly from carboxylic acids. The broad scope of the direct decarboxylative amidosulfonation (DDAS) platform is enabled by the efficient direct conversion of carboxylic acids to sulfinic acids that is catalyzed by acridine photocatalysts and interfaced with copper-catalyzed sulfur–nitrogen bond-forming cross-couplings with both electrophilic and nucleophilic reagents., Sulfonamides are now accessible directly from carboxylic acids by a one-step, tricomponent decarboxylative amidosulfonation that provides the missing link between the two key functionalities.

Published
2021

3. Photoinduced C(sp3)–H sulfination empowers the direct and chemoselective introduction of the sulfonyl group

Author

Shengfei Jin, Viet D. Nguyen, Ramon Trevino, Graham C. Haug, Oleg V. Larionov, and Hadi D. Arman

Subjects
Sulfonyl, chemistry.chemical_classification, Chemistry, Surface modification, Regioselectivity, Reactivity (chemistry), General Chemistry, Chemoselectivity, Medicinal chemistry, Organosulfur compounds
Abstract

Direct installation of the sulfinate group by the functionalization of unreactive aliphatic C–H bonds can provide access to most classes of organosulfur compounds, because of the central position of sulfinates as sulfonyl group linchpins. Despite the importance of the sulfonyl group in synthesis, medicine, and materials science, a direct C(sp3)–H sulfination reaction that can convert abundant aliphatic C–H bonds to sulfinates has remained elusive, due to the reactivity of sulfinates that are incompatible with typical oxidation-driven C–H functionalization approaches. We report herein a photoinduced C(sp3)–H sulfination reaction that is mediated by sodium metabisulfite and enables access to a variety of sulfinates. The reaction proceeds with high chemoselectivity and moderate to good regioselectivity, affording only monosulfination products and can be used for a solvent-controlled regiodivergent distal C(sp3)–H functionalization.

Published
2021

4. Acridine Photocatalysis: Insights into the Mechanism and Development of a Dual-Catalytic Direct Decarboxylative Conjugate Addition

Author

Ngan T. H. Vuong, Viet D. Nguyen, Hadi D. Arman, Oleg V. Larionov, Vu T. Nguyen, Hang T. Dang, and Graham C. Haug

Subjects
010405 organic chemistry, Decarboxylation, Chemistry, General Chemistry, 010402 general chemistry, 01 natural sciences, Combinatorial chemistry, Article, Catalysis, 0104 chemical sciences, chemistry.chemical_compound, Nucleophile, Acridine, Photocatalysis, Conjugate
Abstract

Conjugate addition is one of the most synthetically useful carbon‒carbon bond-forming reactions, however, reactive carbon nucleophiles are typically required to effect the addition. Radical conjugate addition provides an avenue for replacing reactive nucleophiles with convenient radical precursors. Carboxylic acids can serve as simple and stable radical precursors by way of decarboxylation, but activation to reactive esters is typically necessary to facilitate the challenging decarboxylation. Here, we report a direct, dual-catalytic decarboxylative radical conjugate addition of a wide range of carboxylic acids that does not require acid preactivation and is enabled by the visible light-driven acridine photocatalysis interfaced with an efficient copper catalytic cycle. Mechanistic and computational studies provide insights into the roles of the ligands and metal species in the dual catalytic process and the photocatalytic activity of substituted acridines.

Published
2020

5. Visible‐Light‐Enabled Direct Decarboxylative N‐Alkylation

Author

Vu T. Nguyen, Hadi D. Arman, Oleg V. Larionov, Viet D. Nguyen, Graham C. Haug, Ngan T. H. Vuong, and Hang T. Dang

Subjects
Aniline Compounds, Alkylation, Tandem, 010405 organic chemistry, Chemistry, Decarboxylation, General Medicine, General Chemistry, 010402 general chemistry, Ring (chemistry), 01 natural sciences, Combinatorial chemistry, Article, Catalysis, 0104 chemical sciences, Heterocyclic Compounds, Photocatalysis, Acridines, Amines, Oxidation-Reduction, Amination, Visible spectrum
Abstract

The development of efficient and selective C-N bond-forming reactions from abundant feedstock chemicals remains a central theme in organic chemistry owing to the key roles of amines in synthesis, drug discovery, and materials science. Herein, we present a dual catalytic system for the N-alkylation of diverse aromatic carbocyclic and heterocyclic amines directly with carboxylic acids, by-passing their preactivation as redox-active esters. The reaction, which is enabled by visible-light-driven, acridine-catalyzed decarboxylation, provides access to N-alkylated secondary and tertiary anilines and N-heterocycles. Additional examples, including double alkylation, the installation of metabolically robust deuterated methyl groups, and tandem ring formation, further demonstrate the potential of the direct decarboxylative alkylation (DDA) reaction.

Published
2020

6. Visible Light-Induced Borylation of C–O, C–N, and C–X Bonds

Author

Kirk S. Schanze, Graham C. Haug, Shengfei Jin, Vu T. Nguyen, Hadi D. Arman, Viet D. Nguyen, Hang T. Dang, Ru He, and Oleg V. Larionov

Subjects
Light, Nitrogen, General Chemistry, 010402 general chemistry, Boronic Acids, 01 natural sciences, Biochemistry, Combinatorial chemistry, Borylation, Carbon, Article, Catalysis, 0104 chemical sciences, Oxygen, chemistry.chemical_compound, Electron transfer, Colloid and Surface Chemistry, chemistry, Phenothiazine, Functional group, Photocatalysis, Phenol, Visible spectrum
Abstract

Boronic acids are centrally important functional motifs and synthetic precursors. Visible light-induced borylation may provide access to structurally diverse boronates, but a broadly efficient photocatalytic borylation method that can effect borylation of a wide range of substrates, including strong C-O bonds, remains elusive. Herein, we report a general, metal-free visible light-induced photocatalytic borylation platform that enables borylation of electron-rich derivatives of phenols and anilines, chloroarenes, as well as other haloarenes. The reaction exhibits excellent functional group tolerance, as demonstrated by the borylation of a range of structurally complex substrates. Remarkably, the reaction is catalyzed by phenothiazine, a simple organic photocatalyst with MW < 200 that mediates the previously unachievable visible light-induced single electron reduction of phenol derivatives with reduction potentials as negative as approximately - 3 V versus SCE by a proton-coupled electron transfer mechanism. Mechanistic studies point to the crucial role of the photocatalyst-base interaction.

Published
2020

7. Deoxygenative α-alkylation and α-arylation of 1,2-dicarbonyls

Author

Viet D. Nguyen, Shengfei Jin, Graham C. Haug, Hadi D. Arman, Oleg V. Larionov, and Hang T. Dang

Subjects
Chemistry, Nucleophile, chemistry, Reagent, Electrophile, chemistry.chemical_element, General Chemistry, Alkylation, Boron, Combinatorial chemistry
Abstract

Construction of C–C bonds at the α-carbon is a challenging but synthetically indispensable approach to α-branched carbonyl motifs that are widely represented among drugs, natural products, and synthetic intermediates. Here, we describe a simple approach to generation of boron enolates in the absence of strong bases that allows for introduction of both α-alkyl and α-aryl groups in a reaction of readily accessible 1,2-dicarbonyls and organoboranes. Obviation of unselective, strongly basic and nucleophilic reagents permits carrying out the reaction in the presence of electrophiles that intercept the intermediate boron enolates, resulting in two new α-C–C bonds in a tricomponent process., α-Branched carboxylic acids and other carbonyls are readily accessed by a metal- and base-free deoxygenative α-alkylation and α-arylation of 1,2-dicarbonyls via boron enolates, resulting in a tricomponent coupling with unconventional electrophiles.

Published
2020

8. Alkene Synthesis by Photocatalytic Chemoenzymatically Compatible Dehydrodecarboxylation of Carboxylic Acids and Biomass

Author

Shengfei Jin, Hadi D. Arman, Brenda S. Benavides, Viet D. Nguyen, Hang T. Dang, Graham C. Haug, Zhiliang Li, Oleg V. Larionov, Vu T. Nguyen, and Carsten Flores-Hansen

Subjects
010405 organic chemistry, Biomass, General Chemistry, 010402 general chemistry, 01 natural sciences, Catalysis, Article, 0104 chemical sciences, chemistry.chemical_compound, chemistry, Alkene synthesis, Renewable biomass, Photocatalysis, Organic chemistry, Organic synthesis
Abstract

Direct conversion of renewable biomass and bioderived chemicals to valuable synthetic intermediates for organic synthesis and materials science applications by means of mild and chemoselective catalytic methods has largely remained elusive. Development of artificial catalytic systems that are compatible with enzymatic reactions provides a synergistic solution to this enduring challenge by leveraging previously unachievable reactivity and selectivity modes. We report herein a dual catalytic dehydrodecarboxylation reaction that is enabled by a crossover of the photoinduced acridine-catalyzed O–H hydrogen atom transfer (HAT) and cobaloxime-catalyzed C–H-HAT processes. The reaction produces a variety of alkenes from readily available carboxylic acids. The reaction can be embedded in a scalable triple-catalytic cooperative chemoenzymatic lipase–acridine–cobaloxime process that allows for direct conversion of plant oils and biomass to long-chain terminal alkenes, precursors to bioderived polymers.

Published
2022

9. Functional group divergence and the structural basis of acridine photocatalysis revealed by direct decarboxysulfonylation

Author

Vu T. Nguyen, Graham C. Haug, Viet D. Nguyen, Ngan T. H. Vuong, Guna B. Karki, Hadi D. Arman, and Oleg V. Larionov

Subjects
General Chemistry
Abstract

The reactivity of the sulfonyl group varies dramatically from nucleophilic sulfinates through chemically robust sulfones to electrophilic sulfonyl halides-a feature that has been used extensively in medicinal chemistry, synthesis, and materials science, especially as bioisosteric replacements and structural analogs of carboxylic acids and other carbonyls. Despite the great synthetic potential of the carboxylic to sulfonyl functional group interconversions, a method that can convert carboxylic acids directly to sulfones, sulfinates and sulfonyl halides has remained out of reach. We report herein the development of a photocatalytic system that for the first time enables direct decarboxylative conversion of carboxylic acids to sulfones and sulfinates, as well as sulfonyl chlorides and fluorides in one step and in a multicomponent fashion. A mechanistic study prompted by the development of the new method revealed the key structural features of the acridine photocatalysts that facilitate the decarboxylative transformations and provided an informative and predictive multivariate linear regression model that quantitatively relates the structural features with the photocatalytic activity.

Published
2022

10. Bond Memory in Dynamically Determined Stereoselectivity

Author

Oleg V. Larionov, Daniel A. Singleton, Vladislav A. Roytman, Graham C. Haug, Vu T. Nguyen, Shengfei Jin, and Viet D. Nguyen

Subjects
Chemistry, Bond, Cyclohexenes, Molecular Conformation, Stereoisomerism, General Chemistry, 010402 general chemistry, 01 natural sciences, Biochemistry, Article, Catalysis, 0104 chemical sciences, Colloid and Surface Chemistry, Chemical physics, Quantum Theory, Stereoselectivity, Selectivity
Abstract

The carboborative ring contraction of cyclohexenes exhibits an abnormal selectivity pattern in which a formally concerted double migration gives rise to predominant but not exclusive inversion products. In dynamic trajectories, the inversion and retention products are formed from the same transition state, and the trajectories accurately account for the experimental product ratios. The unusual origin of the selectivity is the dynamically retained non-equivalence of newly formed versus pre-existing bonds after the first bond migration.

Published
2019

11. Photoinduced C(sp

Author

Shengfei, Jin, Graham C, Haug, Ramon, Trevino, Viet D, Nguyen, Hadi D, Arman, and Oleg V, Larionov

Subjects
Chemistry
Abstract

Direct installation of the sulfinate group by the functionalization of unreactive aliphatic C–H bonds can provide access to most classes of organosulfur compounds, because of the central position of sulfinates as sulfonyl group linchpins. Despite the importance of the sulfonyl group in synthesis, medicine, and materials science, a direct C(sp3)–H sulfination reaction that can convert abundant aliphatic C–H bonds to sulfinates has remained elusive, due to the reactivity of sulfinates that are incompatible with typical oxidation-driven C–H functionalization approaches. We report herein a photoinduced C(sp3)–H sulfination reaction that is mediated by sodium metabisulfite and enables access to a variety of sulfinates. The reaction proceeds with high chemoselectivity and moderate to good regioselectivity, affording only monosulfination products and can be used for a solvent-controlled regiodivergent distal C(sp3)–H functionalization., The photoinduced C–H sulfination of abundant aliphatic C–H bonds provides direct access to all major classes of organosulfur compounds via the intermediacy of synthetically versatile sulfinate salts.

Published
2021

12. Pattern of dopamine signaling during aversive events predicts active avoidance learning

Author

Alexa P. Magnon, Claire E. Stelly, Kaitlyn M. Fonzi, Graham C. Haug, Miriam A. Garcia, Sean C. Tritley, Matthew J. Wanat, and Maria Alicia P. Ramos

Subjects
Male, 0301 basic medicine, Striatal dopamine, Dopamine, Mean squared prediction error, Population, Mesolimbic dopamine, Striatum, Rats, Sprague-Dawley, 03 medical and health sciences, 0302 clinical medicine, Avoidance learning, Avoidance Learning, medicine, Animals, education, Electroshock, education.field_of_study, Multidisciplinary, Corpus Striatum, Rats, 030104 developmental biology, PNAS Plus, Cues, Aversive Stimulus, Psychology, Neuroscience, 030217 neurology & neurosurgery, Signal Transduction, medicine.drug
Abstract

Learning to avoid aversive outcomes is an adaptive strategy to limit one’s future exposure to stressful events. However, there is considerable variance in active avoidance learning across a population. The mesolimbic dopamine system contributes to behaviors elicited by aversive stimuli, although it is unclear if the heterogeneity in active avoidance learning is explained by differences in dopamine transmission. Furthermore, it is not known how dopamine signals evolve throughout active avoidance learning. To address these questions, we performed voltammetry recordings of dopamine release in the ventral medial striatum throughout training on inescapable footshock and signaled active avoidance tasks. This approach revealed differences in the pattern of dopamine signaling during the aversive cue and the safety period that corresponded to subsequent task performance. Dopamine transmission throughout the footshock bout did not predict performance but rather was modulated by the prior stress exposure. Additionally, we demonstrate that dopamine encodes a safety prediction error signal, which illustrates that ventral medial striatal dopamine release conveys a learning signal during both appetitive and aversive conditions.

Published
2019

13. Z-Selective Dienylation Enables Stereodivergent Construction of Dienes and Unravels a Ligand-Driven Mechanistic Dichotomy

Author

Hadi D. Arman, Viet D. Nguyen, Oleg V. Larionov, Ngan T. H. Vuong, Hang T. Dang, and Graham C. Haug

Subjects
chemistry.chemical_classification, Double bond, Diene, 010405 organic chemistry, Ligand, Sulfolene, chemistry.chemical_element, General Chemistry, Conjugated system, 010402 general chemistry, 01 natural sciences, Combinatorial chemistry, Catalysis, Article, 0104 chemical sciences, chemistry.chemical_compound, chemistry, Organic synthesis, Stereoselectivity, Palladium
Abstract

Development of stereoselective and efficient reactions for construction of conjugated dienes and polyenes has remained at the forefront of organic chemistry, due to their key roles in medicinal chemistry, organic synthesis, and materials science. The synthesis of conjugated dienes and polyenes is typically accomplished in a multistep manner by sequential installation of individual C=C bonds because it allows for control of stereoselectivity and efficiency of formation of each double bond. A conceptually distinct dienylation approach entails a stereoselective appendage of a four-carbon unit, shortcutting diene synthesis. Dienylation with sulfolene provided a direct route to E-dienes, but the synthesis of substantially more challenging Z-dienes remained elusive. Here, we report that a highly Z-selective dienylation can be now achieved by a simple adjustment of a ligand, enabling stereodivergent synthesis of E- and Z-dienes from one reagent and in one step. A detailed mechanistic investigation of the E- and Z-selective dienylation provided insight into the divergent behavior of the two catalytic systems and revealed that differences in relative stabilities of catalytically active palladium phosphine complexes have a major impact on the stereochemical outcomes of the dienylation.

Published
2021

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