Your search keyword '"Phipps, Robert J [0000-0002-7383-5469]"' showing total 19 results

1. Substrate-Directed Enantioselective Aziridination of Alkenyl Alcohols Controlled by a Chiral Cation

Author

Alexander Fanourakis, Nicholas J. Hodson, Arthur R. Lit, Robert J. Phipps, Phipps, Robert J [0000-0002-7383-5469], and Apollo - University of Cambridge Repository

Subjects

Colloid and Surface Chemistry, General Chemistry, Biochemistry, Catalysis

Abstract

Alkene aziridination is a highly versatile transformation for the construction of chiral nitrogen-containing compounds. Inspired by the success of analogous substrate-directed epoxidations, we report an enantioselective aziridination of alkenyl alcohols, which enables asymmetric nitrene transfer to alkenes with varied substitution patterns, including those not covered by the current protocols. We believe that our method is effective because it is substrate-directed, exploiting a network of attractive non-covalent interactions between the substrate, an achiral dianionic rhodium(II,II) tetracarboxylate dimer, and its two associated cinchona alkaloid-derived cations. It is these cations that provide a defined chiral pocket in which the aziridination can occur. In addition to a thorough evaluation of compatible alkene classes, we advance a practical mnemonic to predict reaction outcome and disclose a range of post-functionalization protocols that highlight the unique synthetic potential of the enantioenriched aziridine-alcohol products.

Published

2023

2. Enantioselective Giese Additions of Prochiral α-Amino Radicals

Author

Lahdenperä, Antti SK, Bacoş, P David, Phipps, Robert J, Bacoş, P David [0000-0002-7288-2730], Phipps, Robert J [0000-0002-7383-5469], and Apollo - University of Cambridge Repository

Subjects

Colloid and Surface Chemistry, Stereoisomerism, General Chemistry, Amines, Biochemistry, Carbon, Catalysis

Abstract

Funder: Orionin Tutkimuss??ti?, Funder: Emil Aaltosen S??ti?, Funder: Royal Society, Funder: AstraZeneca, Amines featuring an adjacent stereocenter are important building blocks, and recent years have seen remarkable growth in methods forming these via prochiral α-amino radical intermediates. However, very few can exert control over the newly formed stereocenter. We disclose a strategy to overcome this in the context of one of the most widely used radical carbon-carbon bond forming reactions, the Giese reaction. Incorporation of a removable basic heteroarene into the substrate enables a network of attractive noncovalent interactions between a phosphoric acid catalyst, the subsequently formed α-amino radical, and the Giese acceptor, allowing the catalyst to exert control during the C-C bond forming step. Deprotection of the products leads to analogues of γ-aminobutyric acid. We anticipate that this strategy will be applicable to other asymmetric radical transformations in which catalyst control is presently challenging.

Published

2022

3. Discovery and Development of the Enantioselective Minisci Reaction

Author

Bacoş, P David, Lahdenperä, Antti SK, Phipps, Robert J, Bacoş, P David [0000-0002-7288-2730], Phipps, Robert J [0000-0002-7383-5469], and Apollo - University of Cambridge Repository

Subjects

34 Chemical Sciences, 3405 Organic Chemistry

Abstract

ConspectusThe class of reactions now known as Minisci reactions is broadly defined as the addition of nucleophilic carbon-based radicals to basic heteroarenes with subsequent rearomatization to form a new carbon-carbon bond. Since the pioneering work of Minisci in the 1960s and 1970s, these reactions are now widely used in medicinal chemistry due to the ubiquity of basic heterocycles in druglike molecules. One of the long-standing challenges of Minisci chemistry has been that of regioselectivity due to the mixtures of positional isomers commonly obtained on many substrates if there is a choice between similarly activated sites. At the outset of the work described herein, we hypothesized that it may be possible to tackle this using a catalytic strategy whereby a bifunctional Brønsted acid catalyst simultaneously activates the heteroarene and engages attractive non-covalent interactions with the incoming nucleophile, resulting in a proximal attack. Using chiral BINOL-derived phosphoric acids, we not only were able to achieve this goal of regiocontrol but also discovered that we could control the absolute stereochemistry at the new stereocenter formed when prochiral α-amino radicals were employed. At the time, this discovery was unprecedented in the context of Minisci reactions.This Account details the discovery of this protocol and the further development, expansion, and investigations into the mechanism that we have carried out since then, several in collaboration with other research groups. Collaborative efforts have involved an expansion of the scope to diazines guided by multivariate statistical analysis through the development of a predictive model (collaboration with Sigman). Also, a mechanistic study involving detailed DFT analysis (collaboration with Goodman and Ermanis) unveiled the selectivity-determining step as being the deprotonation of a key cationic radical intermediate by the associated chiral phosphate anion. We have additionally carried out a number of synthetic developments of the protocol such as removing the need to prefunctionalize the radical nucleophile; hydrogen-atom transfer can be used to enable a formal coupling of two C-H bonds to form a C-C bond while retaining high enantio- and regioselectivity. Most recently, we have been able to expand the protocol so that α-hydroxy radicals can be used: until this point, all examples had concerned α-amino radicals. Again, HAT was used to generate the α-hydroxy radicals, and DFT studies carried out in collaboration (Ermanis) provided mechanistic insights.Since our original report, there have appeared a number of exciting developments from other research groups whereby the protocol has been applied to new substrates or using different precursors to generate the requisite α-amino radical. There have also been several examples in which alternative photocatalyst systems have been used to reduce the redox-active esters in the original enantioselective Minisci protocol. While primarily an Account, these contributions from other research groups will be covered briefly for context toward the end of the article.

Published

2023

4. Substrate-Directed Enantioselective Aziridination of Alkenyl Alcohols Controlled by a Chiral Cation

Author

Phipps, Robert, Fanourakis, Alexander, Hodson, Nicholas, Lit, Arthur, Phipps, Robert J [0000-0002-7383-5469], and Apollo - University of Cambridge Repository

Subjects

3402 Inorganic Chemistry, 34 Chemical Sciences, 3405 Organic Chemistry

Abstract

Funder: Agency for Science, Technology and Research, Funder: Cambridge Trust, Funder: Wolfson College, University of Cambridge, Funder: Engineering and Physical Sciences Research Council, Alkene aziridination is a highly versatile transformation for the construction of chiral nitrogen-containing com-pounds. Inspired by the success of analogous substrate-directed epoxidations, we report an enantioselective aziridination of alkenyl alcohols which enables asymmetric nitrene transfer to alkenes with varied substitution patterns, including those not covered by the current protocols. We believe that our method is effective because it is substrate-directed, exploiting a net-work of attractive non-covalent interactions between the substrate, an achiral dianionic rhodium(II,II) tetracarboxylate di-mer and its two associated cinchona alkaloid-derived cations. It is these cations that provide a defined chiral pocket in which the aziridination can occur. In addition to a thorough evaluation of compatible alkene classes, we advance a practical mne-monic to predict reaction outcome and disclose a range of post-functionalization protocols which highlight the unique syn-thetic potential of the enantioenriched aziridine-alcohol products.

Published

2023

5. Substrate-Directed Enantioselective Aziridination of Alkenyl Alcohols Controlled by a Chiral Cation

Author

Fanourakis, Alexander, paragon-plus: 6317634, Hodson, Nicholas J., paragon-plus: 6501156, Lit, Arthur R., paragon-plus: 6501157, Phipps, Robert J., paragon-plus: 1105635, Phipps, Robert J. [0000-0002-7383-5469], and Apollo - University of Cambridge Repository

Subjects

Article

Abstract

Alkene aziridination is a highly versatile transformation for the construction of chiral nitrogen-containing compounds. Inspired by the success of analogous substrate-directed epoxidations, we report an enantioselective aziridination of alkenyl alcohols, which enables asymmetric nitrene transfer to alkenes with varied substitution patterns, including those not covered by the current protocols. We believe that our method is effective because it is substrate-directed, exploiting a network of attractive non-covalent interactions between the substrate, an achiral dianionic rhodium­(II,II) tetracarboxylate dimer, and its two associated cinchona alkaloid-derived cations. It is these cations that provide a defined chiral pocket in which the aziridination can occur. In addition to a thorough evaluation of compatible alkene classes, we advance a practical mnemonic to predict reaction outcome and disclose a range of post-functionalization protocols that highlight the unique synthetic potential of the enantioenriched aziridine-alcohol products.

Published

2023

6. Strategies That Utilize Ion Pairing Interactions to Exert Selectivity Control in the Functionalization of C-H Bonds

Author

Gillespie, James E, Fanourakis, Alexander, Phipps, Robert J, Phipps, Robert J [0000-0002-7383-5469], and Apollo - University of Cambridge Repository

Subjects

Ions, Colloid and Surface Chemistry, Perspective, Transition Elements, Hydrogen Bonding, Indicators and Reagents, General Chemistry, Biochemistry, Catalysis

Abstract

Funder: Cambridge Trust, Funder: Wolfson College, University of Oxford, Electrostatic attraction between two groups of opposite charge, typically known as ion-pairing, offers unique opportunities for the design of systems to enable selectivity control in chemical reactions. Catalysis using noncovalent interactions is an established and vibrant research area, but it is noticeable that hydrogen bonding interactions are still the main interaction of choice in system design. Opposite charges experience the powerful force of Coulombic attraction and have the ability to exert fundamental influence on the outcome of reactions that involve charged reagents, intermediates or catalysts. In this Perspective, we will examine how ion-pairing interactions have been used to control selectivity in C-H bond functionalization processes. This broad class of reactions provides an interesting and thought-provoking lens through which to examine the application of ion-pairing design strategies because it is one that encompasses great mechanistic diversity, poses significant selectivity challenges, and perhaps most importantly is of immense interest to synthetic chemists in both industry and academia. We survey reactions that proceed via radical and ionic mechanisms alongside those that involve transition metal catalysis and will deal with control of site-selectivity and enantioselectivity. We anticipate that as this emerging area develops, it will become an ever-more important design strategy for selectivity control.

Published

2022

7. Regioselective Radical Arene Amination for the Concise Synthesis of ortho-Phenylenediamines

Author

James E Gillespie, Robert J. Phipps, Charlotte Morrill, Phipps, Robert J [0000-0002-7383-5469], Apollo - University of Cambridge Repository, and Phipps, Robert [0000-0002-7383-5469]

Subjects

chemistry.chemical_classification, 34 Chemical Sciences, Communication, Radical, Substrate (chemistry), Regioselectivity, 3405 Organic Chemistry, General Chemistry, 010402 general chemistry, 01 natural sciences, Biochemistry, Combinatorial chemistry, Catalysis, 0104 chemical sciences, 3. Good health, chemistry.chemical_compound, Colloid and Surface Chemistry, Aniline, Radical ion, chemistry, Non-covalent interactions, Selectivity, Amination

Abstract

The formation of arene C-N bonds directly from C-H bonds is of great importance and there has been rapid recent development of methods for achieving this through radical mechanisms, often involving reactive N-centered radicals. A major challenge associated with these advances is that of regiocontrol, with mixtures of regioisomeric products obtained in most protocols, limiting broader utility. We have designed a system that utilizes attractive noncovalent interactions between an anionic substrate and an incoming radical cation in order to guide the latter to the arene ortho position. The anionic substrate takes the form of a sulfamate-protected aniline and telescoped cleavage of the sulfamate group after amination leads directly to ortho-phenylenediamines, key building blocks for a range of medicinally relevant diazoles. Our method can deliver both free amines and monoalkyl amines allowing access to unsymmetrical, selectively monoalkylated benzimidazoles and benzotriazoles. As well as providing concise access to valuable ortho-phenylenediamines, this work demonstrates the potential for utilizing noncovalent interactions to control positional selectivity in radical reactions.

Published

2021

8. An Enantioselective Suzuki-Miyaura Coupling To Form Axially Chiral Biphenols

Author

Pearce-Higgins, Robert, Hogenhout, Larissa N, Docherty, Philip J, Whalley, David M, Chuentragool, Padon, Lee, Najung, Lam, Nelson YS, McGuire, Thomas M, Valette, Damien, Phipps, Robert J, Chuentragool, Padon [0000-0002-7466-8455], Lam, Nelson YS [0000-0002-9307-0619], Valette, Damien [0000-0002-1620-3502], Phipps, Robert J [0000-0002-7383-5469], and Apollo - University of Cambridge Repository

Subjects

Stereoisomerism, Ligands, Catalysis

Abstract

Funder: Engineering and Physical Sciences Research Council, Funder: GlaxoSmithKline, Funder: Trinity Hall College, University of Cambridge, Funder: AstraZeneca, Axial chirality features prominently in molecules of biological interest as well as chiral catalyst designs, and atropisomeric 2,2'-biphenols are particularly prevalent. Atroposelective metal-catalyzed cross-coupling is an attractive and modular approach to access enantioenriched biphenols, and yet existing protocols cannot achieve this directly. We address this challenge through the use of enantiopure, sulfonated SPhos (sSPhos), an existing ligand that has until now been used only in racemic form and that derives its chirality from an atropisomeric axis that is introduced through sulfonation. We believe that attractive noncovalent interactions involving the ligand sulfonate group are responsible for the high levels of asymmetric induction that we obtain in the 2,2'-biphenol products of Suzuki-Miyaura coupling, and we have developed a highly practical resolution of sSPhos via diastereomeric salt recrystallization.

Published

2022

9. Hydrogen Atom Transfer-Driven Enantioselective Minisci Reaction of Amides

Author

Robert J. Phipps, Rupert S. J. Proctor, Padon Chuentragool, Avene C. Colgan, Proctor, Rupert SJ [0000-0002-2296-448X], Colgan, Avene C [0000-0003-3842-6077], Phipps, Robert J [0000-0002-7383-5469], and Apollo - University of Cambridge Repository

Subjects

34 Chemical Sciences, Communication, Enantioselective synthesis, 3405 Organic Chemistry, General Chemistry, Hydrogen atom, 010402 general chemistry, 01 natural sciences, Biochemistry, Combinatorial chemistry, Catalysis, 0104 chemical sciences, 3. Good health, Stereocenter, 3402 Inorganic Chemistry, chemistry.chemical_compound, Colloid and Surface Chemistry, chemistry, Reagent, Amide, Oxidative coupling of methane, Minisci reaction

Abstract

Minisci-type reactions constitute one of the most powerful methods for building up complexity around basic heteroarenes. The most desirable variants involve formal oxidative coupling of a C-H bond on each partner, leading back to the simplest possible starting materials. We herein disclose a method that enables such a coupling of linear amides and heteroarenes with full control of enantioselectivity at the newly formed stereocenter as well as site selectivity on both the heteroarene and the amide. This is achieved by the use of a chiral phosphoric acid catalyst in conjunction with diacetyl as a combined hydrogen atom transfer reagent and oxidant. Diacetyl is directly photoexcitable, and thus, no extraneous photocatalyst is required: an added feature that contributes to the simplicity and practicality of the protocol.

Published

2021

10. Enantioselective Intermolecular C-H Amination Directed by a Chiral Cation

Author

Fanourakis, Alexander, Williams, Benjamin D, Paterson, Kieran J, Phipps, Robert J, Phipps, Robert J [0000-0002-7383-5469], and Apollo - University of Cambridge Repository

Subjects

inorganic chemicals, 3402 Inorganic Chemistry, 34 Chemical Sciences, organic chemicals, heterocyclic compounds, 3405 Organic Chemistry

Abstract

The enantioselective amination of C(sp3)-H bonds is a powerful synthetic transformation yet highly challenging to achieve in an intermolecular sense. We have developed a family of anionic variants of the best-in-class catalyst for Rh-catalyzed C-H amination, Rh2(esp)2, with which we have associated chiral cations derived from quaternized cinchona alkaloids. These ion-paired catalysts enable high levels of enantioselectivity to be achieved in the benzylic C-H amination of substrates bearing pendant hydroxyl groups. Additionally, the quinoline of the chiral cation appears to engage in axial ligation to the rhodium complex, providing improved yields of product versus Rh2(esp)2 and highlighting the dual role that the cation is playing. These results underline the potential of using chiral cations to control enantioselectivity in challenging transition-metal-catalyzed transformations.

Published

2021

11. Electrostatically-directed Pd-catalysis in combination with C-H activation: site-selective coupling of remote chlorides with fluoroarenes and fluoroheteroarenes

Author

Robert J. Phipps, William A. Golding, Golding, William A [0000-0001-6956-4961], Phipps, Robert J [0000-0002-7383-5469], and Apollo - University of Cambridge Repository

Subjects

inorganic chemicals, 34 Chemical Sciences, 010405 organic chemistry, Metalation, chemistry.chemical_element, 3405 Organic Chemistry, General Chemistry, 010402 general chemistry, 01 natural sciences, Oxidative addition, Combinatorial chemistry, 0104 chemical sciences, 3. Good health, Catalysis, Rhodium, 3402 Inorganic Chemistry, Metal, Chemistry, chemistry, visual_art, visual_art.visual_art_medium, Iridium, Selectivity, Palladium

Abstract

Systems incorporating catalyst–substrate non-covalent interactions are emerging as a versatile approach to address site-selectivity challenges in remote functionalization reactions. Given the achievements that have been made in this regard using metals such as iridium, manganese and rhodium, it is surprising that non-covalent catalyst direction has not been utilized in reactions incorporating palladium-catalyzed C–H activation steps, despite palladium being arguably the most versatile metal for C–H activation. Herein, we demonstrate that electrostatically directed, site-selective C–Cl oxidative addition is compatible with a subsequent C–H activation step, proceeding via a concerted metalation deprotonation-type mechanism. This results in site-selective cross-coupling of dichloroarenes with fluoroarenes and fluoroheteroarenes, with selectivity controlled by catalyst structure. This study demonstrates that Pd-catalyzed C–H activation can be used productively in combination with a non-covalently-directed mode of catalysis, with important implications in both fields., Electrostatically-directed oxidative addition is compatible with a subsequent C–H activation step, enabling site-selective coupling of remote chlorides with fluoroarenes and fluoroheteroarenes.

Published

2021

12. Systematic Variation of Ligand and Cation Parameters Enables Site-Selective C-C and C-N Cross-Coupling of Multiply Chlorinated Arenes through Substrate-Ligand Electrostatic Interactions

Author

Golding, William A, Schmitt, Hendrik L, Phipps, Robert J, Phipps, Robert J [0000-0002-7383-5469], and Apollo - University of Cambridge Repository

Subjects

34 Chemical Sciences, 3405 Organic Chemistry

Abstract

Use of attractive noncovalent interactions between ligand and substrate is an emerging strategy for controlling positional selectivity. A key question relates to whether fine control on molecules with multiple, closely spaced reactive positions is achievable using typically less directional electrostatic interactions. Herein, we apply a 10-piece "toolkit" comprising of two closely related sulfonated phosphine ligands and five bases, each possessing varying cation size, to the challenge of site-selective cross-coupling of multiply chlorinated arenes. The fine tuning provided by these ligand/base combinations is effective for Suzuki-Miyaura coupling and Buchwald-Hartwig coupling on a range of isomeric dichlorinated and trichlorinated arenes, substrates that would produce intractable mixtures when typical ligands are used. This study develops a practical solution for site-selective cross-coupling to generate complex, highly substituted arenes.

Published

2020

13. Harnessing non-covalent interactions to exert control over regioselectivity and site-selectivity in catalytic reactions

Author

Robert J. Phipps, Holly J. Davis, Phipps, Robert J [0000-0002-7383-5469], and Apollo - University of Cambridge Repository

Subjects

0306 Physical Chemistry (incl. Structural), chemistry.chemical_classification, 010405 organic chemistry, Hydrogen bond, Enantioselective synthesis, Regioselectivity, Context (language use), Nanotechnology, General Chemistry, 010402 general chemistry, 0305 Organic Chemistry, 01 natural sciences, Small molecule, 0104 chemical sciences, Catalysis, Chemistry, chemistry, 0302 Inorganic Chemistry, Non-covalent interactions, Selectivity

Abstract

This perspective examines the progress that has been made in using non-covalent interactions to control regioselectivity and site-selectivity in catalysis., Asymmetric catalysis has been revolutionised by the realisation that attractive non-covalent interactions such as hydrogen bonds and ion pairs can act as powerful controllers of enantioselectivity when incorporated into appropriate small molecule chiral scaffolds. Given these tremendous advances it is surprising that there are still a relatively limited number of examples of non-covalent interactions being harnessed for control of regioselectivity or site-selectivity in catalysis, two other fundamental selectivity aspects facing the synthetic chemist. This perspective examines the progress that has been made in this area thus far using non-covalent interactions in conjunction with transition metal catalysis as well as in the context of purely organic catalysts. We hope this will highlight the great potential in this approach for designing selective catalytic reactions.

Published

2017

14. Recent Advances in Minisci-Type Reactions

Author

Proctor, Rupert SJ, Phipps, Robert J, Phipps, Robert J [0000-0002-7383-5469], and Apollo - University of Cambridge Repository

Subjects

C−H functionalization, heterocycles, Minisci reaction, radicals

Abstract

Reactions that involve the addition of carbon-centered radicals to basic heteroarenes, followed by formal hydrogen atom loss, have become widely known as Minisci-type reactions. First developed into a useful synthetic tool in the late 1960s by Minisci, this reaction type has been in constant use over the last half century by chemists seeking to functionalize heterocycles in a rapid and direct manner, avoiding the need for de novo heterocycle synthesis. Whilst the originally developed protocols for radical generation remain in active use today, they have been joined in recent years by a new array of radical generation strategies that allow use of a wider variety of radical precursors that often operate under milder and more benign conditions. The recent surge of interest in new transformations based on free radical reactivity has meant that numerous choices are now available to a synthetic chemist looking to utilize a Minisci-type reaction. Radical-generation methods based on photoredox catalysis and electrochemistry have joined approaches which utilize thermal cleavage or the in situ generation of reactive radical precursors. This review will cover the remarkably large body of literature that has appeared on this topic over the last decade in an attempt to provide guidance to the synthetic chemist, as well as a perspective on both the challenges that have been overcome and those that still remain. As well as the logical classification of advances based on the nature of the radical precursor, with which most advances have been concerned, recent advances in control of various selectivity aspects associated with Minisci-type reactions will also be discussed.

Published

2019

15. Para-Selective C-H Borylation of Common Arene Building Blocks Enabled by Ion-Pairing with a Bulky Countercation

Author

Madalina T. Mihai, Robert J. Phipps, Benjamin D Williams, Phipps, Robert J [0000-0002-7383-5469], and Apollo - University of Cambridge Repository

Subjects

34 Chemical Sciences, Chemistry, Ion pairing, Communication, 3405 Organic Chemistry, General Chemistry, 010402 general chemistry, 01 natural sciences, Biochemistry, Borylation, Combinatorial chemistry, Catalysis, 3. Good health, 0104 chemical sciences, 3402 Inorganic Chemistry, Para position, Colloid and Surface Chemistry, Transition metal, 13. Climate action, Substrate specificity, Surface modification

Abstract

The selective functionalization of C-H bonds at the arene para position is highly challenging using transition metal catalysis. Iridium-catalyzed borylation has emerged as a leading technique for arene functionalization, but there are only a handful of strategies for para-selective borylation, which operate on specific substrate classes and use bespoke ligands or catalysts. We describe a remarkably general protocol which results in para-selectivity on some of the most common arene building blocks (anilines, benzylamines, phenols, benzyl alcohols) and uses standard borylation ligands. Our strategy hinges upon the facile conversion of the substrates into sulfate or sulfamate salts, wherein the anionic arene component is paired with a tetrabutylammonium cation. We hypothesize that the bulk of this cation disfavors meta-C-H borylation, thereby promoting the challenging para-selective reaction.

Published

2019

16. Ion-Pair-Directed Borylation of Aromatic Phosphonium Salts

Author

Madalina T. Mihai, Robert J. Phipps, Bernadette Lee, Violeta Stojalnikova, Phipps, Robert J [0000-0002-7383-5469], and Apollo - University of Cambridge Repository

Subjects

0306 Physical Chemistry (incl. Structural), 010405 organic chemistry, Chemistry, Organic Chemistry, Ion pairs, 010402 general chemistry, Note, 01 natural sciences, Borylation, Combinatorial chemistry, 3. Good health, 0104 chemical sciences, Catalysis, chemistry.chemical_compound, Phosphonium, Selectivity

Abstract

Control of positional selectivity in C–H activation reactions remains a challenge for synthetic chemists. Noncovalent catalysis has the potential to be a powerful strategy to address this challenge. As a part of our ongoing investigations into the use of ion-pairing interactions in site-selective catalysis, we demonstrate that several classes of aromatic phosphonium salts undergo iridium-catalyzed C–H borylation with a high selectivity for the arene meta position. This is achieved using a bifunctional bipyridine ligand bearing a pendant sulfonate group, which had previously been successful for borylation of aromatic ammonium salts. In this case, the phosphonium salts give a higher meta selectivity than the corresponding ammonium salts. We propose that the high selectivity occurs due to an attractive electrostatic interaction between the substrate and the ligand in the transition state for borylation.

Published

2019

17. Catalytic enantioselective Minisci-type addition to heteroarenes

Author

Proctor, Rupert SJ, Davis, Holly J, Phipps, Robert J, Proctor, Rupert SJ [0000-0002-2296-448X], Davis, Holly J [0000-0003-3968-9311], Phipps, Robert J [0000-0002-7383-5469], and Apollo - University of Cambridge Repository

Subjects

0306 Physical Chemistry (incl. Structural)

Abstract

Basic heteroarenes are a ubiquitous feature of pharmaceuticals and bioactive molecules, and Minisci-type additions of radical nucleophiles are a leading method for their elaboration. Despite many Minisci-type protocols that result in the formation of stereocenters, exerting control over the absolute stereochemistry at these centers remains an unmet challenge. We report a process for addition of prochiral radicals, generated from amino acid derivatives, to pyridines and quinolines. Our method offers excellent control of both enantioselectivity and regioselectivity. An enantiopure chiral Brønsted acid catalyst serves both to activate the substrate and induce asymmetry, while an iridium photocatalyst mediates the required electron transfer processes. We anticipate that this method will expedite access to enantioenriched small-molecule building blocks bearing versatile basic heterocycles.

Published

2018

18. A Computational and Experimental Investigation of the Origin of Selectivity in the Chiral Phosphoric Acid Catalyzed Enantioselective Minisci Reaction

Author

Jonathan M. Goodman, Rupert S. J. Proctor, Robert J. Phipps, Kristaps Ermanis, Avene C. Colgan, Barbara W. Hadrys, Proctor, Rupert SJ [0000-0002-2296-448X], Phipps, Robert J [0000-0002-7383-5469], Goodman, Jonathan M [0000-0002-8693-9136], and Apollo - University of Cambridge Repository

Subjects

34 Chemical Sciences, Chemistry, Radical, Chiral ligand, Enantioselective synthesis, Regioselectivity, 3405 Organic Chemistry, General Chemistry, 010402 general chemistry, 01 natural sciences, Biochemistry, Combinatorial chemistry, Article, Catalysis, 0104 chemical sciences, 3. Good health, Stereocenter, 3402 Inorganic Chemistry, 3407 Theoretical and Computational Chemistry, Colloid and Surface Chemistry, Deprotonation, Radical ion, Minisci reaction

Abstract

The Minisci reaction is one of the most valuable methods for directly functionalizing basic heteroarenes to form carbon–carbon bonds. Use of prochiral, heteroatom-substituted radicals results in stereocenters being formed adjacent to the heteroaromatic system, generating motifs which are valuable in medicinal chemistry and chiral ligand design. Recently a highly enantioselective and regioselective protocol for the Minisci reaction was developed, using chiral phosphoric acid catalysis. However, the precise mechanism by which this process operated and the origin of selectivity remained unclear, making it challenging to develop the reaction more generally. Herein we report further experimental mechanistic studies which feed into detailed DFT calculations that probe the precise nature of the stereochemistry-determining step. Computational and experimental evidence together support Curtin–Hammett control in this reaction, with initial radical addition being quick and reversible, and enantioselectivity being achieved in the subsequent slower, irreversible deprotonation. A detailed survey via DFT calculations assessed a number of different possibilities for selectivity-determining deprotonation of the radical cation intermediate. Computations point to a clear preference for an initially unexpected mode of internal deprotonation enacted by the amide group, which is a crucial structural feature of the radical precursor, with the assistance of the associated chiral phosphate. This unconventional stereodetermining step underpins the high enantioselectivities and regioselectivities observed. The mechanistic model was further validated by applying it to a test set of substrates possessing varied structural features.

19. Hydrogen Atom Transfer Driven Enantioselective Minisci Reaction of Alcohols

Author

Avene C. Colgan, Rupert S. J. Proctor, David C. Gibson, Padon Chuentragool, Antti S. K. Lahdenperä, Kristaps Ermanis, Robert J. Phipps, Proctor, Rupert SJ [0000-0002-2296-448X], Ermanis, Kristaps [0000-0001-9703-8758], Phipps, Robert J [0000-0002-7383-5469], and Apollo - University of Cambridge Repository

Subjects

Asymmetric Catalysis, 34 Chemical Sciences, Organocatalysis, 3405 Organic Chemistry, Stereoisomerism, General Medicine, General Chemistry, Heterocycles, Amides, Chiral Phosphoric Acids, Catalysis, 3402 Inorganic Chemistry, Alcohols, 3406 Physical Chemistry, Minisci Reaction, Hydrogen

Abstract

Catalytic enantioselective Minisci reactions have recently been developed but all instances so far utilize α‐amino radical coupling partners. We report a substantial evolution of the enantioselective Minisci reaction that enables α‐hydroxy radicals to be used, providing valuable enantioenriched secondary alcohol products. This is achieved through the direct oxidative coupling of two C−H bonds on simple alcohol and pyridine partners through a hydrogen atom transfer (HAT)‐driven approach: a challenging process to achieve due to the numerous side reactions that can occur. Our approach is highly regioselective as well as highly enantioselective. Dicumyl peroxide, upon irradiation with 390 nm light, serves as both HAT reagent and oxidant whilst selectivity is controlled by use of a chiral phosphoric acid catalyst. Computational and experimental evidence provide mechanistic insight as to the origin of selectivity, revealing a stereodetermining deprotonation step distinct from the analogous reaction of amide‐containing substrates.