Andrew J. A. Watson scite author profile

The alkylation of amines by alcohols has been achieved using 0.5 mol % [Ru(p-cymene)Cl(2)](2) with the bidentate phosphines dppf or DPEphos as the catalyst. Primary amines have been converted into secondary amines, and secondary amines into tertiary amines, including the syntheses of Piribedil, Tripelennamine, and Chlorpheniramine. N-Heterocyclization reactions of primary amines are reported, as well as alkylation reactions of primary sulfonamides. Secondary alcohols require more forcing conditions than primary alcohols but are still effective alkylating agents in the presence of this catalyst.

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The Give and Take of Alcohol Activation

Watson

Williams

2010

Science

607

199

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Borrowing Hydrogen Methodology for Amine Synthesis under Solvent-Free Microwave Conditions

2011

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Ruthenium-Catalyzed Oxidation of Alcohols into Amides

2009

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Protecting‐Group‐Free One‐Pot Synthesis of Glycoconjugates Directly from Reducing Sugars

et al. 2014

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The conversion of sugars into glycomimetics typically involves multiple protecting-group manipulations. The development of methodology allowing the direct aqueous conversion of free sugars into glycosides, and mimics of oligosaccharides and glycoconjugates in a high-yielding and stereoselective process is highly desirable. The combined use of 2-azido-1,3-dimethylimidazolinium hexafluorophosphate and the Cu-catalyzed Huisgen cycloaddition allowed the synthesis of a range of glycoconjugates in a one-step reaction directly from reducing sugars under aqueous conditions. The reaction, which is completely stereoselective, may be applied to the convergent synthesis of triazole-linked glycosides, oligosaccharides, and glycopeptides. The procedure provides a method for the one-pot aqueous ligation of oligosaccharides and peptides bearing alkyne side chains.

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Achiral 2-Hydroxy Protecting Group for the Stereocontrolled Synthesis of 1,2-cis-α-Glycosides by Six-Ring Neighboring Group Participation

2015

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Glycosylation of a fully armed donor bearing a 2-O-(trimethoxybenzenethiol) ethyl ether protecting group is completely α-selective with a range of carbohydrate alcohol acceptors. Low-temperature NMR studies confirm the intermediacy of cyclic sulfonium ion intermediates arising from six-membered β-sulfonium ring neighboring group participation. Selective protecting group removal is achieved in high yield in a single operation by S-methylation and base-induced β-elimination.

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Neighbouring Group Participation During Glycosylation: Do 2‐Substituted Ethyl Ethers Participate?

et al. 2014

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The development of new protecting groups that undergo neighbouring group participation (NGP) via six‐membered ring intermediates to promote the formation of α‐1,2‐cis glycosidic linkages complements the established use of 5‐ring NGP in terms of stereochemical outcome. A selection of glycosyl donors was synthesised that possessed novel 2‐iodo‐ and 2‐(phenylseleno)ethyl ether protecting groups in an attempt to promote highly α‐selective glycosylation by 6‐ring NGP. Although the fully armed donors produced α‐glucosides as the predominant reaction products, low‐temperature NMR studies did not show NGP by the observation of cyclised reaction intermediates. The corresponding disarmed glycosyl donors were unexpectedly less stereoselective. NMR spectroscopy revealed that the 2‐iodoethyl ether did not participate in any of the glycosylation processes; however, the 2‐(phenylseleno)ethyl ether did participate, and β‐configured cyclic intermediates were observed. The fact that considerable amounts of β‐glycoside product were formed in these latter cases indicated that the predominant reaction pathway to product did not occur through the observed cyclic species. Clearly, a fine balance exists during glycosylation reactions, and the reaction pathway to product depends on a variety of factors. Notably, the formation of cyclised intermediates by 6‐ring NGP is not on its own sufficient to ensure high levels of α‐stereoselectivity.

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Ruthenium-catalysed oxidative synthesis of heterocycles from alcohols

2012

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Andrew J. A. Watson

Ruthenium-Catalyzed N-Alkylation of Amines and Sulfonamides Using Borrowing Hydrogen Methodology

The Give and Take of Alcohol Activation

Borrowing Hydrogen Methodology for Amine Synthesis under Solvent-Free Microwave Conditions

Ruthenium-Catalyzed Oxidation of Alcohols into Amides

Protecting‐Group‐Free One‐Pot Synthesis of Glycoconjugates Directly from Reducing Sugars

Achiral 2-Hydroxy Protecting Group for the Stereocontrolled Synthesis of 1,2-cis-α-Glycosides by Six-Ring Neighboring Group Participation

Neighbouring Group Participation During Glycosylation: Do 2‐Substituted Ethyl Ethers Participate?

Ruthenium-catalysed oxidative synthesis of heterocycles from alcohols

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