A Cooperative Hydrogen Bond Donor–Brønsted Acid System for the Enantioselective Synthesis of Tetrahydropyrans

Carbocations stabilized by adjacent oxygen atoms are useful reactive intermediates involved in fundamental chemical transformations. These oxocarbenium ions typically lack sufficient electron density to engage established chiral Brønsted or Lewis acid catalysts, presenting a major challenge to their...

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Veröffentlicht in:	Angewandte Chemie 2018-12, Vol.130 (52), p.17471-17475
Hauptverfasser:	Maskeri, Mark A., O'Connor, Matthew J., Jaworski, Ashley A., Davies, Anna V., Scheidt, Karl A.
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Sprache:	eng
Schlagworte:	Catalysis Catalysts Chemistry Chirale Phosphorsäuren Electron density Enantiomers Hydrogen bonds Intermediates Ions Kooperative Katalyse Lewis acid Organic chemistry Oxocarbeniumionen Oxygen atoms Selectivity Tetrahydropyrane Transformations Wasserstoffbrücken
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container_title	Angewandte Chemie
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creator	Maskeri, Mark A. O'Connor, Matthew J. Jaworski, Ashley A. Davies, Anna V. Scheidt, Karl A.
description	Carbocations stabilized by adjacent oxygen atoms are useful reactive intermediates involved in fundamental chemical transformations. These oxocarbenium ions typically lack sufficient electron density to engage established chiral Brønsted or Lewis acid catalysts, presenting a major challenge to their widespread application in asymmetric catalysis. Leading methods for selectivity operate primarily through electrostatic pairing between the oxocarbenium ion and a chiral counterion. A general approach to new enantioselective transformations of oxocarbenium ions requires novel strategies that address the weak binding capabilities of these intermediates. We demonstrate herein a novel cooperative catalysis system for selective reactions with oxocarbenium ions. This new strategy has been applied to a highly selective and rapid oxa‐Pictet–Spengler reaction and highlights a powerful combination of an achiral hydrogen bond donor with a chiral Brønsted acid. Ein kooperatives Katalyseverfahren für asymmetrische Oxa‐Pictet‐Spengler‐Reaktionen wurde entwickelt und zur Synthese substituierter Tetrahydropyranoindole genutzt. Auf diesem Weg gelang die asymmetrische Synthese von (−)‐Coixspirolactam C in sechs Stufen.
doi_str_mv	10.1002/ange.201811383
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subjects	Catalysis Catalysts Chemistry Chirale Phosphorsäuren Electron density Enantiomers Hydrogen bonds Intermediates Ions Kooperative Katalyse Lewis acid Organic chemistry Oxocarbeniumionen Oxygen atoms Selectivity Tetrahydropyrane Transformations Wasserstoffbrücken
title	A Cooperative Hydrogen Bond Donor–Brønsted Acid System for the Enantioselective Synthesis of Tetrahydropyrans
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