A mechanistic study on the Hooker oxidation: synthesis of novel indane carboxylic acid derivatives from lapachol

The Hooker oxidation is one of the most intriguing transformations wherein lapachol (1) is readily converted to norlapachol (2) in very good yield. This one-pot reaction involves a very intricate mechanism in which the alkyl side chain of lapachol is shortened by one carbon unit. Previous studies ha...

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Veröffentlicht in:	Organic & biomolecular chemistry 2013-01, Vol.11 (3), p.459-468
Hauptverfasser:	Eyong, Kenneth O, Puppala, Manohar, Kumar, Ponminor Senthil, Lamshöft, Marc, Folefoc, Gabriel N, Spiteller, Michael, Baskaran, Sundarababu
Format:	Artikel
Sprache:	eng
Schlagworte:	Carboxylic Acids - chemical synthesis Carboxylic Acids - chemistry Indans - chemical synthesis Indans - chemistry Models, Molecular Molecular Structure Naphthoquinones - chemistry Oxidation-Reduction
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container_title	Organic & biomolecular chemistry
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creator	Eyong, Kenneth O Puppala, Manohar Kumar, Ponminor Senthil Lamshöft, Marc Folefoc, Gabriel N Spiteller, Michael Baskaran, Sundarababu
description	The Hooker oxidation is one of the most intriguing transformations wherein lapachol (1) is readily converted to norlapachol (2) in very good yield. This one-pot reaction involves a very intricate mechanism in which the alkyl side chain of lapachol is shortened by one carbon unit. Previous studies have unequivocally established the involvement of an indane carboxylic acid derivative 3, as a key intermediate (Hooker intermediate), and its simultaneous conversion to norlapachol (2) via the oxidative cleavage of vicinol diol and subsequent intramolecular aldol reaction of the resulting keto acid. However, the formation of the key Hooker intermediate 3 from lapachol (1) remains ambiguous. The present study has thrown some light on the formation of the key intermediate 3 from lapachol (1) via benzilic acid rearrangement of the corresponding labile o-diquinone intermediate 8 derived from lapachol. The involvement of o-diquinone intermediate 8 in the Hooker oxidation has been further established by trapping of this labile intermediate as the corresponding phenazine derivative 9. The involvement of benzilic acid rearrangement as a key step in the Hooker oxidation is further shown with a variety of o-quinones prepared from lapachol (1).
doi_str_mv	10.1039/c2ob26737c
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source	MEDLINE; Royal Society Of Chemistry Journals 2008-; Alma/SFX Local Collection
subjects	Carboxylic Acids - chemical synthesis Carboxylic Acids - chemistry Indans - chemical synthesis Indans - chemistry Models, Molecular Molecular Structure Naphthoquinones - chemistry Oxidation-Reduction
title	A mechanistic study on the Hooker oxidation: synthesis of novel indane carboxylic acid derivatives from lapachol
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