Oxidative Halogenation with “Green” Oxidants: Oxygen and Hydrogen Peroxide

Podgoršek, Ajda; Zupan, Marko; Iskra, Jernej

doi:10.1002/anie.200901223

Cited by 391 publications

(221 citation statements)

References 175 publications

(213 reference statements)

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“…1 Furthermore, these molecules find applications in the field of materials science, pharmaceuticals, agrochemicals and bioactive compounds. 2 In a general sense, halogenation is an oxidative process carried out efficiently in nature through enzyme-catalysed reactions where a halide ion is transformed into a halogenating intermediate.…”

Section: Introductionmentioning

confidence: 99%

“…5c, 7a As a logical development, we decided to explore this procedure also for functionalization of toluene at the benzylic position. Bromination in the side chain of aromatic derivatives has been performed with several acid systems containing bromide and an oxidant, 1,8 eventually in the presence of light. 8 Also some dibromo disulfonamides have been proposed as effective brominating agents for toluene.…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

A sustainable two-phase procedure for V-catalyzed toluene oxidative bromination with H2O2–KBr

2013

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A sustainable V(V) and Mo(VI) catalysed two-phase procedure for bromination of toluene under quite mild conditions is proposed; H 2 O 2 is the primary oxidant and KBr is the bromine source; metal precursors are commercially available salts. The reaction is efficient without any additional solvent. By using PhCH 3 as a solvent/substrate good yields, together with interesting selectivity toward the formation of PhCH 2 Br, are obtained with both metal ions. Recycling of the catalytic phase is also possible. Useful information on the V-peroxido chemistry was obtained.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

A sustainable two-phase procedure for V-catalyzed toluene oxidative bromination with H2O2–KBr

2013

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“…Organic bromo-derivatives are important precursors for various selective and efficient transformations in organic synthesis, as industrial intermediates and pharmaceuticals. Hazards and environmental problems correlated with classical bromination methods have encouraged the attention towards the development of safer and environmentally friendlier methods [55]. In this contest vanadium haloperoxidases (VHPOs), which have been isolated mainly from marine algae and fungi, have received much attention because they are able to catalyze the oxidation of halides to the corresponding hypohalous acid using hydrogen peroxide as primary oxidant [56].…”

Section: Haloperoxidationsmentioning

confidence: 99%

Recent advances in vanadium catalyzed oxygen transfer reactions

Licini

Conte

Coletti

et al. 2011

Coordination Chemistry Reviews

162

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Vanadium complexes have proven to be effective catalysts for the activation of peroxides and the selective oxidation of substrates like bromides, sulfides and alkenes. Besides their capability to form metalloperoxo species, which effectively transfer oxygen atoms to the substrate, these systems are synthetically useful for obtaining valuable oxidized molecules on a preparative scale, with a high degree of selectivity and TONs. Furthermore, the use of environmentally friendly oxidants like hydrogen and alkyl hydroperoxides increases significantly their potential application at an industrial level. Here we report a critical survey on the most effective homogeneous vanadium catalysts reported in the last decade concerning their synthetic application in oxygen transfer reactions (sulfoxidation, epoxidation, haloperoxidation) using hydrogen peroxide or alkyl hydroperoxides, demonstrating the different classes of ligands and complexes, their catalytic performances, their reactivity, chemo, stereo and substrate selectivity. Some examples of the use of non conventional reaction media or techniques and catalyst recycling studies will be also discussed

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“…[5] Oxidative methods to catalytically generate halogenating agents from halide salts have been developed, but none of these have solved the aforementioned selectivity problem, and few utilize oxygen as a terminal oxidant (Scheme 1). [6] New, more efficient methods for oxidative halogenation would significantly improve the syntheses of a wide range of chemicals and are therefore highly desirable. [6] Given the high efficiency and selectivity often associated with enzyme-catalyzed reactions, we were drawn to several classes of enzymes that catalyze oxidative halogenation reactions.…”

Section: Introductionmentioning

confidence: 99%

“…[6] New, more efficient methods for oxidative halogenation would significantly improve the syntheses of a wide range of chemicals and are therefore highly desirable. [6] Given the high efficiency and selectivity often associated with enzyme-catalyzed reactions, we were drawn to several classes of enzymes that catalyze oxidative halogenation reactions. [7] Particularly notable in this regard are the FAD-dependent halogenases, which were first characterized by van Pée and coworkers in the late 1990's.…”

Section: Introductionmentioning

confidence: 99%

Regioselective Arene Halogenation using the FAD‐Dependent Halogenase RebH

2013

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Co-expression of the halogenase RebH with GroEL/ES and fusion of the flavin reductase RebF to MBP enabled production of both enzymes on scales sufficient for preparative regioselective oxidative halogenation of arenes. The activity and selectivity of RebH contrast with those reported for PrnA, a structurally homologous halogenase, which provided a narrower substrate scope and only enabled halogenation of unnatural substrates at their most electronically activated positions. KeywordsRebH; halogenase; regioselective; biocatalysis Halogenated organic compounds are essential building blocks for chemical synthesis [1] and play important roles as pharmaceuticals [2] and agrochemicals [3] . Despite the utility of these compounds, installing halogen atoms frequently necessitates the use of activated or prefunctionalized starting materials and wasteful multistep functional group conversion sequences. [4] Arene halogenation via electrophilic aromatic substitution (EAS) requires harsh reaction conditions using stoichiometric reagents and suffers from poor regioselectivity in many cases. [5] Oxidative methods to catalytically generate halogenating agents from halide salts have been developed, but none of these have solved the aforementioned selectivity problem, and few utilize oxygen as a terminal oxidant (Scheme 1). [6] New, more efficient methods for oxidative halogenation would significantly improve the syntheses of a wide range of chemicals and are therefore highly desirable. [6] Given the high efficiency and selectivity often associated with enzyme-catalyzed reactions, we were drawn to several classes of enzymes that catalyze oxidative halogenation reactions. [7] Particularly notable in this regard are the FAD-dependent halogenases, which were first characterized by van Pée and coworkers in the late 1990's. [8] Extensive mechanistic investigation of these enzymes by both van Pée and Walsh, focusing predominately on tryptophan halogenases, has clarified their mechanism. [9] In short, they utilize FADH 2 supplied by a NAD-dependent Correspondence to: Jared C. Lewis, jaredlewis@uchicago.edu. Supporting information, including full experimental procedures, for this article is available on the WWW under http:// www.angewandte.org or from the author. While FAD-dependent halogenases thus have the potential to improve a number of problems with current oxidative halogenation methods, they remain largely unexplored for preparative synthesis. Characterization of their activity in vitro has typically involved analytical scale reactions of tryptophan, [9] but van Pée and coworkers also explored the substrate scope of the tryptophan-7-halogenase PrnA expressed in Pseudomonas fluorescens (Scheme 2). [11] A variety of substituted indoles were accepted by the enzyme, but halogenation invariably occurred at the electronically most activated indole 2-position for all substrates except tryptophan. These same researchers were able to alter the selectivity of PrnA to produce 5-chloro-and 5-bromotryptophan by mutating a single acti...

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Oxidative Halogenation with “Green” Oxidants: Oxygen and Hydrogen Peroxide

Cited by 391 publications

References 175 publications

A sustainable two-phase procedure for V-catalyzed toluene oxidative bromination with H2O2–KBr

A sustainable two-phase procedure for V-catalyzed toluene oxidative bromination with H2O2–KBr

Recent advances in vanadium catalyzed oxygen transfer reactions

Regioselective Arene Halogenation using the FAD‐Dependent Halogenase RebH

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