The expanding utility of continuous flow hydrogenation

Peter J. Cossar; Lacey Hizartzidis; Michela I. Simone; Adam McCluskey; Christopher P. Gordon

doi:10.1039/c5ob01067e

The expanding utility of continuous flow hydrogenation

Peter J. Cossar, Lacey Hizartzidis, Michela I. Simone, Adam McCluskey, Christopher P. Gordon (Lead / Corresponding author)

Centre for Targeted Protein Degradation

Research output: Contribution to journal › Article › peer-review

120 Citations (Scopus)

Abstract

There has been an increasing body of evidence that flow hydrogenation enhances reduction outcomes across a wide range of synthetic transformations. Moreover flow reactors enhance laboratory safety with pyrophoric catalysts contained in sealed cartridges and hydrogen generated in situ from water. This mini-review focuses on recent applications of flow chemistry to mediate nitro, imine, nitrile, amide, azide, and azo reductions. Methodologies to effect de-aromatisation, hydrodehalogenation, in addition to olefin, alkyne, carbonyl, and benzyl reductions are also examined. Further, protocols to effect chemoselective reductions and enantioselective reductions are highlighted. Together these applications demonstrate the numerous advantages of performing hydrogenation under flow conditions which include enhanced reaction throughput, yields, simplified workup, and the potential applicability to multistep and cascade synthetic protocols.

Original language	English
Pages (from-to)	7119-7130
Number of pages	12
Journal	Organic and Biomolecular Chemistry
Volume	13
Issue number	26
Early online date	9 Jun 2015
DOIs	https://doi.org/10.1039/c5ob01067e
Publication status	Published - 14 Jul 2015

ASJC Scopus subject areas

Biochemistry
Physical and Theoretical Chemistry
Organic Chemistry

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abstract = "There has been an increasing body of evidence that flow hydrogenation enhances reduction outcomes across a wide range of synthetic transformations. Moreover flow reactors enhance laboratory safety with pyrophoric catalysts contained in sealed cartridges and hydrogen generated in situ from water. This mini-review focuses on recent applications of flow chemistry to mediate nitro, imine, nitrile, amide, azide, and azo reductions. Methodologies to effect de-aromatisation, hydrodehalogenation, in addition to olefin, alkyne, carbonyl, and benzyl reductions are also examined. Further, protocols to effect chemoselective reductions and enantioselective reductions are highlighted. Together these applications demonstrate the numerous advantages of performing hydrogenation under flow conditions which include enhanced reaction throughput, yields, simplified workup, and the potential applicability to multistep and cascade synthetic protocols.",

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AB - There has been an increasing body of evidence that flow hydrogenation enhances reduction outcomes across a wide range of synthetic transformations. Moreover flow reactors enhance laboratory safety with pyrophoric catalysts contained in sealed cartridges and hydrogen generated in situ from water. This mini-review focuses on recent applications of flow chemistry to mediate nitro, imine, nitrile, amide, azide, and azo reductions. Methodologies to effect de-aromatisation, hydrodehalogenation, in addition to olefin, alkyne, carbonyl, and benzyl reductions are also examined. Further, protocols to effect chemoselective reductions and enantioselective reductions are highlighted. Together these applications demonstrate the numerous advantages of performing hydrogenation under flow conditions which include enhanced reaction throughput, yields, simplified workup, and the potential applicability to multistep and cascade synthetic protocols.

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The expanding utility of continuous flow hydrogenation

Abstract

ASJC Scopus subject areas

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