Reduction Of Aryl Ketones Research Articles

Modifying Proton Relay into Bioinspired Dye‐Based Coordination Polymer for Photocatalytic Proton‐Coupled Electron Transfer

AbstractProton‐coupled electron transfer (PCET) imparts an energetic advantage over single electron transfer in activating inert substances. Natural PCET enzyme catalysis generally requires tripartite preorganization of proton relay, substrate‐bound active center, and redox mediator, making the processes efficient and precluding side reactions. Inspired by this, a heterogeneous photocatalytic PCET system was established to achieve higher PCET driving forces by modifying proton relays into anthraquinone‐based anionic coordination polymers. The proximally separated proton relays and photoredox‐mediating anthraquinone moiety allowed pre‐assembly of inert substrate between them, merging proton and electron into unsaturated bonds by photoreductive PCET, which enhanced reaction kinetics compared with the counter catalyst without proton relay. This photocatalytic PCET method was applied to a broad‐scoped reduction of aryl ketones, unsaturated carbonyls, and aromatic compounds. The distinctive regioselectivities for the reduction of isoquinoline derivatives were found to occur on the carbon‐ring sides. PCET‐generated radical intermediate of quinoline could be trapped by alkene for proton relay‐assisted Minisci addition, forming the pharmaceutical aza‐acenaphthene scaffold within one step. When using heteroatom(X)−H/C−H compounds as proton‐electron donors, this protocol could activate these inert bonds through photooxidative PCET to afford radicals and trap them by electron‐deficient unsaturated compounds, furnishing the direct X−H/C−H functionalization.

Reduction of Aryl Ketones and Aldehydes to Hydrocarbons Catalyzed by Palladium/Carbon

Key words palladium catalysis - reduction - carbonyls - hydrocarbons

Base-free transfer hydrogenation of aryl-ketones, alkyl-ketones and alkenones catalyzed by an IrIIICp* complex bearing a triazenide ligand functionalized with pyrazole

An IrIIICp* complex (2) bearing a triazenide ligand functionalized with pyrazole was synthesized and fully characterized by spectroscopic methods and the structure confirmed by X-ray diffraction studies. The catalytic activity of 2 and the control complex 3, which lacks of pyrazole in its structure, was evaluated in the reduction of aryl-ketones, alkyl-ketones, α,β-unsaturated and γ,δ-unsaturated ketones. The catalytic system, using either 2 or 3, exhibited good to excellent selectivity when tested with ketones and alkenones at 90 °C in 2-propanol as hydrogen source under base-free conditions. Reactivity of 2 in 2-propanol and NaH gave a neutral metal hydride (4) while in the absence of base gave two major cationic hydrides species (5 and 6).

Asymmetric Reduction of Aryl Ketones by Whole Cells of Pichia etchellsii AS2.625 Using β-Cyclodextrin as an Additive

Asymmetric Reduction of Aryl Ketones by Whole Cells of <i>Pichia etchellsii</i> AS2.625 Using <i>β</i>-Cyclodextrin as an Additive

Highly selective anti-Prelog synthesis of optically active aryl alcohols by recombinant Escherichia coli expressing stereospecific alcohol dehydrogenase

ABSTRACTBiocatalytic asymmetric synthesis has been widely used for preparation of optically active chiral alcohols as the important intermediates and precursors of active pharmaceutical ingredients. However, the available whole-cell system involving anti-Prelog specific alcohol dehydrogenase is yet limited. A recombinant Escherichia coli system expressing anti-Prelog stereospecific alcohol dehydrogenase from Candida parapsilosis was established as a whole-cell system for catalyzing asymmetric reduction of aryl ketones to anti-Prelog configured alcohols. Using 2-hydroxyacetophenone as the substrate, reaction factors including pH, cell status, and substrate concentration had obvious impacts on the outcome of whole-cell biocatalysis, and xylose was found to be an available auxiliary substrate for intracellular cofactor regeneration, by which (S)-1-phenyl-1,2-ethanediol was achieved with an optical purity of 97%e.e. and yield of 89% under the substrate concentration of 5 g/L. Additionally, the feasibility of the recombinant cells toward different aryl ketones was investigated, and most of the corresponding chiral alcohol products were obtained with an optical purity over 95%e.e. Therefore, the whole-cell system involving recombinant stereospecific alcohol dehydrogenase was constructed as an efficient biocatalyst for highly enantioselective anti-Prelog synthesis of optically active aryl alcohols and would be promising in the pharmaceutical industry.

Uncatalyzed Hydrogen-Transfer Reductions of Aryl Ketones

A simple, convenient, and environmentally benign procedure has been developed for exclusive reduction of aryl ketones by hydrogen transfer with sec-BuOH as hydrogen donor in the presence of KOH without supercritical conditions, ligands, and any catalytic utility.

Impact of Substituents Attached to N‐Heterocyclic Carbenes on the Catalytic Activity of Copper Complexes in the Reduction of Carbonyl Compounds with Triethoxysilane

AbstractBy using functionalized imidazolium salts such as 1‐allyl‐3‐alkylimidazolium or 1‐alkyl‐3‐vinylimidazolium salts as carbene ligand precursors, the reduction of aryl ketones with triethoxysilane may be catalyzed by copper salt/imidazolium salt/KOtBu systems. The functional substituents attached to the N‐heterocyclic carbene (NHC) serve to enhance the catalytic activity. Different copper salts also have an effect on the catalytic activity, with copper(II) acetate monohydrate being superior to copper(I) chloride.

Enantioselective reduction of aryl ketones using immobilized cells of Candida viswanathii

Enantioselective reduction of 1-acetonapthone to S(−)-1-(1-naphthyl) ethanol, a key intermediate for the synthesis of HMG Co-A reductase inhibitor, was successfully carried out using immobilized cells of a newly isolated carbonyl reductase producing yeast strain Candida viswanathii MTCC 5158. Calcium alginate (1.5%, w/v) gave the best immobilization efficiency. Among different organic solvents and ionic liquids tried as reaction media, isopropanol gave the best enantioselectivity with moderate conversion. The immobilized cells (100 mg/ml in 50 mM Tris buffer pH 9) showed best results at a substrate concentration of 0.2 mg/ml at 30 °C. After twelve cycles of reaction, no significant decrease in bioreduction efficiency of the immobilized cells was observed as compared to the free cells.

Optimization of stereoselective ketone reduction by the white-rot fungus Merulius tremellosus ono991.

A recently isolated white-rot fungal strain, Merulius tremellosus ono991, displays high stereoselectivity during the reduction of arylketones. In order to increase the productivity and specific yield of the optically active alcohols, the culture conditions for the reduction of the model ketone compound 1'-acetonaphtone to alpha-methyl-1-naphtalenemethanol were optimized with respect to oxygen supply, choice of primary substrate and arylketone concentration. Alternative electron acceptors were also used to elucidate the role of reduction equivalents in the reduction process. The optimal yields of alpha-methyl-1-naphtalenemethanol were obtained in N2-flushed incubations with glycerol as primary substrate. The specific yield was increased from 57% to 98% compared to incubations under air with glucose. Most of the yield increase was due to N2-flushing and could be attributed to two factors. First, an increased stability of the product, alpha-methyl-1-naphtalenemethanol, in anaerobic compared to aerobic atmosphere was demonstrated. Second, fermentative metabolism increased reduced enzyme cofactors available for the reduction. Diverting reducing equivalents away from fermentation with alternative electron acceptors correlated with a decreased yield of alpha-methyl-1-naphtalenemethanol. Furthermore, the dependency of ketone reductase for common occurring metabolic reducing equivalents, NAD(P)H, was demonstrated by the reduction of 1'-acetonaphtone in cell extracts of M. tremellosus ono991.

ChemInform Abstract: Viologens that Plunder Electron from Solid Reducing Agent. Reduction of Aryl Ketones by Zinc Powder in the Presence of Propyl Viologen as an Electron Transfer Catalyst.

AbstractIn Gegenwart des im Titel genannten Katalysators (II) werden α‐Diketone (I) zu den Benzoinen (III) reduziert.

Viologens that plunder electron from solid reducing agent. Reduction of aryl ketones by zinc powder in the presence of propyl viologen as an electron transfer catalyst

It was found that viologen (propyl viologen) acted as an Electron Transfer Catalyst (ETC) in the reduction of aryl ketones with zinc powder. α-Diketones undertook the two-electron reduction to obtain the corresponding benzoins in good yields and aromatic ketones could one-electron reduced selectively to give the corresponding pinacols.