Of alcohols to ketones

Pyridinium chlorochromala 1 or Cr03-dimelhylpyrazola 4 for oxidation of alcohols to ketone or aldehydes... 

In Table 9-5 we have listed a large number of reaction types. For many of these reaction types you may be able to think of examples from central metabolism. For example, the oxidation of alcohols to ketones is a very commonly encountered reaction. Thus ... 

The interconversion of alcohols to ketones is a common biochemical reaction. The introduction of hydroxyl groups into toe steroid nucleus and side chain creates a variety of secondary alcohols. Some of these, especially at positions 3, 7, 11 and 17 are frequently oxidised to ketones. 

The above-described reverse reaction (viz. the Fe-catalyzed dehydrogenation of alcohols to ketones/aldehydes) has been reported by Williams in 2009 (Table 9) [58]. In this reaction, the bicyclic complex 16 shows a sluggish activity, whereas the dehydrogenation of l-(4-methoxyphenyl)ethanol catalyzed by the phenylated complex 17 affords the corresponding ketone in 79% yield when 1 equiv. (relative to 17) of D2O as an additive was used. For this oxidation reaction, l-(4-methoxyphenyl) ethanol is more suitable than 1-phenylethanol and the reaction rate and the yield of product are higher. 

Table 9 Fe-catalyzed dehydrogen conversion of alcohol to ketone ...

The proposed catalytic cycle for the dehydrogenation of alcohols to ketones is shown in Scheme 15. The initial reaction of 17 with H2O affords the hydride complex a and C02- Dehydrogenation of a by acetone gives the active species b and 2-propanol. The subsequent reaction of b with the alcohol yields the corresponding ketone and regenerates a to complete the catalytic cycle. 

Scheme 15 Proposed catalytic cycle for dehydrogenation of alcohols to ketones...

Another reagent that finds application of oxidations of alcohols to ketones is ruthenium tetroxide. The oxidations are typically carried out using a catalytic amount of the ruthenium source, e.g., RuC13, with NaI04 or NaOCl as the stoichiometric oxidant.16 Acetonitrile is a favorable solvent because of its ability to stabilize the ruthenium species that are present.17 For example, the oxidation of 1 to 2 was successfully achieved with this reagent after a number of other methods failed. 

Oxidations for oxidation of alcohols to ketones employs dimethyl sulfoxide (DMSO) and any... 

Owing to the efficient oxidation of alcohols to ketones, alcohols can be used as the starting materials in oxidative cleavages. The conditions required are more vigorous than for the alcohol to ketone transformation (see Section 12.1.1). 

Oxidation. DMSO activated by P205 (1 equiv.) and in combination with triethylamine is useful for oxidation of alcohols to ketones and aldehydes, particularly in cases where the Swern reagent results in chlorinated byproducts. Yields are typically 80-85%. 

For the dehydrogenation of CH—XH structures, for example, of alcohols to ketones, of aldehydes to carboxylic acids, or of amines to nitriles, there is a wealth of anodic reactions available, such as the nickel hydroxide electrode [126], indirect electrolysis [127, 128] (Chapter 15) with I , NO, thioanisole [129, 130], or RUO2/CP [131]. Likewise, selective chemical oxidations (Cr(VI), Mn02, MnOJ, DMSO/AC2O, Ag20/Celite , and 02/Pt) [94] are available for that purpose. The advantages of the electrochemical conversion are a lower price, an easier scale-up, and reduced problems of pollution. 

Early electrochemical processes for the oxidation of alcohols to ketones or carboxylic acids used platinum or lead dioxide anodes, usually with dilute sulphuric acid as electrolyte. A divided cell is only necessary in the oxidation of primary alcohols to carboxylic acids if (he substrate possesses an unsaturated function, which could be reduced at the cathode [1,2]. Lead dioxide is the better anode material and satisfactory yields of the carboxylic acid have been obtained from oxidation of primary alcohols up to hexanol [3]. Aldehydes are intermediates in these reactions. Volatile aldehydes can be removed from the electrochemical cell in a... 

Cyclohexanol and cyclohexanone are made by the air oxidation of cyclohexane (81%) with a cobalt(II) naphthenate or acetate or benzoyl peroxide catalyst at 125-160°C and 50-250 psi. Also used in the manufacture of this mixture is the hydrogenation of phenol at elevated temperatures and pressures, in either the liquid or vapor phase (19%). The ratio of alcohol to ketone varies with the conditions and catalysts. 

Another reagent that finds application in oxidations of alcohols to ketones is ruthenium tetroxide. For example, the oxidation of 1 to 2 was successfully achieved with this reagent after a number of other methods failed. 

A very useful group of procedures for oxidation of alcohols to ketones have been developed which involve DMSO and any one of several electrophilic reagents, such as dicyclohexylcarbodiimide, acetic anhydride, trifluoroacetic anhydride, oxalyl chloride, or... 

Convenient new methods for the preparative scale oxidation of alcohols to ketones and carboxylic acids are always welcome. T. Punniyamurthy of the Indian Institute of Technology Guwahati reports (Tetrahedron Lett. 44 6033, 2003) that 30% aqueous H,02 catalyzed by a Co salen complex effects this transformation. 

Hydrogen peroxide is an inexpensive oxidant, but it requires a catalyst to effect oxidation of an alcohol to the ketone. Removal of the catalyst then becomes an issue. Ronny Neumann of the Weizmann Institute of Science reports (J. Am. Chem. Soc. 2004,126, 884) the development of a hybrid organic-tungsten polyoxometalate complex that is not soluble in organic solvents, but that nonetheless catalyzes the hydrogen peroxide oxidation of alcohols to ketones. The solid catalyst is removed by filtration after the completion of the reaction. The catalyst retained its activity after five recyles. 

In several cases A-hydroxyphthalimide has been used as an organic mediator for the oxidation of alcohols to ketones, of benzyl ethers to benzoates , of alkyl aromatics to aryl ketones , and of 4-phenyl-l,3-dioxolanes to unprotected ketones... 

Oxidation of the TV-aryl azanols under controlled conditions yields nitroso compounds. This reaction is not unlike the oxidation of alcohols to ketones (Section 15-6B) ... 

General Procedure for Transformation of Alcohols to Ketones by Jones Oxidation... 

A milestone in the routine employment of perruthenate in the oxidation of alcohols was established with the publication by Griffith, Ley et al. in 1987 on the catalytic use of tetra- -propylammonium perruthenate (TPAP).11 The presence of the tetra- -propylammonium cation renders this compound soluble in apolar media and allows the existence of a high concentration of perruthenate ion in organic solvents. The tetra- -propylammonium perruthenate is easily prepared and can be employed catalytically in CH2CI2 solution in the oxidation of alcohols to ketones and aldehydes, using /V-methyl morpholine A-oxide (NMO) as the secondary oxidant. 

An alternative approach to the oxidation of alcohols to ketones was also reported by Shea et al., who incorporated a nitroxide catalyst into a polymeric matrix [56], A polymerisable 2,2,6,6-tetramethylpiperidine (90) was derivatised as /V-allyl-amine (91), which was removed after polymerisation, leaving a catalytically active nitroxide (92) able to form stable free radicals, thereby efficiently catalysing the reaction of oxidation with yields ranging from 55 to 88%. 

Anodic dehydrogenations, e.g., oxidations of alcohols to ketones, have been treated in Sect. 8.1 and formation of olefins by anodic elimination of C02 and H+ from carboxylic acids was covered in Sect. 9.1. Therefore this section is only concerned with anodic bisdecarboxylations of v/odicarboxylic acids to olefins. This method gives usually good results when its chemical equivalent, the lead tetraacetate decarboxylation, fails. Combination of bisdecarboxylation with the Diels-Alder reaction or [2.2] -photosensitized cycloadditions provides useful synthetic sequences, since in this way the equivalent of acetylene can be introduced in cycloadditions. 

ADHs catalyze the oxidation of alcohols to ketones with simultaneous reduction of NAD(P)+. Due to the reversibility of this reaction, ADH-catalyzed reactions can either be used for the synthesis of (chiral) compounds or for the regeneration of the coenzyme. The latter holds true, for example, in the case of substrate-coupled ADH-catalyzed reduction reactions using isopropanol or ethanol as the hydrogen donor. Several kinds of ADHs have already been described. ADHs of the EC 1.1.1.1 group are dependent on NAD+. They act on primary or secondary alcohols or on hemiacetals. In contrast, ADHs of the group EC 1.1.1.2 depend on NADP+. Some enzymes of this group oxidize only primary alcohols others act on secondary alcohols as well. 

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