Ketone secondary alcohols oxidized

Another factor complicating the situation in composition of peroxyl radicals propagating chain oxidation of alcohol is the production of carbonyl compounds due to alcohol oxidation. As a result of alcohol oxidation, ketones are formed from the secondary alcohol oxidation and aldehydes from the primary alcohols [8,9], Hydroperoxide radicals are added to carbonyl compounds with the formation of alkylhydroxyperoxyl radical. This addition is reversible. 

Both primeiry and secondary alcohols can be oxidized, but tertiary alcohols won t undergo simple oxidation. Oxidation of a primary alcohol gives an aldehyde however, preventing further oxidation of the aldehyde to a carboxylic acid is difficult. Secondary alcohols oxidize to a ketone without the problem of additional oxidation occurring. 

For a synthesis of the anti-cancer drug taxol TPAP/NMO was used in three steps, two for oxidation of primary alcohols to aldehydes (by TPAP/NMO/PMS/ CHjClj) and one for a secondary alcohol to ketone (by TPAP/NMO/PMS/CHjClj-CHjCN) [66], cf. also [111] and for the SERCA inhibitor thapsigargin (two primary alcohol and one secondary alcohol oxidation steps) [112], This system was also used during synthesis of the cholesterol biosynthesis inhibitor 1233A [52], the antibiotic and anti-parasitic ionophore tetronasin [113, 114] and for the cytotoxic sponge alkaloids motopuramines A and B [115]. 

Primary alcohols oxidize to aldehydes, which, in turn, oxidize to carboxylic acids. Secondary alcohols oxidize to ketones. In each case, the reverse process is called re- duction... 

Bomeol, the structure of which is given in text Figure 26.7, is a secondary alcohol. Oxidation of bomeol converts it to the ketone camphor. 

By the three preceding reactions and by the formation of carbohydrates by the oxidation of poly-hydroxy alcohols, carbohydrates are poly-hydroxy alcohols in which one alcohol group is oxidized to aldehyde (primary alcohol group at the end of the chain), or to ketone (secondary alcohol group). 

Conversely, as previously stated, the aldehydes on reduction yield the primary alcohols and in the case of benzaldehyde, which is a commonly occurring substance in oil of bitter almonds, this method is used in the preparation of the alcohol. In the case of the secondary alcohols oxidation to ketones is not easily accomplished but the reverse reaction, the reduction of the ketones to secondary alcohols does take place with ease. 

Reaction of the C-0 and O-H Bonds Primary alcohols oxidize to carboxylic acids secondary alcohols oxidize to ketones with chromium trioxide or sodium dichromate. Tertiary alcohols do not oxidize under mild conditions. With pyridinium chlorochromate (PCC) the oxidation of primary alcohols can be stopped at aldehydes. 

OxidationThe reagent oxidizes primary alcohols in good yield to aldehydes it can also oxidize aldehydes further to carboxylic acids. Ketones are obtained in high yield from secondary alcohols. Oxidation is most rapid in DMSO but proceeds satisfactorily in water. Hydroquinone is oxidized to p-benzoquinone in 89% yield. 

To test the proposed route we capitalized upon our ability to use the intramolecular diyl trapping reaction to synthesize 95, the mono-ketal analog of 143. Ozonolytic cleavage of the C-C n bond of 95 followed by reduction with NaBIfy afforded diol 145 in an 85% yield. The primary alcohol was selectively protected as a silyl ether, and the secondary alcohol oxidized with PCC to provide ketone 146 as a 1 1 mixture of diastereomers. 

Many methods have been developed for the oxidation of primary and secondary alcohols. Oxidation of secondary alcohols normally gives rise to ketone products, whereas primary alcohols form aldehydes or carboxylic acids, depending on the reagent and conditions. Selective oxidation reactions have been developed that give these different types of products, even in the presence of other sensitive functionality. This section will describe, in turn, the different reagents used for the formation of aldehydes and ketones, before discussing the formation of carboxylic acids. 

The chemical (Gif system) and the electrochemical conversion (Gif-Orsay system) have been compared in the oxidation of six saturated hydrocarbons (cyclohexane, 3-ethylpentane, methylcyclopentane, cis- and traus-decalin and adamantane). The results obtained for pyridine, acetone and pyridine-acetone were similar for both systems. Total or partial replacement of pyridine for acetone affects the selectivity for the secondary position and lowers the ratio ketone secondary alcohol. The formation of the same ratio of cis- and traws-decal-9-ol from either cis- or trans-deca in indicates that tertiary alcohols result from a mechanism essentially radical in nature. The C /C ratio between 6.5 and 32.7 rules out a radical mechanism for the formation of ketones and secondary alcohols. Ratios of 0.14 and 0.4 were reported for radical-type oxidations of adamantane and cis-decalin. Partial replacement of pyridine by methanol, ethanol or f-propanol results in diminished yields and a lower selectivity. Acetone gives comparable yields however, the C /C ratio drops to 0.2-10.7. 

The control of the configuration of the side chain at C-8 in a synthesis of C-gly-coside antibiotic pseudonomic acid 212 described by DeShong [46] resulted from a Claisen-Johnson rearrangement Dihydropyrane derivatives 213-214 after treatment with triethyl orthoacetate afforded an inseparable mixture of diastereomers. The anomeric center was then reduced and the side chain secondary alcohol oxidized. Diastereomeric ketones 215 and 216 were isolated at this stage in a 2 1 ratio (Scheme 6.33). 

Oxidation of alcohols can also be effectively carried out using chlorine in pyridine to give aldehydes and ketones. Secondary alcohols can be selectively oxidized in the presence of primary alcohols.For example, treatment of 5/3-cholestane-3/3,19-diol (14) with chlorine and pyridine affords selective oxidation to 19-hydroxy- 5 -cholestan-3-one (15) in almost quantitative yield (eq 9). 

A white solid, m.p. 178 C. Primarily of interest as a brominaling agent which will replace activated hydrogen atoms in benzylic or allylic positions, and also those on a carbon atom a to a carbonyl group. Activating influences can produce nuclear substitution in a benzene ring and certain heterocyclic compounds also used in the oxidation of secondary alcohols to ketones. 

Secondary alcohols may be oxidised to the corresponding ketones with aluminium ferf.-butoxlde (or tsopropoxlde) In the presence of a large excess of acetone. This reaction Is known as the Oppenauer oxidation and Is the reverse of the Meerweln - Ponndorf - Verley reduction (previous Section) it may bo expressed ... 

The widely used Moifatt-Pfltzner oxidation works with in situ formed adducts of dimethyl sulfoxide with dehydrating agents, e.g. DCC, AcjO, SO], P4O10, CCXTl] (K.E, Pfitzner, 1965 A.H. Fenselau, 1966 K.T. Joseph, 1967 J.G. Moffatt, 1971 D. Martin, 1971) or oxalyl dichloride (Swem oxidation M. Nakatsuka, 1990). A classical procedure is the Oppenauer oxidation with ketones and aluminum alkoxide catalysts (C. Djerassi, 1951 H. Lehmann, 1975). All of these reagents also oxidize secondary alcohols to ketones but do not attack C = C double bonds or activated C —H bonds. 

The Dess-Martin periodinane ( DMP ) reagent, U,l-tris(acetyloxy)-l,l-dihydro-l,2-benziodoxol-3(l//)-one, has also been used in several complex syntheses for the oxidation of primary or secondary alcohols to aldehydes or ketones, respectively (e.g., M. Nakatsuka, 1990). It is prepared from 2-iodobenzoic add by oxidation with bromic add and acetylation (D.a Dess, 1983). 

Selective oxidation of secondary alcohols to ketones is usually performed with CrOj/HjSO, I I in acetone (Jones reagent) or with CrOjPyj (Collin s reagent) in the presence of acid-sensitive groups (H.G. Bosche, 1975 C. Djerassi, 1956 W.S. Allen, 1954). As mentioned above, a,)S-unsaturated secondary alcohols are selectively oxidized by MnOj (D.G. Lee, 1969 D. Arndt, 1975) or by DDQ (D. Walker, 1967 H.H. Stechl, 1975). 

Alcohols are oxidized slowly with PdCh. Oxidation of secondary alcohols to ketones is carried out with a catalytic amount of PdCh under an oxygen atmo-sphere[73.74]. Also, selective oxidation of the allylic alcohol 571 without attacking saturated alcohols is possible with a stoichiometric amount of PdfOAc) in aqueous DMF (1% H OifSll],... 

The slow oxidation of primary alcohols, particularly MeOH, is utilized for the oxidation of allylic or secondary alcohols with allyl methyl carbonate without forming carbonates of the alcohols to be oxidized. Allyl methyl carbonate (564) forms 7r-allylpalladium methoxide, then exchange of the methoxide with a secondary or allylic alcohol 563 present in the reaction medium takes place to form the 7r-allylpalladium alkoxide 565, which undergoes elimination of j3-hydrogen to give the ketone or aldehyde 566. The lactol 567 was oxidized selectively with diallyl carbonate to the lactone 568 without attacking the secondary alcohol in the synthesis of echinosporin[360]. 

Secondary alcohols are oxidized to ketones by the same reagents that oxidize primary alcohols... 

To the synthetic chemist the most important of the reactions m Table 17 1 are the last two the oxidation of primary alcohols to aldehydes and secondary alcohols to ketones Indeed when combined with reactions that yield alcohols the oxidation methods are so versatile that it will not be necessary to introduce any new methods for preparing aide hydes and ketones in this chapter A few examples will illustrate this point... 

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