Conversion of ketones

Leuckart reaction The conversion of ketones and aromatic aldehyde,s to primary amines by reaction with ammonium methanoale at a high temperature. 

Most important for the synthetic chemist is an index to the synthesis of functional groups, e.g. synthesis of alkenes from ketones, as well as conversion of ketones to alkenes. 

The procedure described is an example of a more general synthetic method for the direct conversion of ketones into cyanides. " The reaction has been carried out successfully with acyclic and cyclic aliphatic ketones, including numerous steroidal ketones and aryl-alkyl ketones. The conversion of diaryl or highly hindered ketones such as camphor and )3,j8-dimethyl-a-tetralone requires the use of a more polar solvent. The dimethoxyethane used in the present procedure should be replaced by dimethyl sulfoxide. ... 

C=N, C=S, C=C, and N N containing substrates. Thus oxa2oles, imidazoles, thiazoles, p rrroles, and 1,2,4-triazoles have been prepared, respectively. Furthermore, p-tolylsulfonylmethyl isocyanide has found use in a one-step conversion of ketones into cyan-idea and in a two-step synthesis of a-hydroxyaldehydes from ketones. ... 

The hydrogenation of 5a-cholestanone (58) in methanolic hydrobromic acid over platinum gives 3j5-methoxycholestane ° (61). This compound is also obtained from the palladium oxide reduction of (58) in methanol in the absence of acid. Hydrogenation of 5 -cholestanone also gives the 3j5-methoxy product under these conditions. Reduced palladium oxides are quite effective for the conversion of ketones to ethers. The use of aqueous ethanol as the solvent reduces the yield of ether. Ketals are formed on attempted homogeneous hydrogenation of a 3-keto group in methanol. ... 

The treatment of ketoximes with lithium aluminum hydride is usually a facile method for the conversion of ketones into primary amines, although in certain cases secondary amine side products are also obtained. Application of this reaction to steroidal ketoximes, by using lithium aluminum deuteride and anhydrous ether as solvent, leads to epimeric mixtures of monodeuterated primary amines the ratio of the epimers depends on the position of the oxime function. An illustrative example is the preparation of the 3(x-dj- and 3j5-di-aminoandrostane epimers (113 and 114, R = H) in isotopic purities equal to that of the reagent. 

The reaction of peracids with ketones proceeds relatively slowly but allows for the conversion of ketones to esters in good yield. In particular, the conversion of cyclic ketones to lactones is synthetically useful because only a single product is to be expected. The reaction has been carried out with both percarboxylic acids and Caro s acid (formed by the combination of potassium persulfate with sulfuric acid). Examples of both procedures are given. 

Cychc nitroalkenes are prepared from cychc ketones via nitradon of vinylstarmanes v/ith tetranitrmnethane in DMSO, as shown in Eq 2 36, where DMSO is a cridcal choice of solvent for replacing dn by nitre at the unsaturated carbon The conversion of ketones to vinylstarmanes... 

Concealed within spirocyclic intermediate 16 are rings B and F of ginkgolide B. Intermediate 16 is readily formed in two steps from a readily available starting material and it contains a strategically placed ketone carbonyl group which provides several options for further advance. A particularly straightforward route to 15 includes the conversion of ketone 16 into enol triflate 21 by means of McMurry s protocol.16 Thus, enolization of 16 with LDA in dimethoxyethane at -78 °C followed by triflation of the enolate oxygen atom with /V-phenyltrifluoromethanesulfonimide furnishes enol triflate 21 in a yield of 80%. 

A different method for the conversion of ketones to a-hydroxy ketones consists of treating the enolate with a 2-sulfonyloxaziridine (such as 15). This is not a free-radical process the following mechanism is likely ... 

This method is especially useful for the conversion of ketones to ketals, since the direct reaction of a ketone with an alcohol often gives poor results. In another method, the substrate is treated with an alkoxysilane ROSiMe3 in the presence of trimethylsilyl trifluoromethanesulfonate. ... 

For conversion of ketones to either (Z) or ( ) enol borinates, see, for example, Evans,... 

Both the selenoxide and sulfoxide " reactions have been used in a method for the conversion of ketones, aldehydes, and carboxylic esters to their a, P-unsaturated derivatives (illustrated for the selenoxide). 

Selenoxides are even more reactive than sulfoxides toward (3-elimination. In fact, many selenoxides react spontaneously when generated at room temperature. Synthetic procedures based on selenoxide eliminations usually involve synthesis of the corresponding selenide followed by oxidation and in situ elimination. We have already discussed examples of these procedures in Section 4.3.2, where the conversion of ketones and esters to their a, (3-unsaturated derivatives is considered. Selenides can... 

Preparative conversion of ketones (particularly aromatic ones) into pinacols can also be effected photochemically by u.v. irradiation in the presence of a hydrogen donor, e.g. Me2CHOH. 

Nitration of ketones or enol ethers provides a useful method for the preparation of a-nitro ketones. Direct nitration of ketones with HN03 suffers from the formation of a variety of oxidative by-products. Alternatively, the conversion of ketones into their enolates, enol acetates, or enol ethers, followed by nitration with conventional nitrating agents such as acyl nitrates, gives a-nitro ketones (see Ref. 79, a 1980 review). The nitration of enol acetates of alkylated cyclohexanones with concentrated nitric acid in acetic anhydride at 15-22 °C leads to mixtures of cis- and rrans-substituted 2-nitrocyclohexanones in 75-92% yield. 4-Monoalkylated acetoxy-cyclohexanes give mainly m-compounds, and 3-monoalkylated ones yield fra/w-compounds (Eq. 2.40).80... 

Conversion of ketone 80 to the enol silane followed by addition of lithium aluminum hydride to the reaction mixture directly provides the allylic alcohol 81 [70]. Treatment of crude allylic alcohol 81 with tert-butyldimethylsilyl chloride followed by N-b ro m o s u cc i n i m i de furnishes the a-bromoketone 82 in 84 % yield over the two-step sequence from a.p-unsaturated ester 80. Finally, a one-pot Komblum oxidation [71] of a-bromoketone 82 is achieved by way of the nitrate ester to deliver the glyoxal 71. It is worth noting that the sequence to glyoxal 71 requires only a single chromatographic purification at the second to last step (Scheme 5.10). 

Me2Al)2Te is an efficient tellurating reagent for the direct conversion of ketones to telluroketones21 in the presence of cyclopentadiene (Scheme 40). 

Acylbenzotriazoles 162 are efficient C-acylation reagents for the regioselective conversion of ketone enolates into P-diketones . Diethyl(l-benzotriazolmethyl)phosphinate (163) was found to be a convenient reagent for the stereoselective preparation of (E)-l-(l-alkenyl)benzotriazoles <00SC1413>. The novel three-carbon synthon 1-(1//-133-... 

Corey s sulfonium ylide methodology32 was then adopted. As shown in Scheme 7-51, conversion of ketone 161 to spiroepoxide 165 proceeded with high yield, and a Lewis acid-induced epoxide opening gave the desired allylic alcohol 164 with perfect yield. 

The conversion of ketones to esters by perbenzoic acid involves an insertion of an oxygen atom. 

Scheme 20 Anodic conversion of ketones to a-hydroxy ketals.

Methylenecyclohexane oxide has been prepared by the oxidation of methylenecyclohexane with benzonitrile-hydrogen peroxide or with peracetic acid by treatment of 1-chlorocyclo-hexylmethanol with aqueous potassium hydroxide and by the reaction of dimethylsulfonium methylide with cyclohexanone. This reaction illustrates a general method for the conversion of ketones and aldehydes into oxiranes using the methylene-transfer reagent dimethyloxosulfonium methylide. The yields of oxiranes are usually high, and the crude products, in most cases, are of sufficient purity to be used in subsequent reactions (e.g., rearrangement to aldehydes) without further purification. 

Conversion of ketones to amides using HN3 (hydrazoic acid). 

Conversion of ketones to the corresponding thioamide and/or ammonium salt. 

Other examples include conversion of ketones to a-hydroxydimethylace-tals 1 (Scheme la), which result from a nucleophilic ring opening of the intermediate oxiranes 18 by methoxide ions, as shown in Scheme 10. Interestingly, it is possible to isolate such oxirane derivatives in a few cases such as that shown in Eq. (7) (85S326). 

Neutral alumina-supported sodium hydrogen sulfate was also used as a heterogenous catalyst for the one pot conversion of ketones to a great variety of amides in the presence of hydroxylamine under microwave irradiation in solvent-free conditions . ... 

To obtain complete conversion of ketones to enolates, it is necessary to use aprotic solvents so that solvent deprotonation does not compete with enolate formation. Stronger bases, such as amide anion ( NH2), the conjugate base of DMSO (sometimes referred to as the dimsyl anion),2 and triphenylmethyl anion, are capable of effecting essentially complete conversion of a ketone to its enolate. Lithium diisopropylamide (LDA), which is generated by addition of w-butyllithium to diisopropylamine, is widely used as a strong... 

The conversion of ketone /utolucncsulfonylhydrazoncs to alkenes takes place on treatment with strong bases such as an alkyllithium or lithium dialkylamide.205 This is known as the Shapiro reaction 206 The reaction proceeds through the anion of a vinyldiimide, which decomposes to a vinyllithium reagent. Contact of this intermediate... 

Conversion of ketone 437 to hippocasine (105) was accomplished by Bom-ford-Stevens reaction via the following reaction sequence. Successive treatments of 437 with hydrazine, p-toluenesulfonyl chloride, and then lithium tert-butylamine gave hippocasine (105). The reaction occurred exclusively in the desired direction. Treatment of hippocasine (105) with methanolic hydrogen peroxide gave hippocasine oxide (106) (Scheme 54). 

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