Aldoximes, acidity

Tnfluoroacetic anhydride is an efficient dehydrating reagent [46, 47] In the presence of pyndine, it smoothly dehydrates amides and aldoximes to the correspond ing nitriles [46] and adducts of CH-acids and 1,2,3-indantnone [47] (equation 20)... 

The reaction of diacetylene with cyanic acid (HCNO) proceeds at room temperature in the presence of sulfuric acid in aqueous methanol to give 3-formyl-5,5 -diisoxazol-3 -aldoxime (85) and 3,3 -diformyl-5,5 -diisoxazoldioxime (86), whose oxidation with potassium permanganate followed by esterification results in 3,3 -dicarbomethoxy-5,5 -diisoxazoles (87) (59G598). 

The rearrangement of oximes 1 under the influence of acidic reagents to yield A -substituted carboxylic amides 2, is called the Beckmann rearrangement. The reaction is usually applied to ketoximes aldoximes often are less reactive. 

The ketoxime derivatives, required as starting materials, can be prepared from the appropriate aromatic, aliphatic or heterocyclic ketone. Aldoximes (where R is H) do not undergo the rearrangement reaction, but rather an elimination of toluenesulfonic acid to yield a nitrile. With ketoxime tosylates a Beckmann rearrangement may be observed as a side-reaction. 

Schemes 16-19 present the details of the enantioselective synthesis of key intermediate 9. The retrosynthetic analysis outlined in Scheme 5 identified aldoxime 32 as a potential synthetic intermediate the construction of this compound would mark the achievement of the first synthetic objective, for it would permit an evaluation of the crucial 1,3-dipolar cycloaddition reaction. As it turns out, an enantioselective synthesis of aldoxime 32 can be achieved in a straightforward manner by a route employing commercially available tetronic acid (36) and the MEM ether of allyl alcohol (74) as starting materials (see Scheme 16).

The utility of lOOC reactions in the synthesis of fused rings containing a bridgehead N atom such as pyrrolizidines, indolizidines, and quinolizidines which occur widely in a number of alkaloids has been demonstrated [64]. Substrates 242 a-d, that possess properly positioned aldoxime and alkene functions, were prepared from proline or pipecolinic acid 240 (Eq. 27). Esterification of 240 and introduction of unsaturation on N by AT-alkylation produced 241 which was followed by conversion of the carbethoxy function to an aldoxime 242. lOOC reaction of 242 led to stereoselective formation of various tricyclic systems 243. This versatile method thus allows attachment of various unsaturated side chains that can serve for generation of functionalized five- or six-membered (possibly even larger) rings. 

The dehydration reaction of aldoxime to form nitriles using the resting cells of Rhodococcus sp. YH3-3 was optimized. We found that the enzyme was induced by aldoxime and catalyzed the stoichiometric synthesis of nitriles from aldoximes at pH 7.0 and 30°C. Phenylacetonitrile once synthesized from phenylacetaldoxime was hydrolyzed to phenylacetic acid, since the strain has nitrile degradation enzymes such as nitrile hydratase and amidase. We have been successful in synthesizing phenylacetonitrile and other nitriles stoichiometrically by a selective inactivation of nitrile hydratase by heating the cells at 40°C for 1 h. Various nitriles were synthesized under optimized conditions from aldoximes in good yields. 

Anhydrous peroxytrifluoroacetic acid is not easy to handle, but the procedure has recently been revised.121 Namely, reaction of urea-hydrogen peroxide complex (UHP) with tri-fluoroacetic anhydride in acetonitrile at 0 °C gives solutions of peroxytrifluoroacetic acid, which oxidize aldoximes to nitroalkanes in good yields (Eqs. 2.58 and 2.59). Ketoximes fail to react under these conditions, the parent ketone being recovered. 

A simple montmorillonite K 10 clay surface is one among numerous acidic supports that have been explored for the Beckmann rearrangement of oximes (Scheme 6.27) [54]. However, the conditions are not adaptable for the aldoximes that are readily dehydrated to the corresponding nitriles under solventless conditions. Zinc chloride has been used in the above rearrangement for benzaldehyde and 2-hydroxyacetophe-none, the later being adapted for the synthesis of benzoxazoles. 

Glucosinolates derive from amino acids by conversion to an aldoxime, R-CH=N-OH. In a not well understood process, the aldoximine is converted to a thiohydroximic acid, R-C(SH)=N-OH the introduced sulfur is likely derived from... 

In the presence of Lewis acids (Znl2 and BF3 OEt2), aldoximes react with u,l )-unsaturated carbonyl compounds (129) at room temperature affording good yields of /V-alkyl nitrones (130) (Scheme 2.47) (299). 

Acyl nitronates (63) derived from primary AN are characterized by two types of such transformations the rearrangement into a-acetoxy aldoximes (219) and elimination of the corresponding carboxylic acids to form nitrile oxides (Scheme 3.63). 

Intramolecular addition of trialkylboranes to imines and related compounds have been reported and the main results are part of review articles [94, 95]. Addition of ethyl radicals generated from Et3B to aldimines affords the desired addition product in fair to good yield but low diaster control (Scheme 40, Eq. 40a) [96]. Similar reactions with aldoxime ethers [97], aldehyde hydrazones [97], and N-sulfonylaldimines [98] are reported. Radical addition to ketimines has been recently reported (Eq. 40b) [99]. Addition of triethylborane to 2H-azirine-3-carboxylate derivatives is reported [100]. Very recently, Somfai has extended this reaction to the addition of different alkyl radicals generated from trialkylboranes to a chiral ester of 2ff-azirine-3-carboxylate under Lewis acid activation with CuCl (Eq. 40c) [101]. 

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