Nitrogen nucleophiles, 184 Table addition

The use of a nitrogen nucleophile in the side chain (as an amide) also leads to an intramolecular 1,4-addition under the standard conditions for the palladium-catalyzed 1,4-oxidation reactions52. Nitrogen nucleophiles employed for this reaction comprise tosy-lamides, carboxamides, carbamates and ureas. The reactions are run in acetone-acetic acid with p-benzoquinone (BQ) as the oxidant. In most cases highly stereo- and regioselective reactions were obtained and some examples are given in Table 3. 

Ethoxymethylene)-2-phenyl-5(47/)-oxazolone 404, readily available from hippuric acid and triethyl orthoformate, has also been used as a starting material for other unsaturated oxazolones via addition-elimination reactions. Nitrogen nucleophiles are most commonly used and amines give rise to 4-(aminomethyl-ene)-2-phenyl-5(4//)-oxazolones 405 (Scheme 7.130 Table 7.37, Fig. 7.48) which, in many cases have been evaluated as antihypertensives. 

Electrophiles that have been used for the second alkylation of this tandem Michael addition -alkylation sequence are limited to primary iodoalkanes, (bromomethyl)benzenes and 3-bromo-propenes. Tables 9 and 10 provide details of the alkylations of enolate species prepared by 1,4-additions of -a,/j-unsaturated iron-acyl complexes by anionic carbon nucleophiles and anionic nitrogen nucleophiles, respectively. 

As usual, the best strategy is to identify the nucleophile and the electrophile. This chapter introduced a new electrophile, the carbonyl carbon of an aldehyde or ketone. The nucleophiles are listed in Table 18.2. Hydride, water, HCN, and organometallic nucleophiles result in the addition of the nucleophile to the carbon and a hydrogen to the oxygen of the carbonyl group. Ylides and nitrogen nucleophiles result in the formation of a double bond between the carbonyl carbon and the nucleophile. And alcohols and thiols add two nucleophiles to the carbonyl carbon. 

Table 19. Additions of nitrogen nucleophiles to alkynes, RC CR, to form acyclic adducts ... 

As representative data in Table 1 shows, diastereomeric mbctures of gluco and manno iodoamides 2 9 were obtained from the reactions of these nitrogen nucleophiles with protected glucals. The major diastereomers observed in all cases, were the trans addition products, the a-manno and P-gluco isomers. 

In addition to being more basic than arylammes alkylammes are also more nucleophilic All the reactions m Table 22 4 take place faster with alkylammes than with arylammes The sections that follow introduce some additional reactions of amines In all cases our understanding of how these reactions take place starts with a consideration of the role of the unshared electron pair of nitrogen... 

Two recent reports described addition of nitrogen-centered nucleophiles in usefully protected fonn. Jacobsen reported that N-Boc-protected sulfonamides undergo poorly selective (salen) Co-catalyzed addition to racemic epoxides. However, by performing a one-pot, indirect kinetic resolution with water first (HKR, vide infra, Table 7.1) and then sulfonamide, it was possible to obtain highly enantiomer-ically enriched addition products (Scheme 7.39) [71]. These products were transformed into enantioenriched terminal aziridines in straightforward manner. 

Sulfur-stabilized ylides underwent photodriven reaction with chromium alkoxy-carbenes to produce 2-acyl vinyl ethers as E/Z mixtures with the E isomer predominating (Table 22) [ 121-123]. The reaction is thought to proceed by nucleophilic attack of the ylide carbon at the chromium carbene carbon followed by elimination of (CO)5CrSMe2. The same reaction occurred thermally, but at a reduced rate. Sulfilimines underwent a similar addition/elimination process to produce imidates or their hydrolysis products (Table 23) [ 124,125]. Again the reaction also proceeded thermally but much more slowly. Less basic sulfilimines having acyl or sulfonyl groups on nitrogen failed to react. 

Steric effects on the nucleophile, aniline, were clearly evident. Rate constants for bimolecular attack of 2,6-dimethyl- 70a, 2,6-diethyl- 70b, and 3,5-dimethylaniline 70c at 308 K indicate that the ort/zo-substituted anilines react more than an order of magnitude slower at the same temperature (Table 7). Structure 70c must be able approach the reactive nitrogen more closely.42,43 A comparison of the rate constants for reaction of aniline 72c, /V-methyl- 71a and /V-phenylaniline 71b provides further evidence of steric effects although the very small rate constant for the diphenylamine could also be accounted for by reduced nucleophilicity on account of lone pair resonance into the additional phenyl ring. 

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