Acetates nitrogen nucleophilic

Carbamates are allylated in the presenee of strong bases in DMSO or HMPA[197], Phthalimide (320) and succimide are allylated with the allyl-isoureu 321 at room temperature or the allylic acetate 322 at 100 C[I98.I99], Di-/-butyl iminodicarbonate is used as a nitrogen nucleophile[200]. 

Kinetic data on acetate displacement from C-3 using a number of sulfur and nitrogen nucleophiles in aqueous solution at near neutral pH demonstrate that the reaction proceeds by an 5 1 mechanism (B-72MI51004). The intermediate in this reaction is depicted as a dipolar allylic carbonium ion (9) with significant charge delocalization. Of particular significance in this regard is the observation that the free carboxylate at C-4 is required since... 

Additions of oxygen and nitrogen nucleophiles to vinyloxiranes can be achieved with Pd(0) catalysis [103, 104]. Acetate, silanols, amines, sulfonamides, and azide have been used as nucleophiles, and the stereochemical outcome of these additions, where applicable, is normally the result of two consecutive SN2 reactions. This is demonstrated by the additions of NaNHTs to vinylepoxides 29 and 30, affording syn- and anti-amino alcohols 31 and 32, respectively, in good yields and with high diastereoselectivities (Scheme 9.22) [105]. 

A ring opening reaction of (1-lactams promoted by methoxide generated nitrogen nucleophiles in situ that subsequently added to proximal allenes producing trisubstituted pyrroles <06CC2616>. In the event, treatment of (3-lactam 3 with MeONa led to pyrrole-2-acetic ester 4 after cleavage of the amide bond, 5-exo-dig cyclization, and loss of methanol. The sequence was notable as no metal catalyst was required. 

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. 

An alternative route from alkenes to 2-azasulfides reported by the groups of Caserio and Trost involves addition of a thiosulfonium salt, e.g. dimethyl(methylthio)sulfonium tetrafluoroborate (MeSS-Me2+ BF4-), followed by treatment of the resultant thiosulfenylated adduct with an amine or other nitrogen nucleophiles (Schemes 2320 and 24).35 Trost reports that the addition of the thiosulfonium salt can be followed by addition of an oxygen nucleophile, such as acetate, or a carbon nucleophile, such as cyanide, effecting oxosulfenylation and cyanosulfenylation, respectively (Scheme 25).36... 

Additions to l,3-dienes6 (12, 367-368 14, 249-250 15, 245). This reaction can be used to effect intramolecular cyclization of cyclic 1,3-dienes substituted by a suitable nitrogen nucleophile. Thus reaction of the amido diene 1 with lithium acetate catalyzed by Pd(OAc)2 (with benzoquinone as reoxidant) provides the ds-fused heterocycle cis-2, in which the acetoxy group is cis to the ring fusion, formed by an overall trans-1,4-oxyamidation of the diene system. Addition of a trace of LiCl improves the yield and results in an overall cis- 1,4-oxyamidation (equation I). Acetamides and carbamates can also be used in place of amides. 1,4-Chloroamidation can also be effected by use of 2 equiv. of LiCl. 

The second approach for the nucleophilic animation reactions to be considered here will be reactions of allyl halides and allyl acetates leading to allyl amines. Allyl halides are normally very reactive in SN2 reactions, but the direct coupling of allyl halides with nitrogen nucleophiles has been performed with limited success [4], as di- and trialkylated by products often predominate. The application of the Gabriel synthesis can to a certain extent eliminate the problem with polyalkylation of amines using, e.g., the stabilized phthalimide anion 19 as the nucleophile. The allyl amine 20... 

The stereochemistry of Pd -catalyzed allylic alkylation is net retention (equation 62). This arises from sequential inversion steps. Initially, the Pd approaches from the face of the C3 unit opposite the leaving group, to form the jt-allyl complex. Subsequently, the nucleophile adds to the face of the TT-allyl opposite palladium. If a bulky or umeactive nucleophile is used with allylic acetates, the acetoxy group can add again to the complex. Ultimately, this results in the production of a mixture of stereoisomers upon nucleophihc addition. As an example of the range of allylic substrates that react, nitrogen nucleophiles, in particular primary and secondary amines, undergo palladium-catalyzed substimtion with aUyhc alcohols, acetates, and ethers (equation 63). 

Later work has shown that a dynamic kinetic asymmetric transformation could be obtained if the acetates were converted into carbonate groups. With the tetra(2,2,2-trichloroethyl) carbonate derivative, reactions with carbon and nitrogen nucleophiles gave exclusively the monosubstituted products in high yield (61-95%) and excellent enantiomeric excesses (95-99%). However, car-boxylate nucleophiles afforded the disubstituted products in high yield and enantiomeric excess (eq 7). This allowed an efficient synthesis of D-myo-inositol-l,4,5-trisphosphate to be devised. 

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