3 + 3-cycloaddition, amides

Clearly, in the case of (66) two amide tautomers (72) and (73) are possible, but if both hydroxyl protons tautomerize to the nitrogen atoms one amide bond then becomes formally cross-conjugated and its normal resonance stabilization is not developed (c/. 74). Indeed, part of the driving force for the reactions may come from this feature, since once the cycloaddition (of 72 or 73) has occurred the double bond shift results in an intermediate imidic acid which should rapidly tautomerize. In addition, literature precedent suggests that betaines such as (74) may also be present and clearly this opens avenues for alternative mechanistic pathways. 

Alkylarylisoxazoles can be obtained from the cycloaddition of nitrile Af-oxides to substituted alkynes or alkenes (Section 4.16.4.1.2(ii)), and from the condensation of the 1,4-dilithio oximes (358) with benzonitriles (72JHC183) or amides (78JOC3015). 

Other isocyanates undergo [2 + 2] cycloaddition, but only with very electron rich alkenes. Thus phenyl isocyanate gives /3-lactams with ketene acetals and tetramethoxyethylene. With enamines, unstable /3-lactams are formed if the enamine has a /3-H atom, ring opened amides are produced 2 1 adducts are also found. Photochemical addition of cis- and traH5-stilbene to phenyl isocyanate has also been reported (72CC362). 

The trivial name bisnorisopenicillin has been coined for the 6-acylamino-3-thia-l-a2abicyclo[3.2.0]heptane-2-carboxylic acid (85) structural class. While not extensively investigated, an example of this class has been prepared as shown in Scheme 66 (78JMC413). The following features of this sequence are noteworthy (a) the exclusively cis cycloaddition to form intermediate (86) and (b) the use of the 2,4-dimethoxybenzyl amide blocking group. 

The [2 + 2] cycloaddition reaction of A -benzyl-l,4-dihydropyridine 34b with acrylonitrile, followed by catalytic reduction gave two pairs of diastereoisomeric amides 36 and 37 with a low diastereomeric excess, probably due to the large distance between the asymmetric center and the site of acrylonitrile attack. Compounds 36 and 37 were resolved into the four individual diastereoisomers (ca 5% for compound 36 and 15% for 37) [97JCR(M)321], Irradiation of 1,4-dibenzyl-1,4,5,6-tetrahydropyridine 38 in the presence of 29 gave two stereoisomers. 

In a more recent study on 1,3-dipolar cycloaddition reactions the use of succi-nimide instead of the oxazolidinone auxiliary was introduced (Scheme 6.19) [58]. The succinimide derivatives 24a,b are more reactive towards the 1,3-dipolar cycloaddition reaction with nitrone la and the reaction proceeds in the absence of a catalyst. In the presence of TiCl2-TADDOLate catalyst 23a (5 mol%) the reaction of la with 24a proceeds at -20 to -10 °C, and after conversion of the unstable succinimide adduct into the amide derivative, the corresponding product 25 was obtained in an endojexo ratio of <5 >95. Additionally, the enantioselectivity of the reaction of 72% ee is also an improvement compared to the analogous reaction of the oxazolidinone derivative 19. Similar improvements were obtained in reactions of other related nitrones with 24a and b. 

Another conceptually unique approach in alkene aziridination has come from Johnston s labs. These workers shrewdly identified organic azides as nitrene equivalents when these compounds are in the amide anion/diazonium resonance form. Thus, when a range of azides were treated with triflic acid and methyl vinyl ketone at 0 °C, the corresponding aziridines were obtained, in synthetically useful yields. In the absence of the Bronsted acid catalyst, cycloaddition is observed, producing triazolines. The method may also be adapted, through the use of unsaturated imi-des as substrates, to give anti-aminooxazolidinones (Scheme 4.25) [32]. 

Triazoles have been obtained via microwave-assisted [3-i-2] cycloaddition, under solvent-free conditions [54], starting from organic azides and acetylenic amides at 55 °C for 30 min (Scheme 23). The complete conversion of the reagents into AT-substituted-1,2,3-triazoles 69 was achieved without decomposition and side products. A control reaction carried out at the same temperature in an oil bath did not give the cycHc products, not even after 24 h of reaction time. 

The cationic pathway allows the conversion of carboxylic acids into ethers, acetals or amides. From a-aminoacids versatile chiral building blocks are accessible. The eliminative decarboxylation of vicinal diacids or P-silyl carboxylic acids, combined with cycloaddition reactions, allows the efficient construction of cyclobutenes or cyclohexadienes. The induction of cationic rearrangements or fragmentations is a potent way to specifically substituted cyclopentanoids and ring extensions by one-or four carbons. In view of these favorable qualities of Kolbe electrolysis, numerous useful applications of this old reaction can be expected in the future. 

The cycloaddition of alkynes and alkenes to nitrile oxides has been used in the synthesis of functionalised azepine systems <96JHC259>, <96T5739>. The concomitantly formed isoxazole (dihydroisoxazole) ring is cleaved by reduction in the usual way. Other routes to 1-benzazepines include intramolecular amidoalkylation <96SC2241> and intramolecular palladium-catalysed aryl amination and aryl amidation <96T7525>. Spiro-substituted 2-benzazepines have been prepared by phenolic oxidation (Scheme 5) <96JOC5857> and the same method has been applied to the synthesis of dibenzazepines <96CC1481>. 

Pyrroles can also be prepared by 1,3-dipolar cycloaddition of C-trimethylsilyl amides such as 1497 with dimethyl acetylenedicarboxylate in boihng toluene to give, via the azomethinimide 1498, 78% 1499 [45]. On employing a threefold excess of dimethyl acetylenedicarboxylate the cycloadduct 1499 is obtained in nearly quantitative yield [45] (Scheme 9.26). 

The highly ordered cyclic TS of the D-A reaction permits design of diastereo-or enantioselective reactions. (See Section 2.4 of Part A to review the principles of diastereoselectivity and enantioselectivity.) One way to achieve this is to install a chiral auxiliary.80 The cycloaddition proceeds to give two diastereomeric products that can be separated and purified. Because of the lower temperature required and the greater stereoselectivity observed in Lewis acid-catalyzed reactions, the best diastereoselectivity is observed in catalyzed reactions. Several chiral auxiliaries that are capable of high levels of diastereoselectivity have been developed. Chiral esters and amides of acrylic acid are particularly useful because the auxiliary can be recovered by hydrolysis of the purified adduct to give the enantiomerically pure carboxylic acid. Early examples involved acryloyl esters of chiral alcohols, including lactates and mandelates. Esters of the lactone of 2,4-dihydroxy-3,3-dimethylbutanoic acid (pantolactone) have also proven useful. 

Several enamines also participate in these cycloaddition reactions. For example, the addition of methyl lithium to benzaldehyde 5 and the sequential introduction of the vinylogous amide and magnesium bromide results in the cycloaddition elimination product chromene 63 (method G, Fig. 4.33).27 The introduction of methyl magnesium bromide to a solution of the benzaldehyde 5 and two equivalents of the morpholine enamine produces the cycloadduct 64 in 70% yield with better than 50 1 diastereoselectivity (method F). Less reactive enamides, such as that used by Ohwada in Fig. 4.4, however, fail to participate in these conditions. 

There are two important rhodium-catalyzed transformations that are broadly used in domino processes as the primary step. The first route is the formation of keto carbenoids by treatment of diazo keto compounds with Rh11 salts. This is then followed by the generation of a 1,3-dipole by an intramolecular cyclization of the keto carbenoid onto an oxygen atom of a neighboring keto group and an inter- or intramolecular 1,3-dipolar cycloaddition. A noteworthy point here is that the insertion can also take place onto carbonyl groups of aldehydes, esters, and amides. Moreover, cycloadditions of Rh-carbenes and ring chain isomerizations will also be discussed in this section. 

In another variant of these intramolecular 1,3-dipolar cycloadditions, the alkyne-containing amino acid amide 183, when reacted with acetic anhydride, produces a zwitterionic thiazolo-oxazolium intermediate, which may then react intramolecularly with the dipolarophile and give the triheterocycle 184 < 1999J(P 1) 1219, 2002JOC4045> (Equation 18). The benzo-fused analogue 185 is obtained similarly (Equation 19). 

More recently in 2001, Winkler and Kwak reported methodology designed to access the pyrrolidine core of the hetisine alkaloids via a photochemical [2+2], retro-Mannich, Mannich sequence (Scheme 1.3) [26]. In a representative example of the methodology, vinylogous amide 42 was photo-irradiated to give the [2+2] cycloaddition product 43. Heating cyclobutane 43 in ethanol provided enamine 44 via a retro-Mannich reaction. Exposure of enamine 44 to acidic conditions then effected a Mannich reaction, resulting in pyrrolidine 45. 

The feasibility of azomethine ylide generation from 7 and intramolecular dipolar cycloaddition was examined under a variety of conditions. For example, activation of vinylogous amide 71 with BzOTf [41] followed by desilylation with TBAT led to complex mixtures of products. Likewise, using MeOTf as the activating agent yielded similar results. Significantly, none of these protocols furnished the desired pyrrolidine 73. Only decomposition of the silylpyridinone to form unidentified products was observed, despite the fact that quantitative O-methylation of the... 

The acetylenic amide 294 is converted on irradiation in benzene into two oxidized dimers 295.243 A complex pathway involving a [ 4 + Kl cycloaddition followed by oxidation and photorearrangement has been proposed. 

A novel intramolecular photocycloaddition involving vinylogous amides and allenes led to an interesting type lb entry to functionalized pyrroles <060L4031>. For example, photolysis of allene 11 provided fused pyrrole 12 via a [2+2] cycloaddition and retro-Mannich reaction. 

Tandem azidination- and hydroazidination-Hiiisgen [3 +2] cycloadditions of ynamides are regioselective and chemoselective, leading to the synthesis of chiral amide-substituted 1,2,3-triazoles <06OBC2679>. A series of diversely l-substituted-4-amino-l,2,3-triazoles 132 were synthesized by the copper-catalyzed [3+2] cycloaddition between azides 130 and ynamides 131 <06T3837>. 

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