Azido cycloaddition

In 2005, an amphiphiUc ABA triblock polymer capped with Cgo at both ends was prepared by Gan et al. via the ATRP strategy (Figure 7.9) [71]. C o was successfully incorporated at both ends of the polymer chain via azido cycloaddition. In aqueous solution, 57 aggregates to form flower micelles that can potentially be used as carriers for drug/gene deUvery application. 

Thiophene, 2-amino-3-cyano-5-phenyl-synthesis, 4, 888-889 Thiophene, 3-amino-4,5-dihydro-cycloaddition reactions, 4, 848 Thiophene, 2-amino-3-ethoxycarbonyl-ring opening, 4, 73 Thiophene, 2-amino-5-methyl-synthesis, 4, 73 Thiophene, 2-anilino-synthesis, 4, 923-924 Thiophene, aryl-synthesis, 4, 836, 914-916 Thiophene, 2-(arylamino)-3-nitro-synthesis, 4, 892 Thiophene, azido-nitrenes, 4, 818-820 reactions, 4, 818-820 thermal fragmentation, 4, 819-820 Thiophene, 3-azido-4-formyl-reactions... 

The overall pathway for the conversion of the unsaturated azido ether 281 to 2,5-dihydrooxazoles 282 involves first formation of the dipolar cycloaddition product 287, which thermolyzes to oxazoline 282 or is converted by silica gel to oxazolinoaziridine 288. While thermolysis or acid-catalyzed decomposition of triazolines to a mixture of imine and aziridine is well-documented [71,73], this chemoselective decomposition, depending on whether thermolysis or exposure to silica gel is used, is unprecedented. It is postulated that acidic surface sites on silica catalyze the triazoline decomposition via an intermediate resembling 289, which prefers to close to an aziridine 288. On the other hand, thermolysis of 287 may proceed via 290 (or the corresponding diradical) in which hydrogen migration is favored over ring closure. 

Ketenes also add to imines in 2 + 2 cycloadditions giving the important g-lactams (20). The reglochemistry is predictable as the nitrogen is the nucleophilic atom in the imine. This is true even in conjugated imine (21) which gives (22) with azidoketene. The azido group can... 

Recently, Li et al. have reported an efficient 1,3-dipolar cycloaddition of azides with electron-deficient alkynes without any catalysts at room temperature in water.128 The reaction has been applied successfully to the coupling of an azido-DNA molecule with electron-deficient alkynes for the formation of [l,2,3]-triazole heterocycle (Eq. 4.66). 

By combining several click reactions, click chemistry allows for the rapid synthesis of useful new compounds of high complexity and combinatorial libraries. The 2-type reaction of the azide ion with a variety of epoxides to give azido alcohols has been exploited extensively in click chemistry. First of all, azido alcohols can be converted into amino alcohols upon reduction.70 On the other hand, aliphatic azides are quite stable toward a number of other standard organic synthesis conditions (orthogonality), but readily undergo 1,3-dipolar cycloaddition with alkynes. An example of the sequential reactions of... 

Owing to flexibility in the substrate, the TycATE was also used to synthesize a variety of novel cyclic structures. Inclusion of a propargylated amino acid into the linear substrate allowed the synthesis of over 247 macrocyclic glycopeptides, where azido-sugars were coupled onto the cyclized alkyne via copper-catalyzed 1,3-dipolar cycloaddition [44] (Figure 13.12). 

Click chemistry refers to the reaction between an azido functional group and an alkyne to form a [3 + 2] cycloaddition product, a 5-membered triazole ring. This reaction has been used for many years in organic synthesis to form heterocyclic rings. Normally, the click reaction requires high temperatures, and this was the main reason that it was not used as a bioconjugation tool. However, it was discovered that in aqueous solutions and in the presence of Cu(I), the reaction kinetics are dramatically accelerated to provide high yields even at room temperature and ambient pressures (Rostovtsev et al., 2002 Tornoe et al., 2002 Sharpless et al., 2005). 

Figure 17.3 Maleimide-modified glass slides (1) can be derivatized using two chemoselective ligation reactions to create biotin modifications. In the first step, alkyne-PEG4-cyclopentadiene linkers (2) are added to the maleimide groups using a Diels-Alder reaction. In the second reaction, an azido-PEG4-biotin compound (3) is reacted with the terminal alkyne on the slide using click chemistry to result in another cycloaddition product, a triazole ring.

Ethyl 3-azido-l-methyl-177-indole-2-carboxylate 361 is prepared in 70% yield by diazotization of amine 360 followed by substitution of the created diazonium group with sodium azide. In cycloadditions with nitrile anions, azide 361 forms triazole intermediates 362. However, under the reaction conditions, cyclocondensation of the amino and ethoxycarbonyl groups in 362 results in formation of an additional ring. This domino process provides efficiently 4/7-indolo[2,3-i ]l,2,3-triazolo[l,5- ]pyrimidines 363 in 70-80% yield (Scheme 57) <2006TL2187>. 

Table 8 Cycloaddition reactions of 5-azido-1,2,4-triazole derivatives with alkynes (Equation 22)... 

The 1,3-dipolar cycloaddition of azido-l,2,5-oxadiazoles (azidofurazans) to dicarbonyl compounds has been studied and a new procedure for the synthesis of (l,2,3-triazol-l-yl)-l,2,5-oxadiazoles was proposed <2002MC159>. The cycloaddition of 4-amino-3-azido-l,2,5-oxadiazole 168 to nitriles with activated methylene groups has been studied, and 3-amino-4-(5-amino-l/7-l,2,3-triazol-l-yl)-l,2,5-oxadiazoles 169 and the products of their Dimroth rearrangement 170 have been synthesized <2004MC76>. 

The 1,3-dipolar cycloaddition of azidofurazans to acetylenes afforded 1,2,3-triazoles linked with furazan cycle <2000CHE91>. Treatment of 3-azido-2-amino-l,2,5-oxadiazole 194 with ethyl 4-chloroacetoacetate gives access to the functionalized [l,2,3]-triazoles 195, which are good precursors for GSK-3 inhibitors with favorable water solubility (Equation 38) <2003JME3333>. 

One has to realize that the cycloaddition products, namely the tetrazoles, are in equilibrium with the open chain azido form. The aromatic moiety of the phenol and aniline derivatives not only favors the formation of the cyclic... 

In another example (Scheme 8), the intramolecular cycloaddition of an azido functionality onto an enone group afforded bicyclic derivatives with bridgehead iV atoms. The cyclopentenone derivative 28 afforded the indolizidinone 30 through the proposed compound 29 which might react through a diradical intermediate or through a betaine intermediate <2002TL5385>. 

A substantial amount of research has been carried out in the field of tetrazole-fused sugars (rhamnose, mannose, and glucose derivatives) - mostly because of the biological importance of these derivatives. In many of these cases synthesis of the fused tetrazole moieties has been perfected by intramolecular 1,3-cycloaddition reactions with participation of a cyano and azido group. Some of these results are shown in Schemes 26 and 27. 

Two studies appeared during the recent years where fused tetrazolodiazines have been synthesized by application of intramolecular 1,3-dipolar cycloaddition of a cyano and an azido moiety. These transformations are depicted in Scheme 23. 

Several routes to the pyrrolo[l,2-f][l,2,3]triazole skeleton have been described. Intramolecular dipolar cycloaddition of azido-alkenes or alkynes seems to be the most convenient process, although the cyclization efficiency seems to be highly substrate dependent (Scheme 16) <2002JA2134, 2003T1477, 2005SL2187, 2005TL8639>. The formation of this bicyclic system by an intramolecular Heck reaction is an attractive alternative. The recent syntheses of sulfamides by intramolecular cyclization of alkenes or allenes offer a complementary route to the classical... 

A subsequent report outlined the synthesis of a diastereomer of tetrazole 58 that used similar methodology <1997TL4655>. Treatment of nitrile mesylate 60 with sodium azide affords D-talonotetrazole 62, presumably by intramolecular [1,3] dipolar cycloaddition of a 4-azido-4-deoxy-D-talonitrile intermediate 61. Acid hydrolysis affords the deprotected tetrazole 63 (Scheme 5). 

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