Dipolarophiles intramolecular cycloadditions

The reaction is illustrated by the intramolecular cycloaddition of the nitrilimine (374) with the alkenic double bond separated from the dipole by three methylene units. The nitrilimine (374) was generated photochemically from the corresponding tetrazole (373) and the pyrrolidino[l,2-6]pyrazoline (375) was obtained in high yield 82JOC4256). Applications of a variety of these reactions will be found in Chapter 4.36. Other aspects of intramolecular 1,3-dipolar cycloadditions leading to complex, fused systems, especially when the 1,3-dipole and the dipolarophile are substituted into a benzene ring in the ortho positions, have been described (76AG(E)123). 

The importance of the 1,3-dipolar cycloaddition reaction for the synthesis of five-membered heterocycles arises from the many possible dipole/dipolarophile combinations. Five-membered heterocycles are often found as structural subunits of natural products. Furthermore an intramolecular variant makes possible the formation of more complex structures from relatively simple starting materials. For example the tricyclic compound 10 is formed from 9 by an intramolecular cycloaddition in 80% yield ... 

The intramolecular cycloaddition of munchnone intermediates (derived from the cyclodehydration of A-acyl amino acids) with 1,3-dipolarophiles was employed to construct the mitomycin skeleton. Thus, heating alkynyl acids 23 with acetic anhydride forms the intermediates 24 which undergo cyclization with loss of carbon dioxide to afford the 4-oxo-tetrahydroindoles 25 <96TL2887>... 

According to general (or principal) Scheme 2.211a, the enolate group of nitrone (433), generated on treatment with LDA, acts as the dipolarophile on attacking the nitrone group. The bicyclic compound (434) is obtained from a spontaneous intramolecular cycloaddition (Scheme 2.212) (703). 

Recently, dipolarophile 1)13 (fumaronitrile) (777) has been used in the synthesis of indolizine lactone (677). Both, intermolecular and intramolecular cycloadditions were studied. Intermolecular 1,3-cycloaddition of nitrone (671) to D13 led to the formation of isoxazolidine (672). Subsequent deprotection and esterification of the obtained alcohol (673) with (674) gave isoxazolidine (675) in 65% yield. Ester (675), when refluxed in xylene for 10 min, after elimination of fumaronitrile by cyclo-reversion, underwent spontaneously intramolecular cycloaddition to give the tricyclic cycloadduct (676) in 84% yield (Scheme 2.291). 

While the perfluorinated acetates do prefer insertion, they are still capable of forming 1,3-dipoles and have demonstrated interesting effects on the regioselectivity of intramolecular cycloaddition reactions, presumably through Lewis acid-mediated effects on the dipolarophile [83]. Other chemoselectivity effects have been noted in the intramolecular cycloaddition reactions and may or may not be partially induced by conformation and sterics [84]. It was further demonstrated thaL when possible, O-H insertion is the predominant outcome over other types of insertion for rhodium]II)-car-benes, independently of the catalyst. However, cycloaddition reactions have been demonstrated to be hgand-dependent [85]. 

The addition to alkenes normally leads to unstable adducts that lose carbon dioxide under the reaction conditions. The intramolecular cycloaddition of the sydnone (30) takes place at room temperature, however (Equation (5)) and the cycloadduct (31) has been characterized <86HCA927>. The unstable species formed by the loss of carbon dioxide are also azomethine ylides. It is therefore possible for a second 1,3-dipolar addition to take place, as illustrated in Scheme 6 for the reaction of 3-phenylsydnone with Al-phenylmaleimide <86TL317,92JA8414>. This 2 1 addition has been used as the basis of a synthesis of polyimides. Imides of the type (32) were used as the dipolarophiles and their reaction with 3-phenylsydnone gave linear polymers <87MM726>. 

Elsewhere, Heaney et al. (313-315) found that alkenyloximes (e.g., 285), may react in a number of ways including formation of cyclic nitrones by the 1,3-APT reaction (Scheme 1.60). The benzodiazepinone nitrones (286) formed by the intramolecular 1,3-APT will undergo an intermolecular dipolar cycloaddition reaction with an external dipolarophile to afford five,seven,six-membered tricyclic adducts (287). Alternatively, the oximes may equilibrate to the corresponding N—H nitrones (288) and undergo intramolecular cycloaddition with the alkenyl function to afford five,six,six-membered tricyclic isoxazolidine adducts (289, R = H see also Section 1.11.2). In the presence of an electron-deficient alkene such as methyl vinyl ketone, the nitrogen of oxime 285 may be alkylated via the acyclic version of the 1,3-APT reaction and thus afford the N-alkylated nitrone 290 and the corresponding adduct 291. In more recent work, they prepared the related pyrimidodiazepine N-oxides by oxime-alkene cyclization for subsequent cycloaddition reactions (316). Related nitrones have been prepared by a number of workers by the more familiar route of condensation with alkylhydroxylamines (Scheme 1.67, Section 1.11.3). 

The combination of the geometrical preference of the tether and the stereochemical preference of the dipolarophile substituent can be seen in the intramolecular cycloadditions of alkyl nitronates, (Scheme 2.6) (99). When the tether is restricted to two atoms, only the endo approach of the tether is observed in up to a 100 1 ratio, independent of the configuration of the disubstituted dipolarophile. However, in the case of a three-atom linker, there exists a matched and mismatched case with respect to the observed stereoselectivities. With a (Z)-configured dipolarophile, only the exo isomer was observed since the ester moiety also approaches on the exo to the nitronate. However, with an ( )-configured dipolarophile, the ester group is forced to approach in an endo manner to accommodate an exo approach of the tether, thus leading to lower selectivity. 

The intramolecular cycloaddition of a silyl nitronate bearing a dipolarophilic appendage provides easy access to fused, bicyclic isoxazolidines (22). This process, in general, is very facile, and has allowed the use of unfunctionalized alkenes as dipolarophiles (Table 2.39) (106,124). Thus, a silyl nitronate bearing an allyl group will undergo the [3 + 2] cycloaddition at room temperature over 15 h to provide the corresponding isoxazoline upon acidic workup in moderate yield. 

However, by considering models of the anti configured ylide (Fig. 3.18), it was concluded that the inclusion of a three-carbon tether forces the reactive centers to be too sterically constrained to suffer intramolecular cycloaddition with an alkyne dipolarophile. Conversely, the syn ylide is able to achieve the correct approach for such a process, despite the steric interaction with the phenyl ring. Extension of the interim chain by one methylene unit using 6-heptynal, introduced a greater degree of flexibility into the system, allowing for the formation of the expected diaster-eoisomers (Scheme 3.101). 

Epoxide 96 was prepared such that photolytic conversion to the carbonyl ylide could be followed by an intramolecular cycloaddition with the tethered pendant olefin. However, photolysis of epoxide 96 led only to the formation of the regio-isomer 97 and the aldehyde 98 with no evidence of the corresponding cycloadduct. It was presumed that 97 arose from the ylide by thermal recyclization to the epoxide while 98 could form through the loss of a carbene from the ylide. The failure of the tethered alkene to undergo cycloaddition may have resulted from a poor trajectory for the cycloaddition. An extended analogue (99) allowed greater flexibility for the dipolarophile to adopt any number of conformations. Photolysis of epoxide 99 did lead to formation of the macrocyclic adduct 100, albeit in modest yields. 

Reactions of thiocarbonyl ylides with nitriles are scarce. Simple nitriles do not undergo bimolecular cycloaddition (171). There is, however, a single example of an intramolecular case that was reported by Potts and Dery (24c,62). By analogy to the intramolecular cycloaddition with acetylenic dipolarophiles (Scheme 5.40), the primary product derived from the reaction of a thiocarbonyl ylide with a nitrile group undergoes a subsequent elimination of phenylisocyanate to give the fused 1,3-thiazole (131). 

A number of intramolecular cycloadditions of alkene-tethered nitrile oxides, where the double bond forms part of a ring, have been used for the synthesis of fused carbocyclic structures (18,74,266-271). The cycloadditions afford the cis-fused bicyclic products, and this stereochemical outcome does not depend on the substituents on the alkene or on the carbon chain. When cyclic olefins were used, the configuration of the products found could be rationalized in terms of the transition states described in Scheme 6.49 (18,74,266-271). In the transition state leading to the cis-fused heterocycle, the dipole is more easily aligned with the dipolarophile if the nitrile oxide adds to the face of the cycloolefin in which the tethering chain resides. In the trans transition state, considerable nonbonded interactions and strain would have to be overcome in order to achieve good parallel alignment of the dipole and dipolarophile (74,266). 

The intramolecular cycloaddition of nitrile oxides to substituted furans was reported to occur with low stereoselectivity (274). Inserting a stereogenic unit within the chain connecting the dipole and dipolarophile did not increase the stereoselectivity (274). 

Intramolecular cycloaddition of nitrile ylides to olefinic dipolarophiles linked to the dipole by a three-atom chain leads to pyrazoles fused to five-membered rings. Work on stereoselectivity in such reactions has been carried out using the reactant 266 in which the alkene moiety is linked to the C-terminus via a tether that incorporates an enantiomerically pure (R) stereogenic group (165). Both diastereo-isomers 267 and 268 were isolated and it was found that the reaction showed moderate stereoselectivity favoring 267. 

With respect to the large number of unsaturated diazo and diazocarbonyl compounds that have recently been used for intramolecular transition metal catalyzed cyclopropanation reactions (6-8), it is remarkable that 1,3-dipolar cycloadditions with retention of the azo moiety have only been occasionally observed. This finding is probably due to the fact that these [3+2]-cycloaddition reactions require thermal activation while the catalytic reactions are carried out at ambient temperature. A7-AUyl carboxamides appear to be rather amenable to intramolecular cycloaddition. Compounds 254—256 (Scheme 8.61) cyclize intra-molecularly even at room temperature. The faster reaction of 254c (310) and diethoxyphosphoryl-substituted diazoamides 255 (311) as compared with diazoacetamides 254a (312) (xy2 25 h at 22 °C) and 254b (310), points to a LUMO (dipole) — HOMO(dipolarophile) controlled process. The A -pyrazolines expected... 

Although the first attempts at asymmetric azomethine ylide cycloadditions were reported by Padwa s group (92), the acyclic azomethine ylides chosen, bearing an a-chiral alkyl substituent on the nitrogen, showed poor diastereoselectivities (93,94). When the chiral center is fixed in a cyclic structure (95) or when chirality is introduced in an intramolecular cycloaddition system (96-98), high selectivities have been accomplished. There are only a few examples known of asymmetric cycloadditions of achiral azomethine ylides to chiral dipolarophiles where cyclic azomethine ylides (99,100) or cyclic chiral dipolarophiles (94) were used. 

Tamura et al. (170-172) discovered that, when reactions of ester-substituted nitrones with allylic alcohols are performed in the presence of an equimolar amount of titanium tetraisopropoxide under heating or at room temperature, transesterification takes place to form new nitrones bearing an inner alkene dipolarophile. The resulting nitrone substrates undergo regio- and stereoselective intramolecular cycloaddition reactions to give the ring-fused isoxazolidines (Scheme 11.52). This tandem transesterification/[3 + 2]-cycloaddition method leads to the selective... 

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