Intramolecular reaction nitrile oxide cyclization

An alternative to the Diels-Alder reaction for establishing the carbon skeleton is the intramolecular nitrile oxide cyclization (INOC) reaction. An (INOC) reaction was utilized by Kozikowski and MaloneyHuss [119] as the key... 

Novel polycyclic heterocyclic systems including the isoxazoline ring were described. Thus, oximes 191 and 193 in the presence of sodium hypochlorite afforded heterocycles 192 or 194, respectively (equations 83 and 84). Intramolecular cycloaddition of nitrile oxide was used in the synthesis of the A-ring fragments of la,25-dihydrovitamin D3 and taxane diterpenoids, sulphur-containing isoxazoles, fluoro-substituted aminocyclopentanols and aminocyclopentitols . New gem- and vic-disubstituted effects in such cyclization reactions have been reviewed by Jung. ... 

A previous review has highlighted the following methods of ring synthesis intramolecular cyclization of oximes, nitro alkenes, and nitrones, and [4+2] cycloaddition reactions <1996CHEC-II(6)279>. In addition to that, this review includes the intramolecular cyclization of hydroxylamines, hydroxamates, hetero-Diels-Alder [4+2], 1,3-dipolar cycloaddition of nitrile oxides to alkenes, and [3+3] cycloaddition reactions. This review does not cover cycloaddition reactions of the [4+2] [3+2] and [4+2] [3+2] [3+2] types which primarily led to heterocycle-fused oxazine ring systems. 

The convergence of the nitronate and nitrile oxide cycloadditions has allowed for the direct comparisons of yields and stereoselectivities of the two processes. For intramolecular reactions, the nitronate dipole typically required longer reaction times and/or elevated temperatures (22,98,135), however, the nitronate cycloaddition shows considerably higher diastereoselectivity (Table 2.42). Interestingly, the diastereoselectivity is dependent on the placement of a substituent on the tether. In the case of the silyl nitronate derived from 172, the diastereoselectivity is controlled by the substituent at C(l), while cyclization of the analogous nitrile oxide is governed by the substituent at C(l ) (Scheme 2.10) (124). 

The entropically enhanced cycloaddition rate of an intramolecular cycloaddition permits alkenyl nitrile oxides to cyclize in the presence of free amino groups, in contrast to intermolecular reactions. Since nitrile oxides have a wide spectrum of possible intermolecular reactions, they also react well in macro-cyclic cyclizations. 

Cyclization of nitrile oxides with a four-atom intervening chain to the alkene always leads to 5,6-fused bicylic isoxazolines possessing a bridgehead C—N double bond. This is in contrast to nitrone cycliza-tions where competition to form bridged bicyclic isoxazolidines is observed. The alkenyl oximes (73) and (74) cyclize in typical fashion via nitrile oxide intermediates (Scheme 21).33a>36 The stereochemistry of cyclization here was studied both experimentally and by calculation. The higher stereoselectivity observed with the (Z)-alkene is typical. (Z)-Alkenes cycloadd much slower than ( >alkenes in intermole-cular reactions this is attributed to greater crowding in the transition state. Thus, intramolecular cycloaddition of (Z)-alkenes depends on a transition state that is heavily controlled by steric factors. 

Modifying the aldehyde function in the pyrroles 1162 into 1,3-dipoles 1163 (nitrone) and 1167 (nitrile oxide) furnished tricyclic heterocycles 1164 and 1168 via intramolecular 1,3-dipolar cycloaddition reactions (Scheme 226) <2000T3013>. None of the isomeric bridged product 1165 is produced despite the preference for that regiochem-istry in the intermolecular reaction. Generated in situ (from the oximes 1166) nitrile oxides 1167 cyclized spontaneously to the dihydroisooxazole 1168 in quantitative yield at room temperature. 

Pyranoisoxazoles 425 have been prepared by intramolecular 1,3-dipolar cycloaddition of nitrile oxides obtained by treatment of nitrooxaheptynes with -BuLi and AC2O (Scheme 102) <2003H(59)685>. The coupling of the Ugi multicomponent reaction with the intramolecular T-oxide cyclization (Ugi/INOC) provided access to novel fused isoxazoles 426 in two steps from easily available starting materials in moderate to good overall yields... 

The routes leading from lactone A have the advantage of a chiral source of starting materials. With the two chiral centers at C24 and C25 set, the problem reduces down to elaborating the B ring with the appropriate substituents. An early solution was provided in an unusual cyclization of the B ring via an intramolecular Michael addition to the unsaturated aldehyde formed from a nitrile oxide 1,3-dipolar cycloaddition to the allyl methyl ketal of lactone A [76]. This clever use of relative stereocontrol provided by the highly constrained and predictable transition states of both key reactions unfortunately resulted in a low yield. A more conventional approach conceptualized the addition of a sulfoxide [77] to 2 to yield a masked diol-ketone precursor which cyclizes under acidic catalysis. Elimination of the sulfoxide permitted the introduction of the hydroxy substituent at C19 of the spiroketal. 

Also the reaction of a,a-dichloroisocyanate 847 with anilines was studied by Samarai and Vovk in presence of equimolar amounts of 2,4,6-trimethylbenzonitrile oxide [546]. The role of nitrile oxide consists in its unique blocking of the initial stage of the reaction to form 904 [547]. Nitrile oxide can be recovered in almost quantitative yield after completion of the process. It was estabhshed by IR spectroscopy that the reaction actually proceeds through isocyanates 901, which undergo intramolecular cyclization (Scheme 186). 

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