Chiral Dipolarophiles

The use of chiral dipolarophiles, such as the nitrile oxide additions to chiral furanones, have received much interest. The cycloaddition of various 1,3-dipolar reagents to the enantiomeric ally pure furanones 170 and 227 showed excellent diastereofacial control by the menthyloxy substituent, especially in nitrone and nitrile oxide additions (cf. Table II) (88TL5317). 

The reactions of some SENAs with chiral dipolarophiles (284a,b) were also described (411) (Scheme 3.177, Eq. 2). It should be noted that the yields of the target cycloadducts were not always high due to steric hindrance in vicinally substituted dipolarophiles. Also the facial selectivity is rather moderate. 

Various chiral dipolarophiles have been used in the asymmetric synthesis of hexahydro-isoxazolo[2,3- ]pyridines. Examples include // / -2-methylcnc-l, 3-dithiolane 1,3-dioxide 83 <1998JOC3481>, chiral vinyl sulfoxide 85 <1997TA109>, or chiral dioxolanes <2001TA1747> (Scheme 27). 

This section shall consider the effects of substitution on both the nitronate as well as the dipolarophile, as they relate to both the inter- and intramolecular versions of the dipolar cycloaddition. Also included will be a discussion of facial selectivity in the reaction of a chiral dipolarophile. 

In a second report on the use of chiral dipolarophiles, the cycloadditions of silyl nitronates with 123 and 124 provide modest facial selectivity (Table 2.37) (35). Unfortunately, the yields of the cycloadducts are only moderate because of the steric bulk of the dipolarophile. 

Koizumi and co-workers (38) reported the first asymmetric synthesis of (15)-(—)-a-tropanol (149) via a 1,3-dipolar cycloaddition protocol. Treatment of the chiral dipolarophile 150 with 151 in tetrahydrofuron (THF) delivered cycloadducts exo-152 and endo-153. Although the reaction proceeded with low facial selectivity,... 

The azomethine ylide was generated by treatment of A -benzyl-Af-(methoxy-methyl)-trimethylsilylmethylamine (155) with TFA and underwent the required cycloaddition step with chiral dipolarophile 156, stereocontrol being induced by Evan s auxiliary. The ot, p-unsaturated acid dipolarophile was tethered to a chiral oxazoladine in two easy, high-yielding steps. The auxiliary served three purposes to give asymmetric control to the reaction, to allow for separation of the reaction products by generating column separable diastereoisomers, and hnally to activate the olefin in the cycloaddition step (Scheme 3.45). 

Williams and Fegley (40) utilized his chiral template (Section 3.2.3) as a chiral dipolarophile in the concise synthesis of 5 -( )-cucurbitine, a naturally occurring amino acid isolated from species of pumpkin, that acts as a growth inhibitor to... 

In synthetic efforts toward the DNA reactive alkaloid naphthyridinomycin (164), Gamer and Ho (41) reported a series of studies into the constmction of the diazobicyclo[3.2.1]octane section. Constmction of the five-membered ring, by the photolytic conversion of an aziridine to an azomethine ylide and subsequent alkene 1,3-dipolar cycloaddition, was deemed the best synthetic tactic. Initial studies with menthol- and isonorborneol- tethered chiral dipolarophiles gave no facial selectivity in the adducts formed (42). However, utilizing Oppolzer s sultam as the chiral controlling unit led to a dramatic improvement. Treatment of ylide precursor 165 with the chiral dipolarophile 166 under photochemical conditions led to formation of the desired cycloadducts (Scheme 3.47). The reaction proceeded with an exo/endo ratio of only 2.4 1 however, the facial selectivity was good at >25 1 in favor of the desired re products. The products derived from si attack of the ylide... 

The reaction was further developed to form a wide range of p-lactam-based products (52). Treatment of the racemic ylide processor 186 with suitable sulfur-based thiocarboxylate or thiocarbonate dipolarophiles gave rise to the expected racemic penams 189 and 190 and penems as single regioisomers (Scheme 3.54). Once again, the use of the chiral dipolarophile 186 furnished the cycloaddition product 191 with complete enantiomeric integrity. Similarly, the use of aldehydes... 

The chiral dipolarophiles of Garners and Dogan, which were derived from Oppolzer s sultam, have been previously discussed in Section 3.2.1 and, in an extension to these results, the sultam moiety was used as the stereodirecting unit in enantiopure azomethine ylides (56). The ylides were generated either by thermo-lytic opening of N-substituted aziridines or by the condensation of the amine functionality with benzaldehyde followed by tautomerism. These precursors were derived from the known (+)-A-propenoylbornane-2,10-sultam. Subsequent trapping of the ylides with A-phenylmaleimide furnished the cycloaddition products shown in Schemes 3.60 and 3.61. 

Amino acids can be used as azomethine yhde precursors, although the stereo-genic center is by necessity lost and require reaction with chiral dipolarophiles to circumvent the problem of absence of stereocontrol. Harwood et al. (57) demonstrated that the chirality of the original amino acid could be preserved by derivatization to give back not only the original stereocenter, but further stereoinduction. 

Chiral bicyclic lactams have been successfully utilized by Meyers as chiral dipolarophiles in highly diastereoselective azomethine ylide cycloadditions (73). Treatment of the ylide precursor 218 with the unsaturated, non-racemic dipolar-ophile 219 in the presence of a catalytic amount of TFA led to the formation of tricyclic adducts 220 and 221 in excellent yields (85-100%). The diastereofacial preference for the reaction was dependent on the nature of R with a methyl group... 

Nitrile Oxide Cycloadditions with Chiral Dipolarophiles. 386... 

The relative rate constants (fe ) do not account for the fact that approach of the nitrile oxide to the 7i-bond can occur from both olefinic diastereofaces with two regioisomeric modes of reaction (Scheme 6.14). In the case of achiral 1-alkenes, only one regioisomer is formed. With chiral dipolarophiles, preference for one of the two is usually found (diastereodifferentiation). The relative diastereofacial reactivity (fejH) is used to evaluate this effect (121). With ethylene, there are four possibilities of attack (two for each face corresponding to the different regio-isomers), and the of each is set as 0.25. In diastereodifferentiating cycloadditions, such as those with a-chiral alkenes, the major isomer generally results... 

TABLE 6.3. RELATIVE REACTIVITIES (k,) AND RELATIVE DIASTEREOFACIAL RATES (k,K) OF CHIRAL DIPOLAROPHILES" ... 

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. 

The most common method for inducing asymmetry in 1,3-dipolar cycloadditions is by the application of chiral 1,3-dipoles, chiral dipolarophiles, or both, the latter always being the case for intramolecular reactions (5). First the reaction of chiral 1,3-dipoles will be described, then the reactions of chiral dipolarophiles, and finally the intramolecular reactions. In this chapter we have chosen to treat the diaster-eoselective reactions employing chiral auxiliaries separately in Section 12.3. 

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