Nitronates intermolecular

The mechanism for the formation of ( )-169 is explained in terms of an intermolecular nucleophilic dimerization. Nucleophilic addition of C-3 of 19 to the 3 position of the initially generated cation 168 gives an imine-nitrone... 

Inter [4+2]/inter [3+2] The tandem intermolecular [4+2]/intermolecular [3+2] cycloadditions create bicyclic nitroso acetals with up to six stereogenic centers, which can be controlled by the choice of the stereochemistry of each component and the Lewis acids. The nitronate derived from 2-nitrostyrene and 1-trimethylsilyloxycyclohexene reacts with methyl acrylate to give the nitroso acetal in good yield and high diastereoselectivity (Eq. 8.107).154... 

Intermolecular Reactions Intermolecular 1,3-dipolar cycloaddition reactions of nitrones to olefins seem to be the most studied. They are widely used for the synthesis of different enantiomerically pure compounds, including biologically active ones. For example, two new glycosidase inhibitors have been obtained by the nitrone cycloaddition strategy (Fig. 2.32) (733). 

Cycloaddition of nitrone (508) to allyl alcohol at ambient temperature gave a mixture of four cycloadducts in a 23 5 4 1 ratio (Scheme 2.244). All of the adducts (509) are derived from the regiochemical approach opposite to the intramolecular pathway (Fig. 2.35). Formation of the cycloadduct in the intramolecular cycloaddition reaction is ascribed to a high preference for an endo-syn transition state, due to the constraint imposed by the short, three atom connecting chain (116). The major product in the intermolecular cycloaddition reaction was the exo-anti -(509) adduct (Scheme 2.244 and Fig. 2.35). 

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). 

I. Intermolecular [3+2]-Addition of Nitronates to Olefins Of all known types of nitronates (see Section 3.2), alkyl- and silyl nitronates as well as cyclic C5-C6 nitronates are involved in [3+ 2]-cycloaddition reactions. Detailed comparative kinetic studies for different types of nitronates have not been reported. However, a few data (162, 336, 337) allow one to deduce some sequences (Chart 3.10). 

Six-membered Cyclic Nitronates As can be seen from Chart 3.14, the range of olefins involved in intermolecular [3 + 2] -cycloadditions with six-membered nitronates, is substantially wider (49, 91, 92, 97, 138, 143, 146, 151, 156, 160-162, 370-373) compared to five-membered nitronates. 

Intermolecular [3 + 2]-addition to a triple bond The [3+ 2]-addition reactions of acetylenes with nitrones never afford normal adducts instead, they produce the corresponding aziridines (381). An analogous situation is observed for most of nitronates (93, 95, 382 (Scheme 3.132). 

Intramolecular [3+2]-Cycloaddition ofNitronates These reactions are more efficient than analogous intermolecular transformations of nitronates as [1,3]-dipoles, and, consequently, activation of the dipolarophilic fragment is not required. However, another problem arises, that is, the construction of the starting substrate combining the nitronate fragment and the C,C double bond in the required positions. 

Points b to d should be explained in more detail for intermolecular cycloaddition reactions of acyclic nitronates A with monosubstituted olefins. Regioselectivity of the process is determined by the character of the approach of olefin to the dipole (head-to-head or head-to-tail, (Chart 3.16, part (1)). In the former case, the substituent R is bound to the C-5 atom in the latter case, to the C-4 atom. 

Silyl nitronates containing chiral inductors have not been as yet used in intermolecular [3 + 2]-cycloaddition reactions. In this case, the facial discrimination was generally created by introducing chiral nonracemic fragments into dipolarophiles (see review 433). 

In intramolecular [3+ 2]-cycloaddition reactions, silyl nitronates also lead to substantially higher stereoselectivity than intermolecular reactions (see, e.g., Scheme 3.178) (193). 

Intermolecular coupling between ketones and 0-methyl oximes, hydrazones and nitrones is achieved on reduction at a tin cathode in isopropanol [105]. It is not clear which of the reacting species accepts the initial electron in these processes. The reaction with 0-methyloximes, followed by catalytic reduction of the first formed O-methylhydroxylamine, is a convenient synthetic route to 2-amino-alcohols. 

Isoxazolidines from Intermolecular Nitrone Cycloaddition Reactions. 59... 

It has long been recognized that nitrone cycloadditions may allow access to spirocyclic ring systems. Such systems are inherently difficult to synthesize by conventional methods, yet are a structural component of a number of biologically active natural materials. Two common strategies have emerged for spirocycle generation from exocyclic or endocyclic nitrones (Scheme 1.45). In the exocyclic version, the carbon atom (arrowed) of the nitrone C=N double bond of dipole 209 carries a cyclic substitutent and thus an intermolecular cycloaddition reaction will... 

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