Cycloaddition reactions facial selectivity

Facial selectivities of cycloaddition reactions of 5,5-disnbstitnted cyclopentadienes have been stndied by Inagaki and Ishida [32, 44, 45] and other groups [40],... 

This reviews contends that, throughout the known examples of facial selections, from classical to recently discovered ones, a key role is played by the unsymmetri-zation of the orbital phase environments of n reaction centers arising from first-order perturbation, that is, the unsymmetrization of the orbital phase environment of the relevant n orbitals. This asymmetry of the n orbitals, if it occurs along the trajectory of addition, is proposed to be generally involved in facial selection in sterically unbiased systems. Experimentally, carbonyl and related olefin compounds, which bear a similar structural motif, exhibit the same facial preference in most cases, particularly in the cases of adamantanes. This feature seems to be compatible with the Cieplak model. However, this is not always the case for other types of molecules, or in reactions such as Diels-Alder cycloaddition. In contrast, unsymmetrization of orbital phase environment, including SOI in Diels-Alder reactions, is a general concept as a contributor to facial selectivity. Other interpretations of facial selectivities have also been reviewed [174-180]. 

Kahn and Hehre straightforwardly extended this idea to the description of Jt-facial selectivity in Diels Alder reactions. They simply stated cycloaddition involving electron-rich dienes and electron-poor dienophiles should occur preferentially onto the diene face which is the more nucleophilic and onto the diene face which exhibits the greater electrophihcity (Scheme 40) [49],... 

Dienes 581 and 583 undergo smooth Diels-Alder cycloaddition with a wide range of dienophiles affording the corresponding products. Their reaction with PTAD gives the respective products 582 and 584 with complete Jt-facial selectivity (Equations 82 and 83) <2005CEJ5136>. 

The Lewis acid-promoted [4+ 2]-cycloaddition reaction of the allenic ester 103 having a camphor-derived chiral auxiliary with cydopentadiene provided the adduct with excellent Jt-facial selection, leading to an enantioselective synthesis of (-)-/l-san-talene [92]. 

This modification is based on the consideration that such bidentate dienophiles would form rigid complexes with a chiral Lewis acid, resulting in high reactivity and a good level of TT-facial selectivity during the cycloaddition reaction. 

Our initial studies focused on the transition metal-catalyzed [4+4] cycloaddition reactions of bis-dienes. These reactions are thermally forbidden, but occur photochemically in some specific, constrained systems. While the transition metal-catalyzed intermole-cular [4+4] cycloaddition of simple dienes is industrially important [7], this process generally does not work well with more complex substituted dienes and had not been explored intramolecularly. In the first studies on the intramolecular metal-catalyzed [4+4] cycloaddition, the reaction was found to proceed with high regio-, stereo-, and facial selectivity. The synthesis of (+)-asteriscanoHde (12) (Scheme 13.4a) [8] is illustrative of the utihty and step economy of this reaction. Recognition of the broader utiHty of adding dienes across rc-systems (not just across other dienes) led to further studies on the use of transition metal catalysts to facilitate otherwise difficult Diels-Alder reactions [9]. For example, the attempted thermal cycloaddition of diene-yne 15 leads only... 

This chapter is divided into four major sections. The first (Section 2.1) will deal with the structure of both alkoxy and silyl nitronates. Specifically, this section will include physical, structural, and spectroscopic properties of nitronates. The next section (Section 2.2) describes the mechanistic aspects of the dipolar cycloaddition including both experimental and theoretical investigations. Also discussed in this section are the regio- and stereochemical features of the process. Finally, the remaining sections will cover the preparation, reaction, and subsequent functionalization of silyl nitronates (Section 2.3) and alkyl nitronates (Section 2.4), respectively. This will include discussion of facial selectivity in the case of chiral nitronates and the application of this process to combinatorial and natural product synthesis. 

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. 

The number of investigations on the enantioselective dipolar cycloaddition of nitronates is still rather limited. In the case of simple alkyl nitronates, the facial selectivity is controlled solely by the steric environment about the two faces of the chiral unit. For example, the reaction of steroid dipolarophile 270 proceeds with the nitronate approaching the Re face of the alkene (Eq. 2.23) (234). The facial selectivity is controlled by the C(19) methyl group, which blocks the Si face of the dipolarophile. Similarly, exposure of 279 to ethyl acrylate at 40 °C for 24 h, provides a single nitroso acetal (Scheme 2.21) (242). The facial selectivity is presumed to arise from steric shielding by the menthol group, however the full stereostructure has not been established. 

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,... 

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... 

Sulfmyl hydrazones, such as 68, reacting as 1-azabuta-l,3-dienes, undergo cycloaddition reactions with A -methyl-maleimide (NMM), to form tetrahydropyrrolo[3,4-. ]pyridine derivatives in low yield. The reaction occurs to form enantiomerically pure adduct 69 with complete endo- and facial selectivities (Equation 14) <200382241 >. 

A number of electrocyclic reactions under PET conditions have been reported. In this way, A-benzyl-2.3-diphcnylaziridinc (40) underwent a 3 + 2-cycloaddition with alkene and alkyne dipolarophiles to afford substituted pyrrole cycloadducts (41) via the radical cation intermediate (42) see Scheme 7.80 Elsewhere, novel arylallenes have been used as dienophiles in a radical cation-catalysed Diels-Alder cycloaddition reaction with 1,2,3,4,5-pentafluromethylcyclopentadiene, which often occurred with peri-, chemo-, facial- and stereo-selectivity.81... 

The Diels-Alder cycloaddition reaction of both cis- and trans-dienyl-2-azetidi-nones with unsymmetrical dienophiles in the presence of Lewis acid catalysts has been reported to give in regio-, stereo-, and remarkably high 7i-facial selectivity novel l,3,4-trisubstituted-2-azetidinone derivatives in good yields (I and II, Fig. 26), [306],... 

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