Electron-deficient olefins, asymmetric

Electron-deficient olefins, asymmetric epoxidation, 386-91 Electron diffraction dialkyl peroxides, 713 ozonides, 721, 723 1,2,4-trioxolanes, 740 see also Gas electron diffraction Electron-donating substituents ene reactions, 841 sulfonyl peroxides, 1005-7 Electronegative functional groups,... 

Asymmetric versions of the cyclopropanation reaction of electron-deficient olefins using chirally modified Fischer carbene complexes, prepared by exchange of CO ligands with chiral bisphosphites [21a] or phosphines [21b], have been tested. However, the asymmetric inductions are rather modest [21a] or not quantified (only the observation that the cyclopropane is optically active is reported) [21b]. Much better facial selectivities are reached in the cyclopropanation of enantiopure alkenyl oxazolines with aryl- or alkyl-substituted alkoxy-carbene complexes of chromium [22] (Scheme 5). 

Subsequently, stoichiometric asymmetric aminohydroxylation was reported.78 Recently, it was found by Sharpless79 that through the combination of chloramine-T/Os04 catalyst with phthalazine ligands used in the asymmetric dihydroxylation reaction, catalytic asymmetric aminohydroxylation of olefins was realized in aqueous acetonitrile or tert-butanol (Scheme 3.3). The use of aqueous rerr-butanol is advantageous when the reaction product is not soluble. In this case, essentially pure products can be isolated by a simple filtration and the toluenesulfonamide byproduct remains in the mother liquor. A variety of olefins can be aminohydroxylated in this way (Table 3.1). The reaction is not only performed in aqueous medium but it is also not sensitive to oxygen. Electron-deficient olefins such as fumarate reacted similarly with high ee values. 

The first example of asymmetric rhodium-catalyzed 1,4-addition of organoboron reagents to enones was described in 1998 by Hayashi and Miyaura. Significant progress has been made in the past few years. This asymmetric addition reaction can be carried out in aqueous solvent for a broad range of substrates, such as a,/ -unsaturated ketones, esters, amides, phosphonates, nitroalkenes. The enantioselectivity is always very high (in most cases over 90% ee). This asymmetric transformation provides the best method for the enantioselective introduction of aryl and alkenyl groups to the / -position of these electron-deficient olefins. 

Other interesting electron-deficient olefin substrates for the asymmetric conjugate addition include cr-acet-amidoacrylic ester SI,101 dimethyl itaconate S2,114 ct,/3-unsaturated sulfones S3,115 and alkenylphosphonate S4116 (Figure 8). 

In contrast to the limited success with vinyl sulfides as components of [2 + 2] cycloadditions, allenyl sulfides show wide applicability. As illustrated in Scheme 8.91, Lewis acid-catalyzed [2 + 2] cycloadditions of l-trimethylsilyl-l-methylthio-1,2-propadiene (333) with a variety of electron-deficient olefins 336 provide cycloadducts 337 with excellent regioselectivity but with moderate stereoselectivity [175c], Nara-saka and co-workers reported the first Lewis acid-catalyzed asymmetric [2 + 2] cycloaddition of C-l-substituted allenyl sulfides 319 with a,/3-unsaturated compounds 338 using a chiral TADDOL-titanium catalyst. The corresponding cycloadducts 339 were obtained with 88-98% ee, but a low level of trans/cis selectivity (Scheme 8.92) [169,175d[. 

Asymmetric epoxidation of olefins is an effective approach for the synthesis of enan-tiomerically enriched epoxides. A variety of efficient methods have been developed [1, 2], including Sharpless epoxidation of allylic alcohols [3, 4], metal-catalyzed epoxidation of unfunctionalized olefins [5-10], and nucleophilic epoxidation of electron-deficient olefins [11-14], Dioxiranes and oxazirdinium salts have been proven to be effective oxidation reagents [15-21], Chiral dioxiranes [22-28] and oxaziridinium salts [19] generated in situ with Oxone from ketones and iminium salts, respectively, have been extensively investigated in numerous laboratories and have been shown to be useful toward the asymmetric epoxidation of alkenes. In these epoxidation reactions, only a catalytic amount of ketone or iminium salt is required since they are regenerated upon epoxidation of alkenes (Scheme 1). 

Rhodium(l)-Catalyzed Asymmetric Addition of Organometallic Reagents to Electron-Deficient Olefins... 

Rhodium-catalyzed asymmetric conjugate addition has enjoyed uninterrupted prosperity since the first report by Hayashi and Miyaura [6]. Its high enantioselectivity and wide applicability are truly remarkable. However, some problems still remain, since the carbon atoms that can be successfully introduced by this rhodium-catalyzed reaction have been limited to sp carbons and the substrates employed have been limited mostly to the electron-deficient olefins free from sterically bulky substituents at a- and / -positions. These issues will be the subject of increasing attention in the future. 

Next to the base-catalyzed asymmetric epoxidations of electron-deficient olefins with chiral hydroperoxides described above, a few examples of uncatalyzed epoxidations with... 

One of the early examples for organocatalysis is the asymmetric Weitz-Scheffer epoxidation of electron-deficient olefins, which can be effected either by organic chiral phase transfer catalysts (PTC) under biphasic conditions or by polyamino acids. This reaction has gained considerable attention and is of great synthetic use. 

SCHEME 54. Zinc-mediated asymmetric epoxidation of electron-deficient olefins... 

Nickel(0)-catalyzed codimerization of methylenecyclopropanes with electron-deficient olefines are highly regiospedfic, but show a rather poor stereoselectivity. Thus the asymmetric nickel(0)-catalyzed codimerization of methylenecyclopropanes with the chiral bomane derivatives of acrylic acid leads to the optically active 3-methylenecyclopen-... 

The catalytic asymmetric epoxidation of electron-deficient olefins has been regarded as one of the most representative asymmetric PTC reactions, and various such systems have been reported (Scheme 3.12). Lygo reported the asymmetric epoxidation of chalcone derivatives through the use of NaOCl [30,31], while Shioiri and Arai used aqueous H202 as an oxidant, their results indicating hydrogen bonding between the catalyst and substrates because an OH functionality in the catalyst was essential... 

Permanganese is a common oxidative reagent, the application of which to the asymmetric oxidative cyclization of 1,5-dienes has been reported by Brown (Scheme 3.14). The addition of acetic acid is quite important for the reaction to proceed, and highly functionalized tetrahydrofurans are obtained in a range of 58 to 75% ee, in diastereoselective manner [35]. Another oxidative transformation using KMn04 with a chiral ammonium salt has been investigated. Scheme 3.15 illustrates the asymmetric dihydroxylation of electron-deficient olefins to chiral diols in the... 

The asymmetric Michael addition of active methylene or methine compounds to electron-deficient olefins, particularly o,[l-unsaturated carbonyl compounds, represents a fundamental - yet useful - approach to construct functionalized carbon frameworks [36]. 

The catalytic asymmetric epoxidation of electron-deficient olefins, particularly a,P-unsaturated ketones, has been the subject of numerous investigations, and as a result a number of useful methodologies have been elaborated [44], Among these, the method utilizing chiral phase-transfer catalysis occupies a unique position in terms of its practical advantages. Moreover, it also allows the highly enantioselective epoxidation of trans-a,P-unsaturated ketones, particularly chalcone. 

Small chiral organic molecules may catalyze the asymmetric addition of ketones, and aldehydes to electron-deficient olefins, such as vinylidene acetones, nitroole-fins, enones, and vinyl sulfones. In this chapter we will describe the inter- and intramolecular reactions in which activation of the carbonyl compound takes place via enamine formation. 

Porter M. J. and Skidmore, J. Asymmetric epoxidation of electron-deficient olefins, Chem. Commun., 2000, 1215-1225. 

Recently, the transition-metal-catalyzed addition of active methylene C-H bonds to electron-deficient olefins having a carbonyl, a nitrile, or a sulfonyl group has been extensively studied by several research groups. In particular, the asymmetric version of this type of catalytic reaction provides a new route to the enantioselective construction of quaternary carbon centers [88]. Another topic of recent interest is the catalytic addition of active methylene C-H bonds to acetylenes, allenes, conjugate ene-ynes, and nitrile C-N triple bonds. In this section, the ruthenium-catalyzed addition of C-H bonds in active methylene compounds to carbonyl groups and C-C multiple bonds is described. 

Asymmetric aziridination can also be accomplished via chiral salen ligands. Shi has synthesized a number of axially dissymmetric binaphthyldiimine salen complexes that have shown excellent facility in catalytic asymmetric aziridination reactions <2001TA3105>. Although yields were generally good with acyclic electron-deficient olefins, the chemical yield with electron-rich olefin indene was relatively low (25%). A reasonable enantiomeric excess of 73% was achieved at —20°C over a 24h reaction period (Equation 9). 

The asymmetric epoxidation of electron-deficient olefins, particularly a,/3-enones, including the use of chiral metal hydroperoxides, asymmetric phase-transfer methods, polyamino acid catalysts, and the chiral dioxiranes, has been reviewed <2000CC1215>. 

Hayashi, T. Rhodium-Catalyzed Asymmetric 1,4-Addition of Organoboronic Acids and their Derivatives to Electron-Deficient Olefins, Synlett 2001, 879-887. 

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