Radical reactions asymmetric

Mg11 complexes are also effective for controlling asymmetric radical reactions.33,34 Moreover, enantioselective radical reactions using chiral Mg11 complexes have been studied, and high enantioselectivities have been realized in the presence of stoichiometric or catalytic amounts of chiral auxiliaries such as bis-oxazolines (Scheme 8).35-39 In most cases, substrates having bidentate chelating moieties are required. 

Keywords Asymmetric Hydrogenation m Carbon Dioxide m Carbonylation m Dimethylformamide Enantioselectivity m Formic Acid m Homogeneous Hydrogenation n Palladium Catalysts Radical Reactions m Ruthenium Catalysts m Supercritical Fluids m Solvent Replacement... 

Some radical reactions occur under the control of transition metal templates. The first example of asymmetric creation of an asymmetric carbon with a halogen atom is shown by the a DIOP-Rh(I) complex-catalyzed addition of bromotrichloromethane to styrene, which occurs with 32% enantioselectivity (Scheme 99) (233). Ru(II) complexes with DIOP or BINAP ligands promote addition of arenesulfonyl chlorides to afford the products in 25-40% ee (234). A reaction mechanism involving radical redox transfer chain process has been proposed. 

Asymmetric radical reactions. Curran et al,3 report several asymmetric reactions of radicals derived from Oppolzer s camphorsultam. Thus the reaction of the iodosultam 1 with allyltributyltin initiated by triethylborane provides an epimeric... 

Asymmetric radical reactions. Several groups have reported asymmetric radical reactions observed with (S,S)- or (R,R)-1 as the chiral auxiliary. Thus the iodide 2 in the presence of BuySnH and AIBN cyclizes mainly to two diastereomeric endo-cyclic products 3 in the ratio 14 1.2... 

Ogura, K., Aray, T., Kayano, A., and Akazome, M. (1999) Efficient 1,2-asymmetric induction in radical reactions ... 

Keywords Asymmetric synthesis Chiral amines Hydrazones Radical reactions... 

Radical reactions provide a powerful means for manipulating the structure of organic compounds. A vast range of radical transformations is available to the synthetic organic chemist, ranging from functional group interconversions to asymmetric reactions and complex, sequential cyclization reactions where molecular complexity can be increased spectacularly in a single step. Many of these processes are complementary to more traditional polar processes and are characterized by attractive features such as the mild, neutral reaction con-... 

Asymmetric Radical Reactions. Several reports have documented the utility of nonracemic fra/w-2,5-dimethylpyrrolidine as a chiral auxiliary in asymmetric radical reactions. For example, the addition of -hexyl, cyclohexyl, and f-butyl radicals to the chiral acrylamide of 4-oxopentenoic acid provided four diastere-omeric products resulting from a- and p-addition (eq 7). The isomers resulting from p-addition were formed with no diastereoselectivity however, the isomers resulting from a-addidon were formed in ratios of 16 1,24 1, and 49 1. Unfortunately, the application of this chemistry is limited due to the poor regioselectivity in the addition and difficulty in removal of the chiral auxiliary. 

Most organic free radicals are nucleophilic and will react with electrophilic centers. Lewis acids have been used to activate aj3-unsaturated carbonyl compounds towards addition of free radicals and also to stabilize a-keto radicals [67]. The first report of the use of a chiral Lewis acid to effect an asymmetric free-radical reaction was that of Urabe, Yamashita, Suzuki, Kobayashi, and Sato in 1995 [68]. They found that if the BINOL aluminum catalyst 313 is stoichiometrically complexed with lactone 323 and then treated with butyl iodide and tributylstannane in the presence of triethylborane the alkylated lactone 324 can be isolated in 47 % yield with 23 % ee (Sch. 40). 

Both intermolecular and intramolecular additions of carbon radicals to alkenes and alkynes continue to be a widely investigated method for carbon-carbon bond formation and has been the subject of a number of review articles. In particular, the inter- and intra-molecular additions of vinyl, heteroatomic and metal-centred radicals to alkynes have been reported and also the factors which influence the addition reactions of carbon radicals to unsaturated carbon-carbon bonds. The stereochemical outcome of such additions continues to attract interest. The generation and use of alkoxy radicals in both asymmetric cyclizations and skeletal rearrangements has been reviewed and the use of fi ee radical reactions in the stereoselective synthesis of a-amino acid derivatives has appeared in two reports." The stereochemical features and synthetic potential of the [1,2]-Wittig rearrangement has also been reviewed. In addition, a review of some recent applications of free radical chain reactions in organic and polymer synthesis has appeared. The effect of solvent upon the reactions of neutral fi ee radicals has also recently been reviewed. ... 

Asymmetric dihydroxylation of trifluoromethylalkenes is also useful for construction of enantio-enriched trifluoromethylated diols usable for trifluoromethylated amino acids with chiral hydroxyl group. Thus, Sharpless AD reaction of 16 provides diol 17 with excellent enantioselectivity. Regioselective and stereospecific replacement of the sulfonate moiety in 18 with azide ion enables the introduction of nitrogen functionality. A series of well-known chemical transformation of 19 leads to 4,4,4-trifluorothreonine 20 (see Scheme 9.6) [16]. Dehydroxylative-hydrogenation of 21 by radical reaction via thiocarbonate and subsequent chemical transformation synthesize enantio-enriched (S)-2-amino-4,4,4-trifluoro-butanoic acid 22 [16]. Both enantiomers of 20 and 22 were prepared in a similar manner from (2R,3S)-diol of 17. 

Although many tools have been developed for use in the prediction of the outcomes of ionic reactions, some are also applicable to the prediction of the outcomes of free radical reactions. One of the most widely used ionic reactions in diastereoselective synthesis is addition of a nucleophile (Nu-) to the carbonyl group of chiral compound RM20 CLMS, where L, M and S represent, respectively, the largest, the middle-sized and the smallest of the substituents (other than the keto group) on the asymmetric carbon (Scheme 7.17). 

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