Asymmetric reactions oxidations

The cyclohexyloxy(dimethyl)silyl unit in 8 serves as a hydroxy surrogate and is converted into an alcohol via the Tamao oxidation after the allylboration reaction. The allylsilane products of asymmetric allylboration reactions of the dimethylphenylsilyl reagent 7 are readily converted into optically active 2-butene-l, 4-diols via epoxidation with dimethyl dioxirane followed by acid-catalyzed Peterson elimination of the intermediate epoxysilane. Although several chiral (Z)-y-alkoxyallylboron reagents were described in Section 1.3.3.3.3.1.4., relatively few applications in double asymmetric reactions with chiral aldehydes have been reported. One notable example involves the matched double asymmetric reaction of the diisopinocampheyl [(Z)-methoxy-2-propenyl]boron reagent with a chiral x/ -dialkoxyaldehyde87. 

In 1960, Montanari and Balenovic and their coworkers described independently the first asymmetric oxidation of sulfides with optically active peracids. However, the sulphoxides were formed in this asymmetric reaction (equation 130) with low optical purities, generally not higher than 10%. The extensive studies of Montanari and his group on peracid oxidation indicated that the chirality of the predominantly formed sulphoxide enantiomer depends on the absolute configuration of the peracid used. According to Montanari the stereoselectivity of the sulphide oxidation is determined by the balance between one transition state (a) and a more hindered transition state (b) in which the groups and at sulphur face the moderately and least hindered regions of the peracid,... 

Dipolar cycloaddition reactions are of main interest in nitrile oxide chemistry. Recently, reviews and chapters in monographs appeared, which are devoted to individual aspects of these reactions. First of all, problems of asymmetric reactions of nitrile oxides (130, 131), including particular aspects, such as asymmetric metal-catalyzed 1,3-dipolar cycloaddition reactions (132, 133), development of new asymmetric reactions utilizing tartaric acid esters as chiral auxiliaries (134), and stereoselective intramolecular 1,3-dipolar cycloadditions (135) should be mentioned. Other problems considered are polymer-supported 1,3-dipolar cycloaddition reactions, important, in particular, for combinatorial chemistry... 

Transition metal complex-catalyzed carbon-nitrogen bond formations have been developed as fundamentally important reactions. This chapter highlights the allylic amination and its asymmetric version as well as all other possible aminations such as crosscoupling reactions, oxidative addition-/3-elimination, and hydroamination, except for nitrene reactions. This chapter has been organized according to the different types of reactions and references to literature from 1993 to 2004 have been used. 

The asymmetric oxidation of organic compounds, especially the epoxidation, dihydroxylation, aminohydroxylation, aziridination, and related reactions have been extensively studied and found widespread applications in the asymmetric synthesis of many important compounds. Like many other asymmetric reactions discussed in other chapters of this book, oxidation systems have been developed and extended steadily over the years in order to attain high stereoselectivity. This chapter on oxidation is organized into several key topics. The first section covers the formation of epoxides from allylic alcohols or their derivatives and the corresponding ring-opening reactions of the thus formed 2,3-epoxy alcohols. The second part deals with dihydroxylation reactions, which can provide diols from olefins. The third section delineates the recently discovered aminohydroxylation of olefins. The fourth topic involves the oxidation of unfunc-tionalized olefins. The chapter ends with a discussion of the oxidation of eno-lates and asymmetric aziridination reactions. 

Chapter 2 to 6 have introduced a variety of reactions such as asymmetric C-C bond formations (Chapters 2, 3, and 5), asymmetric oxidation reactions (Chapter 4), and asymmetric reduction reactions (Chapter 6). Such asymmetric reactions have been applied in several industrial processes, such as the asymmetric synthesis of l-DOPA, a drug for the treatment of Parkinson s disease, via Rh(DIPAMP)-catalyzed hydrogenation (Monsanto) the asymmetric synthesis of the cyclopropane component of cilastatin using a copper complex-catalyzed asymmetric cyclopropanation reaction (Sumitomo) and the industrial synthesis of menthol and citronellal through asymmetric isomerization of enamines and asymmetric hydrogenation reactions (Takasago). Now, the side chain of taxol can also be synthesized by several asymmetric approaches. 

Scheme 7-15 shows the significant improvement in overall stereoselectivity, due mainly to the adoption of the newly developed Sharpless asymmetric ep-oxidation. Compounds a-epoxy-67 and //-epoxy-67 can be readily obtained from 53 via the Sharpless reaction. Isomers of compounds 57 are then constructed via regioselective ring opening with a copper reagent. 

Chapters 2 through 6 introduced many asymmetric organic reactions catalyzed by small molecules, such as C-C bond formation, reduction, and oxidation reactions. Chapter 7 provided further examples of how asymmetric reactions are used in organic synthesis. This chapter starts with a general introduction to enzyme-catalyzed asymmetric organic reactions. 

DattaGupta and Singh45 report the results of bis(oxazolinyl)pyridine induced asymmetric allylic oxidation. The reaction proceeds with 59% yield and 56% ee (Scheme 8-16). 

The cylindrically chiral diphosphine neither changed, nor lost its reactivity and selectivity in hydrogenation reactions even after long exposure to air. In a 31P-NMR study, no detectable air-oxidation was observed even after a long exposure (3 weeks) to the atmosphere. The procedures for the synthesis of the chiral ligand and the asymmetric reaction described above are very simple, giving high enan-tioselectivity with many dehydroamino acids (Table 12.4). 

The virtue of performing the PKR in an enantioselective manner has been extensively elaborated during the last decade. As a result, different powerful procedures were developed, spanning both auxiliary-based approaches and catalytic asymmetric reactions. For instance, the use of chiral N-oxides was reported by Kerr et al., who examined the effect of the chiral brucine N-oxide in the intermolecular PKR of propargylic alcohols and norbornadiene [59]. Under optimized conditions, ee values up to 78% at - 60 °C have been obtained (Eq. 10). Chiral sparteine N-oxides are also able to induce chirality, but the observed enantioselectivity was comparatively lower [60]. 

Asymmetric allylic oxidation and benzylic oxidation (Kharasch-PSosnovsky reaction) are important synthetic strategies for constructing chiral C—O bonds via C—H bond activation.In the mid-1990s, the asymmetric Kharasch-Sosnovsky reaction was first studied by using chiral C2-symmetric bis(oxazoline)s. " Later various chiral ligands, based mainly on oxazoline derivatives and proline derivatives, were used in such asymmetric oxidation. Although many efforts have been made to improve the enantioselective Kharasch-Sosnovsky oxidation reaction, most cases suffered from low to moderate enantioselectivities or low reactivities. 

Muller has explored enantioselective C-H insertion using optically active rhodium complexes, NsN=IPh as the oxidant, and indane 7 as a test substrate (Scheme 17.8) [35]. Chiral rhodium catalysts have been described by several groups and enjoy extensive application for asymmetric reactions with diazoalkanes ]46—48]. In C-H amination experiments, Pirrung s binaphthyl phosphate-derived rhodium system was found to afford the highest enantiomeric excess (31%) of the product sulfonamide 8 (20equiv indane 7, 71% yield). 

The transition metal based catalytic species derived from hydrogen peroxide or alkyl hydroperoxides are currently regarded as the most active oxidants for the majority of inorganic and organic substrates " An understanding of the mechanism of these processes is therefore a crucial point in the chemistry of catalytic oxidations. This knowledge allows one to predict not only the nature of the products in a given process, but also the stereochemical outcome in asymmetric reactions. 

The Sharpless reagent, i.e. Ti(OPr-i)4/TBHP/diethyl tartrate, has been tested in the asymmetric BV oxidation of mono and bicyclic butanones . Conversions are low in all cases and ee values range from moderate to good. The best result has been obtained with the most bulky bicyclic ketone of the series, oxidized to the corresponding lactone with ee values up to 75%, using (+)-diethyl tartrate as ligand (equation 79). The use of a modified Sharpless reagent, based on Ti-TADDOL catalyst , increased the reaction rates, but decreased the enantiomeric excesses . ... 

Tabie 13 Oxidation of 1,3-dithianes to 1,3-dithiane 1 -oxides or 1, 3-dithiane 1,3-dioxides under various (asymmetric) reaction ... 

Yamamoto and co-workers (135,135-137) recently reported a new method for stereocontrol in nitrile oxide cycloadditions. Metal ion-catalyzed diastereoselective asymmetric reactions using chiral electron-deficient dipolarophiles have remained unreported except for reactions using a-methylene-p-hydroxy esters, which were described in Section 11.2.2.6. Although synthetically very useful and, hence, attractive as an entry to the asymmetric synthesis of 2-isoxazohnes, the application of Lewis acid catalysis to nitrile oxide cycloadditions with 4-chiral 3-(2-aIkenoyl)-2-oxazolidinones has been unsuccessful, even when > 1 equiv of Lewis acids are employed. However, as shown in the Scheme 11.37, diastereoselectivities in favor of the ffc-cycloadducts are improved (diastereomer ratio = 96 4) when the reactions are performed in dichloromethane in the presence of 1 equiv of MgBr2 at higher than normal concentrations (0.25 vs 0.083 M) (140). The Lewis acid... 

The magnesium ion-mediated nitrone cycloaddition methodology can be successfully applied to the asymmetric reactions of a chiral cyclic nitrone of the lactone type (Scheme 11.51) (169). Although (/ )-2(/f)-oxo-5-phenyl-5,6-dihydro-1,4-oxazine A-oxide is an ( )-nitrone, all of its reactions are highly diastereose-lective, producing isoxazolidine 5-alcohol cycloadducts. The chelated transition... 

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