Asymmetric induction also double

Asymmetric induction also occurs during osmium tetroxide mediated dihydroxylation of olefinic molecules containing a stereogenic center, especially if this center is near the double bond. In these reactions, the chiral framework of the molecule serves to induce the diastereoselectivity of the oxidation. These diastereoselective reactions are achieved with either stoichiometric or catalytic quantities of osmium tetroxide. The possibility exists for pairing or matching this diastereoselectivity with the face selectivity of asymmetric dihydroxylation to achieve enhanced or double diastereoselectivity [25], as discussed further later in the chapter. 

The stereochemical outcome of an aldol reaction involving more than one chiral component is consistent with the rule of approximate multiplicativity of diastereofacial selectivities intrinsic to the chiral reactants. For a matched case, the diastereoselectivity approximates (substrate DS) X (reagent DS). For a mismatched case, the diastereoselectivity is (substrate DS) (reagent DS). Double asymmetric induction also can be used to enforce the inherent facial selectivity of a chiral aldehyde, as shown below. 

Asymmetric induction The preferential formation of one enantiomer or diastereo-mer over another, due to the influence of a stereogenic element in the substrate, reagent, catalyst, or environment (such as solvent). Also, the preferential formation of one configuration of a stereogenic element under similar circumstances. When two reactants of a reaction are stereogenic, the stereogenic elements of each reactant may operate either in concert (matched pair) or in opposition (mismatched pair). This phenomenon is known [58,59] as double asymmetric induction, or double diastereoselection. See Section 1.5. 

A more eflicient and general synthetic procedure is the Masamune reaction of aldehydes with boron enolates of chiral a-silyloxy ketones. A double asymmetric induction generates two new chiral centres with enantioselectivities > 99%. It is again explained by a chair-like six-centre transition state. The repulsive interactions of the bulky cyclohexyl group with the vinylic hydrogen and the boron ligands dictate the approach of the enolate to the aldehyde (S. Masamune, 1981 A). The fi-hydroxy-x-methyl ketones obtained are pure threo products (threo = threose- or threonine-like Fischer formula also termed syn" = planar zig-zag chain with substituents on one side), and the reaction has successfully been applied to macrolide syntheses (S. Masamune, 1981 B). Optically pure threo (= syn") 8-hydroxy-a-methyl carboxylic acids are obtained by desilylation and periodate oxidation (S. Masamune, 1981 A). Chiral 0-((S)-trans-2,5-dimethyl-l-borolanyl) ketene thioketals giving pure erythro (= anti ) diastereomers have also been developed by S. Masamune (1986). 

Fluoboric acid is also an efficacious promoter of cyclic oxo-carbenium ions (Scheme 4.24) bearing an activated double bond which, in the presence of open-chain and cyclic dienes, rapidly undergo a Diels-Alder reaction [91]. Chiral a, -unsaturated ketones bearing a -hydroxy substituents, protected as acetals, react with various dienes in the presence of HBF4, affording Diels-Alder adducts that were isolated as alcohols by hydrolysis of the acetal group by TsOH. Some examples of reactions with isoprene are reported in Table 4.23. The enantios-electivity of the reaction is dependent on the size of the substituent R on the of-carbon high levels of asymmetric induction were observed with R = z-Pr (90 1) and R = t-Bu (150 1) and low levels with R = Me (2.7 1) and R = Ph (3.0 1). Scheme 4.24 shows the postulated reaction mechanism. 

Double asymmetric induction (See section 1.5.3) can also be employed in aldol reactions. When chiral aldehyde 15 is treated with achiral boron-mediated enolate 14, a mixture of diastereomers is obtained in a ratio of 1.75 1. However, when the same aldehyde 15 is allowed to react with enolates derived from Evans auxiliary 8, a syn-aldol product 16 is obtained with very high stereo-... 

Now, we examine the interaction of chiral aldehyde (-)-96 with chiral enolate (S )-lOOb. This aldol reaction gives 104 and 105 in a ratio of 104 105 > 100 1. Changing the chirality of the enolate reverses the result Compound 104 and 105 are synthesized in a ratio of 1 30 (Scheme 3-38).66 The two reactions (—)-96 + (S )-lOOb and (—)-96 + (7 )-100b are referred to as the matched and mismatched pairs, respectively. Even in the mismatched pair, stereoselectivity is still acceptable for synthetic purposes. Not only is the stereochemical course of the aldol reaction fully under control, but also the power of double asymmetric induction is clearly illustrated. 

The idea of double asymmetric induction is also applicable to asymmetric epoxidation (see Chapter 1 for double asymmetric induction). In the case of asymmetric epoxidation involving double asymmetric induction, the enantiose-lectivity depends on whether the configurations of the substrate and the chiral ligand are matched or mismatched. For example, treating 7 with titanium tet-raisopropoxide and t-butyl hydroperoxide without (+)- or ( )-diethyl tartrate yields a mixture of epoxy alcohols 8 and 9 in a ratio of 2.3 1 (Scheme 4 3). In a... 

If stoichiometric quantities of the chiral auxiliary are used (i.e., if the chiral auxiliary is covalently bonded to the molecule bearing the prochiral centres) there are in principle three possible ways of achieving stereoselection in an aldol adduct i) condensation of a chiral aldehyde with an achiral enolate ii) condensation of an achiral aldehyde with a chiral enolate, and iii) condensation of two chiral components. Whereas Evans [14] adopted the second solution, Masamune studied the "double asymmetric induction" approach [22aj. In this context, the relevant work of Heathcock on "relative stereoselective induction" and the "Cram s rule problem" must be also considered [23]. The use of catalytic amounts of an external chiral auxiliary in order to create a local chiral environment, will not be considered here. 

A study on the combined use of a chiral substrate obtained by alcoholysis of a 4-benzylidene-5(4//)-oxazolone with a chiral alcohol coupled with hydrogenation using a chiral catalyst has also been described. This work shows that the matching effect of double asymmetric induction in hydrogenation can be modulated by a solvent effect. 

The polarized carbon-nitrogen double bond can also be reduced enantiospecifically using chiral hydrides (7lJCS(C)2560). Although only modest asymmetric inductions were observed, this method holds promise for the synthesis of chiral piperidines (equation 54). 

The double bonds in certain heterocyclic compounds, such as furans, Af-acylpyrroles and A-acylindoles are also susceptible to photoaddition of carbonyl compounds to form oxetanes (equation 106) (77JHC1777). A wide range of carbonyl compounds can be used, including quinones, a-diketones, acyl cyanides, perfluorinated aldehydes and ketones and esters. A remarkable case of asymmetric induction in oxetane formation has been reported from optically active menthyl phenylglyoxylate and 2,3-dimethyl-2-butene the oxetane product obtained after hydrolysis of the ester group had an optical purity of 53% (79AG(E)868). 

A camphor-derived 1,3-diketonate complex 338c worked well (55-80% yield), but no asymmetric induction was observed. One-pot reactions to access 1,2,4-trioxanes were also effective using the new catalysts. Dussault and coworkers used 319 to catalyze the silyl peroxidation of 3-methyl-3-butenol in ethanol in 45% yield (entry 8) [386]. Some silylation of the alcohol function was also found under the reaction conditions. Similar double silyl peroxidation reactions were performed with trisub-stituted olefins in 52-78% yield using 319 as the catalyst [387]. 

Masamune et al. have reviewed in detail the effects of double asymmetric induction not only for epoxidation, but also for the aldol, Diels-Alder, and catalytic hydrogenation reactions. The merits of this strategy are illustrated by an analysis of Woodward s synthesis" of erythromycin A (1), which has 10 chiral centers. 

As pointed out in the introduction, a particular feature of hydrosilylation reactions is that they require catalysis. Arguably the most valuable of enantioselective synthetic methods are those in which asymmetric induction occurs from small quantities of enantiomerically pure catalysts. It is natural, therefore, that considerable effort has been directed towards the catalytic enantioselective hydrosilylation-oxidation of C —C double bonds. Some degree of success has been met in the hydrosilylation of simple alkenes and 1,3-dienes, and in intramolecular hydrosilyla-tions. Also, as discussed at end of this section, a catalytic enantioselective disilylation (effectively the same as a hydrosilylation) has been developed for a,)3-unsaturated ketones. 

The Michael conjugate addition of an oxygen to an activated double bond has also been exploited in order to obtain 2,5-disubstituted tetrahydrofurans. The diacetoxynonenoate 1 is cyclized with methanolic potassium hydroxide to give the tetrahydrofuranyl derivative 2 in 97 % yield after esterification with diazomethane. The 1,3-asymmetric induction is low as indicated by the cisf trans diastereomeric ratio (67 33) which was determined by a GLC comparison with known material50. 

High to total 1,2-asymmetric induction was observed in the iodocyclization of IV-alkoxy-3-sub-stituted 4-alkenylamines, the cyclic products 1 have predominantly the 2,3-trans relationship. When the C-3 substituent is a methyl group, the induced diastereoselectivity also depends on the substitution pattern of the alkene, e.g., changing the toaZ double bond, dramatically increases the trans/cis ratio from 67 33 to 100 0. Diastereomeric ratios were determined by H NMR and chromatographic purification of individual diastereomers77. 

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