Diastereoselectivity optically active compounds

The synthesis of optically active compounds by the diastereoselective reaction of allyltitanium reagents with chiral electrophiles has also been reported. The reaction of allyltitanium reagents with chiral imines proceeds with excellent diastereoselectivity, as shown in Eq. 9.28, thus providing a new method for synthesizing optically active homoallylic amines with or without a P-substituent [51,52],... 

There are two possible approaches for the preparation of optically active products by chemical transformation of optically inactive starting materials kinetic resolution and asymmetric synthesis [44,87], For both types of reactions there is one principle in order to make an optically active compound we need another optically active compound. A kinetic resolution depends on the fact that two enantiomers of a racemate react at different rates with a chiral reagent or catalyst. Accordingly, an asymmetric synthesis involves the creation of an asymmetric center that occurs by chiral discrimination of equivalent groups in an achiral starting material. This can be done either by enan-tioselective (which involves the reaction of a prochiral molecule with a chiral substance) or diastereoselective (which involves the preferential formation of a single diastereomer by the creation of a new asymmetric center in a chiral molecule) synthesis. 

The authors provided some experimental support for their hypothesis by performing various diastereoselective reactions on racemic or optically active compounds. Indeed, they found some differences in stereoselectivity between the two cases. Reduction of DL-camphor or D-camphor with lithium aluminum hydride, for example, gave ratios of isobomeol to bomeol of 7.93 and 9.20, respectively. 

The unique feature of the Diels-Alder reaction — generating up to four new stereogenic centers in one step — combined with the variety of useful reactants, has made this reaction a favorite methodology for constructing molecular diversity [54]. Therefore, asymmetric versions of this reaction represent an attractive tool for the diastereoselective synthesis of optically active compounds [55,56]. Various carbohydrate auxiliaries, either attached to the diene or to the dienophUe component, have been successfully used to produce stereochemically pure cycloadducts [57]. 

To explore synthetic methods for optically active compounds, we next turned our attention to systematic studies on diastereoselectivity in this tandem process, using acyclic secondary allyl alcohols (Z)-12 and (E)-12. Treatment of nitrone lb with alcohol (Z)-12 in the presence of a catalytic amount of TiCLt and MS4A led to smooth transesterification and intramolecular cycloaddition even at room temperature, affording 13b accompanied by a small amount of 14b (Table 6.4, entry 1). The bulkier nitrone Ic also reacted with (Z)-12 under the same conditions, giving 13c and 14c in an excellent combined yield with high diastereofacial selectivity (entry 2). It was also found that reactions of chiral nitrones Im and In with (Z)-12 proceeded smoothly to give 13m and 13n as the major cycloadducts in excellent yields with high diastereofacial selectivity, which was independent of the chirality of nitrones Im and In (entries 3 and 4). 

The diastereoselectivity is observed in the Henry reaction using optical active niti o compounds or a-heteroatom substituted aldehydes. Lor example, the reaction of O-benzyl-D-lactal-dehyde with methyl 3-niti opropionate in the presence of neubal alumina leads to a mixture of three niti o-aldol products from which D-ribo isomer is isolated by direct crystallization. D-Ribo... 

The addition of the dianion of /j-sulfmylcarboxylic acids to carbonyl compounds leads to the formation of the corresponding hydroxy derivatives which undergo spontaneous eyclization to give y-lactones. It was found that when optically active ( + )-(/ )-3-(4-methylphenylsulfinyl)pro-panoic acid is used for the reaction, the corresponding diastereomeric /i-sulfinyl-y-lactones are formed in a ratio which is dependent on the substituents of the carbonyl component. However, the diastereoselectivity was always moderate. 

As with the reduction of aldehydes and ketones (16-23), the addition of organometallic compounds to these substrates can be carried out enantioselectively and diastereoselectively. Chiral secondary alcohols have been obtained with high ee values by addition to aromatic aldehydes of Grignard and organolithium compounds in the presence of optically active amino alcohols as ligands. ... 

Optically active 3-arylisoxazoline-5-carboxylic acid derivatives 403 or 404 have been, prepared by the reaction of (S)- or (/ )-3-acryloyl-4-benzyl-5,5-dimethyloxazolidin-2-one (405 or 406) with nitrile oxides, obtained from benzo-hydroximoyl chloride and its substituted derivatives in the presence of a catalytic amount of metal salt, for example, Yb(OTf)3 (445). This procedure improves the diastereoselectivity of compounds 403 or 404, which are industrially useful as intermediates for various drugs and agrochemicals. It also enables the amount... 

Optically active 2-alkylidene-l,3-dithiane 1,3-dioxides have been prepared as chiral Michael-type acceptors. It was shown that these compounds react under nucleophilic epoxidation conditions to give diastereoselectively the epoxides. Other heteroatom nucleophiles reacted as well <1998JOC7128, 1999PS(153/4)337>. It was further demonstrated that enolates were also effective nucleophiles for the stereoselective addition to 2-alkylidene-l,3-dithiane 1,3-dioxides (Scheme 48) <20050L4013>. 

The (ri" -diene tricarbonyliron)-substituted diazocarbonyl compounds 25 have been found to undergo 1,3-dipolar cycloaddition with methyl acrylate in high yield, but with little or no diastereoselectivity (56). Nevertheless, the facile chromatographic separation of the diastereomeric products 26a,b and 27a,b (Scheme 8.8), permits the synthesis of pure enantiomers when optically active diazo compounds (25) [enantiomeric excess (ee) >96%] are employed. When the reaction of 25 (R = C02Et) with methyl acrylate was carried out at 70 °C, cyclopropanes instead of A -pyrazolines were formed. The enantiomerically pure... 

Only a few reports have described the application of optically active nitrile oxides in 1,3-dipolar cycloadditions (65-70). A general trend for these reactions is that moderate-to-poor diastereoselectivities are obtained when it is attempted to control the stereoselectivity using a chiral nitrile oxide. In one of the few recent examples, the chiral nitrile oxide 43, derived from Al-formylnorephenedrine and 3-methylnitrobutene, was subjected to reaction with diethyl fumerate (Scheme 12.16) (69). Compound 44 was obtained as the major product of this reaction as a 75 25 mixture with its diastereomer. 

The reaction with optically active hydrazones provided an access to optically active ketones. The butylzinc aza-enolate generated from the hydrazone 449 (derived from 4-heptanone and (,S )-1 -amino-2-(methoxymethyl)pyrrolidine (SAMP)) reacted with the cyclopropenone ketal 78 and led to 450 after hydrolysis. The reaction proceeded with 100% of 1,2-diastereoselectivity at the newly formed carbon—carbon bond (mutual diastereo-selection) and 78% of substrate-induced diastereoselectivity (with respect to the chiral induction from the SAMP hydrazone). The latter level of diastereoselection was improved to 87% by the use of the ZnCl enolate derived from 449, at the expense of a slight decrease in yield. Finally, the resulting cyclopropanone ketal 450 could be transformed to the polyfunctional open-chain dicarbonyl compound 451 by removal of the hydrazone moiety and oxymercuration of the three-membered ring (equation 192). 

A highly selective method for the preparation of optically active 3-substituted or 3, y-disubstituted-S-keto esters and related compounds is based on asymmetric Michael additions of chiral hydrazones (156), derived from (5)-l-amino-2-methoxymethylpyrrolidine (SAMP) or its enantiomer (RAMP), to unsaturated esters (154).167-172 Overall, a carbonyl compound (153) is converted to the Michael adduct (155) as outlined in Scheme 55. The actual asymmetric 1,4-addition of the lithiated hydrazone affords the adduct (157) with virtually complete diastereoselection in a variety of cases (Table 3). Some of the products were used for the synthesis of pheromones,169 others were converted to 8-lactones.170 The Michael acceptor (158) also reacts selectively with SAMP hydrazones.171 Tetrahydroquinolindiones of type (159) are prepared from cyclic 1,3-diketones via SAMP derivatives like (160), as indicated in Scheme 56.172... 

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