Stereoselective preparation of chiral

The past decade has seen significant achievements in stereoselective synthesis, with some pertinent developments also in dioxetane chemistry. Herein, we consider the most recent and prominent advances in the stereoselective preparation of chiral dioxetanes and their transformation into building blocks for asymmetric synthesis. 

Scheme 3 The stereoselective preparation of chiral cyclic diorganozincs...

A variety of methods for the stereoselective preparation of chiral 1,2-amino alcohols have been developed in recent years. Among these procedures the enantioselective hydro-... 

Chiral-at-metal cations can themselves serve as chirality inducers. For example, optically pure Ru[(bipy)3] proved to be an excellent chiral auxihary for the stereoselective preparation of optically active 3D anionic networks [M(II)Cr(III)(oxalate)3]- n (with M = Mn, Ni), which display interesting magnetic properties. In these networks all of the metalhc centers have the same configuration, z or yl, as the template cation, as shown by CD spectroscopy and X-ray crystallography [43]. 

The hydroxynitrile lyase (HNL)-catalyzed addition of HCN to aldehydes is the most important synthesis of non-racemic cyanohydrins. Since now not only (f )-PaHNL from almonds is available in unlimited amounts, but the recombinant (S)-HNLs from cassava (MeHNL) and rubber tree (HbHNL) are also available in giga units, the large-scale productions of non-racemic cyanohydrins have become possible. The synthetic potential of chiral cyanohydrins for the stereoselective preparation of biologically active compounds has been developed during the last 15 years. 

Amino alcohols, which have a broad spectrum of biological activities, can be categorized as adrenahne-like with one chiral center at C-1 or as ephedrine-like with two chiral centers at C-1 and C-2 (Scheme 7). Although a variety of methods have been developed for the stereoselective preparation of 1,2-amino alcohols, " in most cases it is easier and more efficient to prepare these important compounds stereoselectively starting from chiral cyanohydrins (Scheme... 

Nitroalkenes with Chiral Auxiliaries The use of carbohydrates as chiral auxiliary in Diels-Alder reactions for the stereoselective preparation of carbocyclic and heterocyclic chiral rings is well documented.48 For example, D-manno-nitroalkene reacts with 2,3-dimethyl-1,3-butadiene to give a 65 35 mixture of adducts, as shown in Eq. 8.29. The configurations at C-4 and C-5 have been determined to be (4R,5R) and (45,55), respectively. Hydrolysis of the product followed by degradative oxidation of the sugar side chains leads to enantiomerically... 

Haynes, R.K., Lam, W.W.-L., and Yeung, L.-L., Stereoselective preparation of functionalized tertiary P-chiral phosphine oxides by nucleophilic addition of lithiated tert-butylphenylphosphine oxide to carbonyl compounds, Tetrahedron Lett., 37, 4729, 1996. 

At that time, as now, the enantiomers of many chiral amines were obtained as natural products or by synthesis from naturally occurring amines, a-amino acids and alkaloids, while others were only prepared by introduction of an amino group by appropriate reactions into substances from the chiral pool carbohydrates, hydroxy acids, terpenes and alkaloids. In this connection, a recent review10 outlines the preparation of chiral aziridines from enantiomerically pure starting materials from natural or synthetic sources and the use of these aziridines in stereoselective transformations. Another report11 gives the use of the enantiomers of the a-amino acid esters for the asymmetric synthesis of nitrogen heterocyclic compounds. 

A method for highly efficient asymmetric cyclopropanation with control of both relative and absolute stereochemistry uses vinyldiazomethanes and inexpensive a-hydroxy esters as chiral auxiliaries263. This method was also applied for stereoselective preparation of dihydroazulenes. A further improvement of this approach involves an enantioselective construction of seven-membered carbocycles (540) by incorporating an initial asymmetric cyclopropanation step into the tandem cyclopropanation-Cope rearrangement process using rhodium(II)-(5 )-N-[p-(tert-butyl)phenylsulfonyl]prolinate [RhjtS — TBSP)4] 539 as a chiral catalyst (equation 212)264. 

G. Sabbioni, J. B. Jones, Enzymes in Organic Synthesis. 39. Preparations of Chiral Cyclic Acid-Esters and Bicyclic Lactones via Stereoselective Pig Liver Esterase Catalyzed Hydrolyses of Cyclic meso Diesters ,./. Org. Chem. 1987, 52, 4565 - 4570. 

In 1988 Kunz and Pfrengle introduced the preparation of chiral amino acid derivatives by the U-4CR in the presence of 2,3,4,6-tetra-6)-pivaloyl- 3-D-galacto-pyranosylamine, 57, in the presence of ZnCl2-etherate as catalyst. They obtained excellent stereoselectivity and high yields of their products. One of the disadvantages of such U-4CRs is that only formic acid can be used as the acid component, and the auxiliary group of the products can only be removed by half-concentrated hot methanolic HCl. 

Oxynitrilases are enzymes that catalyze the formation and cleavage of cyanohydrins through the stereoselective addition of hydrogen cyanide to aldehydes or methyl ketones giving enantiopure a-hydroxynitriles. The use of (R)-oxynitrilases for the preparation of chiral cyanohydrins has dramatically grown in the last decade because of their possibihties as precursors for the synthesis of many compounds with physiological properties [50]. 

Recently, the first examples of catalytic enantioselective preparations of chiral a-substituted allylic boronates have appeared. Cyclic dihydropyranylboronate 76 (Fig. 6) is prepared in very high enantiomeric purity by an inverse electron-demand hetero-Diels-Alder reaction between 3-boronoacrolein pinacolate (87) and ethyl vinyl ether catalyzed by chiral Cr(lll) complex 88 (Eq. 64). The resulting boronate 76 adds stereoselectively to aldehydes to give 2-hydroxyalkyl dihydropyran products 90 in a one-pot process.The diastereoselectiv-ity of the addition is explained by invoking transition structure 89. Key to this process is the fact that the possible self-allylboration between 76 and 87 does not take place at room temperature. Several applications of this three-component reaction to the synthesis of complex natural products have been described (see section on Applications to the Synthesis of Natural Products ). 

A Rh-catalyzed Reformatsky reaction of chiral imine (24) led to the stereoselective preparation of the a,a-difluoro-jS-amino acid (25). 25 was converted to difluor-oalkene (26), and subsequently L-Val-i/r[(Z)CF=CH]Gly derivative (23) in greater than 82% for both steps. The samarium diiodide-mediated reductive transformation of the y,y-difluoro-a, S-enoates proceeded via successive two-electron transfers to form a dienolate species which upon kinetically controlled trapping with fert-BuOH formed 23 (Scheme 6). 

Terashima et al. 231) reported an asymmetric halolactonization reaction. This highly stereoselective reaction permits the synthesis of intermediates for the preparation of chiral a,a-disubstituted a-hydroxycarboxylic acids (227)231c), a-hydroxyketones (228) 231c), functionalized epoxides (229) 231d,e) and natural products 231h,j). Only amino acids have so far been used as a source of the chiral information in the asymmetric halolactonization reaction. Again, the best results have been obtained by using cyclic imino acid enantiomers, namely proline. 

Johnson in 1993 described an approach to racemic p-amyrin involving application of a biomimctic polyene cyclization.7 In the same year Corey accomplished the enantioseleetive synthesis of compound 4. a key intermediate that opened the way to stereoselective preparation of compounds I, 2. and 3 8 A key step in the synthesis of P-amyrin (1) was the introduction of chiral oxazaboroli-dines for enantioseleetive carbonyl reduction. Ba ed on these methods, generation of an enantiomerically pure epoxide and its stereoselective cationic cyclization led to the pentacyclic system of structure 1 Diastereoselective cyclopropanation and an intramolecular protonation of a carbanion represent other interesting steps in this total synthesis. 

The ynamide-Kinugasa reaction has been used for the highly stereoselective synthesis of chiral cz-amino- (3-1 actams. The application of this reaction consists in the preparation of chiral a-amino-2-azetidinones starting from chiral ynamide (Scheme 64), [158]. 

Figure 9 Preparation of chiral synthon for neutral endopeptidase inhibitor stereoselective enzymatic hydrolysis of racemic ot-[(acetylthio)methyl]phenylpropionic acid (21).

As a further stereoselective organic synthesis [40-47] using reactive sp2 carbon-centered radicals, eq. 10.23 shows the preparation of chiral 4-te/7-butylcyclohexene (49) from the optically pure o-bromophenyl sulfoxide (48) through 1,5-H shift by sp2 carbon-centered radical, followed by (3-elimination. This reaction looks like a thermal concerted intramolecular elimination reaction (Ei). 

Interestingly, this substitution reaction can be applied to the stereoselective assembly of chiral quaternary centers and has been extended to the preparation of chiral tertiary alcohols via a stereoselective Baeyer-Villiger rearrangement, and chiral tertiary amines via a stereoselective Curtius rearrangement (Scheme 15)130>130a... 

The use of chiral 1-oxa-l,3-butadienes for the stereoselective preparation of carbohydrates has also been investigated by Schmidt et al. [479]. The elegant syntheses of N-acetyl-/J-D-neuraminic acid derivatives are an impressive result of these studies [480]. 

Collins and coworkers have developed two synthetic routes for the preparation of chiral [l,2-ethylenebis(jj -3-alkylcyclopentadienyl)]titanium dichlorides (R = Me, Et, i-Pr, r-Bu) in 80 85% yields as a nuxture of racemic and meso-titanocene dichlorides. In more recent work, the addition of a methyl group to the cyclopentadienyl rings has allowed Collins and coworkers to prepare a series of [1,2-ethylene-l,T-bis(4-R-2-methylcyclopentadienyl)] titanium dichlorides (R = Me, j-Pr, r-Bu) stereoselectively to give the racemic isomers. ... 

A highly stereoselective preparation of organoselenium compounds having a chiral center at the selenium atom... 

Thiazolidinethiones constitute a class of versatile chiral auxiliaries for asymmetric synthesis. Their easy preparation from readily available /3-amino alcohols and the high levels of asymmetric induction they provide make them excellent chiral auxiliaries for the preparation of chiral intermediates in the synthesis of natural products. These chiral auxiliaries have been utilized in a wide variety of synthetic transformations such as asymmetric aldol-type acyloin condensation, stereoselective alkylation of different electrophiles (Stetter reaction), and stereoselective differentiation of enantiotopic groups in molecules bearing prochiral centers <2002COR303>. 

---