Oxazolines optically active

Hie Leterocydic component in tlie leaving group offers possiLililies for introduction of diirality. Optically active oxazolin-2-yl and tliiazolin-2-yl allyl tliioetliers 7 were tlius diosen as suLstrales (Sdienie 8.8) [17]. 

Oxathiane dioxides lithiated 641 synthesis of 638, 647 Oxathiane oxides, synthesis of 352 Oxathiolane oxides, synthesis of 241 Oxaziridines 72, 254, 826 as optically active oxidizing agents 291 Oxazolidinones 826 Oxazolines 619, 788... 

Asymmetric versions of the cyclopropanation reaction of electron-deficient olefins using chirally modified Fischer carbene complexes, prepared by exchange of CO ligands with chiral bisphosphites [21a] or phosphines [21b], have been tested. However, the asymmetric inductions are rather modest [21a] or not quantified (only the observation that the cyclopropane is optically active is reported) [21b]. Much better facial selectivities are reached in the cyclopropanation of enantiopure alkenyl oxazolines with aryl- or alkyl-substituted alkoxy-carbene complexes of chromium [22] (Scheme 5). 

Optically active, a-branched lactams 30 have been built by means of Meyers chiral auxiliaries [ 10]. The key step included the diastereoselective a-alkylations of the initially formed co-i -sulfonamido oxazolines 26. The R or S configuration in the product 27 was obtained reacting the appropriately configured intermediate aza enolates with alkyl halides, high diastereoselectivities have been reported. Several attempts to achieve a complete ring closure to the lactams 30 (via 29) by an acidic cleavage of the oxazolines 27 failed. Varying mixtures of... 

Associated to copper(II) pre-catalysts, bis(oxazolines) also allowed the asymmetric Diels-Alder and hetero Diels-Alder transformations to be achieved in nearly quantitative yield and high diastereo- and enantioselectivities. Optically active sulfoximines, with their nitrogen-coordinating site located at close proximity to the stereogenic sulfur atom, have also proven their efficiency as copper ligands for these asymmetric cycloadditions. Other precursors for this Lewis acid-catalyzed transformation have been described (e.g., zinc salts, ruthenium derivatives, or rare earth complexes) which, when associated to bis(oxazolines), pyridine-oxazolines or pyridine-bis(oxazolines), led to efficient catalysts. 

In addition to the simple substitutions shown in Scheme 1, this reaction has been used in a variety of complex systems as a route to optically active substances. For example, use of chiral oxazolines in this coupling process has led to an asymmetric synthesis of (-)-steganone,3 podophyllotoxin,4 (-)-schizandrin,5 and (+)-phylictralin.6 The synthesis of (-)-schizandrin is sketched in Scheme 2. 

Lithiated chiral oxazolines have been shown to react with various electrophiles, generating a new asymmetric center with considerable bias. This process has led to the synthesis of optically active a-alkylalkanoic acids,47 n-hydroxy(methoxy)alkanoic acids,48 / -hydroxy(methoxy)alkanoic acids,49 n-substituted y-butyrolactones,50 and 2-substituted-l,4-butanediols (Fig. 2-4).50... 

In addition to the reactions discussed above, a,//-unsaturated oxazolines can also act as chiral electrophiles to undergo conjugated addition of organolithium reagent to give optically active / ,/ -disubstituted carboxylic acids.52 The vinyl oxazolines 48 are prepared using the two methods outlined in Scheme 2-27. 

C, and then three molecular equivalents of acetyl chloride and triethy-lamine were added. Three types of acetylated materials, 11, 12, and 13, were isolated accompanied by a small amount of thioketone 7 and thioamide 9 (Scheme 8 and Table 6). All of the acetylated materials showed optical activity. For the reaction of 6a, 84% ee of 2-(acetylthio)aziridine 11a, 50% ee of 4-(acetyl-thio)oxazoline 12a, and 20% ee of 4-(acetylthio)oxazolidin-2-one 13a were obtained in 39,10, and 16% yields, respectively. In the reaction of 6b,c, the corresponding optically active materials 11-13 were obtained as shown in Table 9. The formation of oxazoline 12 involves the rearrangement ofAT-acyl aziridines, which occurs by intramolecular attack of the carbonyl oxygen at the ring carbon to cause rupture of the system. 

Meyers and Ford (76JOCI735), and Hirai et al. (72CPB206) have used 2-(alkylthio)-2-oxazolines or thiazolines to prepare the corresponding thi-iranes upon treatment with bases and subsequently with carbonyl compounds. The reactions of 2-pyridyl sulfides are expected to proceed similarly as shown in Scheme 22, since the oxazoline ring is a good leaving group in the intramolecular substitution reaction. When optically active oxazolines are used, asymmetric induction takes place to afford the optically active thiiranes in 19-32% enantiomeric excess (ee). The process is shown in Scheme 23. 

Optically active namral and unnamral amino acids as well as various cyclic amino alcohols have been utilized in the synthesis of a wide variety of bis(oxazo-line) ligands. As previously mentioned, the first bis(oxazoline) ligands, py-box la-d, were synthesized by Nishiyama and co-workers in 1989. The common material for their syntheses was pyridine 2,6-dicarboxylic acid 19. Conversion of 19 to the acid chloride was achieved by treatment with thionyl chloride, as illustrated in Figure 9.4. This was followed by condensation with (5)-valinol in the presence of triethylamine. Conversion of the resulting bis(amidodiol) 20 to py-box-ip lb was achieved by sequential treatment of 20 with thionyl chloride at 50 °C followed by cyclization with aqueous sodium hydroxide in methanol to afford py-box-/p lb in 60% overall yield. The same synthetic scheme can be used to obtain the other... 

In early studies of these reactions, the turnover efficiency was not always high, and stoichiometric amounts of the promoters were often necessary to obtain reasonable chemical yields (Scheme 105) (256). This problem was first solved by using chiral alkoxy Ti(IV) complexes and molecular sieves 4A for reaction between the structurally elaborated a,/3-unsaturated acid derivatives and 1,3-dienes (257). Use of alkylated benzenes as solvents might be helpiul. The A1 complex formed from tri-methylaluminum and a C2 chiral 1,2-bis-sulfonamide has proven to be an extremely efficient catalyst for this type of reaction (258). This cycloaddition is useful for preparing optically active prostaglandin intermediates. Cationic bis(oxazoline)-Fe(III) catalysts that form octahedral chelate complexes with dienophiles promote enantioselective reaction with cyclopentadiene (259). The Mg complexes are equally effective. 

Copper complexes catalyze formally related aziridination of olefins with ]7V-(p-toluenesulfonyl)imino]phenyliodinane, a nitrene precursor (219b). As exemplified in Scheme 98, catalysts formed from Cu(I) tri-flate and optically active bis(oxazolines) effect enantioselective reaction of styrene (Scheme 98) (218b, 219a). 

The first general method allowing the preparation of optically active 3,3-dialkylpropionic acids via asymmetric synthesis is based on chiral oxazolines.37-41 The a,3-unsaturated derivatives (41), accessible as pure ( )-isomers from (40) and the respective aldehydes (RCHO), undergo highly selective 1,4-additions in a variety of cases (Scheme 16) when treated with alkyl- or aryl-lithium reagents. The products... 

It is interesting that aldol-type condensation of tosylmethyl isocyanide (16) with aldehydes is catalyzed by the silver catalyst more stereoselectively than that catalyzed by the gold catalyst under the standard reaction conditions (Scheme 8B1.9) [26], Elucidation of the mechanistic differences between the gold and silver catalysts in the asymmetric aldol reaction of 16 needs further study. Oxazoline 17 can be converted to optically active a-alkyl-p-(A-methyl-amino)ethanols. 

The transformation of optically active epoxides with acetonitrile into optically active oxazolines (167,168) can be induced by various superacids714 [Eq. (5.264)]. The reaction proceeds with inversion of the asymmetric center with high stereospecificity with anhydrous HF and A1C13, whereas partial racemization is observed in triflic acid (Table 5.39). 

The most important development of this useful procedure has been the incorporation of an optically active amino alcohol, to provide a chiral adjuvant (or auxilliary), in the resulting oxazoline. The amino alcohol employed was (1S.2S)-... 

The efficient phase-transfer-catalyzed alkylation strategy with le was successfully applied by Jew and Park to the asymmetric synthesis of a-alkyl serines, using phenyl oxazoline derivative 53 as a requisite substrate [28]. The reaction is general, however, and provides a practical access to a variety of optically active a-alkyl serines through acidic hydrolysis of 54 (Scheme 5.26). 

As mentioned, 2-oxazolines may form a ring-opened distonic superelectrophile in reactions in superacid. These carboxonium-carbenium dications are capable of reacting with benzene and moderately deactivated substrates.2 For example, the optically active oxazoline (94) reacts in CF3SO3H to generate the chiral dication (95) and this superelectrophilic species is capable of reacting with o -dichlorobenzene in fair to modest yield and diastereoselectivity (eq 35). 

---