Diastereomers syn/anti

Greene and coworkers showed that deprotonation of Af-Boc-iV-benzylamine with a threefold excess of s-BuLi and twofold excess of TMEDA yields a dilithiated species which adds in a 1,2-fashion to acrolein in 49% yield. The syn anti diastereomer ratio is 86 14 (Scheme 49). The racemic mixture of diastereomers can be protected, oxidized and resolved to yield the enantiomerically pure (>99%) acid shown in 46% overall yield. This molecule is a precursor to the side chain of Taxol. ... 

The stereochemical outcome of the aldol addition reactions to pyruvate and glyoxylates catalyzed by Sn(II) were complementary to the Cu(II)-catalyzed process, giving the anti stereoisomers. Thus, aldol adducts were isolated as mixtures of 10 90-1 99 syn anti diastereom-ers in 92-99% ee. 

In the study by Alexakis, unsymmetrical ketones (e.g. 2-butanone) yielded mixtures consisting of regioisomers and syn/anti diastereomers with ee of the predominant syn isomers not exceeding 51%. For 3-pentanone and cyclohexanone (Scheme 4.24) Barbas et al. also used the related (S)-l-(pyrrolidinylmethyl)-pyrrolidine 54 to catalyze the addition of ketones to alkylidene malonates (Scheme 4.25) [43],... 

The known allylic alcohol 9 derived from protected dimethyl tartrate is exposed to Sharpless asymmetric epoxidation conditions with (-)-diethyl D-tartrate. The reaction yields exclusively the anti epoxide 10 in 77 % yield. In contrast to the above mentioned epoxidation of the ribose derived allylic alcohol, in this case epoxidation of 9 with MCPBA at 0 °C resulted in a 65 35 mixture of syn/anti diastereomers. The Sharpless epoxidation of primary and secondary allylic alcohols discovered in 1980 is a powerful reagent-controlled reaction.12 The use of titanium(IV) tetraisopropoxide as catalyst, tert-butylhydro-peroxide as oxidant, and an enantiopure dialkyl tartrate as chiral auxiliary accomplishes the epoxidation of allylic alcohols with excellent stereoselectivity. If the reaction is kept absolutely dry, catalytic amounts of the dialkyl tartrate(titanium)(IV) complex are sufficient. 

The same bisoxazoline Cu(II) and Sn(II) complexes have been utilized successfully in the corresponding propionate aldol addition reactions (Scheme 8-7). A remarkable feature of these catalytic processes is that either syn or anti simple dia-stereoselectivity may be accessed by appropriate selection of either Sn(II) or Cu(II) complexes. The addition of either - or Z-thiopropionate-derived silyl ke-tene acetals catalyzed by the Cu(II) complexes afford adducts 78, 80, and 82 displaying 86 14-97 3 syn anti) simple diastereoselectivity. The optical purity of the major syn diastereomer isolated from the additions of both Z- and i -enol silanes were excellent (85-99% ee). The stereochemical outcome of the aldol addition reactions mediated by Sn(Il) are complementary to the Cu(U)-catalyzed process and furnish the corresponding anp -stereoisomers 79, 81, and 83 as mixtures of 10 90-1 99 syn/anti diastereomers in 92-99% ee. 

Bidentate Lewis acids result in a-chelation, and the (P)- and (M)-stannanes 286 approach from the less hindered face of the carbonyl, with the small substituent (H) over the metallocycle in the transition states 299 and 300, respectively. In the case of BF3 OEt2, reactions of allenylstannanes (P)-286 and (M)-286 create a matched/mismatched scenario with the (5)-aldehyde (Scheme 5.2.66). Addition of (M)-286 gives the syn,anti diastereomer 301 via the Comforth or polar Felkin-Anh transition state 303, whereas allenylstannane (P)-286 results in a diastereomeric mixtnre of syn,syn-2>fi4 (via 306) and antfanti-305. 

The rearrangement of E and Z-N-crotylamines 364 (R E or Z=Me) gave the corresponding nitriles 366 with 82 and 68% yield, respectively. Disappointingly, the product was obtained as an inseparable mixture of syn/anti diastereomers 366 indicating a low simple diastereoselectivity. Obviously, the intermediate ketene imine fitted neither a chair- nor a boat-like conformation. Hence, a low axis-to-center chirality induction was operative, and the E and Z reactants gave a 1.1 1 and a 1.6 1 ratio in favor of the major compound (isomer not determined. Scheme 10.73). 

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). 

Ghosh and co-workers have recently used the indanyl-derived auxiliary 69 (Table 1.9) in titanium enolate condensations with a range of aldehydes [34], Of the four possible diastereomers, only the anti 71 and syn TL were produced (the alternative anti and syn diastereomers were not detected by 1H or 13C NMR). The use of monodentate aliphatic aldehydes resulted in the formation of anti diastereomers... 

The yield of 17 is 50 62% in the reactions involving butyl- or. vw-butyllithium due to competitive transfer of the butyl or sec-butyl group. Yields of 17 are improved by using pyridine as the additive, but diastereoselectivity is not as high as when the alkyllithiums are employed. Without any additive, a complex mixture of syn- and anti-diastereomers plus products resulting from addition of the a-carbon of the substrate borane to the aldehyde are obtained. 

All four possible diastereomers are formed from the addition of the same Z-azaenolate to a series of aldehydes. Both the ratio of topside (major)/bottomside (minor) attack (4 1, controlled by the dihydroisoxazole substituents) and the diastereofacial selectivity (syn/anti ratio) are nearly independent of the structure of the aldehyde used26. 

Michael addition of alkyl organometallic reagents to a,/ -disubstituted nitroalkenes followed by protonation of the intermediate nitronate anion generally gives mixtures of syn- and anti-diastereomers with poor diastereoselectivity19. 

Indium-mediated allylation of an unreactive halide with an aldehyde132 was used to synthesize an advanced intermediate in the synthesis of antillatoxin,133 a marine cyanobacteria (Lyngbya majus-cula) that is one of the most ichthyotoxic compounds isolated from a marine plant to date. In the presence of a lanthanide triflate, the indium-mediated allylation of Z-2-bromocrotyl chloride and aldehyde in saturated NH4C1 under sonication yielded the desired advanced intermediate as a 1 1 mixture of diastereomers in 70% yield. Loh et al.134 then changed the halide compound to methyl (Z)-2-(bromomethyl)-2-butenoate and coupled it with aldehyde under the same conditions to yield the desired homoallylic alcohol in 80% yield with a high 93 7 syn anti selectivity (Eq. 8.55). 

Reactions of aldehydes with complexes 13—17 provide optically active homoallylic alcohols. The enantioselectivities proved to be modest for 13—16 (20—45% ee). In contrast, they are very high (> 94% ee) for the (ansa-bis(indenyl))(r]3-allyl)titanium complex 17 [32], irrespective of the aldehyde structure, but only for the major anti diastereomers, the syn diastereomers exhibiting a lower level of ee (13—46% ee). Complex 17 also gives high chiral induction (> 94% ee) in the reaction with C02 [32], in contrast to complex 12 (R = Me 11 % ee R = H 19% ee) [15]. Although the aforementioned studies of enan-... 

The diastereoselective addition to imines proceeds well with aromatic enolsi-lanes (249). Propiophenone- and tetralone-derived enolsilanes provide good levels of diastereoselectivity (>95 5) and excellent enantioselectivity (>98% ee) with selective formation of the anti diastereomer. Nonaromatic enolsilanes are somewhat less selective although cyclohexanone enolsilane still provides useful levels of diastereoselectivity and enantioselectivity (92 8 anti/syn and 88% ee at -78°C). A one-pot procedure using glyoxylate, sulfonamide, and enolsilane as coupling partners was developed subsequently, leading to the product in comparable yields and selectivities (250, 251). 

Diastereomer analysis on the unpurified aldol adduct 52b revealed that the total syn anti diastereoselection was 400 1 whereas enantioselective induction in the syn products was 660 1. On the other hand, Evans in some complementary studies also found that in the condensation of the chiral aldehyde 53 with an achiral enolate 56a only a slight preference was noted for the anti-Cram aldol diastereomer 58a (58a 57a = 64 36). In the analogous condensation of the chiral enolate 56b. however, the yn-stereoselection was approximately the same (57b 58b > 400 1) as that noted for enolate 49 but with the opposite sense of asymmetric induction (Scheme 9.17). Therefore, it can be concluded that enolate chirality transfer in these systems strongly dominates the condensation process with chiral aldehydes. 

The construction of an indolizidine skeleton has been successfully obtained by radical cyclizations mediated by (TMS)3SiH. Reaction (7.44) represented a key step in the total synthesis of (—)-slaframine. The two pairs of diastereomers were first separated and then hydrolysed to the corresponding alcohols in a 76% overall yield [55]. On the other hand the cyclization of the A-iodopropyl pyridinones in Reaction (7.45) occurs smoothly at room temperature using Et3B/02 as initiator, to give the desired products with a trifluoromethyl group at the bridgehead position in a syn/anti ratio of 7 3 [56]. 

The increased enantioselectivity of 88 is also apparent in reactions with chiral aldehydes (Figure 28). p-Alkoxypropionaldehydes 90 were relatively poor substrates when 36 was used.3 The best selectivity ever obtained for syn diastereomer 91 in the matched double asymmetric reactions was 89 11 [(S,S)-36 and 90a], whereas the best selectivity for anti diastereomer 92 was 87 13 [reaction of 90b and (R,R)-36. In contrast, the allylborations of 90a,b with the new reagent 88 now proceed with up to 97 3 selectivity for either product diastereomer. Even more impressive results were obtained with glyceraldehyde acetonide (23) the matched double asymmetric reaction leading to 29 now proceeds with 300 1 diastereoselectivity, while the mismatched combination leading to 30 proceeds with 50 1 selectivity. 

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