Asymmetric 1,3 anti

Goddard, N. J. Hulme, J. Malins, C. Singh, K. Fielden, P. R., Asymmetric anti resonant reflecting optical waveguides (ARROW) as chemical sensors, Analyst 2002, 127, 378 382... 

The aldol reactions of the titanium Z-enolates proceeded smoothly with various aldehydes precomplexed with titanium chloride at -78° C. The diastereose-lectivity is high to excellent, with the single exception of benzaldehyde. The high degree of diastereoselection associated with this current asymmetric anti-aldol process can be rationalized by a Zimmerman-Traxler type of six-membered chairlike transition state Al9fl (Scheme 2.2r). The model is based on the assumptions that the titanium enolate is a seven-membered metallocycle with a chairlike conformation, and a second titanium metal is involved in the transition state, where it is chelated to indanolyloxy oxygen as well as to the aldehyde carbonyl in a six-membered chairlike transition-state structure. 

Mitsumori, S. Zhang, H. Ha-Yeon Cheong, P Honk, K. N. Tanaka, R Barbas, C. F. Direct asymmetric anti-Mannich-type reactions catalyzed by a designed amino acid, 7. Am. Chem. Soc. 2006,128, 1040-1041. 

Gennari, C., Hewkin, C. T., Molinari, F., Bemardi, A., Comotti, A., Goodman, J. M., Paterson, I. The rational design of highly stereoselective boron enolates using transition-state computer modeling a novel, asymmetric anti aldol reaction for ketones. J. Org. Chem. 1992, 57, 5173-5177. 

For the introduction of the C g and C19 stereocenters to the aldehyde 17, we first tested Heathcock s asymmetric anti-selective aldol reaction (eq. 6) (43). We anticipated that the stereocenters in 17 would have little effect on diastereoselectivity since the two methylene groups are... 

In 2006 Barbas III, Houk and coworkers reported the direct asymmetric anti-Mannich-type reactions catalysed by the designed amino acid 29, whereas simple (5 )-proline was known to afford the q -adduct selectively (Scheme 11.25). ... 

Scheme 11.25 Asymmetric anti-Mannich-type reactions catalysed by the designed amino acid 29.

Evans DA, Aye Y, Wu J. Asymmetric, anti-selective scandium-catalyzed Sakurai additions to glyoxyamide. Applications to the syntheses of N-Boc o-alloisoleucine and D-isoleucine. Org. Lett. 2006 8 2071-2073. 

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). 

Structural prefixes should be italicized and connected with the chemical formula by a hyphen cis-, trans-, anti-, syn-, cyclo-, catena-, o- or ortho-, m- or meta-, p- or para-, sec- (secondary), tert-(tertiary), v- (vicinal), meso-, as- for asymmetrical, and 3- for symmetrical. 

The addition of methylmagnesium iodide to 2-phenylpropanal is stereoselective in producing twice as much syn-3-phenyl-2-butanol as the anti isomer (entry 5). The stereoselective formation of a particular configuration at a new stereogenic center in a reaction of a chiral reactant is called asymmetric induction. This particular case is one in which the stereochemistry can be predicted on the basis of an empirical correlation called Cram s rule. The structural and mechanistic basis of Cramls rule will be discussed in Chapter 3. 

The enantiomers are obtained as a racemic mixture if no asymmetric induction becomes effective. The ratio of diastereomers depends on structural features of the reactants as well as the reaction conditions as outlined in the following. By using properly substituted preformed enolates, the diastereoselectivity of the aldol reaction can be controlled. Such enolates can show E-ot Z-configuration at the carbon-carbon double bond. With Z-enolates 9, the syn products are formed preferentially, while fi-enolates 12 lead mainly to anti products. This stereochemical outcome can be rationalized to arise from the more favored transition state 10 and 13 respectively ... 

Jessop and co-workers studied asymmetric hydrogenation reactions with the catalyst complex Ru(OAc)2(tolBINAP) dissolved in [BMIM][PFg]. In both reactions under investigation - the hydrogenation of tiglic acid (Scheme 5.2.10) and the hydrogenation of the precursor of the anti-inflammatory dmg ibuprofen (Scheme 5.2.11) - no CO2 was present during the catalytic transformation. However, SCCO2 was used in both cases to extract the reaction products from the reaction mixture when the reaction was complete. 

In a similar manner, the asymmetric hydrogenation of isobutylatropic acid to afford the anti-inflammatory dmg ibuprofen has been carried out (Scheme 5.4-2). Here, the reaction was carried out in a [BMIM][PFg]/MeOH mixture, again followed by product extraction with SCCO2 (see Section 5.2.4.1 for more details on these hydrogenation reactions). 

Bartoli recently discovered that by switching from azide to p-anisidine as nucleophile, the ARO of racemic trans- 3-substituted styrene oxides could be catalyzed by the (salen)Cr-Cl complex 2 with complete regioselectivity and moderate selectivity factors (Scheme 7.36) [14]. The ability to access anti-P-amino alcohols nicely complements the existing methods for the preparation of syn-aryl isoserines and related compounds [67] by asymmetric oxidation of trans-cinnamate derivatives [68]. 

The influence of 1,2-asymmctric induction on the exchange of diastereotopic bromine atoms has also been investigated22,23. Thus, treatment of the / -silyloxydibromo compound 15 with butyllithium at — 110°C in the presence of 2-methylpropana led to products 17-19 after the reaction mixture was warmed to 20 °C. The distribution of the products indicates that the diastereomeric lithium compounds 16 A and 16B were formed in a ratio of 84 16, with 16A being kinetically favored by 1,2-asymmetric induction. Formation of the m-configurated epoxide (cis,anti-18) was slowed to such an extent that its formation was incomplete and a substantial amount of the parent bromohydrin 17 remained. The analogous m.yyn-configurat-ed epoxide was not observed. Presumably for sterie reasons, the parent bromohydrin did not cyclize to the epoxide but instead led to the ketone 1923. 

Optically active (Z)-l-substituted-2-alkenylsilanes are also available by asymmetric cross coupling, and similarly react with aldehydes in the presence of titanium(IV) chloride by an SE process in which the electrophile attacks the allylsilane double bond unit with respect to the leaving silyl group to form ( )-s)vr-products. However the enantiomeric excesses of these (Z)-allylsilanes tend to be lower than those of their ( )-isomers, and their reactions with aldehydes tend to be less stereoselective with more of the (E)-anti products being obtained74. 

The geometry of the ester enolate dictates the configuration of the cxtracyclic asymmetric center an (ii)-enolate gives mainly an anti-adduct and a (Z)-cnolate gives a wn-adduct. This is in accordance with the stereochemical results with tram-acyclic esters bearing in mind the fact that in this case a cw-unsaturated ester is present in the cyclic Michael acceptor. 

The addition of the lithium azaenolate of the SAMP hydrazone of propanal to methyl (E)-2-butenoate to furnish the (S,S,S)-adduct in 58% yield with > 96% ee and de is illustrative for the efficiency of this asymmetric Michael addition10°. Only the anti-isomer (an / adduct) is found. This methodology was used in the synthesis of pheromones of the small forest and red wood ant200. 

All the asymmetric thiirane oxides which have been obtained through this procedure are mixtures of the two possible cis- and trans- syn- and anti-) configurations, but the antiisomer predominates. 

Of perhaps greater use for organic synthesis was the observation that photo-driven reactions of alkoxycarbenes with unsubstituted optically active ene carbamates [65] produced aminocyclobutanones in fair yield with high dia-stereoselectivity (Table 12) [66]. In contrast, with a gem-disubstituted ene carbamate, the syn-anti selectivity was low but high asymmetric induction a to nitrogen was observed (Eq. 16). Trans-monosubstituted ene carbamates failed to react, as did a,/J-unsaturated chromium carbene complexes. 

Thus the product in such cases can exist as two pairs of enantiomers. In a di-astereoselective process, one of the two pairs is formed exclusively or predominantly as a racemic mixture. Many such examples have been reported. In many of these cases, both the enolate and substrate can exist as (Z) or (E) isomers. With enolates derived from ketones or carboxylic esters, (E) enolates gave the syn pair of enantiomers (p. 146), while (Z) enolates gave the anti pair. Addition of chiral additives to the reaction, such as proline derivatives, or (—)-sparteine lead to product formation with good-to-excellent asynunetric induction. Ultrasound has also been used to promote asymmetric Michael reactions. Intramolecular versions of Michael addition are well known. ... 

The 4-thiazolidinyl phosphonates 143 (Scheme 44) are known for their therapeutical properties, in particular as anti-inflammatory agents [5,89]. Their asymmetric synthesis by hydrophosphonylation of 3-thiazolines has been described using various chiral auxiliaries chiral phosphites such as (2S,4i )-2H-2-oxo-5,5-dimethyl-4-phenyl-l,3,2-dioxaphosphorinane (de = 2-8%) [90] or BINOL-phos-phite (de = 65-90%) [91] and also chiral catalyst such as titanium or lanthanide chiral complexes (ee = 29-98%) [92]. Hydrophosphonylation of C2-chiral3-thi-azolines has also been performed (de = 32-38%) [93]. 

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