Acrylates optically active

The trimethylsilyl enol ethers of 1-acetylcyclohexenes 1 undergo a Lewis acid assisted two fold Michael reactions with Michael acceptors 2 to produce 5-substituted 2-decalones 3. The application of these reactions have enabled syntheses of ( )-8-cadinene 4, ( )-khusitone 5, and ( )-khusilal 6. By employing 8- phenylmenthyl acrylate, optically active 2-decalone 3 (ca. 

Recently, optically active (+)-(R)-methy 1 tolyl sulfoxide 102, R = H was alkylated with a very high diastereoselectivity136. The sulfoxide was treated with either lithium diisopropy-lamide (LDA) or lithium tetramethylpiperidide (LTMP) to form the lithio-derivative, which upon subsequent reaction with lithium a-bromomethyl acrylate gave a mixture of two diastereomers of a-methylene-y-sulfinylcarboxylic acid 103. The use of the sterically highly hindered base, LTMP, gave the product with a higher diastereoselectivity. For example, the Sc4 Rc4 ratio was 95 5 when R was the methyl group. 

Hydroperoxides, as optically active oxidizing agents 289-291 Hydrosulphonylation 172 /J-Hydroxyacids 619 a-Hydroxyaldehydes, synthesis of 330 a-Hydroxyalkyl acrylates, chiral 329 j -Hydroxycarboxylic esters, chiral 329 3-Hydroxycycloalkenes, synthesis of 313 Hydroxycyclopentenones, synthesis of 310 -Hydroxyesters 619 synthesis of 616 Hydroxyketones 619, 636 Hydroxymethylation 767 a-Hydroxysulphones, synthesis of 176 / -Hydroxysulphones 638, 639 reactions of 637, 944 electrochemical 1036 synthesis of 636 y-Hydroxysulphones 627 synthesis of 783... 

Hydrostannation of chiral menthyl esters of substituted acrylic acids proceeds stereoselectiveiy, providing a route to optically active alkyl-... 

All sixteen of the racemic carba-sugars predicted are known, as well as fifteen of the enantiomers. The most accessible starting-material for the synthesis of racemic carba-sugars is the Diels-Alder adduct of furan and acrylic acid, namely, e i o7-oxabicyclo[2.2.1]hept-5-ene-2-carboxylicacid (29). Furthermore, adduct 29 is readily resolved into the antipodes, (—)-29 and (+)-29, by use of optically active a-methylbenzylamine as the resolution agent. The antipodes were used for the synthesis of enantiomeric carba-sugars by reactions analogous to those adopted in the preparation of the racemates. 

Reaction of optically active a-sulphinyl acetate 298a with prochiral carbonyl compounds proceeds with a high asymmetric induction - , the degree of which depends on the nature of substituents at the carbonyl group (equation 252 Table 22) . The jS-hydroxy sulphoxides 422 formed may be transformed to optically active p-hydroxycarboxylic esters 423 (equation 253) and optically active long-chain lactones 424 99 (equation 254). Corey and coworkers have used this method to introduce a chiral centre at C-3 in their synthesis of maytansin °°, and Papageorgiou and Benezra for the synthesis of chiral a-hydroxyalkyl acrylates 425 ° (equation 255). 

Therefore, another analogous reaction was studied with a more reactive olefin, viz. methyl acrylate, which reacts with (+)-methylneophylphenyltin deuteride (86) at room temperature and yields after 18 h again an optically inactive adduct which is reduced with lithium aluminum hydride to give racemic isotopically labeled (55) 44). After 18h in the presence of AIBN at room temperature, (86) only loses 30% of its optical activity in benzene. The fact that the obtained adduct is optically inactive might be due to the nucleophilicity of methyl acrylate, which might be important enough to cause the racemization of (56). 

It is also possible to carry out a substrate-controlled reaction with aldehydes in an asymmetric way by starting with an acetylene bearing an optically active ester group, as shown in Eq. 9.8 [22]. The titanium—acetylene complexes derived from silyl propiolates having a camphor-derived auxiliary react with aldehydes with excellent diastereoselectivity. The reaction thus offers a convenient entry to optically active Baylis—Hillman-type allyl alcohols bearing a substituent (3 to the acrylate group, which have hitherto proved difficult to prepare by the Baylis—Hillman reaction itself. 

Both the reaction of yhde 162f with methyl acrylate and the reaction of ylide 162c with methyl methacrylate produce, after hydrolysis, the same optically active tran5-2-methylcyclopropanecarboxylic acid with optical purities of 43.2 and 11.9%, respectively (295). 

Asymmetric induction using an optically active acrylate ester with O-ethylthiohydroxamate has also been reported (87TL4205). [See reaction (52).] A review on the photolysis and thermolysis of O-hydroxamic thio-... 

The present procedure involving homogeneous catalysis is operationally simple and takes advantage of the easy availability of 2-(l -hydroxyalkyl )-acrylic esters. A two-step procedure Involving kinetic resolution of the racemic starting material with an optically active hydrogenation catalyst, followed by a further reduction with an achiral catalyst, leads to diastereomerically pure products in 4. 97t ee. 

Substituted acrylates (which reseitible the enamide substrates employed 1n asymmetric hydrogenation) may be deracemized by reduction with an optically active catalyst, especially DIPAMPRh . Selectivity ratios of 12 1 to 22 1 have been obtained for a variety of reactants with compounds of reasonable volatility, separation of starting material and product may be effected by preparative GLC. Recovered starting material can then be reduced with an achiral catalyst to give the optically pure anti product. Examples of kinetic resolutions by this method are given in Table II. More recently very successful kinetic resolutions of allylic alcohols have been carried out with Ru(BINAP) catalysts. 

Some chiral 1,3,2-dioxastannolanes were used as catalysts in asymmetric Diels-Alder reactions of cyclopentadiene with methyl acrylate <90JCR(S)278>. A-Alkenyl- and -cycloalkenyl 1,3,2-oxaza-stannolanes, generated in situ from chiral amino alcohols, gave optically active 2-substituted aldehydes and ketones in modest to high chemical and optical yields after alkylation with methyl acrylate or acrylonitrile (which is usual for enamines) and subsequent hydrolysis <85CC504,85JOC3863>. 

Isoxazolines can be transformed into a,p-enones by several methods from the initial aldol product. This strategy was applied by Barco et al. (285) toward the synthesis of ( )-pyrenophorin (98), a macrocychc fow(enone-lactone) with antifungal properties. The hydroxy group was introduced from the nitrile oxide component (95), while the carboxy function was derived from the acrylate dipo-larophile. Thus, cycloaddition of the optically active nitropentyl acetate 94 to methyl acrylate 95 afforded isoxazoline 96 as a mixture of optically active diastereomers. Reductive hydrolysis using Raney nickel/acetic acid gave p-hydro-xyketone (97), which was subsequently utilized for the synthesis of (—)-pyreno-phorin (98) (Scheme 6.63) (285). 

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... 

The formation of spirocyclopropanes from the reaction of diazodiphenylmethane and ( )-8-phenylmenthyl esters of acrylic acid and methyl fumarate occurred with a modest level of diastereofacial selectivity (136). In contrast, diastereoselectivities of 90 10 were achieved in the cycloadditions of diazo(trimethylsilyl)methane with acrylamides 65 derived from camphor sultam as the chiral auxiliary (137) (Scheme 8.16). Interestingly, the initial cycloadducts 66 afforded the nonconjugated A -pyrazolines 67 on protodesilylation the latter were converted into optically active azaproline derivatives 68. In a related manner, acrylamide 69 was converted into A -pyrazolines 70a,b (138). The major diastereoisomer 70a was used to synthesize indolizidine 71. The key step in this synthesis involves the hydrogenolytic cleavage of the pyrazoline ring. 

Chiral aziridines having the chiral moiety attached to the nitrogen atom have also been applied for diastereoselective formation of optically active pyrrolidine derivatives. In the first example, aziridines were used as precursors for azomethine ylides (90-95). Photolysis of the aziridine 57 produced the azomethine ylide 58, which was found to add smoothly to methyl acrylate (Scheme 12.20) (91,93-95). The 1,3-dipolar cycloaddition proceeded with little or no de, but this was not surprising, as the chiral center in 58 is somewhat remote from the reacting centers... 

The synthesis of l-methylpyrrolizid-7-one49 was very important for final confirmation of the structure of the naturally occurring pyrrolizi-dine bases. The starting ethyl ester of 3-methylproline (80), obtained by analogy with proline,50 was condensed with ethyl acrylate and the condensation product (81) converted into l-methylpyrrolizidine-7-one (82) by cyclization and ketonic hydrolysis. A similar route starting with the ethyl ester of 3-methyl-L-proline afforded optically active... 

Asymmetric hydrogenationRh(I) complcxed with (R)- or (S)-l catalyzes the asymmetric hydrogenation of prochiral a-(acylamino)acrylic acids, R CHC—C-(COOH)NHCOR2, to optically active derivatives of (R)- or (S)-alanine (85 100% ee). 

This conclusion is wholly proved by the ozonization (36) of polymers of alkyl sorbates and of alkyl styryl-acrylates obtained by anionic mechanism, which yielded optically active methylsuccinic, and respectively phenylsuccinic acid. 

Systematic research on the polymerization of optically active monomers and on polymers derived therefrom, has been mostly carried out with a-olefins, vinyl-ethers and acrylic derivatives. 

A large number of optically active poly-acryl-derivatives, mainly esters or amides, have been described in literature, although no series of homologous compounds has been systematically investigated. 

Optically active acrylic, chloro-acrylic and methacrylic esters of sec. butyl alcohol, 2-methyl-butyl alcohol, 1.3-dimethyl-butyl alcohol, 1-methyl-benzyl alcohol, bomeol and menthol have been polymerized mostly by radical mechanism (Tables 16, 17, 18). 

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