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Esters, 2-hydroxy chiral titanium enolates

Ghosh also took advantage of the C—2 hydroxyl moiety of aminoindanols as a handle in the aldol reaction. Chiral sulfonamide 41 was O-acylated to give ester 42. The titanium enolate of ester 42 was formed as a single isomer and added to a solution of aldehyde, precomplexed with titanium tetrachloride, to yield the anft -aldol product 43 in excellent diastereoselectivities.63 One additional advantage of the ester-derived chiral auxiliaries was their ease of removal under mild conditions. Thus, hydrolysis of 43 afforded a ft -a-methyl- 3-hydroxy acid 44 as a pure enantiomer and cis-1-/ -1 o I y I s u I f on a m i do- 2 - i n da n ol was recovered without loss of optical purity (Scheme 24.7).63... [Pg.467]

The method is also successful for carboxyhc esters , and A,A-disubstituted amides, and can be made enantioselective by the use of a chiral oxaziridine. Dimethyldioxirane also oxidizes ketones (through their enolate forms) to a-hydroxy ketones. Titanium enolates can be oxidized with tert-butyl hydroperoxide or with dimethyl dioxirane and hydrolyzed with aqueous ammonium fluoride to give the a-hydroxy ketone. Ketones are converted to the a-oxamino derivative (0=C CH2- 0=C CHONHPh) with excellent enantioselectivity using... [Pg.1754]

Covalently bonded chiral auxiliaries readily induce high stereoselectivity for propionate enolates, while the case of acetate enolates has proved to be difficult. Alkylation of carbonyl compound with a novel cyclopentadienyl titanium carbohydrate complex has been found to give high stereoselectivity,44 and a variety of ft-hydroxyl carboxylic acids are accessible with 90-95% optical yields. This compound was also tested in enantioselective aldol reactions. Transmetalation of the relatively stable lithium enolate of t-butyl acetate with chloro(cyclopentadienyl)-bis(l,2 5,6-di-<9-isopropylidene-a-D-glucofuranose-3-0-yl)titanate provided the titanium enolate 66. Reaction of 66 with aldehydes gave -hydroxy esters in high ee (Scheme 3-23). [Pg.155]

Chlorophenyl)glutarate monoethyl ester 87 was reduced to hydroxy acid and subsequently cyclized to afford lactone 88. This was further submitted to reduction with diisobutylaluminium hydride to provide lactol followed by Homer-Emmons reaction, which resulted in the formation of hydroxy ester product 89 in good yield. The alcohol was protected as silyl ether and the double bond in 89 was reduced with magnesium powder in methanol to provide methyl ester 90. The hydrolysis to the acid and condensation of the acid chloride with Evans s chiral auxiliary provided product 91, which was further converted to titanium enolate on reaction with TiCI. This was submitted to enolate-imine condensation in the presence of amine to afford 92. The silylation of the 92 with N, O-bis(trimethylsilyl) acetamide followed by treatment with tetrabutylammonium fluoride resulted in cyclization to form the azetidin-2-one ring and subsequently hydrolysis provided 93. This product was converted to bromide analog, which on treatment with LDA underwent intramolecular cyclization to afford the cholesterol absorption inhibitor spiro-(3-lactam (+)-SCH 54016 94. [Pg.70]

Anm Ghosh used aminoindanol as the chiral auxEiary. The titanium enolate was formed by reaction of the ester with titanium tetrachloride and diisopro-pylethylamine. This was reacted at -78 °C with cinnamaldehyde, pre-complexed with Bu2BOTf. The desired anti-enantiomer was obtained in a 6.1 1 excess. The diastereomers were separated by colmnn chromatography. The chiral auxEiary was subsequently cleaved off in a very mEd procedure with lithium hydroperoxide. Attempts to protect the hydroxy-carboxylic acid in the usual way, with pivalaldehyde in presence of camphor-lO-siEfonic acid or p-toluenesulfonic acid, faded. EventuaUy, isopropoxytrimethylsEane, TMSOTf and molecular... [Pg.378]

Duthaler and co vorkers used carbohydrate-titanium complexes for synthesis of optically active syn-/i-hydroxy-a-amino acids [51]. These syn-a-aminoaldols vere obtained in moderate yield and excellent syn diaster-eoselectivity, as shosvn in Table 2.25. Transmetalation of the lithium enolate of glycine ester derivative 145 svith chiral titanium complex 146 provided a titanium enolate svhich upon reaction svith a svide variety of aldehydes provided syn-j5-hydroxy-a-amino esters 148. Subsequent hydrolysis and N-protection gave a-aminoaldols 149. [Pg.92]


See other pages where Esters, 2-hydroxy chiral titanium enolates is mentioned: [Pg.916]    [Pg.487]    [Pg.309]    [Pg.309]    [Pg.309]    [Pg.318]    [Pg.93]    [Pg.2209]    [Pg.249]    [Pg.276]    [Pg.163]   


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Chiral enolate

Enol esters

Enolate ester, chiral

Enolates chiral

Enolates enol esters

Enolates titanium

Ester enolate

Esters chiral

Esters enolates

Esters enolization

Hydroxy chiral

Hydroxy esters

Titanium chirality

Titanium enolate

Titanium ester enolates

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