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Substitution by acetyl

Anilino vinyl derivatives of thiazolium (30, R = H) or acetanilido (30, R = C0CH3), as well as formyl methylene 30b (methods E-G), give asymmetrical dyes when condensed with a methyl reactive group of another species (Scheme 42). Mesosubstituted symmetrical or unsymmet-rical thiazolocyanines are obtainable via /S-alkylmercaptovinyl thiazolium derivatives (32) (methods H and I) (Scheme 43). a or /S carbon atoms of the trimethine chain can be substituted by acetyl when a dye is treated with acetic anhydride (method L). The hydrolysis of neocyanines lead to trimethine cyanine by fractional elimination of a composant chain (method K). [Pg.55]

The two parallel chains on the u-axis can be transformed by the symmetry operations to their antiparallel counterparts shown on the right side of the unit cell. Hydrogen bonds are no longer formed because all hydroxyl groups are substituted by acetyl moieties and CTA becomes a thermoplastic. [Pg.42]

Iwata T., Azuma J., Okamura K., Muramoto M., Chun B., Preparation and NMR assignments of cellulose mixed esters regioselectively substituted by acetyl and propanoyl groups, Carbohyd. Res., 224, 1992,277-283. [Pg.365]

With active methylene compounds, the carbanion substitutes for the hydroxyl group of aHyl alcohol (17,20). Reaction of aHyl alcohol with acetylacetone at 85°C for 3 h yields 70% monoaHyl compound and 26% diaHyl compound. Malonic acid ester in which the hydrogen atom of its active methylene is substituted by A/-acetyl, undergoes the same substitution reaction with aHyl alcohol and subsequendy yields a-amino acid by decarboxylation (21). [Pg.73]

The separation of Hquid crystals as the concentration of ceUulose increases above a critical value (30%) is mosdy because of the higher combinatorial entropy of mixing of the conformationaHy extended ceUulosic chains in the ordered phase. The critical concentration depends on solvent and temperature, and has been estimated from the polymer chain conformation using lattice and virial theories of nematic ordering (102—107). The side-chain substituents govern solubiHty, and if sufficiently bulky and flexible can yield a thermotropic mesophase in an accessible temperature range. AcetoxypropylceUulose [96420-45-8], prepared by acetylating HPC, was the first reported thermotropic ceUulosic (108), and numerous other heavily substituted esters and ethers of hydroxyalkyl ceUuloses also form equUibrium chiral nematic phases, even at ambient temperatures. [Pg.243]

It has been found that substitution of cellulose hydroxyls of cotton by acetyl groups, greatly affects the graft yield [45],... [Pg.536]

The retro-Claisen reaction occurs by initial nucleophilic addition of a cysteine -SH group on the enzyme to the keto group of the /3-ketoacyl CoA to yield an alkoxide ion intermediate. Cleavage of the C2-C3 bond then follows, with expulsion of an acetyl CoA enolate ion. Protonation of the enolate ion gives acetyl CoA, and the enzyme-bound acyl group undergoes nucleophilic acyl substitution by reaction with a molecule of coenzyme A. The chain-shortened acyl CoA that results then enters another round of tire /3-oxidation pathway for further degradation. [Pg.1136]

Schemes 28 and 29 illustrate Curran s synthesis of ( )-hirsutene [( )-1]. Luche reduction58 of 2-methylcyclopentenone (137), followed by acetylation of the resulting allylic alcohol, furnishes allylic acetate 138. Although only one allylic acetate stereoisomer is illustrated in Scheme 28, compound 138 is, of course, produced in racemic form. By way of the powerful Ireland ester enolate Clai-sen rearrangement,59 compound 138 can be transformed to y,S-unsaturated tm-butyldimethylsilyl ester 140 via the silyl ketene acetal intermediate 139. In 140, the silyl ester function and the methyl-substituted ring double bond occupy neighboring regions of space, a circumstance that favors a phenylselenolactonization reac-... Schemes 28 and 29 illustrate Curran s synthesis of ( )-hirsutene [( )-1]. Luche reduction58 of 2-methylcyclopentenone (137), followed by acetylation of the resulting allylic alcohol, furnishes allylic acetate 138. Although only one allylic acetate stereoisomer is illustrated in Scheme 28, compound 138 is, of course, produced in racemic form. By way of the powerful Ireland ester enolate Clai-sen rearrangement,59 compound 138 can be transformed to y,S-unsaturated tm-butyldimethylsilyl ester 140 via the silyl ketene acetal intermediate 139. In 140, the silyl ester function and the methyl-substituted ring double bond occupy neighboring regions of space, a circumstance that favors a phenylselenolactonization reac-...
For the formation of substituted THF rings (Route a, Scheme 8.1), Kishi developed a procedure based on the hydroxy-directed epoxidation of a y-alkenol [10]. Epoxidation of bishomoallylic alcohol 3 by TBHP/VO(acac)2 by this approach, followed by treatment of the intermediate epoxide 4 with acetic acid, gave the TH F derivative 5 of isolasalocid A (a 5-exo cydization Scheme 8.2) [11]. Further epoxidation of 5 (a y-alkenol) under the same conditions, followed by acetylation, afforded epoxide 6. For the synthesis of the natural product, the configuration of epoxide 6 had to be inverted before the second cydization reaction. Epoxide 6 was consequently hydrolyzed under acid conditions to the corresponding diol and was then selectively... [Pg.272]

Acetylchloride is a trapping agent that allows the reaction to go completion, transforming the product into a less oxidizable compound.The results of other reactions between indole (57) and substituted cyclohexa-1,3-dienes show that the photo-induced Diels-Alder reaction is almost completely regioselective. In the absence of 59 the cycloaddition did not occur the presence of [2+2] adducts was never detected. Experimental data support the mechanism illustrated in Scheme 4.14. The intermediate 57a, originated from bond formation between the indole cation radical and 58, undergoes a back-electron transfer to form the adduct 60 trapped by acetyl chloride. [Pg.165]

Interesting developments in simple azetidine chemistry continue to be reported. The apparently general acetylative dealkylation of Af-tert-butyl-3-substituted azetidines 6 (R = Bu ) in the presence of boron trifluoride provides a two-step route to azabicyclobutane 7 from 6 (R = Bu, R = Cl). An aqueous solution of 7 reacts with ethyl chloroformate to give 8. Relatively unexplored 3-azetidinones 9 (R = Ac or NO2) are available from 3-acetoxya2Ktidine 6 (R = Ac, R = OAc) which is obtained by acetylative dealkyation of 6 (R = Bu , R = OAc) <96JOC5453>. 3-Substituted azetidines can be utilized in the synthesis of polyfunctional y- and S-aminophosphonic acid derivatives <95TL9201>. [Pg.65]

Substitution reactions of 36 with nucleophilic acetate ions, followed by acetylation, furnished two carba-sugar pentaacetates of the a-DL-ido (38 31 % yield) and a-DL-galacto configurations (19 10%). The reactions seemed to involve formation of an intermediary 2,3-cyclic acetoxonium ion. ... [Pg.31]

As had been observed in the synthesis of carbohydrate-substituted polymers of different lengths, the reactivity of the monomers was an important parameter in generating the triblock polymers. If the mannose-substituted 7-oxanor-bornene derivative was first polymerized, followed by the galactose-derivatized norbornene and the mannose-substituted norbornene monomers, two distinct sets of products were observed. These were identified by modification of the resulting polymers by acetylation, and analysis of the products by GPC. With this protocol, it was found that the product was composed of short polymers (DP=... [Pg.232]


See other pages where Substitution by acetyl is mentioned: [Pg.72]    [Pg.40]    [Pg.61]    [Pg.81]    [Pg.229]    [Pg.146]    [Pg.128]    [Pg.336]    [Pg.377]    [Pg.19]    [Pg.1561]    [Pg.72]    [Pg.40]    [Pg.61]    [Pg.81]    [Pg.229]    [Pg.146]    [Pg.128]    [Pg.336]    [Pg.377]    [Pg.19]    [Pg.1561]    [Pg.137]    [Pg.30]    [Pg.298]    [Pg.400]    [Pg.100]    [Pg.82]    [Pg.257]    [Pg.295]    [Pg.238]    [Pg.289]    [Pg.212]    [Pg.110]    [Pg.159]    [Pg.248]    [Pg.39]    [Pg.8]    [Pg.15]    [Pg.26]    [Pg.27]    [Pg.138]    [Pg.139]    [Pg.691]    [Pg.41]    [Pg.139]    [Pg.46]    [Pg.564]   


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Acetyl substitution

Acetyl-substituted

By acetylation

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