Substituted acetic acids

Imoto and his co-workers121 have measured the rate of acetoxy-mercuration of some 2-R-substituted thiophenes (R = CH3, H, Br, COCH3, C02Et) in acetic acid. Substitution occurred exclusively... 

Title S-(a,a -Disubstituted-a"-Acetic Acid) Substituted Dithiocarbonate Derivatives for Controlled Radical Polymerizations, Process, and Polymers Made Therefrom... 

A single-step method for preparing -(a, a -disubstituted-a"-acetic acid) substituted dithiocarbonate derivatives is described. These agents are effective as modulators in free radical polymerization reactions. 

Methanesulfonylacetic acid gives an analogous product (92%), so the process may be general for acetic acids substituted by strong electron-withdrawing groups. 

Sulfoxide 6 has been prepared by treating l,2 5,6-dianhydro-3,4-0-isopro-pylidene-D-mannitol successively with the appropriate thiol-potassium carbonate, benzyl bromide-sodium hydride, MCPBA then aqueous acetic acid. Substitution of MCPBA by meta-periodic acid led to the formation of sulfone 7. The compounds were tested as potential inhibitors of HIV-1 protease. ... 

Each experiment began with irrigation of a dog s Heidenhain pouch with a test solution of 100 mN HCl and 15 mN NaCl made isotonic by addition of 78 mM mannitol. The solution contained " Na and 3.6 excess mols of D2O. I followed this control period with two successive 30-minute periods of irrigation with a solution of 100 mN acetic acid substituted for the HCl. I found no difference between the two periods, and I pooled their results. Finally, I tested the pouch again with the HCl test solution. 

Also in other series of growth substances indications are found that substitutions not compatible with auxin activity may lead to an antiauxin character of the respective compound, as e.g. for benzoic acids and phenoxy-acetic acids substituted in the 4- or 2,6-positions respectively . ... 

As the isoelectric point of most enzymes is lower than 7, the entrapment procedure has generally been preferred, particularly when PPy has been involved. However, this method could lead in some cases to a loss of enzyme activity [93, 95]. It has been suggested that such a loss could be avoided by covalent immobilization of the enzyme, as has already been reported for 3-acetic acid-substituted polythiophene [92]. 

CF3CO2H. Colourless liquid, b.p. 72-5 C, fumes in air. Trifluoroacetic acid is the most important halogen-substituted acetic acid. It is a very strong acid (pK = o y) and used extensively for acid catalysed reactions, especially ester cleavage in peptide synthesis. 

Acidic Hydrolysis. Hot concentrated caustic alkalis first hydrolyse off the ethyl group, and then split the molecule to give one equivalent of acetic acid and one equivalent of the mono- or di-substituted acetic acid (as their alkali salts). 

In brief, suitable hydrolysis of ethyl acetoacetate derivatives will give mono-or di-alkyl substituted acetones or acetic acids. Tri-substituted acetones or acetic acids cannot be obtained moreover, the di-substituted acetones must... 

It follows therefore that ethyl malonate can be used (just as ethyl aceto- acetate) to prepare any mono or di-substituted acetic acid the limitations are identical, namely the substituents must necessarily be alkyl groups (or aryl-alkyl groups such as CjHjCHj), and tri-substituted acetic acids cannot be prepared. Ethyl malonate undergoes no reaction equivalent to the ketonic hydrolysis of ethyl acetoacetate, and the concentration of the alkali used for the hydrolysis is therefore not important. 

Formation of a Quinoxaline. Heat together for 5 minutes under reflux 0 2 g. of phenanthraquinone dissolved in i ml. of glacial acetic acid and 0-2 g. of O -phenylene diamine also dissolved in i ml, of glacial acetic acid. The yellow substituted quinoxaline (p. 305) separates rapidly. Cool, filter and recrystallise from benzene m.p. 225 . 

The alkylidene dimethone (dimedone) (I) upon boiling with glacial acetic acid, acetic anhydride, hydrochloric acid and other reagents frequently loses water and passes into a substituted octahydroxanthene or the anhydride (II), which often serves as another derivative. The derivatives (I) are soluble in dilute alkali and the resulting solutions give colourations with ferric chloride solution on the other hand, the anhydrides (II) are insoluble in dilute alkali and hence can easily be distinguished from the alkylidene dimedones (I). 

Dissolve 0 5 g. of the primary amine and 0-5 g. of pure phthaUc anhydride in 5 ml. of glacial acetic acid and reflux for 20-30 minutes. (If the amine salt is used, add 1 g. of sodium acetate.) The N-substituted phthaUmide separates out on cooling. Recrystallise it from alcohol or from glacial acetic acid. 

With concentrated alkali, fission occurs at the position adjacent to the carbonyl group to give acetic acid and a mono-substituted acetic acid the process is termed acid hydrolysis. 

Alkylation of the sodio derivative affords the C-substituted cyanoacetic ester, which when heated with dilute acid gives the mono-substitut acetic acid. 

The catalysed nitration of phenol gives chiefly 0- and />-nitrophenol, (< 0-1% of w-nitrophenol is formed), with small quantities of dinitrated compound and condensed products. The ortho para ratio is very dependent on the conditions of reaction and the concentration of nitrous acid. Thus, in aqueous solution containing sulphuric acid (i 75 mol 1 ) and nitric acid (0-5 mol 1 ), the proportion of oriha-substitution decreases from 73 % to 9 % as the concentration of nitrous acid is varied from o-i mol l i. However, when acetic acid is the solvent the proportion of ortAo-substitution changes from 44 % to 74 % on the introduction of dinitrogen tetroxide (4-5 mol 1 ). 

In solutions of acetyl nitrate in acetic anhydride, prepared from purified nitric acid, the 0 -ratio increases slightly with increasing concentrations of acetyl nitrate (table 5.7, expts. 11,13,16). The use of fuming nitric acid in the preparation of the acetyl nitrate considerably accelerates the rates of reaction and also increases the proportion of o-substitution (table 5.7, expts. 12, 15, 18). These effects resemble, but are much stronger than the corresponding effects in nitrations with solutions of nitric acid in acetic acid contaimng dinitrogen tetroxide. 

The heats of formation of Tt-complexes are small thus, — A//2soc for complexes of benzene and mesitylene with iodine in carbon tetrachloride are 5-5 and i2-o kj mol , respectively. Although substituent effects which increase the rates of electrophilic substitutions also increase the stabilities of the 7r-complexes, these effects are very much weaker in the latter circumstances than in the former the heats of formation just quoted should be compared with the relative rates of chlorination and bromination of benzene and mesitylene (i 3 o6 x 10 and i a-Sq x 10 , respectively, in acetic acid at 25 °C). 

Another way would be to generate ones own HBr gas. If you were to take a look in the Crystallization section of this book one would see that the apparatus used is essentially an HCI gas generator. Substituting the commercially available 48% aq. HBr instead of HCI will give one dry HBr gas instead That gas can be channeled directly into acetic acid just like above. 

METHOD 2 [89]--1M MDA or benzedrine and 1M benzaldehyde is dissolved in 95% ethanol (Everclear), stirred, the solvent removed by distillation then the oil vacuum distilled to give 95% yellow oil which is a Schiff base intermediate. 1M of this intermediate, plus 1M iodomethane, is sealed in a pipe bomb that s dumped in boiling water for 5 hours giving an orangy-red heavy oil. The oil is taken up in methanol, 1/8 its volume of dH20 is added and the solution refluxed for 30 minutes. Next, an equal volume of water is added and the whole solution boiled openly until no more odor of benzaldehyde is detected (smells like almond extract). The solution is acidified with acetic acid, washed with ether (discard ether), the MDMA or meth freebase liberated with NaOH and extracted with ether to afford a yield of 90% for meth and 65% for MDMA. That s not a bad conversion but what s with having to use benzaldehyde (a List chemical) Strike wonders if another aldehyde can substitute. 

Unsymmetrically substituted dipyrromethanes are obtained from n-unsubstitued pyrroles and fl(-(bromomethyl)pyiToIes in hot acetic acid within a few minutes. These reaction conditions are relatively mild and the o-unsubstituted pyrrole may even bear an electron withdrawing carboxylic ester function. It is still sufficiently nucleophilic to substitute bromine or acetoxy groups on an a-pyrrolic methyl group. Hetero atoms in this position are extremely reactive leaving groups since the a-pyrrolylmethenium( = azafulvenium ) cation formed as an intermediate is highly resonance-stabilized. 

A mild procedure which does not involve strong adds, has to be used in the synthesis of pure isomers of unsymmetrically substituted porphyrins from dipyrromethanes. The best procedure having been applied, e.g. in unequivocal syntheses of uroporphyrins II, III, and IV (see p. 251f.), is the condensation of 5,5 -diformyldipyrromethanes with 5,5 -unsubstituted dipyrromethanes in a very dilute solution of hydriodic add in acetic acid (A.H. Jackson, 1973). The electron-withdrawing formyl groups disfavor protonation of the pyrrole and therefore isomerization. The porphodimethene that is formed during short reaction times isomerizes only very slowly, since the pyrrole units are part of a dipyrromethene chromophore (see below). Furthermore, it can be oxidized immediately after its synthesis to give stable porphyrins. 

Reactions of the 2-amino-4,5-substituted thiazole (52) in acetic acid with ethylene oxide has been reported to give the N-exocyclic disubstitution product (S3) (201) in a 40% yield (Scheme 38). The reactive species in this reaction is probably the carbocation generated in acetic acid by ethvlene oxide. 

Phenyl-5-thiazolyl)acetic acids variously substituted in the 2-position give the corresponding naphtho[l,2]thiazoles in the presence of acetic anhydride and sodium acetate (397, 426, 857). 

Halogenation (e.g., bromination) takes place in chloroform for the 2,4-dialkylthiazoles, and the majority of studies have been of 2,4-dimethylthiazole (227, 228). In other cases and in acetic or stronger acids, substitution occurs at the 5-position and is promoted by electronreleasing groups in the 2-position. When the releasing group is in the 4-(or 5-)-position, steric hindrance may decrease the yield of substitution at the 5- (or 4-) position. Nevertheless, the thiazole nucleus is not very reactive since 4-methylthiazole and 2.5-dimethylthiazole are inert in dilute sulfuric acid with bromine (229-231). 

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