Elimination acyl compounds

In contrast to what has been reported (75CB379), 2-(a-hydroxyalkyl)pyri-dinium salts 50 are stable in alkaline solution if no oxidizing agents are present. 2-Acylated compounds (51), however, will hydrolyze instantaneously in alkali and form 52 by elimination of carboxylic acids (65CJC1250 82JHC1549). If oxidation at the 2-a-C position is prevented as in 53, 54 is obtained as might be expected. The alternative oxidation to the 4-pyridone 54 does not occur (75AP637). 

Somewhat similar methods are used in the preparation of bromo-anilines. Consider, for example, the preparation of p-bromoaniline. The action of bromine on aniline gives quantitatively 2, 4, 6-tribro-moaniline. If aniline is first acetylated and then brominated, ortho-and poro-bromoacetanilides are formed with the para isomer predominating. The ortho compound is more soluble in alcohol than the para isomer, and thus can be removed by crystallization. The p-bromoacetanilide is then hydrolyzed. A variation of this method is to add bromine very slowly to aniline dissolved in a large excess of glacial acetic acid, when p-bromoaniline is directly formed, thereby eliminating acylation and hydrolysis. 

Perot et al. [7] in collaboration with Rhodia have studied the deactivation of industrial catalysts HBEA and HY during the acylation of veratrole and anisole. After reaction, the spent catalysts were extracted with methylene chloride. This Soxhlet extraction makes possible the elimination of compounds that were not strongly adsorbed on the zeolites. The composition of the residue obtained after evaporation of methylene chloride was practically the same as that of the reaction mixture at the end of the experiment. By this extraction procedure, approximately 80% of the compounds remaining on the catalysts after reaction were recovered. After Soxhlet extraction, the catalyst samples were recovered and dissolved with hydrofluoric acid. The organic compounds released by the catalysts were extracted again by methylene chloride and, after evaporation of solvent, the residues contained di- and triketones as well as cyclization compounds, the structures of which are presented in Scheme 14.1. 

As we begin now to explore the syntheses of carboxylic acid derivatives, we shall find that in many instances one acid derivative can be synthesized through a nucleophilic addition—elimination reaction of another. The order of reactivities that we have presented gives us a clue as to which syntheses are practical and which are not. In general, less reactive acyl compounds can be synthesissed from more reactive ones, but the reverse is usually difficult and, when possible, requires special reagents. 

Acyl transfer reactions (Section 17.4) A reaction in which a new acyl compound is formed by a nucleophilic addition-elimination reaction at a carbonyl carbon bearing a leaving group. 

The mono-acyl compounds (75) are further convertible into O-acyl derivatives (77), which are once again deacylated on pyrolysis. When the groups and R (in 78) are non-identical, the elimination occurs in such... 

As always, we need to be able to generalize. This chapter describes the chemistry of a set of related acyl compounds. It will be very hard to memorize the vast array of addition-elimination processes, but it should be relatively easy to see them all as the same reaction repeated over and over. Only the detailed stmcture changes—the overall reaction does not. 

As mentioned before, all acyl compounds participate in the addition-elimination process. Acid chlorides are especially reactive toward nucleophiles. Their carbonyl groups, being the least stabilized by resonance, have the highest energy and are the most reactive. So, an initial addition reaction with a nucleophile is relatively easy. The chloride atom of acid chlorides is an excellent leaving group, and sits poised, ready to depart once the tetrahedral intermediate has been formed... 

Many nucleophiles are effective in the addition—elimination reaction of acid chlorides, and a great many acyl compounds can he made using acid chlorides as starting materials. 

The diagram shows that the catalytic action depends on a serine and a histidine residue. The histidine residue functions as a proton donor and acceptor. The reaction proceeds first by eliminating the group NH—X and by binding the acyl radical (the carboxyl group of the peptide bond under attack) to the enzyme, more specifically, to the serine residue. (Very careful hydrolysis has permitted the isolation of such serine-O-acyl compounds.) The ester bond is then hydrob zed the enzyme thus is returned to its original reactive form, and the second product of the hj drolysis, the acid, is liberated. The reactions are reversible to an extent depending on the equilibrium positions. 

The acylpalladium complex formed from acyl halides undergoes intramolecular alkene insertion. 2,5-Hexadienoyl chloride (894) is converted into phenol in its attempted Rosenmund reduction[759]. The reaction is explained by the oxidative addition, intramolecular alkene insertion to generate 895, and / -elimination. Chloroformate will be a useful compound for the preparation of a, /3-unsaturated esters if its oxidative addition and alkene insertion are possible. An intramolecular version is known, namely homoallylic chloroformates are converted into a-methylene-7-butyrolactones in moderate yields[760]. As another example, the homoallylic chloroformamide 896 is converted into the q-methylene- -butyrolactams 897 and 898[761]. An intermolecular version of alkene insertion into acyl chlorides is known only with bridgehead acid chlorides. Adamantanecarbonyl chloride (899) reacts with acrylonitrile to give the unsaturated ketone 900[762],... 

Potassium Amides. The strong, extremely soluble, stable, and nonnucleophilic potassium amide base (42), potassium hexamethyldisilazane [40949-94-8] (KHMDS), KN [Si(CH2]2, pX = 28, has been developed and commercialized. KHMDS, ideal for regio/stereospecific deprotonation and enolization reactions for less acidic compounds, is available in both THF and toluene solutions. It has demonstrated benefits for reactions involving kinetic enolates (43), alkylation and acylation (44), Wittig reaction (45), epoxidation (46), Ireland-Claison rearrangement (47,48), isomerization (49,50), Darzen reaction (51), Dieckmann condensation (52), cyclization (53), chain and ring expansion (54,55), and elimination (56). 

An interesting class ot covalent Inflates are vin l and ar>/ or heteroaryl Inflates Vinyl inflates are used for the direct solvolytic generation of vinyl cations and for the generation of unsaturated carbenes via the a-elimination process [66] A triflate ester of 2-hydroxypyridine can be used as a catalyst for the acylation of aromatic compounds with carboxylic acids [109] (equation 55)... 

The structure of 82 was established by alkaline ring cleavage to benzilic acid amide and by hydrogenolysis to (C6H5)2CH—CONH— COCfiHs. These reactions also served to eliminate 83 as the structure of the 169° compound. The other possible isomeric structure, (C6H5)2C(CN)0C0C6H5, which could have formed after 0-acylation, was ruled out by its independent synthesis from bromodiphenyl-acetonitrile and silver benzoate. 

Elimination of the hydroxyaminomethyl moiety from nitro oxime 15 by treatment with a diazonium salt gave hydrazone 43 (75LA1029) (Scheme 15). The same product was obtained by coupling the diazonium salt with the compound 16. On heating in aniline, oxime 15 was transformed into Schiff base 42. Acylation of the oxime 15 with benzoyl chloride in pyridine led to a mixture of furazan 44 and dinitrile 45. 

Only in 1961 did Woodward and Olofson succeed in elucidating the true mechanism of this interesting reaction by making an extensive use of spectroscopic methods. The difficulty was that the reaction proceeds in many stages. The isomeric compounds formed thereby are extremely labile, readily interconvertible, and can be identified only spectroscopically. The authors found that the attack by the anion eliminates the proton at C-3 (147) subsequent cleavage of the N—0 bond yields a -oxoketene imine (148) whose formation was established for the first time. The oxoketene imine spontaneously adds acetic acid and is converted via two intermediates (149, 150) to an enol acetate (151) whose structure was determined by UV spectra. Finally the enol acetate readily yields the W-acyl derivative (152). 

As a general rule, nucleophilic addition reactions are characteristic only of aldehydes and ketones, not of carboxylic acid derivatives. The reason for the difference is structural. As discussed previously in A Preview of Carbonyl Compounds and shown in Figure 19.14, the tetrahedral intermediate produced by addition of a nucleophile to a carboxylic acid derivative can eliminate a leaving group, leading to a net nucleophilic acyl substitution reaction. The tetrahedral intermediate... 

Hydroxy-substituted iron-acyl complexes 1, which are derived from aldol reactions of iron-acyl enolates with carbonyl compounds, are readily converted to the corresponding /i-methoxy or /1-acetoxy complexes 2 on deprotonation and reaction of the resulting alkoxide with iodomethane or acetic anhydride (Tabic 1). Further exposure of these materials to base promotes elimination of methoxide or acetate to provide the a,/ -unsaturated complexes (E)-3 and (Z)-3 (Table 2). 

Oxazoles (191) are producedwhen triphenylphosphine is treated simultaneously with an a-azidocarbonyl compound and an acyl halide. The intermediate iminophosphoranes (189) react with the acyl halide before they can react with themselves to give pyrazines. Elimination of phosphine oxide from the resulting salts may give the intermediate halo-genoimines (190), or the oxazoles may be formed via the betaines (192). 

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