Acyl bromides reaction with

The intermediate o-bromo acid bromide undergoes a nucleophilic acyl substitution reaction with methanol to give an a-bromo ester. 

The Br of the acyl bromide exchanges with the OH of another molecule of the carboxylic acid to produce the o-brominated acid and an acyl bromide. This exchange reaction proceeds through an anhydride intermediate. 

Acylsulfenyl halides are formed by the reaction of N-bromosuccinimide or tert-butyl hypochlorite with thiocarboxylic acid O-trimethylsilyl esters164 (equation 172). Treatment of silyl carboxylates with triphenylphosphine dibromide gives the corresponding acyl bromide along with the silyl bromide165 (equation 173). It is also possible to convert silyl ethers to the alkyl bromide with this reagent165 or with a mixture of carbon tetrabromide and triphenylphosphine166. The mild nature and selectivity of the reaction is underscored by the conversion of the trimethylsiloxy /Mactam 83 to the bromide 84165 (equation 174). 

Now let s draw the forward scheme. Benzene is converted into bromobenzene upon treatment with Br2 and AlBrs (via an electrophilic aromatic substitution reaction). Bromobenzene is then converted to phenyl magnesium bromide (a Grignard reagent), which is then treated with formalddryde, followed by water work-up, to give benzyl alcohol. This alcohol then serves as a nucleophile in a subsequent acyl substitution reaction with acetyl chloride and pyridine to produce benzyl acetate (a process called acetylation). 

In the following the reaction is outlined for an a-bromination. The reaction mechanism involves formation of the corresponding acyl bromide 3 by reaction of carboxylic acid 1 with phosphorus tribromide PBr3. The acyl bromide 3 is in equilibrium with the enol derivative 4, which further reacts with bromine to give the a -bromoacyl bromide 5 ... 

The ring-contracted analog of alphaprodine is prepared by a variation of the scheme above. Alkylation of 109 with ethyl bromoacetate affords the lower homolog diester (115). Dieckmann cyclization followed by saponification-decarboxylation yields the pyrrolidine (116). Reaction with phenylmagnesium bromide leads to the condensation product (117) acylation with propionic anhydride gives the analgesic agent prolidine (118)... 

The Hell-Volhard-Zelinskii reaction is a bit more complex than it looks and actually involves substitution of an acid bromide enol rather than a carboxylic acid enol. The process begins with reaction of the carboxylic acid with PBr3 to form an acid bromide plus HBr (Section 21.4). The HBr then catalyzes enolization of the acid bromide, and the resultant enol reacts with Br2 in an cr-substitution reaction to give an cv-bromo acid bromide. Addition of water hydrolyzes the acid bromide in a nucleophilic acyl substitution reaction and yields the a-bromo carboxylic acid product. 

Aldehydes can be directly converted to acyl chlorides by treatment with chlorine however, the reaction operates only when the aldehyde does not contain an a hydrogen and even then it is not very useful. When there is an a hydrogen, a halogenation (12-4) occurs instead. Other sources of chlorine have also been used, among them S02Cl2 and r-BuOCl. The mechanisms are probably of the free-radical type. V-Bromosuccinimide, with AIBN (p. 912) as a catalyst, has been used to convert aldehydes to acyl bromides. 

Carboxylic acids can be converted to acyl chlorides and bromides by a combination of triphenylphosphine and a halogen source. Triphenylphosphine and carbon tetrachloride convert acids to the corresponding acyl chloride.100 Similarly, carboxylic acids react with the triphenyl phosphine-bromine adduct to give acyl bromides.101 Triphenviphosphine-iV-hromosuccinimide also generates acyl bromide in situ.102 All these reactions involve acyloxyphosphonium ions and are mechanistically analogous to the alcohol-to-halide conversions that are discussed in Section 3.1.2. 

In this series, too, replacement of the N-methyl by a group such as cyclopropylmethyl leads to a compound with reduced abuse potential by virtue of mixed agonist-antagonist action. To accomplish this, reduction of 24 followed by reaction with tertiary butylmagnesium chloride gives the tertiary carbinol 27. The N-methyl group is then removed by the classic von Braun procedure. Thus, reaction with cyanogen bromide leads to the N-cyano derivative (28) hydrolysis affords the secondary amine 29. (One of the more efficient demethylation procedures, such as reaction with ethyl chloroformate would presumably be used today.) Acylation with cyclopropylcarbonyl chloride then leads to the amide 30. Reduction with lithium aluminum hydride (31) followed by demethylation of the phenolic ether affords buprenorphine (32).9... 

The stereoselective addition of the titanium enolate of A-acetyl-4-phenyl-l,3-thiazolidine-2-thione 153 to the cyclic A-acyl iminium ion 154 is utilized in the synthesis of (-)-stemoamide, a tricyclic alkaloid <06JOC3287>. The iminium ion addition product 155 undergoes magnesium bromide-catalyzed awtz-aldol reaction with cinnamaldehyde 156 to give adduct 157, which possesses the required stereochemistry of all chiral centers for the synthesis of (-)-stemoamide. 

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