Acyl with alcohols

Direct evidence for a mechanism involving a single mode of chain growth as depicted in Scheme 1 came from our studies on the copolymerization reaction in alcoholic solvents35). The mechanism, as outlined in Scheme 1, involves the formation of Pd-acyl species as intermediates at every other step in the propagation sequence. Since the formation of esters through the reaction of transition metal-acyls with alcohols is well-precedented, it should be possible to intercept the propagation sequence if the polymerization was carried out in the presence of alcohols, Eq. (13). 

The first step in the mechanism (Scheme 8) of PdCl2-catalysed oxidative sp C-H bond acylation with alcohols in CgHjCl was the chelation of the catalyst with (49) forming (50), which reacted with TBHP to form (51). Next, (51) reacted with aldehyde, produced in situ from the oxidation of alcohol, to provide the acyl intermediate (52) from which the product ketone (53) was obtained in good yield with high regios-electivity and regeneration of Pd(ll). ... 

Esterification with acyl chlorides (Section 15 8) Acyl chlorides react with alcohols to give esters The reaction is usually carried out in the presence of pyridine... 

Acid anhydrides react with alcohols to form esters The reaction may be carried out in the presence of pyridine or it may be catalyzed by acids In the example shown only one acyl group of acetic anhydride becomes incorporated into the ester the other becomes the ac yl group of an acetic acid molecule... 

Section 20 7 Esters occur naturally or are prepared from alcohols by Fischer estenfi cation or by acylation with acyl chlorides or acid anhydrides (see Table 20 3)... 

Acetals are readily formed with alcohols and cycHc acetals with 1,2 and 1,3-diols (19). Furfural reacts with poly(vinyl alcohol) under acid catalysis to effect acetalization of the hydroxyl groups (20,21). Reaction with acetic anhydride under appropriate conditions gives the acylal, furfuryUdene diacetate... 

In the presence of strong acid, such as boron trifluoride [7637-07-2] appropriately substituted acyl chlorides (7, R = CCl ) add to ketene to form the corresponding acetoacetyl chlorides, which can further react with alcohols to form the corresponding acetoacetates. 

In the piepaiation of ioveisol (12) (41), the key intermediate (23) is prepared from the diacid (20) by the action of thionyl chloride followed by 3-amino-l,2-propanediol. The alcohol groups of (23) are protected as the acetates (25), which is then N-acylated with acetoxyacetyl chloride and deprotected in aqueous methanol with sodium hydroxide to yield (26). N-alkylation of (26) produces ioversol (12). 

Resolution of racemic alcohols by acylation (Table 6) is as popular as that by hydrolysis. Because of the simplicity of reactions ia nonaqueous media, acylation routes are often preferred. As ia hydrolytic reactions, selectivity of esterification may depend on the stmcture of the acylatiag agent. Whereas Candida glindracea Upase-catalyzed acylation of racemic-cx-methylhenzyl alcohol [98-85-1] (59) with butyric acid has an enantiomeric value E of 20, acylation with dodecanoic acid increases the E value to 46 (16). Not only acids but also anhydrides are used as acylatiag agents. Pseudomonasfl. Upase (PFL), for example, catalyzed acylation of a-phenethanol [98-85-1] (59) with acetic anhydride ia 42% yield and 92% selectivity (74). 

In the esterification of organic acids with alcohols, it has been shown that in most cases under acid catalysis, the union is between acyl and alkoxy groups. Acid hydrolysis of acetoxysuccinic acid gives malic acid with retention of configuration at the asymmetric carbon atom (11) ... 

There are alternatives to the addition-elimination mechanism for nucleophilic substitution of acyl chlorides. Certain acyl chlorides are known to react with alcohols by a dissociative mechanism in which acylium ions are intermediates. This mechanism is observed with aroyl halides having electron-releasing substituents. Other acyl halides show reactivity indicative of mixed or borderline mechanisms. The existence of the SnI-like dissociative mechanism reflects the relative stability of acylium ions. 

Esterification with carboxylic acid anhydrides (Section 15.8) Carboxylic acid anhydrides react with alcohols to form esters in the same way that acyl chlorides do. 

AC2O or AcCl, Pyr, DMAP, 24-80°, 1-40 h, 72-95% yield. The use of DMAP increases the rate of acylation by a factor of lO. These conditions acylate most alcohols, including tertiary alcohols. The use of DMAP (4-A,A-dimethylaminopyridine) as a catalyst to improve the rate of esterification is quite general and works for other esters as well, but it is not effective with hindered anhydrides such as pivaloic anhydride. The phosphine i (48-99% yield) and Bu3P have been developed as active acylation catalysts for acetates and benzoates. 

Ac-Imidazole, PtCl2(C2H4), 23°, 0.5-144 h, 51-87% yield. Platinum(II) acts as a template to catalyze the acetylation of the pyridinyl alcohol, C5H4N(CH2) CH20H. Normally, acylimidazoles are not very reactive acylating agents with alcohols. 

Sc(OTf)3, AcOH, p-nitrobenzoic anhydride or Sc(OTf)3, AC2O, 66- >95% yield. The lower yields are obtained with allylic alcohols propargylic alcohols give higher yields. Phenols are effectively acylated with this catalyst, but at a much slower rate than simple aliphatic alco-hols. The method was shown to be superior to most other methods for macrolactonization with minimum diolide formation. 

Reaction of the acyl chloride 1 with alcohol 4 thus formed leads to formation of an ester 6 ... 

An ester of alanine with an arylaliphatic alcohol has shown promise as a non-tricyclic antidepressant. It may be speculated that the hindered milieu of the ester linkage protects the compound from hydrolysis by endogenous esterases. The preparation starts by reaction of pheny-lacctate 83 with methyl magnesium iodide to give tertiary carbinol 84. Acylation with 2-bromo-]>ropionyl bromide leads to ester 85 displacement of halogen with ammonia leads to alaproclate ( 6) [211. 

In an attempt to study the behavior and chemistry of coal in ionic liquids, 1,2-diphenylethane was chosen as a model compound and its reaction in acidic pyri-dinium chloroaluminate(III) melts ([PyHjCl/AlCb was investigated [69]. At 40 °C, 1,2-diphenylethane undergoes a series of alkylation and dealkylation reactions to give a mixture of products. Some of the products are shown in Scheme 5.1-40. Newman also investigated the reactions of 1,2-diphenylethane with acylating agents such as acetyl chloride or acetic anhydride in the pyridinium ionic liquid [70] and with alcohols such as isopropanol [71]. 

NMR spectroscopy of. 823-824 nucleophilic acyl substitution reactions of, 806-807 reaction with alcohols, 807 reaction with amines, 807... 

A novel approach was developed very recently by Kita et al. [15]. DKR of allylic alcohols was performed by combining a lipase-catalyzed acylation with a racemization through the formation of allyl vanadate intermediates. Excellent yields and enantioselectivities were obtained. An example is shown in Figure 4.4. A limitation with this approach for the substrates shown in Figure 4.4 is that the allylic alcohol must be equally disubstituted in the allylic position (R = R ) since C—C single bond rotation is required in the tertiary alkoxy intermediate. Alternatively, R or R can be H if the two allylic alcohols formed by migration of the hydroxyl group are enantiomers (e.g. cyclic allylic acetates). 

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