Carboxylic acid derivatives mechanism

The first stage of the mechanism is exactly the same as for nucleophilic addition to the carbonyl group of an aldehyde or ketone Many of the same nucleophiles that add to aldehydes and ketones—water (Section 17 6) alcohols (Section 17 8) amines (Sections 17 10-17 11)—add to the carbonyl groups of carboxylic acid derivatives... 

Mechanistically amide hydrolysis is similar to the hydrolysis of other carboxylic acid derivatives The mechanism of the hydrolysis m acid is presented m Figure 20 7 It proceeds m two stages a tetrahedral intermediate is formed m the first stage and disso ciates m the second... 

In the next chapter the three elements of the mechanism just described will be seen again as part of the general theme that unites the chemistry of carboxylic acid derivatives. These elements are... 

The hydrolysis of a carboxylic acid derivative is but one exanple of a nucleophilic acyl substitution. The mechanism of nucleophilic acyl substitution is one of the major... 

Most acid-catalyzed hydrolyses of carboxylic acid derivatives proceed by the A2 mechanism, as shown for ester hydrolysis ... 

The formulated mechanism is supported by the finding that no halogen from the phosphorus trihalide is transferred to the a-carbon of the carboxylic acid. For instance, the reaction of a carboxylic acid with phosphorus tribromide and chlorine yields exclusively an a-chlorinated carboxylic acid. In addition, carboxylic acid derivatives that enolize easily—e.g. acyl halides and anhydrides—do react without a catalyst present. 

Acid halides are among the most reactive of carboxylic acid derivatives and can be converted into many other kinds of compounds by nucleophilic acyl substitution mechanisms. The halogen can be replaced by -OH to yield an acid, by —OCOR to yield an anhydride, by -OR to yield an ester, or by -NH2 to yield an amide. In addition, the reduction of an acid halide yields a primary alcohol, and reaction with a Grignard reagent yields a tertiary alcohol. Although the reactions we ll be discussing in this section are illustrated only for acid chlorides, similar processes take place with other acid halides. 

Carboxylic acid derivatives can be converted into primary amines with loss of one carbon atom by both the Hofmann rearrangement and tire Curtius rearrangement. Although the Hofmann rearrangement involves a primary-amide and the Curtius rearrangement involves an acyl azide, both proceed through similar mechanisms. 

In 1983, Yamada et al. developed an efficient method for the racemization of amino acids using a catalytic amount of an aliphatic or an aromatic aldehyde [50]. This method has been used in the D KR of amino acids. Figure 4.25 shows the mechanism of the racemization of a carboxylic acid derivative catalyzed by pyridoxal. Racemization takes place through the formation of Schiff-base intermediates. 

The l-chloro-2,2-dibromocyclopropanes 164 similarly undergo the nickel-carbonyl-induced ring-opening carbonylation with an amine or an alcohol to give the / ,y-unsaturated carboxylic acid derivatives 165 and the dicarboxylic acid ones 166 [84]. The mechanism described above appears to be operating this is supported by the four-component condensation to 167. (Scheme 61 and 62)... 

Before discussmg the mechanism of cleavage of carboxylic acid esters and amides by hydrolases, some chemical principles are worth recalling. The chemical hydrolysis of carboxylic acid derivatives can be catalyzed by acid or base, and, in both cases, the mechanisms involve addition-elimination via a tetrahedral intermediate. A general scheme of ester and amide hydrolysis is presented in Fig. 3. / the chemical mechanisms of ester hydrolysis will be... 

Bender, M.L. (1960). Mechanisms of catiysis of nucleophilic reactions of carboxylic acid derivatives. Chemical Reviews, 60, 53-113. 

Formally related reactions are observed when anthracene [210] or arylole-fines [211-213] are reduced in the presence of carboxylic acid derivatives such as anhydrides, esters, amides, or nitriles. Under these conditions, mono- or diacylated compounds are obtained. It is interesting to note that the yield of acylated products largely depends on the counterion of the reduced hydrocarbon species. It is especially high when lithium is used, which is supposed to prevent hydrodimerization of the carboxylic acid by ion-pair formation. In contrast to alkylation, acylation is assumed to prefer an Sn2 mechanism. However, it is not clear if the radical anion or the dianion are the reactive species. The addition of nitriles is usually followed by hydrolysis of the resulting ketimines [211-213]. 

The most significant change in these reactions is the formation of the carbon-nncleophile bond so, in both types of mechanism, the reaction is termed a nucleophilic addition. It should be noted that the polarization in the carbonyl group leads to nucleophilic addition, whereas the lack of polarization in the C=C donble bond of an alkene leads to electrophilic addition reactions (see Chapter 8). Carbonyl groups in carboxylic acid derivatives undergo a similar type of reactivity to nucleophiles, but the... 

A second route (route B in Fig. 1) relies on an initiation process with an (meth)acryl hydroxyl compound and is adopted from the chemical ROP of lactones. The controlled character of these polymerizations ensures a virtually quantitative initiation and thus incorporation of hydroxy-functional initiator (e.g., acrylate) into the polymer chain. However, this is not automatically the case for lipase-catalyzed ROP due to the different mechanism. The latter follows an activated monomer mechanism in which the lipase activates any carbonyl group of a carboxylic acid derivative present in the system. It has recently been shown that acrylation using hydroxy-functional acrylate initiators like hydroxy ethyl(meth)acrylate (HEMA or... 

The reactivity of carboxyhc acid derivatives depends on the basicity of the substituent attached to the acyl group. Therefore, the less basic the substituent, the more reactive is the derivative. In other words, strong bases make poor leaving groups. Carboxylic acid derivatives undergo a variety of reactions under both acidic and basic conditions, and almost aU involve the nucleophilic acyl substitution mechanism (see Section 5.5.5). 

Carboxylic acid and its derivatives undergo nucleophilic acyl substitution, where one nucleophile replaces another on the acyl carbon. Nucleophilic acyl substitution can interconvert all carboxylic acid derivatives, and the reaction mechanism varies depending on acidic or basic conditions. Nucleophiles can either be negatively charged anion (Nu ) or neutral (Nu ) molecules. 

Note that the reaction at the phosphorus atom is postulated to occur by an SN2 (no intermediate formed) rather than by an addition mechanism such as we encountered with carboxylic acid derivatives (Kirby and Warren, 1967). As we learned in Section 13.2, for attack at a saturated carbon atom, OH- is a better nucleophile than H20 by about a factor of 104 (Table 13.2). Toward phosphorus, which is a harder electrophilic center (see Box 13.1), however, the relative nucleophilicity increases dramatically. For triphenyl phosphate, for example, OH- is about 108 times stronger than H20 as a nucleophile (Barnard et al., 1961). Note that in the case of triphenyl phosphate, no substitution may occur at the carbon bound to the oxygen of the alcohol moiety, and therefore, neutral hydrolysis is much less important as compared to the other cases (see /NB values in Table 13.12). Consequently, the base-catalyzed reaction generally occurs at the phosphorus atom leading to the dissociation of the alcohol moiety that is the best leaving group (P-0 cleavage), as is illustrated by the reaction of parathion with OH ... 

Unsaturated hydrocarbons (alkenes, dienes) react with carbon monoxide and a proton source (H20, alcohols, amines, acids) under strong acidic conditions to form carboxylic acids or carboxylic acid derivatives. Since a carbocationic mechanism is operative, not only alkenes but also other compounds that can serve as the carbocation source (alcohols, saturated hydrocarbons) can be carboxylated. Metal catalysts can also effect the carboxylation of alkenes, dienes, alkynes, and alcohols. 

This chapter deals with the kinetics and mechanisms of the hydrolysis of carboxylic acid derivatives of general formula RCOX. These include carboxylic acid halides, amides, and anhydrides with small sections on carboxylic acid cyanides etc. Many recent developments in this field have been made with acid derivatives in which R is not an aliphatic or aromatic group, for example, carbamic acid derivatives, and these are reported where relevant, as are reactions such as ethanolysis, aminolysis, etc. where they throw light on the mechanisms of hydrolysis. 

In summary, therefore, the detailed mechanism of the hydrolysis of carboxylic anhydrides is still in doubt and we must hope for further experimental evidence to clarify the position. As for the hydrolysis of the other carboxylic acid derivatives dealt with in this chapter, none of the mechanistic criteria, that have been used to interpret the kinetic data, gives an unambiguous interpretation, resulting in a situation where details of mechanism are open to argument. This is particularly the case for solvolysis reactions where uncertainty as to the structure and effect of the solvent preclude a firm assignment of transition state structures. This is not to say that the mechanisms are not... 

Nucleophilic substitutions reactions are those reactions in which the substitution of one nucleophile for another is involved. Alkyl halides, carboxylic acids, and carboxylic acid derivatives undergo nucleophilic substitution. However, the mechanisms involved for alkyl halides are quite different from those involved for carboxylic acids and their derivatives. The reaction of a methoxide ion with ethanoyl chloride is a nucleophilic substitution reaction (Following fig.). In it one nucleophile (the methoxide ion) substitutes another nucleophile Cl. ... 

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