Claisen condensations mechanism

Clearly, the nex.t step will be to investigate the physicochemical effects, such as charge distribution and inductive and resonance effects, at the reaction center to obtain a deeper insight into the mechanisms of these biochemical reactions and the finer details of similar reactions. Here, it should be emphasized that biochemical reactions arc ruled and driven basically by the same effects as organic reactions. Figure 10.3-22 compares the Claisen condensation of acetic esters to acctoacctic esters with the analogous biochemical reaction in the human body. 

FIGURE 21 1 The mechanism of the Claisen condensation of ethyl acetate... 

The mechanism of this reaction is generally understood to consist of subsequent Claisen condensation reactions to produce an intermediate diketone 12, which readily tautomerizes to the fully conjugated dihydroxythiophene 13. ... 

Two possible mechanisms exist for the Friedlander reaction. The first involves initial imine formation followed by intramolecular Claisen condensation, while the second reverses the order of the steps. Evidence for both mechanisms has been found, both... 

The mechanism is postulated to involve the initial formation of a Schiff base 17 from the condensation of the anilinic amine 16 with the carbonyl-containing substrate. This is followed by a Claisen condensation between the benzylic carbonyl and the activated a-methylene of the imine. ... 

Thomson MOW Click Organic Process to view an animation showing the mechanism of the Claisen condensation reaction. 

Tire mechanism of the Claisen condensation is similar to that of the aldol condensation and involves the nucleophilic addition of an ester enolate ion to the carbonyl group of a second ester molecule. The only difference between the aldol condensation of an aldeiwde or ketone and the Claisen condensation of an ester involves the fate of the initially formed tetrahedral intermediate. The tetrahedral intermediate in the aldol reaction is protonated to give an alcohol product—exactly the behavior previously seen for aldehydes and ketones (Section 19.4). The tetrahedral intermediate in the Claisen reaction, however, expels an alkoxide leaving group to yield an acyl substitution product—exactly the behavior previously seen for esters (Section 21.6). The mechanism of the Claisen condensation reaction is shown in Figure 23.5. 

Active Figure 23.5 MECHANISM Mechanism of the Claisen condensation reaction. Sign in at www. thomsonedu.com to see a simulation based on this figure and to take a short quiz. 

The mechanism of the Dieckmann cyclization, shown in Figure 23.6, is the same as that of the Claisen condensation. One of the two ester groups is converted into an enolate ion, which then carries out a nucleophilic acyl substitution on the second ester group at the other end of the molecule. A cyclic /3-keto ester product results. 

The following reaction involves a conjugate addition reaction followed by an intramolecular Claisen condensation. Write both steps, and show their mechanisms. 

Step 5 of Figure 29.5 Condensation The key carbon-carbon bond-forming reaction that builds the fatty-acid chain occurs in step 5. This step is simply a Claisen condensation between acetyl synthase as the electrophilic acceptor and malonyl ACP as the nucleophilic donor. The mechanism of the condensation is thought to involve decarboxylation of malonyl ACP to give an enolate ion, followed by immediate addition of the enolate ion to the carbonyl group of acetyl... 

An important group of acylation reactions involves esters, in which case the leaving group is alkoxy or aryloxy. The self-condensation of esters is known as the Claisen condensation.216 Ethyl acetoacetate, for example, is prepared by Claisen condensation of ethyl acetate. All of the steps in the mechanism are reversible, and a full equivalent of base is needed to bring the reaction to completion. Ethyl acetoacetate is more acidic than any of the other species present and is converted to its conjugate base in the final step. The (3-ketoester product is obtained after neutralization. 

In unsubstituted phenyl ethers, the enolisation is faster than the Cope reaction. This is why the product is predominantly ortho isomer. When both the ortho positions are substituted, the allyl group undergoes a second migration via a concerted sigmatropic mechanism giving a para substituted phenol. This is called para Claisen condensation. 

Workup gives back the (3-ketosulfoxide. This part of the mechanism is directly analogous to a Claisen condensation. 

As a starting point for an examination of the mechanisms of gas phase reactions, the Claisen condensation is a multistep reaction that appears to proceed by essentially the same mechanism in the gas phase as in solution, as illustrated in Figure 5. In the gas phase, in cases where this reaction occurs, all that is observed is a disappearance of the enolate reactant and the appearance of P-carbonyl enolate product. The intermediate ions in the mechanism react too rapidly to exist long enough for detection. In the ICR spectrometer, unless an ion exists for at least a millisecond or longer, there are not enough cyclotron cycles to create a detectable signal. Intermediates such as the ones postulated for this reaction, with 10-50... 

The general mechanism of the Claisen condensation, with ethoxide as the base, is shown in Figure 15-2. Sodium ethoxide is necessary because the starting material is an ethyl ester. If the starting material were a methyl ester, then the base would be sodium methoxide. Choosing a base that matches the type of ester minimizes the formation of other products. 

The Claisen condensation bears some resemblance to the Aldol condensation seen in Chapter 11. The initial step in the mechanisms are very similar in that in both cases a resonance-stabilized ion is formed. 

Write the complete mechanism for each of the reactions in Figures 15-7, 15-8, and 15-9, and compare these to the Claisen condensation in order to identify similarities and differences. 

Other Claisen condensations are involved in synthesis of fatty acids and polyketides217 (Chapter 21) and in formation of 3-hydroxy-3-methylglutaryl-CoA, the precursor to the polyprenyl family of compounds (Chapter 22). In these cases the acetyl group of acetyl-CoA is transferred by a simple displacement mechanism onto an -SH group at the active site of the synthase to form an acetyl-enzyme.218 219 The acetyl-enzyme is the actual reactant in step b of Eq. 17-5 where this reaction, as well as that of HMG-CoA lyase, is illustrated. 

A Claisen condensation is the acylation of an ester enolate by the corresponding ester. By deprotonating an ester with MOR, only a small concentration of the ester enolate is generated and this enolate is in equilibrium with the ester (cf. Table 13.1). The mechanism of the Claisen condensation is illustrated in detail in Figure 13.57 for the example of the condensation of ethyl butyrate. Both the deprotonation of the ester to give enolate A and the subsequent acylation of the latter are reversible. This acylation occurs via a tetrahedral intermediate (B in Figure 13.57) just like the acylations of other nucleophiles (Chapter 6). The equilibrium between two molecules of ethyl butyrate and one molecule each of the condensation product C and ethanol does not lie completely on the side of the products. In fact, Claisen condensations go to completion only... 

Fig. 13.57. Mechanism of a Claisen condensation. The deprotonation step Na 0Et + C -> D + EtOH is irreversible, and it is for this reason that eventually all the starting material will be converted into the enolate D.

Fig. 13.58. Mechanism of a Dieckmann condensation. The Dieckmann condensation is an intramolecular Claisen condensation.

Thus Sn2 alkylation occurs on the carbon atom, whereas a-chloroethers, well known to react by an SnI mechanism, undergo O-alkylation as predicted by the SHAB principle. Both reactions are kinetically controlled, and bond formation is not far advanced in the transition state. Acylating agents (which have a hard electrophilic carbon atom) however, give the C-acylated product in the Claisen condensation. 

Intramolecular Claisen condensations, called Dieckmann condensations, are ringclosing reactions that yield 2-cyclopentanone carboxylic esters (Figure 10.52) or 2-cyclohexanone carboxylic esters. The mechanism of the Dieckmann condensation is, of course, identical to the mechanism of the Claisen condensation (Figure 10.51). To ensure that the Dieckmann condensation goes to completion, the presence of a stoichiometric amount of base is required. As before, the neutral /3-ketoester (B in Figure... 

Key Mechanism 22-12 The Claisen Ester Condensation 1071 22-13 The Dieckmann Condensation A Claisen Cyclization 1074 22-14 Crossed Claisen Condensations 1074 22-15 Syntheses Using /3-Dicarbonyl Compounds 1077 22-16 The Malonic Ester Synthesis 1079 22-17 The Acetoacetic Ester Synthesis 1082 22-18 Conjugate Additions The Michael Reaction 1085 Mechanism 22-13 1,2-Addition and 1,4-Addition (Conjugate Addition) 1085... 

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