Carboxylic Claisen condensation

The acetoacetic ester condensation (involving the acylation of an ester by an ester) is a special case of a more general reaction term the Claisen condensation. The latter is the condensation between a carboxylic ester and an ester (or ketone or nitrile) containing an a-hydrogen atom in the presence of a base (sodium, sodium alkoxide, sodamide, sodium triphenylmethide, etc.). If R—H is the compound containing the a- or active hydrogen atom, the Claisen condensation may be written ... 

Claisen condensation, 6, 156 reactions, S, 92 IsothiazoIe-3-carboxyIic acids decarboxylation, 6, 156 Isothiazole-4-carboxylic acids decarboxylation, 6, 156 Isothiazole-5-carboxylic acids decarboxylation, S, 92 6, 156 IR spectroscopy, 6, 142 Isothiazole-3-diazonium borofluoride decomposition, 6, 158 IsothiazoIe-4-diazonium chloride, 3-methyl-reactions with thiourea, 6, 158 Isothiazole-5-diazonium chloride, 4-bromo-3-methyl-halogen exchange, 6, 163 Isothiazole-5-diazonium chloride, 3-methyl-reactions... 

Pyridine, 4-methoxy-3-styryl-photoelectron spectroscopy, 2, 137 Pyridine, 2-methyI-alkylation, 2, 176 amination, 2, 233, 236 carboxylation, 2, 53 chlorination, 2, 201, 331 Claisen condensation, 2, 51 methiodide... 

Xanthopterin, 7,7-dimethyl-7,8-dihydro-synthesis, 3, 315 Xanthopterin, 7-methyl-synthesis, 3, 303 Xanthopterin, 7-phenacyl-structure, 3, 276 Xanthopterin, 3,5,7-trimethyl-Claisen condensation, 3, 303 Xanthopterin-7-carboxylic acid reactions... 

The reactivity of the methylene group adjacent to the lactam group affords the possibility of a Claisen condensation. Thus, treatment of 2-pyrrolidone or 2-piperidone with ethyl oxalate leads to the J -pyrroline-carboxylic (70) and, d -piperideine-2-carboxylic acids (71), respectively. N-methyl lactams furnish N-methyl derivatives (72,73) (Scheme 3). 

Carboxylic esters can be treated with ketones to give p-diketones in a reaction that is essentially the same as 10-118. The reaction is so similar that it is sometimes also called the Claisen condensation, though this usage is unfortunate. A fairly strong base, such as sodium amide or sodium hydride, is required. Yields can be increased by the catalytic addition of crown ethers. Esters of formic acid (R H) give P-keto aldehydes. Ethyl carbonate gives P-keto esters. 

The Claisen reaction can now proceed smoothly, but nature introduces another little twist. The carboxyl group introduced into malonyl-CoA is simultaneously lost by a decarboxylation reaction during the Claisen condensation. Accordingly, we now see that the carboxylation step helps to activate the a-carbon and facilitate Claisen condensation, and the carboxyl is immediately removed on completion of this task. An alternative rationalization is that decarboxylation of the malonyl ester is used to generate the acetyl enolate anion without any requirement for a strong base (see Box 10.17). 

In the presence of a strong base, the a carbon of a carboxylic ester can condense with the carbonyl carbon of an aldehyde or ketone to give a J3-hydroxy ester,556 which may or may not be dehydrated to the a,J3-unsaturated ester. This reaction is sometimes called the Claisen condensation,557 an unfortunate usage since that name is more firmly connected to 0-108. It is also possible for the a carbon of an aldehyde or ketone to add to the carbonyl carbon of a carboxylic ester, but this is a different reaction (0-109) involving nucleophilic substitution and not addition to a 0=0 bond. It can, however, be a side reaction if the aldehyde or ketone has an a hydrogen. 

A vigorous Claisen condensation ensues when a homophthalic ester and methyl formate are treated with sodium ethoxide and the active methylene group is formylated. Cyclization takes place with ease in acidic media to produce a methyl isocoumarin-4-carboxylate (50JCS3375). Hydrolysis under acid conditions is sometimes accompanied by polymerization, but the use of boron trifluoride in acetic acid overcomes this problem. Decarboxylation may be effected in the conventional manner with copper bronze, though it sometimes accompanies the hydrolysis. 

A subsequent hydrolytic cleavage of the C2-C3 bond of the carboxylation product (this amounts to a reverse Claisen condensation Section 18-8B) yields two molecules of D-3-phosphoglycerate.9... 

Carboxylation of CHsCOS—ACP yields a propanedioyl thioester, 6, which then undergoes a Claisen condensation with a second mole of CH3COS—ACP accompanied by decarboxylation to yield a 3-oxobutanoyl thioester, 7 ... 

Claisen condensation of ethyl quinuclidine-2-carboxylate (73) with ethyl acetate yields ethyl j8-oxo-j8-(2-quinuclidyl)propionate (84). This was transformed into j8-amino-j3-(2-quinuclidyl)propionic acid (85)108 and 2-acetylquinuclidine (86).43... 

The Claisen condensation reaction occurs by a nucleophilic addition to an ester carboxyl group, which follows these steps ... 

Like the related fatty acid synthases (FASs), polyketide synthases (PKSs) are multifunctional enzymes that catalyze the decarboxylative (Claisen) condensation of simple carboxylic acids, activated as their coenzyme A (CoA) thioesters. While FASs typically use acetyl-CoA as the starter unit and malonyl-CoA as the extender unit, PKSs often employ acetyl- or propionyl-CoA to initiate biosynthesis, and malonyl-, methylmalonyl-, and occasionally ethylmalonyl-CoA or pro-pylmalonyl-CoA as a source of chain-extension units. After each condensation, FASs catalyze the full reduction of the P-ketothioester to a methylene by way of ketoreduction, dehydration, and enoyl reduction (Fig. 3). In contrast, PKSs shortcut the FAS pathway in one of two ways (Fig. 4). The aromatic PKSs (Fig. 4a) leave the P-keto groups substantially intact to produce aromatic products, while the modular PKSs (Fig. 4b) catalyze a variable extent of reduction to yield the so-called complex polyketides. In the latter case, reduction may not occur, or there may be formation of a P-hydroxy, double-bond, or fully saturated methylene additionally, the outcome may vary between different cycles of chain extension (Fig. 4b). This inherent variability in keto reduction, the greater variety of... 

Diketones are synthesized by Claisen condensation of appropriate acetyl methyl ketone and ethyl perfluoroalkyl carboxylate. For example, 4,4/-bis(l",l,/,l//,2//,2",3//,3//-heptafluoro-4//,6//-hexanedion-6"-yl)-chlorosulfo-o-terphenyl (BHHCT) was synthesized from o-terphenyl by three step reactions (scheme 3 (Yuan et al., 1998a, 1998b)). The o-ter-phenyl are acetylated by acetyl chloride with anhydrous aluminum chloride as a Lewis acid and 4,4 -diacetyl-e>-terphcnyl is obtained. Then, the 4,4/-diacetyl-o-terphenyl is reacted with perfluoropropionic acid ethyl ester with sodium methoxide as a base. Finally, 4,4,-bis(l", 1",l//,2,2,3,/,3"-heptafluoro-4//,6"-hexanedion-6//-yl)-o-terphenyl is chloro-sulfonylatcd by chlorosulfonic acid to form BHHCT. 

The reactivity of the a-methylene group in lactams allows Claisen condensation with esters of formic, oxalic, and arylcarboxylic acids. Treatment of ethyl formate with A-methylpiperidone, followed by acidification, yields a salt of 1 -methyl- J2-piperideine, whereas in an alkaline medium its dimer was isolated.34- 158 With oxalic acid ester as the condensing reagent, 1-methyl-J2-pyrroline-2-carboxylic acid159 and l-methyl-d2-piperideine-2-carboxylic acid160 were obtained (Scheme 4). 

B as an ester- or lactone-substituted aldehyde enolate. Such enolates undergo condensations with all kinds of aldehydes, including paraformaldehyde. An adduct E is formed initially, acy-lating itself as soon as it is heated. The reaction could proceed intramolecularly via the tetrahedral intermediate D or intermolecularly as a retro-Claisen condensation. In both cases, the result is an acyloxy-substituted ester enolate. In the example given in Figure 13.50, this is the formyloxy-substituted lactone enolate C. As in the second step of an Elcb elimination, C eliminates the sodium salt of a carboxylic acid. The a,/)-unsaturated ester (in Figure 13.50 the 0J,/3-unsaturated lactone) remains as the aldol condensation product derived from the initial ester (here, a lactone) and the added aldehyde (here, paraformaldehyde). 

Accordingly, crossed Claisen condensations occur without any problems if the acylating agent is a better electrophile than the other, nondeprotonated ester. This is the case, for example, if the acylating agent is an oxalic ester (with an electronically activated carboxyl carbon) or a formic ester (the least sterically hindered carboxyl carbon). 

Assisted by Lewis acid the acyl imidazole 266 can be cleaved to provide the expected carboxylic acid 267. With fluoride in the presence of a Michael acceptor the intermediate enolate can be trapped. A subsequent intramolecular 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... 

Many observations, however, have provided strong evidence that site-site interactions are quite facile. Carboxylic acids bound to polystyrenes of varying degrees of cross-links have been observed to undergo anhydride formation even at low levels of functionalization 140,14I). The observation that cross-Claisen condensation products result from polymers on which two esters are attached also supports the view that intersite reactions can occur in polymer matrices142). Barany and Merrifield U) analysed a number of situations under which intersite reactions occured and found that they usually occur when... 

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