Claisen condensation, also

Like the mixed aldol reaction between different partners shown in Figure 17.16, mixed Claisen condensations also occur frequently in living organisms, particularly in the pathway for fatty-acid biosynthesis that we ll discuss in Section 23.6. Butyryl synthase, for instance, reacts with malonyl ACP in a mixed Claisen condensation to give 3-ketohexanoyl ACP. 

This preparation was discovered independently by Geuther (1863) and by Frankland and Duppa (1865). The reaction was subsequently investigated in detail and so w idely extended by Claisen that it has become solely a specific example of the more general process known as the Claisen Condensation. Claisen showed that an ester under the influence of sodium ethoxide would not only condense with itself (as in the preparation of ethyl acetoacetate), but also with (i) another ester, (ii) a ketone, if of formula RCHgCOR, (iii) a nitrile, if of formula RCH CN, in each case with the elimination of alcohol. Examples of these modifications are ... 

The a-ionization of 7-methylpteridines can also be utilized in aldol-type condensation reactions. 7-Methyl-pterin and -lumazine and 2,4-diaminopteridine condense readily in aqueous base with aromatic aldehydes to afford 7-alkylidenepteridines (77JOC2951). A Claisen condensation requires the protection of the acidic hydrogens of the amide bonds. 

On treatment with alkoxide bases, esters undergo self-condensation to give a p-keto ester and an alcohol. Ethyl acetate, for exanple, undergoes a Claisen condensation on treatment with sodium ethoxide to give a p-keto ester known by its common nane ethyl ace-toacetate (also called acetoacetic ester) ... 

The final step in the /3-oxidation cycle is the cleavage of the /3-ketoacyI-CoA. This reaction, catalyzed by thiolase (also known as j8-ketothiolase), involves the attack of a cysteine thiolate from the enzyme on the /3-carbonyI carbon, followed by cleavage to give the etiolate of acetyl-CoA and an enzyme-thioester intermediate (Figure 24.17). Subsequent attack by the thiol group of a second CoA and departure of the cysteine thiolate yields a new (shorter) acyl-CoA. If the reaction in Figure 24.17 is read in reverse, it is easy to see that it is a Claisen condensation—an attack of the etiolate anion of acetyl-CoA on a thioester. Despite the formation of a second thioester, this reaction has a very favorable A).q, and it drives the three previous reactions of /3-oxidation. 

The carbanions derived from acylthiophenes have been condensed with aldehydes,and, through the Claisen condensation with esters, thienylsubstituted -diketones have been obtained. 2-Thenoyl trifluoroacetone, first prepared by Reid and Calvin through the Claisen condensation of 2-acetylthiophene with ethyl trifluoracetate, has become an extremely useful chelating agent for the extraction of numerous elements from strongly acidic solutions, The tautomeric form which dominates in aqueous solution is the ketone hy-drate. Other thiophenes have also proved useful for analytical purposes. ... 

Acetylisothiazoles have been prepared by ketonic hydrolysis of the jS-ketoesters derived from the Claisen condensation on 5-ethoxycar-bonylisothiazoles. 5-Acetyl-3-methylisothiazole is also obtained from the reaction of 5-cyano-3-methylisothiazole with methylmagnesium iodide. ... 

Esters, like aldehydes and ketones, are weakly acidic. When an ester with an a- hydrogen is treated with 1 equivalent of a base such as sodium ethoxide, a reversible carbonyl condensation reaction occurs to yield a /3-keto ester. For example, ethyl acetate yields ethyl acetoacetate on base treatment. This reaction between two ester molecules is known as the Claisen condensation reaction. (We ll use ethyl esters, abbreviated "Et," for consistency, but other esters will also work.)... 

Mixed Claisen-like reactions can also be carried out between an ester and a ketone, resulting in the synthesis of a jS-diketone. The reaction works best when the ester component has no a hydrogens and thus can t act as the nucleophilic donor. For example, ethyl formate gives high yields in mixed Claisen condensations with ketones. 

The Claisen condensation of t-butyl acetate with a methyl ester is a general route for the preparation of complex P-ketoesters.4 The reaction requires an excess of the enolate of t-butyl acetate to rapidly deprotonate the product and prevent tertiary alcohol formation. Some workers have also used excess LDA or t-butoxide for this purpose. 

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. 

It Is of Interest to note that the preparation of dimethyldihydroresorcinol (also named dimed one and methone Section VII, 15) involves an initial IVIichael addition to mesityl oxide, followed by an internal Claisen condensation. 

TiIV compounds also work well at promoting cross-aldol reactions between two different aldehydes and/or ketones without prior activation or protection (Scheme 19).74 Claisen condensation and Knoevenagel condensation are promoted by TiX4, an amine, and trimethylsilyl triflate.75-77... 

The esters LXXVIII and LXXIX also fail to undergo the Claisen condensation with sodium ethoxide as the catalyst, but do give the reaction if mesitylmagnesium bromide is used.480... 

Dartanol, 24 536 Dart impact strength, 20 429 Darzens-Claisen condensation, 14 570 Darzens condensation, 10 505 DAS antibody, 14 145, 147 DAS-hemisuccinate (DAS-HMS), 14 144 DASH-Sodium Study, 22 813 Data, growth of, 21 612-613. See also Decay data... 

Claisen condensation org chem 1. Condensation, in the presence of sodium ethox-ide, of esters or of esters and ketones to form p-dicarbonyl compounds. 2. Condensation of arylaldehydes and acylphenones with esters or ketones In the presence of sodium ethoxide to yield unsaturated esters. Also known as Claisen reaction. klas-3n kand-on sa-shon ... 

Very strong bases can be used in other reactions that are similar to the Claisen condensation. In these reactions, carbanions are formed instead of enolates. Figures 15-7, 15-8, and 15-9 show examples of various reactions employing three different strong bases sodium ethoxide, sodium amide, and sodium triphenylmethanide. Sodium hydride, NaH, is a strong base that would also work. Any of these very strong bases could be used in each of the specific reactions. 

The method described is that of Hampton, Harris, and Hauser6 and is an improvement over the benzyne method, which gives poor yields.6,7 This /J-diketone has been prepared by Claisen condensation of ethyl phenylacetate with acetone,8 but the yield is poorer and the product has been shown by gas chromatography to be impure.6 The j8-diketone has also been prepared by the hydrolysis of 4-methoxy-5-phenyl-3-penten-2-one and by hydrolysis and decarboxylation of ethyl a-acetyl-/3-oxo-y-phenylbutyrate10 but these compounds are more difficult to obtain than the starting materials used in the present synthesis. 

Lithium amide is used in synthesis of histamine and analgesic drugs. The compound also is used in many organic synthetic reactions including alkylation of ketones and nitriles, Claisen condensation, and in synthesis of antioxidants and acetylenic compounds. 

Other methods of preparing flavone include the action of ethanolic alkali on 2 -acetoxy-a,/3-dibromochalcone 7 Claisen condensation of ethyl o-ethoxybenzoate and acetophenone, and cyclization of the resulting 1,3-diketone with hydriodic acid 8 and treatment of 3-bromoflavanone with potassium hydroxide in ethanol.9 Flavone has also been prepared from ethyl phenyl-propiolate by condensation with sodium phenoxide and subsequent cyclization with phosphorus pentachloride in benzene 10 by fusing o-hydroxyacetophenone with benzoic anhydride and sodium benzoate 11 by the dehydrogenation of 2 -hydroxychal-cone with selenium dioxide 12 and by the action of alkali on flavylium chloride.13... 

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. 

Methyl groups in the 2-, 4- or 6-position of pyrimidine are also more reactive. In addition to typical reactions such as condensation with benzaldehyde, selenium dioxide oxidation and halogenation, they can be converted into oximino groups by nitrous acid, and undergo Claisen condensation with (C02Et)2. In the reaction of 2,5-dimethylpyrimidine with benzaldehyde, only the electrophilic 2-methyl group reacts preferentially to yield the 2-styryl derivative (631). In quinazolines partial double bond fixation makes a methyl group in the 4-position more reactive than that in the 2-position. 

Polycarboxylic acid synthases. Several enzymes, including citrate synthase, the key enzyme which catalyzes the first step of the citric acid cycle, promote condensations of acetyl-CoA with ketones (Eq. 13-38). An a-oxo acid is most often the second substrate, and a thioester intermediate (Eq. 13-38) undergoes hydrolysis to release coenzyme A.199 Because the substrate acetyl-CoA is a thioester, the reaction is often described as a Claisen condensation. The same enzyme that catalyzes the condensation of acetyl-CoA with a ketone also catalyzes the second step, the hydrolysis of the CoA thioester. These polycarboxylic acid synthases are important in biosynthesis. They carry out the initial steps in a general chain elongation process (Fig. 17-18). While one function of the thioester group in acetyl-CoA is to activate the methyl hydrogens toward the aldol condensation, the subsequent hydrolysis of the thioester linkage provides for overall irreversibility and "drives" the synthetic reaction. 

Except for some vitamin B12-dependent reactions, the cleavage or formation of carbon-carbon bonds usually depends upon the participation of carbonyl groups. For this reason, carbonyl groups have a central mechanistic role in biosynthesis. The activation of hydrogen atoms (3 to carbonyl groups permits (3 condensations to occur during biosynthesis. Aldol or Claisen condensations require the participation of two carbonyl compounds. Carbonyl compounds are also essential to thiamin diphosphate-dependent condensations and the aldehyde pyridoxal phosphate is needed for most C-C bond cleavage or formation within amino acids. 

Both bacteria and plants have separate enzymes that catalyze the individual steps in the biosynthetic sequence (Fig. 17-12). The fatty acyl group grows while attached to the small acyl carrier protein (ACP).54 58 Control of the process is provided, in part, by the existence of isoenzyme forms. For example, in E. coli there are three different P-oxoacyl-ACP synthases. They carry out the transfer of any acyl primer from ACP to the enzyme, decarboxylate malonyl-ACP, and carry out the Claisen condensation (steps b, e, and/in Eq. 17-12)58a e One of the isoenzymes is specialized for the initial elongation of acetyl-ACP and also provides feedback regulation.58c The other two function specifically in synthesis of unsaturated fatty acids. 

The other variables may be altered to the same wide extent as in the route based on the Claisen condensation. The rearrangement also occurs under the influence of other basic catalysts, including sodium metal, sodium hydride and sodium hydroxide, and indeed it has been suggested that these strongly basic species are more effective than potassium carbonate. For instance, the diacetyl derivative of 2,4-dihydroxyacetophenone did not rearrange in the presence of potassium carbonate (33JCS1381) but did so on treatment with sodium in benzene <49PIA(A)(30)57). 

C-Acylations of C,H-acidic compounds have also been realized on insoluble supports. The few examples that have been reported include the C-acylation of support-bound ester enolates with acyl halides [9], Claisen condensations of polystyrene-bound ketones with benzoic acid esters, the C-acylation of nitriles with acyl nitriles or anhydrides, and the C-acylation of phosphonates with acyl halides (Entries 5-9, Table... 

---