Condensation reactions intramolecular, Claisen

Dieckmann cyclization reaction (Section 23.9) An intramolecular Claisen condensation reaction to give a cyclic /3-keto ester. 

As we have seen in the section on thiolases, Claisen condensations normally involve activation of the electrophilic carhonyl through formation of a thioester and stabilization of the attacking carbanion also as a thioester. Dihydroxynaphthoyl-CoA synthase (MenB) catalyzes an intramolecular Claisen condensation reaction in which only the nucleophilic portion of the molecule has been converted to a thioester. This reaction is a component of the menaquinone biosynthetic pathway, and most studies have focused on the enzyme from M. tuberculosis based on the premise that this pathway may be a valid target for the development of novel compounds that inhibit both replicating and nonreplicating bacteria. ... 

There are several variations of the Claisen condensation. The intramolecular variation is called the Dieckmann condensation. A crossed Claisen condensation is possible between two different esters, but this reaction can lead to multiple products. Claisen condensations can operate in the forward direction or in the reverse direction, and these two processes lead to the construction and deconstruction of fatty acids. 

The Claisen condensation reaction is a carbonyl condensation that occurs between two ester components and gives a /3-keto ester product. Mixed Claisen condensations between two different esters are successful only when one of the two partners has no acidic a hydrogens (ethyl benzoate and ethyl formate, for instance) and thus can function only as the acceptor partner. Intramolecular Claisen condensations, called Dieckmann cyclization reactions, yield five-and six-membered cyclic j8-keto esters starting from 1,6- and 1,7-diesters. 

Dieckmann reaction (Section 21 2) An intramolecular version of the Claisen condensation... 

The intramolecular Claisen condensation of diesters, or Dieckman reaction, occurs readily to give five- or six-membered rings, and it has been extensively used for cyclopentanone and cyclohexanone derivatives. 

Dieckmann cyclization (Section 21.2) An intramolecular analog of the Claisen condensation. Cyclic p-keto esters in which the ring is five- to seven-membered may be formed by using this reaction. 

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... 

Carboxylic esters 1 that have an a-hydrogen can undergo a condensation reaction upon treatment with a strong base to yield a /3-keto ester 2. This reaction is called the Claisen ester condensation or acetoacetic ester condensation, the corresponding intramolecular reaction is called the Dieckmann condensation ... 

Intramolecular Claisen condensations can be carried out with diesters, just as intramolecular aldol condensations can be carried out with diketones (Section 23.6). Called the Dieckmann cyclization, the reaction works best on 1.6-diesters and 1,7-diesters. Intramolecular Claisen cyclization of a 1,6-diester gives a five-membered cyclic /3-keto ester, and cyclization of a 1,7-diester gives a six-membered cyclic /3-keto ester. 

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

In the course of the first total synthesis of (+)-halichlorine <1999TL6513, 1999AGE3542>, the spiroquinolizidine unit 460 was constructed by a two-carbon chain extension in compound 458 through a crossed Claisen condensation, leading to 459, and an intramolecular Mannich reaction of this compound with formaldehyde (Scheme 109). 

Nucleophilic addition to C=0 (contd.) ammonia derivs., 219 base catalysis, 204, 207, 212, 216, 226 benzoin condensation, 231 bisulphite anion, 207, 213 Cannizzaro reaction, 216 carbanions, 221-234 Claisen ester condensation, 229 Claisen-Schmidt reaction, 226 conjugate, 200, 213 cyanide ion, 212 Dieckmann reaction, 230 electronic effects in, 205, 208, 226 electrons, 217 Grignard reagents, 221, 235 halide ion, 214 hydration, 207 hydride ion, 214 hydrogen bonding in, 204, 209 in carboxylic derivs., 236-244 intermediates in, 50, 219 intramolecular, 217, 232 irreversible, 215, 222 Knoevenagel reaction, 228 Lewis acids in, 204, 222 Meerwein-Ponndorf reaction, 215 MejSiCN, 213 nitroalkanes, 226 Perkin reaction, 227 pH and, 204, 208, 219 protection, 211... 

Benzene and thiophene rings can of course often be interchanged in biologically active agents. The very broad structural latitude consistent with NSAID activity is by now a familiar theme as well. Preparation of the fused thiophene counterpart of the NSAID piroxicam (Chapter 11) starts with the reaction of thiophene (25-1), itself the product of a multistep sequence, with ethyl A-methylglycinate to give the sulfonamide (25-2). Treatment of that intermediate with a base leads to intramolecular Claisen condensation and thus the formation of the 3-ketoester (25-3). An amide-ester interchange with 2-aminopyridme (25-4) completes the synthesis of tenoxicam (25-5) [25]. 

In the case of a ketone with two active methylene groups, such as dibenzylketone, the reaction can take two courses. The pyranone results from Michael addition to the alkyne followed by normal ring closure. The second product, a resorcinol, arises from either Michael condensation followed by an intramolecular Claisen condensation or the order of these two reactions may be reversed (60JCS5153). 

The intramolecular carbon-carbon bond-forming reactions considered in this section are based on the aldol condensation (see Section 5.18.2, p. 799), the Claisen-Schmidt reaction (see Section 6.12.2, p. 1032), the Claisen ester condensation (see Section 5.14.3, p. 736), and the Claisen reaction (see Section 6.12.2, p. 1032). Since these carbonyl addition reactions are reversible, the methods of synthesis are most successful for the formation of the thermodynamically stable five- and six-membered ring systems. The preparation of the starting materials for some of these cyclisation reactions further illustrates the utility of the Michael reaction (see Section, 5.11.6, p. 681). 

The base-induced transfer of the ester acyl group in an o-acylated phenol ester, which leads to a 1,3-diketone. This reaction is related to the Claisen Condensation, and proceeds through the formation of an enolate, followed by intramolecular acyl transfer. 

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). 

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