Intramolecular ester condensation

This case study deals with an industrial Dieckmann condensation (intramolecular ester condensation Scheme 5.6) considering the laboratory and the operation scale. 

DMSO resulted in an intramolecular ester condensation (Baker Venkataraman-type rearrangement) to give a Cl 5 phenol the cyclization of which furnished the 0-benzyl-protected flavone-C-glycoside. After deprotection, isoembigenin was obtained. 

Intramolecular ester condensation reactions are called Dieckmann condensations and are very useful ring-forming reactions. Examples are shown in the following equations. In the second equation the yield is only 54% if sodium ethoxide is used as the base. 

Stream of nitrogen. The initial product, the jS-keto sulfoxide II, undergoes intramolecular ester condensation with formation of the 1,3-indanedione system. Ill, which in the presence of hydrochloric acid undergoes Pummerer rearrangement to 2-chloro-2-methylmercapto-l,3-indanedione (IV). This crystalline product (m.p. 63°) is obtained in yield of 80% and is hydrolyzed in boiling water nearly quantitively to ninhydrin (V). 

Dimedon, 5,5-dimethylcyclohexane-l,3-dione, is prepared by an interesting process discovered by Vorlander. The reaction of 1 mole each of diethyl malonate, mesityl oxide, and sodium ethoxide in absolute ethanol probably involves a Michael addition followed by an intramolecular ester condensation to close the ring to give the diketo ester formulated (procedure of Shriner and Todd. Aqueous potassium... 

The addition reaction of enolates to activated cyclopropanes has also been applied to intramolecular reactions leading to cyclic and bicyclic products as the result of a subsequent intramolecular ester condensation ... 

Intramolecular ester condensation. Indian chemists have synthesized 2-(6 -methoxycarbonylhexyl)cyclopentene-2-one-l (4) from methyl 10-undecene-oate (1). The enone has been used for synthesis of prostaglandins. 

The coupling of 3-tert-butyl [1 - " C]malonate (393) with the /3-amino acid derivative 395 to give amide 396 was developed as an alternative route to the 1,4 addition of 395 to the corresponding [l- " C]acrylate 394, which might have failed due to radiation-induced polymerization. Subsequent treatment with 2,4-bis(4-methoxyphenyl)-l,3,2,4-dithiadi-phosphetane-2,4-disulfide (Lawesson s reagent) followed by Raney nickel-mediated desulfurization of the thioamide function formed converted 396 into the target /3-amino acid ester 397. Intramolecular ester condensation upon treatment of 397 with sodium methoxide and concluding saponification and decarboxylation of the f-butyl ester function afforded the trisubstituted 4-[2- " C]piperidone derivative 398. 

Cydopentane reagents used in synthesis are usually derived from cyclopentanone (R.A. Ellison, 1973). Classically they are made by base-catalyzed intramolecular aldol or ester condensations (see also p. 55). An important example is 2-methylcydopentane-l,3-dione. It is synthesized by intramolecular acylation of diethyl propionylsucdnate dianion followed by saponification and decarboxylation. This cyclization only worked with potassium t-butoxide in boiling xylene (R. Bucourt, 1965). Faster routes to this diketone start with succinic acid or its anhydride. A Friedel-Crafts acylation with 2-acetoxy-2-butene in nitrobenzene or with pro-pionyl chloride in nitromethane leads to acylated adducts, which are deacylated in aqueous acids (V.J. Grenda, 1967 L.E. Schick, 1969). A new promising route to substituted cyclopent-2-enones makes use of intermediate 5-nitro-l,3-diones (D. Seebach, 1977). 

The decarboxylation of allyl /3-keto carboxylates generates 7r-allylpalladium enolates. Aldol condensation and Michael addition are typical reactions for metal enolates. Actually Pd enolates undergo intramolecular aldol condensation and Michael addition. When an aldehyde group is present in the allyl fi-keto ester 738, intramolecular aldol condensation takes place yielding the cyclic aldol 739 as a main product[463]. At the same time, the diketone 740 is formed as a minor product by /3-eIimination. This is Pd-catalyzed aldol condensation under neutral conditions. The reaction proceeds even in the presence of water, showing that the Pd enolate is not decomposed with water. The spiro-aldol 742 is obtained from 741. Allyl acetates with other EWGs such as allyl malonate, cyanoacetate 743, and sulfonylacetate undergo similar aldol-type cycliza-tions[464]. 

Original Synthesis. The first attempted synthesis of i7-biotin in 1945 afforded racemic biotin (Fig. I). In this synthetic pathway, L-cysteine [52-90-4] (2) was converted to the methyl ester [5472-74-2] (3). An intramolecular Dieckmaim condensation, during which stereochemical integrity was lost, was followed by decarboxylation to afford the thiophanone [57752-72-4] (4). Aldol condensation of the thiophanone with the aldehyde ester [6026-86-4]... 

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 first step of the Robinson annulation is simply a Michael reaction. An enamine or an enolate ion from a jS-keto ester or /3-diketone effects a conjugate addition to an a-,/3-unsaturated ketone, yielding a 1,5-diketone. But as we saw in Section 23.6,1,5-diketones undergo intramolecular aldol condensation to yield cyclohexenones when treated with base. Thus, the final product contains a six-membered ring, and an annulation has been accomplished. An example occurs during the commercial synthesis of the steroid hormone estrone (figure 23.9). 

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

Esters of dicarboxylic acids having hydrogen on the 8 or e carbon atcans undergo intramolecular cyclisation when heated with sodium or with sodium ethoxide. This cyclisation is known as the Dieckmaim reaction. It is essentially an application of the Claiseu (or acetoacetic ester) condensation to the formation of a ring system the condensation occurs internally to produce s... 

The intramolecular version of ester condensation is called the Dieckmann condensation.217 It is an important method for the formation of five- and six-membered rings and has occasionally been used for formation of larger rings. As ester condensation is reversible, product structure is governed by thermodynamic control, and in situations where more than one product can be formed, the product is derived from the most stable enolate. An example of this effect is the cyclization of the diester 25.218 Only 27 is formed, because 26 cannot be converted to a stable enolate. If 26, synthesized by another method, is subjected to the conditions of the cyclization, it is isomerized to 27 by the reversible condensation mechanism. 

The intramolecular version of ester condensation is called the Dieckmann condensation,119 It is an important method for the formation of five- and six-membered rings and has occassionally been used for formation of larger rings. Entries 3-6 in Scheme 2.13 are illustrative. 

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]. 

The condensation of glycine esters with /S-keto esters gives 3-hydroxypyrroIes (equation 115). The cyclization is effected using strong base and is, in effect, an intramolecular Claisen condensation (67AJC935). 

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