Decarboxylation, ketoester

In addition to formation from a ketone, the hydra2ones can be obtained from dicarbonyl compounds by a Japp-Klingemann reaction. This is especially useful for P-ketoesters and P-ketoacids, which undergo either deacylation or decarboxylation. 

A fully unsaturated tricyclic indole derivative serves as the aromatic moiety for a nonsteroid antiinflammatory agent. Preparation of this compound starts with the Michael addition of the anion from methyl diethylmalonate to cyclohexanone. The product (32) is then hydrolyzed and decarboxylated to give ketoester 33. Fischer condensation with p-chlorophenylhydrazine leads to the indole This is then esterified (35) and dehydrogenated to the carbazole 36. Saponification leads... 

One such compound, bropirimine (112), is described as an agent which has both antineo-plastic and antiviral activity. The first step in the preparation involves formation of the dianion 108 from the half ester of malonic acid by treatment with butyllithium. Acylation of the anion with benzoyl chloride proceeds at the more nucleophilic carbon anion to give 109. This tricarbonyl compound decarboxylates on acidification to give the beta ketoester 110. Condensation with guanidine leads to the pyrimidone 111. Bromination with N-bromosuccinimide gives bropirimine (112) [24]. 

The utility of base catalyzed condensations of esters to give jS-ketoesters is well known. A straightforward example of this reaction is the intermolecular cyclization of diethyl succinate giving 2,5-dicarbethoxy-l,4-cyclohexanedione, which can in turn be easily decarboxylated to give 1,4-cyclohexanedione. 

The familiar alkylation of -ketoesters followed by decarboxylation is still a useful route to a-alkyl ketones, although the alkylation of enamines is frequently the preferred route. Given below are two examples of alkylation of 2-carbethoxycycloalkanones (prepared in Chapter 10, Section I). In the first case, sodium ethoxide is the base employed to generate the enolate ion of 2-carbethoxycyclohexanone. In the second case, the less acidic 2-carbethoxycyclooctanone requires sodium hydride for the generation of the enolate ion. 

Two chiral p-tolylsulphinylmethyl ketones 299 were prepared by decarboxylation of optically active sulphinyl ketoesters 300 which were obtained from (— )-(S)-276 and the... 

A divergent synthesis of tropane alkaloid ferruginine was reported by Node and coworkers [59]. The P-ketoester intermediate was prepared by a novel PLE-catalyzed asymmetric dealkoxycarbonylation (hydrolysis followed by a decarboxylation) of a symmetric tropinone-type diester (Figure 6.12). Dimethyl sulfoxide was added to the phosphate buffer pH 8 (1 9) to reduce the activity of PLE and prevent over-deal-koxycarbonylation leading to tropinone. 

These carbon nucleophiles react with acyl chlorides220 or acyl imidazolides.221 The initial products decarboxylate readily so the isolated products are (3-ketoesters. 

Esters of 1,2,3-triazolecarboxylic acids are the most common derivatives of triazole (Section 5.01.9) therefore, their conversions to other, more useful, functionalities are of great importance. In an example given in Scheme 48, 4-triazolecarbocylic ester 317, obtained from a reaction of (3-ketoester 316 with 4-chloro-2-nitrophenyl azide, is hydrolyzed to free acid 318 (82% yield) by 4% KOH. Heated to reflux in DMF for 3 h, acid 318 undergoes decarboxylation to triazole derivative 319 with 81% isolated yield <2004FA397>. 

Thermal rearrangement of (3-ketoesters followed by decarboxylation to yield Y-unsaturated ketones via anion-assisted Claisen rearrangement. It is a variant of the Claisen rearrangement (page 131). 

Pyrrolo[3,4-c][l,5]-benzothiazepin-3-ones 300 are available from ketoester 299 by a three-step sequence which includes hydrolysis and decarboxylation, aldol condensation and cyclization with o-aminothiophenol (Equation (35) (1993CE773)). 

The use of /i-ketocstcrs and malonic ester enolates has largely been supplanted by the development of the newer procedures based on selective enolate formation that permit direct alkylation of ketone and ester enolates and avoid the hydrolysis and decarboxylation of ketoesters intermediates. Most enolate alkylations are carried out by deprotonating the ketone under conditions that are appropriate for kinetic or thermodynamic control. Enolates can also be prepared from silyl enol ethers and by reduction of enones (see Section 1.3). Alkylation also can be carried out using silyl enol ethers by reaction with fluoride ion.31 Tetraalkylammonium fluoride salts in anhydrous solvents are normally the... 

The -ketoester (90) (R = Bu ) undergoes hydrolysis and decarboxylation on treatment with acid and subsequent heating, yielding the 5-acetonyl derivative (89). In contrast, when (90) (R = Et) is allowed to react with aqueous acid, the acetic acid (91) (R = H) is isolated (Scheme 22) <82M793>. Treatment of the methyl ester (91) (R = R = Me) with triethylamine and tosyl azide leads to the diazoester which was shown by IR and NMR spectroscopy to exist in the open chain form (93) and not the cyclic form (92) (Scheme 22) <92JHC713>. 

The dibasic side chain at position 7 can be alternatively provided by a substituted amino alkyl pyrrolidine. Preparation of that diamine in chiral form starts with the extension of the ester function in pyrrolidone (46-1) by aldol condensation with ethyl acetate (46-2). Acid hydrolysis of the (3-ketoester leads to the free acid that then decarboxylates to form an acetyl group (46-3). The carbonyl group is next converted to an amine by sequential reaction with hydroxylamine to form the oxime, followed by catalytic hydrogenation. The desired isomer (46-4) is then separated... 

During attempts to synthesize a series of optically active, bicyclic a-aminoketones (195-198), Kuneida and co-workers found that racem-ization invariably took place during the saponification and decarboxylation of the /9-ketoester intermediates, prepared via Dieckmann reactions [Eqs. (26) and (27)].253... 

Ketoacids126,127 form the same intermediates as the allyl 3-ketoesters by nucleophilic addition of the carboxylate to a n-allylpalladium complex. Decarboxylation generates the allylpalladium enolate, which again yields Pd° and allylated ketone. Enol silyl ethers have also been employed with allyl arsenites93 to provide allylated ketones. 

Now all is well in terms of polarity and we recognize this as a Dieckmann reaction followed by hydrolysis and decarboxylation of the yS-ketoester product. Proceeding backward we write... 

This reaction allows the preparation of dihydropyridine derivatives by condensation of an aldehyde with two equivalents of a p-ketoester in the presence of ammonia. Subsequent oxidation (or dehydrogenation) gives pyridine-3,5-dicarboxylates, which may also be decarboxylated to yield the corresponding pyridines. 

To get conjugate addition we might use a -ketoester 18 or an enamine for the enolate and we might carry out the reaction using the Mannich salt 19 so that the elimination will be caused by the same base that makes the enolate. Ester hydrolysis and decarboxylation of 20 would give 1. 

The butylated /J-ketoester C of Figure 13.26 is not the final synthetic target of the acetoacetic ester synthesis of methyl ketones. In that context, the /J-ketoester C is converted into the corresponding /J-ketocarhoxylic acid via acid-catalyzed hydrolysis (Figure 13.27 for the mechanism, see Figure 6.22). This /i-ketocarboxylic acid is then heated either in the same pot or after isolation to effect decarboxylation. The /f-ketocarboxylic acid decarboxylates via a cyclic six-membered transition state in which three valence electron pairs are shifted at the same time. The reaction product is an enol, which isomerizes immediately to a ketone (to phenyl methyl ketone in the specific example shown). 

Fig. 13.29. Synthesis of complicated ketones in analogy to the acetoacetic ester synthesis II generation of a cyclic ketone. In the first step, the /3-ketoester is alkylated at its activated position. In the second step, the /3-ketoester is treated with Li I . SN2 reaction of the iodide at the methyl group generates the /3-ketocar-boxylate ion as the leaving group. The /3-ketocarboxylate decarboxylates immediately under the reaction conditions (temperature above 100 °C) and yields the enolate of a ketone.

Fig. 13.65. Acylation of various malonic diester or malonic half-ester enolates with carboxylic acid chlorides. Spontaneous decarboxylation of the acylation products to furnish /3-ketoesters (see variants 1 and 2) and transformation of the acylation products into /3-ketoesters by way of alcoholysis/decarboxylation (see variant 3).

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