Keto anion

Figure 12.6 Geometry-optimized forms of cytosine anion in the keto and enol forms, AMI calculations. Note the twisted amino group and hent N—H bond in the keto anion and the bent O—H bond in the enol form.

Azetidinyl-4-ketones are closer than azetidinyl-4-carboxylic esters to the target 4-acyloxy derivatives 11, 29, 36. Thus, Hanessian s version of the threonine route [29], utilizing a-keto anions, can be considered an improvement over Shiozaki s a-carboxyanion strategy, especially when its aptitude for being scaled-up for industrial production is considered. The key-step, cyclization of amide 68a (prepared from epoxyacid 64 and fV-anisylphenacylamine) to azeti-dinone 28a, is carried out by simple treatment with K2CO3 at ambient temperature silylation, CAN-mediated cleavage and oxidation with mono-perphthalic acid complete the sequence to synthon 29b. 

The synthesis of spiro compounds from ketones and methoxyethynyl propenyl ketone exemplifies some regioselectivities of the Michael addition. The electrophilic triple bond is attacked first, next comes the 1-propenyl group. The conjugated keto group is usually least reactive. The ethynyl starting material has been obtained from the addition of the methoxyethynyl anion to the carbonyl group of crotonaldehyde (G. Stork, 1962 B, 1964A). 

The 1,6-difunctional hydroxyketone given below contains an octyl chain at the keto group and two chiral centers at C-2 and C-3 (G. Magnusson, 1977). In the first step of the antithesis of this molecule it is best to disconnect the octyl chain and to transform the chiral residue into a cyclic synthon simultaneously. Since we know that ketones can be produced from add derivatives by alkylation (see p. 45ff,), an obvious precursor would be a seven-membered lactone ring, which is opened in synthesis by octyl anion at low temperature. The lactone in turn can be transformed into cis-2,3-dimethyicyclohexanone, which is available by FGI from (2,3-cis)-2,3-dimethylcyclohexanol. The latter can be separated from the commercial ds-trans mixture, e.g. by distillation or chromatography. 

A hydrogen attached to the a carbon atom of a p keto ester is relatively acidic Typical p keto esters have pA values of about 11 Because the a carbon atom is flanked by two electron withdrawing carbonyl groups a carbanion formed at this site is highly stabi hzed The electron delocalization m the anion of a p keto ester is represented by the res onance structures... 

Principal resonance structures of the anion of a 3 keto ester... 

In general the equilibrium represented by the sum of steps 1 to 3 is unfavorable (Two ester carbonyl groups are more stable than one ester plus one ketone carbonyl) However because the p keto ester is deprotonated under the reaction conditions the equilibrium represented by the sum of steps 1 to 4 does he to the side of products On subsequent acidification (step 5) the anion of the p keto ester is converted to its neutral form and isolated... 

Unless the p keto ester can form a stable anion by deprotonation as m step 4 of Figure 21 1 the Claisen condensation product is present m only trace amounts at equi librium Ethyl 2 methylpropanoate for example does not give any of its condensation product under the customary conditions of the Claisen condensation... 

Even though ketones have the potential to react with themselves by aldol addition recall that the position of equilibrium for such reactions lies to the side of the starting materials (Section 18 9) On the other hand acylation of ketone enolates gives products (p keto esters or p diketones) that are converted to stabilized anions under the reaction conditions Consequently ketone acylation is observed to the exclusion of aldol addition when ketones are treated with base m the presence of esters... 

The carbon-carbon bond forming potential inherent m the Claisen and Dieckmann reac tions has been extensively exploited m organic synthesis Subsequent transformations of the p keto ester products permit the synthesis of other functional groups One of these transformations converts p keto esters to ketones it is based on the fact that p keto acids (not esters ) undergo decarboxylation readily (Section 19 17) Indeed p keto acids and their corresponding carboxylate anions as well lose carbon dioxide so easily that they tend to decarboxylate under the conditions of their formation... 

The anion of a p keto ester may be alkylated at carbon with an alkyl halide and the product of this reaction subjected to ester hydrolysis and decarboxylation to give a ketone... 

The increased nucleophilicity of the ring permits it to react with carbon dioxide An inter mediate is formed that is simply the keto form of salicylate anion... 

These reversible reactions are cataly2ed by bases or acids, such as 2iac chloride and aluminum isopropoxide, or by anion-exchange resias. Ultrasonic vibrations improve the reaction rate and yield. Reaction of aromatic aldehydes or ketones with nitroparaffins yields either the nitro alcohol or the nitro olefin, depending on the catalyst. Conjugated unsaturated aldehydes or ketones and nitroparaffins (Michael addition) yield nitro-substituted carbonyl compounds rather than nitro alcohols. Condensation with keto esters gives the substituted nitro alcohols (37) keto aldehydes react preferentially at the aldehyde function. 

Carbanions derived from carbonyl compoimds are often referred to as etiolates. This name is derived from the enol tautomer of carbonyl compounds. The resonance-stabilized enolate anion is the conjugate base of both the keto and enol forms of carbonyl... 

Enolate anions of p-keto esters react with some fluoroolefms, initially by replacement of a vinylic fluorine atom, to give ultimately heterocyclic products [2S, 29] (equation 25). 

Anions of (3-keto esters are said to be synthetically equivalent to the enolates of ketones. The anion of ethyl acetoacetate is synthetically equivalent to the enolate of acetone, for example. The use of synthetically equivalent groups is a common tactic in synthetic organic chemistry. One of the skills that characterize the most creative practitioners of organic synthesis is an ability to recognize situations in which otherwise difficult transfonnations can be achieved through the use of synthetically equivalent reagents. 

Anion 3 can add to another ester 1. The resulting anionic species 4 reacts to the stable /3-keto ester by loss of an alkoxide anion R 0 5 ... 

Condensation of an appropriately substituted phenylacetic acid with phthalic anhydride in the presence of sodium acetate leads to aldol-like reaction of the methylene group on the acid with the carbonyl on the anhydride. Dehydration followed by decarboxylation of the intermediate affords the methylenephthal-ides (12). Treatment of the phthalides with base affords directly the indandiones, probably via an intermediate formally derived from the keto-acid anion (13). The first agent of this class to be introduced was phenindandione (14) this was followed by anisindandione (1S) and chlorindandione (16). ... 

Hydrazinopyridazines such as hydralazine have a venerable history as anti hypertensive agents. It is of note that this biological activity is maintained in the face of major modifications in the heterocyclic nucleus. The key intermediate keto ester in principle can be obtained by alkylation of the anion of pi peri done 44 with ethyl bromo-acetate. The cyclic acylhydrazone formed on reaction with hydrazine (46) is then oxidized to give the aromatized compound 47. The hydroxyl group is then transformed to chloro by treatment with phosphorus oxychloride (48). Displacement of halogen with hydrazine leads to the formation of endralazine (49). ... 

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