2-Heptanone enolization

Electron rich enol acetates react in a fashion similar to that described above for other poor Michael acceptors. Vinyl acetate reacts in the Michael sense with chloroform under phase transfer conditions to give 2,2,2-trichloroisopropyl acetate [14,53], but more highly substituted enol acetates undergo dichlorocyclopropanation. The reaction scheme is similar to that shown in equation 2.28 (above) and the Michael addition of trichloromethide ion to vinyl acetate and the cyclopropanation of bicyclo-[3.2.1] heptanone enol acetate [54] are shown in equations 2.29 and 2.30, respectively. 

Prepare the desired one of the two possible enolate ions. The two ions, for example, 127 and 128 for 2-heptanone, interconvert rapidly only in the... 

The effect of HMPA on the reactivity of cyclopentanone enolate has been examined.44 This enolate is primarily a dimer, even in the presence of excess HMPA, but the reactivity increases by a factor of 7500 for a tenfold excess of HMPA at -50° C. The kinetics of the reaction with CH3I are consistent with the dimer being the active nucleophile. It should be kept in mind that the reactivity of regio- and stereoisomeric enolates may be different and the alkylation product ratio may not reflect the enolate composition. This issue was studied with 2-heptanone.45 Although kinetic deprotonation in THF favors the 1-enolate, a nearly equal mixture of C(l) and C(3) alkylation was observed. The inclusion of HMPA improved the C(l) selectivity to 11 1 and also markedly accelerated the rate of the reaction. These results are presumably due to increased reactivity and less competition from enolate isomerization in the presence of HMPA. 

Examples of this approach to the synthesis of ketones and carboxylic acids are presented in Scheme 1.6. In these procedures, an ester group is removed by hydrolysis and decarboxylation after the alkylation step. The malonate and acetoacetate carbanions are the synthetic equivalents of the simpler carbanions lacking the ester substituents. In the preparation of 2-heptanone (entries 1, Schemes 1.5 and 1.6), for example, ethyl acetoacetate functions as the synthetic equivalent of acetone. It is also possible to use the dilithium derivative of acetoacetic acid as the synthetic equivalent of acetone enolate.29 In this case, the hydrolysis step is unnecessary, and decarboxylation can be done directly on the alkylation product. 

This procedure for the acetylation of methyl alkyl ketones to form /3-diketones is a modification5 of an earlier procedure, which used boron trifluoride gas as the catalyst.6 3-n-Butyl-2,4-pentanedione has also been prepared by the acetylation of 2-heptanone catalyzed with boron trifluoride gas,7 by the thermal rearrangement of the enol acetate of 2-heptanone,7 and by the alkylation of the potassium enolate of 2,4-pentanedione with n-butyl bromide.8... 

The annulation reaction of bis(trimethylsilyloxy)enol ether 26 with 1,4-pentanedione in the presence of a catalytic quantity of tiimethylsilyltriflate at -50 "C in dry dichloromethane furnishes oxabicyclo[3,2.1]heptanone 27 in 92% yield. Compound 27 is used as starting material for (+)-davanone, a major component of the South Indian plant Artemisia pattens <99T617>. 

The enolization of 2-heptanone (2) provides a typical example of the different regioselectivities which can be obtained by applying conditions for thermodynamic8 or kinetic9,10 control. 

The reaction with optically active hydrazones provided an access to optically active ketones. The butylzinc aza-enolate generated from the hydrazone 449 (derived from 4-heptanone and (,S )-1 -amino-2-(methoxymethyl)pyrrolidine (SAMP)) reacted with the cyclopropenone ketal 78 and led to 450 after hydrolysis. The reaction proceeded with 100% of 1,2-diastereoselectivity at the newly formed carbon—carbon bond (mutual diastereo-selection) and 78% of substrate-induced diastereoselectivity (with respect to the chiral induction from the SAMP hydrazone). The latter level of diastereoselection was improved to 87% by the use of the ZnCl enolate derived from 449, at the expense of a slight decrease in yield. Finally, the resulting cyclopropanone ketal 450 could be transformed to the polyfunctional open-chain dicarbonyl compound 451 by removal of the hydrazone moiety and oxymercuration of the three-membered ring (equation 192). 

The present procedures illustrate general methods for the use of preformed lithium enolates5 as reactants in the aldol condensation6 and for the quenching of alkali metal enolates in acetic anhydride to form enol acetates with the same structure and stereochemistry as the starting metal enolate.7 The aldol product, [Pg.55]

Regioselective alkylation of a methyl ketone Even though the kinetic enolate of 2-heptanone consists of a mixture of terminal and internal enolates in the ratio 87 13, benzylation in DME results in preferential internal alkylation. Regioselective benzylation at the terminal position can be enhanced by addition of various ligands such as benzo-14-crown-4 and DMF, but HMPT is the most effective ligand, resulting in a ratio of terminal to internal benzylation of 11 1. The three ligands also increase the rate of alkylation. The same effect, but less marked, is observed in alkylation with the less reactive electrophile butyl iodide. 

Enol acetylation (I, 1174 1178). As a Grst step in the synthesis of 3-n-butyl-2,4-pentanedione, a mixture of 28.6 g. (0.25 mole) of 2-heptanone, 51.0 g. (0.50 mole) of acetic anhydride, and 1.9 g. (0.01 mole) of p-toluenesulfonic acid monohydrate contained in a stoppered 500-ml. round-bottomed flask equipped with a magnetic stirrer is stirred at room temperature for 30 min. Then 55 g. (0.43 mole) of the I 1 boron trifluoridc-acetic acid complex [Reagents, I, 69 (1967)] is added some heat is evolved... 

Cyclohexanones can be dehydrogenated to enones by treatment of the corresponding enol silanes with DDQ in the presence of a catalytic amount of the bis-silyl derivative of acetamide. However, the yields fall off drastically when the reaction is applied to cyclopentanones and cyclo-heptanones. Another new method for dehydrogenation of carbonyl compounds consists of conversion to their pyridine-2-sulfIde derivatives, followed by oxidation (MCPBA), and by mild heat. ... 

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