Preparation acetoacetic ester synthesis

Section 21 6 The acetoacetic ester synthesis is a procedure in which ethyl acetoac etate is alkylated with an alkyl halide as the first step in the preparation... 

Acetoacetic ester synthesis (Section 21 6) A synthetic method for the preparation of ketones in which alkylation of the enolate of ethyl acetoacetate... 

This reaction sequence is called the acetoacetic ester synthesis. It is a standard procedure for the preparation of ketones from alkyl halides, as the conversion of 1-bromobutane to 2-heptanone illustrates. 

Using the Acetoacetic Ester Synthesis to Prepare a Ketone... 

How would you prepare 2-pentanone by an acetoacetic ester synthesis ... 

Which of the following compounds cannot be prepared by an acetoacetic ester synthesis Explain. 

Both the malonic ester synthesis and the acetoacetic ester synthesis are easy to cany out because they involve unusually acidic dicarbonyi compounds. As a result, relatively mild bases such as sodium ethoxide in ethanol as solvent can be used to prepare the necessary enolate ions. Alternatively, however, it s also possible in many cases to directly alkylate the a position of monocarbonyl compounds. A strong, stericaliy hindered base such as LDA is needed so that complete conversion to the enolate ion takes place rather than a nucleophilic addition, and a nonprotic solvent must be used. 

The cyclic /3-keto ester produced in a Dieckmann cyclization can be further alkylated and decarboxylated by a series of reactions analogous to those used in the acetoacetic ester synthesis (Section 22.7). For example, alkylation and subsequent decarboxylation of ethyl 2-oxocyclohexanecarboxylate yields a 2-alkylcvclohexanone. The overall sequence of (1) Dieckmann cyclization, (2) /3-keto ester alkylation, and (3) decarboxylation is a powerful method for preparing 2-substituted cyclohexanones and cyclopentanones. 

Another alternative for preparing a primary amine from an alkyl halide is the Gabriel amine synthesis, which uses a phthalimide alkylation. An imide (—CONHCO—) is similar to a /3-keto ester in that the acidic N-H hydrogen is flanked by two carbonyl groups. Thus, imides are deprotonated by such bases as KOH, and the resultant anions are readily alkylated in a reaction similar to the acetoacetic ester synthesis (Section 22.7). Basic hydrolysis of the N-alkylated imide then yields a primary amine product. The imide hydrolysis step is analogous to the hydrolysis of an amide (Section 21.7). 

It is obvious that many carboxylic acids of the formulas RCH2COOH and RR CHCOOH can be synthesized by this method (for some other ways of preparing such acids, see 10-106, 10-108, and 10-109). Another important example is the acetoacetic ester synthesis, in which Z is COOEt and Z is COCH3. In this case the product can be decarboxylated with acid or dilute base (12-38) to give a ketone or cleaved with concentrated base (12-41) to give a carboxylic ester and a salt of acetic acid ... 

Among other methods for the preparation of alkylated ketones are (1) the Stork enamine reaction (12-18), (2) the acetoacetic ester synthesis (10-104), (3) alkylation of p-keto sulfones or sulfoxides (10-104), (4) acylation of CH3SOCH2 followed by reductive cleavage (10-119), (5) treatment of a-halo ketones with lithium dialkyl-copper reagents (10-94), and (6) treatment of a-halo ketones with trialkylboranes (10-109). 

The esters of nitrous acid are characterised by their high velocities of formation and hydrolysis. They are almost instantaneously decomposed by mineral acids and in the method of preparation given this has been taken into account. The slightest excess of hydrochloric acid must be avoided. Advantage is taken of this property of the alkyl nitrites in all cases where it is desired to liberate nitrous acid in organic solvents (in which metallic nitrites are insoluble). Examples addition of N203 to olefines, preparation of solid diazonium salts (p. 286), production of isonitroso-derivatives from ketones by the action of HN02. This synthesis is often also carried out in the manner of the acetoacetic ester synthesis, with ketone, alkyl nitrite, and sodium ethylate the sodium salt of the isonitrosoketone is formed (cf. in this connexion p. 259) ... 

Acetoacetic ester synthesis is the preparation of substituted acetones, and it s an important method for creating a variety of products. It begins with the reaction of acetoacetic ester (a dicarbonyl) or a similar compound with a strong base to produce a carbanion, which then reacts with alkyl halide, RX. The structure of acetoacetic ester is in Figure 15-10. Figure 15-11 illustrates an example of an acetoacetic ester synthesis and two possible outcomes. Figure 15-12 shows the preparation of 2-heptanone with a 65 percent yield via the acetoacetic ester synthesis. Figure 15-13 presents the preparation of 2-benzylcyclohexanone with a 77 percent yield. 

Malonic esters have two ester groups, each of which may react as in the acetoacetic ester synthesis due to their similar structure (see the preceding section). The malonic ester synthesis provides a method for preparing a substituted acetic acid. Figure 15-14 shows the structure of one type of malonic ester. Figure 15-15 outlines the basic malonic ester synthesis. May repeat in that figure refers to the reaction with a second molecule of RX (or R X). 

Problem 17.19 Use aae (acetoacetic ester) synthesis to prepare the /3-diketone 2,4-hexanedione,... 

Problem 17.47 Can the following ketones be prepared by the acetoacetic ester synthesis Explain, (a) CHjCOCHX H, (b) CHX0CHX(CH3),. ... 

This method of preparation can be applied generally to the esters of the phenyl-olefinic acids. Although metallic sodium is used, yet as in the acetoacetic ester synthesis (see Reaction XLVI.) a trace of alcohol must always be present to form sodium ethoxide. This is usually the case. If necessary, sodium ethoxide itself can be employed. The use of some other condensing agents will be clear from the following preparation. 

Fig. 13.26. Acetoacetic ester synthesis of methyl ketones I preparation of an alkylated acetoacetic ester.

Ester-substituted ketone enolates are stabilized, and these enolates can be alkylated (ace-toacetic ester synthesis). Alkylation is, however, also possible for enolates that are not stabilized. In the case of the stabilized enolates, the alkylated ketones are formed in two or three steps, while the nonstabilized enolates afford the alkylated ketones in one step. However, the preparation of nonstabilized ketone enolates requires more aggressive reagents than the ones employed in the acetoacetic ester synthesis. 

Alkylation of the enolate anion derived from ethyl acetoacetate followed by removal of the ester group is known as the acetoacetic ester synthesis and is an excellent method for the preparation of methyl ketones. The product of an acetoacetic ester synthesis is the same as the product that would be produced by the addition of the same... 

Although the acetoacetic ester synthesis and the malonic ester synthesis are used to prepare ketones and carboxylic acids, the same alkylation, without the hydrolysis and decarboxylation steps, can be employed to prepare substituted /3-ketoesters and /3-diesters. In fact, any compound with two anion stabilizing groups on the same carbon can be deprotonated and then alkylated by the same general procedure. Several examples are shown in the following equations. The first example shows the alkylation of a /3-ketoester. Close examination shows the similarity of the starting material to ethyl acetoacetate. Although sodium hydride is used as a base in this example, sodium ethoxide could also be employed. 

Decide which synthesis to use. The acetoacetic ester synthesis is used to prepare methyl ketones, and the malonic ester synthesis is used to prepare carboxylic acids. Both syntheses provide a method to add alkyl groups to the a-carbon. Therefore, next identify the group or groups that must be added to the a-carbon. Remember that the a-carbon is the nucleophile, so the groups to be attached must be the electrophile in the Sn2 reaction they must have a leaving group bonded to the carbon to which the new bond is to be formed. 

The acetoacetic ester synthesis is used to prepare methyl ketones such as this. In this example, a butyl group must be attached to the enolate nucleophile. 

The acetoacetic ester synthesis can t be used to prepare compounds that are... 

The method is especially valuable for the preparation of certain substituted acetophenones, namely, o- and p-nitroacetophenone and o-chloro-acetophenone. Methods involving Grignard, Friedel-Crafts, or nitration reactions are apparently not applicable for the preparation of these nitro compounds, and the Friedel-Crafts reaction is not applicable to the preparation of o-chloroacetophenone. Although the acetoacetic ester synthesis has been used for the preparation of these and other substituted acetophenones, it may be complicated by O-acylation and also by cleavage at either acyl group (cf. method 212). 

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