Acetoacetic acid utilization

Scheme 14.22. Utilization of condensation chemistry of ethyl acetoacetate (ethyl 3-oxopropanoate) with ethyl iodide and the t-butyl ester of acetoacetic acid to produce yet another pyrrole derivative 3-ethyl-2,4-dimethylpyrrole.

Scheme 14.22 utilizes ethyl iodide (iodoethane) and the t-butyl ester of acetoacetic acid (t-butyl 3-oxobutanoate) in a similar set of condensation reactions. Here, however, the t-butyl ester is not hydrolyzed under basic conditions, and... 

Curran, G. L. Utilization of acetoacetic acid in cholesterol synthesis by surviving rat liver. J. biol. Chem. 191, 775 (1951). 

A modihed Hantzsch synthesis has been utilized for the preparation of 1,4-dihydropyridines (Scheme 66). Thus, condensation of formylfurazans 116 with an acetoacetic ester and aminocrotonic acid ester in isopropanol at reflux led to 1,4-dihydropyridine derivatives 117 in about 70% yield (92AE921). Both isomeric furoxan aldehydes reacted in a similar way. 

The rate of mitochondrial oxidations and ATP synthesis is continually adjusted to the needs of the cell (see reviews by Brand and Murphy 1987 Brown, 1992). Physical activity and the nutritional and endocrine states determine which substrates are oxidized by skeletal muscle. Insulin increases the utilization of glucose by promoting its uptake by muscle and by decreasing the availability of free long-chain fatty acids, and of acetoacetate and 3-hydroxybutyrate formed by fatty acid oxidation in the liver, secondary to decreased lipolysis in adipose tissue. Product inhibition of pyruvate dehydrogenase by NADH and acetyl-CoA formed by fatty acid oxidation decreases glucose oxidation in muscle. 

The synthesis of the representative compound of this series, 1,4-dihydro-l-ethyl-6-fluoro (or 6-H)-4-oxo-7-(piperazin-l-yl)thieno[2/,3/ 4,5]thieno[3,2-b]pyridine-3-carboxylic acid (81), follows the same procedure as that utilized for compound 76. Namely, the 3-thienylacrylic acid (77) reacts with thionyl chloride to form the thieno Sjthiophene -carboxyl chloride (78). Reaction of this compound with monomethyl malonate and n-butyllithium gives rise to the acetoacetate derivative (79). Transformation of compound 79 to the thieno[2 3f 4,5]thieno[3,2-b]pyhdone-3-carboxy ic acid derivative (80) proceeds in three steps in the same manner as that shown for compound 75 in Scheme 15. Complexation of compound 75 with boron trifluoride etherate, followed by reaction with piperazine and decomplexation, results in the formation of the target compound (81), as shown in Scheme 16. The 6-desfluoro derivative of 81 does not show antibacterial activity in vitro. 

The addition product of ethyl acetoacetate and methyl a-methoxyacrylate was hydrolyzed, and the resulting dicarboxylic acid was treated with dimethylamine hydrochloride and aqueous formaldehyde. The product of the Mannich reaction was decarboxylated, reesterifed, and finally treated with methyl iodide to supply quaternary salt 469 as the main product. During the above one-pot process, elimination also took place, yielding unsaturated ketone 470, which was later utilized as its hydrogen bromide adduct 471. Reaction of 3,4-dihydro- 3-car-boline either with 469 or 471 furnished the desired indolo[2,3-a]quinolizine derivative 467 as a mixture of two diastereomeric racemates. 

However, the reaction is not quite that simple, and to understand and utilize the Claisen reaction we have to consider pAT values again. Loss of ethoxide from the addition anion is not really favourable, since ethoxide is not a particularly good leaving group. This is because ethoxide is a strong base, the conjugate base of a weak acid (see Section 6.1.4). So far then, the reaction will be reversible. What makes it actually proceed further is the fact that ethoxide is a strong base, and able to ionize acids. The ethyl acetoacetate prodnct is a 1,3-dicarbonyl componnd and has relatively acidic protons on the methylene between the two carbonyls (see Section 10.1). With... 

In mammals, muscle breakdown or excess protein intake results in an imbalance between the fates of the carbon chains and the amino nitrogen. Unlike fat (lipid storage) or glycogen (carbohydrate storage), excess amino acids are not stored in polymeric form for later utilization. The carbon chains of amino acids are generally metabolized into tricarboxylic acid (TCA) cycle intermediates, although it is also possible to make ketone bodies such as acetoacetate from some. Conversion to TCA intermediates is easy to see in some instances. For example, alanine is directly transaminated to pyruvate. 

Augustine et al. prepared 2-methylindole in high yield by hydrogenating o-ni-trophenylacetone, obtained from o-fluoronitrobenzene and ethyl acetoacetate, over 5% Pd-C in acetic acid at room temperature and 0.28 MPa H2 (Scheme 9.18).164 Examples of utilization of condensation at the amino group for the formation of six-membered nitrogen rings are shown in eqs. 9.67165 and 9.68.166... 

The synthetic utility of alkylation of enolates is utilized in the syntheses of malonic ester (3.3) and acetoacetic ester (3.2). For example, carbanion generated from malonic ester undergoes an Sn2 reaction with alkyl halide to yield alkyl-substituted malonic ester. The monosubstituted malonic ester still has an active hydrogen atom. The second alkyl group (same or different) can be introduced in a similar manner. Acid-catalyzed hydrolysis or base-catalyzed hydrolysis of mono- or disubstituted derivative of malonic ester followed by acidification gives the corresponding mono- or disubstituted malonic acid, which on decarboxylation yields the corresponding monocarboxylic acid (Scheme 3.3). 

Figure 22.20. Utilization of Acetoacetate as a Fuel. Acetoacetate can be converted into two molecules of acetyl CoA, which then enter the citric acid cycle.

Figure 6-13. Ketone body synthesis and utilization. FA = fatty acid AcCoA = acetyl CoA AcAcCoA = ace-toacetyl CoA aKG = a-ketoglutarate OAA = oxaloacetate HMG CoA = hydroxymethylglutaryl CoA. The thio-transferase is succinyl CoA-acetoacetate-CoA transferase.

Succinyl-CoA can also be synthesized from propionyl-CoA by way of methylmalonyl-CoA, which is formed in the oxidation of branched-chain amino acids (e.g., valine, isoleucine) and in the terminal stage of oxidation of odd-chain-length fatty acids (Chapter 18). Succinyl-CoA is utilized in the activation of acetoacetate (Chapter 18) and the formation of (5-aminolevulinate, a precursor of pro-phyrin (Chapter 29). 

Acetoacetate and 6-hydroxybutyrate are products of normal metabolism of fatty acid oxidation and serve as metabolic fuels in extrahepatic tissues. Their level in blood depends on the rates of production and utilization. Oxidation increases as their plasma level increases. Some extra-hepatic tissues (e.g., muscle) oxidize them in preference to glucose and fatty acid. Normally, the serum concentration of ketone bodies is less than 0.3 mM/L. 

Ketone body production and utilization. Ketone bodies are produced in the liver from fatty acids derived from adipocyte lipolysis. They are released and used as fuel in peripheral tissues. The initial step in acetoacetate metabolism is activation to acetoacetyl-CoA by succinyl-CoA. HMG-CoA, /S-hydroxy-y3-methylglutaryl-CoA HB, /i-hydroxybutyrate. 

Danishefsky has exploited his widely utilized silyloxydiene chemistry to complete a formal total synthesis of 90 (Scheme 1.20). By employing the appropriate oxidation levels for both the diene and dienophile, a resorcinyl ester possessing the required differentiation of the phenolic groups was obtained without further oxidative manipulation. To this end, the dianion of propiolic acid was alkylated with l-bromo-7-octene to give acid 98 in 68% yield. Further alkylation with methyl iodide then gave the ester 99. A Diels-Alder reaction with diene 100, a derivative of methyl acetoacetate, and alkyne 99 then furnished an initial phenolic intermediate which was protected as the benzyl ether to afford... 

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