Ester groups products

With a more complex diazo compound containing amino and ester groups, products resulting from 1,3- and 1,5-dipolar elec-trocyclization are obtained. Two-fold extrusion reactions with 1 and diverse diazo compounds are reported to be aimed at the preparation of stericaUy crowded ethylenes. An example with bis(/er/-butyl)diazomethane (25) is shown in eq 12. 

A regioselective aldol condensation described by Biichi succeeds for sterical reasons (G. Biichi, 1968). If one treats the diaidehyde given below with acid, both possible enols are probably formed in a reversible reaaion. Only compound A, however, is found as a product, since in B the interaction between the enol and ester groups which are in the same plane hinders the cyclization. BOchi used acid catalysis instead of the usual base catalysis. This is often advisable, when sterical hindrance may be important. It works, because the addition of a proton or a Lewis acid to a carbonyl oxygen acidifies the neighbouring CH-bonds. 

Step 2 Nucleophilic addition of the ester enolate to the carbonyl group of the neutral ester The product is the anionic form of the tetrahedral intermediate... 

The product of this reaction is geranyl pyrophosphate Hydrolysis of the pyrophosphate ester group gives geramol a naturally occurring monoterpene found m rose oil... 

Fig. 8. Rephcation. The amino adenosine X and the pentafluorophenyl ester Y form a hydrogen-bonded dimer XY, prior to reaction between the amine and the activated ester groups (shown in the circle). The reaction product is a <7 -amide conformer cis-Z that isomeri2es to the more stable trans- acnide Z. The rephcative process is cataly2ed by the reaction product Z (also referred to as the template). First, a termolecular complex XYZ is formed from X, Y, and Z.

THE can be polymerized by many strongly acidic catalysts, but not all of them produce the requked bitimctional polyether glycol with a minimum of by-products. Several large-scale commercial polymerization processes are based on fluorosulfonic acid, HESO, catalysis, which meets all these requkements. The catalyst is added to THE at low temperatures and an exothermic polymerization occurs readily. The polymerization products are poly(tetramethylene ether) chains with sulfate ester groups (8). 

The most successful of these products contain high ratios of VP to DMAEMA and are partially quatemized with diethyl sulfate (Polyquaternium 11) (142—144). They afford very hard, clear, lustrous, nonflaking films on the hair that are easily removed by shampooing. More recendy, copolymers with methyl vinyl imidazoliiim chloride (Polyquaternium 16) (145) or MAPTAC (methacrylamidopropyltrimethyl ammonium chloride) (Polyquaternium 28) have been introduced. Replacement of the ester group in DMAEMA with an amide analog as in Polyquaternium 28 results in a resin resistant to alkaline hydrolysis and hence greater utility in alkaline permanent-wave and bleach formulations (see Quaternary ammonium compounds). 

In an attempt to prepare an isothiazolobenzodiazepine, ethyl 5-o-aminoanilino-3-methyl-isothiazole-4-carboxylate was treated with sodium methoxide, but the only reaction was transesterification to the methyl ester 76UC(B)394). Only the 5-ester group of dimethyl 3-methylisothiazole-4,5-dicarboxylate reacts with iV,iV -diphenylguanidine, as with the corresponding isoxazole compound, but the product could not be cyclized, even under drastic conditions. This is in marked constrast to the isoxazole compound which cyclized at room temperature (80JCS(P1)1667). 

On heating arecoline with ammonia in alcohol, addition occurs at the ethylenic linkage followed by amination at the ester group the products formed are A -methyl-4-aminopiperidinc-3-carboxyamide, m.p. 180° ... 

Addition to 1,2-dimethyl- -piperideine or 1,2-dimethyl- -pyrroline is followed by intramolecular alkylation by the ester group as a side reaction to give 140 and 141 ( = 1, 2), respectively. Cyclization products 142 and... 

In the first step of what is considered to be a fairly straightforward mechanism, the anilinic nitrogen reacts with the ester group of the 3-ketoester 5 to provide the anilide 3. The latter can either be isolated or carried on directly. Upon warming in the presence of acid, the acetanilide cyclizes with subsequent loss of water to yield the quinolone product 9. ... 

Pyridine and dimethyl acetylenedicarboxylate in methanol yield - a mixture of (33) and (34). It is tempting to assume that a zwitterion (30) is first formed and that this then adds a proton followed by a methoxide ion (Michael addition) under the influence of both the positive charge on the ring and the assisting ester group. The resulting structure (31) could then add another molecule of the ester and cyclize, as indicated, to (32). Subsequent aromatization accompanied by loss of one, or the other, substituent at position 3 would lead to the two products, (33) and (34), actually isolated. 

An alternative scheme which has parallels with several reactions described in Section II can also account for the production of Kashi-moto s compound and is outlined in the following. Initial attack of the pyridine nitrogen atom on the ester group with the expulsion of... 

The reasonable mechanism outlined above has not yet been rigorously proven in every detail, but is supported by the fact that a 1 1-intermediate 5 has been isolated." The ester groups are essential for the Weiss reaction because of the /3-keto ester functionalities however, the ester groups can be easily removed from the final product by ester hydrolysis and subsequent decarboxylation. 

The finding that the anthelmintic thiazoloimidazole levamisole showed immunoregulatory activity spurred further investigation of this heterocyclic system. Synthesis of a highly modified analogue starts by displacement of bromine in keto ester 149 by sulfur in substituted benzimidazole 148. Cyclization of the product (150), leads initially to the carbinol 151. Removal of the ester group by saponification in base followed by acid-catalyzed dehydration of the carbinol affords the immune regulator tilomisole (152) [28]. 

This product was dissolved in 10 ml of chloroform. To this solution were added 10 ml of a 10% aqueous solution of caustic soda and the mixture was warmed at 50°C to effect hydrolysis of the ester group. After completion of the reaction, the organic phase was separated, washed with water and distilled to remove the solvent whereby 2.1 g (yield 4B%) of the end product, i.e., N-(3, 4 -dimethoxycinnamoyl)-anthranilic acid, were obtained. This product had a melting point of 211°C to 213°C. 

The mechanism of the Dieckmann cyclization, shown in Figure 23.6, is the same as that of the Claisen condensation. One of the two ester groups is converted into an enolate ion, which then carries out a nucleophilic acyl substitution on the second ester group at the other end of the molecule. A cyclic /3-keto ester product results. 

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