Intramolecular dehydration

Dehydration is the first step of pinacol rearrangement of vzc-diol. Tertiary alcohols can dehydrate intramolecularly with an acid as a catalyst to form olefins, which provides another mechanism of a reverse polarity change from a polar to nonpolar state [353]. 

In 2001, another procedure reported the use of ethyl chloroformate as promoter of the dehydrative intramolecular cychzation of the (5)-HPMPC... 

The aldol reaction is a carbonyl condensation that occurs between two aldehyde or ketone molecules. Aldol reactions are reversible, leading first to /3-hydroxy aldehydes/ketones and then to a,/8-unsaturated products after dehydration. Intramolecular aldol condensations of 1,4- and 1,5-diketones are also successful and provide a good way to make five- and six-membered rings. 

In Summary Carboxylic acids react with alcohols to form esters, as long as a mineral acid catalyst is present. This reaction is only shghtly exothermic, and its equilibrium may be shifted in either direction by the choice of reaction conditions. The reverse of ester formation is ester hydrolysis. The mechanism of esterification is add-catalyzed addition of alcohol to the carbonyl group followed by acid-catalyzed dehydration. Intramolecular ester formation results in lactones, favored only when five- or six-manbered rings are produced. 

In his cephalosporin synthesis methyl levulinate was condensed with cysteine in acidic medium to give a bicyclic thiazolidine. One may rationalize the regioselective formation of this bicycle with the assumption that in the acidic reaction mixture the tMoI group is the only nucleophile present, which can add to the ketone. Intramolecular amide formation from the methyl ester and acid-catalyzed dehydration would then lead to the thiazolidine and y-lactam rings. The stereochemistry at the carboxylic acid a-... 

Lithiated indoles can be alkylated with primary or allylic halides and they react with aldehydes and ketones by addition to give hydroxyalkyl derivatives. Table 10.1 gives some examples of such reactions. Entry 13 is an example of a reaction with ethylene oxide which introduces a 2-(2-hydroxyethyl) substituent. Entries 14 and 15 illustrate cases of addition to aromatic ketones in which dehydration occurs during the course of the reaction. It is likely that this process occurs through intramolecular transfer of the phenylsulfonyl group. 

The reaction is very slow in neutral solution, but the equiUbrium shifts toward the lactam rather than glutamic acid. Under strongly acidic or alkaline conditions, the ring-opening reaction requires a very short time (10). Therefore, neutralization of L-glutamic acid should be performed cautiously because intramolecular dehydration is noticeable even below 190°C. 

Inter and Intramolecular nucleophiKc displacement o< alcohols wHh inversion by means of cHethyi azo cartMxylate (DEAD)-triphenylphosphine and a nucleophile. Also dehydration, esterification of alcohols or alkylallon of phenols,... 

When a hydrogen atom is present next to the carboxyl group, an intramolecular dehydration may occur, resulting in a ketene Two highly fluonnated, sulfur-con-taming ketenes were prepared this way [67, 84] (equations 54 and 55)... 

The mechanism of the indolization of aniline 5 with methylthio-2-propanone 6 is illustrated below. Aniline 5 reacts with f-BuOCl to provide A-chloroaniline 9. This chloroaniline 9 reacts with sulfide 6 to yield azasulfonium salt 10. Deprotonation of the carbon atom adjacent to the sulfur provides the ylide 11. Intramolecular attack of the nucleophilic portion of the ylide 11 in a Sommelet-Hauser type rearrangement produces 12. Proton transfer and re-aromatization leads to 13 after which intramolecular addition of the amine to the carbonyl function generates the carbinolamine 14. Dehydration of 14 by prototropic rearrangement eventually furnishes the indole 8. 

The mechanism of the Feist-Benary reaction involves an aldol reaction followed by an intramolecular 0-alkylation and dehydration to yield the furan product. In the example below, ethyl acetoacetate (9) is deprotonated by the base (B) to yield anion 10 this carbanion reacts with chloroacetaldehyde (8) to furnish aldol adduct 11. Protonation of the alkoxide anion followed by deprotonation of the [i-dicarbonyl in 12 leads to... 

Forty years after the initial proposal, Sweet and Fissekis proposed a more detailed pathway involving a carbenium ion species. According to these authors the first step involved an aldol condensation between ethyl acetoacetate (6) and benzaldehyde (5) to deliver the aldol adduct 11. Subsequent dehydration of 11 furnished the key carbenium ion 12 which was in equilibrium with enone 13. Nucleophilic attack of 12 by urea then delivered ureide 14. Intramolecular cyclization produced a hemiaminal which underwent dehydration to afford dihydropyrimidinone 15. These authors demonstrated that the carbenium species was viable through synthesis. After enone 13 was synthesized, it was allowed to react with N-methyl urea to deliver the mono-N-methylated derivative of DHPM 15. 

Coumarin formation proceeds via an intramolecular attack by enol ester 9 on the ketone to give 10. Dehydration of 10 then affords coumarin 11. It has been observed that coumarins are favored when higher order homologs of acetic anhydride and their corresponding salts such as propionic anhydride/sodium propionate and butyric anhydride/ sodium butyrate are used. 

In the reaction of 4-methoxybut-3-en-2-one with amines 223 and 226, the products of methoxy group substitution 224 and 227 were isolated. Under subsequent intramolecular dehydration these products give quinoline derivatives 225 (50°C, H2SO4, 15 min, yield 25%) (61GEP1017613) and 228 (0°C, 35% KOH, 10 min, yield 88.7%) [65NEP6401199 80MI2]. 

The mechanism for the conversion of the A -oxide (94) to the o-methylaminophenylquinoxaline (96) involves an initial protonation of the A -oxide function. This enhances the electrophilic reactivity of the a-carbon atom which then effects an intramolecular electrophilic substitution at an ortho position of the anilide ring to give the spiro-lactam (98). Hydrolytic ring cleavage of (98) gives the acid (99), which undergoes ready dehydration and decarboxylation to (96), the availability of the cyclic transition state facilitating these processes. ... 

The next step is an intramolecular aldol reaction leading to closure of a six-membered ring. Subsequent dehydration yields the bicyclic enone 4 ... 

A closely related oxygenated heterocyclic system devoid of acidic groups interestingly shows quite different biological activity. Thus, condensation of the benzofuran hydroxyketone 66 with ethyl thiomethyl acetate (67) probably proceeds initially by formation of the acylation product 68. Intramolecular dehydration leads to formation of a pyran ring. There is thus obtained the hypo-cholesterolemic agent timefurone (69) [14],... 

The final two stages are very straightforward. Oxidative scission of the C3-C5 double bond in 6 with ozone provides triketone 5 which, without purification, is subjected to a base-induced intramolecular aldol/dehydration reaction. The crystalline product obtained from this two-step sequence (45 % overall yield) was actually an 85 15 mixture of ( )-progesterone and a diastereomeric substance, epimeric at C-17. Two recrystallizations afforded racemic progesterone [( )-(1)] in diastereomerically pure form. 

The mechanism of the condensation in Part D probably involves thioformylation of the metallated isocyanoacetate followed by intramolecular 1,1-addition of the tautomeric enethiol to the isonitrile. This thi2izole synthesis is analogous to the formation of oxazoles from acylation of metallated isonitriles with acid chlorides or anhydrides. " Interestingly, ethyl formate does not react with isocyanoacetate under the conditions of this procedure. Ethyl and methyl isocyanoacetate have been prepared in a similar manner by dehydration of the corresponding N-formylglycine esters with phosgene and trichloromethyl chloroformate, respectively. The phosphoryl chloride method described here was provided to the submitters by Professor U. Schollkopf and is based on the procedure of Bohme and Fuchs. The preparation of O-ethyl thioformate in Part C was developed from a report by Ohno, Koi/.uma, and Tsuchihaski. " ... 

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