Displacement enol chloride

Considerable work has been devoted to the search for agents devoid of the sedative effect that accompanied some of the earlier antihistamines. One stratagem for achieving that comprises adding a function that will diminish the likelihood that the dmg will cross the blood-brain barrier. The antistamine emedastine (41-3), for example, incorporates a terminal ether that can be potentially metabolized to a carboxylic acid. Alkylation of the imidazole (41-1), available from imidazol-2-one by reaction with phosphoms oxychloride, with the chloroether (41-2) leads to a reaction on nitrogen to afford (41-3). Displacement of the enol chloride in that intermediate with A-methyl-l-4-diazepine (41-4) leads to emedastine (41- 5) [43]. 

Dihydralazine (67-3) is the less important of the two phthalazine antihypetensive agents its preparation is however recorded first because of its simplicity. Thus, reaction of phthaUiydrazide (67-1) with phosphorus oxychloride leads to the by now very famihar conversion of the amide functions to enol chlorides (67-2). The displacement of halogen by hydrazine leads directly to the antihypertensive agent dihydralazine (67-3) [76]. 

Incorporation of a piperazine function on the heterocyclic ring leads to a compound in which bronchodilator activity predominates. Treatment of the amino-amide (73-1) with trimethyl orthoformate provides the additional carbon atom for the formation of the quinazolone ring in (73-2). Reaction with phosphoms oxychloride in effect converts the ring to its aromatic form (73-3) by locking in the former amide as an enol chloride. Displacement of the halogen with the isobutyryl urethane (73-4) from piperazine affords piquizil (73-5) [82]. 

The particularly good activity against protein kinases of a-aminoquinazoline derivatives is borne out by their activity against both in vitro and in vivo models of human tumors. The examples that follow are but two of a number of compounds from this structural class that have emerged from the focus that has been devoted to this stmctural class. Nitration of the benzoate (78-1) with nitric acid affords the nitro derivative. Hydrogenation converts this to the anthrandate (78-2). In one of the standard conditions for forming quinazolones, that intermediate is then treated with ammonium formate to yield the heterocycle (78-3). Reaction of this last product with phosphorus oxychloride leads to the corresponding enol chloride (78-4). Condensation of this last intermediate with meta-iodoanUine (78-5) leads to displacement of chlorine and the consequent formation of the aminoquinazoline... 

A much less promising cyclisation gives the biologically patterned insecticide permethrin5 17. The enolate of the ester in the starting material 15 must cyclise by displacement of chloride at a tertiary centre. Cyclisation to form three-membered rings can be remarkably favourable. 

The ethoxide is not incorporated into the product but appears in the rate expression. Its role must be as base and there is only one set of enolizable protons. We start by making the enolate of the chloroketone. Then we can attack the aldehyde with the enolate and finally close the epoxide ring vith a nucleophilic displacement of chloride ion. 

However, 4-chlorobenzoyl-CoA dehalogenase is also a member of the enoyl-CoA hydratase superfamily. The mechanism of its reaction involves nucleophilic aromatic substitution in which an active site Asp adds to the 4-position of the benzoyl ring to necessarily form a Meisenheimer complex this Meisenheimer complex is an analog of a thioester enolate anion. Although the Meisenheimer complex cannot be observed for displacement of chloride from 4-chlorobenzoyl-CoA due to the rate constants for formation and decomposition of the intermediate, the Meisen-... 

Deprotonation of the a-carbon of the ketone by ethoxide to make an enolate whose carbon does an Sjj2 displacement of chloride from chloroacetonitrile, followed by intramolecular nucleophilic formation of the epoxide ring in structure E. 

An example of this displacement between a pyridine nitrogen atom and an aryl halide is shown in Scheme 21. When 2-pyridyl acetates 138 were C-acylated with 2-halobenzoyl chlorides, the enolized products 139 resulting from the reaction suffered an intramolecular nucleophilic attack of the pyridine nitrogen atom onto the ipso-position to give benzo[c]quinolizinium salts 140 as intermediates. Loss of HC1 gas from 140 afforded benzo[c]quinolizine derivatives 141 <2002JOC2082>. 

The Sonogashira reaction is of considerable value in heterocyclic synthesis. It has been conducted on the pyrazine ring of quinoxaline and the resulting alkynyl- and dialkynyl-quinoxalines were subsequently utilized to synthesize condensed quinoxalines [52-55], Ames et al. prepared unsymmetrical diynes from 2,3-dichloroquinoxalines. Thus, condensation of 2-chloroquinoxaline (93) with an excess of phenylacetylene furnished 2-phenylethynylquinoxaline (94). Displacement of the chloride with the amine also occurred when the condensation was carried out in the presence of diethylamine. Treatment of 94 with a large excess of aqueous dimethylamine led to ketone 95 that exists predominantly in the intramolecularly hydrogen-bonded enol form 96. 

Acylation of A-hydroxy-2-phenylbutyramidine (112-1) with 3-chloropropionyl chloride in the absence of an added base proceeds as might be expected to give the product (112-2) from acylation on the more basic nitrogen. Heating this compound leads to the formation of the oxadiazole (112-3) almost certainly via the enol tautomer of the amide. Displacement of the terminal chlorine with diethylamine leads to the tertiary amine and thus proxazole (112-4) [123], a compound that is said to exhibit antispasmodic activity. 

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