Displacement addition-elimination

The enamino ketone (49) was reported to give no identifiable products on reaction with N,N-dimethyl carbamoyl chloride 63). However, reaction of (49) with N,N-diethyl carbamoyl chloride in refluxing chlorobenzene gave the N-(3-diethyl-amino-5,5-dimethylcyclohex-2-en-1 -ylidene)pyrrolidinium salt, isolated as the perchlorate. The latter must have been formed as outlined in Scheme I, involving initial O carbamoylation followed by an addition-elimination reaction to give 138 cation which can react with diethylamino anion by a further addition-elimination displacement to give the product 46). 

Carbanions can take part in most of the main reaction types, e.g. addition, elimination, displacement, rearrangement, etc. They are also involved in reactions, such as oxidation, that do not fit entirely satisfactorily into this classification, and as specific—ad hoc—intermediates in a number of other processes as well. A selection of the reactions in which they participate will now be considered many are of particular synthetic utility, because they result in the formation of carbon-carbon bonds. 

The reaction of 2-polyfluoroalkylchromones (e.g., 323) with l,3,3-dimethyl-3,4-dihydroisoquinolines (e.g., 324) gave zwitterionic 6,7-dihydrobenzo[ ]quinolizinium compounds such as 326 (Scheme 70). The mechanism proposed for this transformation involves an addition-elimination displacement of the chromane heterocyclic oxygen by the enamine tautomer of the dihydroisoquinoline, followed by intramolecular cyclization of the intermediate 325 <20030L3123>. 

Carbanions take part in the usual types of reactions, viz., addition, elimination, displacement, oxidation and rearrangement. 

The 3-substituents in 3-nitro- and 3-phenylsulfonyl-2-isoxazolines were displaced by a variety of nucleophiles including thiolate, cyanide and azide ions, ammonia, hydride ions and alkoxides. The reaction is pictured as an addition-elimination sequence (Scheme 54) (72MI41605, 79JA1319, 78JOC2020). 

The addition-elimination mechanism uses one of the vacant n orbitals for bonding interaction with the nucleophile. This permits addition of the nucleophile to the aromatic ring without displacement of any of the existing substituents. If attack occurs at a position occupied by a potential leaving group, net substitution can occur by a second step in which the leaving group is expelled. 

The addition-elimination mechanism involves two intermediates, a chlorophenyl anion and benzyne. A simple displacement mechanism can be ruled out because reaetion of ort/io-chlorotoluene gives not only ort/io-methylphenol but also meto-methylphenol. 

The low structural specificity in the local anesthetic sell cs is perhaps best illustrated by phenacalne (91), a local an-I -.lhetic that lacks not only the traditional ester or amide func-I ion but the basic aliphatic nitrogen as well. First prepared at I lie turn of the century, a more recent synthesis starts by con-ili iusation of p-ethoxyaniline with ethyl orthoacetate to afford I he imino ether (90), Reaction of that intermediate with a sec-I liil mole of the aniline results in a net displacement of ethanol, iiobably by an addition-elimination scheme. There is thus ob-I.lined the amidine, 91, phenacalne. 

Another entry into the anti ulcer sweepstakes is etinfidine (50). It is synthesized by displacement of halide from 4-chloromethyl-5-methylimidazole (4 ) with substituted thiol The latter is itself made from thiourea analogue by an addition-elimination reaction with cysteamine 52. °... 

Cancer chemothCTapeutic agents as a rule poorly penetrate the blood brain barrier. Brain tumors are thus not readily treatable by chemotherapy. Diaziquone (at one time known as AZQ) is an exception to this generalization. Treatment of chloranil (213) with the anion from urethane gives intermediate 214, probably by an addition elimination scheme. Displacement of the remaining halogen with aziridine yields diaziquone (215) [.55J. 

The majority of analgesics can be classified as either central or peripheral on the basis of their mode of action. Structural characteristics usually follow the same divisions the former show some relation to the opioids while the latter can be recognized as NSAlD s. The triamino pyridine 17 is an analgesic which does not seem to belong stmcturally to either class. Reaction of substituted pyridine 13 (obtainable from 12 by nitration ) with benzylamine 14 leads to the product from replacement of the methoxyl group (15). The reaction probably proceeds by the addition elimination sequence characteristic of heterocyclic nucleophilic displacements. Reduction of the nitro group with Raney nickel gives triamine 16. Acylation of the product with ethyl chlorofor-mate produces flupirtine (17) [4]. 

The net effect of the addition/elimination sequence is a substitution of the nucleophile for the -Y group originally bonded to the acyl carbon. Thus, the overall reaction is superficially similar to the kind of nucleophilic substitution that occurs during an Sn2 reaction (Section 11.3), but the mechanisms of the two reactions are completely different. An SN2 reaction occurs in a single step by backside displacement of the Leaving group a nucleophilic acyl substitution takes place in two steps and involves a tetrahedral intermediate. 

Nucleophilic displacement of bromide from 5-acetyl-10-bromo-5//-dibenz[7>,/]azepine (41) by alkoxide,132 and by cyanide ion in dimethylformamide,212 has been noted. However, replacement of bromide by cycloalkylamines (e.g., piperidine) to give the 10-cycloalkylamino derivatives. e.g. 44, is best accomplished in the presence of potassium ferf-butoxide, a result which suggests that the aminodebromination proceeds via an elimination-addition (EA) pathway involving an azepyne intermediate 43 (see Section 3.2.1.5.7.) rather than by the more usual addition-elimination (AF.) mechanism.118... 

Normally, reactive derivatives of sulfonic acids serve to transfer electrophilic sulfonyl groups259. The most frequently applied compounds of this type are sulfonyl halides, though they show an ambiguous reaction behavior (cf. Section III.B). This ambiguity is additionally enhanced by the structure of sulfonyl halides and by the reaction conditions in the course of electrophilic sulfonyl transfers. On the one hand, sulfonyl halides can displace halides by an addition-elimination mechanism on the other hand, as a consequence of the possibility of the formation of a carbanion a to the sulfonyl halide function, sulfenes can arise after halide elimination and show electrophilic as well as dipolarophilic properties. 

Direct nucleophilic displacement of halide and sulfonate groups from aromatic rings is difficult, although the reaction can be useful in specific cases. These reactions can occur by either addition-elimination (Section 11.2.2) or elimination-addition (Section 11.2.3). Recently, there has been rapid development of metal ion catalysis, and old methods involving copper salts have been greatly improved. Palladium catalysts for nucleophilic substitutions have been developed and have led to better procedures. These reactions are discussed in Section 11.3. 

Displacement of halogen by ammonia leads to the corresponding amine, probably by an addition-elimination mechanism. There is thus obtained amquinsin (10), a hypotensive agent. Formation of the Shiff base of amquinsin with veratraldehyde gives leniquinsin (11),5 possibly a prodrug. 

Condensation of aminopyrazole 116 with ethoxy-methylene malonic ester gives the product of addition-elimination (117), which is then cyclized to the piperidone by heating in diphenyl ether. The product tautomerizes spontaneously to the hydroxypyridine 118. The hydroxyl group is then converted to the chloro derivative by means of phosphorus oxychloride (119). Displacement of halogen by n-butylamine gives... 

Reaction between 2,8-dichloro derivative 115 and sodium azide in DMSO does not lead to 3,9-diazido derivative 116 expected by direct displacement. Instead, the reaction gives isomeric 3,9-diazide 117, presumably by an addition-elimination sequence <1995JOC6110, 1995HAC391>. Compound 116 is available by treatment of tetra-nitro derivative 90 (z-TACOT) with LiN3 in DMSO (Scheme 11) <1967JA2626>. 

Such nucleophilic displacements are likely to be addition-elimination reactions, whether or not radical anions are also interposed as intermediates. The addition of methoxide ion to 2-nitrofuran in methanol or dimethyl sulfoxide affords a deep red salt of the anion 69 PMR shows the 5-proton has the greatest upfield shift, the 3- and 4-protons remaining vinylic in type.18 7 The similar additions in the thiophene series are less complete, presumably because oxygen is relatively electronegative and the furan aromaticity relatively low. Additional electronegative substituents increase the rate of addition and a second nitro group makes it necessary to use stopped flow techniques of rate measurement.141 In contrast, one acyl group (benzoyl or carboxy) does not stabilize an addition product and seldom promotes nucleophilic substitution by weaker nucleophiles such as ammonia. Whereas... 

For example, in the instance of 9-chloroacridine, the attachment of the halogen (leaving group) at a suitably electrophilic carbon site allows the occurrence of a replacement reaction, presumably occurring via an addition-elimination procedure for phosphorus attachment, followed by the common nucleophilic displacement (ester cleavage) of the Michaelis-Arbuzov process (Figure 6.1).4... 

As we have seen (Section 4, p. 191) the range of effective molarities associated with ring-closure reactions is very much greater than that characteristic of intramolecular general acid-base catalysis the main classification is therefore in terms of mechanism. By far the largest section (I, Tables A-D) gives EM s for intramolecular nucleophilic reactions. These can be concerted displacements (mostly at tetrahedral carbon), stepwise displacements (mostly addition-elimination reactions at trigonal carbon), or additions, and they have been classified in terms of the nucleophilic and electrophilic centres. 

For neutral nucleophiles (e.g. amines, alcohols, water) there is much evidence that the addition-elimination mechanism depicted in equation 1 fits very well most of the intermolecular and intramolecular nucleophilic displacements involving nitro-activated aromatic substrates1. 

In the first step, 01 attacks P9 and displaces Cl 10. After deprotonation of N3, a carbocation at C2 (stabilized by resonance with N4) is formed. Addition-elimination then gives the product. An alternative and reasonable mechanism would have C7 attack C2 before the C2-01 bond cleaves (addition-elimination type mechanism), but the conventional wisdom is that the reaction proceeds through the nitrlium ion intermediate. 

Although the reaction responsible for the generation of the hydride is not specified, it is assumed that it arises from a disproportionation of iron carbonyl complexes. The hydride presumably adds after ir-complexing to form the c-bonded complex which then splits out the metal hydride in either direction. The ir-complexed olefin may then be displaced by another olefin or undergo another hydride addition-elimination sequence. The second path involves olefin complexing with the deficient Fe(CO)3 species and formation of a jr-allyliron hydride intermediate ... 

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