Intermediates addition-elimination reactions

Hydrolysis. Esters are cleaved (hydroly2ed) into an acid and an alcohol through the action of water. This hydrolysis is cataly2ed by acids or bases. The mechanistic aspects of ester hydrolysis have received considerable attention and have been reviewed (16). For most esters only two reaction pathways are important. Both mechanisms involve a tetrahedral intermediate and addition-elimination reactions i7i7... 

Chloroth1ete 1,1-dioxide is a potentially useful intermediate for the preparation of other 3-substituted thiete 1,1-dioxides via addition-elimination reactions. 

Because of thetr electron deficient nature, fluoroolefms are often nucleophihcally attacked by alcohols and alkoxides Ethers are commonly produced by these addition and addition-elimination reactions The wide availability of alcohols and fliioroolefins has established the generality of the nucleophilic addition reactions The mechanism of the addition reaction is generally believed to proceed by attack at a vinylic carbon to produce an intermediate fluorocarbanion as the rate-determining slow step The intermediate carbanion may react with a proton source to yield the saturated addition product Alternatively, the intermediate carbanion may, by elimination of P-halogen, lead to an unsaturated ether, often an enol or vinylic ether These addition and addition-elimination reactions have been previously reviewed [1, 2] The intermediate carbanions resulting from nucleophilic attack on fluoroolefins have also been trapped in situ with carbon dioxide, carbonates, and esters of fluorinated acids [3, 4, 5] (equations 1 and 2)... 

The nucleophilic attack of nitrogen bases leads to a variety of products as the result of addition or addition-elimination reactions The regioselectivity resembles that of attack by alcohols and alkoxides an intermediate carbanion is believed to be involved In the absence of protic reagents, the fluorocarbanion generated by the addition of sodium azide to polyfluonnated olefins can be captured by carbon dioxide or esters of fluonnated acids [J 2, 3] (equation I)... 

Fluoride ion produced from the nucleophilic addition-elimination reactions of fluoroolefins can cataly7e isomerizations and rearrangements The reaction of per fluoro-3-methyl-l-butene with dimethylamine gives as products 1-/V,/Vdimeth-ylamino-1,1,2,2,4,4,4-heptafluoro-3-trifluoromethylbutane, N,W-dimetliyl-2,2,4,4,4-pentafluoro 3 trifluoromethylbutyramide, and approximately 3% of an unidentified olefin [10] The butylamide results from hydrolysis of the observed tertiary amine, and thus they share a common intermediate, l-Al,A -dimethylamino-l,l 24 44-hexafluoro-3-trifluoromethyl-2-butene, the product from the initial addition-elimination reaction (equation 4) The expected product from simple addition was not found... 

A 1,8-naphthyridine, nalidixic acid (39), shows clinically useful antibacterial activity against Gram-negative bacteria as such, the drug is used in the treatment of infections of the urinary tract. Condensation of ethoxymethylenemalonate with 2-amino-6-methylpyridine (36) proceeds directly to the naphthyri-dine (38) the first step in this transformation probably involves an addition-elimination reaction to afford the intermediate, 37. W-Ethylation with ethyl iodide and base followed by saponification then affords nalidixic acid (39). 

Progressive departure from the fundamental structure of the lead agent cimetidine led to the anti ulcer agent oxmetidine (47). The synthesis involves -methylation (CH3I) of the 2-thiouracil intermediate and is followed by an addition-elimination reaction with 2-(5-methyl-4-imidazolylmethylthio) ethylamine to give oxmetidine (47). ... 

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... 

Finally, Cristau and coworkers have reported on a quite efficient preparation of triphenylphosphine oxide (Figure 2.13) by a similar addition-elimination reaction of red phosphorus with iodobenzene in the presence of a Lewis acid catalyst followed by oxidation of an intermediate tetraarylphosphonium salt.42 This approach holds the potential for the preparation of a variety of triarylphosphine oxides without proceeding through the normally used Grignard reagent. Of course, a variety of approaches is available for the efficient reduction of phosphine oxides and quaternary phosphonium salts to the parent phosphine, including the use of lithium aluminum hydride,43 meth-ylpolysiloxane,44 trichlorosilane,45 and hexachlorodisilane.46... 

At higher temperatures retro-Diels-Alder reaction may also occur in the opposite sense to addition, as in the reaction of methyl pyrrole-1-carhoxylate with dimethyl acetylenedicarboxylate at 200°, which affords acetylene and the pyrrole triester (56). The decomposition of the suspected intermediate Diels-Alder adduct (11) at 170° has been separately established. Compounds 19 and 20 are intermediates in similar addition-elimination reactions leading to pyrrole-l,3,4-triesters, in which removal of acetylene from the system makes the reaction sequence effectively irreversible. 

Another interesting example of Ugi-Michael process is represented by the synthesis of pyridones 145 (Fig. 28), which originate from an intramolecular domino addition-elimination reaction of the active methylene group proceeding through intermediate 144 [120]. 

Carbanions play critical roles in a wide variety of reaction pathways. As stated in the Introduction, this chapter will not focus on the synthetic utility of carbanions, but will instead focus on their mechanistic significance. In this section, a sample of important reaction mechanisms that involve transient or relatively short-lived car-banion intermediates will be introduced. As you will see, the key element in these mechanisms is the ability to form a carbanion that is reasonably stable, and often the kinetics of the reactions are dominated by carbanion stability. The role of carbanion intermediates in elimination reactions will be presented in some detail as a way to illustrate some of the methods that have been developed to probe for carbanion intermediates in reaction mechanisms. Other processes including additions and rearrangement reactions will be presented in less detail, but the role of carbanion stability in these reactions will be outlined. 

A compound that includes an aminopyrimidine ring as well as the quaternary salt present in thiamine shows preferential inhibition of absorption of that co-factor by coccidia parasites over uptake by vertebrates. The compound is thus used in poultry where coccidiosis is an economically important disease. Condensation of ethoxymethylenemalononitrile (42-1) with the amidine (42-2) leads to the aminopyrimidine (42-4), probably via the intermediate addition-elimination intermediate (42-3). The nitrile group is then reduced to the methylamino derivative (42-5) by means of hthium aluminum hydride. Exhaustive methylation, for example by reaction with formaldehyde and formic acid, followed by methyl iodide leads to the quaternary methiodide (42-6). The quaternary salt is then displaced by bromine, and the resulting benzyhc-like cylic halide (42-7) is displaced by 2-picoline (42-8). There is thus obtained amprolium (42-9) [43]. 

Unsaturated fluorinated compounds are fundamentally different from those of hydrocarbon chemistry. Whereas conventional alkenes are electron rich at the double bond, fluoroal-kenes suffer from a deficiency of electrons due to the negative inductive effect. Therefore, fluoroalkenes react smoothly in a very typical way with oxygen, sulfur, nitrogen and carbon nucleophiles.31 Usually, the reaction path of the addition or addition-elimination reaction goes through an intermediate carbanion. The reaction conditions decide whether the product is saturated or unsaturated and if vinylic or allylic substitution is required. Highly branched fluoroalkenes, obtained from the fluoride-initiated ionic oligomerization of tetrafluoroethene or hexafluoropropene, are different and more complex in their reactions and reactivities. 

CAi90) 123047). The isolation of 2-chloro-5-formylpyrrole from the Vilsmeier-Haack formylation of 2-bromopyrrole (75JOC3161) can be rationalized in terms of an addition-elimination reaction of the intermediate azafulvenium cation (Scheme 82). Displacement... 

In the case of certain diolefins, the palladium-carbon sigma-bonded complexes can be isolated and the stereochemistry of the addition with a variety of nucleophiles is trans (4, 5, 6). The stereochemistry of the addition-elimination reactions in the case of the monoolefins, because of the instability of the intermediate sigma-bonded complex, is not clear. It has been argued (7, 8, 9) that the chelating diolefins are atypical, and the stereochemical results cannot be extended to monoolefins since approach of an external nucleophile from the cis side presents steric problems. The trans stereochemistry has also been attributed either to the inability of the chelating diolefins to rotate 90° from the position perpendicular to the square plane of the metal complex to a position which would favor cis addition by metal and a ligand attached to it (10), or to the fact that methanol (nucleophile) does not coordinate to the metal prior to addition (11). In the Wacker Process, the kinetics of oxidation of olefins suggest, but do not require, the cis hydroxypalladation of olefins (12,13,14). The acetoxypalladation of a simple monoolefin, cyclohexene, proceeds by trans addition (15, 16). 

Another more efficient catalytic version of the reaction consists of the interaction of ketones with chiral amines [6] to form enolate-like intermediates that are able to react with electrophilic imines. It has been postulated that this reaction takes place via the catalytic cycle depicted in Scheme 33. The chiral amine (130) attacks the sp-hybridized carbon atom of ketene (2) to yield intermediate (131). The Mannich-like reaction between (131) and the imine (2) yields the intermediate (132), whose intramolecular addition-elimination reaction yields the (5-lactam (1) and regenerates the catalyst (130). In spite of the practical interest in this reaction, little work on its mechanism has been reported [104, 105]. Thus, Lectka et al. have performed several MM and B3LYP/6-31G calculations on structures such as (131a-c) in order to ascertain the nature of the intermediates and the origins of the stereocontrol (Scheme 33). According to their results, conformations like those depicted in Scheme 33 for intermediates (131) account for the chiral induction observed in the final cycloadducts. 

The mechanism of these displacement processes presumably involves a metal-assisted addition-elimination reaction, in which the metal ion stabilises the charge in the intermediate (Fig. 8-33). A number of useful synthetic applications of this methodology are... 

As mentioned before, alkyl radicals and acyl radicals have a nucleophilic character therefore, radical alkylation and acylation of aromatics shows the opposite reactivity and selectivity to polar alkylation and acylation with the Friedel-Crafts reaction. Thus, alkyl radicals and acyl radicals do not react with anisole, but may react with pyridine. Eq. 5.1 shows the reaction of an alkyl radical with y-picoline (1). The nucleophilic alkyl radical reacts at the 2-position of y-picoline (1), where electron density is lower than that of the 3-position. So, 2-alkyl-4-methylpyridine (2) is obtained with complete regioselectivity. When pyridine is used instead of y-picoline, a mixture of 2-alkylpyridine and 4-alkylpyridine is obtained. Generally, radical alkylation or radical acylation onto aromatics is not a radical chain reaction, since it is just a substitution reaction of a hydrogen atom of aromatics by an alkyl radical or an acyl radical through the addition-elimination reaction. Therefore, the intermediate adduct radical (a complex) must be rearomatized to form a product and a hydrogen atom (or H+ and e ). Thus, this type of reactions proceeds effectively under oxidative conditions [1-6]. 

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