Enolate compounds nucleophilic substitution

If the anodic oxidation of N-alkylanilines is performed in the presence of nucleophiles like enol ethers, nucleophilic substitution in the of-position to nitrogen by the enol ether can be observed in low yields. The electrophilic intermediate is the N-aryl iminium ion or the N-aryl imine after loss of two electrons and one or two protons. These intermediates add to the enol ether to give acetals (up to 26%) as addition products, or the first addition step is followed by an electrophilic aromatic substitution to form tetrahydroqui-nolines (13-39%) [47]. It should be noted at this point that better results for the nucleophilic a-substitution to nitrogen can be obtained with N,N-dialkylanilines (see next subsection). Optimum results, however, are obtained with N-acylated compounds via the intermediate N-acyl iminium ions (see Ref. 8). 

A classical reaction leading to 1,4-difunctional compounds is the nucleophilic substitution of the bromine of cf-bromo carbonyl compounds (a -synthons) with enolate type anions (d -synthons). Regio- and stereoselectivities, which can be achieved by an appropiate choice of the enol component, are similar to those described in the previous section. Just one example of a highly functionalized product (W.L. Meyer, 1963) is given. 

To obtain this compound the key step consisted in the epimerization of the C-5 in compound 6. This was acomplished by triflation of the alcohol 6 and nucleophilic substitution of the triflate by a large excess of tetrabutylammonium acetate in dichloromethane. A controlled (4 °C, 3 h) basic methanolysis of the enol benzoate led to the keto-ester 11" whose hydroxyl functions at C-4 and C-6 were simultaneously deprotected under acidic conditions to furnish 12. Finally a Zemplen deprotection of the 5-acetoxy group led to 13 obtained in five steps and 11% overall yield from 6 (figure 4). 

Lewis acids are also effective to induce the nucleophilic substitution of allylic nitro compounds. These compounds react with allyltrimethylsilane,28 silyl enolates,28 or cy-anotrimethylsilane29 in the presence of SnCl4 to give substitution products, respectively (see Eqs. 7.24-7.26). 

The essential feature of enamines is that they are nitrogen analogues of enols and behave as enolate anions. They effectively mask a carbonyl function while activating the compound towards nucleophilic substitution. 

In the reactions with phosphonio-a-methoxycarbonyl-alkanides, the products of type 261 derived from 1,3-cycloaddition can rearrange to the tautomeric lif-pyrazolo-triazole (87MI2). The reaction of 3-diazopyra-zoles and 3-diazoindazole with acyl-substituted phosphonium ylides led to pyrazolo-triazine and indazolo-triazine derivatives 266 instead of the expected triazole compounds (8IJHC675). In this case, the ylides, which can exist as phosphonium enolates, possess nucleophilic and electrophilic centers in a /8-relationship, giving [7 + 2] or [11 -I- 2]cycloaddition reactions. With dimethylsulfonio-a-aroyl-methanides, very complex, temperature-dependent mixtures were obtained, in some cases with sulfur retention (87MI3). 

The introduction of a heteroelement Z on the -position of an ester functionality is possible by trapping an enolate with a suitable Z—Cl compound, namely via nucleophilic substitution at the Z atom. The heteroelement Z could correspond to Si, , P, S etc. 

Examples of the preparation of cyclopropanes by intramolecular nucleophilic substitution are illustrated in Scheme9.17. The first example is a synthesis of [l.l.ljpro-pellane, which yields the product in acceptable yields, despite the high strain and poor stability of this compound [66]. The second and third examples illustrate the remarkable ease with which 3-halopropyl ketones cyclize to yield cyclopropanes instead of cyclic, five-membered enol ethers or ketones. Similarly, carbamates of 2-haloethylglycine esters do not undergo intramolecular N- or O-alkylation on treatment with bases, but yield cyclopropanes instead [67, 68]. Some nucleophiles can undergo Michael addition to 3-halomethyl acrylates faster than direct Sn2 reaction, to yield cyclopropanes by cyclization of the intermediate enolates (fourth example, Scheme9.17) [69]. 

Quite recently Gitis [42] isolated a number of coloured products formed by polynitro compounds with acetone in the presence of sodium hydroxide. The author, like Reitzenstein and Stamm, postulated that it was the enol form of acetone that reacted with a nitro compound, products of nucleophilic substitution of the type described by Meisenheimer [36-38] (p. 202), being formed ... 

The array of dienophiles amenable to these hetero Diels-Alder reactions is not limited to enol ethers and enamines since allylsilanes and simple alkenes have also been successfully employed [370, 371]. More recently, it has been shown that methoxy allenes such as 4-41 undergo formation of 6H-l,2-oxazines 4-43 upon cycloaddition to nitrosoalkenes such as 4-34 and subsequent tauto-merisation of the intermediate exo-methylene compound 4-42 (Fig. 4-9) [372, 373]. In these studies, 4-43 proved to be a versatile synthetical intermediate allowing oxidative demethylation or reductive removal of the methoxy group as well as nucleophilic substitutions after the generation of an azapyrylium ion [372 - 374]. Furthermore, ring contraction reactions of these oxazines leading to pyrroles [373] and y-lactames [375] are known. 

Tfce preferred synthetic route to these important intermediates is the Mannich reaction (Chapter 27), The compound is stored as the stable Mannich base and the unstable enone released by elimination of a tertiary amine with mild base, The same conditions are right for this elimination and for conjugate addition, Thus the aw-methylene compounds can be formed in the flask for immediate reaction with the enol(ate) nucleophile, The overall reaction from (3-amino carbonyl to 1,5-dicarbonyl appears to be a substitution but the actual mechanism involves elimination and conjugate addition,... 

Among common carbon-carbon bond formation reactions involving carbanionic species, the nucleophilic substitution of alkyl halides with active methylene compounds in the presence of a base, e. g., malonic and acetoacetic ester syntheses, is one of the most well documented important methods in organic synthesis. Ketone enolates and protected ones such as vinyl silyl ethers are also versatile nucleophiles for the reaction with various electrophiles including alkyl halides. On the other hand, for the reaction of aryl halides with such nucleophiles to proceed, photostimulation or addition of transition metal catalysts or promoters is usually required, unless the halides are activated by strong electron-withdrawing substituents [7]. Of the metal species, palladium has proved to be especially useful, while copper may also be used in some reactions [81. Thus, aryl halides can react with a variety of substrates having acidic C-H bonds under palladium catalysis. 

Ambident anions are mesomeric, nucleophilic anions which have at least two reactive centers with a substantial fraction of the negative charge distributed over these cen-ters ) ). Such ambident anions are capable of forming two types of products in nucleophilic substitution reactions with electrophilic reactants . Examples of this kind of anion are the enolates of 1,3-dicarbonyl compounds, phenolate, cyanide, thiocyanide, and nitrite ions, the anions of nitro compounds, oximes, amides, the anions of heterocyclic aromatic compounds e.g. pyrrole, hydroxypyridines, hydroxypyrimidines) and others cf. Fig. 5-17. 

As it is well known, nucleophilic substitution of a C-X bond, one of the key synthetic reactions with aliphatic compounds is severely limited with aromatic derivatives, where it occurs thermally only with electron-withdrawing substituted compounds and/or under severe conditions. Alternatives include time honored reactions involving the phenyl radical generated by decomposition of diazonium salts after a reductive step, such as the Meerwein and the Gomberg-Bachmann reactions, as well as the (often photoinitiated) SrnI reaction, where a (usually weak, e.g. carbon-iodine) bond is cleaved after monoelectronic reduction to give an aryl radical as the active inter-mediate that adds to an enolate, cyanide or other nucleophiles (and thus again with an aryl radical as the key intermediate. Scheme S). ... 

Avoidance by choice of oxygenated starting materials Oxidation through Lithiation and Ort/ro-Lithiation Hydroxylation of Pyridines by ortho-Lithiation Synthesis of Atpenin B Introducing OH by Nucleophilic Substitution Part II - Oxidation of Enols and Enolates Direct Oxidation without Formation of a Specific Enol Selenium dioxide Nitrosation with nitrites Nitrosation with stable nitroso compounds Indirect Oxidation with Formation of a Specific Enol Enone Formation Pd(II) oxidation ofsilyl enol ethers Bromination of enols in enone formation Sulfur and selenium compounds in enone formation Asymmetric Synthesis of Cannabispirenones... 

Some typical reactions of 1,1 -difluoroethene with nucleophiles are summarized in Scheme 2.18. Alkoxides [3], trialkylsilyl anion [4], ester enolates [5], and diphenylphosphinyl anion [6] attack the gem-difluorinated carbon of 5. However, it is noteworthy that nucleophilic substitution and proton abstraction are in some cases competitive, and thus s -butyl lithium abstracts the (3 -vinylic proton predominantly to generate vinyllithium. The lithium species can be trapped with an aldehyde, providing difluoroallyl alcohol, which is then hydrolyzed to a, (3-unsaturated carboxylic ester (11) [ 7 ] (Scheme 2.19). Some synthetically useful examples are shown in Schemes 2.20 and 2.21. Tetrathiafulvalene derivative (14) is prepared from difluorinated derivative (13) [8]. An elegant intramolecular version was demonstrated by Ichikawa, which provided a range of cyclized compounds (17), including dihydrofurans, thiophenes, pyrroles, and cyclopentenes, and also corresponding benzo derivatives (20) [2]. 

Danishefsky s synthesis (Scheme 4) [7] started from the readily available Wieland-Mie-scher ketone (19) which, by a series of mainly protection and oxidation reactions, was transformed to the fully functionalized C ring precursor 21. The oxetane moiety was introduced very early on in the synthesis, from a corresponding triol, again by nucleophilic substitution at C5. Noteworthy is the selective protection or modification of primary versus secondary versus tertiary hydroxy groups for this purpose. The benzyl protected enolized form 20 then could be oxidized, cleaved oxidatively and processed to compound 21 which, apart from complete C/D rings, possesses the necessary handles (C2 and C9/10) to bind to the A ring precursor 22 and thus form the B ring. 

As mentioned above, carbocations feature in many reactions, such as nucleophilic substitution (Sjjl) and elimination (El), additions of electrophiles to double and triple bonds, electrophilic aromatic substitution, and additions to carbonyl compounds and enolate chemistry (albeit in masked form). 

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