Amination electrophilic, review

The C-nitrosation of aromatic compounds is characterized by similar reaction conditions and mechanisms to those discussed earlier in this section. The reaction is normally carried out in a strongly acidic solution, and in most cases it is the nitrosyl ion which attacks the aromatic ring in the manner of an electrophilic aromatic substitution, i. e., via a a-complex as steady-state intermediate (see review by Williams, 1988, p. 58). We mention C-nitrosation here because it may interfere with diazotization of strongly basic aromatic amines if the reaction is carried out in concentrated sulfuric acid. Little information on such unwanted C-nitrosations of aromatic amines has been published (Blangey, 1938 see Sec. 2.2). 

During the past few years, increasing numbers of reports have been published on the subject of domino reactions initiated by oxidation or reduction processes. This was in stark contrast to the period before our first comprehensive review of this topic was published in 1993 [1], when the use of this type of transformation was indeed rare. The benefits of employing oxidation or reduction processes in domino sequences are clear, as they offer easy access to reactive functionalities such as nucleophiles (e. g., alcohols and amines) or electrophiles (e. g., aldehydes or ketones), with their ability to participate in further reactions. For that reason, apart from combinations with photochemically induced, transition metal-catalyzed and enzymatically induced processes, all other possible constellations have been embedded in the concept of domino synthesis. 

Most reactive metabolites produced by CYP metabolic activation are electrophilic in nature, which means that they can react easily with the nucleophiles present in the protein side chains. Several functional groups are recurrent structural features in M Bis. These groups have been reviewed by Fontana et al. [26] and can be summarized as follows terminal (co or co — 1) acetylenes, olefins, furans and thiophenes, epoxides, dichloro- and trichloroethylenes, secondary amines, benzodioxoles (methylenediox-yphenyl, MDP), conjugated structures, hydrazines, isothiocyanates, thioamides, dithiocarbamates and, in general, Michael acceptors (Scheme 11.1). 

Since then, optically active a-aminophosphonates have been obtained by a variety of methods including resolution, asymmetric phosphite additions to imine double bonds and sugar-based nitrones, condensation of optically active ureas with phosphites and aldehydes, catalytic asymmetric hydrogenation, and 1,3-dipolar cycloadditions. These approaches have been discussed in a comprehensive review by Dhawan and Redmore.9 More recent protocols involve electrophilic amination of homochiral dioxane acetals,10 alkylation of homochiral imines derived from pinanone11 and ketopinic acid,12 and alkylation of homochiral, bicyclic phosphonamides.13... 

The action of chloroamine and bromoamine on organometallic reagents has been reviewed102 and a comprehensive review of electrophilic aminations of carbanions has appeared103. Alkyl, alkenyl and aryllithium compounds are converted into tertiary amines 84 by reaction with the mesityl compounds 83 (R2 = Me or Et Ar = 2,4, 6-MesCeHj)104. 

As with the O-Mannich bases discussed above, the rate of nonenzymatic hydrolysis of N-Mannich bases depends on factors such as steric hindrance and electrophilicity of the sp3 C-atom. A rather large number of studies have been published on the value and properties of N-Mannich bases as potential prodrugs for amines, amides, and imides [80] [82] [88] [89], Here, we first review available reactivity data and then discuss selected examples of medicinal relevance. 

During the coverage period of this chapter, reviews have appeared on the following topics reactions of electrophiles with polyfluorinated alkenes, the mechanisms of intramolecular hydroacylation and hydrosilylation, Prins reaction (reviewed and redefined), synthesis of esters of /3-amino acids by Michael addition of amines and metal amides to esters of a,/3-unsaturated carboxylic acids," the 1,4-addition of benzotriazole-stabilized carbanions to Michael acceptors, control of asymmetry in Michael additions via the use of nucleophiles bearing chiral centres, a-unsaturated systems with the chirality at the y-position, and the presence of chiral ligands or other chiral mediators, syntheses of carbo- and hetero-cyclic compounds via Michael addition of enolates and activated phenols, respectively, to o ,jS-unsaturated nitriles, and transition metal catalysis of the Michael addition of 1,3-dicarbonyl compounds. ... 

This chapter on electrophilic amination using O-substituted hydroxylamines 1-5 and oximes 7 is focused on the various methods that have been reported for the amination of carbon nucleophiles. Synthetic aspects and applications of the methods for C—N bond formation are accompanied by a brief discussion of the reaction mechanisms. The preparation of O-substituted hydroxylamines and oximes has not been considered in detail. This review covers the literature up to August 2007 and is partly based on reviews on the electrophilic amination of carbanions and a-amination of carbonyl compounds. ... 

In this chapter, C—N couplings, e.g. substitution reactions of carbanions on nitrogen atom of oximes to yield primary amines, have been reviewed. A list of oximes and 0-sulfonyloximes used for electrophilic amination is given in Table 6. These reagents aminate carbanions to A-organylimines as isolable intermediates which are hydrolyzed to primary amines (Scheme 53, path d Scheme 54). Depending on the organometaUic... 

The normal reactions of benzo[6]thiophene 1,1-dioxides have been reviewed (70AHC(11)177). Electrophilic substitution (nitration, bromination) takes place at position 6. 3-Halo derivatives undergo normal nucleophilic displacement reactions, but 2-bromobenzo[6]thiophene dioxide gives the 3-ethoxy derivative in ethanolic NaOH. The reaction of 3-methoxy derivatives with secondary amines can give rise either to enamines... 

For reviews of metalalion and electrophilic substitution of amine derivatives adjacent to nitrogen, see Chem Rev 84 471 (1984)... 

There do not appear to be any direct approaches for electrophilic addition of amines across C—C double or triple bonds. However, aminomercuration-demercuration affords a very useful process to effect this transformation (equation 151). This reaction has been thoroughly reviewed recently.194... 

The research work of recent years includes predominantly the epoxidation of alkenes9,200, asymmetric hydroxylations209,224-228 and the asymmetric oxidation of sulfides to sulfoxides205,209,229,230. Optical yields of practical significance were obtained (>90%). A detailed review published in 1991231 reports about the versatile use of oxaziridines in the field of the electrophilic amination. 

Another type of electrophilic substitution subject to microscopic diffusion control occurs when a highly reactive form of the substrate is produced in a pre-equilibrium step (e.g. by proton loss) and when this form reacts on encounter with the electrophile. The nitration of p-nitroaniline in 90% sulphuric acid appears to be a reaction of this type (Hartshorn and Ridd, 1968), although the short lifetime of the free amine complicates the mechanistic interpretation. The formulation in Scheme 1 fits this type of reaction provided A is taken to represent the protonated amine, X the free amine, and B the nitronium ion. In 90% sulphuric acid, the nitronium ion is the bulk component of the NOJ—HN03 equilibrium mixture. Many of the reactions in this review can be represented by Scheme f with some reservations concerning the lifetime of the intermediate X. 

Discovered over a century ago, electrophilic mercuration is probably the oldest known C-H bond-activation reaction with a metal compound. The earliest examples of aromatic mercuration were reported by Volhard (mercuration of thiophene) [1], Pesci (mercuration of aromatic amines) [2], and Dimroth [3], who was the first to mercurate benzene and toluene, generalize the reaction, and assign the correct structures to the products originally observed by Pesci. Since the work of Dimroth electrophilic aromatic metalation reactions with compounds of other metals, for example Tl(III), Pb(IV), Sn(IV), Pt(IV), Au(III), Rh(III), and Pd(II), have been discovered [4], In this chapter, we will focus on intermolecular SEAr reactions involving main-group metal electrophiles and resulting in the formation of isolable metal aryls which find numerous important applications in synthesis [5], Well-known electrophilic cyclometalation reactions, for example cyclopalla-dation can be found in other chapters of this book and will not be reviewed here. 

However, when H2 is bound to a highly electrophilic cationic metal center, the acidity of H2 gas can be increased spectacularly, up to 40 orders of magnitude. The pK of H2 can become as low as —6 and thus the acidity of rf -H2 becomes as strong as that in sulfuric or triflic acid. As discussed in reviews by Morris (4,5) and Jia (25) and further work by Morris (26,27), such pK values are usually determined by NMR measurement of the concentrations of M H2 complexes in equilibrium with an external base such as a phosphine or amine. Electron deficient cationic and dicationic H2 complexes with strong short H-H bonds (<0.9 A) and weakly bound H2 such as [Cp Re(H2)(CO)(NO)]+ and [Re(H2)(CO)4(PR3)]+ are among the most acidic complexes (Table I). These acidic complexes typically have relatively high values of Jhd for their r 2-HD isotopomers, although pK values do not correlate... 

This book is intended to provide an overview of several areas of research in which amination plays a key role, and to introduce the reader to new concepts that have been developed quite recently for generating new C - N bonds. As the pharmaceutical and chemical industries move rapidly away from the development of racemic compounds, the access to synthetic routes that lead efficiently to enantiomerically pure materials is becoming increasingly important. For this reason, most of the contributions in this book refer to asymmetric synthesis. However, no attempt has been made to present a comprehensive work, and important areas such as asymmetric hydroxyamination [1] have not been dealt with. Furthermore, it may be worth mentioning that viable, useful and comprehensive sources of information about the methodological approaches to electrophilic amination developed since 1985 have already been reported [2], and that a chapter in Houben-Weyl reviewing several aspects of the asymmetric electrophilic amination [3] compiles important contributions up to 1995. 

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