Vicarious substitution hydrogen

Scheme 3.8 represents a typical ion-radical mechanism of the so-called vicarious nucleophilic substitution of hydrogen as it was described by the pioneering chemist M kocza (M kocza 1989) in his summarizing review. ESR studies of other heterocyclic systems in conditions of the hydrogen-to-nucleophile vicarious substitution were reported by the research group at the Siberian branch of the Russian Academy of Sciences (Donskaya et al. 2002, Vakul skaya et al. 2005, 2006, Titova et al. 2005). 

Replacement of an aromatic fluorine atom by a carbon nucleophile is facilitated by the presence of electron-withdrawing groups [82] (equation 44) Replacement of an activated aryl hydrogen can occur in preference to a nonactivated aryl fluorine [S3] (equation 45) in reactions known as vicarious substitutions. 

The nitroazoles are widely used in the reaction of vicarious nucleophilic substitution of hydrogen. Vicarious nucleophilic C-amination is, practically, the single method of direct introduction of the amino group into nitro compounds. Using the vicarious nucleophilic substitution reaction we have successfully carried out the C-amination of some representatives of nitrobenzazoles, nitroazoles, and model compounds thereof and studied the structure of aminated products and the C-amination mechanism [673-678],... 

The initially formed adducts can be converted into products of nucleophilic substitution of hydrogen in a variety of ways oxidation with external oxidants, conversion into nitrosoarenes according to intramolecular redox stoichiometry, vicarious substitution, cine- and fe/e-elimination, ANRORC, etc. These processes have been discussed in a concise way in our preceding reviews [4,6-10]. The major message of those reviews is that nucleophilic substitution of hydrogen, in its many variants, is the main, primary process, whereas the conventional nucleophilic substitution of halogens X, the SnAt process, is just a secondary ipso reaction [9, 10]. 

Mechanisms of the nucleophilic substitution of hydrogen have been reviewed, and there has been a report of the synthesis of nitroaryl derivatives of glycine using the oxidative pathway. An example of the vicarious substitution mechanism is the formation of (13), a 3-styryl-substituted boron dipyrromethene, by reaction of a... 

M A K O S Z A Vicarious nucleoptiiHc substitution Synthesis of akyl substituted hetsrocydss by vicai1ous nucleophilic substitution ol hydrogen in heteroarenes, nitrodenvatives ol heleroarenes. 

The reaction of 3-methoxy-1,2,4-triazine 1-oxide 20 with the carbanion generated from chloromethyl phenyl sulfone proceeds as the vicarious nucleophilic substitution (VNS) of hydrogen (Scheme 1, path B) via addition of the carbanion at position 5 of the heterocycle. Following base-induced elimination of HCl and protonation, 3-methoxy-5-phenylsulfonyl-1,2,4-triazine 4-oxides 65 result (88LA627). 

The carbanion of 2,3-dimethylthiazolidine-4-one reacted with nitroarenes to give either a ting opened product (50) via a VNS (vicarious nucleophilic substitution) reaction or a product resulting from oxidative nucleophilic substitution of hydrogen (51). Ring opening VNS reactions with 5-membered 5-heterocycles are limited to those heterocycles which show some conformational flexibility <96TL983>. 

Aromatic nitro compounds undergo nucleophilic aromatic substitutions with various nucleophiles. In 1991 Terrier s book covered (1) SNAr reactions, mechanistic aspects (2) structure and reactivity of anionic o-complexes (3) synthetic aspects of intermolecular SNAr substitutions (4) intramolecular SNAr reactions (5) vicarious nucleophilic substitutions of hydrogen (VNS) (6) nucleophilic aromatic photo-substitutions and (7) radical nucleophilic aromatic substitutions. This chapter describes the recent development in synthetic application of SNAr and especially VNS. The environmentally friendly chemical processes are highly required in modem chemical industry. VNS reaction is an ideal process to introduce functional groups into aromatic rings because hydrogen can be substituted by nucleophiles without the need of metal catalysts. 

In the presence of KOH, /m(benzotriazol-l-yl)methane 729 reacts with nitrobenzenes to produce />-(/fc (bcnzo-triazol-lyl)methyl]nitrobenzenes 730 (Scheme 114) <1996TL347>. This vicarious nucleophilic substitution of hydrogen <1991S103> can be considered as a convenient way to />-nitrobenzaldehydes 731. Meta and para substituted nitrobenzenes do not react with compound 729 under these conditions, probably due to steric reasons, but 1-nitronaphthalene reacts producing a naphthalene analog of derivative 730. 

Some derivatives of the [l,2,4]triazolo[4,3-3]pyridazine ring system 33 were subjected to a special type of nucleophilic substitution called vicarious nucleophilic substitution (VSN) <2006TL4259>. In the course of this transformation a formal substitution of az aromatic hydrogen atom - occurring via an addition-elimination mechanism - takes place. 

The vicarious nucleophilic substitution of hydrogen in nitrothiophenes is of great synthetic potential (87ACR282,91S103). Carbanions bearing leaving groups (L) at the carbanion center can initially add to... 

When the attacking atom of the nucleophile carries a leaving group, replacement of hydrogen can take place via the VNS (vicarious nucleophilic substitution) reaction,15 as shown in Scheme 3.16 The key feature of this reaction is the rate-limiting base-induced 3-elimination from the cr-adduct. 

The synthetic application of vicarious nucleophilic substitution, whereby hydrogen of an electrophilic arene is replaced by an a-functionalized alkyl substituent, has been reviewed 177 the sequence usually involves attack on a nitroalkene by a carbanion containing a leaving group X at the carbanionic centre, /i-elimination of HX from the er-adduct, and rearomatization on subsequent protonation. 

The regioselective functionalization of nitrobenzene and benzonitrile derivatives has been performed via nucleophilic aromatic substitution of hydrogen by phosphorus-stabilized carbanions.41 Lithium phosphazenes have been found to be the most suitable nucleophiles for the substitution of hydrogen in nitrobenzene. This method represents a convenient alternative to the vicarious nucleophilic substitution for the synthesis of benzylic phosphorus derivatives using phosphorus-stabilized anions that do not bear a leaving group at the carbanionic centre. 

The theory and practice of vicarious nucleophilic substitution of hydrogen (VNS) were examined in detail mostly by Mqkosza and his co-workers (87ACR282,... 

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