Nucleophilic substitution formate reactions

Allyl carbamates also can serve as amino-protecting groups. The allyloxy group is removed by Pd-catalyzed reduction or nucleophilic substitution. These reactions involve formation of the carbamic acid by oxidative addition to the palladium. The allyl-palladium species is reductively cleaved by stannanes,221 phenylsilane,222 formic acid,223 and NaBH4,224 which convert the allyl group to propene. Reagents... 

If the groups Ri, R2 and R3 are different, C is a asymmetric carbon atom. It has been found that the rate of formation of the optical antipode is identical with the exchange rate, which is the proof of the mechanism of second-order nucleophilic substitution (Sn2 reaction). 

Nucleophilic substitution (5 ) reactions of saturated aliphatic compounds may be either associative or dissociative and the majority lie between the limits set by iSnI reactions, in which the rate-determining step is heterolysis of the bond to the leaving group, and typical 5 2 reactions with fully synchronous bond-formation and bond-rupture. Nl-like reactions represent an intermediate case and are characterized by a greater extent of bond-rupture than bond-formation. Hence, in aliphatic 5 reactions the rate-limiting process involves some degree of prior or concurrent bond-rupture. 

XJ F NH2 R-SH 0 H Observations - The linker is immobilized through an anilide formation. N-Boc-cyslcine is coupled to the anchor by a nucleophilic substitution. Further reactions can be preformed either on the COOH or NH2 of cysteine. - Compatible with Boc/Bnz-SPPS strategy. ... 

Since the pioneering studies of Bunnett [3], the scope of the unimolecular radical nucleophilic substitution (SrnI) reaction has increased considerably, and today this approach is well established for the formation of aryl-carbon and aryl-heteroatom bonds. The SrnI reaction is a chain process which includes radicals and radical anions as intermediates the reaction mechanism is depicted in Scheme 13.1 [1]. 

Electron-attracting substituents should assist this reaction. However, with acetic anhydride in acetonitrile, 2-picolinic acid 1-oxide gives mainly pyridine 1-oxide and carbon dioxide, whilst the same reaction carried out under ultra-violet irradiation proceeds similarly but with the formation of a little more 2-hydroxypyridine. The methyl esters of the pyridine-carboxylic acid 1-oxides behave normally, but there is no evidence that the methoxycarbonyl group promotes the reaction, and 2-cyanopyridine 1-oxide does not react with acetic anhydride . The results of a kinetic study of the rearrangement of pyridine 1-oxide in acetic anhydride exclude the intramolecular rearrangement of the free cation (113) and also a free radical process. There remain the two possibilities of nucleophilic substitution by reaction between... 

Nucleophilic Substitution.— The reactivities of 2-halogeno-thiazoles with arenethiols are explained by the existence of an acid-base equilibrium preceding the substitution step the formation of an ion-pair or of thiazolium and arene-thiolate ions is the rate-determining step. Some 4- or 5-substituted 2-chloro-thiazoles apparently react with methoxide ion in a normal aza-activated nucleophilic substitution, the reaction being influenced by the substituent. In the case... 

Pd(II) compounds coordinate to alkenes to form rr-complexes. Roughly, a decrease in the electron density of alkenes by coordination to electrophilic Pd(II) permits attack by various nucleophiles on the coordinated alkenes. In contrast, electrophilic attack is commonly observed with uncomplexed alkenes. The attack of nucleophiles with concomitant formation of a carbon-palladium r-bond 1 is called the palladation of alkenes. This reaction is similar to the mercuration reaction. However, unlike the mercuration products, which are stable and isolable, the product 1 of the palladation is usually unstable and undergoes rapid decomposition. The palladation reaction is followed by two reactions. The elimination of H—Pd—Cl from 1 to form vinyl compounds 2 is one reaction path, resulting in nucleophilic substitution of the olefinic proton. When the displacement of the Pd in 1 with another nucleophile takes place, the nucleophilic addition of alkenes occurs to give 3. Depending on the reactants and conditions, either nucleophilic substitution of alkenes or nucleophilic addition to alkenes takes place. 

With higher alkenes, three kinds of products, namely alkenyl acetates, allylic acetates and dioxygenated products are obtained[142]. The reaction of propylene gives two propenyl acetates (119 and 120) and allyl acetate (121) by the nucleophilic substitution and allylic oxidation. The chemoselective formation of allyl acetate takes place by the gas-phase reaction with the supported Pd(II) and Cu(II) catalyst. Allyl acetate (121) is produced commercially by this method[143]. Methallyl acetate (122) and 2-methylene-1,3-diacetoxypropane (123) are obtained in good yields by the gas-phase oxidation of isobutylene with the supported Pd catalyst[144]. 

An important method for construction of functionalized 3-alkyl substituents involves introduction of a nucleophilic carbon synthon by displacement of an a-substituent. This corresponds to formation of a benzylic bond but the ability of the indole ring to act as an electron donor strongly influences the reaction pattern. Under many conditions displacement takes place by an elimination-addition sequence[l]. Substituents that are normally poor leaving groups, e.g. alkoxy or dialkylamino, exhibit a convenient level of reactivity. Conversely, the 3-(halomethyl)indoles are too reactive to be synthetically useful unless stabilized by a ring EW substituent. 3-(Dimethylaminomethyl)indoles (gramine derivatives) prepared by Mannich reactions or the derived quaternary salts are often the preferred starting material for the nucleophilic substitution reactions. 

Overall the stereospecificity of this method is the same as that observed m per oxy acid oxidation of alkenes Substituents that are cis to each other m the alkene remain CIS m the epoxide This is because formation of the bromohydrm involves anti addition and the ensuing intramolecular nucleophilic substitution reaction takes place with mver Sion of configuration at the carbon that bears the halide leaving group... 

Carbonates undergo nucleophilic substitution reactions analogous to chloroformates except in this case, an OR group (rather than chloride) is replaced by a more basic group. Normally these reactions are cataly2ed by bases. Carbonates are sometimes preferred over chloroformates because formation of hydrogen chloride as a by-product is avoided, which simplifies handling. However, the reactivity of carbonates toward nucleophiles is considerably less than chloroformates. 

The first benzazetidine (243) was isolated from the photolysis of 3-phenyldihydroben-zotriazine (242) (66JA1580). Another route to benzazetidines involving formation of the N to aryl-C bond utilizes intramolecular nucleophilic substitution via aryne (287). It is not general, however, and is only satisfactory when R and/or are alkoxy groups. The reaction also fails for iV-alkylamines (78LA608). 

The azinones and their reaction characteristics are discussed in some detail in Section II, E. Because of their dual electrophilic-nucleophilic nature, the azinones may be bifunctional catalysts in their own formation (cf. discussion of autocatalysis below) or act as catalysts for the desired reaction from which they arise as byproducts. The uniquely effective catalysis of nucleophilic substitution of azines has been noted for 2-pyridone. 

Intramolecular nucleophilic displacement of the bromo group by an azine-nitrogen occurs in the cyclization of A-2-quinaldyl-2-bromo-pyridinium bromide (248) to give the naphthoimidazopyridinium ring system. The reaction of 2-bromopyridine and pyridine 1-oxide yields l-(2-pyridoxy)pyridinium bromide (249) which readily undergoes an intramolecular nucleophilic substitution in which departure of hydrogen as a proton presumably facilitates the formation of 250 by loss of the JV-oxypyridyl moiety. 

Even polyalkoxy-s-triazines are quite prone to nucleophilic substitution. For example, 2,4,6-trimethoxy-s-triazine (320) is rapidly hydrolyzed (20°, dilute aqueous alkali) to the anion of 4,6-dimethoxy-s-triazin-2(l )-one (331). This reaction is undoubtedly an /S jvr-4r2 reaction and not an aliphatic dealkylation. The latter type occurs with anilines at much higher temperatures (150-200°) and with chloride ion in the reaction of non-basified alcohols with cyanuric chloride at reflux temperatures. The reported dealkylation with methoxide has been shown to be hydrolysis by traces of water present. Several analogous dealkylations by alkoxide ion, reported without evidence for the formation of the dialkyl ether, are all associated with the high reactivity of the alkoxy compounds which ai e, in fact, hydrolyzed by usually tolerable traces of water. Brown ... 

Specific alterations of the relative reactivity due to hydrogen bonding in the transition state or to a cyclic transition state or to electrostatic attraction in quaternary compounds or protonated azines are included below (cf. also Sections II, B, 3 II, B, 5 II, C and II, F). A-Protonation is often reflected in an increase in JS and therefore the relative reactivity can vary with the significance of JS in controlling the reaction rate. Variation can also result from rate determination by the second stage of the SjjAr2 mechanism or from the intervention of thermodynamic control of product formation. Variation in the rate and in the reactivity pattern of polyazanaph-thalenes will result when nucleophilic substitution [Eq. (10)] occurs only on a covalent adduct (408) of the substrate rather than on its aromatic form (400). This covalent addition is prevented by any 4-... 

In general, all of the title compounds can be classified as either compounds in which the heteroarylium moiety remains in the molecule after the nucleophilic substitution (pathway a, formation of 45) or compounds in which that moiety was substituted by a suitable nucleophile to yield 46 (pathway b). Proper selection of the nucleophile Nu in 45 (or Nu in 46) should thus allow control of the consecutive substitution reactions, which would lead to a preference of 47 over 48 or vice versa (Scheme 14). 

The nitration of l,2,5-selenadiazolo[3,4-/] quinoline 77 with benzoyl nitrate affords the 8-nitro derivative 78, whereas methylation with methyl iodide or methyl sulfate afforded the corresponding 6-pyridinium methiodide 79 or methosulfate 80, respectively (Scheme 29). The pyridinium salt 80 was submitted to oxidation with potassium hexacyanoferrate and provided 7-oxo-6,7-dihydro derivative 81 or, by reaction of pyridinium salt 79 with phenylmagnesium bromide, the 7-phenyl-6,7-dihydro derivative 82. Nucleophilic substitution of the methiodide 79 with potassium cyanide resulted in the formation of 9-cyano-6,9-dihydroderivative 83, which can be oxidized by iodine to 9-cyano-l,2,5-selenadiazolo [3,4-/]quinoline methiodide 84. All the reactions proceeded in moderate yields (81IJC648). 

Two reaction mechanisms, such as SN1 and SN2 mechanisms, seem to be possible for explaining formations of 158a-c (Scheme 25). The former requires a resonance-stabilized indolyl cation 165 as an intermediate, while the latter indicates the presence of a transition state like 167. The introduction of a methoxy group into the 5 position of 165 should stabilize the corresponding cation 166, in which nucleophilic substitution on indole nitrogen would become a predominant pathway. 

The reaction of wasabi phytoalexin (109) with excess 15% aqueous NaSMe gives methyl 2-methylthioindole-3-carboxylate (184,70%) and 140 (20%). In this reaction, formation of 2-methylthioindole-3-carboxylic acid (185) is not observed under various reaction conditions. The fact indicates that once 140 is formed, it does not undergo nucleophilic substitution reaction. In addition, hydrolysis of the... 

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