Nucleophilic substitution carbon nucleophile cyclization

Chloro-3-methylthio-l,2,4-thiadiazol-2-ium salts 51 have undergone nucleophilic displacement with a variety of nitrogen and carbon nucleophiles to give bicyclic compounds such as 52. The substitution reaction and cyclization... 

The Williamson ether synthesis remains the most practical method for the preparation of tetrahydrofurans, as can be exemplified by the two examples shown in the following schemes. A simple synthesis of 2-substituted tetrahydrofuran-3-carbonitriles 84 is achieved by generating the alkoxide under a phase transfer condition via reaction between 4-chlorobutyronitrile and non-enolizable aldehydes <00SL1773>. A synthesis of 2-alkylidene-tetrahydrofuran 85 was recorded, in which a dianion can be generated through treatment of the amide shown below with an excess of LDA, and is followed by addition of l-bromo-2-chloroethane. In this way, the more basic y-carbon is alkylated and leads eventually to the nucleophilic cyclization <00SL743>. 

The proposed mechanism for this reaction involves the initial coordination of styrene oxide to Tbt(Tip)Sn=Se followed by nucleophilic attack of a second Tbt(Tip)Sn=Se molecule on the less substituted carbon with the formation of cis- and trans-195. Alternatively, the unimolecular cyclization of the initial styrene oxide-Tbt(Tip)Sn=Se complex leads to the formation of compound 196 as a minor product (Scheme 10). 

The fate of isocyanosulfide (70) depends on the nature of the substituent originally at C-4 of the isothiazole ring. If R is aryl, as in 55, the extended conjugation of the sulfide and the aryl group is expected to lower the basicity of the sulfide resulting in reprotonation at the isocyano carbon to yield 71. Protonation at this site renders the carbon more susceptible to nucleophilic attack by the negative sulfur. As a result, these substituted isocyanides spontaneously cyclize to 4-arylthiazoles 73 (R=Ar). 

The same differential behavior can be observed with amine nucleophiles. For example, calcium triflate promotes the aminolysis of propene oxide 84 with benzylamine to give 1-(A -benzyl)amino-2-propanol 85, the result of attack at the less substituted site <03T2435>, and which is also seen in the solventless reaction of epoxides with heterocyclic amines under the catalysis of ytterbium(III) triflate <03SC2989>. Conversely, zinc chloride directs the attack of aniline on styrene oxide 34 at the more substituted carbon center <03TL6026>. A ruthenium catalyst in the presence of tin chloride also results in an SNl-type substitution behavior with aniline derivatives (e.g., 88), but further provides for subsequent cyclization of the intermediate amino alcohol, thus representing an interesting synthesis of 2-substituted indoles (e.g., 89) <03TL2975>. 

In view of their high electronegativity, fluorine atoms accumulated in the benzene ring substantially increase the electrophilicity of the carbon atoms. This creates conditions for high mobility of the fluorine atoms of polyfluorinated aromatic compounds in nucleophilic substitution reactions and hence for intramolecular nucleophilic cyclizations by the elimination of the fluorine atom ortho to the... 

When butadiene is treated with PdCU the l-chloromethyl-7r-allylpalladium complex 336 (X = Cl) is formed by the chloropalladation. In the presence of nucleophiles, the substituted 7r-methallylpalladium complex 336 (X = nucleophile) is formed(296-299]. In this way, the nucleophile can be introduced at the terminal carbon of conjugated diene systems. For example, a methoxy group is introduced at the terminal carbon of 3,7-dimethyl-I,3,6-octatriene to give 337 as expected, whereas myrcene (338) is converted into the tr-allyl complex 339 after the cyclization[288]. 

Anomalous Fischer cyclizations are observed with certain c-substituted aryl-hydrazones, especially 2-alkoxy derivatives[l]. The products which are formed can generally be accounted for by an intermediate which w ould be formed by (ip50-substitution during the sigmatropic rearrangement step. Nucleophiles from the reaction medium, e.g. Cl or the solvent, are introduced at the 5-and/or 6-position of the indole ring. Even carbon nucleophiles, e.g. ethyl acetoacelate, can be incorporated if added to the reaction solution[2]. The use of 2-tosyloxy or 2-trifluoromethanesulfonyloxy derivatives has been found to avoid this complication and has proved useful in the preparation of 7-oxygen-ated indoles[3]. 

The cyclization involves a nucleophilic attack of the malonic ester car-banion on the carbonyl carbon atom of the aldehyde, and the substituted malonic ester carbanion attacks the electron-deficient carbon atom bearing the iodine atom, or in the reverse order, to give 119. The hydroxyl group generated in the first step of the reaction attacks the carbon atom, giving the pyranose product. 

As mentioned earlier, the McDonald group was able to extend their epoxide-domino-cyclization strategy to 1,5,9-triepoxides [10]. Indeed, they were successful in converting precursor 1-143 into the tricyclic product 1-146 in 52 % yield after hydrolysis (Scheme 1.36) [41]. As a possible mechanism of this polyoxacyclization it can be assumed that, after activation of the terminal epoxide by BF3, a sequence of intramolecular nucleophilic substitutions by the other epoxide oxygens takes place, which is induced by a nucleophilic attack of the carbonate oxygen, as indicated in 1-144 to give 1-145. 

Bromoethylamine (11.133, R = Br, Fig. 11.18) is a potent nephrotoxin used to create an experimental model of nephropathy. Its mechanism of toxicity is postulated to involve perturbation of mitochondrial function, and its metabolism was investigated in a search for toxic metabolites. In rat plasma, 2-bromoethylamine was converted to aziridine (11.134), formed by intramolecular nucleophilic substitution and bromide elimination [155], Another major metabolite was oxazolidin-2-one (11.136). This peculiar metabolite resulted from the reaction of 2-bromoethylamine with endogenous carbonate to form carbamic acid 11.135, followed by cyclization-elimination to oxazoli-din-2-one. In aqueous media containing excess carbonate, the formation of... 

The intramolecular reaction of activated alkenes of the type 8 leads to the formation of 5- or 6-membered rings [26] and has been carried out only at a mercury cathode in a divided cell. In these processes, the activated alkene radical-anion is formed at a less negative potential than that required for cleavage of the carbon-bromine bond. Cyclization then occurs by nucleophilic substitution. 

The two reaction modes of the Michael adducts 145 demonstrate two general principles for the possible preparation of ordinary size heterocyclic compounds from the chlorocyclopropylideneacetates 1,2. Thus, either the heterocycles 153 can be formed by Michael addition of a bidentate nucleophile 150 onto the chloro ester 1-Me and subsequent ring closure of the intermediate 151 [26] by nucleophilic substitution of the chlorine atom at the newly formed sp carbon center adjacent to both the carbonyl and the cyclopropyl group (Route B in Scheme 48). Alternatively, the intermediate 151 can cyclize by nucleophilic attack on the ester moiety to give heterocycles of type 152 (Route A in Scheme 48) [26]. 

Nucleophilic attack at substituted ring carbon is probably the most common reaction of 1,3,4-oxadiazoles. However, few examples have been reported of nucleophilic attack at unsubstituted carbon since such compounds (19a) are relatively uncommon. The mechanism of the well-known conversion of 2-amino-oxadiazoles (in aqueous alkali) into triazoles has been studied in the case of the reaction where (19a R = NHPh) is converted to (20). This proceeds via the anion of semi-carbazide PhNHCONHNHCHO and is initiated by hydroxide attack at C-5 <84JCS(P2)537>. A similar nucleophilic attack by hydroxide on oxadiazole (19a R = 5-pyrazolyl) was followed by cyclization to the pyrazolo-triazine (21). Hydrolytic cleavage of 2-ary 1-1,3,4-oxadiazoles to aroyl-hydrazides allows use of the former as protected hydrazides. Oxadiazole (19a R = 4-... 

Nucleophilic substitution of the 4-chloro group of the 4-pyranotriazines 103 with hydrazine gives the 4-hydrazino-triazines 104, which can be further elaborated to the corresponding azides 105 or cyclized upon reaction with formic acid or carbon disulfide to give the triazolotriazines 106 or thioxotriazolotriazines 107, respectively (Scheme 11) <2005HC0495>. 

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