Oxindoles addition

More recently, Wright et al. have shown that sulfoxides (11) can be converted into the desired chlorosulfonium intermediates by using oxalyl chloride. This operationally more simple approach can be used make a variety of oxindoles. Additional examples using these approaches for the in situ preparation of the chlorosulfonium salts will be shown below. 

Besides Pd-catalysed cyclizations, both radical[12] and organolithium[13] intermediates can give oxindoles by exo-trig additions. 

A solution of 2-aminobenzophenone (98 g, 0.50 mol) and methyl 2-(methyl-thio)propanoate (74 g, 0,50 mol) in CH Clj (21) was cooled to —70 C and 95% 7-butyl hypochlorite (56 g, 0.5 mol) was added dropwise at such a rate that the temperature did not rise above — 65 C. One hour after the addition was complete, EtjN was added and the mixture was allowed to come to room temperature. The solution w as mixed with 3 N HCl (800 ml) and stirred for 1 h. The organic layer was separated, dried (Na2S04 ) and filtered. The solution was evaporated in vacuo and the residue triturated with ether. Filtration gave the 3-(methylthio)oxindole intermediate (92 g) in 62% yield. 

The conversion of indoles to oxindoles can be achieved in several ways. Reaction of indoles with a halogenaling agent such as NCS, NBS or pyridin-ium bromide perbromide in hydroxylic solvents leads to oxindoles[l]. The reaction proceeds by nucleophilic addition to a 3-haloindolenium intermediate. 

An unusual case of addition of a carbanion to an unconjugated carbon-carbon double bond is shown in Scheme 47a. The subsequent transfer of the amide group is also noteworthy (80CC1042). The intramolecular addition of a carbanion to an aryne is a more widely established process. Such reactions have been applied to the synthesis of indoles (Scheme 47b) (75CC745> and oxindoles (Scheme 47c) (63JOC1,80JA3646). 

The mechanism of the rearrangement is explained as shown in Scheme 19. Protonation of the 9-hydroxy group followed by its elimination and subsequent chloride attack at the 4a-carbon generates a chloroindolenine 126. Addition of water to the 9a-imine carbon atom of 126 gives 127. Concerted elimination of the chloride with rearrangement of the alkyl side chain attached to the 9a carbon atom results in 3,3-disubstituted oxindole structure 120a. 

A convenient modification of the Gassman oxindole synthesis was reported using ethyl (methylsulfinyl)acetate (101) activated by oxalyl chloride to generate the same chlorosulfonium salt 102 normally generated from ethyl (methylthio)acetate 100 and elemental chlorine <96TL4631>. Thus, treatment of the sulfoxide 101 with oxalyl chloride, followed by the addition of the desired aniline, triethylamine, and finally acid cyclization of 103 affords the oxindoles 104. This procedure is particularly convenient for reactions carried out on smaller scales and for anilines that ate susceptible to electrophiUc halogenation. 

The same group recently disclosed a related free radical process, namely an efficient one-pot sequence comprising a homolytic aromatic substitution followed by an ionic Homer-Wadsworth-Emmons olefination, for the production of a small library of a,/3-unsaturated oxindoles (Scheme 6.164) [311]. Suitable TEMPO-derived alkoxy-amine precursors were exposed to microwave irradiation in N,N-dimethylformam-ide for 2 min to generate an oxindole intermediate via a radical reaction pathway (intramolecular homolytic aromatic substitution). After the addition of potassium tert-butoxide base (1.2 equivalents) and a suitable aromatic aldehyde (10-20 equivalents), the mixture was further exposed to microwave irradiation at 180 °C for 6 min to provide the a,jS-unsaturated oxindoles in moderate to high overall yields. A number of related oxindoles were also prepared via the same one-pot radical/ionic pathway (Scheme 6.164). 

Hartwig has reported an intramolecular/intermolecular process affording the 3-aryloxindoles 105 (Scheme 32).115 The intermolecular arylation of acetanilide derivative 104 is slower than the intramolecular arylation to form the oxindole. Thus, the overall transformation starts with cyclization followed by intermolecular arylation of indole. In order to slow down the intermolecular process and speed up the intramolecular reaction, chloroarene and bromine-substituted acetanilide precursors are used according to their respective reactivity with palladium(O) in the oxidative addition process. 

Only three examples of ibogan-type oxindole alkaloids are known, and two of them, crassanine (156) and tabemoxidine (155), were found in Tabernaemon-tana. Crassanine (C23H30N2O5, MP 191°C, [a]D +21°) was isolated in minute amounts by Cava et al. from T. crassa (79). Its IR spectrum indicated the presence of two carbonyl groupings (1739 and 1709 cm - ), while its UV spectrum was almost superimposable on that of known 10,11-dimethoxyoxindoles such as kisantine (200). In addition to the carbomethoxy methyl at 3.47 ppm and two aromatic methoxyls at 3.83 ppm (6H), the H-NMR spectrum of 156 exhibited two singlets (1H) at 6.50 and 7.01 ppm and the low-field oxindole NH at 9.30 ppm. The latter values are similar to those recorded for kisantine, and on this basis Cava et al. proposed the structure 102 for crassanine. To date, no evidence is available on the configuration at the C-7 spiro center. 

The probable pathway of the reaction is shown in Fig. 14 and it seems to be an addition of the indole to the carbonyl group of isatin, followed by the condensation of a second indole moiety on the same carbon, resulting in the formation of 3,3-di (3-indolyl)oxindole. 

Organometallic compounds asymmetric catalysis, 11, 255 chiral auxiliaries, 266 enantioselectivity, 255 see also specific compounds Organozinc chemistry, 260 amino alcohols, 261, 355 chirality amplification, 273 efficiency origins, 273 ligand acceleration, 260 molecular structures, 276 reaction mechanism, 269 transition state models, 264 turnover-limiting step, 271 Orthohydroxylation, naphthol, 230 Osmium, olefin dihydroxylation, 150 Oxametallacycle intermediates, 150, 152 Oxazaborolidines, 134 Oxazoline, 356 Oxidation amines, 155 olefins, 137, 150 reduction, 5 sulfides, 155 Oxidative addition, 5 amine isomerization, 111 hydrogen molecule, 16 Oxidative dimerization, chiral phenols, 287 Oximes, borane reduction, 135 Oxindole alkylation, 338 Oxiranes, enantioselective synthesis, 137, 289, 326, 333, 349, 361 Oxonium polymerization, 332 Oxo process, 162 Oxovanadium complexes, 220 Oxygenation, C—H bonds, 149... 

In addition to its susceptibility to oxidation, 2-aminoindole is easily converted into oxindole by aqueous acids and is deaminated by sodium in ethanol (72HC(25-1)227). 

Intramolecular nucleophilic substitution by the anions of o-haloanilides is another viable oxindole synthesis. This is a special example of the category Ic process described in Section 3.06.2.3. The reaction is photo-stimulated and the mechanism is believed to be of the electron-transfer type SRN1 rather than a classical addition-elimination mechanism. The reaction is effective when R = H if 2 equivalents of the base are used to generate the dianion (equation 202) (80JA3646). 

The formation of cyclopropane derivatives by photolysis of diazoalkanes in the presence of alkenes is believed to occur by photolytic decomposition of the diazoalkane to yield the carbene, followed by addition of this carbene to the alkene. Cycloaddition of this type has been reported in furan, dihydrofuran, and thiophene.198 Thus, photolysis of ethyl diazoacetate in thiophene yields the bicyclic sulfur heterocycle (215). Alternatively, photolysis of 3-diazo-l-methyl-oxindole (216) in cyclohexene leads to the formation of two isomers which are thought to have the spirocyclopropyl structure (217) photolysis in ethanol yields 3-ethoxy-1-methyloxindole.194... 

The analogous Z aryl triflate 19.1 reacts under the cationic manifold to give, ultimately, oxindole (/ )-17.3a in 72% yield and 43-48% ee (Scheme 8G.19) [38]. An important synthetic advance is the observation that Heck cyclization of this substrate could be diverted to the more selective neutral pathway by addition of halide salts. For example, Heck cyclization of triflate 19.1 in the presence of 1 equiv. of n-Bu4NI gave (/ )-17.3a in 62% yield and 90% ee, which is similar to the enantioselectivity obtained for cyclization of the corresponding iodide 18.1c under neutral conditions (see entry 6, Table 8G, 1). Conversely, cyclization of iodide 18.1c in the... 

Their most detailed investigations focused on the Heck cyclization of iodide 18.1c to form oxindole 17.3a (Scheme 8G.18) [38a,b]. A chiral-amplification study [47] established that the catalytically active species is a monomeric Pd-BINAP complex, a conclusion also corroborated by NMR studies by Amatore and co-workers [42d,43], In addition, two possibilities for the enantioselective step of the neutral pathway were easily eliminated [38a], Oxidative addition was precluded as the enantioselective step, because iodides cyclize with very different enantioselectivities in the presence of Ag(I) salts. A scenario where migratory insertion is reversible and [l-hydridc elimination is the enantioselective step was also ruled out, because this is not consistent with the dependence of enantioselectivity on the geometry of the double bond of the cyclization precursor. 

Interestingly, cyclic / -keto esters, e.g. 69, can be also fhiorinated with enantioselectivity up to 80% ee, although the yield and enantioselectivity depend strongly on the type of substrate. A representative example of asymmetric fluorination of a cyclic ester is shown in Scheme 3.27, Eq. (2). In addition, oxindoles 71 have been successfully fhiorinated, as shown in Scheme 3.27, Eq. (3). Under optimized conditions, the desired 3-substituted 3-fluorooxindole, 72, was obtained in 79% yield and with enantioselectivity of 82% ee. 

Additions to prochiral ketenes [13.2] Desymmetrization of meso-diols [13.3] Dynamic kinetic resolution of azlactones rearrangement of O-acyl azlactones, O-acyl oxindoles, O-acyl benzofuranones [13.6]... 

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