Oxindoles 3-substituted

Oxindoles substituted in unusual positions have been obtained by base-induced intramolecular nucleophilic substitution of hydrogen in OT-nitroacylanilides. For example, treatment of the substrate 228 with potassium /-butoxide in DMSO gave the product 229 (Equation 71). However, the yields in such annulations are generally low, and some substrates give mixtures of isomeric oxindoles <2002S2203>. 

The CuCl2-catalysed oxidative coupling of alkenes and aldehydes in presence of TBHP (t-butylhydroperoxide) is developed for the synthesis of unsaturated a,fi-ketones. Both the aldehydes and alkenes tolerated a variety of functional groups. A preliminary mechanistic study indicated that the reaction is likely to proceed through a single-electron transfer. A similar intramolecular oxidative coupling of substimted amides in the presence of t-BuONa affords corresponding oxindoles substituted in the... 

Intramolecular Friedel-Crafts substitution has also figured prominently in the synthesis of oxindoles from cx-haloacelanilides. Typical reaction conditions for cyclizalion involve heating with A1CI,[13-17]. 

The oxidation of 3-substituted indole to oxindoles can also be done with a mixture of DMSO and cone, hydrochloric acid[6-9]. This reaction probably involves a mechanism similar to the halogenation with a protonated DMSO molecule serving as the electrophile[10]. 

Another indole/oxindole synthesis achieves the critical ortho-substitution by Sommelet-Hauser rearrangement of an anilinosiilfonium ion intermediate. Use of P-thioketones (G = R, an alkyl group) generates 2-substituted indoles, whereas P-thioesters (G = OR) lead to oxindoles. In each case, a 3-thio substituent must be removed by desulfuri2ation. 

When reacted with dimethyl acetylenedicarboxylate, the amines produced ben-zotriazolylaminobutendioates 188 accompanied by A-benzotriazolyl substituted 2-pyridones only in the case of 5-amino-2-methyl-2//-benzotriazole, the triazolo-9,10-dihydrobenzo[d]azepine and an unusual cyclization product, triazolo-2-oxindole (convertible into 2-methyltriazolo[4,5-/]carbostyril-9-carboxylate) were formed. The quinolones 189 were aromatized to chloroesters 190 these in turn were hydrolyzed to chloroacids 191 and decarboxylated to 9-chlorotriazolo[4, 5-/]quinolines 192 (Scheme 58) (93H259). The chlorine atom could be replaced with 17 various secondary amines to give the corresponding 9-aminoalkyl(aryl) derivatives 193, some of which exhibit both cell selectivity and tumor growth inhibition activity at concentrations between 10 and 10 " M (95FA47). 

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. 

In the presence of tetramethyltin, 1-bromonauclefine reacts with CO in a Pd-catalyzed carbonylation to give the alkaloid naucletine [202], Dong and Busacca effected a new synthesis of tryptamines and tryptophols via a Rh-catalyzed hydroformylation of functionalized anilines that are prepared by a standard Heck reaction, as shown for the preparation of tryptamine sulfonamide 325 [423]. This reaction is applicable to ring-substituted tryptamines (Cl, Br, F. OMe, CF3). Likewise, the Rh-catalyzed carbonylation of o-alkynylanilines, which were prepared by a Pd-catalyzed Sonogashira coupling, leads to oxindoles (60-86% yields) [424],... 

Anodic regioselective fluorination of a-phenylsulphenylated ethyl acetates, 1-naphthalene and 2-pyridine derivatives [80], l-aryl-3-(phenylthio)oxindoles and 2-substituted-3-oxo-4-(phenylthio)-l, 2, 3,4-tetrahydroisoquinolines [81], 2-benzo-thiazolyl and 5-chloro-2-benzothiazolyl sulfides [82], a-(phenylsulfenyl)lactams [83], as well as various heterocycles such as thiolanones, oxathiolanones, dithi-olanones, 3Fl-l,4-benzoxathian-2-ones [84] in Et3N-3HF or Etr NF- HF [n = 3,4), has been reported. 

Trost and his co-workers succeeded in the allylic alkylation of prochiral carbon-centered nucleophiles in the presence of Trost s ligand 118 and obtained the corresponding allylated compounds with an excellent enantioselec-tivity. A variety of prochiral carbon-centered nucleophiles such as / -keto esters, a-substituted ketones, and 3-aryl oxindoles are available for this asymmetric reaction (Scheme jg) Il3,ll3a-ll3g Q jjg recently, highly enantioselective allylation of acyclic ketones such as acetophenone derivatives has been reported by Hou and his co-workers, Trost and and Stoltz and Behenna - (Scheme 18-1). On the other hand, Ito and Kuwano... 

Makosza et al.115 have also reported similar reactions with a 3-substituted oxindol and an aryl halide. The reaction occurs only if the aryl halide is activated by an electron-withdrawing substituent. 

Reductive cyclization of o-nitrophenylacetic acids is a very general method of oxindole synthesis (see Section 3.06.2.1.1 for the application of this method to indoles in general). The main problem is efficient construction of the desired phenylacetic acid. One method involves base-catalyzed condensation of substituted nitrotoluenes with diethyl oxalate followed by oxidation of the 3-arylpyruvate (equation 200) (63CB253). Nucleophilic substitution of o-nitrophenyl trifluoromethanesulfonate esters, which are readily prepared from phenols, by dimethyl malonate provides another route (equation 201) (79TL2857). 

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). 

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