Intramolecular oxidative coupling

Oxidation of thiol 287 with air in glyme gave disulfide 288, which on intramolecular oxidative coupling with A,)V-dibromoisocyanurate formed macrocycle 289 in 42% yield (Scheme 188) (99MI3). 

In the event, treatment of a rapidly stirred solution of 3 and sodium acetate in MeOH-tbO at 38 °C with PdCl2 results in the fomation of carpanone (1) in 46% yield. The ordered unimolecular transition state for the oxidative coupling reaction furnishes putative bis(quinodimethide) 2 stereoselectively. Once formed, 2 readily participates in an intramolecular Diels-Alder reaction4 to give carpanone (1). Two new rings and all five contiguous stereocenters are created in this spectacular sequential transformation.5... 

Cyclopentene, cyclohexene, and cycloheptene were obtained by intramolecular oxidative couplings of the bis-ylides (161 n = 3, 4, or 5) but oxidation of (161 n = 2) gave cyclo-octa-1,5-diene. Oxidation of the bis-ylide (161 n — 8) gave cyclic polyenes containing 20, 30, 40, 50, and 60 atoms. 

Antioxidant capacities of common individual curcuminoids were determined in vitro by phosphomolybdenum and linoleic acid peroxidation methods. Antioxidant capacities expressed as ascorbic acid equivalents (pmol/g) were 3099 for curcumin, 2833 for demethoxycurcumin, and 2677 for bisdemethoxycurcumin at concentrations of 50 ppm. The same order of antioxidant activity (curcumin > demethoxycurcumin > bisdemethoxycurcumin) was observed when compared with BHT (buty-lated hydroxyl toluene) in linoleic peroxidation tests. The antioxidant activity of curcumin in the presence of ethyl linoleate was demonstrated and six reaction products were identified and structurally characterized. The mechanism proposed for this activity consisted of an oxidative coupling reaction at the 3 position of the curcumin with the lipid and a subsequent intramolecular Diels-Alder reaction. ... 

Proton-coupled intramolecular electron transfer has been investigated for the quinonoid compounds linked to the ferrocene moiety by a 7r-conjugated spacer, 72 (171) and 75 (172). The complex 72 undergoes 2e oxidation in methanol to afford 74, which consists of an unusual allene and a quinonoid structure, with the loss of two hydrogen atoms from 72 (Scheme 2). The addition of CF3SO3H to an acetonitrile solution of 74 results in two intense bands around 450 nm, characteristic of a semi-quinone radical, and a weak broad band at lOOOnm in the electronic... 

Chan has discovered a completely atropdiasteroselective synthesis of a biaryl diphosphine by asymmetric intramolecular Ullmann coupling or Fe(m)-promoted oxidative coupling. A chiral atropisomeric biaryl bisphosphine ligand 2 was synthesized through this central-to-axial chirality transfer.38 Recently, a xylyl-biaryl bisphosphine ligand, Xyl-TetraPHEMP, was introduced by Moran, and is found to be effective for the Ru-catalyzed hydrogenation of aryl ketone.39... 

C-C bond formation mediated by silane.6,6a 6f With respect to the development of intramolecular variants, these seminal studies lay fallow until 1990, at which point the palladium- and nickel-catalyzed reductive cyclization of tethered 1,3-dienes mediated by silane was disclosed. As demonstrated by the hydrosilylation-cyclization of 1,3,8,10-tetraene 21a, the /rarcr-divinylcyclopentanes 21b and 21c are produced in excellent yield, but with modest stereoselectivity.46 Bu3SnH was shown to participate in an analogous cyclization.46 Isotopic labeling and crossover experiments provide evidence against a mechanism involving initial diene hydrosilylation. Rather, the collective data corroborate a mechanism involving oxidative coupling of the diene followed by silane activation (Scheme 15). 

The oxidative coupling/cyclization process occurs via stoichiometric carbo-palladation using a Pd(II) species, typically Pd(OAc)2. In an early example, submission of diphenylamines 3 to the palladium(II)-promoted oxidative intramolecular cyclization conditions yielded carbazoles 4 [15-... 

A)-Ketorolac 132, a nonsteroidal anti-inflammatory dmg (NSAID), was synthesized in a two-step procedure based on an intramolecular oxidative coupling of pyrrole at the C-2 position with a chiral sultam enolate 130 leading to dihydropyrrolizine 131 as a 4.5 1 mixture of epimers (Scheme 23). Subsequent benzoylation, performed on the crude... 

There is ample evidence that the reductive elimination of alkanes (and the reverse) is a not single-step process, but involves a o-alkane complex as the intermediate. Thus, looking at the kinetics, reductive elimination and oxidative addition do not correspond to the elementary steps. These terms were introduced at a point in time when o-alkane complexes were unknown, and therefore new terms have been introduced by Jones to describe the mechanism and the kinetics of the reaction [5], The reaction of the o-alkane complex to the hydride-alkyl metal complex is called reductive cleavage and its reverse is called oxidative coupling. The second part of the scheme involves the association of alkane and metal and the dissociation of the o-alkane complex to unsaturated metal and free alkane. The intermediacy of o-alkane complexes can be seen for instance from the intramolecular exchange of isotopes in D-M-CH3 to the more stable H-M-CH2D prior to loss of CH3D. 

ET-induced cycloadditions of polycyclic olefins and cycloreversions of cyclobutane species have been studied by ESR spectroscopy [266]. Upon chemical and electrochemical reduction, 2,2 -distyrylbiphenyl rearranges by intramolecular coupling into a bis-benzylic dihydrophenanthrene dianion (Scheme 1), which can be either protonated to a 9,10 -dibenzyl-9,10-dihydrophenanthrene or oxidatively coupled to a cyclobutane species. It is interesting to note that the intramolecular bond... 

Intramolecular oxidative coupling of silylated phenols 251 with IBTA leads to the formation of spiropiperidine derivatives 253, called aza-anthraquinone-spirodienones (89TL1119) (Scheme 64). The first step of this conversion is the electrophilic attack of reagent on the phenolic group to give intermediate 252. Intramolecular C—C bond formation leads... 

Retrosynthetic analysis of carbazoquinocin C (274) and (+ )-carquinostatin A ( + )-278 based on our highly convergent palladium(II)-mediated intramolecular oxidative coupling of arylamino-l,2-benzoquinones provides aniline (839) and 4-heptyl-3-methyl-l,2-benzoquinone (946) as precursors for 274, and 4-prenylaniline (945) and 4-(2-hydroxypropyl)-3-methyl-l,2-benzoquinone (947) as precursors for ( + )-278 (646) (Scheme 5.126). 

A very large number of these systems with ring junction heteroatoms exists, and this number is constantly increasing. Only illustrative examples of the preparation of such systems can be given here. The synthetic methods for the formation of this type of heterocycle can be usefully classified as follows (i) various cyclocondensations between the corresponding heterocyclic derivatives and bifunctional units, (ii) intramolecular cyclizations of electrophilic, nucleophilic or (still rare) radical type, (iii) cycloadditions, (iv) intramolecular oxidative coupling, (v) intramolecular insertions, (vi) cyclization of open-chained predecessors, (vii) various reactions (quite often unusual) which are specific for each type of system. Examples given below illustrate all these cases. 

Morphine is biosynthesized from norreticuline through intramolecular oxidative coupling of the electron-rich aromatic rings, transformation that is difficult to achieve with chemical oxidizing agents. The most convenient synthesis, illustrated in Scheme 23, consists of partial saturation of the aromatic ring by the Birch reaction followed by an acid-Catalyzed Grewe-type cyclization to form the required tetracyclic skeleton (48). 

Table 2 Intramolecular Thallium Trinitrate Oxidative Coupling 17-19 ...

Marc-Andre Poupart, Gilbert Lassalle, and Leo A. Paquette 173 INTRAMOLECULAR OXIDATIVE COUPLING OF A BISENOLATE 4-METHYLTRICYCLO[2.2.2.035]-OCTANE-2.6-DIONE... 

The use of hypervalent iodine reagents in carbon-carbon bond forming reactions is summarized with particular emphasis on applications in organic synthesis. The most important recent methods involve the radical decarboxylative alkylation of organic substrates with [bis(acyloxy)iodo]arenes, spirocyclization of para- and ortho-substituted phenols, the intramolecular oxidative coupling of phenol ethers, and the reactions of iodonium salts and ylides. A significant recent research activity is centered in the area of the transition metal-mediated coupling reactions of the alkenyl-, aryl-, and alkynyliodonium salts. 

Oxidative homocoupling of aromatic and heteroaromatic rings proceeds with Pd(OAc)2 in AcOH. Biphenyl (165) is prepared by the oxidative coupling of benzene [104,105], The reaction is accelerated by the addition of perchloric acid. Biphenyl-tetracarboxylic acid (169), used for polyimide synthesis, is produced from dimethyl phthalate (168) commercially [106], Intramolecular coupling of the indole rings 170 is useful for the synthesis of staurosporine aglycone 171 [107]. 

Acetals result from oxidative coupling of alcohols with electron-poor terminal olefins followed by a second, redox-neutral addition of alcohol [11-13]. Acrylonitrile (41) is converted to 3,3-dimethoxypropionitrile (42), an intermediate in the industrial synthesis of thiamin (vitamin Bl), by use of an alkyl nitrite oxidant [57]. A stereoselective acetalization was performed with methacrylates 43 to yield 44 with variable de [58]. Rare examples of intermolecular acetalization with nonactivated olefins are observed with chelating allyl and homoallyl amines and thioethers (45, give acetals 46) [46]. As opposed to intermolecular acetalizations, the intramolecular variety do not require activated olefins, but a suitable spatial relationship of hydroxy groups and the alkene[13]. Thus, Wacker oxidation of enediol 47 gave bicyclic acetal 48 as a precursor of a fluorinated analogue of the pheromone fron-talin[59]. 

These ligands can be prepared by two methods demethylation of enantiomerically pure MeO-BIPHEP (96a) followed by alkylation with the corresponding dihalide to form the cyclic diether backbone (Scheme 12.40)134 or an intramolecular Fe(III)-promoted oxidative coupling of a meta-substituted bis(arylphosphine oxide) connected by a 1,3-propoxyl unit followed by resolution with DBTA and reduction to the bisphosphines (Scheme 12.41).133... 

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