Subject oxidative rearrangement

Building blocks, useful for supramolecular or material science, have also been prepared using the Boekelheide reaction. Thus bipyridyl derivative 23 was subjected to the standard sequence of reactions (oxidation, rearrangement, and hydrolysis) to afford the diol 24. 

The Ir-catalyzed borylation of the indole nucleus is another important development that promises to find widespread use in complex molecule synthesis. Early reports include the functionalization of C(7) and also of C(2), reported by Malezcka and Smith and by Hartwig, respectively [39, 40]. In a report in 2011, Movassaghi, Miller, and coworkers demonstrated the borylation of tryptamine derivative 61 to afford 62 in 70 % yield [41]. This material was subjected to Suzuki-Miyaura cross coupling with 7-bromoindole (63) to set the stage for studying the oxidative rearrangement of 64, which would eventually provide diketopiperazine indole alkaloids such as asperazine (Scheme 11.11). 

Scheme IS dq>icts a high yield, general method for specific ortho allgriation of polycyclic aromatic hydrocarbons. In this example, biphenyl is subjected to reductive methyladon followed by oxidative rearrangement with trityl tetrafiuoioborate to give 2-methylbipbenyl. In unsymmetrical substrates the regioselectivity is poor, phenanthiene gives a 3 2 mixture of 4-methyl- and 1-mediyI-phenanlhrene.

In 1975 Tamura et al. reported on the synthesis of two allyhc sulfoximines (25a and 25b) via oxidative imination using 0-mesitylenesulfonyl hydroxy-lamine (MSH) (Scheme 3) [11]. Both compounds are described as thermally stable, contrasting the behavior of the corresponding suMmines (Sect. 3.6, Type L). Interestingly, 4 years later Johnson et al. pointed out that sulfoximine 25c is readily subject to rearrangement and/or C - S bond heterolysis [12]. 

Aqueous permanganate converts l,3-dibenzyl-2-phenylimidazolidine into a mixture of benzamide and benzoic acid. When l-alkyl-3-phenylimidazolidines are subjected to N-oxidation the unstable JV-oxides rearrange to give tetrahydro-l,2,5-oxadiazines (180) via the ring-opened product (Scheme 89) (77LA956). 

The reaction between the acid chloride of chromone-2-carboxylic acid and ethyl ethoxymagnesioacetoacetate probably leads to the expected fi-diketone which enolizes and cyclizes spontaneously to spirofuranone(52).127 A different approach was made by Hungarian workers in their synthesis of tachrosin (53), an unusual kind of flavone isolated from Tephrosia poly-stachyoides and one of the earliest natural furanones to be isolated. They subjected an unsaturated ketone (Scheme 32) to oxidative rearrangement by thallium(III) salts, a reaction well known in chalcone chemistry, and eliminated methanol from the product to obtain the necessary starting material.128... 

N-6-Demethylated ergolines were first allylated, then oxidised to 6-allyl oxides which were subjected to rearrangement to N-6-allyloxy derivatives—Figure 8 (Nordmann and Gull, 1986). Nordmann and Loosli (1985) prepared N-6-carboxamidines from 6-cyano-6-norergolines. 

A large variety of organic oxidations, reductions, and rearrangements show photocatalysis at interfaces, usually of a semiconductor. The subject has been reviewed [326,327] some specific examples are the photo-Kolbe reaction (decarboxylation of acetic acid) using Pt supported on anatase [328], the pho-... 

The cycloadducts formed from the Diels-Alder reaction of 3-amino-5-chloro-2(17/)-pyrazinones with methyl acrylate in toluene are subject to two alternative modes of ring transformation yielding either methyl 6-cyano-l,2-dihydro-2-oxo-4-pyridinecarboxylates or the corresponding 3-amino-6-cyano-l,2,5,6-tetrahydro-2-oxo-4-pyridinecarboxylates. From the latter compounds, 3-amino-2-pyridones can be generated through subsequent loss of HCN <96 JOC(61)304>. Synthesis of 3-spirocyclopropane-4-pyridone and furo[2,3-c]pyridine derivatives can be achieved by the thermal rearrangement of nitrone and nitrile oxide cycloadducts of bicyclopropylidene <96JCX (61)1665>. 

Attempts to initiate formation of a nitrene, and its rearrangement to the iminooxo-phosphorane 80, by subjecting l-chloroamino-2,2,3,4,4-pentamethylphosphetane 1-oxide to a-elimination with sodium methoxide proved unsuccessful48). In contrast, however, the phosphorylhydroxylamides 88 rearrange in the presence of tert-butyl-amine to the heterocumulene 89 and then add base to give the phosphonic diamides 90 (>90%)49). The reaction is reminiscent of the well-known Lossen degradation. 

The use of m-CPBA allows the formation of nitrones in the oxidation of tertiary amines. The resulting amines A-oxides are subject to either Cope or Meisenheimer rearrangements, providing formation of nitrones. Thus, the generated corresponding nitrones in the oxidation of bicyclic aziridines give nitrones as a result of a Meisenheimer rearrangement (Scheme 2.14) (93). 

Arylindenes undergo sigmatropic 1,5-shifts, induced oxidatively [267], thermally [268], photochemically [269], and re-ductively [270]. The reductive rearrangement of 1,1,3-triphenylindene, yielding the dianion of l,2,3-triphenyl-2H-indene, has been the subject of voltammetric investigations in DMF-TBAP [271]. The reaction follows an EEC or EDisp C pathway. 

A rearrangement process analogous to that involved in conversion 323 to 324 (Scheme 83) occurs when several 2,2-dialkyl-substituted chroma-nones 334 are subjected to oxidation with HTIB. The reaction involving a... 

In a study of the addition of nitrosyl chloride or nitrosyl bromide to norbor-nene and norbomadiene, it was observed that (a) there was no structural rearrangement during the reaction, (b) a cis addition had taken place, (c) nucleophilic solvents such as ethanol or acetic acid were not incorporated in the products. These facts seem to speak against an ionic addition mechanism, while a free radical initiated by NO radicals was considered unlikely since nitric oxide is inactive toward norbomadiene. Therefore a four-center mechanism has been suggested [70], However, when a relatively simple, unstrained olefin such as A9-octalin was subjected to the reaction, only blue, crystalline, monomeric 9-nitroso-10-chlorodecalin was produced. This product had a trans configuration. Thus it is evident that the structure of the olefin has a significant bearing on the steric course of the addition [71]. 

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