Chiral iodonium salts

Tetraphenylstannane was the reagent of choice for the conversion of two chiral precursors, i.e. 2-(diacetoxyiodo)- and 2,2 -bis(diacetoxyiodo)-l,r-binaph-thyls, into chiral iodonium salts (Scheme 35) [106]. 

Chiral iodonium salts of the general type p-RC6H4C = CI+Ph X-, where R was S-2-methylbutyloxy or S-2-methylbutyloxycarbonyl and X was TsO or TfO, were prepared from silylated alkynes with either [hydroxy(tosyloxy)iodo]benzene or PhI(OTf)OI(OTf)Ph [138]. 

Asymmetric phenylation of carbanions with chiral iodonium salts has recently been reported [70]. The chiral diiodonium salt 93 selectively reacts with potassium enolate of l-oxo-2-indancarboxylate 92 to give the a-phenylated indanone 94 with moderate enantioselectivity (Scheme 42). 

Although formation of primary vinyl cation was disproved by the chirality probe approach, a vinyl cationic intermediate can be generated from a primary substrate via participation if a more stable cation could result. Unsymmetrically substituted 2,2-dialkylvinyl iodonium salt 24 gave mainly rearranged products on solvolysis.15 The products involve those of the 1,2-shift of either of the alkyl groups on the p position (Scheme 4). Those formed from migration of the alkyl... 

A new type of iodonium salts constitute the conformationally rigid, tetranu-clear macrocyclic ring systems dubbed molecular boxes. The relatively simpler tetraaryltetraiodonium salts were obtained from 4,4 -bis(diacetoxyiodo)bi-phenyl and 4,4 -bis(trimethylsilyl)biphenyl [119]. The iodonium salt derived from 4-(4 -lithiophenyl)pyridine was made using the method of /J-(dichloroio-do)chloroethylene and it was used for the construction of hybrid iodonium-platinum (or palladium) cationic tetranuclear macrocyclic squares including some in which the ligand of the metal was a chiral biphosphine [120,121]. 

A similar procedure was employed in the asymmetric Heck-type coupling of iodonium salt 81 with 2,3-dihydrofuran (Scheme 38) [65]. When carried out in the presence of the chiral bidentate ligand (R)-BINAP, this reaction afforded optically active (up to 78% ee) coupling product 82 in moderate yield. 

Alkynyl(phenyl)iodonium salts can be used for the preparation of substituted alkynes by the reaction with carbon nucleophiles. The parent ethynyliodonium tetrafluoroborate 124 reacts with various enolates of /J-dicarbonyl compounds 123 to give the respective alkynylated products 125 in a high yield (Scheme 51) [109]. The anion of nitrocyclohexane can also be ethynylated under these conditions. A similar alkynylation of 2-methyl-1,3-cyclopentanedione by ethynyliodonium salt 124 was applied in the key step of the synthesis of chiral methylene lactones [110]. 

Aggarwal and Olofsson have developed a direct asymmetric a-arylation of prochiral ketones using chiral lithium amide bases and diaryliodonium salts [881]. In a representative example, the deprotonation of cyclohexanone derivative 684 using chiral Simpkins (/ ,/ )-base followed by reaction with the pyridyl iodonium salt gave the arylated product 685 in 94% ee (Scheme 3.275). This reaction has been employed in a short total synthesis of the alkaloid (-)-epibatidine [881]. 

Asymmetric a-functionalization of carbonyl compounds with iodine(lll) reagents is discussed in Chap. 639 and in a recent review [178], and is only briefly covered here. Asymmetric a-arylations with chiral diaryliodonium salts have proven to be difficult to achieve, both because of complicated synthetic routes to chiral, unsymmetric salts with suitable dummy groups, and because of the modest enantioselectivities observed in the arylations [188, 189]. Ochiai and coworkers reported the only successful example to date, where 1,1 -binaphthyl-derived iodonium salts gave chemo- and enantioselective arylation of p-ketoesters in up to 53% ee (see Scheme 7 in Chap. X) [190]. 

Stereoselective carbon-carbon bond formations with hypervalent iodine reagents are also prominently described in the literature. Direct asynunetric a-arylation reactions are not easy to perform. Ochiai et al. synthesized chiral diaryliodonium salts such as [l,l -binaphthalen]-2-yl(phenyl)iodonium tetrafluoroborate derivatives 21 via a BFs-catalyzed tin-X -iodane exchange reaction and developed the direct asymmetric a-phenylation of enolate anions derived from cyclic p-ketoesters (Scheme 7) [37]. A beautiful example of direct asymmetric a-arylation of cyclohexanones in the course of a natural product synthesis was presented through the desymmetrization of 4-substituted cyclohexanones using Simpkin s base, followed by coupling with diaryliodonium salts [38]. Other binaphthyl iodonium salts related to 21 have also been reported [39]. 

Allen and MacMillan demonstrated the introduchon of a trifluoromethyl group at the a-position of enolizable aldehydes by a simple deployment of the corresponding iodonium salts [41]. Enamines of enolizable aldehydes and chiral imidazolidin-4-ones react with trifluoromethyl-benziodoxole in the presence of catalytic amounts of Lewis acids to give a-trifluoromethylated aldehydes with high degrees of enantioselectivities (Scheme 4.11). 

Several iodonium ylides, thermally or photochemically, transferred their carbene moiety to alkenes which were converted into cyclopropane derivatives. The thermal decomposition of ylides was usually catalysed by copper or rhodium salts and was most efficient in intramolecular cyclopropanation. Reactions of PhI=C(C02Me)2 with styrenes, allylbenzene and phenylacetylene have established the intermediacy of carbenes in the presence of a chiral catalyst, intramolecular cyclopropanation resulted in the preparation of a product in 67% enantiomeric excess [12]. 

Interest in the synthesis and reactivity of the six-membered, potentially aromatic, phosphinine ring system has also continued, but at a much lower level than in recent years. New synthetic work includes the application of the pyrylium salt route to phosphinine synthesis, this time starting from pyrylium salts bearing chiral substituents to give the related chiral phosphinines," and the development of new routes to the 2-phosphanaphthalene (137)" ° and the phosphinine-2-aldehyde (138). Also reported is an approach to the synthesis of l,2-dihydro-l,4,2-benzo-diazaphosphinines," cationic gold(I) complexes of 2,4,6-tri-t-butyl-l,3,5-triphosphabenzene," and the synthesis of some X -phosphinines from phosphonium-iodonium ylides." " ... 

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