Intramolecular silicon tethers

A synthetic method for the introduction of an ethynyl group in cyclic structures is based on an intramolecular silicon-tethered radical cyclization with iodine transfer (Scheme 25.8). For example, starting from alkyne 10, a triethyl borane-initiated process allows a radical formation and cyclization to give the alkenyl radical 11. An iodine atom is abstracted from the starting material to give the alkenyl iodide 12, thus, propagating the chain. Treatment of 12 with tetra-/j-butylammonium fluoride (TBAF) results in elimination to furnish 13 in good yields. 

Intramolecular reactions of temporarily silicon-tethered molecules in synthesis of 0,Si-heterocycles 97S813. 

Difunctional reagents, for example the very cheap dimethyldichlorosilane 48, which is produced on a large technical scale, and the much more reactive and expensive dimethylsilyl bis(O-triflate) 49 [65-67] (Scheme 2.8) convert alcohols or phenols 11 in the presence of bases, for example triethylamine or DBU, into the silylated compounds 50. Thus 48 and 49 and other bifunctional reagents such as di-tert-butyldichlorosilane [68] or di(tert-butylsilyl)-bis(0-triflate) [69] and the subsequently described 51 and 52 combine two alcohols to silicon-tethered molecules 50, which can undergo interesting intramolecular reactions [70-74]. 

Cyclic alkyl nitronates may be used in tandem [4+2]/[3+2] cycloadditions of nitroalkanes, and this reaction has been extensively studied by Denmark et al. (64,333-335). In recent work, they developed the silicon-tethered heterodiene-alkene 219 (Scheme 12.63). Steric hindrance and the fact that both the nitroalkene and the a,p-unsaturated ester in 219 are electron deficient renders the possibility of self-condensation. Instead, 219 reacts with the electron-rich chiral vinyl ether 220 in the presence of the catalyst 224 to form the intermediate chiral nitronate 221. The tandem reaction proceeds from 221 with an intramolecular 1,3-dipolar cycloaddition to form 222 with 93% de. Further synthetic steps led to the formation of ( )-detoxinine 223 (333). A similar type of tandem reaction has also been applied by Chattopadhyaya and co-workers (336), using 2, 3 -dideoxy-3 -nitro-2, 3 -didehydrothymidine as the starting material (336). 

J. C. Lopez, A. M. Gomez, and B. Fraser-Reid, Silicon-tethered radical cyclization and intramolecular Diels-Alder strategies are combined to provide a ready route to highly functionalized decalins, J. Chem. Soc. Chem. Comtmm. p. 762 (1993). 

Z. Xi, J. Rong, and J. Chattopadhyaya, Diastereospecific synthesis of 2 - or 3 -C-branched nucleosides through intramolecular free-radical capture by silicon-tethered acetylene, Tetrahedron 50 5255 (1994). 

Intramolecular anodic olefin coupling reactions involving allyl- (equation 18) and vinyl-silanes (equation 19) can lead to good yields of quaternary carbons with control of the relative stereochemistry19,20. This is the first example of an electrochemical reaction that makes use of a temporary silicon tether. 

A silicon-tethered [5+2] intramolecular cycloaddition of vinylsilane moiety to apyrone ring to 220 has been executed in regio- and stereoselective manners (equation 181)326. 

Silicon-tethered intramolecular carbonyl-ene reactions of vinylsilanes have been shown to generate methylene silacyclohexanols 232 stereoselectively in good yield (equation 190)340. 

Scheme 18. Examples of silicon tethered intramolecular reactions.

Curran and co-workers have explored the use of silicon tethers to carry out these reactions. They have successfully demonstrated the 1,5 and 1,6 translocation of a radical that goes on to do intramolecular cyclization reactions. This method was used to synthesize natural product such as crinipellin A22 and 2-(o)-(2-bromoaryl)dimethylsilyl-a-methyl-D-mannopyranoside.24 One of the nice benefits to the use of silicon tethers is that they serve as a hydroxyl-protecting group before and after the reaction is performed. 

When ethylene glycol was used instead of (-)-hydroxybenzoin (step e) in the preparation of the silicon tether, the intramolecular Diels-Alder reaction of step h proceeded with reverse diastereoselectivity, affording a mixture corresponding to 6 7 in a 1 10 ratio. Give an explanation for this finding. 

A diastereoselective formal addition of a 7ra i-2-(phenylthio)vmyl moiety to a-hydroxyhydrazones through a radical pathway is shown in Scheme 2.29. To overcome the lack of a viable intermolecular vinyl radical addition to C=N double bonds, not to mention a reaction proceeding with stereocontrol, this procedure employs a temporary silicon tether, which is used to hold the alkyne unit in place so that the vinyl radical addition could proceed intramolecularly. Thus, intermolecular addition of PhS" to the alkyne moiety in the chiral alkyne 161 leads to vinyl radical 163, which cyclizes in a 5-exo fashion, according to the Beckwith-Houk predictions, to give aminyl radical 164 with an a 7z-arrangement between the ether and the amino group. Radical reduction and removal of the silicon tether without prior isolation of the end product of the radical cyclization cascade, 165, yields the a-amino alcohol 162. This strategy, which could also be applied to the diastereoselective synthesis of polyhydroxylated amines (not shown), can be considered as synthetic equivalent of an acetaldehyde Mannich reaction with acyclic stereocontrol. 

Analogously, intramolecular hydrosilation reactions have been carried out with alkenes cyclization of alkenyloxy-silanes catalyzed by thiols <1998J(P1)467> and by Pt <1996TL827> has been described. In addition, intramolecular temporary silicon-tethered rhodium-catalyzed [4- -2- -2]-cycloisomerization reactions have been carried out by Evans and Bawn (Equation 50) <2004JA11150>. 

Bols, M, Efficient stereocontrolled glycosidation of secondary sugar hydroxyls by silicon tethered intramolecular glycosidation, Tetrahedron, 49, 10049-10060, 1993. 

Silicon tethers can be used to bring about close proximity of cyclopentadienyl and benzyne groups such that intramolecular cycloadditions take place to give products of type 195 (Scheme 49). The linking unit can then be removed to furnish unsymmetrical C-aryl glycosides <2003JA12994>. 

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