Prins using allylsilanes

Aubele et al. studied the aqueous Prins cyclization using cyclic unsaturated acetals as oxocarbenium ion progenitors and allylsilanes are used as nucleophiles. Cyclizations proceed efficiently inside Lewis acidic micelles (of cerium salt) in water. A variety of vinyl- and aryl-substituted tetrahydropyrans with excellent stereocontrol was obtained (Eq. 3.26).113... 

Aldehydes undergo a Mukaiyama-aldol reaction followed by a Prins cyclization with the highly reactive allylsilane 329 to afford jy -2,6-tetrahydropyrans 330 that feature an oeo-methylene group at C-4 (Equation 140, Table 12). This Mukaiyama-aldol-Prins (MAP) cascade cyclization has been used to form a key bis-tetrahydropyran intermediate during the total synthesis of leucascandrolide A <2001JA8420>. Similarly, titanium tetrabromide mediated MAP reactions afford 4-bromo tetrahydropyrans <20030L3163>. 

Coverage in this chapter is restricted to the use of alkenes or alkynes as enophiles (equation 1 X = Y = C) and to the use of ene components in which a hydrogen is transferred. Coverage in Sections 1.2 and 1.3 is restricted to ene components in which all three heavy atoms are carbon (equation 1 Z = C). Thermal intramolecular ene reactions of enols (equation 1 Z = O) with unactivated alkenes are presented in Section 1.4. Metallo-ene reactions are covered in the following chapter. Use of carbonyl compounds as enophiles, which can be considered as a subset of the Prins reaction, is covered in depth in Volume 2, Chtqiter 2.1. Addition of enophiles to vinylsilanes and allylsilanes is covered in Volume 2, Chapter 2.2, while addition of enophiles to enol ethers is covered in Volume 2, Chapters 2.3-2.S. Addition of imines and iminium compounds to alkenes is presented in Volume 2, Part 4. Use of alkenes, aldehydes and acetals as initiators for polyene cyclizations is covered in Volume 3, Chapter 1.9. Coverage of singlet oxygen, azo, nitroso, S=N, S=0, Se=N or Se=0 enophiles are excluded since these reactions do not result in the formation of a carbon-carbon bond. 

The ene and Prins reactions are not mechanistically distinct. Coverage will therefore be organized by the nature of the carbonyl compound, with intermolecular reactions presented first, followed by intramolecular reactions. The emphasis will be on material published since the field has been reviewed " and on examples demonstrating the stereo-, regio- and chemo-selectivity of these reactions. Coverage is restricted to the addition of carbonyl and thiocarbonyl compounds to simple alkenes. Addition of carbonyl compounds to vinylsilanes, allylsilanes and enol ethers is covered in the following chapters. Addition of imines and iminium compounds to alkenes is presented in Part 4 of this volume. Ene reactions with alkenes and alkynes as enophiles are covered in Volume 5, Chapter 1.1. Use of aldehydes and acetals as initiators for polyene cyclizations is covered in Volume 3, Chapter 1.6. 

Wender et al. implemented a Prins reaction in the context of a late-stage macrocyclization event. Treatment of allylsilane aldehyde 158 with TMSOTf gave excellent conversion to 20-membered macrocycle 159 (96 % yield). Keck et al. also disclosed a related intermolecular strategy incorporating an allylsilane and an enal. In the presence of TMSOTf, allylsilane 160 and enal 161 led to macrocyclic precursor 162 in an impressive 84 % yield. The highly functionalized substrates used in these examples underscore the mildness of the reaction conditions. 

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