Allyl additions allylsilane reagents

The class of 3-silyl-substituted reagents provides, upon addition with aldehydes, allylic silanes that offer many options for further derivatization. Oxidative processes are described in previous sections (see the sections on Preparation of 1,2-Diols and 1,4-Diols). If the appropriate silicon substituents are chosen, formal [3+2] cycloadditions with aldehydes can be promoted under Lewis acid catalysis. For example, the mismatched addition of the Z-3-propyl-3-benzhydryldimethyl allylsilane 183 to an a-benzyloxy aldehyde proceeds with low diastereofacial selectivity in favor of product 184 however, after protection of the secondary alcohol, an efficient [3+2] annulation provides the polysubsubstituted furan 185 in good yield and acceptable stereoselectivity (Scheme 24). ° The latter is brought forward to a tricyclic unit found in the antitumor natural product angelmicin B. 

Allyl- and vinylsilane chemistry was one of the first areas of reagent synthesis impacted by CM methodology. Allylsilanes are commonly employed in nucleophilic additions to carbonyl compounds, epoxides, and Michael acceptors (the Sakurai reaction) vinylsilanes are useful reagents for palladium-coupling reactions. As the ubiquitous application of CM to this substrate class has recently been described in several excellent reviews, this topic will not be discussed in detail, with the exception of the use of silane moieties to direct CM stereoselectivity (previously discussed in Section 11.06.3.2). 

In addition to allylsilanes, CM can also be applied to allylstannanes, which serve as valuable reagents for nucleophilic additions and radical reactions.To date, only eatalyst 1 has been shown to demonstrate CM reactivity in the preparation of 1,2-disubstituted allylstannanes, as ruthenium catalysts were found to be inactive in the presence of this substrate class.Poor stereoselectivities were generally observed, with the exeeption of one instance of >20 1 Z-selectivity in the reaction of allyltributylstannane with an acetyl-protected allyl gluco-side. 

The Lewis acid catalyzed conjugate addition of allylsilanes (140) to (142) and allylstannanes (154) and (155) to ot,0-enones, described by Sakurai,68a,68b is highly efficient and experimentally simple in contrast to the allylcuprate additions. Various substituents can be incorporated into the allylsilanes (allylstannanes), e.g. alkoxy, alkoxycarbonyl and halogen, some of which are incompatible with cuprate reagents 69 In addition, Heathcock and Yamamoto report that diastereoselectivity is correlated to the alkene geometry of both the allylmetals and the acceptor units for example, allylation of ( )-enones (143) and (146) affords predominantly the syn adducts (144) and (147), while (Z)-enone (149) gives predominantly the anti adduct (150 Scheme 25).680 On the other hand, with cyclohexen-2-one the (Z)-silane (141) affords predominantly the threo adduct (152), while (142) affords erythro adduct (ISS).686 The more reactive allylstannanes (154) and (155) also afford similar diastereoselectivity.68e,f... 

Annelation.1 This reagent is used for conversion of 3-substituted aldehydes (or acetals) into methylenecyclohexanes. The conversion involves addition of the allylsilane group to the aldehyde or acetal to provide an adduct that undergoes radical cyclization via the allylic sulfide group. The phenylthio group is used to enhance 6-endo cyclization over the usual 5-exo cyclization. In addition it allows use of bis(tributyltin) as the initiator (14,173-174). Unfortunately the radical cyclization shows only slight stereoselectivity. 

The effects of the cr—JT interaction on the ground-state properties of allyltrimethylmetal compounds are paralleled by the effect on reactivity towards electrophilic reagents. Mayr demonstrated that allyltrialkylsilanes, allyltrialkyl-germanes, and trialkylstannanes react with diphenylcarbenium ions at rates 105,5.6 x 105, and 109, respectively, relative to propene.158 The reaction rates were also found to be sensitive to the inductive effects of the other substituents attached to the metal. A theoretical evaluation of the factors determining the regiochemistry and stereochemistry of electrophilic addition to allylsilanes and other allyl systems is reported by Hehre et al.159 They predict a preference for electrophilic attack anti with respect to the silane substituent, a prediction that is supported by many experimental studies.82,160... 

Several methods promoted by a stoichiometric amount of chiral Lewis acid 38 [51] or chiral Lewis bases 39 [52, 53] and 40 [53] have been developed for enantioselective indium-mediated allylation of aldehydes and ketones by the Loh group. A combination of a chiral trimethylsilyl ether derived from norpseu-doephedrine and allyltrimethylsilane is also convenient for synthesis of enan-tiopure homoallylic alcohols from ketones [54,55]. Asymmetric carbonyl addition by chirally modified allylic metal reagents, to which chiral auxiliaries are covalently bonded, is also an efficient method to obtain enantiomerically enriched homoallylic alcohols and various excellent chiral allylating agents have been developed for example, (lS,2S)-pseudoephedrine- and (lF,2F)-cyclohex-ane-1,2-diamine-derived allylsilanes [56], polymer-supported chiral allylboron reagents [57], and a bisoxazoline-modified chiral allylzinc reagent [58]. An al-lyl transfer reaction from a chiral crotyl donor opened a way to highly enantioselective and a-selective crotylation of aldehydes [59-62]. Enzymatic routes to enantioselective allylation of carbonyl compounds have still not appeared. 

Diethyl[dimethyl(phenyl)sUyl aluminum. ( HjlCHOiSiAUC H,), (1). The aluminum reagent is prepared in situ by addition of (C HO AICl to QHdCHdiSiLi in THF at 0°. The reagent converts allylic phosphates into allylsilanes. Rearrangement products can be formed from unsymmetrical allylic phosphatc>... 

In this synthesis of 1,5-dicaibonyl compounds, 3-butenyl halide is behaving as a madced 3-oxobutyl reagent, and can be used as an equivalent of metiiyl vinyl ketone. These reactirais offer new anellation methods. Also 1,4-addition of the allyl group to enones, followed by oxidatitm. offers a conveiuent synthetic method for 1,5-diketone preparation. Lewis acid promoted Nfichael addition of allylsilane (48) to a,p-unsaturated ketones, followed by the palladium-catalyzed oxidation, affods 1,5-diketones (Scheme 17). 3... 

The 1,5-diketone formation by the Michael addition of allylsilane (48) to a, -unsaturated ketones was applied to the synthesis of (+)-nootkatone. Reaction of the keto group of keto aldehyde (58) with allyl Orignard reagent and dehydration gave the diene aldehyde (59). The selective oxidation of the terminal double bond afforded the 1,5-dica nyl compound (60), which is not stable and converted directly to pyridines and phenols (Scheme 18). ... 

Other important feature of the allylsilane-TiC reagent system can be seen in 1,4-addition of an allyl group to a,/3-unsaturated ketones [248,249], illustrated in Eq. (94) [249]. This reaction has been reviewed [2,3,110,159-161,250] more examples can be seen in Table 9. 

In addition to Ni and Pd catalysts, Li2CuCU is also an effective catalyst for the coupling of alkenyl iodides with Grignard reagents. Since the stereochemistry of alkenyl iodides is also retained, the coupling reactions are useful for the stereoselective synthesis of disubstituted alkenes, - trisubstituted al-kenes, allylsilanes, allyl alcohols and tetrasubstituted alkenes (equations 25-29). ... 

The enantioselective asymmetric allylation of imines has been a synthetic challenge, the initial solutions of which required stoichiometric amounts of chiral allylbor on [87], allylsilane [88], allylzinc [89], or allylindium reagents [90]. Itsuno showed that a chiral B allyloxazaborolidine derived from norephedrine could add to the N trimethylsilyl imine prepared from benzaldehyde in high yield and enantiomeric excess (Scheme 1.22) [91]. Brown later reported that B allyldiisopinocamphenylbor ane is also very effective for the allylation of the same electrophiles, but the addition of a molar amount of water is necessary to obtain high yields [92]. The diastereo and... 

The electrochemical a-cyanation of 1,2,3,4-tetrahydroquinoline has been investigated <97LA2089>. The quinolin-4-one 40 is substituted by conversion to the 4-silyloxyquinolinium triflate and 1,4-addition of the organo-magnesium or lithium reagent <97SL313>. The triflate ion-promoted addition of allylsilane onto the 2-position of quinolines acylated by chloroformate esters affords the 2-allyl-l,2-dihydroquinoline (Scheme 12) <97TL403>. 

The ( -y-(silyl) allyl boronates 47 and 48 were subsequently introduced in order to access more highly oxygenated aldehyde addition products. For example, the allylic silane addition products can undergo subsequent oxidation to provide 1,2- and 1,4-diol products. The allylsilane products are also allylmetal reagents Roush and co-workers have demonstrated their ability to undergo addition reactions with Lewis acid activated aldehydes to form tetrahydrofuran products. ... 

In order to access the 1,2-anti diol oxidation product, (E)-y-[(menthofuryl)dimethylsilyl]allyl boronate 48 was designed. This reagent reacts selectively with chiral aldehydes to form addition products with useful levels of selectivity. Fleming-Tamao oxidation of the allylsilane addition products provides 1,2-anti diols without substantial Peterson elimination. 

A zinc-silver couple has been reported to be an improved reagent for the reductive addition of allylic bromides to nitriles. l-Trimethylsilyl-2-methyl-cyclopropane is a convenient regio- and stereospecific precursor of unsaturated ketones [equation (37)]. The reaction of allylsilanes with a-nitro-olefins has been found to proceed smoothly in the presence of aluminium trichloride [equation (38)]. The unstable nitronic acid product may be converted readily into the unsaturated ketone by the Nef reaction. 

Miscellaneous Reactions. AICI3 has been used to catalyze the addition of allylsilanes to aldehydes and acid chlorides (eq 37). Cyclic ethers (pyrans and oxepins) have been prepared with hy-droxyalkenes (eq 38). The course of reactions between aldehydes and allylic Grignard reagents can be completely diverted to a-allylation by AICI3 (eq 39). The normal course of the reaction gives y-allylation products. 

This book chapter is limited to Lewis acid-mediated reactions, and does not discuss the important field of Lewis base-mediated allylations, nor does it describe the reactions of allylsilanes with other electrophiles such as epoxides, imines, and allyl-X (X = -Cl, -OR, -OAc). The SaJcurai reaction has been covered under different forms in reviews focusing on The Stereochemistry of the Sakurai reaction , Intramolecular Addition Reactions of Allylic and Propargylic Silanes ," Selective Reactions Using Allylic Metals , Catalytic Enantioselective Addition of Allylic Organometallic Reagents to Aldehydes and Ketones , and Modem Carbonyl Chemistry . ... 

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