YAMAMOTO Allylation

RCM was also used in Yamamoto s total synthesis of the marine neurotoxin gambierol (81) [62], to close the central seven-membered E ring, thereby completing the octacyclic polyether core 80 (Scheme 15). Following previously developed methodology [63], metathesis precursor 79 was produced as the major epimer, by boron trifluoride etherate-mediated intramolecular allylation of a-chloroacetoxy ether 78. Subsequent treatment of 79 with catalyst C produced the octacyclic ether 80 in 88% yield. 

Scheme 15 Formation of the central rings D and E by sequential intramolecular allylation and RCM in Yamamoto s total synthesis of the marine neurotoxin gambierol (81) [62]...

Intramolecular allylation of a-chloroacetoxy ether 185 followed by RCM (Scheme 35) was used by Yamamoto and coworkers to construct the eight-membered cyclic ether in the F-K ring segment 186 of the marine neurotoxin brevetoxin B (184) [91]. 

Formation of a bis-allylated product of 4-nitrobenzoyl chloride by the reaction with allyltrimethyltin in the presence of a benzylpalladium(ll) complex was observed by Stille and co-workers in 1983.4 Trost and King also reported allylation of aldehydes by allyltin reagents in 1990.456 However, the precise mechanism was unclear until the extended studies were performed by Yamamoto and co-workers since 1995.4S7,4S7a 4S7 Aldehydes and imines react with allyltin reagents in the presence of a palladium catalyst (Equations (95) and (96)), and imines are chemoselectively allylated in the presence of aldehydes (Equation (97)).4S7,4S7l 4 b Mechanistic studies using NMR spectroscopy proved that bis-7t-allylpalladium complex 203 is a key nucleophilic intermediate (Figure 3). 

The palladium-catalyzed multicomponent coupling reactions have attracted considerable interest.12,12a 12e A reaction using allylstannane 39 and allyl chloride 40 was applied to the three-component diallylation of benzylidenema-lonitrile and its congeners by Yamamoto et al 2 Analogous diallylation of isocyanate 41 was studied by Szabo et al. (Scheme 7).12a The reaction mechanism can be explained by formation of an amphoteric bis-allylpalladium intermediate 43 which undergoes an initial electrophilic attack on one of the allyl moieties followed by a nucleophilic attack on the other. 

For a review of allyl additions to aldehydes, see A. Yanagi-sawa, in Comprehensive Asymmetric Catalysis (Eds. E. N. Jacobsen, A. Pfaltz, H. Yamamoto), Springer, Berlin, 1999 pp. 965-982. 

In 1996, Yamamoto et al. investigated the intramolecular Pd(0)-catalyzed reactions of allylic acetates with allenes and observed the isomerization of triene 261 to the cyclic diene 262 (Scheme 15.83) [156], The reaction probably proceeds via oxidative addition to Pd(0), insertion of the allene and return of the acetate. 

Stereoselective substitution reactions of chiral dienyl electrophiles have also been carried out. In analogy to the copper-promoted 8 2 reactions of simple allylic electrophiles [3], the corresponding 8 2 (1,3) substitutions of dienyl carbonates [43] have been reported to proceed with high anti selectivity. Interestingly, treatment of chiral dienyl acetal 63 with the Yamamoto reagent PhCu BFs gave rise to the formation of a 1 3 mixture of the anti-S l substitution product 64 and the syn-Sn2" (1,5) substitution product 65 (Eq. 4.28) [44]. A mechanistic explanation of this puzzling result has yet to be put forward, however. 

Y. Yamamoto and co-workers used L-aspartic acid 4-methyl ester (108) as their starting material for the synthesis of preussin [64]. The ester was transformed in nine steps to the TBDPS-protected aminoalcohol 109 (Scheme 28). Allylation of the iST-Boc-protected amine using allyl bromide... 

Ishihara, Yamamoto, and coworkers demonstrated that 26 SnCl4 is an artificial cyclase that is useful for not only achiral but also chiral substrates. The diastereo-selective cyclization of ( )-nerolidol (29) has been examined with 1 equiv of the achiral LBA, 2-methoxyphenol (32) SnCl4, in dichloromethane at —78°C (entry 1, Table 12.1). Cyclization of ( )-29 bearing an acid-sensitive allylic hydroxy group gives a complex reaction mixture, and the desired trans-fused 2-oxabicyclo[4.4.0]... 

H. Yamamoto reported an enantioselective allylation of aldehydes catalyzed by AgF-p-tol-BINAP complex, [Eq. (13.24)]. High enantioselectivity was obtained... 

By 1984, the palladium-catalyzed aUyhc alkylation reaction had been extensively studied as a method for carbon-carbon bond formation, whereas the synthetic utility of other metal catalysts was largely unexplored [1, 2]. Hence, prior to this period rhodium s abihty to catalyze this transformation was cited in only a single reference, which described it as being poor by comparison with the analogous palladium-catalyzed version [6]. Nonetheless, Yamamoto and Tsuji independently described the first rhodium-catalyzed decarboxylation of allylic phenyl carbonates and the intramolecular decarboxylative aUylation of aUyl y9-keto carboxylates respectively [7, 8]. These findings undoubtedly laid the groundwork for Tsuji s seminal work on the regiospecific rho-... 

Nagano M, Yamamoto H, Harada K, et ah Comparative study of modification and degradation of neurofilament proteins in rats subchronically treated with allyl chloride, acrylamide or 2, 5-hexanedione. Environ Res 63 229-240, 1993... 

The first systematic investigations of the catalytic Friedel-Crafts-type reaction with alcohols and olefines were performed by Yamamoto and colleagues. After reporting the development of a Pd-catalyzed method for the allylation of different naphthol derivatives [24], the authors used Mo(CO)g for the Friedel-Crafts-type alkylation of electron-rich arenes with allyl acetates [25], The same molybdenum catalyst was additionally used for a Friedel-Crafts-type alkylation of arenes using 1-phenylethanol and styrene as alkylating reagents [26], However, Mo(CO)g is toxic and must be handled under strictly inert conditions. Thus, more stable Lewis acids were necessary. 

Prior to the usage of the Ti-based catalytic system , the Sharpless group had reported their first asymmetric epoxidation of allylic alcohols using a combination of VO(acac)2/ TBHP and the chiral hydroxamic acid 67 (ee < 50%) or derivatives (ee 80%) ". In 1999, Yamamoto and coworkers described an improvement of this oxidation protocol, ee values up to 94%, by using hydroxamic acids derived from binaphthol, 68 being the... 

Patil NT, Yamamoto Y (2006) Palladium Catalyzed Cascade Reactions Involving w-Allyl Palladium Chemistry. 19 91-114 Pawlow JH, see Tindall D, Wagener KB (1998) 1 183-198 Pena D, see Guitian E (2005) 14 109-146 Perez D, see Guitian E (2005) 14 109-146... 

With a twist on the Sharpless asymmetric epoxidation protocol, Yamamoto and co-workers <99JOC338> have developed a chiral hydroxamic acid (17) derived from binaphthol, which serves as a coordinative chiral auxiliary when combined with VO(acac)j or VO(i-PrO)j in the epoxidation of allylic alcohols. In this protocol, triphenylmethyl hydroperoxide (TiOOH) provides markedly increased enantiomeric excess, compared to the more traditional t-butyl hydroperoxide. Thus, the epoxidation of E-2,3-diphenyl-2-propenol (18) with 7.5 mol% VO(i-PiO)3 and 15 mol% of 17 in toluene (-20 °C 24 h) provided the 2S,3S epoxide 19 in 83% ee. 

Novel palladium-catalyzed transformations of allylic alcohol and its derivatives are developed by Yamamoto and his co-workers. Bis(7r-allyl)palladium complexes are considered to be the key intermediates for the allylation of benzyl-idenemalonitrile and benzyl chloride (Scheme 29) (for examples see Refs 176,176a-176d). Asymmetric version of these reactions is being awaited. 

A complementary method for allylation reported (J. Org. Chem. 68 5593, 2003) by Hishashi Yamamoto, now of the University of Chicago, works particularly well with branched aldehydes. The ally source is the inexpensive allyltrimethoxysilane, with BINAP-complexed Ag ion as the catalyst. Activation of the allylsilane with KF and 18-crown-6 is critical to the success of this reaction. 

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... 

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