Nucleophiles transition-metal catalyzed allylic

Although transition metal-catalyzed allylic alkylation has become one of the most powerful methods in chemical synthesis, the formation of ether bonds using this process has been slow to evolve.119-121 The main reasons for this disparity are the lower nucleophilicity and higher basicity of oxygen nucleophiles, particularly those derived from aliphatic alcohols, compared to their carbon or nitrogen analogs. However, this notion has rapidly been revised, as recent advances in the O-allylation area have largely addressed the issue of the reactivity mismatch between the hard alkoxide and the soft 7r-allylmetal species to provide a considerable body of literature. 

While the notion that the alkoxides derived from aliphatic alcohols are poor nucleophiles toward 7r-allylmetal complexes has prevailed over the years, much progress made in the recent past has rendered the transition metal-catalyzed allylic alkylation a powerful method for the O-allylation of aliphatic alcohols. In particular, owing to the facility of five- and six-membered ring formation, this process has found extensive utility in the synthesis of tetrahydrofurans (THFs) (Equation (29))150-156 and tetrahydropyrans (THPs).157-159 Of note was the simultaneous formation of two THP rings with high diastereoselectivity via a Pd-catalyzed double allylic etherification using 35 in a bidirectional synthetic approach to halichondrin B (Equation (30)).157 The related ligand 36 was used in the enantioselective cyclization of a Baylis-Hillman adduct with a primary alcohol (Equation (31)).159... 

Ketone and ester enolates have historically proven problematic as nucleophiles for the transition metal-catalyzed allylic alkylation reaction, which can be attributed, at least in part, to their less stabilized and more basic nature. In Hght of these limitations, Tsuji demonstrated the first rhodium-catalyzed allylic alkylation reaction using the trimethly-silyl enol ether derived from cyclohexanone, albeit in modest yield (Eq. 4) [9]. Matsuda and co-workers also examined rhodium-catalyzed allylic alkylation, using trimethylsilyl enol ethers with a wide range of aUyhc carbonates [22]. However, this study was problematic as exemplified by the poor regio- and diastereocontrol, which clearly delineates the limitations in terms of the synthetic utihty of this particular reaction. 

The transition metal-catalyzed allylic substitution using hard or unstabilized nucleophiles has not been extensively studied, particularly with unsymmetrical allylic alcohol derivatives. This may be attributed to the highly reactive and basic nature of these nucleophiles and the inability to circumvent regiochemical infidehty in unsymmetrical systems. Hard nucleophiles may be characterized as those that undergo substitution with net inversion of stereochemistry [29], due to their propensity to add directly to the... 

Transition metal-catalyzed allylic substitution with phenols and alcohols represents a fundamentally important cross-coupling reaction for the construction of allylic ethers, which are ubiquitous in a variety of biologically important molecules [44, 45]. While phenols have proven efficient nucleophiles for a variety of intermolecular allylic etherification reactions, alcohols have proven much more challenging nucleophiles, primarily due to their hard, more basic character. This is exemphfied with secondary and tertiary alcohols, and has undoubtedly limited the synthetic utihty of this transformation. 

Transition metal-catalyzed allylic alkylation is generally considered to involve mechanistically four fundamental steps as shown in Scheme 1 coordination, oxidative addition, ligand exchange, and reductive elimination. A key step of the catalytic cycle is an initial formation of a (7r-allyl)metal complex and its reactivity. The soft carbon-centered nucleophiles, defined as those derived from conjugate acids whose pAj, < 25, usually attack the allyl ligand from the opposite side... 

E. Ketone Enolates as Nucleophiles in Transition-metal Catalyzed Allylic... 

The transition metal-catalyzed allylation of carbon nucleophiles was a widely used method until Grieco and Pearson discovered LPDE-mediated allylic substitutions in 1992. Grieco investigated substitution reactions of cyclic allyl alcohols with silyl ketene acetals such as Si-1 by use of LPDE solution [95]. The concentration of LPDE seems to be important. For example, the use of 2.0 M LPDE resulted in formation of silyl ether 88 with 86 and 87 in the ratio 2 6.4 1. In contrast, 3.0 m LPDE afforded an excellent yield (90 %) of 86 and 87 (5.8 1), and the less hindered side of the allylic unit is alkylated regioselectively. It is of interest to note that this chemistry is also applicable to cyclopropyl carbinol 89 (Sch. 44). 

In general, the catalytic cycle for the transition-metal catalyzed allylic substitution reactions involves initial attack of the metal at the double bond followed by oxidative insertion into the antiperiplanar C-0 bond to afford the Ti-allyl system. At this point, depending on whether soft or hard nucleophiles are used, however, the alkylation reaction proceeds through distinctly different pathways (Scheme 10). With soft nucleophiles, where Pd is often the metal center of choice. 

Other leaving groups like the enantiomerically pure imidate85 (Table 8, entry 11) can also be used to give the substituted product with net retention of configuration. Without an external nucleophile, transition metal-catalyzed Claisen rearrangement occurs for allyl imidates. 

Transition metal catalyzed allylation by using allylic carbonates is one of the most versatile allylation methods. The Pd-catalyzed reaction is believed to proceed by the following mechanism. Eirst of all, oxidative addition of the C-0 bond to Pd(0) gives (r/ -allyl)(carbonato)palladium(II) complex, which undergoes decarboxylation to give the alkoxo complex [70]. The resulting (t] -allyl)(alkoxo)palladium(II) complex immediately reacts with nucleophiles (HNu)... 

Transition Metal-catalyzed Allylic Alkylation. Simple ketone enolates were found to be suitable nucleophiles for palladium-catalyzed allylic alkylations. The palladium-catalyzed asymmetric allylic alkylation of a-aryl ketones will take place in the presence of NaHMDS and allyl acetate to produce the desired a,a-disubstituted ketone derivative in high yields andee (eq 16). ... 

Transition metal-catalyzed allylic substitution reactions with carbon nucleophiles are among the most important carbon-carbon bond formation methods in modem organic synthesis, because of their broad substrate scope under mild reaction conditions. In addition, they are applicable to enantioselective reactions, as well as exhibiting versatility towards the alkene functionality adjacent to the chiral centre for stereoselective derivatization. Tsuji-Trost allylic substitution, involving a (Ti-allyl) metal intermediate, has provided a particular advance in this regard [34, 35]. Most recently, Sawamura et al. [36, 37] have improved the regioselectivity of this reaction with unsymmetrically substituted allylic esters, and thus opened a new approach to sertraline. 

On the other hand, a transition-metal-catalyzed allylic substitution reaction with soft nucleophiles generally... 

Konno T, Takehana T, Ishihara T, Yamanaka H. The fluorine-containing 7t-allylmetal complex. The transition metal-catalyzed allylic substitution reaction of fluorinated allyl mesylates with various carbon nucleophiles. Org. Biomol. Chem. 2004 2 93-98. 

An important variant for transition metal-catalyzed carbon-nitrogen bond formation is allylic substitution (for reviews, see1,la lh). Nucleophilic attack by an amine on an 7r-allyl intermediate, generated from either an allylic alcohol derivative,2 16,16a 16f an alkenyloxirane,17-19,19a-19d an alkenylaziridine19,19a 19d, or a propargyl alcohol derivative,21,21a 21d gives an allylic amine derivative. 

Hydroboration of allenes 65 with pinacolborane in the presence of Pt(DBA)2 and a trialkylphosphine provides either the allyl boronate 66 or the vinyl boronate 67 regioselectively, depending on the stereoelectronic factors of the phosphine employed (Equation 2) <1999CL1069>. Allyl and vinyl boronates are synthetically important because of their ability to undergo nucleophilic addition to carbonyl compounds as well as transition metal-catalyzed cross-coupling. 

The transition-metal-catalyzed formation of 1,3-dioxepanes from vinyl ethers has also been described . For example, reaction of allyl ether 426 with a nonhydridic ruthenium complex at higher temperatures and without any solvent produce 1,3-dioxepane 427 (Scheme 197). It was suggested that cyclic acetal formation proceeds via a -allyl-hydrido transient complex, which undergoes nucleophilic attack by the OH group at the coordinated -allyl <2004SL1203>. 

Fischer-type carbenes can also be modified via transition metal catalyzed reactions. Fischer chromium aminocarbene complexes can be used as nucleophiles in palladium-catalyzed allyUc substitution reactions with aUylic acetates and carbonates, alFording the corresponding allyl-substituted aminocarbenes. For example, reaction of the Uthiated carbene (15) gives (16) in good yield (Scheme 25). ... 

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