Enantioselective synthesis Tsuji allylation

An ingenious extension of the Tsuji-Trost reaction was the cornerstone of Oppolzer s enantioselective synthesis of a heteroyohimbine alkaloid, (-t-j-B-isorauniticine (267) [117]. Substrate 263 was prepared from a commercially available glycinate equivalent by Malkylation, installation of the sultam chiral auxiliary followed by a sultam-directed C-alkylation. As illustrated in Scheme 48, the crucial double cyclization was accomplished by the treatment of 263 with Pd(dba), Bu,P, in the presence of carbon monoxide (1 atm) in acetic acid to give enone 264 and two other stereoisomers in a 67 22 11 ratio. In this case, an allyl carbonate, rather than an allyl acetate, was used as the allyl precursor. Since carbonate is an irreversible leaving group, formation of the n-allylpalladium complex occurs readily. In the presence of Pd(0), the allylic carbonate is converted into a n-allylpalladium complex with concurrent release of CO, and... 

Asymmetric Induction on the Nucleophile The use of the tBu-PHOX ligand led to the first catalytic enantioselective Tsuji allylations of simple alkanone enol derivatives 62. These mild, operationally straightforward and stereoselective reactions described by Stoltz et al. [52] produce chiral cycloalkanones 63 with quaternary stereocenters at the a-position with high enantiopurities and in excellent chemical yields (Scheme 12.31). Mechanistic studies showed the incorporation of an O-bound enolate in the intermediate Pd-allyl complex [53]. Further investigations on the substrate scope led to several applications in the synthesis of natural products [54]. Recently, a similar approach was used to afford enantiopure quaternary lactams 65 that intercept synthetic intermediates previously used in the synthesis of the Aspidospcrma alkaloids quebrachamine and rhazinilam, but that were previously only available by chiral-auxiliary-assisted approaches or as racemic mixtures (Scheme 12.32) [55],... 

Silyl Enol Ethers A disadvantage of the aforementioned enantioselective Tsuji allylations was that they were performed in an intramolecular fashion, requiring the need to synthesize the allyl enol carbonate starting materials. Although their synthesis is not overly cumbersome, the... 

One distinguishes palladium(0)- and palladium(ll)-catalysed reactions. The most common palladium(O) transformations are the Mizoroki-Heck and the cross-coupling transformations such as the Suzuki-Miyaura, the Stille and the Sonogashira reactions, which allow the arylation or alkenylation of C=C double bonds, boronic acid derivates, stan-nanes and alkynes respectively [2]. Another important palladium(O) transformation is the nucleophilic substitution of usually allylic acetates or carbonates known as the Tsuji-Trost reaction [3]. The most versatile palladium(ll)-catalysed transformation is the Wacker oxidation, which is industrially used for the synthesis of acetaldehyde from ethylene [4]. It should be noted that many of these palladium-catalysed transformations can also be performed in an enantioselective way [5]. 

In their enantioselective total synthesis of the alkaloid cephalotaxine (246), Tietze and Schirok [127] used a combination of a Tsuji-Trost and a Mizoroki-Heck reaction (Scheme 8.62). It was necessary to adjust the reactivity of the two palladium-catalysed transformations to allow a controlled process. Reaction of 243a using Pd(PPh3)4 as catalyst led to 244, which furnished 245 in a second palladium-catalysed reaction. In this process, the nucleophilic substitution of the allylic acetate is faster than the oxidative addition of the arylbromide moiety in 243a however, if one uses the iodide 243b, then the yield drops dramatically due to an increased rate of the oxidative addition. 

Thanks to the fundamental studies of Tsuji, Trost, and others, palladium-catalyzed allylic substitution has become a versatile, widely used process in organic synthesis [40]. The search for efficient enantioselective catalysts for this class of reactions is an important goal of current research in this field [41]. It has been shown that chiral phosphine ligands can induce substantial enantiomeric excesses in Pd-catalyzed reactions of racemic or achiral allylic substrates with nucleophiles [42]. Recently, promising results have also been obtained with chiral bidentate nitrogen ligands [43]. We have found that palladium complexes of neutral aza-semicorrin or methylene-bis(oxazoline) ligands are effective catalysts for the enantioselective allylic alkylation of l,3-diphenyl-2-propenyl acetate or related substrates with dimethyl malonate (Schemes 18 [25,30] and 19 [44]). 

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. 

Nickel and platinum mediated allylation reactions have been reported and in terms of AAA reactions, perhaps the most useful processes have involved hard nucleophiles. For example, high enantioselectivities have been realized in nickel-catalyzed processes employing Grignard reagents. Tungsten has also been used in Tsuji-Trost type reactions, however it has thus far not been applied to complex molecule synthesis. ... 

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