Tsuji-Trost nucleophilic substitution

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. 

The applications of palladium in organic syntheses are numerous,this metal possibly being the most important one in the field. Numerous reactions are known oxidations of the Wacker type, C-C coupling by transmetallation and/or insertion of CO or olefin (see following section). A category of reactions that is also very common concerns the catalytic use of palladium to carry out the substitution of a nucleofuge (typically acetate) in allylic position by a carbanion or any other nucleophile. This is the Tsuji-Trost allylic substitution ... 

To date, only a few examples have been described where a Heck reaction has been combined with a Pd°-catalyzed nucleophilic substitution and the yields are less satisfying. However, the opposite variation - namely the combination of a Tsuji-Trost and a Heck reaction - has been used more often (see Section 6.1.3). 

The formation of chromane derivatives has also been realised in the palladium catalyzed intramolecular nucleophilic substitution of allyl carbonates (Tsuji-Trost reaction). In most cases the reaction is accompanied by the formation of a new centre of chirality. Using Trost s chiral ligand the ring closure was carried out in an enantioselective manner. The asymmetric allylation of the phenol derivative shown in 4.20. was achieved both in good yield and with excellent selectivity.23... 

The palladium catalyzed intramolecular nucleophilic substitution of allyl alcohol derivatives (Tsuji-Trost reaction) has successfully been extended to the closure of a seven membered ring. The coupling of the allyl alcohol unit and the enamide was the key step in the preparation of the natural product claviciptic acid (5.14.),14... 

Allylic alcohols can serve as 7t-allyl cation precursors to act as electrophiles in Sn reactions with a tethered O-nucleophile giving rise to the formation of spiroannulated tetrahydrofurans <2000TL3411>. Michael acceptors are also suitable electrophiles for the cyclization to tetrahydrofuran rings <2003T1613>. The Tsuji-Trost allylation has found widespread application in the synthesis of carbo- and heterocyclic compounds. Allylic substitution has been employed in the stereoselective synthesis of 2-vinyl-5-substituted tetrahydrofurans <2001H(54)419>. A formal total synthesis of uvaricin makes twofold use of the Tsuji-Trost reaction in a double cyclization to bis-tetrahydrofurans (Equation 73) <20010L1953>. 

Pd° species and TPPTS are excellent catalysts for allylic substitution with a variety of nucleophiles (carbon and hetero nucleophiles) in nitrile-water media (Tsuji-Trost reaction eq. (9) [182, 183]). 

The Tsuji-Trost ally lie substitution catalyzed by Pd complexes using CH-acidic nucleophiles can be performed in an ionic liquid of type 1 alone [30] as well as in a biphasic system [31]. In the latter case the use of trisulfonated triphenylphosphine (TPPTS) prevents the catalyst from leaching into the organic phase. In comparison with water as the catalyst-supporting phase, the ionic liquid system exhibits higher activity and selectivity. The enantio-selective version of the allylic substitution with dimethyl malonate can also be performed in ionic liquids with a homochiral ferrocenylphosphine as the ligand [32]. 

Tsuji, J. Palladium-catalyzed nucleophilic substitution involving allylpalladium, propargylpalladium, and related derivatives the Tsuji-Trost reaction and related carbon-carbon bond formation reactions overview of the palladium-catalyzed carbon-carbon bond formation viart-allylpalladium and propargylpalladium intermediates, in Handbook of Organopalladium Chemistry for Organic Synthesis (ed. Negishi, E.-L), 2, 1669-1687 (John Wiley Sons, New York, 2002). 

A wide variety of nucleophiles add to an -rf-allyl ligand. Desirable nucleophiles typically include stabilized carbanions such as CH(COOR)2 or 1° and II0 amines. Unstabilized nucleophiles such as MeMgBr or MeLi often attack the metal first and then combine with the n-allyl by reductive elimination. The Tsuji-Trost reaction, which is typified by the addition of stabilized carbanions to T 3—allyl ligands complexed to palladium followed by loss of the resulting substituted alk-ene, comprises an extremely useful method of constructing new C-C bonds, and many applications of this reaction have appeared in the literature.61 Equation 8.43 illustrates an example of a Pd-catalyzed addition of a stabilized enolate to an allyl acetate.62 The initial step in the catalytic cycle is oxidative addition of the allyl acetate to the Pd(0) complex, followed by nq1 to nq3—allyl isomerization, and then attack by the nucleophile to a terminal position of the T 3—allyl ligand. We will discuss the Tsuji-Trost reaction, especially in regard to its utility in chiral synthesis,63 more extensively in Chapter 12. 

Leaving groups in the Tsuji-Trost reaction include acetates, halides, ethers, carbonates, sulfones, carbamates, epoxides, and phosphates. Reviews (a) Tsuji, J. In Handbook of Organopalladium Chemistry for Organic Synthesis, Negishi, E. deMeijere, A., Eds. Wiley-lnterscience New York, 2002 Vol II, Palladium-Catalyzed Nucleophile Substitution Involving Allyl Palladium, Propargyl-palladium and Related Derivatives, pp. 1669-1687. (b) Frost C. G. Howarth, J. Williams, J. M. J. Tetrahedron Asymmetry 1992, 3, 1089-1122. 

Palladium-catalyzed nucleophilic substitution of allylic substrates (Tsuji-Trost coupling) is a most important methodology in organic synthesis and therefore it is no wonder that such reactions have been developed also in aqueous systems. Carbo- and heteronucleophiles have been found to react with allylic acetates or carbonates in aqueous acetonitrile or DMSO, in water or in biphasic mixtures of the latter with butyronitrile or benzonitrile, affording the products of substitution in excellent yields (Scheme 6.19) [7-11,14,45,46], Generally, K2C03 or amines are used as additives, however in some cases the hindered strong base diazabicycloundecene (DBU) proved superior to other bases. 

In Sect. B, the intermolecular carbopalladations of aUenes are followed by a /S-hydride elimination to afford a 1,3-diene. However, in the presence of a nucleophile, a Tsuji-Trost-type nucleophilic substitution of the intermediate Tr-allylpaUadium spedes has been fuUy established (Scheme 6). 

The Tsuji-Trost reaction is the palladium-catalyzed substitution of allylic leaving groups by carbon nucleophiles. These reactions proceed via 7i-allylpalladium intermediates. 

The Pd-catalysed allylation of carbon nucleophiles with allylic compounds via Jt-aUylpaUadium complexes is called the Tsuji-Trost reaction [32]. Typically, an allyl acetate or carbonate (54) reacts with a Pd-catalyst resulting in displacement of the leaving group to generate a Jt-allylpalladium complex (55) that can undergo substitution by a nucleophile (56) (Scheme 4.14). In 1965, Tsuji reported the reaction of ti-aUylpaUadium chloride with nucleophiles such as enamines and anions of diethyl malonate and ethyl acetoacetate. A catalytic variant was soon reported thereafter in the synthesis of allylic amines [33]. In 1973, Trost described the alkylation of alkyl-substituted 7i-aUylpalladium complexes with methyl methylsulfonylacetate... 

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]. 

The palladium(0)-catalysed nucleophilic substitution of allylic acetates, carbonates or halides, also known as the Tsuji-Trost reaction, is a powerful procedure for the formation of C—C, C—O and C—N bonds. One of the early impressive examples, where this transformation had been combined with a pallada-ene reaction, was developed by Oppolzer and Gaudin [126], Although, in general, the Tsuji-Trost reaction can be combined with other palladium-catalysed transformations, there are only a few examples where it is combined with a Mizoroki-Heck transformation. 

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. 

Palladium-catalyzed allylic substitution reactions, known as Tsuji-Trost reactions, are a well-established method for carbon-carbon bond forming processes [48]. The generally accepted mechanism for this reaction involves the oxidative addition of the allylic substrate to Pd(0) to provide a Jt-allylpalladium complex. The subsequent reaction of the electrophilic 7t-allylpalladium complex with the nucleophile affords the substituted product and Pd(0), which is regenerated to start the catalytic cycle (Scheme 7.26). 

---