Tsuji-Trost type reaction

The Tsuji-Trost-type reaction is applicable to bifunctional vinyl epoxide 144 and 1,3-diketone using a palladium catalyst as demonstrated by Koizumi, who obtained polymer 145 (Equation (67)). The reaction proceeds at 0 °C to a reflux temperature of THE. The resulting polymer 145 is isolated in a quantitative yield. The molecular weight of 145 is ca. 3000 (PDI = 2.0-2.7) when 5 mol% of Pd(PPh3)4 is employed as a catalyst. Use of Pd2(dba)3 with several bidentate phosphines such as dppe, dppp, dppb, and dppf is also effective for the polymerization reaction. Propargyl carbonate 146 also reacts with bisphenols in the presence of a palladium catalyst to afford polyethers 147 via carbon-oxygen bond formation at s - and r/) -carbon atoms (Equation (68)). 

Intramolecular Reaction of Ally Halides Tsuji-Trost-Type Reaction... 

The allylic alcohol products from Morita-Baylis-Hillman reactions were shown to participate in a DMAP-mediated Tsuji-Trost-type reaction with /3-diketones or /3-ketoesters, forming the C-allylation product without requiring the use of palladium. Previously, it was shown that allylic alcohols combined with /8-ketoesters and DMAP afforded the transesterification products, in which the allylic alcohol displaced the ester substituent. The difference between these diverging reaction pathways is likely due to the electron-withdrawing group on the allylic alcohol in the MBH adducts vs. just alkyl substituents in the latter case. 

The palladium-catalyzed allylic substitution reaction presents one of the most versatile and efficient methods for C-C and C-X bond formation, and consequently a broad range of procedures have been reported [8]. However, despite this importance, the implementation of such Tsuji-Trost type reactions in sequential processes do not appear to have been fully exploited, even though it has obvious potential in enabling a rapid increase of structural complexity from simple starting materials by combining several synthetic transformations in a one-pot manner. 

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. ... 

It is very well known that jr-allyl palladium complex 1, which is a key intermediate for the Tsuji-Trost type allylation, has an electrophilic character and reacts with nucleophiles to afford the corresponding allylation products. We discovered that bis 7r-allyl palladium complex 2 is nucleophilic and reacts with electophiles such as aldehydes [27] and imines [28-32] (Scheme 2, Structure 2). We have also shown that bis 7r-allyl palladium complex 2 can act as an amphiphilic catalytic allylating agent it reacts with both nucleophilic and electrophilic carbons at once to produce double allylation products [33]. These complexes incorporate two allyl moieties that can bind with different hapticity to palladium (Scheme 3). The different complexes may interconvert by ligand coordination. The complexes 2a, 2b and 2c are called as r]3,r]3-bisallypalladium complex (also called bis-jr-allylpalladium complex), r)l,r)3-bis(allyl)palladium complex, -bis(allyl)palladium complex, respectively. Bis zr-allyl palladium complex 2 can easily be generated by reaction of mono-allylpalladium complex 1 and allylmetal species 3 (Scheme 4) [33-36]. Because of the unique catalytic activities of the bis zr-allyl palladium complex 2, a number of interesting cascade reactions appeared in the literature. The subject of the present chapter is to review some recent synthetic and mechanistic aspects of the interesting palladium catalyzed cascade reactions which in-... 

Several Pd-catalyzed domino processes start with a Tsuji-Trost reaction, a pal-ladation of alkynes or allenes [5], a carbonylation [6], an amination [7] or a Pd(II)-cat-alyzed Wacker-type reaction [8]. A novel illustrious example of this procedure is the efficient enantioselective synthesis of vitamin E [9]. 

Grigg and coworkers developed bimetallic domino reactions such as the electro-chemically driven Pd/Cr Nozaki-Hiyama-Kishi reaction [69], the Pd/In Barbier-type allylation [70], Heck/Tsuji-Trost reaction/1,3 dipolar cycloaddition [71], the Heck reaction/metathesis [72], and several other processes [73-75]. A first example for an anion capture approach, which was performed on solid phase, is the reaction of 6/1-134 and 6/1-135 in the presence of CO and piperidine to give 6/1-136. Liberation from solid phase was achieved with HF, leading to 6/1-137 (Scheme 6/1.30) [76]. 

In 2006 Fukuyama published a total synthesis of racemic morphine starting from isovanillin and a cyclohexene-epoxide [16, 17]. The key features in their synthesis are (1) a construction of the ether linkage between A and C rings by Tsuji-Trost coupling, (2) an intramolecular Heck reaction to construct A-C-E tricyclic system, and (3) an intramolecular Mannich-type reaction of a ketone with an aminal to provide the pentacyclic structure of morphine in a one-step reaction by double cyclization. 

In most of the palladium-catalysed domino processes known so far, the Mizoroki-Heck reaction - the palladium(0)-catalysed reaction of aryl halides or triflates as well as of alkenyl halides or triflates with alkenes or alkynes - has been apphed as the starting transformation accordingly to our classification (Table 8.1). It has been combined with another Mizoroki-Heck reaction [6] or a cross-coupling reaction [7], such as Suzuki, Stille or Sonogashira reactions. In other examples, a Tsuji-Trost reaction [8], a carbonylation, a pericyclic or an aldol reaction has been employed as the second step. On the other hand, cross-couphng reactions have also been used as the first step followed by, for example, a Mizoroki-Heck reaction or Tsuji-Trost reactions, palladation of alkynes or allenes [9], carbonylations [10], aminations [11] or palladium(II)-catalysedWacker-type reactions [12] were employed as the first step. A novel illustrative example of the latter procedure is the efficient enantioselective synthesis of vitamin E [13]. 

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 ... 

In the twentieth century, palladium was the most important metal catalyst in transition metal-catalyzed organic transformations. First, many types of transformations can be catalyzed by a palladium catalyst, including the Heck reaction, the cross-coupling reaction, and the Tsuji-Trost reaction. Second, palladium is extraordinarily tolerant of nearly any type of organic functional group and its high chemoselectivity makes it feasible for use in functionalized or complex systems. Due to these characteristics, palladium is an ideal catalyst in cascade reactions and the total synthesis of natural products. 

When CoCl2 is used as a co-catalyst, the CDC reactions of allylic sp3 C—H and 1,3-dicarbonyl compounds smoothly afford Trost—Tsuji-type products, which are traditionally prepared from allyl halides or acetates (Equation 11.4) [14]. Moreover, when NBS is used instead of TBHP, selective C—H cleavage of tertiary aliphatic amines is possible (Equation 11.5) [15]. For benzylic C—H bonds, direct C—C bond formation can be achieved using copper perchlorate (Equation 11.6) [16]. 

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