Tandem reactions carbopalladation

The cyclic carbopalladation-cross-coupling tandem reaction has been extensively developed over the past several years. Despite earlier favorable findings with A1 and Zr [84], these metals are still scarcely used. On the other hand, organometals containing Sn and B have been widely used, and favorable results have been obtained for the formation of ffve-membered car-bocycles and heterocycles containing N and O from halodienes [88] (Eqs. 1 and 2 in Scheme 29), haloenynes [89-92] (Eqs. 3-5 in Scheme 29), haloaryl-alkynes [94,95] (Eqs. 6 and 7 in Scheme 29), and allenene derivatives [93,96] (Eqs. 8 and 9 in Scheme 29). 

Cop6ret, C. and Negishi, E.-i. (1999) Palladium-catalyzed highly diastereoselective cyclic carbopalladation-carbonylative esterification tandem reaction of iododienes and iodoary-lalkenes. Org. Lett., 1,165-7. 

Pettier, L.R., Peyrat, J.-R, Alami, M. and Brion, J.-D. (2004) Unexpected tandem Sonogashira-carbopalladation-Sonogashira coupling reaction of benzyl halides with terminal alkynes a novel four-component domino sequence to highly substituted enynes. Synlett, 1503-8. 

Patterns of cyclic carbopalladation. As discussed above, the fundamentally stoichiometric and living nature of carbopalladation imposes various difficulties to be overcome. Carbopalladation can, in principle, be either a single-stage process or double- or multiple-stage processes. Double-and multiple-stage carbopalladation reactions have often been called either domino or cascade carbopalladation reactions. In some cases, two-stage carbopalladation reactions have also been called tandem carbopalladation reactions. None of these three words is a chemical term, and choice between them is a matter of taste. In this chapter, the term cascade will be used for both double- and multiple-stage carbopalladation processes. 

Negishi E, Coperet C (2002) Palladium-Catalyzed Tandem and Cascade Carbopalladation of Alkynes and 1,1-Disubstituted Alkenes Terminated by Carbonylative Reactions. In Negishi E, de Meijere A (eds) Handbook of Organopalladium Chemistry for Organic Synthesis. Wiley, New York, p 1431... 

Arai et al. reported that asymmetric tandem cyclization of the dialkenyl alcohol 182 in the presence of Pd(II)— spiro bis(isoxazoline) catalyst gave the bicyclic heterocycle 183 in 89% yield with 82% ee (Scheme 61).132d The reaction proceeds through Wack-er-type oxypalladation, formation of the palladacycle 185 by carbopalladation of the resulting alkylpalla-dium intermediate 184, elimination of HX, and subsequent reductive elimination of Pd(0) to give the product 183. 

Arylaluminums have not been used as extensively as some other arylmetals in Pd-catalyzed cross-coupling. However, the intrinsic reactivity of arylaluminums appears to be somewhere between that of Zn and Sn. It is this relatively low intrinsic reactivity of arylaluminums that is critically required in the cyclic carbopalladation-cross-coupUng tandem process shown in Scheme 44. The high intrinsic reactivity of Zn leads to the formation of the unwanted direct cross-coupling prodnct in 57% yield, while the corresponding reaction of PhSnBus does not produce either product under the conditions used. ... 

IV.3.3 Palladium-Catalyzed Tandem and Cascade Carbopalladation of Alkynes and 1,1-Disubstituted Alkenes Terminated by Carbonylative Reactions... 

In principle, carbonylative cyclization, that is, acylpalladation or Ac—Pd process, or noncarbonylative cyclization, that is, sample carbopalladation or C—Pd process, in the presence of CO and a Pd catalyst. Various possibilities with halo alkenes as representative substrates are shown in Scheme 2P Those processes that incorporate CO in the cyclization processes are discussed in Part VI including Sects. VI.4-VI.6. hi this section, those cases that do not incorporate CO during the cychzation processes but do so only after cyclization will be discussed. Such cychc carbopalladation-carbonylative termination tandem and cascade processes are represented by the Type II C—Pd process in Scheme 2, which may take place in competition with the other processes shown in Scheme 2, especially the cyclic Heck reaction (Type 1 C—Pd process) and cyclic carbopalladation involving cyclopropa-nation (Type 111 C— Pd process). 

The relative rates of carbopalladation and CO insertion represent a very delicate issue, which is, to a considerable extent, dependent on the reaction conditions. The reaction of Phi with even 1 attn of CO in the presence of 1-octyne and MeOH under the influence of 5 mol % of Cl2Pd(PPh3)2 gives only methyl benzoate (73%) without the sign of either intermolecular carbopalladation or acylpalladation. One may conclude that inter-molecular C—Pd and Ac—Pd processes are, in general, decidedly slower than the CO insertion-methanolysis tandem process. 

A detailed investigation with 10 summarized in Table 2 indicates that premature esterification and cyclopropanation (Type HI C— Pd process in Scheme 2) can occur as dominant side reactions but that, under the optimized conditions (entry 7), both can be suppressed to insignificant levels (<3%). It is also important to note that, in marked contrast with the cyclic acylpalladation (Type n Ac—Pd) discussed in Sect. VI.4.1.1, monosubstituted alkenes that can readily participate in dehydropalladation (e.g., 11) cannot undergo the cyclic carbopalladation-carbonylative esterification tandem process (Type II C-Pd) since they merely undergo the cyclic Heck reaction (Type I C— Pd process in Scheme 14). The contrasting behavior mentioned above may be attributable to a chelation effect exerted by the carbonyl group in the acylpalladation (Scheme 15), which is lacking in the carbopalladation shown in Scheme 14. 

As in the cases of termination by lactonization and lactamization, some specially structured alkenes, such as norbomene and related alkenes, can participate in intermolecular carbopalladation-carbonylative ketonization tandem processes. In the reactions shown in Scheme 22, the acylpalladium intermediates undergo intramolecular acylpalladation with arenes to provide ketones. ... 

A unique example of direct olefination of a cyclopropane was also disclosed by the Yu lab [21]. An electron-deficient arylamide was employed as directing group, as the previously employed oxazoline or hydroxamic acid was unreactive in the alkenylation. The proposed mechanism for the reaction involves an amide-directed C-H insertion of the Pd(II) catalyst into the cyclopropane methylene C-H bond of 9, followed by olefin carbopalladation and p-hydride elimination to provide intermediate 10 (Scheme 3a). Pd(0) is re-oxidized back to Pd(II) by Ag(I)/Cu(II), and a tandem 1,4-addition between the amide moiety of 10 and the acrylate provides the corresponding y-lactam 11 as the sole isolated product, fii the presence of an... 

Yang has reported a related tandem cydization for the synthesis of pyrroloindoline derivatives that also proceeds though a mechanism involving alkene aminopalladation followed by carbopalladation of a second alkene [46]. As shown below, the 2-allylaniline derivative 48 was converted to 49 in 95% yield through treatment with a catalyst composed of Pd(OAc)2 and pyridine (Eq. (1.22)). Use of (-)-sparteine as a ligand in this reaction provided 49 with up to 91% ee. 

Scheme 18 Tandem carbopalladation-Stille coupling reaction of Y-bromopropargylic-1,2 diols.

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