Alkene amides, cyclization

Sames et al. have reported the intramolecular cyclization of alkene-amide substrates catalyzed by [Ir(COE)2Cl]2 and the A-heterocyclic carbene ligand, N, A -bis-(2,6-diisopropylphenyl)-imidazolyl, via olefin insertion following oxidative addition of an sp C-H bond (Scheme 11) [117]. 

Scheme 11 Cyclization of alkene-amide via sp C-H Bond cleavage...

Finally, several palladium-catalyzed processes appear to occur by insertion of alkenes into palladium amides. Cyclizations of aminoalkenes in the presence of aryl halides to form P5nrolidines appear to occur by intramolecular insertion of alkenes into palladium amides. One example of the cyclizations of aminoalkenes in the presence of aryl halides is shown in Equation 9.89a. The relative stereochemistry of the aryl group and the nitrogen in the ring structure of the product indicates that syn addition of palladium and nitrogen occurred across the alkene. 

IPr [Ar W -bis-(2,6-diisopropylphenyl)imidazolyl] carbine ligand, and norbornene (4equiv.) [156]. In a typical example, the treatment of an amide that has an alkene moiety with the aforementioned Ir catalyst gave cyclization of the alkene-amide moiety through coupling of the sp C-H bonds. The reaction is proposed to proceed by the formation of an amide-coordinated iridium-IPr-Cl complex as the key intermediate, which reacts by C-H bond activation of the double bond followed by C-C formation to give the cyclized product (Scheme 11.9). 

Under certain conditions, amides can add directly to alkenes to form N-alkylated amides. 3-Pentenamide was cyclized to 5-methyl-2-pyrrolidinone by treatment with trifluorosulfonic acid. Acylbydrazine derivatives also cyclized in the presence of hypervalent iodine reagents to give lactams. When a carbamate was treated with Bu3SnH, and AIBN, addition to an alkene led to a bicyclic lactam. 

Alkenes can add to double bonds in a reaction different from those discussed in 15-19, which, however, is still formally the addition of RH to a double bond. This is called the ene reaction or the ene synthesis For the reaction to proceed without a catalyst, one of the components must be a reactive dienophile (see 15-58 for a definition of this word) such as maleic anhydride, but the other (which supplies the hydrogen) may be a simple alkene such as propene. Cyclopropene has also been used. ° The reaction is compatible with a variety of functional groups that can be appended to the ene and dienophile. N,N-Diallyl amides give an ene cyclization. 

Schreiber and co-workers (436) prepared a library calculated to contain 2.18 million polycyclic compounds through the 1,3-dipolar cycloaddition of a number of nitrones with alkenes supported on TentaGel S NH2 resin (Scheme 1.83). (—)-Shikimic acid was converted into the polymer bound epoxycyclohexenol carboxylic acid 376 (or its enantiomer), coupled to the resin via a photolabile linker developed by Geysen and co-workers (437) to allow release of the products from the resin in the presence of live cells by ultraviolet (UV)-irradiation. A range of iodoaromatic nitrones (377) was then reacted with the ot,p-unsaturation of the polymer-bound amide in the presence of an organotin catalyst, using the tandem esterification/ dipolar cycloaddition methodology developed by Tamura et al. (84,85) Simultaneous cyclization by PyBrop-mediated condensation of the acid with the alcohol... 

The use of lithium amides to metalate the a-position of the N-substituent of imines generates 2-azaallyl anions, typically stabilized by two or three aryl groups (Scheme 11.2) (48-62), a process pioneered by Kauffmann in 1970 (49). Although these reactive anionic species may be regarded as N-lithiated azomethine ylides if the lithium metal is covalently bonded to the imine nitrogen, they have consistently been discussed as 2-azaallyl anions. Their cyclization reactions are characterized by their enhanced reactivity toward relatively unactivated alkenes such as ethene, styrenes, stilbenes, acenaphtylene, 1,3-butadienes, diphenylacetylene, and related derivatives. Accordingly, these cycloaddition reactions are called anionic [3+2] cycloadditions. Reactions with the electron-poor alkenes are rare (54,57). Such reactivity makes a striking contrast with that of N-metalated azomethine ylides, which will be discussed below (Section 11.1.4). 

The N-heterocyclic alkenes derived from ring-closing metathesis are useful substrates for further transformation. In a synthesis directed toward the insecticidal cripowellin 12, Dieter Enders of RWTH Aachen has shown (Angew. Chem. Int. Ed. 2005,44, 3766) that the tertiary amide 8 cyclizes efficiently to the nine-membered alkene 9. The vision was that an intramolecular Heck cyclization could then deliver the cripowellin skeleton. Indeed, the Heck did proceed, and, depending on conditions, could be directed toward either 10 or 11. Unfortunately, the conformation of 9 is such that the cyclization proceeded cleanly across the undesired face. Nevertheless, both 10 and 11 appear to be valuable intermediates for further transformation. 

The alcohol is oxidized to the corresponding aldehyde with 1 equivalent of IBX at room temperature. The use of 2.2 equivalents of IBX at a higher temperature causes the additional interaction with the amide moiety, leading to a radical cation that cyclizes on the alkene. Employing excess of IBX in the presence of /j-TsOH produces the introduction of an alkene conjugated with the initially formed aldehyde. 

Perhaps the most useful type of alkene substrates for these reactions are enol ethers, enol esters and vinyl sulfides. Silyl enol ethers have excellent electron-donor properties, with an ionization potential of about 8 eV and an oxidation potential in various solvents of approximately 1.0-1.5 V vs SCE161. These compounds are easily synthesized by reaction of an enolate with a chlorosilane. (A very recent report synthesized a variety of silyl enol ethers with extremely high stereochemical yield, using the electrogenerated amidate of 2-pyrolidinone as the base.)162 An interesting point is that the use of oxidative or reductive cyclization reactions allows carbonyl functionalities to be ambivalent, either oxidizable or reducible (Scheme 65)163. 

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