Cyclization-carbonylation reaction

A Pd(ll) catalyst system with an oxazoline ligand 44 has been described that allows the desymmetrization of meso-Z-alkyl-2-propargylcyclohexane-l,3-diols in an asymmetric cyclization-carbonylation reaction. The products which contain a chiral quaternary carbon were obtained in excellent yields with high ee s (Scheme 56) <2006T9988>. 7-Hydroxy terminal <2005JOC3099> and internal <2006TL2793> alkenes can be converted to tetrahydrofurans by Pd(0)-catalyzed carboetherification reactions combined with a coupling of aryl or vinyl halides. 

Carbonyl condensation reactions are widely used in synthesis. One example of their versatility is the Robinson anuulation reaction, which leads to the formation of an substituted cyclohexenone. Treatment of a /3-diketone or /3-keto ester with an a,/3-unsaturated ketone leads first to a Michael addition, which is followed by intramolecular aldol cyclization. Condensation reactions are also used widely in nature for the biosynthesis of such molecules as fats and steroids. 

Chapter 10 considers the role of reactive intermediates—carbocations, carbenes, and radicals—in synthesis. The carbocation reactions covered include the carbonyl-ene reaction, polyolefin cyclization, and carbocation rearrangements. In the carbene section, addition (cyclopropanation) and insertion reactions are emphasized. Recent development of catalysts that provide both selectivity and enantioselectivity are discussed, and both intermolecular and intramolecular (cyclization) addition reactions of radicals are dealt with. The use of atom transfer steps and tandem sequences in synthesis is also illustrated. 

Another interesting cyclization employing 2-hydroxy-substituted methoxyallenes 101 was reported by Takahashi et al. (Scheme 8.29) [85]. Their novel Ru3(CO)12-cata-lyzed carbonylation reaction of allenyl alcohols 101 furnished y-lactones 108 in almost quantitative yields. 

This chapter covers the recent advances in amidocarbonylations, cyclohydrocarbonylations, aminocarbonylations, cascade carbonylative cyclizations, carbonylative ring-expansion reactions, thiocarbonylations, and related reactions from 1993 to early 2005. In addition, technical development in carbonylation processes with the use of microwave irradiation as well as new reaction media such as supercritical carbon dioxide and ionic liquids are also discussed. These carbonylation reactions provide efficient and powerful methods for the syntheses of a variety of carbonyl compounds, amino acids, heterocycles, and carbocycles. 

In this chapter, the recent advances in amidocarbonylations, cyclohydrocarbonylations, aminocarbonylations, cascade carbonylative cyclizations, carbonylative ring-expansion reactions, thiocarbonylations, and related reactions are reviewed and the scope and mechanisms of these reactions are discussed. It is clear that these carbonylation reactions play important roles in synthetic organic chemistry as well as organometallic chemistry. Some of the reactions have already been used in industrial processes and many others have high potential to become commercial processes in the future. The use of microwave irradiation and substitutes of carbon monoxide has made carbonylation processes suitable for combinatorial chemistry and laboratory syntheses without using carbon monoxide gas. The use of non-conventional reaction media such as SCCO2 and ionic liquids makes product separation and catalyst recovery/reuse easier. Thus, these processes can be operated in an environmentally friendly manner. Judging from the innovative developments in various carbonylations in the last decade, it is easy to anticipate that newer and creative advances will be made in the next decade in carbonylation reactions and processes. 

A phosphorus ylide serves as the carbanionic component in a synthesis of pyran-2-ones from 1,3-diketones (70ACS343). A Wittig reaction between the ylide and one of the carbonyl groups is envisaged as the first step in the sequence and the resulting keto ester spontaneously cyclizes. The reaction is conducted under pressure and yields are low. 

Similarly, cyclizative tandem double-carbonylation reactions of 4-pentenyl iodide under irradiation conditions, is boosted by the addition of a catalytic amount of palladium complexes [72]. When performed in the presence of diethylamine, the carbonylation provided a triply carbonylated a,<5-diketo amide as the major product along with the doubly carbonylated y-keto amide (Scheme 6.48). Experimental evidence supports the interplay of two reactive species, radicals and organopalladium... 

Fig. 46 Light-stimulated palladium-catalyzed tandem radical cyclization/carbonylation/ Suzuki-Miyaura coupling reactions...

Two other Ni(CO)4 substitutes, Ni(CO)3PPh3 and Ni(COD)2/dppe, prove to be appropriate for the catalysis of tandem metallo-ene/carbonylation reactions of allylic iodides (Scheme 7)399. This process features initial oxidative addition to the alkyl iodide, followed by a metallo-ene reaction with an appropriately substituted double or triple bond, affording an alkyl or vinyl nickel species. This organonickel species may then either alkoxycar-bonylate or carbonylate and undergo a second cyclization on the pendant alkene to give 51, which then alkoxycarbonylates. The choice of nickel catalyst and use of diene versus enyne influences whether mono- or biscyclization predominates (equations 200 and 201). 

Ruthenium complexes are also suitable catalysts for carbonylation reactions of a variety of substrates. Indeed, when a reaction leads to C-Ru or het-eroatom-Ru bond formation in the presence of carbon monoxide, CO insertion can take place at the coordinatively unsaturated ruthenium center, leading to linear ketones or lactones. Thus, ruthenium-catalyzed carbonylative cyclization was involved in the synthesis of cyclopentenones by reaction of allylic carbonates with alkenes in the presence of carbon monoxide [124] (Eq. 93). 

A selenium-assisted carbonylation reaction has been developed which gives 1,3-dihydro-2/f-imidazo[4,5-b]pyridin-2-ones (314) in an excellent yield (Scheme 30) <87BCJ1793>. Heating 2,3-diaminopyridine (312) with CO and an equimolar amount of selenium in the presence of N-methylpyrrolidine, proceeds through a selenolcarbonate intermediate (313) which then cyclizes to the desired product (314). 

In their enantioselective total synthesis of (+)-triptocallol (3-79), a naturally occurring terpenoid, Yang and coworkers made use of a concise Mn(OAc)rmediated and chiral auxiliary-assisted oxidative free-radical cyclization [39]. Reaction of 3-77, bearing a (R)-pulegone-based chiral auxiliary, with Mn(OAc)3 and Yb(OTf)3 yielded tricyclic 3-78 in a twofold ring closure in 60% yield and a diastereomeric ratio of 9.2 1 (Scheme 3.20). A further two steps led to (-i-)-triptocallol (3-79). For the interpretation of the stereochemical outcome, the authors proposed the hypothetical transition state TS-3-80, in which chelation of the (3-keto ester moiety with Yb(OTf)3 locks the two carbonyl groups in a syn orientation. The attack of the Mn -oxidation-generated radical onto the proximate double bond is then restricted to the more accessible (si)-face, as the (re)-face is effectively shielded by the 8-naphthyl moiety. 

This titanocene-catalyzed procedure was immediately extended by Gansauer et al. to the enantioselective opening of meso-epoxides by employing substoichiometric quantities of titanocene complexes with chiral hgands [58-60]. It has also been applied by this group in racemic form not only for reductive epoxide openings and intermolecular additions to a,P-unsaturated carbonyl compounds, but also to achieve 3-exo, 4-exo, and 5-exo cycliza-tions, as well as tandem cyclization addition reactions featuring vinyl radicals (Scheme 9) [8,9,44,46,57,61-65]. 

Many unaccomplished and yet highly necessary tasks remain. The scope and limitations as well as mechanistic details of most of the reactions discussed above need to be further delineated. More extensive and challenging applications of the newly developed reactions to the synthesis of natural products and other complex organic molecules must also be carried out. In addition, other less routine but highly desirable aspects should also be explored. These include asymmetric cyclization and catalytic procedures for cyclization-carbonylation. 

Schiff bases (14), which are formed by reaction between DAMN and appropriate carbonyl reagents, are oxidatively cyclized to give a variety of 2-substituted 4,5-dicyanoimidazoles (15) (Scheme 2.1.5). Although dichlorodicyanoquinone (DDQ) or diaminosuccinonitrilc (DISN) have been used frequently to achieve the oxidative cyclization, long reaction times (17 h to 4 days under reflux) are a disadvantage, and N-chlorosuccinimide (NCS) under basic conditions is more convenient in many cases. The Schiff bases are best formed from aromatic aldehydes, but aliphatic aldehydes and ketones, ketoesters, orthoesters, amides, imidates and cyanogen chloride have all been used [15, 41-49J. 

At the same time, Reppe (158) discovered the catalytic properties of tetracarbonyinickel and its derivatives in the carbonylation reactions and in the cyclization of alkynes, and this gave a tremendous thrust forward to the experimental research on the chemistry of carbonylnickel derivatives. In the beginning the development of the chemistry of low oxidation states proceeded concomitantly with the chemistry of zerovalent... 

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