Cyclization related carbonylation reactions

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. 

Transition-metal mediated carbene transfer from 205 to benzaldehyde generates carbonyl ylides 211 which are transformed into oxiranes 216 by 1,3-cyclization, into tetrahydrofurans 212, 213 or dihydrofurans 214 by [3 + 2] cycloaddition with electron-deficient alkenes or alkynes, and 1,3-dioxolanes 215 by [3 + 2] cycloaddition with excess carbonyl compound120 (equation 67). Related carbonyl ylide reactions have been performed with crotonaldehyde, acetone and cyclohexanone (equation 68). However, the ylide generated from cyclohexanone could not be trapped with dimethyl fumarate. Rather, the enol ether 217, probably formed by 1,4-proton shift in the ylide intermediate, was isolated in low yield120. In this respect, the carbene transfer reaction with 205 is not different from that with ethyl diazoacetate121, whereas a close analogy to diazomalonates is observed for the other carbonyl ylide reactions. 

Cyclization to carbonyl groups by sp3 or sp2 carbon-centered radicals and other related reactions... 

The cyclization of 6-aminouracils with three-carbon fragments such as a,B- unsaturated carbonyl compounds, /3-dicarbonyl compounds, acetylenic esters, etc., is dealt with as a [3+3] reaction (see Section 2.15.5.7.2). Reactions with alkoxymethylenemalonates and related compounds are regarded as proceeding through [6 + 0 (y)] cyclizations (see Section 2.15.5.4.2). 

Azirines (three-membered cyclic imines) are related to aziridines by a single redox step, and these reagents can therefore function as precursors to aziridines by way of addition reactions. The addition of carbon nucleophiles has been known for some time [52], but has recently undergone a renaissance, attracting the interest of several research groups. The cyclization of 2-(0-tosyl)oximino carbonyl compounds - the Neber reaction [53] - is the oldest known azirine synthesis, and asymmetric variants have been reported. Zwanenburg et ah, for example, prepared nonracemic chiral azirines from oximes of 3-ketoesters, using cinchona alkaloids as catalysts (Scheme 4.37) [54]. 

As discussed in Chapter 9, various nucleophiles can be introduced at the ortho position of nitroarenes via the VNS process. This provides a useful strategy for the synthesis of indoles. One of the most attractive and general methods of indoles and indolinones would be the reductive cyclization of a-nitroaryl carbonyl compounds (Eq. 10.54). The VNS and related reactions afford a-nitroaryl carbonyl compounds by a simple procedure. For example, alkylation of 4-fluoronitrobenzene with a lactone silyl enol ether followed by reductive cyclization leads to tryptophols (Eq. 10.55).73... 

The presence of a 2-substitutent in 3-phenylazirines (17, R —H in Scheme 21) modifies the mode of reaction with molybdenum carbonyl.47 In contrast to pyrazine formation for (17, R =H see Section V,C,2), the alkenyl azirine (18, Scheme 22) is transformed in excellent yield into 2-phenyl-5-carboxy-methylpyrrole. This product probably arises by intramolecular cyclization within an intermediate dienylnitrene intermediate, and related reactions have been devised to synthesize isoxazoles (see Section IV,E,2) and pyrazoles (see Section IV,D,1).47 The molybdenum carbonyl-promoted formation of 2,5-disubstituted pyrroles47 has analogy in uncatalyzed thermal, but not photochemical decomposition of 3-phenyl-2//-azirine 2-acrylate.49... 

The scheme below depicts the novel use of a carbonyl ene cyclization (A, Lewis acid-catalyzed) and a closely related Prins cyclization (B, Brpnsted acid-catalyzed) to generate predominantly trans (cyclization condition A) or cis (cyclization condition B), di and tri substituted piperidines 160 and 161 <06JOC2460 06OBC51>. Of note, in the formation of di-substituted derivatives, R1 = H and R2 = Ph, no reaction occurs under cyclization condition B and the cis isomer 160 is obtained exclusively under cyclization condition A. In the case of tri-substituted derivatives, when bulky substituents at the 2-position (R1 = f-Bu or Ph) are present the trans diastereomer 161 is obtained almost exclusively under cyclization condition A, while no diastereoselectivity is seen under cyclization condition B. 

This section presents selected examples of the use of zeolites and related porous materials for transformations of carbohydrates, that fall beyond the scope of the previous paragraphs. They include the use of zeolites in click chemistry and in a variety of reactions, including the synthesis of anhydro sugars, cyclization, elimination, and addition reactions to the carbonyl group. 

Padwa and Prein (105,106) applied chiral, but racemic, isomiinchnone dipoles in diastereoselective 1,3-dipolar cycloadditions. The carbonyl ylide related isomiinch-none derivative rac-70 was obtained from the rhodium-catalyzed cyclization of diazo-derivative rac-69 (Scheme 12.24) (105). The reactions of the in situ formed dipole with a series of alkenes was described and in particular the reaction with maleic acid derivatives 71a-c gave rise to reaction with high selectivities. The tetracyclic products 72a-c were all obtained in good yield with high endo/ exo and diastereofacial selectivities. In another paper by the same authors, the reactions of racemic isomilnchnones having an exo-cyclic chirality was described (106). 

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