Carbonyl compounds intramolecular radical cyclization

The (3-metaloxy radical was first exploited for synthetic purposes in C—H and C—C bond-forming reactions by Nugent and RajanBabu through the use of titanocene(III) chloride as an electron-transfer reagent [5]. They established that the (3-titaniumoxy radicals formed after electron transfer can be reduced by hydrogen atom donors, e. g. 1,4-cy-clohexadiene or tert-butyl thiol, that they add to a,(3-unsaturated carbonyl compounds, and that they can react intramolecularly with olefins in 5-exo cyclizations. 

In intermolecular PET processes, radical ions are formed either as close pairs or as free species from neutral molecules (Sch. 1) [2,6]. Most commonly, carbonyl compounds or related derivatives as for example enol ethers, cyclopropyl ketones, and siloxycyclopropanes are used for intramolecular cyclization reactions. With the exception of cycloadditions the ring-building key step is always an intramolecular bond formation. In PET... 

Cross-Coupling with Carbonyl Compounds. The electroreductive cross-coupling of olefins with carbonyl compounds, which are initially reduced to radical or anion intermediates to attack the olefins, is synthetically useful. The stereochemistry of this type of intermolecular reaction has lately been examined less [70-72] than that of intramolecular cyclization [73-77]. 

Carbonyl couplings. Many variations of cross couplings are possible these include aldehydes with a-dicarbonyl compounds. Ketyl radicals derived from carbonyl compounds also add to alkenes such as acrylonitrile " or N-allyl moieties. Intramolecular cyclizations on terminal alkenes or allene species have also been exploited for synthetic purposes. 

Epoxides can also be reductively opened to form a radical. An example of an intramolecular cyclization of such a radical has recently been reported <06TL7755>. Treatment of 40 with Cp2TiCl generates an intermediate alkoxy radical, which then adds to the carbonyl of the formate ester. The product, 41, is formed as a 2 1 mixture of isomers at the anomeric carbon. This reaction is one of the first examples of a radical addition to an ester. The major byproduct of this reaction is the exo-methylene compound, 42, arising from a P-hydrogen elimination. 

Cyclization of alkyl radicals derived from acryl enamides gives piperidin-2-ones (Equation (10)).51 Radical carbonyla-tions have become a promising tool for the introduction of carbon monoxide into organic molecules. Macrocyclic compounds are prepared by intramolecular cyclization via radical carbonylation (Equation (1l)).53... 

A tandem carbonylation-cyclization radical process in heteroaromatic systems bearing electron-attracting substituents such as l-(2-iodoethyl)indoles and pyrroles 970 result in the formation of 2,3-dihydto-l//-pyrrolo[l,2- ]indol-1-ones and 2,3-dihydro-l//-pyrrolizin-l-ones 974 (Scheme 188). The AIBN-induced radical reaction of compounds 970 with Bu3SnH under pressure of CO suggests that the acyl radical 972, derived from radical 971 and CO, would undergo intramolecular addition to C-2 of heteroaromatic system, and the benzylic radical 973 so obtained, upon in situ oxidation would produce final product 974 <1999TL7153>. 

Exploration of the reduction of dicarbonyl compounds has centered on attempts to achieve intramolecular coupling of radical intermediates to give a cyclic 1,2-diol. A mechanistic study of the production of cyclopropanediols, during the reduction of 1,3-dibenzoylpropane in acetonitrile, has been made [110]. It is suggested that the ratedetermining cyclization step is the addition of the radical anion from one ketone function onto the second carbonyl group in the same molecule. 

It is also worthwhile comparing the intramolecular photochemical cycloaddition reactions of ethylenic aldehydes and ketones with free radical intramolecular additions. For instance, irradiation of 5-hexen-2-one (470) (Scheme 161) in the gas phase gives the oxetane 471 as only cyclized product, as expected from the known photochemical intermolecular reaction between olefins and ketones. If the irradiation is conducted in solution 470 gives 471 (26%) and 472 (18%). With other y,< -unsaturated ketones, the bicyclic compound analogous to 472 may become the major product. With 2-allylcyclanones such as 473 (Scheme 161) bicyclic compounds are obtained (80% yield) as a mixture of 474 and 475, with 475 being the major product, but such compounds are difficult to isolate. " In the same manner, selective irradiation of the carbonyl group of 2-acyl-2,3-dihydro-4/f-pyrans (476) leads exclusively (23% yield) to exo-brevicomin (477) (a sex attractant), neither oxetane formation nor Norrish type II reaction being observed. The formation of the compounds 472, 475, and 477 which was considered as unexpected... 

The key step in the total synthesis of e/ir-lycoricidine, recently accomplished by Keck and Wager [55] consisted of the thiy] radical addition to a triple bond of a suitable precursor followed by cyclization onto a pendant oxime moiety, as shown in Scheme 7. Then the alkoxyaminyl radical abstracts hydrogen from PhSH, when R=C02Me, or attacks intramolecularly the carbonyl moiety, when R = CHO. Following the former strategy, the target compound was obtained after two other transformations and in an overall yield of 11.1 % starting from lyxo.se, in 14 steps. 

Aqueous TiCU also promotes a chemoselective reduction of a,p-dicar-bonyl compounds to give ketyl radicals that add to the carbonyl carbon of aldehydes affording a,p-dihydroxyketones. The reaction yields are excellent and the diastereoselection depends on the steric hindrance of the groups bonded to the reagents [80e]. When the ketyl radical is generated from methyl phenylglyoxalate and added to p-ketoesters and p-keto acids, the intermediate pinacols rapidly afford lactones by intramolecular cyclization [80d]. 

Two unselective approaches to the two alkaloids are illustrated in Scheme 50. A straightforward synthesis by King relied on acid-induced intramolecular Mannich reaction of ammoketone 396, prepared from 5-aminopentanal diethyl acetal and pent-3-en-2-one, to give a mixture of ( )-394 (55%) and ( )-395 (20%) (367). The synthesis by Pilli et at. involved a one-pot trimethylsilyl triflate-catalyzed condensation between pent-3-en-2-one and the acyliminium ion derived fium JV-Boc-2-ethoxypiperidine (397) (368,369). Under the reaction conditions, the intermediate 398 underwent spontaneous V-deprotection and cyclization to give a 5.5 1 mixture of ( )-394 and ( )-395 (67%). In the same Scheme is also shown the much shorter stereoselective synthesis of ( )-394 by Beckwith et al, who used a radical-mediated cyclization on the V-acylated 2,3-dihydropyridin-4-one 399 to give the bicyclic product 400 as the sole diastereomer (91%) (370). Compound 400 was readily converted into the target alkaloid by reduction of both carbonyl groups with lithium aluminum hydride followed by reoxidation of the secondary alcohol at C-2. 

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