Alkenes reactions with ketyls

The transformation of2-734 involves an initial generation of an organosamarium species 2-735 with subsequent nucleophilic addition to the lactone carbonyl. Presumably, a tetrahedral intermediate 2-736 is formed that collapses to yield the ketone 2-737. This reacts with Sml2 to give a ketyl radical 2-738, which undergoes an intramolecular S-exo radical cyclization reaction with the alkene moiety. The resultant... 

Ketone-Alkene Coupling Reactions. Ketyl radicals derived fromreduction of ketones or aldehydes with Sml2 may be coupled both inter- and intramolecularly to a variety of alkenic species. Excellent diastereoselectivities are achieved with intramolecular coupling of the ketyl radical with Q ,/3-unsaturated esters. In the following example, ketone-alkene cyclization took place in a stereocontrolled manner established by chelation of the resulting Sm(III) species with the hydroxyl group incorporated in the substrate (eq 22). ... 

A ketone or aldehyde is reduced to an alcohol by reaction with sodium or lithium metal in liquid ammonia, in the presence of ethanol. This is called a dissolving metal reduction and it proceeds by an alkoxy-radical known as a ketyl 21, 22, 46, 49. Alkynes are reduced to E-alkenes under dissolving metal conditions. Benzene is reduced to a cyclohexadiene under the same conditions 23, 28, 33, 37, 41, 48. 

Kariv-Miller and coworkers have developed indirect electroreductive cyclizations with the dimethyl-pyrrolidinium ion (DMP") as a mediator. Preparative electrolysis of 6-hepten-2-one (9) at a graphite cathode afforded cu-dimethylcyclopentanol (10) in 90% yield (equation 5). The reduction is believed to occur via the ketyl radical anion, which cyclizes onto the alkenic bond. In the absence of DMP simple reduction to 6-hepten-2-ol takes place.Very recently it was shown that instead of DMP several aromatic hydrocarbons can be used as mediators to initiate the cyclization reaction. The carbonyl group can also be cyclized onto an alkynic bond and even an aromatic ring. - ... 

The reductive coupling of ketones or aldehydes with electrophilic alkenes such as conjugated esters (Scheme 52) has been described independently by Inanaga et al. [38] and Fukuzawa et al. [123,124]. The reaction was performed in THF either in the presence of HMPA [38] or an alcohol [123,124]. The mechanistic aspects of this reaction have been discussed [ 124]. Presumably, the ketyl radical or its protonated form adds to ethyl acrylate with formation of the C-C bond. An efficient enantioselective synthesis of v-butyrolactones has been derived by using AT-methylephedrinyl acrylate or crotonate [125]. One example (synthesis of 33) is indicated in Scheme 52. 

By far the most useful and highly utilized radical reactions promoted by Sml2 are couplings between ketyls and alkenes or alkynes. The selectivity that can be achieved in these transformations, combined with the versatility of the method for the construction of diverse targets, makes it an extremely attractive means to form carbon-carbon bonds. 

Intermolecular ketyl alkene coupling reactions have been incorporated into a cascade that ultimately affords medium sized rings [58]. Specifically, chloroalkyl ketones react with acrylates, whereupon chloroalkyl lactones are formed in situ. Photolysis of these intermediates in the presence of excess Sml2 initiates an intramolecular nucleophilic acyl substitution reaction between the halide and the lactone, creating the medium-sized ring (Eq. 50). 

Annulation reactions are possible when a precursor monocyclic substrate contains an activated alkene in a tether [4a]. As demonstrated in Scheme 5, an ester was employed to activate the olefin appended to cycloalkanone 17. Upon generation of the 0-stannyl ketyl with tributyltin hydride, the carbon-centered radical attacks the electron-poor /(-position on the activated alkene. The corresponding cyclized adduct 18 is a bicyclic skeleton with a bridgehead hydroxyl group. An example of this reaction shows cyclopentanone 19 undergoing cyclization to diquinane 20 and tricycle 21 (76 24) in 69% yield. The presence of reasonable amounts of the minor, yet readily isolable, jn-diastereomers in the reaction indicated that the reaction may not be reversible. 

More interesting reactions are possible when the carbonyl-alkene cyclizations are applied in a tandem reaction sequence [4b]. The three precursor motifs of spiro , separated , and fused ring systems 22, 24 and 26, respectively, were each constructed however, not all cyclized readily (Scheme 6). In each reaction the intermediate alkene bearing the EWG, which both receives the radical and transfers the radical in the last cyclization, was activated for addition from the <9-stannyl ketyl. With the appropriate placement of the alkene tether in the starting substrate, complex ring structures can be synthesized in a one-pot procedure. 

Toward this end, Caryn Kenny set out to investigate the scope and limitations of the process. Indeed, the reaction turned out to be quite versatile (Eqs. 4 and 5). Both p-keto esters and p-keto amides could be used as substrates. Unactivated alkenes, electron deficient alkenes, and alkynes all served as suitable ketyl acceptors under Sm(II)-promoted conditions. As anticipated, high diastereoselectivity over three stereocenters could be achieved. However, although five-membered rings could be formed with exceptional ease, in these systems virtually all attempts at forming six-membered rings met with disappointment. 

Previously, tin-ketyl radicals have been added to alkenes only in an intramolecular fashion. [9] In recent publications, however, pinacols and amino alcohols have been prepared by cyclisation of dicarbonyl compounds [10] or keto-oximes [11] with tributyltin hydride. Cyclisation of 1,5-ketoaldehydes 1 and 1,5-dialdehydes with tributyltin hydride yields cw-diols 2 with excellent stereoselectivities, whereas the keto-oxime 4 with four benzyloxy-substituents affords a 58 42 cis trans) mixture. The tran -product was transformed in two more steps to the potent glycosidase inhibitor 1-deoxynojirimycin (6). [lib] The reversibility of both the addition of the tributyltin-radical to the carbonyl group and the intramolecular radical C-C bond formation is believed to be responsible for the high selectivity in the formation of 2. In the cyclisation of 1,5-pentanedial the unhydrolyzed coupling product 3 could be isolated, therefore providing evidence for a new mechanistic variant of the pinacol reaction, in which only 1.2 equivalent of the reducing agent are necessary. 

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