Intramolecular reaction dicarbonyl coupling

Oxo esters undergo an intramolecular dicarbonyl coupling reaction on treatment with a low-valent titanium reagent to form a ketone. This was used in the synthesis of (Z)-7,l0,10-trimethyl-bicyclo[7.2.0]undec-6-en-2-one (4) from ethyl ( )-6-methyl-7-(4,4-dimethyl-2-oxocyclobutyl)-hept-5-enoate,108 Interestingly, the configuration of the isolated C -C double bond in the isolated product is sensitive to the reaction conditions. 

Cycloalkenes. McMurry and Kees have described an intramolecular coupling of dicarbonyl compounds to cycloalkenes. In the intermolecular version of this reaction titanium(O) powder obtained by reduction with potassium or lithium is used (7, 368). In the intramolecular reaction a superior coupling reagent is prepared by reduction of TiClg with a zinc/copper couple in DME. 

Mixed coupling reactions, using two different carbonyl compounds, can be effected, but they generally lead to mixtures of products and are of limited use in synthesis. Intramolecular reactions with dicarbonyl compounds, on the other hand, provide a good route to cyclic alkenes. The keto-aldehyde 80, for example, gave the cyclic diterpene kempene-2, despite the presence of a saturated ketone... 

The proposed catalytic mechanism for intramolecular McMurry reaction begins with the reduction of TiCl3 by zinc metal to generate the activated titanium species A-19. Reductive cyclization of the dicarbonyl substrate forms the McMurry coupling product, along with titanium oxide complex B-15. To close the catalytic cycle, the oxide complex B-15 is converted to TiCl3 by Me3SiCl (Scheme 63).8d,8e... 

In the intermolecular mode, this reaction has been utilized for the preparation of products 28 from various nucleophiles, including C-nucleophiles (e. g. (3-dicarbonyl compounds). A similar reaction in the intramolecular mode provides a powerful synthetic tool for the preparation of various polycyclic compounds via oxidative biaryl coupling [21,27 - 30]. Several examples of these C-C bond forming reactions are shown in Schemes 13-15. Specifically, various dibenzoheterocyclic compounds 30 have been prepared by the oxidation of phenol ether derivatives 29 with [bis(trifluoroacetoxy)iodo]benzene in the presence of BF3-etherate in dichloromethane (Scheme 13) [27-29]. 

The primary adduct 53 (Eq. (117) ) of the anodically generated radical R undergoes a series of follow-up reactions a) hydrogen abstraction to 54, b) dimerization to additive dimers 55, c) coupling with R to 1,2-disubsti-tuted monomers56, d) le-oxidation to a carbonium ion that either solvolyzes to 57 or, when 1,3-dicarbonyl compounds are added cyclizes intramolecularly to tetra (58) - or dihydrofuran derivatives (59). Product control is possible in some cases by suitable choice of the anode potential. With a high anode potential,... 

In 1977, McMurry and Kees [152] developed a titanium-induced intramolecular coupling procedure to form cycloalkenes from dicarbonyl compounds. Mechanistically, as shown in Scheme 85, the coupling reaction proceeds by an initial pinacol dimerization of the dicarbonyl 253 to 254, followed by titanium-induced deoxygenation to afford alkene 255. 

Intramolecular free radical cyclization of dicarboxylic esters leads to a-hydroxy ketones (acyloins). Reductive coupling of dicarbonyl compounds provides 1,2-diols ipinacols) and further reaction of these yields cycloalkenes (McMurry reaction). These cyclization reactions are especially valuable for the preparation of medium and large rings that are not readily accessible by other methods. 

An intramolecular variation of the arylation reaction of a p-diketone led to cyclised products (24). The reaction involved the treatment of an a-(aryl)alkyl p-dicarbonyl derivative (22) with phenyl-iodine(in) bistrifluoroacetate (23), followed by base catalysed ligand coupling reaction. 2... 

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. 

In a related study, intramolecular oxidative coupling of enolate derivatives has been investigated by Schmittel and co-workers [167]. The intermolecular version of this reaction provides a useful route to 1,4-dicarbonyl compounds but typically suffers from low levels of stereoselectivity. Furthermore, in mixed systems, the desired heterocoupling products are often accompanied by appreciable amounts of homocoupling products. It was hoped that the use of a single metal for both enolate precursors with concomitant intramolecularization of the bond-forming event might overcome some of these problems. 

ABSTRACT. Dicarbonyl(t 5-cyclopentadienyl)carbyne complexes of molybdenum and tungsten prove to be a valuable synthetic tool Reaction with phosphines provides substituted carbyne complexes and leads via an intramolecular CC-coupling to t 1- or Tj -ketenyl complexes respectively. Electrophiles attack the metal carbyne triple bond forming hetero- and acyclic carbene complexes, r 2-acyl compounds, T -ketene complexes and metalla-dithia-bicyclobutane cations. Dithio-carboxylates are formed in reaction of these dicarbonyl(Ti5 cyclo-pentadienyl)carbyne complexes with sulfur or cyclohexene sulfide. 

The asymmetric reduction of y-phenylseleno ketones and the intramolecular substitution of the phenylselenone residue by the oxygen atom of a hydroxy group led to 2-substituted tetrahydrofurans (13OL3906). Polysubstituted furans were formed in the photoredox neutral coupling of alkynes with 2-bromo-1,3-dicarbonyl compounds. The reaction was carried out without any external stoichiometric oxidants (130L4884). 

The tandem McMurry reaction of dicarbonyl compounds consists of an initial in-termolecular coupling followed by an intramolecular cydization (Scheme 6.3). 

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