Alkynes intramolecular cyclization with

The exploitation of intramolecular Diels-Alder reactions has included synthetic applications in the thienopyrimidine series as well. Thus, the 1,2,4-triazine with a tethered alkyne (276) participates in an intramolecular cyclization, with concomitant loss of RCN, to produce the thienopyrimidine (277) (Equation (97)) <87JOC4287>. A similar reaction occurs with oxygen analogues. 

Chloro-2-trifluoromethyl quinolines 95 can be obtained from the corresponding N-aryl trifluoroacetimidoyl chlorides through the Rh(I)-catalyzed intramolecular cyclizations with the alkyne moieties (Scheme 39) [60,61],... 

Biphenyl derivatives bearing an alkyne unit at one of their ortho positions were converted into substituted phenanthrene derivatives with catalytic amounts of either PtCla, AuCla, GaCls, or InCls in toluene (Scheme 18.5) [5]. The reaction proceeds through the 6-endo-dig cyclization. In the case of biaryls with a lateral haloalkyne unit, InCls was found to affect the intramolecular cyclization with good selectivity. The resulting 10-halophenanthrene derivatives are suited for further elaboration. 

In this method, one alkyne is treated with Schwartz s reagent (see 15-17) to produce a vinylic zirconium intermediate. Addition of MeLi or MeMgBr, followed by the second alkyne, gives another intermediate, which, when treated with aqueous acid, gives the diene in moderate-to-good yields. The stereoisomer shown is the one formed in usually close to 100% purity. If the second intermediate is treated with I2 instead of aqueous acid, the 1,4-diiodo-1,3-diene is obtained instead, in comparable yield and isomeric purity. This reaction can also be done intramolecularly Diynes 56 can be cyclized to ( , E) exocychc dienes 57 by treatment with a zirconium complex. 

Particularly interesting are the results obtained with the phosphonium ylides including an acyl rest derived from aminoacid if the N-H bond reactivity is blocked by an amide protection, the alkyne formation takes place [25,27], but if the N-H bond is not deactivated, an intramolecular cyclization occurs to give a new stabilized ylide [27,28]. 

Diterpenoids related to lambertianic acid were prepared by intramolecular cyclization of either an alkene or an alkyne with a furan ring <2005RJ01145>. On heating amine 101 with allyl bromide, the intermediate ammonium ion 102 was formed which then underwent [4+2] cycloadditions in situ to give the spiroazonium bromides 103 and 104 (Scheme 13). These isomers arose from either endo- or co-transition states. The analogous reaction was also carried out with the same amine 101 and propargyl bromide. The products 105 and 106 contain an additional double bond and were isolated in 58% yield. The product ratios of 103 104 and 105 106 were not presented. 

Ni(COD)2 alone catalyzes intramolecular alkylative cyclization of an alkynal with diethylzinc, while Ni(COD)2/PBu3 catalyzes reductive cyclization with the same zinc reagent (Scheme 87). 

The final cyclization manifold has been realized with a different ruthenium catalyst (Scheme 22). The cationic [Cp Ru(MeCN)3]PF6 induces exclusive endo-dig cyclization of both homopropargylic and bis-homopropargylic alcohols.29 73 The clean reaction to form a seven-membered ring is noteworthy for several reasons intramolecular exo-dig cyclization with bis-homopropargylic alcohols is not well established, the platinum-catalyzed case has been reported to be problematic,80 and the selectivity for seven-membered ring formation over the exo-dig cyclization to form a six-membered ring is likely not thermodynamic. The endo-dig cyclization manifold was thus significant evidence that a re-examination of alkyne hydrosilylation mechanisms is necessary (see Section 10.17.2). 

Although terminal acetylenes themselves do not form stable titanium—acetylene complexes upon reaction with 1, the reaction with terminal alkynes having a keto group at the 5- or y-position induces an intramolecular cyclization, apparently via the above titanium-acetylene complex to afford the four- and five-membered cycloalkanols, as shown in Eq. 9.6 [28]. 

The Pd-catalyzed electro-cleavage of the C—O bond of allyl aryl ether proceeds smoothly in a DMF-Bu4NBp4-(Mg)-(Stainless Steel) system, giving depro-tected products in 73 99% yield [437]. The sp-sp intermolecular coupling reaction with the Pd water-soluble catalyst prepared in situ from Pd(II) acetate and sul-fonated triphenylphosphine in an MeCN-H2O system yields diynes in 45 65% yields [438]. Similarly, the sp -sp coupling of 2-iodophenols or 2-iodoanilines and terminal alkynes followed by intramolecular cyclization gives indol and furan... 

Radical intermediates are also trapped by intramolecular reaction with an alkene or alkyne bond. At a mercury cathode this process competes with formation of the dialkylmercury [51], At a reticulated vitreous carbon cathode, this intramolecular cyclization of radicals generated by reduction of iodo compounds is an important process. Reduction of l-iododec-5-yne 5 at vitreous carbon gives the cyclopentane... 

The electrophile-induced cyclization of heteroatom nucleophiles onto an adjacent alkene function is a common strategy in heterocycle synthesis (319,320) and has been extended to electrophile-assisted nitrone generation (Scheme 1.62). The formation of a cyclic cationic species 296 from the reaction of an electrophile (E ), such as a halogen, with an alkene is well known and can be used to N-alkylate an oxime and so generate a nitrone (297). Thus, electrophile-promoted oxime-alkene reactions can occur at room temperature rather than under thermolysis as is common with 1,3-APT reactions. The induction of the addition of oximes to alkenes has been performed in an intramolecular sense with A-bromosuccinimide (NBS) (321-323), A-iodosuccinimide (NIS) (321), h (321,322), and ICl (321) for subsequent cycloaddition reactions of the cyclic nitrones with alkenes and alkynes. 

Pd/tppts-catalysed intermolecular sp-sp couplings to afford diynes and sp2-sp coupling of 2-iodophenols or iodoanilines with alkynes followed by intramolecular cyclization to benzofurans and indoles, respectively, with moderate to good yields in H20/CH3CN solvent mixtures have also been described.517 8... 

Acylation of alkynes, cyclopentenones. Acylation of alkynes with a,a-disubsti-llllotE/f, y-unsaturated acid chlorides, catalyzed with A1C13> results in 5,5-disubstituted-2-cyclopentenones by an unexpected intramolecular cyclization-rearrangement.2 Example ... 

The treatment of 1,2,3-selenadiazoles (79) with a catalytic amount of tributyltin hydride and AIBN in the presence of an excess of olefin, gives 2,3-dihydroselen-ophenes (80) in good yield (Scheme 20). The reaction proceeds via tributyltin radical-promoted denitrogenation to give a vinyl radical, which then adds to the olefin followed by intramolecular cyclization. Under similar conditions 1,2,3-selenadiazoles and aliphatic or aromatic ketones afford alkynes as the sole products [114, 115]... 

It might, at first glance, come as a surprise that, despite the ban on 5-endo-trig cyclizations, 5-endo-dig cyclizations are allowed. A possible reason for this observation is that intramolecular nucleophilic or electrophilic attack at an alkyne can proceed with the substrate in a flat conformation, because two orthogonal jt (or jt) orbitals are available. Similarly, hydroxymethyl allenes cyclize on treatment with a base (Scheme 9.7), because the terminal Jt orbital of the allene and the hydroxymethyl group can readily achieve a synperiplanar orientation. Intramolecular... 

Intramolecular radical cyclization of an aryl bromide and an alkyne can be used to produce dihydroquinolines (Equation 57) <1998TL2965>. An analogous reaction setup utilizes a Lewis acid-catalyzed novel one-pot domino pathway using silver catalysis in high regioselectivity (Scheme 26) <2005OL2675>. Three mole equivalents of the alkyne are used with the final cyclization step arising from alkynic addition. 

All the examples described above involved the reaction of diazoacetate derivatives with silver salts to initiate the formation of a putative silver carbene however, other pathways exist. For example, Porcel and Echavarren have reported an intramolecular cyclization of an allylstannane to a pendent alkyne (Scheme 8.22) that involves the intermediacy of a silver carbene.52 As can be seen in Table 8.12, the reactions proceeded in moderate to excellent yield, providing the dienylstannane, while in some cases, reductive destannylation occurred. Several asymmetric reactions were reported with substrate ( )-145d, leading to the formation of the expected adduct in reasonable enantioselectivities (ee = 73-78%) in a preliminary screen with a number of different ligands. 

Recently, most radical cyclizations of halides have been performed using iodides with intramolecular alkene or alkyne functionality. As with chain elongation reactions, both chain and nonchain processes are possible, with the former being the most common. The nonchain processes are not covered here and the reader is referred to the excellent reviews in the literature for details. 

The radical intermediates from Cr(II) reduction of alkyl halides can in principle be used synthetically, but have only seen limited attention to this point. co-Haloalkynes (bromides, iodides), in the presence of excess Cr(C104)2, undergo cyclization reactions to form exo-alkylidene cycloalkanes (equation 176)347. These reactions proceed by the radical cyclization of intermediate 42 onto the alkyne unit, which undergoes subsequent reduction by Cr(II) to give a hydrolytically unstable vinylchromium(III). Rings of four, five and six members can be formed. Alternatively, a-iodo esters undergo intramolecular atom transfer radical cyclizations onto alkynes or alkenes with catalytic or stoichiometric amounts of... 

Various benzazepines can be prepared by transition-metal-catalyzed cyclizations for example, a palladium-catalyzed intramolecular hydroamidation with the alkyne 188 affords the 3-benzazepinone 189 (Scheme 115) <2006TL3811>. 

In contrast to intramolecular cyclizations, the intermolecular addition of O-centered radicals to ti systems as initiating step in complex radical cyclization cascades has only recently attracted considerable attention. The reason for the low number of papers published on O radical addition to alkenes and alkynes could originate from the perception that O-centered radicals, such as alkoxyl radicals, RO, or acyloxyl radicals, RC(0)0", may not react with 7t systems through addition at rates that are competitive to other pathways, for example, allylic hydrogen abstraction and p-fragmentation in the case of RO" or decarboxylation in the case of RC(0)0" (Scheme 2.9). 

Later, Arcadi showed that /J-keto-imines react with alkynes intramolecularly to give pyrroles. The intermolecular animation with aniliaes was later developed by Hayashi and Tanaka using a cationic Au(I) catalyst to form imines (equation 27). More recently, Arcadi etal. developed an intramolecular version for the cyclization of o-alkynylanilines to form indoles (equation 28) and Li reported a double intra- and intermolecular hydroamination to obtain A-vinylindoles. " O-Substituted hydroxylamines can also undergo this type of transformation to dihydroisoxazole derivatives. " " Tandem sequences that involve a first alkyne-hydroamination step with anilines have been recently developed " " and are similar to the previonsly discnssed additions with phenols that access isoflavone skeletons. 

Endo-skeletal rearrangements also take place with 1,6-enynes, bnt the proposed mechanism is just a variation of the exo-single-cleavage rearrangement. Formed by endo cyclization, bicyclo[4.1.0]hept-4-ene derivatives arise in some cyclizations of 1,6-enynes by proton loss and protodemetalation ofthe endo cyclopropylcarbene. " That is the case from 1,6-enynes tethered as sulfonamides and in the intramolecular cyclization of 1,6-enol ethers with alkynes (equation 40). ... 

In addition to cationic cyclizations, other conditions for the cyclization of polyenes and of ene-ynes to steroids have been investigated. Oxidative free-radical cyclizations of polyenes produce steroid nuclei with exquisite stereocontrol. For example, treatment of (259) and (260) with Mn(III) and Cu(II) afford the D-homo-5a-androstane-3-ones (261) and (262), respectively, in approximately 30% yield. In this cyclization, seven asymmetric centers are established in one chemical step (226,227). Another intramolecular cyclization reaction of iodo-ene poly-ynes was reported using a carbopaUadation cascade terminated by carbonylation. This carbometalation—carbonylation cascade using CO at 111 kPa (1.1 atm) at 70°C converted an acycHc iodo—tetra-yne (263) to a D-homo-steroid nucleus (264) [162878-44-6] in approximately 80% yield in one chemical step (228). Intramolecular aimulations between two alkynes and a chromium or tungsten carbene complex have been examined for the formation of a variety of different fiised-ring systems. A tandem Diels-Alder—two-alkyne annulation of a triynylcarbene complex demonstrated the feasibiHty of this strategy for the synthesis of steroid nuclei. Complex (265) was prepared in two steps from commercially available materials. Treatment of (265) with Danishefsky s diene in CH CN at room temperature under an atmosphere of carbon monoxide (101.3 kPa = 1 atm), followed by heating the reaction mixture to 110°C, provided (266) in 62% yield (TBS = tert — butyldimethylsilyl). In a second experiment, a sequential Diels-Alder—two-alkyne annulation of triynylcarbene complex (267) afforded a nonaromatic steroid nucleus (269) in approximately 50% overall yield from the acycHc precursors (229). 

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