Cyclization allenic

Addition of arylhydroxylamines to electrophilic allenes such as methyl propadienoate or l-methancsulfonyl-l,2-propadiene is another route to 0-vinyl derivatives[2]. The addition step is carried out by forming the salt of the hydroxylamine using NaH and the addition is catalysed with LiO CCFj. The intermediate adducts are cyclized by warming in formic acid. Yields are typically 80% or better. 

The reactive structural element for the Myers cyclization is an enyne allene, the heptatrienyne 6, which reacts to form a diradical species 7 ... 

Analogous to the allylsilane cyclizations, alkynylsilanes can also be used to synthesize 1,2-fused bicyclic compounds. The intramolecular addition of 4-[5-(trimethylsilyl)-3-pentynyl]-2-cyclo-hexenone proceeded smoothly in the presence of various Lewis acids, yielding functionalized cw-fused octahydro-5/f-inden-5-ones containing the synthetically useful terminal allene unit45. 

Table 10-6. Intramolecular cyclization of compounds with the general structure 10.41 (after Saunders and Allen, 1985).

Cyclization of allene 71 using a catalyst system comprising 10 mol % Pd(OAc)2, 20 mol % PPhj and K COj in the presence of amine 72 affords isoquinolone 73 <95CC1903>. 

Ma S (2005) Pd-catalyzed Two or Three-component Cyclization of Fnnctionalized Allenes. 14 183-210... 

As typical examples of crystal-to-crystal thermal reactions, the cyclization of allene derivatives to four-membered ring compounds and the transformation of a racemic complex into a conglomerate complex are described. 

Crystal-to-Crystal Cyclization Reactions of Allene Derivatives... 

When colorless crystals of rac-s-trans-3,8-di-tert-butyl-l,5,6,10-tetraphenyl-deca-3,4,6,7-tetraene-l,9-diyne (123) were heated at 140 °C for 2 h, the ben-zodicylobutadiene derivative (126) was produced as green crystals. As shown in the sequence (Scheme 20), 123 is first isomerized to its s-ds-isomer (124), and intramolecular thermal reaction of the two allene moieties through a [2+2] conrotatory cyclization gives the intermediate 125, which upon further thermal reaction between acetylene moieties gives the final product 126 [19,22].This is another example of the crystal-to-crystal reaction. 

An analogous catalytic system has been applied to the IH of y- and 5-allenic amines which cyclize smoothly in the 5-Exo-Trig or 6-Exo-Trig mode, giving vinylpyrrolidines and vinylpiperidines, respectively (Eq. 4.92) [313]. 

This Pd(0)/formic acid system was effective for the cyclization of substituted 5-allene-l-ynes to give diene 140 (Eq. 25) through initial insertion into the internal 7r-bond of the allene followed by insertion into the alkyne [79]. All of the examples provided were geminally substituted within the backbone to facilitate cyclization. Intramolecular allene-alkyne reductive couplings to generate six-membered rings were not achieved. 

Allenynes 160 were also cyclized chemo- and regioselectively to methylen-eyclopentane derivatives 161 and 162 using Rh(acac)(CO)2 as the catalyst and silanes or alkoxysilanes as the reductant (Eq. 32) [96]. The major product resulted from initial insertion of the internal Jt-bond of the allene into the Rh-Si bond. Only 1,1-disubstituted allenes were used for this reaction others may show less selectivity for the internal Jt-bond of the allene. 

Kant and coworkers [89] synthesized cefzil (2-167) through a Normant cuprate addition to allene 2-164, readily available from inexpensive penicillins, to give 2-165, which cyclized to the cefzil precursor 2-166 in a SN -type reaction (Scheme 2.38). The conversion of 2-166 into 2-167 was already known [90]. 

Recently, a further unique domino methodology has been reported by Lu and coworkers (Scheme 2.74) [173]. Herein, a triphenyl phosphine-catalyzed umpolung addition/cyclization of allenes and alkynes containing an electron-withdrawing group 2-316-2-318 followed by reaction with a double nucleophile 2-319 is assumed to account for the production of a broad palette of various heterocycles 2-321 and 2-323 via 2-320 and 2-322, respectively. Dihydrofurans, piperazines, morpholines and diazepanes were obtained during the process. 

Scheme 3.48. Thermolysis of benzoenynes-allenes initiating a domino radical cyclization.

As shown in the preceding examples, although intramolecular Pd-catalyzed poly-cyclization is a well-established procedure, some few examples exist of polycycliza-tions where the first step is an intermolecular process. In this respect, the Pd°-cata-lyzed domino reaction of allenes in the presences of iodobenzene reported by Tanaka and coworkers [40] is an intriguing transformation. As an example the Pd-catalyzed reaction of 6/1-60 in the presence of iodobenzene led to 6/1-61 in 49% yield, allowing the formation of three rings in one sequence (Scheme 6/1.14). 

All the synthetic protocols described above have limitations to some extent and the yields of the products were modest. In some cases the formation of 1,2-alkadi-enephosphonate derivatives is essential for obtaining the final cyclic products. This is the reason why many authors have used the higher reactivity of 1,2-alkadi-enephosphonates, discovered by Mark [42] in 1962 for the preparation of 2,5-dihydro-l,2-oxaphosphole-2-oxide derivatives. Since then, the oxaphospholic cyclization of 1,2-alkadienephosphonate system of double bonds has become the easiest method for the synthesis of these compounds. The special structure of phosphorylated allenes is responsible for their special properties, which has attracted the attention of chemists for a long time [43 16],... 

Clavepictines A and B (210 and 211, respectively) were obtained from the allenic ester 227. The reduction of its ester group to aldehyde, followed of addition to the latter of hexylmagnesium bromide, OH protection, and N-deprotection gave compound 228. A silver(i)-mediated cyclization of this compound afforded quinolizidine 229 and its C-6 epimer in a 7 1 ratio (Scheme 44). The former compound was readily converted into the target alkaloids <1997JOC4550>. 

Since cumulenes and alkynes are often easily interconvertible, many syntheses discussed above have allenic counterparts, especially base-catalyzed cyclizations of allenic alcohols.77 And, of course, several of the alkyne-based syntheses may well have allenic intermediates. There are, however, a few syntheses based specifically upon allene chemistry. In an important one, due to Stirling and his collaborators,78 an allenic sulfonium salt reacts with an enolate anion. Scheme 12 sketches the main features yields as high as 86% are recorded. Methoxyallene is easily metallated by butyllithium and so converted into an allenic epoxide that can be isomerized by fe/T-butoxide into a furan (Scheme 13) or an exocyclic equivalent similar to 15 clearly this method is particularly suited to the preparation of 3-methoxyfuran... 

Intramolecular nucleophilic additions by nitrogen functional groups onto pendant alkynes and allenes represent an important class of type la approaches to functionalized pyrroles. A platinum-catalyzed (PtCl4) cyclization of homopropargyl azides provided an entry to 2,5-disubstituted pyrroles and 4,5,6,7-tetrahydroindoles (fused pyrroles) <06OL5349>. 

A ring opening reaction of (1-lactams promoted by methoxide generated nitrogen nucleophiles in situ that subsequently added to proximal allenes producing trisubstituted pyrroles <06CC2616>. In the event, treatment of (3-lactam 3 with MeONa led to pyrrole-2-acetic ester 4 after cleavage of the amide bond, 5-exo-dig cyclization, and loss of methanol. The sequence was notable as no metal catalyst was required. 

A nickel-chromium catalyst prepared from chromous chloride and (p-diphenylphos-phinopolystyrene)nickel dichloride mediates the ring-closure of the ene-allene 236 (R = H) to a mixture of 3.4 parts of 237 and 1 part of 238 (equation 120)121. An analogous reaction of the t-butyldimethylsilyl ether of 236 yields solely the (E)-isomer 237 (R = t-BuMeaSi). Cyclization of the ene-allene 239 affords the perhydroindane 240 in 72%... 

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