Furans allenyl ketones

The 4-kcto group in the alkyne 262 as an enol form adds to the triple bond to give the furan 263[133], Even the conjugated keto alkyne 264 was converted into the furan 266 via isomerization to the allenyl ketone 265[134],... 

Disubstituted furans 62 are obtained from a gold-catalyzed cycloisomerization/dimerization pathway involving terminal allenyl ketones and a,(3-unsaturated ketones <00AG(E)2285>. 

Pd-catalyzed isomerization of ynones to furans has been an active area of research over the last decade. Huang et al. described a Pd-catalyzed rearrangement of a,P-acetylenic ketones to furans in moderate yield [102], For example, Pd(dba)2 promoted the isomerization of alkyne 124 to a putative allenyl ketone intermediate 125, which subsequently cyclized to the corresponding furan 126. 

The analogous transformation of 125, also realized by flash vacuum pyrolysis, gave rise to allenic oximes 126 [165], which are not directly accessible by the classical route starting from allenyl ketones and hydroxylamine (see Section 7.3.2) [122], Because compounds 125 are prepared from allenyl ketones and furan by [4 + 2]-cycloaddition followed by treatment with hydroxylamine, the retro-Diels-Alder reaction 125 —> 126 is in principle the removal of a protecting group (see also Scheme 7.46). 

Marshall et al. noted that under the catalysis of Ag+ or Rh+, 1,2-allenyl ketone or aldehyde 417 may undergo cycloisomerization to afford furans 418. The reaction proceeded via the interaction of Ag+ or Rh+ with the relatively electron-rich C=C bond in the allene moiety followed by nucleophilic attack of the carbonyl oxygen [187]. Through a labeling study, it was found that the reaction proceeds by the mechanism shown in Scheme 10.162 [188]. 

Allenyl alcohols have been used as starting materials for a different kind of dihydrofuran synthesis. This is a process with great generality and utility in total synthesis. An example of the process is shown in Eq. 13.43 [42]. Treatment of allenyl alcohol 133 with silver nitrate in aqueous acetone at room temperature leads stereospe-cifically to dihydrofuran 134 in excellent yield. A similar reaction occurs with allenyl ketones, leading to furans. The isomerization is known to take place with Rh(I) [43], Ag(I) [44, 45] Pd(II) [46], Au(III) [47, 48] Cu(I) [49] or Hg(II) [50, 51],... 

The Mo(CO)s(NEt3) complex isomerizes the allenyl ketone 111 to the furan 112 even the free hydroxyl group is tolerated, but with 50% of catalyst a 28% yield is not too (effective turnover number (TON) =0.5 Scheme 15.30) [69]. 

A similar isomerization of an allenyl ketone, catalyzed by a Cr(CO)sL complex, is most probably the mechanistic key step of the palladium-catalyzed conversion of chromium carbene complexes and propargyl bromide to furans. In control experiments different aryl and alkyl allenyl ketones 96 isomerized to the furans 99 in the presence of 10 mol% of Cr(CO)5(NEt3) in good yields (Scheme 15.31) [70],... 

Gevorgyan and co-workers demonstrated that allenyl imines can be formed in situ by treating alkynylimines with a base (see Section 15.8, compound 185) [71, 72]. The same principle also works for the in situ formation of allenyl ketones from alkynyl ketones and their conversion to furans with a copper(I) catalyst [71, 72]. That Cu(I) would catalyze the isomerization of an allenyl ketone was known from work of Hashmi et al. [57, 58],... 

Although, as shown above, a number of metals [Hg(II), Rh(I), Ag(I), Pd(II), Au(III) and Cu(I)[ are active for the cycloisomerization of allenyl ketones, some substrates are still restricted to the use of Hg(II) as Leclerc and Tius demonstrated recently for 113, the cyclopentane-anellated furan 114 was only accessible with the mercury catalyst (Scheme 15.32) [73],... 

Allenyl ketones and aryl halides undergo coupling and cyclization in the presence of a palladium-triphenylphosphine catalyst and silver carbonate. The reaction leads to the formation of furane derivatives, the aryl group being introduced into the 3-position (3.72.) 90... 

The formation of 2 furane rings was achieved in one transformation by Ma and co-workers. Allenoic acids and allenyl ketons were reacted in the presence of a palladium catalyst to give the unsymmetrical bifuryl product, arising from the cyclization of both allene derivatives mediated by the same palladium centre followed by their coupling (3.73.) 91... 

Reactions by Arenes The work of Hashmi et al. to form a, 3 -unsaturated ketones by reacting allenyl ketones and furans presented the first results in these types of gold-catalyzed processes [28] (Scheme 8.3). 

In a more recent publication Hashmi et al. reported that propargyl ketones such as 20 and allenyl ketones such as 21 can be cyclized to furans such as 22 in reactions catalyzed by gold(III) chloride (Scheme 5) [12]. This type of reaction had already been described as a... 

In addition to this latter work, a silver-catalyzed 1,2-alkyl/aryl shift is also possible with allenyl ketones (16), giving, as before, highly substituted furans (17, Scheme 5.9).44 Not surprisingly, Gevorgyan et al. observed that the migratory aptitude... 

Terminal disubstituted allenyl ketones were used in the synthesis of tri- and tetra-substituted furans in the presence of In(OTf)3 and other metal salts as catalyst. In this reaction, a 1,2-shift of a terminal alkyl group is a key step <07AGE5195>. 

The cycloisomerization of allenyl ketones can be exploited for the synthesis of 2,3,4- or 2,3,5-trisubstituted and tetrasubstituted furans, when the Pd(0)-catalyzed cyclization of a,7-disubstituted substrates is combined with the coupling of an aryl halide or substituted allyl halide, as has been reported by Ma et al. (Equation 14) <20000L941, 2000CC117, 2003CEJ2447>. 

Hashmi et al. have found that terminal allenyl ketones give dimerization products when Pd(ll)-catalysts are employed furnishing 2,4-disubstituted furans (Equation 15) <1995AGE1581, 1997JOC7295>. Tetrakis(2,2,2-trifluoroethoxycarbonyOpalladacyclopentadiene proved to be the most effective catalyst to obtain predominantly dimerization instead of cycloisomerization. 

In the presence of 1 mol% AuCls, allenyl ketones undergo a rapid cycloisomerization and can be reacted with a Michael acceptor. In a cross-dimerization of terminal allenyl ketones and a,/3-unsaturated ketones, 2,5-disubstituted furans can be obtained (Equation 16) <2000AGE2285>. 

It has been shown by Marshall and Sehon that in the presence of AgNOs absorbed on silica gel, /3-alkynyl allylic alcohols, which are more accessible than allenyl ketones, also undergo cycloisomerization to furans (Equation 19) <1995JOC5966>. Similarly, 3-trifluoromethylfurans can be prepared utilizing a Pd(ii) catalyst <2000JOC2003>. 

Allenyl ketones can also be cross-coupled with allenoic acids to give 2,4-disubstituted furans <2002AGE1775> or with allenamides to yield 4-(3 -furanyl)-2(5//)-furanimines <2005JOC6291>. With chiral allenoic acid derivatives, 4-(3 -furanybbutenolides can be synthesized stereoselectively with complete chirality transfer (Equation 47) <2004CEJ2078>. 

Isomerization of an a-allenylcyclopentenone, obtained from a propargyl ether and a mopholino a,p-unsaturated amide, in the presence of Hg-catalyst to a furanyl cyclopentenone provided another example of the conversion of allenyl ketones to furans <03OLl 171>. 

Tandem coupling and cyclization. Functionalized allenes are converted to a-arylvinylated cyclopropanes and heterocycles including epoxides, tetrahydrofurans, and oxazolidinones. Furan derivatives are formed from allenyl ketones." ... 

Allenyl ketones cyclise to furans with metal ion or metal(O) catalysis. 

Allenyl ketones presynthesised, or generated in situ by acylation of silyl-allenes, or by palladium(0)-catalysed isomerisation of conjugated or non-conjugated alkynyl ketones, can be cyclised to furans. The ring closure has been effected with silver or palladium catalysis acylation of silylallenes leads to the furan directly. In the presence of water, palladium(II)-catalysed closure of / ,7-alkynyl ketones is believed to proceed via the enol, not the allene. l,2,3-Trienyl-4-ols have also been shown to cyclise to give furans. ... 

We have also shown that under the catalysis of Pd(PPh3)4 and Ag2C03, the coupling cyclization of 1,2-allenyl ketones with organic halides afforded poly-substituted furans (Scheme 6). The diversity of the reaction depends on the structures of the two starting materials, i.e., once the expected substituent is in a certain location of two starting materials, it can be assembled into the expected location of polysubstituted furans. However, for the synthesis of tetra-substituted furans, the reaction should be carried out in the presence of 20 mol% of n-Bu4N Br in DMA (conditions B). 

In 1997, Hashmi et al. observed the Pd-catalyzed homodimerization of 1,2-allenyl ketones affording2-substituted4-(4 -oxo-2 -alken-2 -yl)furans (Scheme 31) [23]. The reaction may proceed via intramolecular oxypalladation involving the carbonyl oxygen, leading to the formation of furanylpalladium intermediate 69, followed by intermolecular carbopalladation with a second molecule of 1,2-allenyl ketone. Protonation of the C-Pd bond in 70 afforded the product 66 and regenerated Pd(II) (Scheme 32). 

Acetylenic ketones are viable substrates as well for gold-catalyzed cyclizations to furans. Whereas alk-3-yn-l-ones readily cyclize to substituted furans in the presence of gold(I) or gold(III) chloride (possibly via isomerization to a-allenyl ketones see Section 5.2), the corresponding transformation of alk-4-yn-l-ones takes place in the presence of the cationic gold catalyst generated in situ from PhsPAuCl and AgOTf in toluene (Scheme 4-83). The cyclization is accelerated by... 

The cycloisomerization of a-allenyl ketones to the corresponding substituted furans was the first example of a gold-catalyzed addition of an oxygen nucleophile to an allene (Scheme 4-86). Traditionally, silver or palladium catalysts were employed for cyclizations of this type advantages of gold catalysis incluiie shorter reaction times, milder conditions, an or lower catalyst loadings. Variable amounts of... 

Transition metal-catalyzed cydoisomerization of allenyl ketones into furan products was first introduced by Marshall. In the first report from this group, it was demonstrated that various alkyl-substituted furans 2 could be prepared in high yields via the Ag-[50] or the Rh(I)-catalyzed [85, 86] cydoisomerization of allenyl ketones 1 (Scheme 8.1) [87]. This type of transformation of allenyl ketones [88-90] proved to be highly effident for the synthesis of up-to-trisubstituted furans. Furthermore, Marshall applied this strategy as the key step in the construction of the 2,5-disubstituted furanocycle 2a (Scheme 8.2) [87]. 

Cycloisomerization of allenyl ketones 11 into furan products 12 was further elaborated by Hashmi (Scheme 8.5). It was found that this transformation could be effectively catalyzed by other transition metals, such as Cu(I), Ag, Rh(II), and Ru(II) [100, 101], Several aryl-containing furans were synthesized via the silver-catalyzed protocol in high yields (Scheme 8.6) [102]. 

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