Ethers, alkynic enol ether preparation

The preparation of the quinoline system by pericyclic reactions is less important than the previous syntheses. Some cyclization/elimination reactions of iV-phenylimines 95 and 96 with alkynes, enol ethers or enamines are of preparative interest. Although they correspond to [4+2] cycloadditions, they are likely to proceed by SeAt mechanisms and are usually catalysed by Lewis acids. In the enolether cycloaddition to imines 95 ytterbium(III)triflate proved to be particularly effective [104]. 

The cyclic enol ether 255 from the functionalized 3-alkynoI 254 was converted into the furans 256 by the reaction of allyl chloride, and 257 by elimination of MeOH[132], The alkynes 258 and 260, which have two hydroxy groups at suitable positions, are converted into the cyclic acetals 259 and 261. Carcogran and frontalin have been prepared by this reaction[124]. 

Cyclobutanones (11, 560-561). Ketenimium salts are more reactive than ke-tenes in [2 + 2] cycloadditions with alkenes to prepare cyclobutanones. The salts are readily available by in situ reaction of tertiary amides with triflic anhydride and a base, generally 2,4,6-collidine. The cycloaddition proceeds satisfactorily with alkyl-substituted alkenes and alkynes, but not with enol ethers or enamines.1... 

In addition to reactions characteristic of carbonyl compounds, Fischer-type carbene complexes undergo a series of transformations which are unique to this class of compounds. These include olefin metathesis [206,265-267] (for the use as metathesis catalysts, see Section 3.2.5.3), alkyne insertion, benzannulation and other types of cyclization reaction. Generally, in most of these reactions electron-rich substrates (e.g. ynamines, enol ethers) react more readily than electron-poor compounds. Because many preparations with this type of complex take place under mild conditions, Fischer-type carbene complexes are being increasingly used for the synthesis [268-272] and modification [103,140,148,273] of sensitive natural products. 

Another rhodium vinylidene-mediated reaction for the preparation of substituted naphthalenes was discovered by Dankwardt in the course of studies on 6-endo-dig cyclizations ofenynes [6]. The majority ofhis substrates (not shown), including those bearing internal alkynes, reacted via a typical cationic cycloisomerization mechanism in the presence of alkynophilic metal complexes. In the case of silylalkynes, however, the use of [Rh(CO)2Cl]2 as a catalyst unexpectedly led to the formation of predominantly 4-silyl-l-silyloxy naphthalenes (12, Scheme 9.3). Clearly, a distinct mechanism is operative. The author s proposed catalytic cycle involves the formation of Rh(I) vinylidene intermediate 14 via 1,2-silyl-migration. A nucleophilic addition reaction is thought to occur between the enol-ether and the electrophilic vinylidene a-position of 14. Subsequent H-migration would be expected to provide the observed product. Formally a 67t-electrocyclization process, this type of reaction is promoted by W(0)-and Ru(II)-catalysts (Chapters 5 and 6). 

Methylene difluorocyclopropanes are relatively rare and their rearrangement chemistry has been reviewed recently [14]. In addition, electron deficient alkenes such as sesquiterpenoid methylene lactones may be competent substrates. Two crystal structures of compounds prepared in this way were reported recently [15,16]. Other relatively recent methods use dibromodifluoromethane, a relatively inexpensive and liquid precursor. Dolbier and co-workers described a simple zinc-mediated protocol [17], while Balcerzak and Jonczyk described a useful reproducible phase transfer catalysed procedure (Eq. 6) using bromo-form and dibromodifluoromethane [18]. The only problem here appears to be in separating cyclopropane products from alkene starting material (the authors recommend titration with bromine which is not particularly amenable for small scale use). Schlosser and co-workers have also described a mild ylide-based approach using dibromodifluoromethane [19] which reacts particularly well with highly nucleophilic alkenes such as enol ethers [20], and remarkably, with alkynes [21] to afford labile difluorocyclopropenes (Eq. 7). 

Dehydrobromination of bromotrifluoropropene affords the more expensive trifluoropropyne [237], which was metallated in situ and trapped with an aldehyde in the TIT group s [238]synthesis of 2,6-dideoxy-6,6,6-trifluorosugars (Eq. 77). Allylic alcohols derived from adducts of this type have been transformed into trifluoromethyl lactones via [3,3] -Claisen rearrangements and subsequent iodolactonisation [239]. Relatively weak bases such as hydroxide anion can be used to perform the dehydrobromination and when the alkyne is generated in the presence of nucleophilic species, addition usually follows. Trifluoromethyl enol ethers were prepared (stereoselectively) in this way (Eq. 78) the key intermediate is presumably a transient vinyl carbanion which protonates before defluorination can occur [240]. Palladium(II)-catalysed alkenylation or aryla-tion then proceeds [241]. 

Enantioselective conjugate addition can also be carried out with cyclic enones. Shuichi Oi and Yoshio Inoue of Tohoku University in Sendai report (Tetrahedron Lett. 2004, 45, 5051) that a BINAP complex of Rh catalyzes the enantioselective conjugate addition of alkenyl Zr species such as 5, to give 7 in high enantiomeric excess. Alkenyl Zr species such as 5 are readily prepared by hydridozirconation of alkynes. It is particularly important that addition of TMS-C1 to the reaction mixture at the end of the conjugate addition leads cleanly to the enol ether 6. 

Most of the approaches outlined in Figure 15.10 have been successfully realized on insoluble supports, either with the alkene or alkyne linked to the support, or with support-bound 1,3-dipoles (Table 15.16). Nitrile oxides are highly reactive 1,3-dipoles and react smoothly with both electron-poor and electron-rich alkenes, including enol ethers [200]. The addition of resin-bound nitrile oxides to alkenes (Entries 5 and 6, Table 15.16) has also been accomplished enantioselectively under catalysis by diisopropyl tartrate and EtMgBr [201], The diastereoselectivity of the addition of nitrile oxides and nitrones to resin-bound chiral acrylates has been investigated [202], Intramolecular 1,3-dipolar cycloadditions of nitrile oxides and nitrones to alkenes have been used to prepare polycyclic isoxazolidines on solid phase (Entries 7 and 9, Table 15.16). 

Allyl cyanides can be added across alkynes in the presence of a nickel catalyst prepared from (COD)2Ni and (4-CF3CeH4)3P in situ to give functionalized di- or tri-substituted acrylonitriles in a highly stereoselective manner, presumably via n-allylnickel intermediates. a-Siloxyallyl cyanides also react at the y -position of a cyano group with both internal and terminal alkynes to give silyl enol ethers, which can be converted into the corresponding aldehydes or ketones upon hydrolysis.70... 

Intramolecular Lewis acid-promoted reaction of coordinated propargylic ether with the silyl enol ether in 158 has been applied successfully to the construction of the highly strained 10-membered cyclic enediyne system 159, present in esperamycin and calicheamycin [39,40]. The enediyne system 157 was prepared by the Pd-catalysed Sonogashira coupling of (Z)-l,2-dichloroethylene (154) with two different terminal alkynes 155 and 156. 

In previous investigations allynes and alkyne derivatives containing enol ethers, alkoxy and acetal and ketal olefins were prepared by the author and are described (1). 

As with other intramolecular ene reactions, this reaction is best suited to the preparation of cyclopentanes, but can also be used for the preparation of cyclohexanes. The reaction cannot be used for the formation of cyclopropanes or cyclobutanes since the unsaturated carbonyl compound is more stable than the ene adduct. 8,e-Unsaturated ketones (167) do not give cyclobutanes (171) by enolization to give (170) followed by a type I reaction but instead give cyclohexanones (169) by enolization to give (168) followed by a type II reaction. Alkynes can replace alkenes as the enophile. Enols can be prepared from pyrolysis of enol esters, enol ethers and acetals and from -keto esters and 1,3-dicaibonyl compounds. Tlie reaction is well suited to the preparation of fused or bridged bicyclic and spirocyclic compounds. Tandem ene reactions in which two rings are formed in one pot from dienones have also been described. The examples discussed below 2-i63 restricted to those published since Conia and Le Perchec s 1975... 

Here lies the first roadblock. Although the large scale preparation of some related vinyl derivatives such as enol ethers from acetylene itself has been used in the chemical industry for years, these syntheses usually require catalysis by mercuric salts and yields are often quite poor. Similarly, enamines have been claimed to be intermediates in the synthesis of amines from alkynes, but this process also requires mercuric ion catalysis. ... 

In contrast to the addition of water, the addition of alcohols to alkynes leads to stable enol ethers. Those of economic importance are almost exclusively the vinyl ethers prepared from acetylene. This preparation is carried out under base catalysis [41] (KOH, alcoholates, and the like). The noble metal-catalyzed alcohol addition does in fact likewise lead, in an intermediate stage, to vinyl ethers, but these react under the prevailing conditions, generally in a quantitative reaction, to give to corresponding acetaldehyde dialkyl acetals [42]. This is illustrated in (eq. (18)), which takes as its example the addition of n-butanol to acetylene in the presence of Na2PtCl6. 

Trialkylsiloxyallylidene)cyclopropanes 58, prepared from the corresponding ketones 57, underwent facile cycloadditions with activated alkenes and alkynes to give 59 and 60, respectively (Table 6). The enol ethers were hydrolyzed directly upon aqueous workup. 

Among the reactions of the 1,2,4-triazines, the hetero-DlELS-ALDER reactions with electron-rich alkenes and alkynes are of special importance in preparative chemistry [168]. The heterocyclic ring reacts with enamines, enol ethers and ketene acetals as an electron-deficient 2,3-diazadiene across the ring positions C-3 and C-6 ... 

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