Vinyl epoxides cyclic

Cationic t 3-allyltetracarbonyliron complexes are generated by oxidative addition of allyl iodide to pentacarbonyliron followed by removal of the iodide ligand with AgBF4 under a carbon monoxide atmosphere [35]. Similarly, photolysis of vinyl epoxides or cyclic vinyl sulfites with pentacarbonyliron or nonacarbonyldiiron provides Jt-allyltricarbonyliron lactone complexes. Oxidation with CAN provides by demetallation with concomitant coupling of the iron acyl carbon to one of the termini of the coordinated allyl moiety either [3- or 8-lactones (Scheme 1.12) [36, 37]. In a related procedure, the corresponding Jt-allyltricarbonyliron lactam complexes lead to P- and 8-lactams [37]. 

The above reaction is reversible, and the monomer competes with ylid 5 for the reaction with HX. Those monomers which are more nucleophilic than 5 can be polymerized, i.e. they are epoxides, vinyl ethers and cyclic acetals. 

The epoxidation of cyclic vinyl sulfone 254 proceeded with high diastereoselec-tivity, only the anti epoxide 255 was formed as a single isomer (Scheme 65).135... 

Relative reactivities 254 Simple vinyl epoxides 255 Cyclic vinyl epoxides 257... 

However, unlike the triaryIsulfonium salts, these compounds undergo reversible photoinduced ylid formation rather than homolytic carbon-sulfur bond cleavage. Because the rate of the thermal back reaction is appreciable at room temperature, only those monomers that are more nucleophilic than the ylid will polymerize. Epoxides, vinyl ethers, and cyclic acetals undergo facile cationic polymerization when irradiated in the presence of dialkylphenacylsulfonium salts as photoinitiators. 

A variety of classes of monomers undergo cationic chain polymerization, including epoxides, vinyl ethers, propenyl ethers, siloxanes, oxetanes, cyclic acetals and for-mals, cyclic sulfides, lactones, and lactams. Any monomer that undergoes cationic polymerization is a candidate for cationic photopoiymerization, and a suitable monomer may be selected based upon the specific requirements of the application. 

Until this work, the reactions between the benzyl sulfonium ylide and ketones to give trisubstituted epoxides had not previously been used in asymmetric sulfur ylide-mediated epoxidation. It was found that good selectivities were obtained with cyclic ketones (Entry 6), but lower diastereo- and enantioselectivities resulted with acyclic ketones (Entries 7 and 8), which still remain challenging substrates for sulfur ylide-mediated epoxidation. In addition they showed that aryl-vinyl epoxides could also be synthesized with the aid of a,P-unsaturated sulfonium salts lOa-b (Scheme 1.4). 

Anionic copolymerization of cyclic monomers occurs only between similar monomer pairs. Random copolymers are not formed between vinyl monomers and epoxides or lactones198 because the propagating species are very different. Thus, the success of the copolymerization of cyclic disulfide and nitropropylene was an exceptional case... 

An alternate way to make block copolymers involving PDMS blocks 124,125) is to have these chains fitted with epoxide functions at chain end, and to react them with a vinylic or dienic polymer carrying terminal COOH functions. Sequential addition of monomers has also been used, the ring opening polymerization of the cyclic trimer (D3) being initiated by the anionic site of a living polymer126). 

In Entry 5, the carbanion-stabilizing ability of the sulfonyl group enables lithiation and is then reductively removed after alkylation. The reagent in Entry 6 is prepared by dilithiation of allyl hydrosulfide using n-bulyl lithium. After nucleophilic addition and S-alkylation, a masked aldehyde is present in the form of a vinyl thioether. Entry 7 uses the epoxidation of a vinyl silane to form a 7-hydroxy aldehyde masked as a cyclic acetal. Entries 8 and 9 use nucleophilic cuprate reagents to introduce alkyl groups containing aldehydes masked as acetals. 

The results of the olefin oxidation catalyzed by 19, 57, and 59-62 are summarized in Tables VI-VIII. Table VI shows that linear terminal olefins are selectively oxidized to 2-ketones, whereas cyclic olefins (cyclohexene and norbomene) are selectively oxidized to epoxides. Cyclopentene shows exceptional behavior, it is oxidized exclusively to cyclopentanone without any production of epoxypentane. This exception would be brought about by the more restrained and planar pen-tene ring, compared with other larger cyclic nonplanar olefins in Table VI, but the exact reason is not yet known. Linear inner olefin, 2-octene, is oxidized to both 2- and 3-octanones. 2-Methyl-2-butene is oxidized to 3-methyl-2-butanone, while ethyl vinyl ether is oxidized to acetaldehyde and ethyl alcohol. These products were identified by NMR, but could not be quantitatively determined because of the existence of overlapping small peaks in the GC chart. The last reaction corresponds to oxidative hydrolysis of ethyl vinyl ether. Those olefins having bulky (a-methylstyrene, j8-methylstyrene, and allylbenzene) or electon-withdrawing substituents (1-bromo-l-propene, 1-chloro-l-pro-pene, fumalonitrile, acrylonitrile, and methylacrylate) are not oxidized. 

The use of vinyl epoxides as substrates in enantioselective copper-catalyzed reactions, on the other hand, has met with more success. An interesting chiral ligand effect on Cu(OTf)2-catalyzed reactions between cyclic vinyloxiranes and dialkylzinc reagents was noted by Feringa et al. [51]. The 2,2 -binaphthyl phosphorus amidite ligands 32 and 43 (Fig. 8.5), which have been successfully used in copper-catalyzed enantioselective conjugate additions to enones [37], allowed kinetic resolution of racemic cyclic vinyloxiranes (Scheme 8.26). 

The influence of the size and configuration of various cyclic vinyl carriers (Scheme 6.26) on the stereoselectivity of cycloaddition was studied, and included epoxides, (3-lactams, dioxaborolanes, and dioxans (22). Although the anti preference was maintained in all cases, the conformation of the carrier ring must also be taken into account in order to rationalize the stereoselections observed. The highest diastereomeric ratio was observed with the vinyl-tetrahydrofuran derived from glucose, where the conformational mobility of the carrier ring is substantially locked by an acetonide clamp and one face of the C=C bond is effectively shielded (22,165,215). 

A series of functionalized alkenes has been subjected to selective epoxidation reactions. Oxidation of perfluorinated vinyl polyethers by bubbling oxygen through the liquid that contains a catalytic amount of a Lewis acid, e.g. antimony(V) fluoride, results in the formation of acid fluorides together with a smaller amount of C = C bond cleavage.76 Perfluorinated pentaaIkyI-2.3-dihydrofuran 38, an example of an unsaturated cyclic ether that is quite stable owing to perfluoroalkylation. is epoxidized by hypochlorite to the product 39 at 45 C.62... 

Vinyl epoxides have been found to eliminate a 0-H on treatment with Pd° in the absence of nucleophiles. Acyclic vinyl epoxides give dienols, whereas cyclic vinyl epoxides yield fj/y-unsaturated ketones (equations 127 and 128).326 Additional examples of 0-H elimination of allylpalladium complexes to generate dienes have been reported.327-332... 

The palladium-catalyzed reaction of aryl- and vinyl-tin reagents with stereochemically defined allyl chlorides proceeds with overall retention of configuration, indicating that the second step, entailing interaction of the iT-allylpalladium complex and the organotin, proceeds by transmetallation and reductive elimination (attack at Pd, retention) (equations 166 and 167).142145 Comparable results were obtained with cyclic vinyl epoxides and aryltins.143... 

It was found that the cyclic vinyl sulfone with t-BuOOLi yielded only a single stereoisomer. The structure was established as the anti-epoxide by an X-ray crystal structure... 

The palladium-catalyzed fixation of C02 is also a useful method for the synthesis of CCs, with the first such example using vinyl-substituted epoxides and a palladium catalyst [Pd(PPh3)4/PPh3] having been reported independently by both Fujinami and Trost [147, 148]. Here, the carbonate is produced via the formation of a first tr-allyl-palladium intermediate (I) this then fixes C02 to form a second tr-allyl-intermediate (II) that produces vinyl-substituted cyclic carbonates (Scheme 7.8). 

Alkylation of vinyl epoxides. Although Pd(0) catalyzes the rearrangement of vinyl epoxides (9,452-453), alkylation of cyclic or acylic vinyl epoxides with dimethyl malonate under neutral conditions is possible with the same catalyst or with bis[l,2-bis(diphenylphosphino)ethane]palladium. The rearrangement and alkylation proceed with different regio- and stereoselectivity.19... 

The cyclic substrate 32 and other disubstituted olefins such as 35a were oxidized in sc C02 to give the corresponding epoxides with reasonable rates (>95% conversion in less than 18 h) and excellent selectivities (>98%) under otherwise similar reaction conditions (Loeker and Leitner, 2000). It is important to note, however, that no addition of a metal catalyst was required in the supercritical reaction medium. Detailed control experiments revealed that the stainless steel of the reactor walls served as efficient initiator for the epoxidation under these conditions. Terminal olefins 35b,c were oxidized with somewhat reduced rates and either epoxidation or vinylic oxidation occurred as the major reaction pathway depending on the substrate (eq. 5.11). Apart from providing the first examples for efficient and highly selective oxidation with 02 in sc C02 (earlier attempts Birnbaum et al., 1999 Loeker et al., 1998 Wu et ah, 1997), this study points to the possible importance of wall effects during catalytic reactions in this medium (see also Christian et ah, 1999 Suppes et ah, 1989). 

Various unsaturated compounds, such as CO2, isocyanates and aldehydes, undergo Pd-catalysed cycloaddition with vinyl epoxides. Reaction of CO2 with 127 affords cyclic carbonates 128 with retention of the configuration at C(3), offering a method of cis hydroxylation of epoxides [66], and has been used for the synthesis of the side-chain unsaturated (—)-exo-brevicomin (129) [67], The tetrahydrofuran 131 was prepared by [3+2] cycloaddition of activated alkenes such as benzylidene malononitrile (130) with vinyl epoxide via Michael addition and allylation [68],... 

An NMR spectrum would readily distinguish between these possibilities. For example, the vinyl ether would show a methyl singlet at about 5 3-4, the middle structure would show a 4H multiplet at 8 3-4, and the epoxide would show a methyl doublet at about 5 1.0-1.5. The presence of a band at about 1650 cm-1 in the IR spectrum (C=C stretch) would indicate that the compound is the vinyl ether (the first of the three compounds) and not the cyclic ethers. 

Cyclic allylic cyanocuprates can also be prepared from cyclic allylic stannanes by reaction with CH3Li followed by CuCN solubilized with LiCl. These cyanocuprates couple with enones, primary and vinylic halides and epoxides (equation III).9... 

Indeed, Adam observed that, whereas acyclic vinyl silanes 132 undergo smooth epoxidation in excellent yield, the cyclic substrates exhibit varying amounts of allylic oxidation as well. The C-H insertion pathway becomes more prominent when the double bond is deactivated by either steric or electronic influences. Thus, the /-butyl derivative 134 gives as much as 20% of the allylic oxidation product (136) [95TL4991]. 

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