Acetates vinyl, epoxidation

Allylic acetates are widely used. The oxidative addition of allylic acetates to Pd(0) is reversible, and their reaction must be carried out in the presence of bases. An important improvement in 7r-allylpalladium chemistry has been achieved by the introduction of allylic carbonates. Carbonates are highly reactive. More importantly, their reactions can be carried out under neutral con-ditions[13,14]. Also reactions of allylic carbamates[14], allyl aryl ethers[6,15], and vinyl epoxides[16,17] proceed under neutral conditions without addition of bases. 

The 1,3-diene moiety in 227 which included the carbon atoms and CVC was oxidized to the l,4-dihydroxy-2-ene moiety in 238 that was further exploited to functionalise the A-ring as well as for the annulation of the C-ring (Scheme 37). The transformation of 227 into 238 was realized by a diastereoselective epoxidation of 227 to afford a vinyl epoxide (241) that was subjected to the conditions for a Palladium(O)-catalysed allylic substitution with the acetate ion [126]. The mechanism and the stereochemical course of the allylic substitution may be explained as depicted in Scheme 37. Sn2 ring opening of the protonated vinyl epoxide 241 by an anionic Pd complex proceeded with a (3Si) topicity to the r-allyl Pd com-... 

Trost and Scanlan reported a Pd-catalyzed condensation of a vinyl epoxide 75 and an allyl sulfone 76 in the presence of dppf under neutral conditions [231]. This alkylation allows a room temperature entry to a basic indolizidine ring system as a step towards the synthesis of (+)-aj//o-Pumiliotoxin 339B [232], The modification of allylic alkylations by condensation of a diene 77 with a pronucleophile 78 also leads to C-C bond formation at the allylic position in both 1 1 (79 and 80) and 2 1 (81 and 82) products [233]. Reactions between ketene silyl acetals 83 with allyl... 

Besides ordinary halides and sulfonic acid esters, the development of transition metal catalyzed processes has enabled allylic alcohols, acetates, carbonates, vinyl epoxides and vinyllactones also to be successfully employed as allylic substrates. 

The resulting derivatives were applied with success in the standard asymmetric allylic alkylation (up to 97 % ee) [134, 136] or in transformations involving either specific allylic substrates (2-cycloalkenyl derivatives, up to >99% ee) [135, 137], unsymmetrical substrates (monosubstituted allyl acetate, up to 83% ee) [140], or especial nucleophiles (nitroalkanes [141], iminoesters [138 a], or diketones [139, 140, 142]). Such ligands were also effective in the formation of quaternary chiral carbon through allylic substitution (eq. (6)) [138, 143], deracemiza-tion of vinyl epoxides (up to 99% ee) [144], or alkylation of ketone enolates [138 b], and deracemization of allylic derivatives [145]. 

Ethylene oxide and simple primary and secondary epoxides 271 Tertiary epoxides 272 Acetals and epoxy ethers 272 Vinyl epoxides 273... 

One can open the epoxide, however, by treating it with sodium acetate in acetic acid at 85 °C for 48 hours and obtain the gylcol acetate, 12, in quantitative yield. Treatment of tridiphane with one equivalent of sodium methoxide in methanol at room temperature causes hydrogen chloride elimination and formation of the vinyl epoxide, 13, which has little herbicidal activity. In contrast to sodium methoxide, sodium methylthiolate readily opens the epoxide ring giving the / -thioalcohol, 14 in quantitative yield. 

A-Glycosylimidazoles (related to nucleosides) are of interest in the preparation of novel chemotherapeutic agents, hence selective A -glycosylation techniques are of interest. The palladium-catalyzed addition of vinyl epoxides and allyl acetates to imidazoles provides one such route to imidazole nucleoside analogues <91JCS(Pi)2603, 9UOC4990>. The silyl-Hilbert-Johnson method is another in which the imidazole is silylated, then treated with a suitable peracetylated carbohydrate derivative in the presence of trimethylsilyl triflate catalyst. With 4-carbamoylimidazolium-5-olate, for example, the major product is the l-glycosyl-5-carbamoyl isomer with only low yields of the... 

Alkylation of allylic acetates also occurred under these conditions, NEt3 - or better l,8-diazabicyclo[5.4.0]undec-7-ene (dbu) - being used as the base, as well as that of vinyl epoxides. 

Alkylation of allylic acetates or vinyl epoxide occurred also under these conditions,... 

Allyl sulfones can be obtained by the Pd(Ph3P)4-catalyzed reaction of ally lie acetates and ally lie nitro compounds with NaS02Ar (eq 28). Pd(Ph3P)4 also catalyzes the addition of HOAc to vinyl epoxides, providing a facile entry into 1,4-hydroxy acetates. ... 

McIntosh et al. have applied the Ireland-Claisen rearrangement of bis-allyl silyl ketene acetals in studies directed toward the synthesis of the eupomatilones (Scheme 4.135) [128]. The 1,2-transposition of the alkene, which occurred in the rearrangement afforded a reactive vinyl epoxide (cf Scheme 4.83). Stereoselective cyclization of the carboxylic acid onto the vinyl epoxide generated the 5-aryl lactone, which was further manipulated to the putative structure of 5-epi-eupoma-tilone-6. 

In contrast, a-allylated products such as 93 are obtained, when ester enolate 90 is treated with vinyl epoxides, although the yields varied, depending on the vinyl epoxide used (Scheme 12.49) [114]. As usual, nucleophilic attack occurs at the sterically less hindered position yielding an ( /Z)-isomeric product mixture. Similar results are obtained with silyl ketene acetals in the presence of bidentate phosphine ligands [115]. 

Reactions that proceed under neutral conditions are highly desirable. An important event in TT-allylpalladium chemistry is the introduction of highly reactive allylic carbonates (Sect. V.2.1.3), Their reactions can be carried out under mild neutral conditions. " Also, reactions of allylic carbamates, " allyl aryl ethers, and vinyl epoxides proceed without addition of bases. As shown by the mechanism in Scheme 6, the oxidative addition of allyl methyl carbonates is followed by decarboxylation as an irreversible process to afford TT-allylpalladium methoxide, and the generated methoxide picks up a proton from pronucleophiles (NuH), such as active methylene compounds. This in situ formation of the alkoxide is the reason why the reaction of aUyl carbonates can be carried out without addition of bases from outside. Alkoxides are rather poor nucleophiles, and alkyl allyl ethers are not formed from them. In addition, formation of TT-allylpalladium complexes from allylic carbonates involving decarboxylation is irreversible. In contrast, the formation of TT-allylpalladium acetate from allyl acetate is reversible. 

We mentioned that by mixing vinyl epoxides and zerovalent palladium, the alcoholate formed was usually sufficiently basic to deprotonate the pronucleophile entity. In some cases, especially with ketones, low reactivity and yields were reported (Table To overcome the problem of the weak basicity of the alcoholate, silyl enol ethers, keto adds, or preformed lithium enolates have successfully been employed.f f" f f /3-Keto acids are masked enolates via the decarboxylation of the intermediary Tr-allylpalladium ]3-ketocarboxylate complexes. The main limitation of the use of keto adds as pronucleophiles seems to be their low reactivity toward the hindered cyclic vinyl epoxides. In these cases, the cationic n-allylpalladium complex undergoes ]S-elimination. Indeed, the reaction between benzoyl acetic acid and cyclobutadiene monoxide in the presence of Pd(PPh3>4 gives only the corresponding cyclopentanone and acetophenone as the... 

Formation of Allyl and Aryl Primary AUyUc and HomoallyUc Alcohols from Vinyl Epoxides and Oxetanes. Vinylic epoxides can be coupled with aryl (eq 30) or vinyl (eq 31) iodides or tri-flates to form allylic alcohols in 40-90% yield. When employing palladium acetate as the catalyst, a reducing agent such as sodium formate is required in addition to the salts normally present under phase transfer conditions. 

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