Triflates allyl esters/ethers

The highest diastereoselectivity of asymmetric methoxyselenenylation of alkenes was achieved using the ferrocenylselenium triflates in excellent chemical yields [5gj. For example, the stoichiometric reaction of the chiral ferrocenylselenium triflate 41, prepared from the chiral diferrocenyl diselenide 2, with traus- -methylstyrene afforded the corresponding methoxyselenenylated product in high chemical yield with excellent diastereoselectivity (up to 98 % de). Fukuzawa and co-workers employed the diferrocenyl diselenide 2 for the catalytic asymmetric oxidation of, y-unsaturated esters and traus- -methylstyrene to the corresponding optically active allylic methyl ethers with moderate enantio-selectivity (Scheme 24) [27]. The allylic ethers were produced from 4-phenyl-3-butenoic acid esters in 70-78% yield with 17-22% ee. 

The C-4 acids (183 and 184) have also been subjected to borane reduction conditions to afford alcohol 195 in 23-50% yield or 64% yield as the C-8 epimeric mixture (195 and 196, Scheme 29) [34, 49, 64]. The C-8 alcohol epimers 195 and 196 have been treated separately as a common intermediate for a number of C-4 derivatives including esters, ethers, and amines [34, 49, 64], Alcohols 195 and 196 was subjected to DCC, DMAP, and desired acid chloride or carboxylic acid in CH2CI2 affording ester analogs in 50-92% yield [64], Esters prepared include alkyl, aryl, and fluorenylmethyloxycarbonyl (Fmoc) protected amino acid derivatives (197 and 198) [64]. Ethers were prepared with various alkyl halides and Ag20 in CH3CN at 40 °C. Alkyl, allyl, and benzyl ethers were prepared in 45-80% yield (199 and 200) [34,64]. Alcohols 195 and 196 were then activated to the triflates and displaced by a variety of amines by treatment with trifluoromethanesulfonic anhydride and desired amine in 22% - quantitative yield over two steps (201 and 202)... 

Catalytic cyclopropanation of alkenes with diazomalonates is sometimes carried out with copper powder, but it appears that copper(I) halide/trialkyl phosphite complexes (for a procedure see Houben-Weyl Vol. E19b, p 1113), bis(acetylacetonato)copper(II), " ° and tet-raacetatodirhodium can be employed more advantageously (Table 13, entries 7-9). For the cyclopropanation of styrene with dicyclohexyl diazomalonate, however, copper(I) triflate was the catalyst of choice, while intramolecular C —H insertion at the cyclohexyl ring took place in the presence of tetraacetatodirhodium. A detailed comparison of copper catalysts for the cyclopropanation of cyclohexene, 1-methyl- and 1,2-dimethylcyclohexene, (Z)- and ( )-hept-2-ene with dimethyl diazomalonate, including competitive reaction pathways such as allylic C-H insertion and carbene dimer formation, is available. The catalyzed interaction between diazomalonic esters and enol ethers leads to cyclopropanes in some cases (e.g. ethoxymethylenecyclohexane to dimethyl 2-ethoxyspiro[2.5]octane-l,l-dicarboxylate ) and to different products in other cases (e.g. 1-methoxycyclohexene, 2-methoxy-3,4-dihydro-2/7-pyran ). This behavior is attributed to the occurence of stabilized dipolar intermediates in these reactions. 

The synthesis of lepimectin (Scheme 29.6.2) is described in the following, as it is published in the patent literature [42-44]. However, it may be assumed that this sequence will be modified in the actual industrial preparation. To introduce the required oxygen functionality at Cl3, milbemycin A3/A4 is first protected as 5-0-trimethylsilyl ether. Reaction with 3-chloroperbenzoic acid results in the ep-oxidation of the double bond between C14 and CIS. The epoxide is rearranged by treatment with a mild Lewis acid (trimethylsilyl triflate), and the product is deprotected. To suitably protect the sensitive allylic C5 hydroxy group, it is oxidized to the ketone. The Cl3 ester substituent is introduced by an acid-mediated... 

The synthetic technique is summarized in Scheme 3. Reaction of chaparrin (41b) with tert-butyldimethylsilyl chloride 11) afforded the crystalline disilyl derivative (93). The latter was obtained in better yield by silylation of (41b) with tert-butyldimethylsilyl enol ether of pentane-2,4-dione 105). The hydroxyl function at C-1 of (93) was effectively protected using trimethylsilyl triflate to afford the trisilyl lactone (94) which upon treatment with lithium diisopropylamide (LDA) and subsequent exposure to MoOs-pyridine-HMPA (M0O5PH) 104) gave the required 15-hydroxy lactone (95). Treatment of the latter with isovaleryl chloride afforded the crystalline ester (96) which was selectively desilylated to (97). Oxidation of the free allylic hydroxyl and complete desilylation of the resulting disilyl enone with tetrabutylammonium fluoride (BU4NF) afforded the natural cytotoxic quassinoid castelanone (34). 

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