Methylenation lactones

The preparation of protected (/ )-2-methyl-cysteine by Fukuyama starts with the enantio-selective discrimination of the prochiral ester groups in 6 with pig liver esterase (Scheme 3) [5]. The ester function of the resulting product 7 is selectively reduced (7 16). Cyclization to the )9-lactone gives compound 17. Attack of the thioacetate at the )9-lactone methylene carbon atom provides the (/f)-compound 18. Selective reduction of the carboxylic acid function in 7 gives the (S)-compound 19 in an analogous fashion. 

A 1-H triplet at 8 4.09 was due to the / -methylene proton of the lactone junction. Two multiplets centered at 8 2.80 and 8 4.58 were attributed to the methine protons at the C-2 and C-3 positions, the methine proton at the C-4 position and the a -proton of the lactone methylene group respectively. 

Lactones. Methylenation (Cp2TiMe2 in refluxing toluene) of cyclic carbonates that bear a vinyl group at a carbinolated carbon is followed by a Claisen rearrangement to... 

Lactone methylenation. Dimethylaminomethylation of lactone enolates can be carried out with (1, A = I"). A hydroxyl group need not be protected thus (2) is converted into (3) without the usual necessity of protection of the OH group (equation I). In the same way, bisnorvemolepin was converted into rf/-vemolepin in 317 overall yield. The yield is decreased to 18% if the hydroxyl group is... 

A detailed study of the use of the titanium complex (34) for a wide range of ester and lactone methylenations has shown that it is a general and high-yielding... 

The Tebbe reaction, which converts the oxo groups of esters and lactones to methylene groups to give enol ethers, is described in section 2.1.2. 

The reaction can be applied to allyl malonates. Alkylation of diallyl mal-onate (734) with bromoacetate and acetoxymethylation afford the mixed triester 735. Treatment of the tricster 735 with Pd catalyst affords allyl ethyl itaconate (736). In a similar way, a-methylene lactone and the lactam 737 can be prepared[462]. 

DimeriZa.tlon. A special case of the [2 + 2] cyclo additions is the dimerization of ketenes. Of the six possible isomeric stmctures, only the 1,3-cyclobutanediones and the 2-oxetanones (P-lactones) are usually formed. Ketene itself gives predominandy (80—90%) the lactone dimer, 4-methylene-2-oxetanone (3), called diketene [674-82-8], approximately 5% is converted to the symmetrical dimer, 1,3-cyclobutanedione [15506-53-3] (4) which undergoes enol-acetylation to so-called triketene [38425-52-4] (5) (44). 

Composition. Shellac is primarily a mixture of aUphatic polyhydroxy acids in the form of lactones and esters. It has an acid number of ca 70, a saponification number of ca 230, a hydroxyl number of ca 260, and an iodine number of ca 15. Its average molecular weight is ca 1000. Shellac is a complex mixture, but some of its constituents have been identified. Aleuritic acid, an optically inactive 9,10,16-trihydroxypalmitic acid, has been isolated by saponification. Related carboxyflc acids such as 16-hydroxy- and 9,10-dihydroxypalmitic acids, also have been identified after saponification. These acids may not be primary products of hydrolysis, but may have been produced by the treatment. Studies show that shellac contains carboxyflc acids with long methylene chains, unsaturated esters, probably an aliphatic aldehyde, a saturated aliphatic ester, a primary alcohol, and isolated or unconjugated double bonds. 

In addition to its water solubility poly(vinyl pyrrolidone) is soluble in a very wide range of materials, including aliphatic halogenated hydrocarbons (methylene dichloride, chloroform), many monohydric and polyhdric alcohols (methanol, ethanol, ethylene glycol), some ketones (acetyl acetone) and lactones (a-butyrolactone), lower aliphatic acids (glacial acetic acid) and the nitro-paraffins. The polymer is also compatible with a wide range of other synthetic polymers, with gums and with plasticisers. 

Bicuculline, C2oHi,06N. (Items 1, 9, 10, 13, 14, 18, 20, 23-26, 34, 35, 38 list, p. 169). This alkaloid exists in two forms, m.p. 177° and m.p. 196°, and has [a], ° + 130- 5° (CHCI3). The hydrochloride has m.p. 259° (dec.) and from the methiodide, W-methylbicuculline, plates, m.p. 246°, has been prepared. Bicuculline contains no methoxyl groups it behaves as a lactone and is convertible by alkalis into bicucine, which is possibly the corresponding hydroxy-aeid (see below). It simulates hydrastine in its reactions and differs from that base by CH, indicating that a methylene-dioxy group replaces two methoxyl groups, and this view is supported by comparison of the products of oxidative hydrolysis of the two alkaloids. Both yield hydrastinine (p. 163) as the basic product, but while hydrastine provides as the second product, opianic acid,... 

Bicucine, C20H19O7N, H2O. This alkaloid has m.. 222° (dec.) and — 115 4° (N/10, KHO) but in N/HCl it shows mutarotation — 145° to — 100°,due to the formation of an equilibrium mixture of bicucine and bicuculline. Alkaline permanganate oxidises it to 3 4-methylene-dioxyphthalic acid, isolated as the ethylimide. In view of its formation from bicuculline by the action of alkali, Manske has suggested for its formula (II) or (III), the former representing it as the nomarceine (p. 208) analogue of bicuculline, whilst (III) makes it the hydroxy-acid corresponding to the lactone, bicuculline and is preferred. 

An important side reaction observed during methylenation of 17a-acetoxy 20-ketones (4) is the formation of the unsaturated lactones (6) in high yield. These compounds arise by aldol condensation and dehydration. 

Bromo-5-methylene-2(5//)-furanone 133 was obtained from the /3-angelica lactone 129 by using mild simple methods that combine bromination and dehy-drobromination or debromination processes accomplished in a convenient order, as illustrated in Scheme 41 (94T12457). 

When a solution of 25 in a 1 1 mixture of methanol and methylene chloride is exposed to periodic acid, the dithiane group is cleaved oxidatively to give, after treatment of the crude product with camphorsulfonic acid (CSA) in methanol, bisacetal 12 as a 2 1 mixture of C-12 anomers in a yield of 80% (Scheme 3). Although the conversion of 12 into 10 could be carried out on the mixture of anomers, it was found to be more convenient to carry each isomer forward separately. When 12 is treated with lithium diethylamide, the methine hydrogen adjacent to the lactone carbonyl is removed as a proton to give an enolate which is then oxidized in a completely diastereoselective fashion with Davis s oxaziridine18 to afford 11. 

The oxidation of diethyl 3,6-hexanooxepin-4,5-dicarboxylate with a mixture of sodium periodate and potassium permanganate as oxidizing agent gives diethyl 3-[(formyioxy)methylene]-l 0-oxocyclodec-l-en-l,2-dicarboxylate (2) in 91 % yield.130 A minor modification of the reaction conditions gives two products 2 (35 %) and a product which retains the oxepin structure (23 %) identified as the same lactone described in Section 1.2.1.1.129... 

Thus, the lithiated SAMP hydrazones of various methyl ketones on addition to 2-(aryl-methylene)- , 3-propanedionates and propanedinitriles provide, after the removal of the auxiliary, (R)-2-( l-aryl-3-oxobutyl)-1,3-propanedioates and -propanedinitriles with high enantiomeric excess (> 95%) in 50 82% yield (sec Table 6) 195,197. Using similar methods optically active (5-lactones (90% to > 96% ee) are obtained198. 

---