Hydroxy-7-butyrolactones, synthesis

Reaction of ketyls. The carbonyl group reacts with Smlj to generate ketyl species which may be reduced further. Capture of the ketyls with suitable reactants expands the utility of the samarium chemistry. Important reactions include butyrolactone synthesis that is amenable to asymmetric induction when chiral acrylic esters are employed. The reagent system (catalytic in Smij) generated in situ from Smij and Zn-Hg is more economical. The system also contains Lil and MCjSiOTf, and in practice MejSiOTf is added to the mixture of the other components at just the rate to maintain a light blue color (indicating the presence of Smij). When Nilj is added as a catalyst, p-propiolactone instead of acrylic esters can be used. Sometimes steric factors preclude cyclization, and 7-hydroxy esters result. Ketyl addition to acrylamides opens a route to 1,4-amino alcohols. ... 

Sp th and Platzer (27) subsequently described a simpler synthesis of the alkaloid, by condensing o-aminobensylamine with ot-hydroxy-butyrolactone (XX) with butyrolactone itself, peg-9-en (desoigrvasicine) (VII) was obtained. 

The synthesis of 4-alkyl-y-butyrolactones 13 and 5-alkyl-<5-valerolactones 14 can be achieved in high enantiomeric excess by alkylation of ethyl 4-oxobutanoate and ethyl 5-oxopentanoate (11, n = 2, 3). The addition of diethylzinc, as well as dimethylzinc, leads to hydroxy esters 12 in high optical purity. When methyl esters instead of ethyl esters are used as substrates, the enantioselectivity of the addition reaction is somewhat lower. Alkaline hydrolysis of the hydroxy esters 12, followed by spontaneous cyclization upon acidification, leads to the corresponding y-butyro- and -valerolactones32. 

Lithiated chiral oxazolines have been shown to react with various electrophiles, generating a new asymmetric center with considerable bias. This process has led to the synthesis of optically active a-alkylalkanoic acids,47 n-hydroxy(methoxy)alkanoic acids,48 / -hydroxy(methoxy)alkanoic acids,49 n-substituted y-butyrolactones,50 and 2-substituted-l,4-butanediols (Fig. 2-4).50... 

An obvious way to target chiral compounds is to start with a compound in which the chiral center is already present. Here natural products and derivatives offer a rich pool of generally inexpensive starting materials. Examples include L-hydroxy and amino adds. Sometimes, just one out of many chiral centers is predestined to remain, as in the synthesis of vitamin C from D-glucose, or in the preparation of (S)-3-hydroxy-y-butyrolactone from ladose. 

Chiral butyrolactones of type 27 and 28 have substantial value in asymmetric synthesis because they contain readily differentiable difunctional group relationships e.g. 1,5-di-carboxylic acid, 1,4-hydroxy carboxylic acid, 1,6-hydroxy-carboxylic acid, 1,6-diol etc.) that would be difficult to assemble by existing asymmetric condensation and pericyclic processes. Applications of these chiral derivatives of glutaric acid to syntheses of indole, indoline and quinolinone alkaloids are illustrated in Schemes 16-18. 

Block copolymers of (R,S)-(3-butyrolactone and eCL have been synthesized by combining the anionic ROP of the first monomer with the coordinative ROP of the second one (Scheme 15) [71]. The first step consisted of the synthesis of hydroxy-terminated atactic P(3BL by anionic polymerization initiated by the alkali-metal salt of a hydroxycarboxylic acid complexed with a crown ether. The hydroxyl end group of P(3BL could then be reacted with AlEt3 to form a macroinitiator for the eCL ROP. 

The biotechnological synthesis of lactones has reached a high standard. Besides microbial production, lactones can also be enzymatically produced. For instance, a lipase-catalysed intramolecular transesterification of 4-hydroxy-carboxylic esters leads enantioselectively (ee>80%) to (S)-y-lactones the chain length may vary from C5 to Cl 1 [13]. y-Butyrolactone can be produced in that way with lipase from Mucor miehei [30]. 

The process of racemization has a number of practical application in the laboratory and in industry. Thus, in the synthesis of an optical isomer it is frequently possible to racemize the unwanted isomer and to separate additional quantities of the desired isomer. By repeating this process a number of times it is theoretically possible to approach a 100% yield of Synthetic product consisting of only one optical isomer, An example of the utilization of such a process is found in the production of pantothenic acid and its salts, In this process the mixture of D- and L-2-hydroxy-3,3-butyrolactones are separated. The D-lactone is condensed with the salt of beta-alanine to give the biologically active salt of pantothenic acid, The remaining L-lactone is racemized and recycled. 

Several recent reviews have included specific types of electrophilic cyclofunctionalization reactions.1 Important areas covered in these reviews are halolactonization u cyclofunctionalization of unsaturated hydroxy compounds to form tetrahydrofurans and tetrahydropyrans lb cyclofunctionalization of unsaturated amino compounds lc cyclofunctionalization of unsaturated sulfur and phosphorus compounds ld lf electrophilic heterocyclization of unconjugated dienes 1 synthesis of y-butyrolactones 1 h synthesis of functionalized dihydro- and tetrahydro-furans lj cyclofunctionalization using selenium reagents lk lm stereocontrol in synthesis of acyclic systems 1" stereoselectivity in cyclofunctionalizations lP and cyclofunctionalizations in the synthesis of a-methylenelactones.lq Previous reference works have also addressed this topic.2... 

Some terminal alkenes are oxidized to aldehydes depending on their structure. As described before, acrylonitrile and acrylate are oxidized to acetals of aldehydes in alcohols or ethylene glycol.Selective oxidation of terminal carbons in 4-hydroxy-1-alkenes (18) gave the five-membered hemiacetals (19), which can be converted to y-butyrolactones by PCC oxidation (Scheme 4). Formation of a tricyclic six-membered hemiacetal (62%) from a 5-hydroxy-1-alkene system was used for the synthesis of rosa-ramicin. Formation of aldehydes as a major product from terminal alkenes using (MeCN)2Pd(Cl)(N02) and CuCU in r-butyl alcohol under selected conditions was reported. The vinyl group in the -lactam was oxidized mainly to the aldehyde as shown below (equation 12). ... 

Hydroxy acids are important chiral starting materials in the synthesis of many biologically active compounds (135). (S)-3-Hydroxy-y-butyrolactone (91)is a very useful synthetic... 

Solladie, G., Wilb, N., Bauder, C. Highly stereoselective synthesis of enantiomerically pure -hydroxy- -sulfenyl- -butyrolactone by asymmetric Pummerertype cyclization. Tetrahedron Lett. 2000, 41,4189-4192. 

Corbet, J.-P., and Benezra, C., Allergenic a-methylene-y-lactones. General method for the preparation of P-acetoxy- and P-hydroxy-a-methylene-y-butyrolactones from sulfoxides. Apphcation to the synthesis of a tuliposide B derivative, J. Org. Chem., 46, 1141, 1981. 

As well as the above-described intermolecular alcoholysis of esters, the intramolecular version has been successfully utilized for the synthesis of lactones from racemic hydroxy carboxylic acid esters (25-41, 64—66) (Table 11.1-22). High selectivity in the pig pancreas lipase-catalyzed enantiomer-differentiating lactonization of y-hydroxy carboxylic acid esters with formation of butyrolactones substituted in... 

Trost has used a,a-disulfenylated lactones as enolate precursors. As shown in equation (23), a,a-di-(phenylthio)- v-butyrolactone is treated sequentially with ethylmagnesium bromide and acetaldehyde to obtain -hydroxy lactone (8) in virtually quantitative yield. Oxidation of the phenylthio group and subsequent elimination of the resulting sulfoxide provides the unsaturated hydroxy lactone (9). The process was employed with more complex lactones in a total synthesis of iridoids. The method fails with a,a-di-sulfenylated ketones unless a catalytic amount of copper(I) bromide is included in the reaction mixture. 

Scheme 47). In the synthesis of 9-acetoxyfukinanolide (140), the propargyl ester derived from the precursor 138 underwent successful cyclization to yield the lactone 139 [95] (Scheme 48). A retroaldol-aldol sequence on the hydroxy lactone derivative resulted in the epimerization at the quaternary diastereogenic center leading to the natural configuration. The allylic propiolate 141 reacted with tribu-tylstannane to produce the Z-a-stannylmethylene-y-butyrolactone 142, which served as an intermediate in the stereoselective synthesis of gadain (143) [96] (Scheme 49). 

Enzymatic desymmetrization of substituted 1,3-propanediols has been used as key step in the synthesis of y-butyrolactones by Itoh and coworkers, Scheme (8) [54],The diols 43 were treated with lipase PS (Pseudomenas sp.) in the presence of vinyl acetate as acyl donor to afford acetates 44 in excellent chemical yields and very high enantiomeric excesses (90-98%). These monoacetates were then converted into hydroxy nitriles 46 using a three step procedure. Tosylation of the hydroxyl group of 44, followed by treatment with potassium cyanide in dimethyl sulfoxide at 80°C gave the corresponding acetates 45. The acetoxy groups of 45 were finally hydrolysed with lithium hydroxide in a... 

A method was developed for the synthesis of quinoline derivatives from isatoic anhydrides and lactones. The amino ketones formed at the first stage were then converted into the desired products by cyclocondensation after isolation or by direct heating of the reaction mass. Thus, the reaction of the anhydride 2 with the butyrolactones 94 in the presence of lithium diisopropylamide gave the amino ketones (95) (yield 99%), which when boiled in toluene gave 4-hydroxy-3-R-l-methyl-2-quinolones 96 (yield 98% with R = H or 70% with R = Me). It was established that the latter exist in two isomeric forms 96a,b [57],... 

Readily available /3-hydroxy-esters (e.g. 49) can be converted into butyrolactones (e.g. 50) simply by treatment with concentrated sulphuric acid. Cyclic ether-lactones (52) are available from hydroxy-acids (51) by iodolactonization followed by dehalogenation with silver acetate. A stereoselective total synthesis of the antifungal mould metabolite (53) has been reported. ... 

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