Acetals from -2,4-pentanediol

Fig. 9. SEM photographs of cellulose acetate membranes cast from a solution of acetone (volatile solvent) and 2-meth5l-2,4-pentanediol (nonvolatile solvent). The evaporation time before the stmcture is fixed by immersion ia water is shown (24).

The chiral catalyst was made from Raney nickel, which was prepared by addition in small portions of 3.9 g Raney nickel alloy to 40 ml water containing9 g NaOH. The mixture was kept at 100 C for 1 h, and then washed 15 times with 40 ml water. Chirality was introduced by treatment of the Raney nickel for I h at lOO C with 178 ml water adjusted to pH 3.2 with NaOH and containing 2g (S,S)-tartaric acid and 20 g NaBr. The solution was then decanted, and the modifying procedure was twice repeated. Hydrogenation over this catalyst of acetylacctone (100 atm, 100" C) in THF containing a small amount of acetic acid gave an isolated yield of chiral pentanediol of 44% (99.6% optical purity). 

A ketene acetal-terminated prepolymer was first prepared from 2 eq of the diketene acetal 3,9-bis(ethylidene-2,4,8,10-tetraoxaspiro-[5,5]undecane) and 1 eq of the diol 3-raethyl-l,5-pentanediol and. then 30 wt% levonorgestrel, 7 wt% Mg(OH)2j and a 30 mole% excess of 1,2,6-hexanetriol mixed into the prepolymer. This mixture was then extruded into rods and cured. Erosion and drug release from these devices was studied by implanting the rod-shaped devices subcutaneously into rabbits, explanting at various time intervals, and measuring weight loss and residual drug (15). 

A third route to nonracemic a-alkoxy and a-hydroxy stannaries employs the chiral acetal 73 prepared from (f ,f )-2,4-pentanediol (Scheme 30)66. Addition of various Grignard reagents to this acetal in the presence of TiCLt results in selective displacement yielding (S )-a-alkoxy stannanes. The corresponding a-hydroxy derivatives can be obtained after oxidation and mild base treatment. Organocuprates can also be employed to cleave this acetal but with somewhat lower selectivity67. 

Chiral acetals/ketals derived from either (R,R)- or (5,5 )-pentanediol have been shown to offer considerable advantages in the synthesis of secondary alcohols with high enantiomeric purity. The reaction of these acetals with a wide variety of carbon nucleophiles in the presence of a Lewis acid results in a highly diastereoselective cleavage of the acetal C-0 bond to give a /1-hydroxy ether, and the desired alcohols can then be obtained by subsequent degradation through simple oxidation elimination. Scheme 2-39 is an example in which H is used as a nucleophile.97... 

H) [a]D -64.1° (CHCI3), c 1.0). The optical purity of this adduct was 95% as determined by 200 MHz 1H NMR spectroscopy and GC analysis (capillary column PEG, 0.25 mm x 25 m, purchased from Gaskuro Kogyo Company, Ltd. in Japan) after conversion to the corresponding chiral acetal as follows A solution of the adduct, (2R,4R)-(-)-pentanediol (1.2 equiv, obtained from Wako Pure Chemical Industries), triethyl orthoformate (1.2 equiv), and p-toluenesulfonic acid monohydrate (as a 5 mM solution) in dry benzene is stirred at ambient temperature for 3 hr. The mixture is poured into saturated sodium bicarbonate and the product is extracted with ether. The... 

A Du Pont patent (2) describes a colorless, viscous polyacetal from the divinyl ether of 1, 5-pentanediol and subsequent acetalization. This product can be used for cross-linking polyvinyl alcohol films. 

Asymmetric induction in the cyclopropanations of unsaturated substrates with methylene has been extensively investigated. A propensity of the Simmons-Simth and related reagents to make coordination to basic atoms is most frequently exploited. Treatment of a,/J-unsaturated aldehyde acetals derived from the aldehydes and chiral dialkyl tartrates or 2,4-pentanediol, with diiodomethane/diethylzinc in hexane, produces cyclopro-panecarboxaldehyde acetals with high diastereoselectivity (equation 69)109 110. Uniformly good diastereoselectivity has also been realized in the cyclopropanations of chiral acetals... 

Chiral hydroxy carboxylic acids The chiral acetals 2, available from (2R, 4R)-pentanediol (12,375-378), couple with ketene f-butyl f-butyldimethylsiiyl acetal (3) in the presence of TiCl4 (0.5 equiv.) to give adducts that are hydrolyzed by TFA-H20 to 4 and 5. The mixture is converted on oxidation and p-elimination into essentially pure (3R)-p-hydroxy carboxylic acids (6). 

R,S)-Citronellal can be purchased from BASF, and (R)-citronellal from Dragoco, Fluka, or Takasgo Perfumery Co., Ltd., Japan. (R)-Citronellal can also be synthesized from pulegone with ee >99%.5 (S)-Citronellal may be obtained by oxidation of (S)-citronellol,6 which is accessible by different routes with ee 95%.7 The optical purity of citronellal can be determined by GLC after conversion to the acetal of (-)-(2R,4R)-pentanediol.8 For the reactions described, (R,S)-citronellal from BASF, (R)-citronellal from Dragoco, and (S)-citronellol from Fluka were used. (R,S)-Citronellal... 

The residue from the first distillation is a mixture of acetic acid, 4-penten-l-ol acetate, and 1,5-pentanediol diacetate. Another 15-35 g. (6-15%) of 1,4-pentadiene can be obtained by passing the residue through the pyrolysis tube under the conditions described above. 

Reaction with chiral acetals. The chiral ketals derived from (2R,4R)-(-)-2,4-pentanediol (1) can be cleaved with high diastercoselectivity by aluminum hydride reagents, in particular DIBAH, CI2AIH, and Br,AlH. Oxidative removal of the chiral auxiliary affords optically active alcohols. This process provides a useful method for highly asymmetric reduction of dialkyl ketones. ... 

Cleavage of acetals. The acetals derived from (2R,4R)-2,4-pentanediol (this volume) are cleaved by organotitanium reagents of the type RTiCI, or R,TiCf. with high chemo- and stereoselectivity. Removal of the chiral auxiliary gives chiral secondary alcohols in high purity. Acetals complexed with TiCb arc also cleaved by treatment with an alkyllithium. 

Aldol coupling of chiral acetals. The acetals (2) prepared from an aldehyde and (2R,4R)-pentanediol react with a-silyl ketones orenol silyl ethers in the presence of TiCI, to form aldol ethers 3 and 4 with high diastereoselectivity (>95 5). Removal of the chiral auxiliary usually results in decomposition of the aldol, but can be effected after reduction... 

Reduction of Acetals. Reductions of acetals of 2,4-pentanediol can provide (after removal of the chiral auxiliary by oxidation and 3 elimination) secondary alcohols with good enan-tioselectivity. The choice of reagents dictates the configuration of the final product. Use of Dibromoalane gives products from selective syn cleavage of the acetal while Triethylsilane/Titanium(IV) Chloride gives the more usual anti cleavage products (eq 2). ... 

The cyclization in Step B is an improvement of Butler s procedure for the synthesis of which employs less convenient reagents, KNH and l-bromo-3-chloroacetone acetal. Beside the acetals derived from neopentyl glycol, those derived from ethanol, 1,3-propanediol and 2,4-pentanediol have been synthesized by the present method. The second part of Step B involves the formation and the electrophilic trapping of cyclopropenyl anion 2, which is the key element of the present preparations. Step B provides a simple route to substituted cyclopropenones, but the reaction is limited to alkylation with alkyl halides. The use of lithiated and zincated cyclopropenone acetal, on the other hand, is more general and permits the reaction with a variety of electrophiles alkyl, aryl and vinyl halides, Me3SiCl, Bu3SnCl, aldehydes, ketones, and epoxides. Repetition of the lithiation/alkylation sequence provides disubstituted cyclopropenone acetals. 

Kinetic resolution of chiral acetals has been effected by use of some organoaluminum reagents [84], On treating a chiral acetal 88, derived from (2, 4/ )-(-)-pentanediol, with -Bu3A1 at room temperature, one diastereomer was found to react much faster than the other, and the residu enol ether is transformed into optically pure ketone. The efficiency of this method is demonstrated by a concise synthesis of (5)-(-)-5-hexadecan-l,5-lactone (89), the pheromone of Vespa orientalis, as shown in Sch. 56. 

Acetals prepared from chiral diols and carbonyl compounds serve as a chiral synthetic equivalent of aldehydes or ketones. 1,3-Dioxanes synthesized from chiral 2,4-pentanediols are especially useful, and high asymmetric inductions are observed in the Lewis acid promoted reactions of a variety of organometallic compounds. After the removal of the chiral auxiliary by the oxidation and -elimination procedures, optically active alcohols are obtained. Optically active propargylic alcohols and cyanohydrins are synthesized from organosilane compounds, TMS-C CR or TMS-CN in the presence of TiCU (Scheme 24). 1 6-138 Reactive wganometals such as alkyl-lithiums, -magnesiums or -coppers also react with chiral... 

Chiral acetals derived from (R,R)-2,5-pentanediol 1.38 (R = Me. Y = R ) react with Me3SiCN in the presence of TiC. After appropriate treatment, (/O-cya-nohydrins are obtained in a good enantiomeric excess [213] (Figure 6.27). Following quatemization with Mel, cyclic N, O-acetals 6.32 derived from (1R, 25)-ephedrine 1.61 (R = Me) suffer stereoselective ring opening by NaCN in DMSO at 130°C [1158], (R)-a-Hydroxyacids are obtained with an excellent enantiomeric excess after quatemization and treatment with HC1 (Figure 6.27). 

Aside from the type III cyclizations described above, acetals have seen limited use in intermolecular Prins reactionsand extensive use as initiators for cation-alkene cyclizations.Only limited success has been achieved in Lewis acid catalyzed addition of acetals to alkenes. Better success has been achieved in the synthesis of C-glycosides by Lewis acid catalyzed addition of glycosyl acetates or glycals to alkenes. Johnson has extensively developed the use of acetals as initiators for cation-alkene cyclizations. Recent studies have shown that excellent asymmetric induction can be obtained using chiral acetals derived from optically active 2,3-butanediol or 2,4-pentanediol. - ... 

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