Acetic optical purity

For the construction of oxygen-functionalized Diels-Alder products, Narasaka and coworkers employed the 3-borylpropenoic acid derivative in place of 3-(3-acet-oxypropenoyl)oxazolidinone, which is a poor dienophile in the chiral titanium-catalyzed reaction (Scheme 1.55, Table 1.24). 3-(3-Borylpropenoyl)oxazolidinones react smoothly with acyclic dienes to give the cycloadducts in high optical purity [43]. The boryl group was converted to an hydroxyl group stereospecifically by oxidation, and the alcohol obtained was used as the key intermediate in a total synthesis of (-i-)-paniculide A [44] (Scheme 1.56). 

Scheeren et al. reported the first enantioselective metal-catalyzed 1,3-dipolar cycloaddition reaction of nitrones with alkenes in 1994 [26]. Their approach involved C,N-diphenylnitrone la and ketene acetals 2, in the presence of the amino acid-derived oxazaborolidinones 3 as the catalyst (Scheme 6.8). This type of boron catalyst has been used successfully for asymmetric Diels-Alder reactions [27, 28]. In this reaction the nitrone is activated, according to the inverse electron-demand, for a 1,3-dipolar cycloaddition with the electron-rich alkene. The reaction is thus controlled by the LUMO inone-HOMOaikene interaction. They found that coordination of the nitrone to the boron Lewis acid strongly accelerated the 1,3-dipolar cycloaddition reaction with ketene acetals. The reactions of la with 2a,b, catalyzed by 20 mol% of oxazaborolidinones such as 3a,b were carried out at -78 °C. In some reactions fair enantioselectivities were induced by the catalysts, thus, 4a was obtained with an optical purity of 74% ee, however, in a low yield. The reaction involving 2b gave the C-3, C-4-cis isomer 4b as the only diastereomer of the product with 62% ee. 

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). 

The proline derived diamines 2 and 4 (vide supra) are also suitable chiral additives in enantiose-lective additions of a-unsubstituted enolates. Best results are obtained with the naphthyl derivative, as demonstrated in the tin(II) triflate mediated addition of the O-silylketene thio-acetal l-toT-butylthio-l-trimethylsilyloxyethane to aldehydes which delivers 3-hydroxythio esters in optical purities of up to 95% ee and chemical yields between 50 and 90 %24... 

Recently, this procedure was slightly modified by using sodium cyanide and an equivalent amount of the hydrochloride of the chiral amine, instead of adding acetic acid46, which resulted in a slightly improved yield and optical purity of the product. 

Of course, the influence of organic solvents on enzyme enantioselectivity is not limited to proteases but it is a general phenomenon. Quite soon, different research groups described the results obtained with lipases [28]. For instance, the resolution of the mucolytic drug ( )-trans-sobrerol (11) was achieved by transesteriflcation with vinyl acetate catalyzed by the lipase from Pseudomonas cepacia adsorbed on celite in various solvents. As depicted in Scheme 1.3 and Table 1.5, it was found that t-amyl alcohol was the solvent of choice in this medium, the selectivity was so high ( >500) that the reaction stopped spontaneously at 50% conversion giving both +)4rans-sobrerol and (—)-trans-sobrerol monoacetate in 100% optical purity [29]. 

DKR reactions were performed with lipase and Pd(PPh3)4 in the presence of dppf and 2-propanol in THF. 2-Propanol was used as an acyl acceptor. Various acyclic allyhc acetates were transformed to their corresponding allylic alcohols at room temperature in good yields and excellent optical purities (Table 16). 

The 3,4-dihydrodiol is a major component of the free dihydrodiols formed in mouse skin maintained in short-term culture (28). The optical purities of these dihydrodiols were determined by a CSP-HPLC method (43). The metabolic fates of the enantiomeric DMBA 3,4-dihydrodiols are not yet known. Studies in our laboratory indicate that the products formed in liver microsomal metabolism of DMBA 3,4-dihydrodiol bind extensively to the components of liver microsomes and the expected 1,2,3,4-tetrols of DMBA were not detected in the acetone/ethyl acetate extract of the incubation mixture (unpublished results). It is known that these products bind extensively to DNA... 

The lipase-catalysed resolution of racemic 105 in the presence of vinyl acetate afforded isoxazolidines 105 and their corresponding acetates in 52-82% ee. A higher optical purity... 

The synthesis of nitronates (297) in the presence of electron-deficient olefins (398) produces optically pure nitroso acetals (300) with high optical purity. Interestingly, the use of ethanol as the solvent in the (296— 298) reaction leads to a substantial increase in de compared to CH2CI2 (157). 

Azidation.1 Arylsulfonyl azides generally react with enolates to effect net diazo transfer, but this hindered and electron-rich azide can effect azide transfer at the expense of diazo transfer. The nature of the enolate counterion also plays a role, with K being more effective than Na. In addition, acetic acid (or KOAc) is required as the quench for decomposition of the triazine intermediate to the azide with elimination of the arylsulfinic acid, ArS(0)0H. By use of these conditions, chiral N-acyloxazolidones such as 2 undergo diastereoselective azidation to give the azides 3 in 75-90% yield and in high optical purity (>91 9). These... 

In contrast, the results obtained in the methanolysis, acetolysis, and trifluoroacetolysis of the tosylate 91 were not the expected ones. Cram obtained the methyl ether 93, the acetate 94 and the trifluoro-acetate 95 with the same configuration and optical purity as in the direct synthesis from the alcohol 92. These solvolyses at the bridge carbon atom of [2.2]paracyclophane therefore proceed with complete retention of configuration. The rate of acetolysis of the tosylate 91 also deviates considerably from that of aliphatic secondary tosylates it is some 100 times faster than that of 2-butyl tosylate and about the same as that of a-phenylneopentyl tosylate, acetolysis of which is only slightly stereospecific. 

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... 

In her initial investigation, Lundquist studied the monolayer behavior of racemic and optically active forms of both tetracosan-2-ol and its acetate derivative on 0.0 lA aqueous HCl over a considerable range of temperature (77). In each case, it was possible to demonstrate chiral discrimination between pure enantiomers versus the racemic substance. Furthermore, the extent of enantiomer discrimination was significantly temperature dependent, being enhanced at lower temperatures and frequently disappearing at higher ones. Under favorable conditions of temperature, however, the appearance of the force-area curves could be very sensitive to the optical purity... 

Recently, new examples of asymmetric induction in the Pummerer reaction of chiral sulfoxides have been described. Oae and Numata (301) reported that the optically active a-cyanomethyl p-tolyl sulfoxide 275 undergoes a typical Pummerer rearrangement upon heating with excess of acetic anhydride at 120°C, to give the optically active a-acetoxy sulfide 276. The optical purity at the chiral a-carbon center in 276, determined by means of H- NMR spectroscopy using a chiral shift reagent, was 29.8%. 

The complete transformation of a racemic mixture into a single enantiomer is one of the challenging goals in asymmetric synthesis. We have developed metal-enzyme combinations for the dynamic kinetic resolution (DKR) of racemic primary amines. This procedure employs a heterogeneous palladium catalyst, Pd/A10(0H), as the racemization catalyst, Candida antarctica lipase B immobilized on acrylic resin (CAL-B) as the resolution catalyst and ethyl acetate or methoxymethylacetate as the acyl donor. Benzylic and aliphatic primary amines and one amino acid amide have been efficiently resolved with good yields (85—99 %) and high optical purities (97—99 %). The racemization catalyst was recyclable and could be reused for the DKR without activity loss at least 10 times. 

Both the exo- and endo-reactants gave rise to a closely similar distribution of products. The major difference between the reactions being the retention of much more optical activity in the products of the endo-isomer. Both reactants yielded more than 95% exoderivatives and it is important to note that the exo-acetate obtained from the exo-amine retained 11% optical purity. 

The firmest conclusion that can be drawn with regard to the structural problem is that both the exo- and endo-amines yield a substantial amount of classical norbomyl ions during deamination. If stabilization by non-classical bridging is in competition with classical ion formation, one might deduce from the optical purity of the exo-acetate produced from the exo-amine that it amounts to less than T4 kcal mole . On the other hand all the data could be reconciled without invoking the non-classical species provided that a small barrier is proposed for the Wagner-Meerwein shift. 

To overcome this issue Kureshy et al. [55, 56] reported dimeric form of Jacobsen s catalysts 3, 4. They used the concept of solubility modification by altering the molecular weight of the catalyst so that in a post catalytic work-up procedure the catalyst is precipitated, filtered and used for subsequent catalytic runs. The complexes 3, 4 (0.2 mol % of Co(lll)-salen unit) (Figure 2) were effectively used for HKR of racemic epoxides, e.g., styrene oxide, epichlorohydrin, 1,2-epoxypropane, 1,2-epoxyhexane, 1,2-epoxyoctane, and 1,2-epoxydodecane to achieve corresponding epoxides and 1,2-diols in high optical purity and isolated yields. In this process, once the catalytic reaction is complete the product epoxides were collected by reduced pressure distillation. Addition of diethylether to the residue precipitated the catalyst which was removed by filtration. However, the recovered catalyst was required to be reactivated by its treatment with acetic acid in air. The catalysts were reused 4 times with complete retention of its performance. 

Benzylic halides are reduced very easily using complex hydrides. In a-chloroethylbenzene lithium aluminium deuteride replaced the benzylic chlorine by deuterium with inversion of configuration (optical purity 79%) [537]. Borane replaced chlorine and bromine in chloro- and bromodiphenylme-thane, chlorine in chlorotriphenylmethane and bromine in benzyl bromide by hydrogen in 90-96% yields. Benzyl chloride, however, was not reduced [5iSj. Benzylic chlorine and bromine in a jy/n-triazine derivative were hydrogeno-lyzed by sodium iodide in acetic acid in 55% and 89% yields, respectively [5i9]. 

Optically active cyanohydrins are obtained in good selectivity by the nucleophilic attack of cyanating reagents to chiral acetals.(21) However, the chiral auxiliaries are destroyed, and not recovered. In catalytic processes with chiral boryl compounds,(22) D-oxynitrilase,(23) and synthetic peptides,(24) the optical purities of the resulting cyanohydrins are generally not sufficient. 

We discovered that cymene-ruthenium catalysts 3a-c were effective catalyst systems for facile DKR of secondary alcohols at 40 °C. This catalyst system was particularly useful for the DKR of allylic alcohols [18], which underwent smoothly at room temperature to provide the corresponding chiral acetates with excellent optical purities (Scheme 1.16). This work has for the first time demonstrated that DKR can be performed at room temperature. 

Iodide with optical purity of 89% gave acetal with aD + 7.6° (neat, l — 100 mm.). 

The diol was further purified by recrystallization from ethyl acetate and petroleum ether in 62% recovery. The (+)-(1R,2R)-1-phenylcyclohexane-cis-1,2-diol thus obtained had a mp of 122-123°C (lit. mp 121-122°C) and was found to have an optical purity of >99.5% ee by chiral SFC. The following physical data was observed ... 

Simultaneous deprotection and cyclization of diols 60a and 60b with 3 M HCl in MeOH followed by acetylation yielded the 2,3-trans- ( 50%) (61a and 61b) and for the first time 2,3-cw-flavan-3-ol methylether acetate derivatives ( 20%) (62a and 62b) in excellent enantiomeric excesses (>99%). The optical purity was assessed by H NMR using [Eu(hfc)3] as chiral shift reagent. The absolute configuration of the derivatives of the tram- and cii-flavan-3-ol derivatives was assigned by comparison of CD data with those of authentic samples in the catechin or epicatechin series flavan-3-ols. Thus, the absolute configuration of the flavan-3-ol methyl ether acetates confirms the assigned configuration of the diols as derived from the Sharpless model. 

In order to determine yield and optical purity, the unstable 3-phenylalkanals were reduced and then acylated to the acetates. 

Chiral P-formyl-p-hydroxycarboxylic esters were also obtained by the employment of either lithium or zinc enolate of ethyl acetate in place of Grignard reagents in the above-mentioned reaction in moderate to excellent optical purity (62 to 92 % e.e.)122). 

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