Big Chemical Encyclopedia

Chemical substances, components, reactions, process design ...

Articles Figures Tables About

And optical purity

Resolution of Racemic Amines and Amino Acids. Acylases (EC3.5.1.14) are the most commonly used enzymes for the resolution of amino acids. Porcine kidney acylase (PKA) and the fungaly3.spet i//us acylase (AA) are commercially available, inexpensive, and stable. They have broad substrate specificity and hydrolyze a wide spectmm of natural and unnatural A/-acyl amino acids, with exceptionally high enantioselectivity in almost all cases. Moreover, theU enantioselectivity is exceptionally good with most substrates. A general paper on this subject has been pubUshed (106) in which the resolution of over 50 A/-acyl amino acids and analogues is described. Also reported are the stabiUties of the enzymes and the effect of different acyl groups on the rate and selectivity of enzymatic hydrolysis. Some of the substrates that are easily resolved on 10—100 g scale are presented in Figure 4 (106). Lipases are also used for the resolution of A/-acylated amino acids but the rates and optical purities are usually low (107). [Pg.343]

Below is a table of asymmetric Diels-Alder reactions of a,/ -unsaturated aldehydes catalyzed by chiral Lewis acids 1-17 (Fig. 1.10, 1.11). The amount of catalyst, reaction conditions (temperature, time), chemical yield, endojexo selectivity, and optical purity are listed (Table 1.32). [Pg.48]

The same reaction utilizing chlorotriisopropoxytitanium gives a lower yield and optical purity of the (Z)-anti product ( + )-4 (yield 33% 64% ee). Utilization of tetraisopropoxytita-nium causes complete racemization16. The reaction of (Z)-l-methylbutenyltitanium with both enantiomers of 2-( er/-butyldimethylsilyloxy)propanal proceeds only very sluggishly with approximately 20% yield99. The results are best explained by the assumption of a (twist)boat transition state. [Pg.421]

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. [Pg.789]

In case of primary alcohol substrates, biooxidation can also proceed to the carboxylic acid, enabling a facile separation of the chiral products by simple extraction. Whole-cells of Gluconobacter oxydans were utilized to produce S-2-phenylpro-panoic acid and R-2-phenylpropionic alcohol in excellent yields and optical purities (Scheme 9.4) [46]. [Pg.234]

Selectivity (individual impurity) and optical purity of the batch and micro-reaction technology (MRT) processes for (S)-2-acetyl tetrahydro ran synthesis... [Pg.33]

However, pMBCl 42 has a thermal stability issue and is expensive (Aldrich price 25 g for 69.90 the largest bottle). On the other hand, pMBOH 43 is stable and economically viable (Aldrich price 500 g for 84.90 the largest bottle). It was found that mono-N-alkylation of 36 proceeded well by slow addition (over 3 h) of 43 to a solution of 36 in acetonitrile in the presence of a catalytic amount of acid (p-TsOH) at 70 °C, as shown in Scheme 1.16. Slow addition of alcohol 43 minimized the self-condensation of 43 to form symmetrical ether 44, which was an equally effective alkylating agent. The product 41 was then directly crystallized from the reaction mixture by addition of water and was isolated in 90% yield and in >99% purity. A toluene solution of 41 can be used for the next reaction without isolation but the yield and optical purity of the asymmetric addition product were more robust if isolated 41 was used. In general, the more complex the reaction, the purer the starting materials the better. [Pg.22]

The 1 1 inclusion complexes 68 composed of 2a and nitrones 67 were prepared by keeping a solution of 2a and an equimolar amount of 67 in benzene-hexane (1 1) at room temperature for 12 h 40). Melting points of the complexes 68 are shown in Table 8. Irradiation of 68 in the solid state gave optically active oxaziridines 69. Irradiation time, yields and optical purity of the products are summarized in Table 8 40). Enantioselectivity in the formation of 67d, 67f, and 67g is high, but that of 69b, 69 c, and 69 e is low. This suggests a distinct influence coming from the substituents. [Pg.238]

Complex8 Irradiation time (h) Yieldb (%) Product [[a]D value (°)c and optical purity (%ee)d] Ratio of 75 76... [Pg.239]

When re-alkyl ethynyl ketones were tested as the substrate of LBADH, the preferred stereochemistry and optical purity of the resulting propargylic alcohol were dependent upon the size of the alkyl group (Figure 7.26) [71]. [Pg.152]

For Z-a-benzoylaminocinnamic acid and methyl ester substrates, with various donor and acceptor substituents in the phenyl ring, there was no correlation between the Hammett o--values of para substituents and optical purity of the product (239). The DIOP systems hydrogenate Z isomers more rapidly than E isomers, and induce a greater optical bias. N-Acetyl substrates always gave higher optical purities than the JV-benzoyl substrates, and similarly acid substrates were better than the corresponding methyl esters (239). [Pg.343]

First, both the configuration and optical purity of the stereocenters of the starting nitronates are retained in pyrrolidines B. If RsO is an auxiliary, the degree of recovery of the corresponding alcohol R5OH and the optical purity of the isolable pyrrolidine are higher than 95%. [Pg.536]

The IPA system does not require a co-solvent, but one can be used if this proves advantageous. In the TEAF system a solvent is normally used, though neat TEAF or formic acid can be used if required. The solvent can have a large effect on the reaction rate and optical purity of the product this may in part be because the substrate seems to bind by weak electrostatic interactions with the catalyst, and is also partly due to the pH of the system. Solvents have a dramatic effect on the ionization of formic acid for example, in water the piCa is 3.7, but in DMF it is 11.5. This is because formation of the formate anion becomes less favorable with less polar solvents (see Table 35.2). The piCa of triethy-lamine is far less sensitive. As a consequence, formic acid and triethylamine may remain unreacted and not form a salt. The variation in formic acid piCa can also have a significant impact on the catalyst and substrate, particularly when this is an imine. [Pg.1235]

Table 35.7 The effect of temperature on rate and optical purity in enantiomeric transfer hydrogenation of 4-fluoroaceto-phenone. Table 35.7 The effect of temperature on rate and optical purity in enantiomeric transfer hydrogenation of 4-fluoroaceto-phenone.
Optical activity, optical isomer, and optical purity... [Pg.63]

Reduction of diketones such as pentane-2,4-dione using (RfBiNAP-RuCF under hydrogen (75 100 atm) gives the corresponding diol, in this case (R),(R)-2,4-pentanediol with an excellent diastereomer ratio (98 %) and optical purity (>99 %)[48]. [Pg.15]

One facet of the whole cell work that draws attention is the sometimes profitable operation of a cascade of reactions in the multi-enzyme portfolio of the microorganism. For instance (Scheme 11), the allylic alcohol (14) is reduced to the corresponding saturated compound in high yield and optical purity (though in a slow reaction) via the intermediacy of the corresponding enal and (S)-2-benzyloxymethylpropanal[531. [Pg.16]

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. [Pg.107]

Although many previous reviews (5-12) and literature compilations (13-16) have dealt with sulfur stereochemistry, we decided to write a new report on chiral sulfur compounds to provide a survey of the topic with emphasis on the most recent findings. This chapter consists of four major parts treating syntheses of chiral sulfur compounds, methods for determination of their absolute configuration and optical purity, the dynamic stereochemistry of organosulfur compounds, and the use of chiral sulfur compounds in asymmetric synthesis. [Pg.335]

III. DETERMINATION OF ABSOLUTE CONFIGURATION AND OPTICAL PURITY OF CHIRAL SULFUR COMPOUNDS... [Pg.386]

When benzylideneaniline is reacted with ylide 162b, optically active N-phenyl-2-phenylaziridine 261 of unknown absolute configuration and optical purity is produced (294). [Pg.438]

It is of some interest that optically active spiroketone 262 is formed when tra/i5-benzalacetophenone is treated with ylide 162g (295). The absolute configuration and optical purity of this ketone are unknown. [Pg.438]

Reaction of 299 with benzaldehyde was found to give an equimolar mixture of diastereomeric j3-hydroxysulfoxides (314). Addition of 299 to a-tetralone 300 was more satisfactory, since the corresponding diastereomeric/3-hydroxysulfoxides 301 were formed in a 1.8 1 ratio. Their subsequent desulfuration with Raney nickel yielded levorota-tory 1-hydroxy-1-methyl-1,2,3,4-tetrahydronaphthalene 302 of unknown absolute configuration and optical purity. Similarly, addition of 299 to cyclohexene oxide leads to the formation of diastereomeric /3-hydroxysulfoxides 303 in a 2 1 ratio which, after separation, may be desulfurized to give (R,R)- and (S,S)- trans-2-methylcyclo-hexanols 304, respectively. Analysis of NMR spectra of the... [Pg.449]

Table 9.1 shows some examples of the different substrates that can be reduced to various single diastereomers of the same compound, as the keto alcohols and hydroxy esters, by choosing the use of different enzymes. The chemoenzymatic syntheses of the aggregation pheromones (+)-Sitophilure and Sitophilate by the use of the above isolated, NADPH-dependent KREDs were successfully accomplished by our group" with high chemical and optical purities (98 % de, >99 % ee). [Pg.282]

What happens for a nonracemic mixture of enantiomers Is it possible to calculate the values of the chiral properties of the solution from knowledge of the properties of the enantiopure compound In principle, yes, on the condition that there is no autoassociation or aggregation in solution. Then, the observed properties will be simply the weighted combination of the properties of two enantiomers. A nice example of where this normal law may be broken was discovered by Horeau in 1967 it is the nonequivalence between enantiomeric excess (ee) and optical purity (op, with op = [a]exi/[ ]max) for 2,2-methylethyl-succinic acid. In chloroform op is inferior to ee, while in methanol op = ee. This was explained by the formation of diastereomeric aggregates in chloroform, while the solvation by methanol suppresses the autoassociation. [Pg.208]

See other pages where And optical purity is mentioned: [Pg.334]    [Pg.164]    [Pg.298]    [Pg.233]    [Pg.298]    [Pg.302]    [Pg.150]    [Pg.344]    [Pg.339]    [Pg.186]    [Pg.533]    [Pg.244]    [Pg.333]    [Pg.386]    [Pg.387]    [Pg.437]    [Pg.45]    [Pg.113]    [Pg.135]    [Pg.206]    [Pg.284]    [Pg.341]   
See also in sourсe #XX -- [ Pg.155 ]



SEARCH



Enantiomeric Excess and Optical Purity

Optical Filters and Signal Purity

Optical Purity and Epimerization

Optical purity

© 2024 chempedia.info