Optical yields reaction conditions

Fig. 12. Effect of hydrogenalion temperalure on optical yield. Reaction conditions MAA (neat), atmospheric pressure. RNi and modifying conditions as slated as Table IX.

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). 

A very efficient and universal method has been developed for the production of optically pue L- and D-amino adds. The prindple is based on the enantioselective hydrolysis of D,L-amino add amides. The stable D,L-amino add amides are effidently prepared under mild reaction conditions starting from simple raw materials (Figure A8.2). Thus reaction of an aldehyde with hydrogen cyanide in ammonia (Strecker reaction) gives rise to the formation of the amino nitrile. The aminonitrile is converted in a high yield to the D,L-amino add amide under alkaline conditions in the presence of a catalytic amount of acetone. The resolution step is accomplished with permeabilised whole cells of Pseudomonas putida ATCC 12633. A nearly 100% stereoselectivity in hydrolysing only the L-amino add amide is combined with a very broad substrate spedfidty. 

The bis-DIOP complex HRh[(+)-DIOP]2 has been used under mild conditions for catalytic asymmetric hydrogenation of several prochiral olefinic carboxylic acids (273-275). Optical yields for reduction of N-acetamidoacrylic acid (56% ee) and atropic acid (37% ee) are much lower than those obtained using the mono-DIOP catalysts (10, II, 225). The rates in the bis-DIOP systems, however, are much slower, and the hydrogenations are complicated by slow formation of the cationic complex Rh(DIOP)2+ (271, 273, 274) through reaction of the starting hydride with protons from the substrate under H2 the cationic dihydride is maintained [cf. Eq. (25)] ... 

Table 34.8 Typical ranges of reaction conditions, optical yields, turnover frequencies (TOF) and substratexatalyst ratios (SCR) for the hydrogenation of C = N functions using various chiral catalytic systems.

The advantages of the carbon tetrahalide-organophosphine-alcohol reaction to prepare halides are simplicity of experimental procedure good yields relatively mild, essentially neutral reaction conditions absence of allylic rearrangements. The reaction proceeds with inversion of configuration and is a useful simple device for converting optically active alcohols to chiral halides in high optical purity.12-22... 

Although similar efforts have been devoted to related polymer systems (Overberger and Cho, 1968 Overberger and Dixon, 1977 Okamoto, 1978), large enantioselectivity has not been observed. Goldberg et al. (1978) conducted borohydride reduction of phenyl ketones in micelles of the chiral surfactant [44]. The result was disappointing, since the maximal enantioselectivity was only 1.66% for phenyl propyl ketone. A much better optical yield was reported when this reaction was carried out under phase-transfer conditions (Masse and Parayre, 1976). The cholic acid micelle and bovine serum albumin exhibited the relatively high enantioselectivity in the reduction of trifluoroacetophenone (Baba ef al., 1978). 

The optical yield was found to be very sensitive to structural modifications of the achiral agent. For example, use of the more bulky FV or Bu substituents in the 3,5-positions of phenol resulted in lower optical yields. In some cases a reversal of the sense of asymmetric induction was observed. Systematic variation of reaction conditions using the best achiral component, 3,5-xylenol, established that optimum results were obtained in ether solvent at about - 15°C. There was also a minor but definite influence of the rate of addition of ketone as well as an effect of concentration on optical yield, with a slower rate being advantageous. The results of reduction of aryl alkyl ketones are shown in Table 9, along with comparative results of reduction with similar chiral auxiliary reagents. 

The chiral dialuminum Lewis acid 14, which is effective as an asymmetric Diels-Alder catalyst, has been prepared from DIBAH and BINOL derivatives (Scheme 12.12). " The catalytic activity of 14 is significantly greater than that of monoaluminum reagents. The catalyst achieves high reactivity and selectivity by an intramolecular interaction of two aluminum Lewis acids. Similarly, the chiral trialuminum Lewis acid 15 is quantitatively formed from optically pure 3-(2,4,6-triisopropylphenyl)binaphthol (2 equiv) and MeaAl (3 equiv) in CH2CI2 at room temperature (Scheme 12.12). " The novel structure of 15 has been ascertained by NMR spectroscopic analysis and measurement of the methane gas evolved. Trinuclear aluminum catalyst 15 is effective for the Diels-Alder reaction of methacrolein with cyclopentadiene. Diels-Alder adducts have been obtained in 99% yield with 92% exo selectivity. Under optimum reaction conditions, the... 

Furthermore, Rueping and coworkers applied their reaction conditions to the cyanation of ketimines [54]. The use of A-benzylated imines derived from aryl-methyl ketones generally gave comparable yields, but lower enantioselectivities. However, this method furnished Strecker products bearing a quaternary stereogenic center, which are valuable intermediates for the preparation of optically active a,a-disubstituted a-amino acids. 

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