Enantioselectivities maximum

The enantioselective hydrogenation of oc,p-unsaturated acids (or their esters) and a-ketoesters, mainly pyruvates, (Figure 1) is a subject of high industrial relevance in the pharmaceutical and agrochemical areas, considering the very different activity of pure enantiomers (1,2). However, the former reaction has been up to today less investigated, evidencing a lower enantioselectivity (maximum ee 38% in comparison to 90% for the ethyl pymvate) (3,4). 

We therefore prepared a new chiral ligand, (l ,J )-isopropylidene-2,2 -bis[4-(o-hy-droxybenzyl)oxazoline)], hereafter designated J ,J -BOX/o-HOBn. To our delight, the copper(II) complex catalyst prepared from J ,J -BOX/o-HOBn ligand and Cu(OTf)2 was quite effective (Scheme 7.45). Especially, the reaction of O-benzylhydroxylamine with l-crotonoyl-3-isopropyl-2-imidazolidinone in dichloromethane (0.15 m) at -40°C in the presence of J ,J -BOX/o-HOBn-Cu(OTf)2 (10 mol%) provided the maximum enantioselectivity of 94% ee. 

To evaluate the economics of this process, a cost model has been developed to estimate the separation costs for a specific racemate [68, 69]. For this purpose, the sensitivity of the separation costs for several key process parameters have been established as compared to a base-case separation in which a purity of 99 % is required at an enantioselectivity of 1.15. The maximum solubility of the drug is set... 

A number of studies have recently been devoted to membrane applications [8, 100-102], Yoshikawa and co-workers developed an imprinting technique by casting membranes from a mixture of a Merrifield resin containing a grafted tetrapeptide and of linear co-polymers of acrylonitrile and styrene in the presence of amino acid derivatives as templates [103], The membranes were cast from a tetrahydrofuran (THF) solution and the template, usually N-protected d- or 1-tryptophan, removed by washing in more polar nonsolvents for the polymer (Fig. 6-17). Membrane applications using free amino acids revealed that only the imprinted membranes showed detectable permeation. Enantioselective electrodialysis with a maximum selectivity factor of ca. 7 could be reached, although this factor depended inversely on the flux rate [7]. Also, the transport mechanism in imprinted membranes is still poorly understood. 

On the other hand, high levels of diastereoselectivity are relatively easy to achieve in matched double asymmetric reactions since the intrinsic diastereofacial preference of the chiral aldehyde reinforces that of the reagent, and in many cases it has been possible to achieve synthetically useful levels of matched diastereoselection by using only moderately enantioselective chiral allylboron reagents. Finally, it is worth reminding the reader that both components of double asymmetric reactions need to be both chiral and nonracemic for maximum diastereoselectivity to be realized. 

Enzymatic KRs, as all resolutions, are limited to a maximum theoretical yield of 50%. Strategies to increase the yield are therefore of great importance. The opposite of a resolution, that is, the racemization of a chiral compound, can sometimes be highly desirable and applicable in enantioselective synthesis. By combining a... 

Very few examples have been described for the non-covalent immobilization of chiral porphyrin complexes (Fig. 26). In the first case, the porphyrin-dichlororutheninm complex was encapsulated in silica, which was prepared around the complex by a sol-gel method [78], in an attempt to prevent deactivation observed in solution in the epoxidation of different alkenes with 2,6-dichloropyridine N-oxide. In fact, the heterogeneous catalyst is much more active, with TON up to 10 800 in the case of styrene compared to a maximum of 2190 in solution. Enantioselectivities were about the same imder both sets of conditions, with values aroimd 70% ee. 

A novel nitrilase was purified from Aspergillus niger K10 cultivated on 2-cyanopyridine. It was found to be homologous to a putative nitrilase from Aspergillus fumigatus Af293. The nitrilase exhibited maximum activity at 45 °C and pH 8.0 with much less activity observed at slightly acid pH. Its substrate preference was for 4-cyanopyridine, benzonitrile, 1,4-dicyanobenzene, thio-phen-2-acetonitrile, 3-chlorobenzonitrile, 3-cyanopyridine, and 4-chlorobenzonitrile. ( )-2-Phenylpropionitrile was only poorly converted by this enzyme and with minimal enantioselectivity. The enzyme was shown to be multimeric (>650 kDa) and be stabilized in the presence of sorbitol and xylitol [57]. 

The effects of temperature on enantioselectivities have been examined using a Rh-Et-DuPhos catalyst in both MeOH [56d] and THF [144]. With /5-dehydro-amino acid derivative 73 in MeOH, an increase in temperature was found to have a slight beneficial effect for both ( ) and (Z)-isomers over a 70°C range, with maximum values being observed between 0°C and 25°C. In THF, however, the effect is much more pronounced, especially for the (Z)-isomer which varies in selectivity from 65% ee at 10 °C to 86% ee at 25 °C. Interestingly, when substrate 72 was reduced with a Rh-Et-BPE catalyst in THF, this temperature dependence on enantioselectivity for the (Z)-isomer was most apparent, the se-lectivities varying from 43% ee (10°C) to 90% ee (40°C). Examination of these results also seemed to indicate that the hydrogenation of /9-dehydroamino acid derivatives follows an unsaturated pathway (vide supra) [144]. 

Another PHOX analogue has the aryl ring of the PHOX catalyst replaced by a thiophene unit 16 (Fig. 29.4) [15]. The synthesis is similar to that of the PHOX catalysts, starting with oriho-nu lallaliori of the thiophene. The catalysts showed similar selectivity to PHOX, and were used to hydrogenate substrates 1 and 2 with maximum enantioselectivities of 99% and 94%, respectively. 

The minimum amount of catalyst needed to obtain maximum selectivity was determined to be 5 mol%. Larger quantities had no effect. Consistent with other literature reports[17], very small quantities of water (5 mol% = 2.5 mg E O/g 3) lowered the selectivities (Table 11.6, entry 4). Water sensitivity required thorough drying of the equipment, the starting materials and the solvents. In the case of tetrahydrofuran, drying was achieved by using activated 5 A molecular sieves (KF titration >0.005%). On the other hand, solvents used for crystallization of the starting material (3), such as 2-propanol and acetonitrile showed little effect on the enantioselectivities of the reaction (entries 6 and 7). 

Belokon et al. (260) reported that Cu(II) complex 426 may function as a chiral phase-transfer catalyst, although enantioselectivities are poor reaching a maximum of 22% based on optical rotation, Eq. 224. The authors suggest that the metal serves to carry the OH as a ligand into the organic phase. 

The asymmetric reduction of C=N double bonds in prochiral oximes afforded a maximum of 18% ee [380, 384, 385]. Prochiral azomethines were reduced to the corresponding 1,2-diamines and secondary amines using 36 optically active supporting electrolytes. The dimers were optically inactive, while the monomers showed low optical inductions (<11% ee). The effect of electrolyte, substrate concentration, temperature, pH, and cathode potential on the induction was studied. It was proposed that the enantioselectivity... 

The maximum enantioselectivity of 18 % achieved so far in aqueous hydroformylations may not seem very promising. However, the history of asymmetric hydrogenation of prochiral olefins and ketones demonstrates that such a situation may change fast if there is a strong drive behind the case. 

Hence, a reaction of Type I will involve a racemic or achiral/me,t(9 nncleophile which will react enantioselectively with an achiral acyl donor in the presence of a chiral catalyst, while on the other hand, a reaction of Type II will associate an achiral nncleophile and a racemic or udm lmeso acyl donor in the presence of a chiral catalyst. In both cases, when a racemic component is implicated the process constitntes a KR and the maximum theoretical yield of enantiomerically pure product, given perfect enantioselectivity, is 50%. When an achiral/mera component is involved, then the process constitutes either a site-selective asymmetric desymmetrisation (ASD) or, in the case of tt-nucleophiles and reactions involving ketenes, a face-selective addition process, and the maximum theoretical yield of enantiomerically pure product, given perfect enantioselectivity, is 100%. 

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