Chirality enantioselective measurement

Section 2 discusses the syntheses of different classes of concave acids and bases. Convergent synthetic strategies were chosen for an easy structural variation of the reagents (modular assembly). Section 3 characterizes the concave acids and concave bases and checks whether the acid/base properties of the parent compounds benzoic acid, pyridine and 1,10-phenanthroline are conserved in the bimacrocyclic structures. In Section 4, the influence of the concave shielding on the reactivity and selectivity of the concave reagents is measured in model reactions. In principle, the concave shielding should be able to influence inter- and intramolecular competitions as well as chemoselectivity and (dia)stereoselectivity. If the reagent is chiral, enantioselectivity should also be observable. 

Changing the location of the oxazoline units from the external position to the internal position (position 5) allows the formation of a monomeric species in which the metal is in a C2-chiral environment. Measurable but low enantioselectivities were observed by using the open-ring form whereas the closed-ring counterpart, isolated after UV irradiation, did not lead to significant stereoselectivity as a result of a more rigid architecture which prevents a suitable coordination site for the metal center. 

More recently, further developments have shown that the reaction outlined in Scheme 4.33 can also proceed for other alkenes, such as silyl-enol ethers of acetophenone [48 b], which gives the endo diastereomer in up to 99% ee. It was also shown that / -ethyl-/ -methyl-substituted acyl phosphonate also can undergo a dia-stereo- and enantioselective cycloaddition reaction with ethyl vinyl ether catalyzed by the chiral Ph-BOX-copper(ll) catalyst. The preparative use of the cycloaddition reaction was demonstrated by performing reactions on the gram scale and showing that no special measures are required for the reaction and that the dihydro-pyrans can be obtained in high yield and with very high diastereo- and enantioselective excess. 

Zeijden [112] used chiral M-functionalized cyclopentadiene ligands to prepare a series of transition metal complexes. The zirconium derivative (82 in Scheme 46), as a moderate Lewis acid, catalyzed the Diels-Alder reaction between methacroleine and cyclopentadiene, with 72% de but no measurable enantiomeric excess. Nakagawa [113] reported l,T-(2,2 -bis-acylamino)binaphthalene (83 in Scheme 46) to be effective in the ytterbium-catalyzed asymmetric Diels-Alder reaction between cyclopentadiene and crotonyl-l,3-oxazolidin-2-one. The adduct was obtained with high yield and enantioselectivity (97% yield, endo/exo = 91/9, > 98% ee for the endo adduct). The addition of diisopropylethylamine was necessary to afford high enantioselectivities, since without this additive, the product was essentially... 

These ligands were active for allyhc substitutions but the process was not enantioselective in the benchmark reaction (88, in Scheme 49). More structurally constrained chelates led, however, to measurable enantioselectivities 40% ee for 89, 50% ee for 90, and 64% ee for 91 in the test reaction. By further modifications in the structure of these bipyridine-type hgands (see 92 in Scheme 51, a chiral Ci-symmetric 2,2 -bipyridine) [126], enantioselectivities up to 89% were obtained. 

The latter effect has been demonstrated by Meijer et al., who attached chiral aminoalcohols to the peripheral NH2-groups of polypropylene imine) dendrimers of different generations [100]. In the enantioselective addition of diethyl-zinc to benzaldehyde (mediated by these aminoalcohol appendages) both the yields and the enantioselectivities decreased with increasing size of the dendrimer (Fig. 28). The catalyst obtained from the 5th-generation dendrimer carrying 64 aminoalcohol groups at its periphery showed almost no preference for one enantiomer over the other. This behavior coincides with the absence of measurable optical rotation as mentioned in Sect. 3 above. The loss of activity and selectivity was ascribed to multiple interactions on the surface which were... 

This enantioselective mechanism is also in accordance with the elegant analysis and optical activity measurements by Pino et al.44,45 on the saturated propene oligomers obtained under suitable conditions with this kind of catalysts, proving that the re insertion of the monomer is favored in case of (R, R) chirality of coordination of the C2H4(1-Ind)2 ligand. 

Enantioselective reagents for ammonium ions include, for example, a mixture containing a host chiral crown ether such as 196, possessing four (R) centers and symbolized as M, a host achiral crown ether of similar functionality, symbolized as R, and a salt of a guest chiral amine, symbolized as A, which is analyzed by fast atom bombardment MS (FAB-MS), and the relative peak intensity of the equilibrium complexes 7(MA)//(RA) is measured and correlated with the chirality of the guest molecule. Many host and guest molecules have been investigated405. 

The rate of reaction 29 is found to be sensitive to the configuration of the guest A, making p-CD a gas-phase chiral selector. Its enantioselectivity, defined by the measured ko/kL ratio, is as large as far kolkL is from unit. Table 12 indicates that the /3-CD increases from alanine kolk = 0.62) to valine kolkL = 0.32), leucine... 

Gagne and coworkers utilized this combination to discover enantioselec-tive receptors for (-)-adenosine [12]. A racemic dipeptide hydrazone [( )-pro-aib] generated a stereochemically diverse DCL of n-mer. The dimers were composed of two chiral (DD/LL) and one achiral isomer (DL), the four trimers (DDD, LLL, DDL, and LLD), the tetramers of four chiral and two achiral isomers, etc. Two techniques were used to measure the enan-tio-imbalance that was caused by the enantioselective binding of the chiral analyte to the enantiomeric receptors (Fig. 5.11). Since the unperturbed library is optically inactive, the optical enrichment of each library component could be measured by a combined HPLC optical rotation detection scheme (laser polarimeter, LP). LP detection differentiated unselective binding (amplification but not optical enrichment) from enantioselective recognition of the analyte (amplification and optical enrichment). In this manner the LL dimer (SS) of the dipeptide was amplified and identified as the enantioselective match for (-)-adenosine. 

This tethered ferrocenyl-based Pd complex on MCM-41 (17) was then used for the catalytic amination reaction between cinnamyl acetate and benzylamine (40 °C, THF) [59]. In this case, confinement of the catalyst results in profound changes in regio- and enantioselectivity. When the homogeneous equivalent is used to catalyze the reaction, the straight chained derivative is the sole product. Similar results (only 2% of the branched product) were obtained when the catalyst was tethered to the surface of the non-porous silica Cabosil. When tethered inside the pores of MCM-41 a major change occurred in that now the branched product accounts for about 50% and a change in e.e. from 49% e.e. when anchored to the Cabosil support to +99% when anchored inside the MCM-41 pore could be observed. If the catalyst s chirality was reversed in the MCM-41 immobihzed case, so was the chirality of the product (measured at 93% e.e.) [60]. 

A chiral dichlororuthenium(IV) complex of a Z)4-symmetric porphyrin, [Ru (Z)4-por )(Cl)2], has been prepared by heating [Ru (Z>4-por )(CO)(MeOH)] in CCI4. The complex is characterized by NMR (paramagnetically shifted pyrrolic protons at = 52.3 ppm), FAB-MS, and magnetic susceptibility measurement (/.teff= 3.1/.tB). It is a very active catalyst for enantioselective alkene epoxidations using 2,6-dichloropyridine A-oxide as the terminal oxidant, with a turnover number of up to 2000 the ee of the epoxides is 50-80%. The complex can be incorporated into sol-gel and turnovers of over 10" can be achieved." ... 

Enantioselective enzyme-catalyzed reactions may involve the transformation of a prochiral substrate into a chiral product, in which case the selectivity is measured by the enantiomeric excess (ee). The transformations can also involve kinetic resolution of racemic substrates, in which case enantioselectivity is measured by the selectivity factor E reflecting the relative rates of reaction of the R)- and (5)-enantiomer. 

One of the first fluorescence-based ee assays uses umbelliferone (14) as the built-in fluorophore and works for several different types of enzymatic reactions 70,86). In an initial investigation, the system was used to monitor the hydrolytic kinetic resolution of chiral acetates (e.g., rac-11) (Fig. 8). It is based on a sequence of two coupled enzymatic steps that converts a pair of enantiomeric alcohols formed by the asymmetric hydrolysis under study (e.g., R - and (5)-12) into a fluorescent product (e.g., 14). In the first step, (R)- and (5)-ll are subjected separately to hydrolysis in reactions catalyzed by a mutant enzyme (lipase or esterase). The goal of the assay is to measure the enantioselectivity of this kinetic resolution. The relative amount of R)- and ( S)-12 produced after a given reaction time is a measure of the enantioselectivity and can be ascertained rapidly, but not directly. 

Reetz and coworkers developed a highly efficient method for screening of enantioselectivity of asymmetrically catalyzed reactions of chiral or prochiral substrates using ESI-MS [60]. This method is based on the use of isotopically labeled substrates in the form of pseudo-enantiomers or pseudo-prochiral compounds. Pseudo-enantiomers are chiral compounds which are characterized by different absolute configurations and one of them is isotopically labeled. With these labeled compounds two different stereochemical processes are possible. The first is a kinetic separation of a racemic mixture, the second the asymmetric conversion of prochiral substrates with enantiotopic groups. The conversion can be monitored by measuring the relative amounts of substrates or products by electrospray mass spectrometry. Since only small amounts of sample are required for this method, reactions are easily carried out in microtiter plates. The combination of MS and the use of pseudo-enantiomers can be used for the investigation of different kinds of asymmetric conversion as shown in Fig. 3 [60]. 

The ready availability of the transketolase (TK E.C. 2.2.1.1) from E. coli within the research collaboration in G. A. Sprenger s group suggested the joint development of an improved synthesis of D-xylulose 5-phosphate 19, which was expensive but required routinely for activity measurements [27]. In vivo, transketolase catalyzes the stereospecific transfer of a hydroxyacetyl nucleophile between various sugar phosphates in the presence of a thiamine diphosphate cofactor and divalent cations, and the C2 donor component 19 offers superior kinetic constants. For synthetic purposes, the enzyme is generally attractive for its high asymmetric induction at the newly formed chiral center and high kinetic enantioselectivity for 2-hydroxyaldehydes, as well as its broad substrate tolerance for aldehyde acceptors [28]. 

Enantiomeric purity. In order to assess the efficiency of an enantioselective hydrolase-catalyzed reaction, it is imperative that one can accurately measure at least the conversion and the enantiomeric excesses of either the substrate or the product (see equations Equation 1, Equation 2, and Equation 3). Although optical rotation is sometimes used to assess enantiomeric excess, it is not recommended. Much better alternatives are various chromatographic methods. For volatile compounds, capillary gas chromatography on a chiral liquid phase is probably the most convenient method. Numerous commercial suppliers offer a large variety of columns with different chiral liquid phases. Hence it is often easy to find suitable conditions for enantioselective GC-separations that yield ee-values in excess of... 

To test the feasibility of enzyme-catalyzed enantiosective reactions in solid/gas reactors and to evaluate the efficiency of the resolution obtained in the gas phase compared to liquid systems, resolution of racemic 2-pentanol, catalyzed by CALB, through alcoholysis with methyl propanoate as acyl donor has been investigated in both liquid media and the gas phase [24]. As CALB has an enantiopreference for R enantiomers of secondary alcohols, this last reaction leads to S-2-Pentanol. This compound is a chiral intermediate in the synthesis of several potential anti-Alzheimer s drugs that inhibit 3-amyloid peptide release and/or its synthesis [25]. The degree of enantioselectivity was measured by using the enantiomeric ratio E, which is defined as the ratio of the specificity constants kcat/KM for the enantiomers (R/S in this case). E can be determined from the enantiomeric excess of... 

A similar nonlinearity is seen in the ene reaction of methyl glyoxylate and a-methylstyrene (Scheme 43) (69). Thus, the reaction catalyzed by a complex in situ formed from dibromo(diisopropoxy)titanium(IV) and (/ )-binaphthol in 33% ee affords the chiral adduct in 91% ee with the same enantioselectivity as would have been obtained had enantiomerically pure binaphthol been used. Molecular weight measurements suggest the catalyst is a dinuclear titanium compound, although the structure has not been elucidated. This nonlinear effect is interpreted by the difference in the dissociation constant of the diastereomeric dimers as... 

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