Chiral acids

To understand how this method of resolution works, let s see what happens when a racemic mixture of chiral acids, such as (+)- and (-)-lactic acids, reacts with an achiral amine base, such as methylamine, CH3NH2. Stereochemically, the situation is analogous to what happens when left and right hands (chiral) pick up a ball (achiral). Both left and right hands pick up the ball equally well, and the products—ball in right hand versus ball in left hand—are mirror images. In the same way, both ( H- and (-)-lactic acid react with methylamine equally... 

The direct biocatalytic esterification of a chiral acid with a simple achiral alcohol in organic media is a reversible process and, in order to bias the equilibrium to the... 

The oldest method of resolving enantiomers by TLC takes advantage of the natural chiral properties of cellulose and triacetylcellulose resulting from the helical structure of the polymers (98). Amino acid derivatives have been resolved on silica gel layers impregnated with chiral acids or bases, for example. 

Our approach for chiral resolution is quite systematic. Instead of randomly screening different chiral acids with racemic 7, optically pure N-pMB 19 was prepared from 2, provided to us from Medicinal Chemistry. With 19, several salts with both enantiomers of chiral acids were prepared for evaluation of their crystallinity and solubility in various solvent systems. This is a more systematic way to discover an efficient classical resolution. First, a (+)-camphorsulfonic acid salt of 19 crystallized from EtOAc. One month later, a diastereomeric (-)-camphorsulfonic acid salt of 19 also crystallized. After several investigations on the two diastereomeric crystalline salts, it was determined that racemic 7 could be resolved nicely with (+)-camphorsulfonic acid from n-BuOAc kinetically. In practice, by heating racemic 7 with 1.3equiv (+)-camphorsulfonic acid in n-BuOAc under reflux for 30 min then slowly cooling to room temperature, a cmde diastereomeric mixture of the salt (59% ee) was obtained as a first crop. The first crop was recrystallized from n-BuOAc providing 95% ee salt 20 in 43% isolated yield. (The optical purity was further improved to -100% ee by additional recrystallization from n-BuOAc and the overall crystallization yield was 41%). This chiral resolution method was more efficient and economical than the original bis-camphanyl amide method. 

After salt break chiral acid 11 was converted to the methyl ketone 13 in essentially quantitative yield via the intermediacy of the Weinreb amide and processed as an oil without further purification (Scheme 9.6). The carbonyl group in 13 was then reduced to the secondary alcohol 16 using L-Selectride as previously described in 97% assay yield. We were pleased to find that an attainable reaction temperature of-50°C was sufficient to obtain high selectivity of >98 2, and that, in the absence of the reactive nitrile group, no issues were observed or during... 

The palladium-catalyzed oxidation of the 1,2-divinylcyclohexane system was applied to diastereoselective reactions with the use of chiral acids as nucleophiles25. With this technique an asymmetric induction of up to 76% was obtained in the formation of 21 from 14 (equation 9). The use of molecular sieves was essential in order to obtain a good asymmetric induction. 

The enantioselective hydrogenation of a,fj- or / ,y-unsaturated acid derivatives and ester substrates including itaconic acids, acrylic acid derivatives, buteno-lides, and dehydrojasmonates, is a practical and efficient methodology for accessing, amongst others, chiral acids, chiral a-hydroxy acids, chiral lactones and chiral amides. These are of particular importance across the pharmaceutical and the flavors and fragrances industries. 

In 1965, Denney et al. (98) reported the reaction of a number of alkenes with ferf-butyl hydroperoxide (TBHP) and cupric salts of chiral acids. The use of ethyl camphorate copper complex 144 in the allylic oxidation of cyclopentene provides, upon reduction of the camphorate ester, the allylic alcohol in low yield and low selectivity, Eq. 82. The initial publication only provided the observed rotation of cyclopentenol, but comparison to subsequent literature values (99) reveals that this reaction proceeds in 12% ee and 43% yield (based on the metal complex). 

Starting from the Pt-cinchona modified system, more recently an interesting concept has been developed by Feast and coworkers [144], A chiral acidic zeolite was created by loading one molecule of iM,3-dithianc-l-oxide per supercage of zeolite Y, either during or after the zeolite synthesis. Other chiral zeolites were formed by adsorbing ephedrine as a modifier on zeolites X and Y for the Norrish-Yang reaction [145],... 

Bidentate chiral water-soluble ligands such as (S,S)-2,4-bis(diphenyl-sulfonatophosphino)butane BDPPTS (Fig. 2) or (R,R) 1,2-bis(diphenylsul-fonatophosphinomethyl)cyclobutane have been prepared [25]. Their palladium complexes catalyze the synthesis of chiral acids from various viny-larenes and an ee of 43% has been reached for p-methoxystyrene with the BDPPTS ligand. Furthermore, recycling of the aqueous phase has shown that the regio- and enantioselectivity are maintained and that no palladium leaches. 

For this purpose, the chiral acid (R)-(-)-22 was chosen as the starting material and converted to the spirolactam 25. Condensation with benzylamine followed by catalytic dihydroxylation and oxidation gave aldehyde 23. 

Deprotection followed by A -acylation of 40 gave highly advanced diene 41 which was subjected to the final RCM with 42 and the desired dilactam (-)-(24Z)-43 was isolated from the mixture of geometrical isomers ZIE = ca. 2 3). Reduction of 43 with Red-Al resulted in the first total synthesis of enr-(+)-nakadomarin A from the readily available chiral acid 22. The absolute configuration of natural nakadomarin A was assigned to be R (Scheme 10.4) [9]. 

FIGURE 1.3 Enantiomer separation of the chiral acid iV-acetyl-a-allyl-glycine on CHIR-ALPAK QN-AX (a) and CHIRALPAK QD-AX (b) by an enantioselective anion-exchange retention process. Chromatographic conditions Column dimension, 150 x 4 mm ID eluent, 1 % (v/v) glacial acetic acid in methanol flow rate, 1 mLmin temperature, 25°C detection, UV 230 nm. (Reproduced from M. Lammerhofer, et ah, Nachrichten aus der Chemie, 50 1037 (2002). With permission.)... 

Meanwhile, a wide variety of cinchona alkaloid derivatives have been systematically developed as chiral selectors, which complement each other in their enantiomer discrimination profiles. Considering the variety of derivatives, an overall reasonably broad applicability spectrum, approximating for chiral acids a 100% success rate, is yielded and extreme enantiorecognition levels (a-values above 15) could be realized for some chiral solutes with certain selectors. Moreover, various studies carried out with the CHIRALPAK QD/QN-AX columns in industry and academia clearly document their practical usefulness for solving challenging real-life problems and this should be illustrated by the present review article as well. 

The PO mode is a specific elution condition in HPLC enantiomer separation, which has received remarkable popularity especially for macrocyclic antibiotics CSPs and cyclodextrin-based CSPs. It is also applicable and often preferred over RP and NP modes for the separation of chiral acids on the cinchonan carbamate-type CSPs. The beneficial characteristics of the PO mode may arise from (i) the offset of nonspecific hydrophobic interactions, (ii) the faster elution speed, (iii) sometimes enhanced enan-tioselectivities, (iv) favorable peak shapes due to improved diffusive mass transfer in the intraparticulate pores, and last but not least, (v) less stress to the column, which may extend the column lifetime. Hence, it is rational to start separation attempts with such elution conditions. Typical eluents are composed of methanol, acetonitrile (ACN), or methanol-acetonitrile mixtures and to account for the ion-exchange retention mechanism the addition of a competitor acid that acts also as counterion (e.g., 0.5-2% glacial acetic acid or 0.1% formic acid) is required. A good choice for initial tests turned out to be a mobile phase being composed of methanol-glacial acetic acid-ammonium acetate (98 2 0.5 v/v/w). 

Although the cinchonan carbamate-based CSPs are of primary interest for the separation of chiral acids, it needs to be stressed that the scope of application is, however, not restricted to chiral acids. A few reports in the literature deal with the separation of the enantiomers of neutral and weakly basic chiral compounds, respectively, on quinine carbamate-type CSPs [50-54]. Both RP and NP modes may be applicable. 

Overall, the /er/-butyl carbamates of quinine and quinidine evolved as the most effective chiral selectors among this family because of their broad enantioselectivity spectmm and exceptional degree of selectivity for a wide variety of chiral acids. On... 

Separation of Various Chiral Acids on Complementary Cinchonan Carbamate CSPs ... 

In a recent study, chiral separations for pyrethroic acids, which are the chiral building blocks of synthetic pyrethroids and the primary metabolites of the acid part of these potent ester insecticides, have been developed [62], For example, a polar-organic mobile phase allowed the complete baseline resolution of all four stereoisomers of chrysanthemic acid (2,2-dimethyl-3-(2-methylprop-l-enyl)-cyclopropanecarboxylic acid) on a 0-9-(tcrt-butylcarbamoyl)quinine-based CSP(acjj = 1.20, oLtrans = 1-35, critical Rs = 3.03) (Figure 1,32a). This chiral acid is the precursor of pyrethroids like allethrin, phenothrin, resmethrin, and tetramethrin but not excreted as metabolite. The primary acid metabolite of these pyrethroids is chrysanthemum dicarboxylic acid (3-[(l )-2-carboxyprop-l-enyl]-2,2-dimethylcyclopropanecarboxylic acid) the stereoisomers of which could also be resolved with a reversed-phase eluent (acetonitrile— 30-mM ammonium acetate buffer 90 10, v/v pHa = 6.0) and employing an O-9-(2,6-diisopropylphenylcarbamoyl)quinine-based CSP ads = 1-09, atrans = 1-50,... 

The broad and nearly universal applicability of the cinchonan carbamate CSPs for chiral acid separations is further corroborated by successful enantiomer separations of acidic solutes having axial and planar chirality, respectively. For example, Tobler et al. [124] could separate the enantiomers of atropisomeric axially chiral 2 -dodecyloxy-6-nitrobiphenyl-2-carboxylic acid on an C-9-(tert-butylcarbamoyl)quinine-based CSP in the PO mode with a-value of 1.8 and Rs of 9.1. This compound is stereolabile and hence at elevated temperatures the two enantiomers were interconverted during the separation process on-column revealing characteristic plateau regions between the separated enantiomer peaks. A stopped-flow method was utilized to determine the kinetic rate constants and apparent rotational energy barriers for the interconversion process in the presence of the CSP. Apparent activation energies (i.e., energy barriers for interconversion) were found to be 93.0 and 94.6 kJ mol for the (-)- and (-l-)-enantiomers, respectively. 

Other examples of successful enantiomer separations of miscellaneous chiral acids on cinchonan carbamate CSPs are collected in Table 1.11. 

Applicability Spectrum of Cinchona Alkaloid-Derived CSPs for Miscellaneous Chiral Acids... 

With capillary electrophoresis (CE), another modern primarily analytically oriented separation methodology has recently found its way into routine and research laboratories of the pharmaceutical industries. As the most beneficial characteristics over HPLC separations the extremely high efficiency leading to enhanced peak capacities and often better detectability of minor impurities, complementary selectivity profiles to HPLC due to a different separation mechanism as well as the capability to perform separations faster than by HPLC are frequently encountered as the most prominent advantages. On the negative side, there have to be mentioned detection sensitivity limitations due to the short path length of on-capillary UV detection, less robust methods, and occasionally problems with run-to-run repeatability. Nevertheless, CE assays have now been adopted by industrial labs as well and this holds in particular for enantiomer separations of chiral pharmaceuticals. While native cyclodextrins and their derivatives, respectively, are commonly employed as chiral additives to the BGEs to create mobility differences for the distinct enantiomers in the electric field, it could be demonstrated that cinchona alkaloids [128-130] and in particular their derivatives are applicable selectors for CE enantiomer separation of chiral acids [19,66,119,131-136]. 

These enantioselective capillary columns showed extremely good performance in the CEC mode. Plate numbers in excess of 100,000 m could be easily achieved for a variety of amino acid derivatives (with chromophoric and fluorophoric labels) (Eigure 1.34a) as well as other chiral acids such as 2-aryloxycarboxylic acids. 

Recently, on-line FBRM, ATR-FTIR spectroscopy, Raman spectroscopy and PLS were used to moifitor a complex crystallization system a racemic free base of a given componnd and a chiral acid. The anthors first demonstrate that the diastereomeric composition can be estimated nsing Raman spectral data, slnrry density and temperature using a PLS model. Consequently the issne of on-line slurry density prediction, which is not readily available, arises. An additional PLS model was constructed that used the ATR-FTIR spectral data to infer slurry density. Slurry density as predicted in real-time via ATR-FTIR spectroscopy was fed into the aforementioned Raman, slurry density and temperatnre PLS model to yield a more accnrate estimate of the fractional solid composition of the two diastereomers. ... 

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