Enantiomer principle

The principle of this method depends on the formation of a reversible diastereomeric complex between amino acid enantiomers and chiral addends, by coordination to metal, hydrogen bonding, or ion—ion mutual action, in the presence of metal ion if necessary. L-Proline (60), T.-phenylalanine (61),... 

It is a general principle that optically active products cannot be formed when optically inactive substrates react with optically inactive reagents. This principle holds itie-spective of whether the addition is syn or anti, concerted or stepwise. No matter how many steps are involved in a reaction, if the reactants ar e achiral, formation of one enantiomer is just as likely as the other, and a racemic mixture results. 

Liquid-liquid extraction is a basic process already applied as a large-scale method. Usually, it does not require highly sophisticated devices, being very attractive for the preparative-scale separation of enantiomers. In this case, a chiral selector must be added to one of the liquid phases. This principle is common to some of the separation techniques described previously, such as CCC, CPC or supported-liquid membranes. In all of these, partition of the enantiomers of a mixture takes place thanks to their different affinity for the chiral additive in a given system of solvents. 

In the classical set-up of bulk liquid membranes, the membrane phase is a well-mixed bulk phase instead of an immobilized phase within a pore or film. The principle comprises enantioselective extraction from the feed phase to the carrier phase, and subsequently the carrier releases the enantiomer into the receiving phase. As formation and dissociation of the chiral complex occur at different locations, suitable conditions for absorption and desorption can be established. In order to allow for effective mass transport between the different liquid phases involved, hollow fiber... 

Fig. 5-17. Principle of micellar-enhanced ultrafiltration (MEUF). The d-enantiomer of a racemic mixture is preferentially bound to the micelles, which are retained by the membrane. The bulk containing the 1-enantiomer is separated through the membrane [72].

Process validation should be extended to those steps determined to be critical to the quality and purity of the enantiopure drug. Establishing impurity profiles is an important aspect of process validation. One should consider chemical purity, enantiomeric excess by quantitative assays for impurity profiles, physical characteristics such as particle size, polymorphic forms, moisture and solvent content, and homogeneity. In principle, the SMB process validation should provide conclusive evidence that the levels of contaminants (chemical impurities, enantioenrichment of unwanted enantiomer) is reduced as processing proceeds during the purification process. 

The answer is both yes and no. Yes in principle, but no in practice. Trivalent nitrogen compounds undergo a rapid umbrella-like inversion that inter-converts enantiomers. We therefore can t isolate individual enantiomers except in special cases. 

In principle, it should be possible to selectively reduce one of the enantiomers in a racemic sulfoxide mixture that is, an asymmetric kinetic resolution via reduction should... 

This type of procedure is referred to as a kinetic resolution since the enantiomers of the racemic substrate exhibit different rates of reaction with the optically active compound, i.e. the diastereomeric transition states that arise from differences in e.g. non-bonded interactions have different free energies. Horeau and Nouaille (1966) estimate that a rate difference corresponding to A AG of the order of 0 2 cal mol at 25°C could in principle be revealed by this method. 

A closely related method does not require conversion of enantiomers to diastereomers but relies on the fact that (in principle, at least) enantiomers have different NMR spectra in a chiral solvent, or when mixed with a chiral molecule (in which case transient diastereomeric species may form). In such cases, the peaks may be separated enough to permit the proportions of enantiomers to be determined from their intensities. Another variation, which gives better results in many cases, is to use an achiral solvent but with the addition of a chiral lanthanide shift reagent such as tris[3-trifiuoroacetyl-Lanthanide shift reagents have the property of spreading NMR peaks of compounds with which they can form coordination compounds, for examples, alcohols, carbonyl compounds, amines, and so on. Chiral lanthanide shift reagents shift the peaks of the two enantiomers of many such compounds to different extents. 

A single image recorded for a fixed enantiomer and fixed circular polarization state in principle carries the full information sought consisting, after inversion, of the parameters and the radial distribution function n r). After... 

Enantioselective enolate formation can also be achieved by kinetic resolution through preferential reaction of one of the enantiomers of a racemic chiral ketone such as 2-(f-butyl)cyclohcxanone (see Section 2.1.8 of Part A to review the principles of kinetic resolution). 

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