Polysaccharides chiral selectors

The preparation of the conventional chiral stationary phases can be realized both by surface immobilization of natural chiral selectors (polysaccharides, proteins) on chromatographic supports, and by direct synthesis of stationary phases composed of polyacrylates with pendant chiral groups, amides, or helical polymers. Even if they are quite expensive and poorly resistant to chemical and biological attack, these materials are largely used to separate racemic mixtures for preparative and... 

The type of CSPs used have to fulfil the same requirements (resistance, loadabil-ity) as do classical chiral HPLC separations at preparative level [99], although different particle size silica supports are sometimes needed [10]. Again, to date the polysaccharide-derived CSPs have been the most studied in SMB systems, and a large number of racemic compounds have been successfully resolved in this way [95-98, 100-108]. Nevertheless, some applications can also be found with CSPs derived from polyacrylamides [11], Pirkle-type chiral selectors [10] and cyclodextrin derivatives [109]. A system to evaporate the collected fractions and to recover and recycle solvent is sometimes coupled to the SMB. In this context the application of the technique to gas can be advantageous in some cases because this part of the process can be omitted [109]. 

Examples with other Pirkle-type CSPs have also been described [139, 140]. In relation to polysaccharides coated onto silica gel, they have shown long-term stability in this operation mode [141, 142], and thus are also potentially good chiral selectors for preparative SFC [21]. In that context, the separation of racemic gliben-clamide analogues (7, Fig. 1-3) on cellulose- and amylose-derived CSPs was described [143]. 

Mourier s report was quickly followed by successful enantiomeric resolutions on stationary phases bearing other types of chiral selectors, including native and deriva-tized cyclodextrins and derivatized polysaccharides. Many chiral compounds of pharmaceutical interest have now been resolved by packed column SFC, including antimalarials, (3-blockers, and antivirals. A summary is provided in Table 12-2. Most of the applications have utilized modified CO, as the eluent. 

Nishi et al. [110] used dextran and dextrin as chiral selectors in capillary-zone electrophoresis. Polysaccharides such as dextrins, which are mixtures of linear a-(l,4)-linked D-glucose polymers, and dextrans, which are polymers of D-glucose units linked predominantly by a-(l,6) bonds, have been employed as chiral selectors in the capillary electrophoretic separation of enantiomers. Because these polymers are electrically neutral, the method is applicable to ionic compounds. The enantiomers of basic or cationic drugs such as primaquine were successfully separated under acidic conditions. The effects of molecular mass and polysaccharide concentration on enantioselectivity were investigated. 

Different classifications for the chiral CSPs have been described. They are based on the chemical structure of the chiral selectors and on the chiral recognition mechanism involved. In this chapter we will use a classification based mainly on the chemical structure of the selectors. The selectors are classified in three groups (i) CSPs with low-molecular-weight selectors, such as Pirkle type CSPs, ionic and ligand exchange CSPs, (ii) CSPs with macrocyclic selectors, such as CDs, crown-ethers and macrocyclic antibiotics, and (iii) CSPs with macromolecular selectors, such as polysaccharides, synthetic polymers, molecular imprinted polymers and proteins. These different types of CSPs, frequently used for the analysis of chiral pharmaceuticals, are discussed in more detail later. 

Based on the theory, the separation of enantiomers requires a chiral additive to the CE separation buffer, while diastereomers can also be separated without the chiral selector. The majority of chiral CE separations are based on simple or chemically modified cyclodextrins. However, also other additives such as chiral crown ethers, linear oligo- and polysaccharides, macrocyclic antibiotics, chiral calixarenes, chiral ion-pairing agents, and chiral surfactants can be used. Eew non-chiral separation examples for the separation of diastereomers can be found. 

H Nishi. Enantiomer separation of basic drugs by capillary electrophoresis using ionic and neutral polysaccharides as chiral selectors. J Chromatogr A 735 345-351, 1996. 

RMC Sutton, KL Sutton, AM Stalcup. Chiral capillary electrophoresis with noncyclic oligo- and polysaccharide chiral selectors. Electrophoresis 18 2297-2304, 1997. 

As discussed in Section 3.1.6.1., natural biopolymers are useful chiral selectors, some of which are readily available they are constructed from chiral subunits (monomers), for instance, from L-amino acids or D-glucose. If synthetic chiral polymers of similar type are to be synthesized, appropriate chiral starting materials and subunits, respectively, must be found. Chiral polymers with, for example, a helical structure as the chiral element, are built using a chiral catalyst as chirality inducing agent in the polymerization step. If the chirality is based on a chiral subunit, the chirality of the polymer is inherent, whereas if the polymer is constructed from chiral starting materials, chiral subunits are formed which lead to chirally substituted synthetic polymers that in addition may order or fold themselves to a supramolecular structure (cf. polysaccharides). 

In contrast, CSPs have achieved great repute in the chiral separation of enantiomers by chromatography and, today, are the tools of the choice of almost all analytical, biochemical, pharmaceutical, and pharmacological institutions and industries. The most important and useful CSPs are available in the form of open and tubular columns. However, some chiral capillaries and thin layer plates are also available for use in capillary electrophoresis and thin-layer chromatography. The chiral columns and capillaries are packed with several chiral selectors such as polysaccharides, cyclodextrins, antibiotics, Pirkle type, ligand exchangers, and crown ethers. 

The chiral recognition mechanisms in NLC and NCE devices are similar to conventional liquid chromatography and capillary electrophoresis with chiral mobile phase additives. It is important to note here that, to date, no chiral stationary phase has been developed in microfluidic devices. As discussed above polysaccharides, cyclodextrins, macrocyclic glycopeptide antibiotics, proteins, crown ethers, ligand exchangers, and Pirkle s type molecules are the most commonly used chiral selectors. These compounds... 

Figure 35 CEC enantioseparations of 2-(benzylsulfinyl)benzamide in capillaries packed with derivitized with differing amounts of the polysaccharide derivative cellulose tris(3,5-dichlorophenylcarbamate). The stationary phase contained (a) 4.8%, (b) 1.0%, and (c) 0.5% (w/w) of the chiral selector. (Reprinted from Ref. 1 56, with permission.)...

The chiral SO is coated to the capillary wall. This technique is known as open-tubular electrochromatography (OT-EC) )5(X)1. Enantioselective OT-EC methods have been described for CDs 1277), proteins ).501), polysaccharides )5021 and terguride [503] as chiral selectors. The main disadvantage is the low loading capacity, and therefore this technique has not gained high popularity. 

A CSP consists of a chiral selector, which either alone constitutes the stationary phase or which has been immobilised to a solid phase. The chiral selector is a low molecular weight compound or a polymer, either synthetic or natural. A broad range of CSPs has been developed. Examples of CSPs that have been used successfully include polysaccharides, such as cellulose and its derivatives [6] and cyclodex-trins [7], and proteins, e.g. bovine serum albumin, aj-acid glycoprotein, cellulase, trypsin and a-chymotrypsin [8]. Several different synthetic polymers have also proven to be useful CSPs, for example the Blaschke-type CSPs (polyacrylamides and polymethacrylamides) [9] and the Pirkle-type CSPs [10]. 

Chiral columns are packed with stereo-specific sorbents for the separation of stereoisomers in the sample.27 Many chiral columns operate in hydrophilic interaction mode (e.g., Pirkle-type) whereas others are used in reversed-phase mode (proteins, macrocyclic antibiotics, polysaccharides, etc.). The use of these columns is critical in the development of chiral drugs. Most chiral columns are quite expensive and many older chiral columns have low efficiencies and limited lifetimes. Examples of chiral separations are shown in Chapter 6. Alternately, convention columns can also be used for chiral separations using a chiral selector in the mobile phase.27... 

The chiral buffer additives include antibiotics, cyclodextrins, crown ethers, polysaccharides, proteins, and chiral surfactants. Cyclodextrins are the most versatile and popular chiral selectors (163-168). 

A review of enantiomeric separations by CE using polysaccharides as chiral selectors has been reported (217). Ionic and neutral polysaccharides (e.g., heparin, chondroitin sulfate, dextrin, and maltodextrins) have been used to resolved enantiomers. Racemic acidic drugs were resolved with maltodextrins (218), while heparins and cyclodextrins were used to resolve oxamigue (219). A large number of drugs have been found to bind enantioselectively to proteins. 

As in analytical chiral LC, Daicel derivatised polysaccharide CSPs are the most frequently used materials in preparative scale chiral separations. Recently CSPs have been prepared in which derivatised polysaccharides have been covalently bonded to the solid support rather than coated on as in the Diacel materials. The rationale for this is that it is advisable to reduce the chance of the chiral selector leeching off the column in trace amounts to contaminate samples of chiral dmgs isolated by production scale LC. However, the extent to which the Daicel coated CSPs are now used in production scale chiral LC would tend to suggest that such a problem, if it exists, is not a very significant risk. 

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