Glycopeptide macrocycle antibiotics chiral separations

Since the natural target of macrocyclic antibiotics is the A-acyl-D-alanyl-D-alanine terminus (see Section 2.1), the early choice of suitable substrates for this kind of CSPs was that of amino acids [45]. However, it turned out that the macrocyclic CSPs were very successful not only in amino acids enantioresolution, but also in the separation of a wide variety of different structures. The early stages of application of macrocyclic antibiotics have been surveyed in the different fields of chromatography [1,2]. A summary of the different categories of chiral compounds separated by HPLC on glycopeptides containing CSPs is reported in Table 2.3. 

Non steroidal antiinflammatory drugs were among the first classes of chiral compounds investigated in the early stages of the application of macrocyclic antibiotics as chiral selectors therefore, they were screened on vancomycin [7], teicoplanin [30], ristocetin A [33] CSPs under RPmode systems, and on avoparcin CSP under NP mode systems [37]. The enantioresolution of a variety of pro fens was later reported on commercially available vancomycin CSPs [128, 168], and recently on a ME-TAG CSP [58]. Ibuprofen enantiomers were also separated on a CDP-1-containing CSP [55]. Glycopeptide A-40,926 CSP was successfully employed in the analytical and semipreparative separation of 2-arylpropionic acids [63]. 

The use of macrocyclic antibiotics as chiral selectors for HPLC was first proposed by Armstrong et al. [50] in 1994. The most successful of the CSPs are based on the glycopeptide antibiotics vancomycin, teicoplanin and ristocetin A and are commercially available through Advanced Separation Technologies Inc. (Astec Inc.) as Chirobiotic V , Chirobiotic 1 and Chirobiotic R , respectively. More recently, a number of other derivatives of these antibiotics have also been developed offering different stereoselectivities. A comprehensive handbook is now available from Astec Inc. [51 ] alongside a number of recent review articles... 

In addition to the vancomycin and teicoplanin CSPs, ristocetin A (Chirobiotic R) [289] and recently avoparcin [280] have been evaluated as novel chiral SOs and CSPs. It turned out that within the large family of macrocyclic antibiotics complementarity of enantioselectivity exists for different glycopeptides. As a consequence, very often it is possible to obtain a complete resolution by switching to a congeneric antibiotic CSP, if after optimization no baseline, but partial. separation can be achieved on a certain macrocyclic antibiotic type CSP (see Fig. 9.22). It can be expected that the enantioselectivity potential of closely related antibiotics will be further exploited in the future leading to an increase in the number of macrocyclic antibiotic type CSPs. 

Tesarova and Bosakova [58] proposed an HPLC method for the enantio-selective separation of some phenothiazine and benzodiazepine derivatives on six different chiral stationary phases (CSPs). These selected CSPs, with respect to the structure of the separated compounds, were either based on b-CD chiral selectors (underivatized (J>-CD and hydroxypropyl ether (3-CD) or on macrocyclic antibiotics (vancomycin, teicoplanin, teicoplanin aglycon and ristocetin A). Measurements were carried out in a reversed-phase separation mode. The influence of mobile phase composition on retention and enantio-selective separation was studied. Enantioselective separation of phenothiazine derivatives, including levopromazine (LPZ), promethazine and thioridazine, was relatively difficult to achieve, but it was at least partly successful with both types of CSPs used in this work (CD-based and glycopeptide-based CSP), except for levomepromazine for which only the [CCD-based CSP was suitable. 

Since first demonstration in 1994 of the potential use of macrocyclic antibiotics as chiral selectors in analysis, glycopeptide antibiotics have been successfully applied for enantiomer separations by liquid chromatography, as recognition components of chiral stationary phases, and by capillary electrophoresis (CE) as soluble chiral selec-tors. Four chiral stationary phases for chromatography with the selectors vancomycin, ristocetin, teicoplanin, and the teicoplanin aglycone are commercialized under the trade name Chirobiotic by Astec and Supelco. Various aspects of analytical applications of glycopeptide antibiotics have been extensively covered in the recent reviews cited above. As an example. Table 2 shows some representative results for CE enantioseparations with vancomycin, ristocetin A, and teicoplanin, which were taken from Ref. 39. 

Abstract Medical studies established that vancomycin and other related macro-cyclic antibiotics have an enhanced antimicrobial activity when they are associated as dimers. The carbohydrate units attached to the vancomycin basket have an essential role in the dimerization reaction. Covalently synthesized dimers were found active against vancomycin-resistant bacterial strains. A great similarity between antibiotic potential and enantioselectivity was established. A covalent vancomycin dimer was studied in capillary electrophoresis producing excellent chiral separation of dansyl amino acids. Balhimycin is a macrocyclic glycopeptide stmcturally similar to vancomycin. The small differences are, however, responsible for drastic differences in enantioselectivity in the same experimental conditions. Contributions from studies examining vancomycin s mechanism for antimicrobial activity have substantially aided our understanding of its mechanism in chiral recognition. 

The group of Bakhtiar [57-59] described the chiral bioanalysis of MPH in various matrices, utilizing a number of sample pretreatment strategies, separation on a Chirobiotic V columns, and the use of positive-ion APCI-MS in SRM mode. The chiral selectivity of the Chirobiotic V column is based on the use of the macrocyclic glycopeptide antibiotic vancomycin. The column can be used in both aqueous and organic mobile phase. 

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