Big Chemical Encyclopedia

Chemical substances, components, reactions, process design ...

Articles Figures Tables About

CSPs , glycopeptides

Table 2-2. The relative strength of potential interactions between glycopeptide CSPs and chiral analytes. Table 2-2. The relative strength of potential interactions between glycopeptide CSPs and chiral analytes.
The macrocyclic glycopeptides CSPs arc capable of operating in three different mobile phase systems reversed phase, normal phase, and the new polar organic mode. The new polar organic mode refers to the approach when methanol is used as the mobile phase with small amounts of acid and/or base as the modifier to control... [Pg.28]

The enantioselectivity of the macrocyclic CSPs are different in each of the operating modes, probably because of different separation mechanisms functioning in the different solvent modes. The possible chiral recognition mechanisms for three mobile phase compositions on glycopeptide phases are listed in Table 2-3 in descending order of strength. [Pg.29]

Statistically, of the compounds enantioresolved by macrocyclic glycopeptide CSPs, new polar organic mode accounts for more than 40 %, balanced by reversed-phase mode, while typical normal-phase operation resulted in approximately 5 % of separations. Some categories of racemic compounds that are resolved on the glycopeptide CSPs at different operating modes are listed in Table 2-4. [Pg.29]

Each glycopeptide CSP has unique selectivity as well as complementary characteristics, and a considerable number of racemates have been resolved on all three of them. Interestingly, most of the resolved enantiomers have the same retention order on these macrocyclic CSPs. When they are mixed or coupled with each other, the selectivity on one CSP will not be canceled by another. Even if some compounds may not have the same retention order, the complementary effects will result in an identifiable selectivity. Therefore, the coupled chiral columns can be used as a screening tool and save chromatographers substantial time in method development. [Pg.40]

For most free amino acids and small peptides, a mixture of alcohol with water is a typical mobile phase composition in the reversed-phase mode for glycopeptide CSPs. For some bifunctional amino acids and most other compounds, however, aqueous buffer is usually necessary to enhance resolution. The types of buffers dictate the retention, efficiency and - to a lesser effect - selectivity of analytes. Tri-ethylammonium acetate and ammonium nitrate are the most effective buffer systems, while sodium citrate is also effective for the separation of profens on vancomycin CSP, and ammonium acetate is the most appropriate for LC/MS applications. [Pg.51]

Typical normal-phase operations involved combinations of alcohols and hexane or heptane. In many cases, the addition of small amounts (< 0.1 %) of acid and/or base is necessary to improve peak efficiency and selectivity. Usually, the concentration of polar solvents such as alcohol determines the retention and selectivity (Fig. 2-18). Since flow rate has no impact on selectivity (see Fig. 2-11), the most productive flow rate was determined to be 2 mL miiT. Ethanol normally gives the best efficiency and resolution with reasonable back-pressures. It has been reported that halogenated solvents have also been used successfully on these stationary phases as well as acetonitrile, dioxane and methyl tert-butyl ether, or combinations of the these. The optimization parameters under three different mobile phase modes on glycopeptide CSPs are summarized in Table 2-7. [Pg.52]

Macrocyclic glycopeptides. The first of these CSPs - based on the cavity of the antibiotic vancomycin bound to silica - was introduced by Armstrong [25]. Two more polycyclic antibiotics teicoplanin and ristocetin A, were also demonstrated later. These selectors are quite rugged and operate adequately in both normal-phase and reversed-phase chromatographic modes. However, only a limited number of such selectors is available, and their cost is rather high. [Pg.58]

This relatively new class of CSPs incorporates glycopeptides attached covalently to silica gel. These CSPs can be used in the normal phase, reversed phase, and polar organic modes in LC [62]. Various functional groups on the macrocyclic antibiotic molecule provide opportunities for tt-tt complexation, hydrogen bonding, and steric interactions between the analyte and the chiral selector. Association of the analyte... [Pg.309]

Table 2-3. Possible separation mechanisms for three mobile phase compositions on glycopeptide CSPs. Table 2-3. Possible separation mechanisms for three mobile phase compositions on glycopeptide CSPs.
Table 2-4. Typical categories of racemic compounds resolved on glycopeptide CSPs in three mobile phase modes. Table 2-4. Typical categories of racemic compounds resolved on glycopeptide CSPs in three mobile phase modes.
Fig. 2-5. Examples showing the complementary separations on glycopeptide CSPs. (A) Separation of N-CBZ-norvaline on vancomycin (left) and teicoplanin (right). The mobile phase was methanol 1 % triethylammonium acetate (20/80 v/v) pH 4.1. (B) Separation of warfarin on teicoplanin (left) and vancomycin (right) CSPs. The mobile phase was acetonitrile 1 % triethylammonium acetate (10/90 v/v) pH 4.1. (C) Separation of naproxen on teicoplanin (left) and ristocetin A (right). The mobile phase was methanol 0.1 % triethylammonium acetate (30/70 v/v) pH 4.1. All columns were 250 x 4.6 mm i.d. The flow rate for all the separations was 1 mL min1 at ambient temperature (23 °C). Fig. 2-5. Examples showing the complementary separations on glycopeptide CSPs. (A) Separation of N-CBZ-norvaline on vancomycin (left) and teicoplanin (right). The mobile phase was methanol 1 % triethylammonium acetate (20/80 v/v) pH 4.1. (B) Separation of warfarin on teicoplanin (left) and vancomycin (right) CSPs. The mobile phase was acetonitrile 1 % triethylammonium acetate (10/90 v/v) pH 4.1. (C) Separation of naproxen on teicoplanin (left) and ristocetin A (right). The mobile phase was methanol 0.1 % triethylammonium acetate (30/70 v/v) pH 4.1. All columns were 250 x 4.6 mm i.d. The flow rate for all the separations was 1 mL min1 at ambient temperature (23 °C).

See other pages where CSPs , glycopeptides is mentioned: [Pg.24]    [Pg.25]    [Pg.26]    [Pg.27]    [Pg.29]    [Pg.30]    [Pg.30]    [Pg.35]    [Pg.37]    [Pg.38]    [Pg.38]    [Pg.38]    [Pg.39]    [Pg.41]    [Pg.43]    [Pg.44]    [Pg.46]    [Pg.48]    [Pg.51]    [Pg.53]    [Pg.6]    [Pg.39]    [Pg.40]    [Pg.44]    [Pg.44]    [Pg.49]    [Pg.52]    [Pg.52]    [Pg.52]    [Pg.58]    [Pg.60]    [Pg.62]   


SEARCH



CSPs

CSPs , glycopeptides containing

Glycopeptide

Glycopeptide-type CSPs

Glycopeptides

Macrocyclic Glycopeptide Antibiotic CSPs

Method Development with Glycopeptide CSPs

© 2024 chempedia.info